Ks0428 keyestudio Mini Tank Robot V2: Difference between revisions

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'''*About keyestudio'''
'''*About keyestudio'''


Keyestudio is a best-selling brand owned by KEYES Corporation, our product lines range from controller boards, shields and sensor modules to smart car and complete starter kits for Arduino, Raspberry Pi and BBC micro:bit, which designed for customers of any level to learn electronics and programming knowledge. All of our products comply with international quality standards and are greatly appreciated in a variety of different markets throughout the world.
Keyestudio is a best-selling brand owned by KEYES Corporation, our product lines range from controller boards, shields and sensor modules to smart car and complete starter kits for Arduino, Raspberry Pi and BBC micro:bit, which designed for customers of any level to learn electronics and programming knowledge. All of our products comply with international quality standards and are greatly appreciated in a variety of different markets throughout the world.<br>
You can obtain the details and the latest information through visiting the following web sites:http://www.keyestudio.com
You can obtain the details and the latest information through visiting the following web sites:http://www.keyestudio.com<br>


'''*References and After-sales Service'''
'''*References and After-sales Service'''


1.Download Profile:https://fs.keyestudio.com/KS0428
1.Download Profile:https://fs.keyestudio.com/KS0428<br>
2.Feel free to contact us please, if there is missing part or you encounter some troubles. Welcome to send email to us:service@keyestudio.com. We will update projects and products continuously based on your sincere advice.
2.Feel free to contact us please, if there is missing part or you encounter some troubles. Welcome to send email to us:service@keyestudio.com. <br> We will update projects and products continuously based on your sincere advice.<br>


'''*Warning'''
'''*Warning'''


1.This product contains tiny parts(screws, copper pillars), keep it out of reach of children under 7 years old please.
1.This product contains tiny parts(screws, copper pillars), keep it out of reach of children under 7 years old please.<br>
2. This product contains conductive parts (control board and electronic module). Please operate according to the requirements of this tutorial. Improper operation may cause overheating and damage parts. Do not touch and immediately disconnect the circuit power.
2. This product contains conductive parts (control board and electronic module). Please operate according to the requirements of this tutorial. Improper operation may cause overheating and damage parts. Do not touch and immediately disconnect the circuit power.<br>




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== Introduction ==  
== Introduction ==  
   
   
Nowadays, technological education such as VR, kids programming, and artificial intelligence, has become mainstream in educational industry. Thereby, people attach importance to STEAM education. Arduino is pretty notable in Maker education.
Nowadays, technological education such as VR, kids programming, and artificial intelligence, has become mainstream in educational industry. Thereby, people attach importance to STEAM education. Arduino is pretty notable in Maker education.<br>


So what is Arduino? Arduino is an open-source electronics platform based on easy-to-use hardware and software. Arduino boards are able to read inputs - light on a sensor, a finger on a button, or a Twitter message - and turn it into an output - activating a motor, turning on an LED, publishing something online. Based on this, Keyestudio team has designed a mini tank robot. The tank robot has a processor which is programmable using the Arduino IDE, to mapped its pins to sensors and actuators by a shield that plug in the processor, it reads sensors and controls the actuators and decides how to operate.
So what is Arduino? Arduino is an open-source electronics platform based on easy-to-use hardware and software. Arduino boards are able to read inputs - light on a sensor, a finger on a button, or a Twitter message - and turn it into an output - activating a motor, turning on an LED, publishing something online. Based on this, Keyestudio team has designed a mini tank robot. The tank robot has a processor which is programmable using the Arduino IDE, to mapped its pins to sensors and actuators by a shield that plug in the processor, it reads sensors and controls the actuators and decides how to operate.<br>


15 learning projects, from simple to complex, will guide you how to make a smart tank robot on you own and introduce the detailed knowledge about sensors and modules. <br>
15 learning projects, from simple to complex, will guide you how to make a smart tank robot on you own and introduce the detailed knowledge about sensors and modules. <br>
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Make sure no any parts missing please when you get this robot kit. And  if it is, please feel free to contact us.
Make sure no any parts missing please when you get this robot kit. And  if it is, please feel free to contact us.


<br>[[File:0428-4.png|500px|frameless|thumb]]<br>
'''Please tear off the protective film on the acrylic board before mounting the kit'''
<br>[[File:0428-5.png|500px||frameless|thumb]]<br> 
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QQ图片20210422152554.png|
<br>[[File:0428-15.png|500px|frameless|thumb]]<br>


== Assembly Guide ==
== Assembly Guide ==
<span style=color:red> <big>Note: Remove the Bluetooth module before uploading test code, otherwise, you will fail to upload test code</big></span>
    
    
After making an inventory all the parts in this kit, then we need to mount the tank robot. Let’s install smart car in compliance with the following instructions.
<span style=color:red>'''Note: Peel the plastic film off the board first when installing the smart car. To be honest, we never intend to send wood to you.'''<br>


Step 1: Install the tank bottom motor
After making an inventory all the parts in this kit, then we need to mount the tank robot. Let’s install smart car in compliance with the following instructions.<br>
 
Step 1: Install Bottom Motor


Prepare the parts as follows:
Prepare the parts as follows:


* M4 nut * 2
* M4 Nut * 2
* Metal motor *2  
* Metal Motor *2  
* Metal holder *2
* Metal Holder *2
* Copper coupler *2
* Copper Coupler *2
* Blue supporting parts *2
* Blue Supportive Parts *2
* M4*12MM inner hex screw * 2
* M4*12MM Inner Hex Screw * 2
* L-type M1.5 inner hex wrench *1
* M1.5 Hex Key Nickel Plated Allen Wrench *1
* L-type M3 inner hex wrench *1
* M3 Hex Key Nickel Plated Allen Wrench *1
* L-type M2.5 inner hex wrench *1
* M2.5 Hex Key Nickel Plated Allen Wrench *1
* M3*8MM inner hex screw * 4
* M3*8MM Inner Hex Screw * 4


<br>[[File:0428-1.png|500px|frameless|thumb]]<br>   
<br>[[File:QQ图片20210907153855.png|500px|frameless|thumb]]<br>   
<br>[[File:0428-2.png|500px|frameless|thumb]]<br>   
<br>[[File:0428-2.png|500px|frameless|thumb]]<br>   


Step 2: Install the tank driver wheel
Step 2: Install Driver Wheel


Prepare the parts as follows:
Prepare the parts as follows:


* M4*12MM inner hex screw * 2
* M4*12MM Inner Hex Screw * 2
* M4*50MM inner hex screw * 2
* M4*50MM Inner Hex Screw * 2
* Tank Load-bearing wheel * 2
* Tank Load-bearing Wheel * 2
* Flange Bearing * 4
* Flange Bearing * 4
* Copper bush *2
* Copper Bush *2
* Caterpillar Band *2
* Caterpillar Band *2
* M4 self-locking nut * 2
* M4 Self-locking Nut * 2
* L-type M3 inner hex wrench *1
* M3 Hex Key Nickel Plated Allen Wrench *1


<br>[[File:0428-16.png|500px|frameless|thumb]]<br>   
<br>[[File:0428-16.png|500px|frameless|thumb]]<br>   
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Step 3: Install the battery holder
Step 3: Install the Battery Holder


Prepare the parts as follows:  
Prepare the parts as follows:  
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<br>[[File:0428-19.png|300px|right|frameless|thumb]]<br>   
<br>[[File:0428-19.png|300px|right|frameless|thumb]]<br>   


* Battery holder *1
 
* M3 nut * 2
* Battery Holder *1
* M3 Nut * 2
* Blue Metal holder *2
* Blue Metal holder *2
* M4 nut *8
* M4 Nut *8
* M3*10MM flat-head screw * 2
* M3*10MM Flat Head Screw * 2
* M4*40MM inner hex screw *4
* M4*40MM Inner Hex Screw *4
* L-type M2.5 inner hex wrench *1
* M2.5 Hex Key Nickel Plated Allen Wrench*1
* L-type M3 inner hex wrench *1
* M3 Hex Key Nickel Plated Allen Wrench *1
* M3*25MM inner hex screw *4
* M3*25MM Inner Hex Screw *4


Finish the above part. Go to fix the metal holder on the motor wheel with four M4*40MM inner hex screws and four M4 nuts.
Finish the mount process. Go to fix the metal holder on the motor wheel with four M4*40MM inner hex screws and four M4 nuts.
<br>[[File:0428-20.png|500px|frameless|thumb]]<br>   
<br>[[File:0428-20.png|500px|frameless|thumb]]<br>   
<br>[[File:0428-21.png|500px|frameless|thumb]]<br>   
<br>[[File:0428-21.png|500px|frameless|thumb]]<br>   
<br>[[File:0428-22.png|500px|frameless|thumb]]<br>   
<br>[[File:0428-22.png|500px|frameless|thumb]]<br>   


Step 4: Mount the sensor module
Step 4: Mount Acrylic Board and Sensors
   
   
* Install Acrylic board and sensor modules:
* Acrylic Board * 2
* Acrylic Board * 2
* L- type black bracket *1
* L- type Black Bracket *1
* Photocell Sensor *2
* Photocell Sensor *2
* IR Receiver Module *1
* IR Receiver Module *1
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* M2 Nut *4  
* M2 Nut *4  
* M3 Nut *10
* M3 Nut *10
* M3*8MM inner hex screw * 4
* M3*6MM Inner Hex Screw * 8
* L-type M2.5 inner hex wrench *1
* M2.5 Hex Key Allen Wrench *1
* M3*12MM Round-head screw *7
* M3*12MM Round Head Screw *7
* M2*11MM dual-pass copper pillar *4
* M3*10MM Hexagon Copper Bush *8
* M2*10MM Round-head screw * 8
* M2*10MM Round Head Screw * 4


<br>[[File:0428-23.png|500px|frameless|thumb]]<br>   
<br>[[File:QQ图片2020091718.png|500px|frameless|thumb]]<br>   
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<br>[[File:0428-26.png|500px|frameless|thumb]]<br>  
<br>[[File:QQ图片20200917191-11.png|500px|frameless|thumb]]<br>  


Step 5: Install the servo platform
Step 5: Install the Servo Platform 


Prepare the parts as follows:
Prepare the parts as follows:


* Servo *1
* Servo *1
* Black gimbal *1
* Black Gimbal *1
* Cable tie *2
* Cable Tie *2
* M2x8 Round head cross tapping screw *2
* M2x8 Round Head Cross Tapping Screw *2
* Ultrasonic *1
* Ultrasonic Sensor *1
* M2*4 screw *1
* M2*4 Screw *1
* M1.2*5 screw *4
* M1.2*5 Screw *4
 
 
Note: for convenient debugging, keep the ultrasonic module straight ahead and the angle of servo motor 90°. Therefore, we need to set servo to 90° before installing the servo platform.   


Note: For convenient debugging, make sure that the ultrasonic module is in front of tank robot, and the angle of servo motor is 90°. Therefore, we need to set servo to 90° before installing the servo platform.  
<br>[[File:图片123564.png|800px|frameless|thumb]]<br>
 
<br>[[File:QQ图片20220121101851.png|800px|frameless|thumb]]<br>
 
<big><span style=color:red>'''You can find M1.2*5 Screws inside the bag of Plastic Platform.'''</big></span>


<br>[[File:0428-27.png|500px|frameless|thumb]]<br>
<br>[[File:0428-28.png|500px|frameless|thumb]]<br>  
<br>[[File:0428-28.png|500px|frameless|thumb]]<br>  




Step 6: Install all parts of Acrylic plate
Step 6: Install Sensors and Boards


Prepare the parts as follows:
Prepare the parts as follows:


* M2*5MM round head screw *4
* M3*6MM Round Head Screw *12
* M3*6MM round head screw *8
* M3*12MM round head screw *2
* M3 nickel plating nut *2
* L298P Shield *1
* L298P Shield *1
* V4.0 Board *1
* V4.0 Board *1
* V5 Sensor Shield *1
* V5 Sensor Shield *1
* Screwdriver *1
* Screwdriver *1
* Bluetooth *1
* Bluetooth Module *1


<br>[[File:0428-29.png|500px|frameless|thumb]]<br>  
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<br>[[File:QQ图片20200917191-14.png|500px|frameless|thumb]] [[File:04288-1.png|500px|frameless|thumb]]<br>  
<br>[[File:0428-32.png|700px|frameless|thumb]]<br>  
<br>[[File:QQ图片20200917191-15.png|700px|frameless|thumb]]<br>  


Step 7: Hook-up Guide
Step 7: Hook-up Guide


<br>[[File:0428-33.png|700px|frameless|thumb]]<br>  
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<br>[[File:04288-5.png|700px|frameless|thumb]]<br>
<br>[[File:04288-6.png|700px|frameless|thumb]]<br>  


Step 8: Wire up LED panel


<br>[[File:0428-35.png|500px|frameless|thumb]]<br>
Step 8: Wire up LED Panel
<br>[[File:0428-36.png|500px|frameless|thumb]]<br>


<br>[[File:04288-7.png|500px|frameless|thumb]]<br>
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<br>[[File:04288-9.png|500px|frameless|thumb]]<br>
<br>[[File:04288-10.png|500px|frameless|thumb]]<br>


Step 9: Install all parts of Acrylic plate


Step 9: install all parts of Acrylic plate
<br>[[File:0428-37.png|500px|frameless|thumb]]<br>  
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<span style=color:red>Note: Remove the Bluetooth module before uploading test code, otherwise, you will fail to upload test code.<br>


== Install Arduino IDE and Driver ==  
== Install Arduino IDE and Driver ==  
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It has 14 digital input/output pins (of which 6 can be used as PWM outputs), 6 analog inputs, a 16 MHz quartz crystal, a USB connection, a power jack, 2 ICSP headers and a reset button.
It has 14 digital input/output pins (of which 6 can be used as PWM outputs), 6 analog inputs, a 16 MHz quartz crystal, a USB connection, a power jack, 2 ICSP headers and a reset button.


<br>[[File:0470---39.png|500px|frameless|thumb]]<br>
<br>[[File:0428---1000.png|500px|frameless|thumb]]<br>


It contains everything needed to support the microcontroller; simply connect it to a computer with a USB cable or power it via an external DC power jack (DC 7-12V) or via female headers Vin/ GND(DC 7-12V) to get started.
It contains everything needed to support the microcontroller; simply connect it to a computer with a USB cable or power it via an external DC power jack (DC 7-12V) or via female headers Vin/ GND(DC 7-12V) to get started.
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=== '''Arduino IDE Setting''' ===


Click[[Image:0486-12.png|200px|frameless]] icon,open Arduino IDE.
<br>[[Image:0085=14.png|400px|frameless]]<br>


To avoid the errors when uploading the program to the board, you need to select the correct Arduino board that matches the board connected to your computer.
Then come back to the Arduino software, you should click Tools→Board, select the board. (as shown below)
<br>[[Image:0085=15.png|500px|frameless]]<br>




Then select the correct COM port (you can see the corresponding COM port after the driver is successfully installed)


<br>[[Image:0085=16.png|500px|frameless]]<br>
<br>[[Image:0085=17.png|500px|frameless]]<br>


Before uploading the program to the board, let’s demonstrate the function of each symbol in the Arduino IDE toolbar.<br>


A- Used to verify whether there is any compiling mistakes or not.<br>
B- Used to upload the sketch to your Arduino board.<br>
C- Used to create shortcut window of a new sketch.<br>
D- Used to directly open an example sketch.<br>
E- Used to save the sketch.<br>
F- Used to send the serial data received from board to the serial monitor.<br>


=== Start your first program ===


Open the file to select Example, choose BLINK from BASIC, as shown below:




<br>[[Image:048610png.png|500px|frameless]]<br>


<br>[[Image:048611png.png|500px|frameless]]<br>


Set board and COM port, the corresponding board and COM port are shown on the lower right of IDE.


<br>[[Image:048612png.png|500px|frameless]]<br>       


Click [[Image:0486-20.png|50px|frameless]] to start compiling the program, check errors.


<br>[[Image:048613png.png|500px|frameless]]<br>


Click  [[Image:0486-23.png|50px|frameless]]to upload the program, upload successfully.


<br>[[Image:048614png.png|500px|frameless]]<br>


Upload the program successfully, the onboard LED lights on for 1s, lights off for 1s. Congratulation, you finish the first program.








== How to Add a Library? ==




What are Libraries ?<br>
Libraries are a collection of code that makes it easy for you to connect to a sensor,display, module, etc. <br>
For example, the built-in LiquidCrystal library helps talk to LCD displays. There are hundreds of additional libraries available on the Internet for download. <br>
The built-in libraries and some of these additional libraries are listed in the reference. <br>


Here we will introduce the most simple way for you to add libraries .<br>
Step 1:After downloading well the Arduino IDE, you can right-click the icon of Arduino IDE.<br>
Find the option "Open file location" shown as below:<br>


<br>[[File:0085--200.png|500px|frameless|thumb]]<br>


Step 2: Enter it to find out libraries folder which is the library file of Arduino.<br>


<br>[[File:0428---81.png|800px|frameless|thumb]]<br>




Step 3:Next to find out the“libraries”of tank robot(seen in the link: https://fs.keyestudio.com/KS0428), you just need to replicate and paste into the libraries folder of Arduino IDE.


<br>[[File:图片1042801.png|800px|frameless|thumb]]<br>
<br>[[File:图片1042802.png|800px|frameless|thumb]]<br>


Then the libraries of tank robot are installed successfully, as shown below:
<br>[[File:图片1042803.png|800px|frameless|thumb]]<br>


== Projects ==


=== Project 1: LED Blink === 


'''(1)Description'''
<br>[[File:0428-46.png|300px|frameless|thumb]]<br>


For the starter and enthusiast, this is a fundamental program---LED Blink.<br>
LED, the abbreviation of light emitting diodes, consist of Ga, As, P, N chemical compound and so on. The LED can flash diverse color by altering the delay time in the test code. When in control, power on GND and VCC, the LED will be on if S end is high level; nevertheless, it will go off.


'''(2)Specification'''


<br>[[File:0428-47.png|500px|frameless|thumb]]<br>


* Control interface: digital port
* Working voltage: DC 3.3-5V
* Pin spacing: 2.54mm
* LED display color: red


'''(3)Equipment'''


<br>[[File:0428-48.png|700px|frameless|thumb]]<br>




'''(4) V5 Sensor Shield''' <br>             
There will be troublesome when we combine Arduino development boards with numerous sensors. However, the V5 sensor shield, compatible with Arduino development board, address this problem perfectly. Just stack V5 board on it.
This sensor shield can be inserted into 3pin sensor modules and breaks out some some communication pins, like serial, IIC, and SPI communication as well.


'''Pins Description'''
<br>[[File:0428-49.png|700px|frameless|thumb]]<br>




Connection Diagram:


<br>[[File:0428---1.png|700px|frameless|thumb]]<br>


Seen from the above diagram, LED is linked with D2


(5) Test Code


<pre>
/*
keyestudio Mini Tank Robot V2
lesson 1.1
Blink
http://www.keyestudio.com
*/
void setup()
{
    pinMode(2, OUTPUT);// initialize digital pin 2 as an output.
}
void loop() // the loop function runs over and over again forever


{
  digitalWrite(2, HIGH); // turn the LED on (HIGH is the voltage level)
  delay(1000); // wait for a second
  digitalWrite(2, LOW); // turn the LED off by making the voltage LOW
  delay(1000); // wait for a second
}
//****************************************************************


</pre>


'''(6) Test Result'''


(There will be contradict about serial communication between code and  Bluetooth when uploading code, therefore, don’t link with Bluetooth module before uploading code.)
Upload the program on the development board, LED flicker with the interval of 1s.


<br>[[File:0428-50.png|500px|frameless|thumb]]<br>


'''(7)Code Explanation'''


pinMode(2,OUTPUT) - Set pin2 to OUTPUT


digitalWrite(2,HIGH) - When set pin2 to HIGH level(output 5V) or to LOW level(output 0V)


(8)Extension Practice
We succeed to blink LED. Next, let’s observe what LED will change if we modify pins and delay time.




'''Connection Diagram'''


<br>[[File:0428-51.png|500px|frameless|thumb]]<br>


We’ve altered pins and connected LED to D10.


Test Code:


<pre>


/*
keyestudio Mini Tank Robot V2
lesson 1.2
delay
http://www.keyestudio.com
*/
void setup() {  // initialize digital pin 10 as an output.
  pinMode(10, OUTPUT);
}
// the loop function runs over and over again forever
void loop() {
  digitalWrite(10, HIGH); // turn the LED on (HIGH is the voltage level)
  delay(100); // wait for 0.1 second
  digitalWrite(10, LOW); // turn the LED off by making the voltage LOW
  delay(100); // wait for 0.1 second
}
//****************************************************************


</pre>


The LED flickers faster than before through the test result, therefore, pins and delay time affect flash frequency.


=== Project 2: Adjust LED Brightness ===


(1)Description
In previous lesson, we control LED on and off and make it blink.
In this project, we will control LED brightness through PWM to simulate breathing effect. Similarly, you can change the step length and delay time in the code so as to demonstrate different breathing effect.
PWM is a means of controlling the analog output via digital means. Digital control is used to generate square waves with different duty cycles (a signal that constantly switches between high and low levels) to control the analog output.In general, the input voltage of port are 0V and 5V. What if the 3V is required? Or what if switch among 1V, 3V and 3.5V? We can’t change resistor constantly. For this situation, we need to control by PWM.


<br>[[File:0085=33.png|500px|frameless|thumb]]<br>


For the Arduino digital port voltage output, there are only LOW and HIGH, which correspond to the voltage output of 0V and 5V. You can define LOW as 0 and HIGH as 1, and let the Arduino output five hundred 0 or 1 signals within 1 second.
If output five hundred 1, that is 5V; if all of which is 1, that is 0V. If output 010101010101 in this way then the output port is 2.5V, which is like showing movie. The movie we watch are not completely continuous. It actually outputs 25 pictures per second. In this case, the human can’t tell it, neither does PWM. If want different voltage, need to control the ratio of 0 and 1. The more 0,1 signals output per unit time, the more accurately control.
 


(2) Specification
* Control interface: digital port
* Working voltage: DC 3.3-5V
* Pin spacing: 2.54mm
* Display color: red




(3) Equipment
<br>[[File:0428-53.png|700px|frameless|thumb]]<br>


(4) Connection Diagram
<br>[[File:0428-51.png|500px|frameless|thumb]]<br>


(5) Test Code


<pre>
/*
keyestudio Mini Tank Robot V2
lesson 2.1
pwm
http://www.keyestudio.com
*/
int ledPin = 10; // Define the LED pin at D10
int value;
void setup ()
{
pinMode (ledPin, OUTPUT); // initialize ledpin as an output.
}
void loop ()
{
for (value = 0; value <255; value = value + 1)
{
analogWrite (ledPin, value); // LED lights gradually light up
delay (5); // delay 5MS
}
for (value = 255; value> 0; value = value-1)
{
analogWrite (ledPin, value); // LED gradually goes out
delay (5); // delay 5MS
}}//**********************************************************


</pre>


=== '''Arduino IDE Setting''' ===
(6)Test Result<br>  
 
Click[[Image:0486-12.png|200px|frameless]] icon,open Arduino IDE.
<br>[[Image:0085=14.png|400px|frameless]]<br>
 
To avoid the errors when uploading the program to the board, you need to select the correct Arduino board that matches the board connected to your computer.
Then come back to the Arduino software, you should click Tools→Board, select the board. (as shown below)
<br>[[Image:0085=15.png|500px|frameless]]<br>


Upload test code successfully, LED gradually becomes brighter then darker, like human breath, rather than light on and off immediately.


Then select the correct COM port (you can see the corresponding COM port after the driver is successfully installed)
(7)Code Explanation


<br>[[Image:0085=16.png|500px|frameless]]<br>
When we need to repeat some statements, we could use FOR statement.<br>  
<br>[[Image:0085=17.png|500px|frameless]]<br>
FOR statement format is shown below:


Before uploading the program to the board, let’s demonstrate the function of each symbol in the Arduino IDE toolbar.<br>
<br>[[File:0085=36.png|500px|frameless|thumb]]<br>  


A- Used to verify whether there is any compiling mistakes or not.<br>
B- Used to upload the sketch to your Arduino board.<br>
C- Used to create shortcut window of a new sketch.<br>
D- Used to directly open an example sketch.<br>
E- Used to save the sketch.<br>
F- Used to send the serial data received from board to the serial monitor.<br>


=== Start your first program ===


Open the file to select Example, choose BLINK from BASIC, as shown below:
FOR cyclic sequence:
Round 1:1 → 2 → 3 → 4
Round 2:2 → 3 → 4
Until number 2 is not established, “for”loop is over,
After knowing this order, go back to code:
for (int value = 0; value < 255; value=value+1){
        ...
}
for (int value = 255; value >0; value=value-1){
      ...
}


The two“for”statements make value increase from 0 to 255, then reduce from 255 to 0, then increase to 255,....infinitely loop
There is a new function in the following ----- analogWrite()
We know that digital port only has two state of 0 and 1. So how to send an analog value to a digital value? Here,this function is needed. Let’s observe the Arduino board and find 6 pins marked“~”which can output PWM signals.<br>


<br>[[Image:048610png.png|500px|frameless]]<br>
Function format as follows:
analogWrite(pin,value)
analogWrite() is used to write an analog value from 0~255 for PWM port, so the value is in the range of 0~255. Attention that you only write the digital pins with PWM function, such as pin 3, 5, 6, 9, 10, 11.<br>  
PWM is a technology to obtain analog quantity through digital method. Digital control forms a square wave, and the square wave signal only has two states of turning on and off (that is, high or low levels). By controlling the ratio of the duration of turning on and off, a voltage varying from 0 to 5V can be simulated. The time turning on(academically referred to as high level) is called pulse width, so PWM is also called pulse width modulation.<br>
Through the following five square waves, let’s acknowledge more about PWM. <br>  


<br>[[Image:048611png.png|500px|frameless]]<br>
<br>[[File:0085=37.png|500px|frameless|thumb]]<br>  


Set board and COM port, the corresponding board and COM port are shown on the lower right of IDE.
In the above figure, the green line represents a period, and value of analogWrite() corresponds to a percentage which is called Duty Cycle as well. Duty cycle implies that high-level duration is divided by low-level duration in a cycle. From top to bottom, the duty cycle of first square wave is 0% and its corresponding value is 0. The LED brightness is lowest, that is, turn off. The more time high level lasts, the brighter the LED. <br> Therefore, the last duty cycle is 100%, which correspond to 255, LED is brightest. 25% means darker.<br>
PWM mostly is used for adjusting the LED brightness or rotation speed of motor.<br>
It plays vital role in controlling smart robot car. I believe that you can’t wait to enter next project.<br>


<br>[[Image:048612png.png|500px|frameless]]<br>       


Click [[Image:0486-20.png|50px|frameless]] to start compiling the program, check errors.
(8) Extension Practice:


<br>[[Image:048613png.png|500px|frameless]]<br>
Let’s modify the value of delay and remain the pin unchanged, then observe how LED changes.


Click [[Image:0486-23.png|50px|frameless]]to upload the program, upload successfully.
<pre>
/*
  keyestudio Mini Tank Robot V2
lesson 2.2
pwm-slow
http://www.keyestudio.com
*/
int ledPin = 10; // Define the LED pin at D10
int value;
void setup ()
{
pinMode (ledPin, OUTPUT); // initialize ledpin as an output.
}
void loop ()
{
for (value = 0; value <255; value = value + 1)
{
analogWrite (ledPin, value); // LED lights gradually light up
delay (30); // delay 30MS
}
for (value = 255; value> 0; value = value-1)
{
analogWrite (ledPin, value); // LED gradually goes out
delay (30); // delay 30MS
}}//**********************************************************


<br>[[Image:048614png.png|500px|frameless]]<br>
</pre>


Upload the program successfully, the onboard LED lights on for 1s, lights off for 1s. Congratulation, you finish the first program.
Upload code on the development board and LED gradually get brighter then darker.


=== Project 3: Photoresistor Sensor ===


<br>[[File:0428-56.png|200px|frameless|thumb]]<br>
(1)Description<br>


The photoresistor is a special resistor made of semiconductor materials such as CdS or Selenide septum. The surface is also coated with moisture-proof resin, which has a photoconductive effect. It is sensitive to ambient light. Its resistance varies from different light intensities.<br>


== How to Add a Library? ==
We use the characteristics of the photo-resistor to design the circuit and generate the photo-resistor module.<br>
Connecting the signal pin of photocell module to Analog port, when the stronger the light intensity, the greater the voltage of analog port, the greater the analog value is. <br>
On the contrary, the weaker the light intensity, the smaller the voltage of analog port, the smaller the analog value is.
Based on that, we can use the photocell module to read the analog value, so get the ambient light intensity.


(2)Specification


What are Libraries ?<br>
<br>[[File:0428-57.png|300px|frameless|thumb]]<br>  
Libraries are a collection of code that makes it easy for you to connect to a sensor,display, module, etc. <br>
For example, the built-in LiquidCrystal library helps talk to LCD displays. There are hundreds of additional libraries available on the Internet for download. <br>
The built-in libraries and some of these additional libraries are listed in the reference. <br>


Here we will introduce the most simple way for you to add libraries .<br>
* Resistance:5K ohm-0.5Mohm
Step 1:After downloading well the Arduino IDE, you can right-click the icon of Arduino IDE.<br>
* Interface Type: analog
Find the option "Open file location" shown as below:<br>
* Working Voltage: 3.3V-5V
* Easy installation: with screw fixing holes
* Pin spacing: 2.54mm


<br>[[File:0085--200.png|500px|frameless|thumb]]<br>
(3)Equipment


Step 2: Enter it to find out libraries folder which is the library file of Arduino.<br>
<br>[[File:0428-58.png|700px|frameless|thumb]]<br>  


<br>[[File:0428---81.png|800px|frameless|thumb]]<br>
'''Connection Diagram:'''


<br>[[File:0428-59.png|500px|frameless|thumb]]<br>
The two photoresistor sensors are linked with A1 and A2, then finish the experiment via photoresistor connected to A1. Then finish the following experiment via photoresistor connected A1. Let’s read its analog value.


Step 3:Next to find out the“libraries”of tank robot(seen in the link: https://fs.keyestudio.com/KS0428), you just need to replicate and paste into the libraries folder of Arduino IDE.


<br>[[File:0428---82.png|800px|frameless|thumb]]<br>
(4)Test Code
<br>[[File:0428---83.png|800px|frameless|thumb]]<br>


Then the libraries of tank robot are installed successfully, as shown below:
<pre>
<br>[[File:0428---84.png|800px|frameless|thumb]]<br>
 
/*
keyestudio Mini Tank Robot V2
lesson 3.1
photocell
http://www.keyestudio.com
*/
int sensorPin = A1;    // select the input pin for the photocell
int sensorValue = 0;  // variable to store the value coming from the sensor
void setup() {
Serial.begin(9600);
}
void loop() {
sensorValue = analogRead(sensorPin);  // read the value from the sensor:
Serial.println(sensorValue);  //Serial port prints the resistance value
delay(500);
}
//******************************************************
</pre>


== Projects ==
(5)Test Result


=== Project 1: LED Blink === 
<br>[[File:0428-60.png|500px|frameless|thumb]]<br>


'''(1)Description'''
<br>[[File:0428-46.png|300px|frameless|thumb]]<br>


For the starter and enthusiast, this is a fundamental program---LED Blink.<br>
Upload code on development board, open serial monitor, check if its value diminishes when covering photoresistor. However, the value increases when uncovered.
LED, the abbreviation of light emitting diodes, consist of Ga, As, P, N chemical compound and so on. The LED can flash diverse color by altering the delay time in the test code. When in control, power on GND and VCC, the LED will be on if S end is high level; nevertheless, it will go off.


'''(2)Specification'''
(6)Code Explanation
analogRead(sensorPin):read the analog value of photoresistor via analog ports.
Serial.begin(9600): Initialize the serial port, baud rate of serial communication is 9600
Serial.println : Serial port prints and word wrap.


<br>[[File:0428-47.png|500px|frameless|thumb]]<br>


* Control interface: digital port
(7)Extension Practice
* Working voltage: DC 3.3-5V
We’ve known how to read the value of photoresistor. Let’s combine photoresistor with LED and view the status of LED.
* Pin spacing: 2.54mm
* LED display color: red


'''(3)Equipment'''
<br>[[File:0428-61.png|500px|frameless|thumb]]<br>
PWM restrains the brightness, so LED is linked with PWM pins, connect LED to pin 10, keep pin of photoresistor unchanged, then design the code:


<br>[[File:0428-48.png|700px|frameless|thumb]]<br>
<pre>
/*keyestudio Mini Tank Robot V2
lesson 3.2
photocell-analog output
http://www.keyestudio.com
*/
int analogInPin = A1;  // Analog input pin that the photocell is attached to
int analogOutPin = 10; // Analog output pin that the LED is attached to
int sensorValue = 0;        // value read from the pot
int outputValue = 0;        // value output to the PWM (analog out)
void setup() {
Serial.begin(9600);
}
void loop() {
  // read the analog in value:
  sensorValue = analogRead(analogInPin);
  // map it to the range of the analog out:
  outputValue = map(sensorValue, 0, 1023, 0, 255);
  // change the analog out value:
  analogWrite(analogOutPin, outputValue);
  // wait 2 milliseconds before the next loop for the analog-to-digital
  // converter to settle after the last reading:
Serial.println(sensorValue);  //serial port prints the value of photoresistor
delay(2);
}
//***************************************************************


</pre>


'''(4) V5 Sensor Shield''' <br>             
Upload code, press it by hand and see the the LED brightness.
There will be troublesome when we combine Arduino development boards with numerous sensors. However, the V5 sensor shield, compatible with Arduino development board, address this problem perfectly. Just stack V5 board on it.
This sensor shield can be inserted into 3pin sensor modules and breaks out some some communication pins, like serial, IIC, and SPI communication as well.


'''Pins Description'''
<br>[[File:0428-49.png|700px|frameless|thumb]]<br>


=== Project 4: Servo Control ===


Connection Diagram:
'''(1)Description'''


<br>[[File:0428---1.png|700px|frameless|thumb]]<br>  
<br>[[File:Ks0194- servo.png|300px|frameless|thumb]]<br>  


Seen from the above diagram, LED is linked with D2
Servo motor is a position control rotary actuator. It mainly consists of housing, circuit board, core-less motor, gear and position sensor. Its working principle is that the servo receives the signal sent by MCU or receiver and produces a reference signal with a period of 20ms and width of 1.5ms, then compares the acquired DC bias voltage to the voltage of the potentiometer and obtain the voltage difference output.<br>


(5) Test Code
When the motor speed is constant, the potentiometer is driven to rotate through the cascade reduction gear, which leads that the voltage difference is 0, and the motor stops rotating. Generally, the angle range of servo rotation is 0° --180 °


<pre>
The rotation angle of servo motor is controlled by regulating the duty cycle of PWM (Pulse-Width Modulation) signal. The standard cycle of PWM signal is 20ms (50Hz). Theoretically, the width is distributed between 1ms-2ms, but in fact, it's between 0.5ms-2.5ms. The width corresponds the rotation angle from 0° to 180°. But note that for different brand motor, the same signal may have different rotation angle.  
/*
keyestudio Mini Tank Robot V2
lesson 1.1
Blink
http://www.keyestudio.com
*/
void setup()
{
    pinMode(2, OUTPUT);// initialize digital pin 2 as an output.
}
void loop() // the loop function runs over and over again forever


{
<br>[[File:0428-69.png|500px|frameless|thumb]]<br>
  digitalWrite(2, HIGH); // turn the LED on (HIGH is the voltage level)
  delay(1000); // wait for a second
  digitalWrite(2, LOW); // turn the LED off by making the voltage LOW
  delay(1000); // wait for a second
}
//****************************************************************


</pre>
The corresponding servo angles are shown below:
<br>[[File:0428-70.png|500px|frameless|thumb]]<br>  


'''(6) Test Result'''


(There will be contradict about serial communication between code and  Bluetooth when uploading code, therefore, don’t link with Bluetooth module before uploading code.)
'''(2)Specification''' <br>
Upload the program on the development board, LED flicker with the interval of 1s.


<br>[[File:0428-50.png|500px|frameless|thumb]]<br>
* Working voltage: DC 4.8V ~ 6V
* Operating angle range: about 180 ° (at 500 → 2500 μsec)
* Pulse width range: 500 → 2500 μsec
* No-load speed: 0.12 ± 0.01 sec / 60 (DC 4.8V) 0.1 ± 0.01 sec / 60 (DC 6V)
* No-load current: 200 ± 20mA (DC 4.8V) 220 ± 20mA (DC 6V)
* Stopping torque: 1.3 ± 0.01kg · cm (DC 4.8V) 1.5 ± 0.1kg · cm (DC 6V)
* Stop current: ≦ 850mA (DC 4.8V) ≦ 1000mA (DC 6V)
* Standby current: 3 ± 1mA (DC 4.8V) 4 ± 1mA (DC 6V)


'''(7)Code Explanation'''


pinMode(2,OUTPUT) - Set pin2 to OUTPUT
'''(3)Equipment'''


digitalWrite(2,HIGH) - When set pin2 to HIGH level(output 5V) or to LOW level(output 0V)
<br>[[File:0428-71.png|500px|frameless|thumb]]<br>


(8)Extension Practice
'''(4)Connection Diagram:'''
We succeed to blink LED. Next, let’s observe what LED will change if we modify pins and delay time.


<br>[[File:0428-72.png|500px|frameless|thumb]]<br>


'''Connection Diagram'''
Wiring note: the brown line of servo is linked with Gnd(G), the red line is connected to 5v(V) and orange line is attached to digital 9.


<br>[[File:0428-51.png|500px|frameless|thumb]]<br>
The servo have to be connected to external power, due to its high demand for driving servo current. Generally, the current of development board is not enough. If without connected power, the development board could be burnt.


We’ve altered pins and connected LED to D10.


Test Code:
'''(5)Test Code1'''


<pre>
<pre>
/*
/*
keyestudio Mini Tank Robot V2
keyestudio Mini Tank Robot V2
lesson 1.2
lesson 4.1
delay
Servo
http://www.keyestudio.com
http://www.keyestudio.com
*/
*/
void setup() {  // initialize digital pin 10 as an output.
#define servoPin 9  //servo Pin
  pinMode(10, OUTPUT);
int pos; //angle variable of servo
int pulsewidth; // pulse width variable of servo
void setup() {
  pinMode(servoPin, OUTPUT); //set servo pin to OUTPUT
  procedure(0); //set the angle of servo to 0°
}
}
// the loop function runs over and over again forever
void loop() {
void loop() {
  digitalWrite(10, HIGH); // turn the LED on (HIGH is the voltage level)
  for (pos = 0; pos <= 180; pos += 1) { // goes from 0 degrees to 180 degrees
  delay(100); // wait for 0.1 second
    // in steps of 1 degree
  digitalWrite(10, LOW); // turn the LED off by making the voltage LOW
    procedure(pos);              // tell servo to go to position in variable 'pos'
  delay(100); // wait for 0.1 second
    delay(15);                   //control the rotation speed of servo
  }
  for (pos = 180; pos >= 0; pos -= 1) { // goes from 180 degrees to 0 degrees
    procedure(pos);              // tell servo to go to position in variable 'pos'
    delay(15);                   
  }
}
// function to control servo
void procedure(int myangle) {
  pulsewidth = myangle * 11 + 500;  //calculate the value of pulse width
  digitalWrite(servoPin,HIGH);
  delayMicroseconds(pulsewidth);   //The duration of high level is pulse width
  digitalWrite(servoPin,LOW);
  delay((20 - pulsewidth / 1000)); // the cycle is 20ms, the low level last for the rest of time
}
}
//****************************************************************
//********************************************************************
 
</pre>
</pre>


The LED flickers faster than before through the test result, therefore, pins and delay time affect flash frequency.
Upload code successfully, servo swings back in the range of 0° to 180°


=== Project 2: Adjust LED Brightness ===
There is another guide for restraining servo---- servo library file, the following link of official website is for your reference.
https://www.arduino.cc/en/Reference/Servo


(1)Description
'''<big>Servo library file</big>'''
In previous lesson, we control LED on and off and make it blink.
In this project, we will control LED brightness through PWM to simulate breathing effect. Similarly, you can change the step length and delay time in the code so as to demonstrate different breathing effect.
PWM is a means of controlling the analog output via digital means. Digital control is used to generate square waves with different duty cycles (a signal that constantly switches between high and low levels) to control the analog output.In general, the input voltage of port are 0V and 5V. What if the 3V is required? Or what if switch among 1V, 3V and 3.5V? We can’t change resistor constantly. For this situation, we need to control by PWM.


<br>[[File:0085=33.png|500px|frameless|thumb]]<br>
'''(6)Test Code2'''
 
For the Arduino digital port voltage output, there are only LOW and HIGH, which correspond to the voltage output of 0V and 5V. You can define LOW as 0 and HIGH as 1, and let the Arduino output five hundred 0 or 1 signals within 1 second.
If output five hundred 1, that is 5V; if all of which is 1, that is 0V. If output 010101010101 in this way then the output port is 2.5V, which is like showing movie. The movie we watch are not completely continuous. It actually outputs 25 pictures per second. In this case, the human can’t tell it, neither does PWM. If want different voltage, need to control the ratio of 0 and 1. The more 0,1 signals output per unit time, the more accurately control.
 
 
(2) Specification
* Control interface: digital port
* Working voltage: DC 3.3-5V
* Pin spacing: 2.54mm
* Display color: red
 
 
(3) Equipment
<br>[[File:0428-53.png|700px|frameless|thumb]]<br>
 
(4) Connection Diagram
<br>[[File:0428-51.png|500px|frameless|thumb]]<br>
 
(5) Test Code


<pre>
<pre>
/*
/*
  keyestudio Mini Tank Robot V2
  keyestudio Mini Tank Robot V2
  lesson 2.1
  lesson 4.2
  pwm
  servo
  http://www.keyestudio.com
  http://www.keyestudio.com
*/
*/
int ledPin = 10; // Define the LED pin at D10
#include <Servo.h>
int value;
Servo myservo;  // create servo object to control a servo
void setup ()  
// twelve servo objects can be created on most boards
{
int pos = 0;   // variable to store the servo position
pinMode (ledPin, OUTPUT); // initialize ledpin as an output.
void setup() {
  myservo.attach(9); // attaches the servo on pin 9 to the servo object
}
}
void loop ()  
void loop() {
{
  for (pos = 0; pos <= 180; pos += 1) { // goes from 0 degrees to 180 degrees
for (value = 0; value <255; value = value + 1)
    // in steps of 1 degree
{
    myservo.write(pos);              // tell servo to go to position in variable 'pos'
analogWrite (ledPin, value); // LED lights gradually light up
    delay(15);                      // waits 15ms for the servo to reach the position
delay (5); // delay 5MS
  }
  for (pos = 180; pos >= 0; pos -= 1) { // goes from 180 degrees to 0 degrees
    myservo.write(pos);             // tell servo to go to position in variable 'pos'
    delay(15);                       // waits 15ms for the servo to reach the position
  }
}
}
for (value = 255; value> 0; value = value-1)
//****************************************************************
{
analogWrite (ledPin, value); // LED gradually goes out
delay (5); // delay 5MS
}}//**********************************************************
 
</pre>
</pre>


(6)Test Result<br>
'''(7)Test Result'''


Upload test code successfully, LED gradually becomes brighter then darker, like human breath, rather than light on and off immediately.
Upload code successfully and power on, servo rotates in the range of 0° to 180°. The result is same. We usually control it by library file.


(7)Code Explanation
'''
(8)Code Explanation'''


When we need to repeat some statements, we could use FOR statement.<br>  
Arduino comes with #include <Servo.h> (servo function and statement)
FOR statement format is shown below:
The following are some common statements of the servo function:
1. attach(interface)——Set servo interface, port 9 and 10 are available


<br>[[File:0085=36.png|500px|frameless|thumb]]<br>
3.write(angle)——The statement to set rotation angle of servo, the angle range is from 0° to 180°
3. read()——The statement to read angle of servo, read the command value of “write()”
4. Note: The above written format is “servo variable name, specific statement()”, for instance: myservo.attach(9)


=== Project 5: Ultrasonic Sensor ===


'''(1)Description'''


FOR cyclic sequence:
<br>[[File:0428-73.png|300px|frameless|thumb]]<br>
Round 1:1 → 2 → 3 → 4
Round 2:2 → 3 → 4
Until number 2 is not established, “for”loop is over,
After knowing this order, go back to code:
for (int value = 0; value < 255; value=value+1){
        ...
}
for (int value = 255; value >0; value=value-1){
      ...
}


The two“for”statements make value increase from 0 to 255, then reduce from 255 to 0, then increase to 255,....infinitely loop
The HC-SR04 ultrasonic sensor uses sonar to determine distance to an object like bats do. It offers excellent non-contact range detection with high accuracy and stable readings in an easy-to-use package. It comes complete with ultrasonic transmitter and receiver modules.<br>
There is a new function in the following ----- analogWrite()
The HC-SR04 or the ultrasonic sensor is being used in a wide range of electronics projects for creating obstacle detection and distance measuring application as well as various other applications. Here we have brought the simple method to measure the distance with arduino and ultrasonic sensor and how to use ultrasonic sensor with arduino.<br>  
We know that digital port only has two state of 0 and 1. So how to send an analog value to a digital value? Here,this function is needed. Let’s observe the Arduino board and find 6 pins marked“~”which can output PWM signals.<br>  


Function format as follows:
'''(2)Specification'''
analogWrite(pin,value)
analogWrite() is used to write an analog value from 0~255 for PWM port, so the value is in the range of 0~255. Attention that you only write the digital pins with PWM function, such as pin 3, 5, 6, 9, 10, 11.<br>
PWM is a technology to obtain analog quantity through digital method. Digital control forms a square wave, and the square wave signal only has two states of turning on and off (that is, high or low levels). By controlling the ratio of the duration of turning on and off, a voltage varying from 0 to 5V can be simulated. The time turning on(academically referred to as high level) is called pulse width, so PWM is also called pulse width modulation.<br>
Through the following five square waves, let’s acknowledge more about PWM. <br>


<br>[[File:0085=37.png|500px|frameless|thumb]]<br>  
<br>[[File:0428-74.png|500px|right|frameless|thumb]]<br>  


In the above figure, the green line represents a period, and value of analogWrite() corresponds to a percentage which is called Duty Cycle as well. Duty cycle implies that high-level duration is divided by low-level duration in a cycle. From top to bottom, the duty cycle of first square wave is 0% and its corresponding value is 0. The LED brightness is lowest, that is, turn off. The more time high level lasts, the brighter the LED. <br> Therefore, the last duty cycle is 100%, which correspond to 255, LED is brightest. 25% means darker.<br>
* Power Supply :+5V DC
PWM mostly is used for adjusting the LED brightness or rotation speed of motor.<br>  
* Quiescent Current : <2mA
It plays vital role in controlling smart robot car. I believe that you can’t wait to enter next project.<br>  
* Working Current: 15mA
* Effectual Angle: <15°
* Ranging Distance : 2cm – 400 cm
* Resolution : 0.3 cm
* Measuring Angle: 30 degree
* Trigger Input Pulse width: 10uS
 
 
'''(3)Equipment'''
 
<br>[[File:0428-75.png|600px|frameless|thumb]]<br>  


'''(4)The principle of ultrasonic sensor'''


(8) Extension Practice:
As the above picture shown, it is like two eyes. One is transmitting end, the other is receiving end.


Let’s modify the value of delay and remain the pin unchanged, then observe how LED changes.
The ultrasonic module will emit the ultrasonic waves after trigger signal. When the ultrasonic waves encounter the object and are reflected back, the module outputs an echo signal, so it can determine the distance of object from the time difference between trigger signal and echo signal.
The t is the time that emitting signal meets obstacle and returns.
and the propagation speed of sound in the air is about 343m/s, therefore,  distance = speed * time, because the ultrasonic wave emits and comes back, which is 2 times of distance, so it needs to be divided by 2, the distance measured by ultrasonic wave = (speed * time)/2
 
1.Use method and timing chart of ultrasonic module:
Setting the delay time of Trig pin of SR04 to 10μs at least, which can trigger it to detect distance.
2. After triggering, the module will automatically send eight 40KHz ultrasonic pulses and detect whether there is a signal return. This step will be completed automatically by the module.
3. If the signal returns, the Echo pin will output a high level, and the duration of the high level is the time from the transmission of the ultrasonic wave to the return.


<pre>
/*
keyestudio Mini Tank Robot V2
lesson 2.2
pwm-slow
http://www.keyestudio.com
*/
int ledPin = 10; // Define the LED pin at D10
int value;
void setup ()
{
pinMode (ledPin, OUTPUT); // initialize ledpin as an output.
}
void loop ()
{
for (value = 0; value <255; value = value + 1)
{
analogWrite (ledPin, value); // LED lights gradually light up
delay (30); // delay 30MS
}
for (value = 255; value> 0; value = value-1)
{
analogWrite (ledPin, value); // LED gradually goes out
delay (30); // delay 30MS
}}//**********************************************************


</pre>
<br>[[File:0428-84.png|500px|frameless|thumb]]<br>  


Upload code on the development board and LED gradually get brighter then darker.
Circuit diagram of ultrasonic sensor:


=== Project 3: Photoresistor Sensor ===
<br>[[File:0428---106.png|500px|frameless|thumb]]<br>  
   


<br>[[File:0428-56.png|200px|frameless|thumb]]<br>
(1)Description<br>


The photoresistor is a special resistor made of semiconductor materials such as CdS or Selenide septum. The surface is also coated with moisture-proof resin, which has a photoconductive effect. It is sensitive to ambient light. Its resistance varies from different light intensities.<br>
'''(5)Connection Diagram'''


We use the characteristics of the photo-resistor to design the circuit and generate the photo-resistor module.<br>  
<br>[[File:0428-83.png|500px|frameless|thumb]]<br>  
Connecting the signal pin of photocell module to Analog port, when the stronger the light intensity, the greater the voltage of analog port, the greater the analog value is. <br>  
On the contrary, the weaker the light intensity, the smaller the voltage of analog port, the smaller the analog value is.
Based on that, we can use the photocell module to read the analog value, so get the ambient light intensity.


(2)Specification
<br>[[File:0428-85.png|500px|frameless|thumb]]<br>


<br>[[File:0428-57.png|300px|frameless|thumb]]<br>


* Resistance:5K ohm-0.5Mohm
'''(6)Test Code'''
* Interface Type: analog
* Working Voltage: 3.3V-5V
* Easy installation: with screw fixing holes
* Pin spacing: 2.54mm
 
(3)Equipment
 
<br>[[File:0428-58.png|700px|frameless|thumb]]<br>
 
'''Connection Diagram:'''
 
<br>[[File:0428-59.png|500px|frameless|thumb]]<br>
The two photoresistor sensors are linked with A1 and A2, then finish the experiment via photoresistor connected to A1. Then finish the following experiment via photoresistor connected A1. Let’s read its analog value.
 
 
(4)Test Code


<pre>
<pre>
/*
/*
  keyestudio Mini Tank Robot V2
  keyestudio Mini Tank Robot V2
  lesson 3.1
  lesson 5
  photocell
  Ultrasonic sensor
  http://www.keyestudio.com
  http://www.keyestudio.com
*/
*/  
int sensorPin = A1;    // select the input pin for the photocell
int trigPin = 5;    // Trigger
int sensorValue = 0; // variable to store the value coming from the sensor
int echoPin = 4;   // Echo
long duration, cm, inches;
void setup() {
void setup() {
Serial.begin(9600);
  //Serial Port begin
  Serial.begin (9600);
  //Define inputs and outputs
  pinMode(trigPin, OUTPUT);
  pinMode(echoPin, INPUT);
}
}
void loop() {
void loop() {
sensorValue = analogRead(sensorPin); // read the value from the sensor:
  // The sensor is triggered by a HIGH pulse of 10 or more microseconds.
Serial.println(sensorValue); //Serial port prints the resistance value
  // Give a short LOW pulse beforehand to ensure a clean HIGH pulse:
delay(500);
  digitalWrite(trigPin, LOW);
  delayMicroseconds(2);
  digitalWrite(trigPin, HIGH);
  delayMicroseconds(10);
  digitalWrite(trigPin, LOW);
  // Read the signal from the sensor: a HIGH pulse whose
  // duration is the time (in microseconds) from the sending
  // of the ping to the reception of its echo off of an object.
  duration = pulseIn(echoPin, HIGH);
  // Convert the time into a distance
  cm = (duration/2) / 29.1;    // Divide by 29.1 or multiply by 0.0343
  inches = (duration/2) / 74;   // Divide by 74 or multiply by 0.0135
  Serial.print(inches);
  Serial.print("in, ");
  Serial.print(cm);
  Serial.print("cm");
  Serial.println();
  delay(250);
}
}
//******************************************************
//****************************************************************
</pre>
</pre>


(5)Test Result
(7)Test Result
Upload test code on the development board, open serial monitor and set baud rate to 9600. The detected distance will be displayed, unit is cm and inch. Hinder the ultrasonic sensor by hand, the displayed distance value is smaller.


<br>[[File:0428-60.png|500px|frameless|thumb]]<br>


<br>[[File:0428-86.png|500px|frameless|thumb]]<br>


Upload code on development board, open serial monitor, check if its value diminishes when covering photoresistor. However, the value increases when uncovered.


(6)Code Explanation
(8)Code Explanation
analogRead(sensorPin):read the analog value of photoresistor via analog ports.
int trigPin = 5; this pin is defined pin to transmit ultrasonic waves, generally output.
Serial.begin(9600): Initialize the serial port, baud rate of serial communication is 9600
int echoPin = 4; this is defined as the pin of reception, generally input
Serial.println : Serial port prints and word wrap.
cm = (duration/2) / 29.1;  inches = (duration/2) / 74;  by 0.0135
We can calculate the distance by using the following formula:
distance = (traveltime/2) x speed of sound
The speed of sound is: 343m/s = 0.0343 cm/uS = 1/29.1 cm/uS
Or in inches: 13503.9in/s = 0.0135in/uS = 1/74in/uS
We need to divide the traveltime by 2 because we have to take into account that the wave was sent, hit the object, and then returned back to the sensor.
(9)Extension Practice:
We have just measured the distance displayed by the ultrasonic. How about controlling the LED with the measured distance? Let's try it, connect an LED light module to the D10 pin.


 
<br>[[File:0428-87.png|500px|frameless|thumb]]<br>  
(7)Extension Practice
We’ve known how to read the value of photoresistor. Let’s combine photoresistor with LED and view the status of LED.
 
<br>[[File:0428-61.png|500px|frameless|thumb]]<br>  
PWM restrains the brightness, so LED is linked with PWM pins, connect LED to pin 10, keep pin of photoresistor unchanged, then design the code:


<pre>
<pre>
/*keyestudio Mini Tank Robot V2
/*
lesson 3.2
keyestudio Mini Tank Robot V2
photocell-analog output
lesson 5
http://www.keyestudio.com
Ultrasonic LED
*/
http://www.keyestudio.com
int analogInPin = A1; // Analog input pin that the photocell is attached to
*/  
int analogOutPin = 10; // Analog output pin that the LED is attached to
int trigPin = 5;   // Trigger
int sensorValue = 0;       // value read from the pot
int echoPin = 4;   // Echo
int outputValue = 0;        // value output to the PWM (analog out)
long duration, cm, inches;
void setup() {
void setup() {
Serial.begin(9600);
   //Serial Port begin
}
   Serial.begin (9600);
void loop() {
   //Define inputs and outputs
   // read the analog in value:
   pinMode(trigPin, OUTPUT);
   sensorValue = analogRead(analogInPin);
   pinMode(echoPin, INPUT);
   // map it to the range of the analog out:
   outputValue = map(sensorValue, 0, 1023, 0, 255);
   // change the analog out value:
  analogWrite(analogOutPin, outputValue);
  // wait 2 milliseconds before the next loop for the analog-to-digital
  // converter to settle after the last reading:
Serial.println(sensorValue);  //serial port prints the value of photoresistor
delay(2);
}
}
//***************************************************************
void loop()
 
{
</pre>
  // The sensor is triggered by a HIGH pulse of 10 or more microseconds.
 
  // Give a short LOW pulse beforehand to ensure a clean HIGH pulse:
Upload code, press it by hand and see the the LED brightness.
  digitalWrite(trigPin, LOW);
 
  delayMicroseconds(2);
 
  digitalWrite(trigPin, HIGH);
=== Project 4: Servo Control ===
  delayMicroseconds(10);
 
  digitalWrite(trigPin, LOW);
'''(1)Description'''
  // Read the signal from the sensor: a HIGH pulse whose
 
  // duration is the time (in microseconds) from the sending
<br>[[File:Ks0194- servo.png|300px|frameless|thumb]]<br>  
  // of the ping to the reception of its echo off of an object.
  duration = pulseIn(echoPin, HIGH);
  // Convert the time into a distance
  cm = (duration/2) / 29.1;    // Divide by 29.1 or multiply by 0.0343
  inches = (duration/2) / 74;  // Divide by 74 or multiply by 0.0135
  Serial.print(inches);
  Serial.print("in, ");
  Serial.print(cm);
  Serial.print("cm");
  Serial.println();
  delay(250);
if (cm>=2 && cm<=10)
digitalWrite(10, HIGH);
delay(1000);
digitalWrite(10, LOW);
delay(1000);
}
//****************************************************************
 
</pre>


Servo motor is a position control rotary actuator. It mainly consists of housing, circuit board, core-less motor, gear and position sensor. Its working principle is that the servo receives the signal sent by MCU or receiver and produces a reference signal with a period of 20ms and width of 1.5ms, then compares the acquired DC bias voltage to the voltage of the potentiometer and obtain the voltage difference output.<br>
Upload test code to development board and block ultrasonic sensor by hand, then check if LED is on


When the motor speed is constant, the potentiometer is driven to rotate through the cascade reduction gear, which leads that the voltage difference is 0, and the motor stops rotating. Generally, the angle range of servo rotation is 0° --180 °
=== Project 6: IR Reception ===


The rotation angle of servo motor is controlled by regulating the duty cycle of PWM (Pulse-Width Modulation) signal. The standard cycle of PWM signal is 20ms (50Hz). Theoretically, the width is distributed between 1ms-2ms, but in fact, it's between 0.5ms-2.5ms. The width corresponds the rotation angle from 0° to 180°. But note that for different brand motor, the same signal may have different rotation angle.  
(1)Description<br>
There is no doubt that infrared remote control is ubiquitous in daily life. It is used to control various household appliances, such as TVs, stereos, video recorders and satellite signal receivers. Infrared remote control is composed of infrared transmitting and infrared receiving systems, that is, an infrared remote control and infrared receiving module and a single-chip microcomputer capable of decoding.​    <br>
The 38K infrared carrier signal emitted by remote controller is encoded by the encoding chip in the remote controller. It is composed of a section of pilot code, user code, user inverse code, data code, and data inverse code. The time interval of the pulse is used to distinguish whether it is a 0 or 1 signal and the encoding is made up of these 0, 1 signals. <br>
The user code of the same remote control is unchanged. The data code can distinguish the key.<br>
When the remote control button is pressed, the remote control sends out an infrared carrier signal. When the IR receiver receives the signal, the program will decode the carrier signal and determines which key is pressed. The MCU decodes the received 01 signal, thereby judging what key is pressed by the remote control.<br>
Infrared receiver we use is an infrared receiver module. Mainly composed of an infrared receiver head, it is a device that integrates reception, amplification, and demodulation. Its internal IC has completed demodulation, and can achieve from infrared reception to output and be compatible with TTL signals. Additionally, it is suitable for infrared remote control and infrared data transmission. The infrared receiving module made by the receiver has only three pins, signal line, VCC and GND. It is very convenient to communicate with arduino and other microcontrollers.<br>


<br>[[File:0428-69.png|500px|frameless|thumb]]<br>  
<br>[[File:0428-88.png|300px|frameless|thumb]]<br>  


The corresponding servo angles are shown below:
<br>[[File:0428-70.png|500px|frameless|thumb]]<br>


(2)Specification


'''(2)Specification''' <br>  
<br>[[File:0428-89.png|200px|frameless|thumb]]<br>  


* Working voltage: DC 4.8V ~ 6V
* Operating Voltage: 3.3-5V(DC)
* Operating angle range: about 180 ° (at 500 → 2500 μsec)
* Interface: 3PIN
* Pulse width range: 500 → 2500 μsec
* Output Signal: Digital signal
* No-load speed: 0.12 ± 0.01 sec / 60 (DC 4.8V) 0.1 ± 0.01 sec / 60 (DC 6V)
* Receiving Angle: 90 degrees
* No-load current: 200 ± 20mA (DC 4.8V) 220 ± 20mA (DC 6V)
* Frequency: 38khz
* Stopping torque: 1.3 ± 0.01kg · cm (DC 4.8V) 1.5 ± 0.1kg · cm (DC 6V)
* Receiving Distance: 10m
* Stop current: ≦ 850mA (DC 4.8V) ≦ 1000mA (DC 6V)
* Standby current: 3 ± 1mA (DC 4.8V) 4 ± 1mA (DC 6V)




'''(3)Equipment'''


<br>[[File:0428-71.png|500px|frameless|thumb]]<br>
(3)Equipment


'''(4)Connection Diagram:'''
<br>[[File:0428-90.png|700px|frameless|thumb]]<br>


<br>[[File:0428-72.png|500px|frameless|thumb]]<br>
(4)Connection Diagram


Wiring note: the brown line of servo is linked with Gnd(G), the red line is connected to 5v(V) and orange line is attached to digital 9.
<br>[[File:0428-91.png|500px|frameless|thumb]]<br>


The servo have to be connected to external power, due to its high demand for driving servo current. Generally, the current of development board is not enough. If without connected power, the development board could be burnt.
Respectively link “-”、“+” and S of IR receiver module with G(GND), V(VCC)and A0 of keyestudio development board.<br>
Attention: On the condition that digital ports are not available, analog ports can be regarded as digital ports. A0 equals to D14, A1 is equivalent to digital 15.<br>




'''(5)Test Code1'''
(5)Test Code
 
Firstly import library file of IR receiver module(refer to how to import Arduino library file) before designing code.<br>


<pre>
<pre>
/*
/*
keyestudio Mini Tank Robot V2
keyestudio Mini Tank Robot V2
lesson 4.1
lesson 6
Servo
IRremote
http://www.keyestudio.com
http://www.keyestudio.com
*/
*/  
#define servoPin 9  //servo Pin
#include <IRremoteTank.h>    // IRremote library statement
int pos; //angle variable of servo
int RECV_PIN = A0;       //define the pins of IR receiver as A0
int pulsewidth; // pulse width variable of servo
IRrecv irrecv(RECV_PIN); 
void setup() {
decode_results results;   // decode results exist in the “result” of “decode results”
  pinMode(servoPin, OUTPUT);  //set servo pin to OUTPUT
void setup()
  procedure(0); //set the angle of servo to 0°
{
}
      Serial.begin(9600);   
void loop() {
      irrecv.enableIRIn(); //Enable receiver
  for (pos = 0; pos <= 180; pos += 1) { // goes from 0 degrees to 180 degrees
}
    // in steps of 1 degree
void loop() {
    procedure(pos);              // tell servo to go to position in variable 'pos'
  if (irrecv.decode(&results))//decode successfully, receive a set of infrared signals
    delay(15);                  //control the rotation speed of servo
  {
  }
    Serial.println(results.value, HEX);//Wrap word in 16 HEX to output and receive code
  for (pos = 180; pos >= 0; pos -= 1) { // goes from 180 degrees to 0 degrees
    irrecv.resume(); // Receive the next value
    procedure(pos);             // tell servo to go to position in variable 'pos'
  } 
    delay(15);                   
  delay(100);   
  }
}
}
//*******************************************************
// function to control servo
 
void procedure(int myangle) {
  pulsewidth = myangle * 11 + 500; //calculate the value of pulse width
  digitalWrite(servoPin,HIGH);
  delayMicroseconds(pulsewidth);  //The duration of high level is pulse width
  digitalWrite(servoPin,LOW);
  delay((20 - pulsewidth / 1000));  // the cycle is 20ms, the low level last for the rest of time
}
//********************************************************************
</pre>
</pre>


Upload code successfully, servo swings back in the range of 0° to 180°


There is another guide for restraining servo---- servo library file, the following link of official website is for your reference.
(6)Test Result
https://www.arduino.cc/en/Reference/Servo


'''<big>Servo library file</big>'''
Upload test code, open serial monitor and set baud rate to 9600, point remote control to IR receiver and the corresponding value will be shown, if pressing so long, the error codes will appear.<br>  


'''(6)Test Code2'''
<br>[[File:0428-92.png|500px|frameless|thumb]]<br>


<pre>
Below we have listed out each button value of keyestudio remote control. So you can keep it for reference. <br>  
/*
keyestudio Mini Tank Robot V2
lesson 4.2
servo
http://www.keyestudio.com
*/
#include <Servo.h>
Servo myservo;  // create servo object to control a servo
// twelve servo objects can be created on most boards
int pos = 0;    // variable to store the servo position
void setup() {
  myservo.attach(9);  // attaches the servo on pin 9 to the servo object
}
void loop() {
  for (pos = 0; pos <= 180; pos += 1) { // goes from 0 degrees to 180 degrees
    // in steps of 1 degree
    myservo.write(pos);              // tell servo to go to position in variable 'pos'
    delay(15);                      // waits 15ms for the servo to reach the position
  }
  for (pos = 180; pos >= 0; pos -= 1) { // goes from 180 degrees to 0 degrees
    myservo.write(pos);              // tell servo to go to position in variable 'pos'
    delay(15);                      // waits 15ms for the servo to reach the position
  }
}
//****************************************************************
</pre>


'''(7)Test Result'''
<br>[[File:0428-93.png|500px|frameless|thumb]]<br>


Upload code successfully and power on, servo rotates in the range of 0° to 180°. The result is same. We usually control it by library file.
(7)Code Explanation<br>
irrecv.enableIRIn(): after enabling IR decoding, the IR signals will be received, then function“decode()”will check continuously if decode successfully.<br>


'''
irrecv.decode(&results): after decoding successfully, this function will come back to “true”, and keep result in “results”. After decoding a IR signals, run the resume()function and receive the next signal
(8)Code Explanation'''
(8)Extension Practice
We decoded the key value of IR remote control. How about restrain LED by the measured value? We could operate an experiment to affirm. Attach a LED to D10. When keep the pin of IR receiver unchanged, LED will be on when pressing the key of remote control; press again, LED will be off.


Arduino comes with #include <Servo.h> (servo function and statement)
<br>[[File:0428-94.png|500px|frameless|thumb]]<br>
The following are some common statements of the servo function:
1. attach(interface)——Set servo interface, port 9 and 10 are available


3.write(angle)——The statement to set rotation angle of servo, the angle range is from 0° to 180°
3. read()——The statement to read angle of servo, read the command value of “write()”
4. Note: The above written format is “servo variable name, specific statement()”, for instance: myservo.attach(9)


=== Project 5: Ultrasonic Sensor ===
<pre>
 
/* keyestudio Mini Tank Robot V2
'''(1)Description'''
lesson 6.2
 
IRremote
<br>[[File:0428-73.png|300px|frameless|thumb]]<br>
http://www.keyestudio.com
 
*/
The HC-SR04 ultrasonic sensor uses sonar to determine distance to an object like bats do. It offers excellent non-contact range detection with high accuracy and stable readings in an easy-to-use package. It comes complete with ultrasonic transmitter and receiver modules.<br>
#include <IRremoteTank.h>
The HC-SR04 or the ultrasonic sensor is being used in a wide range of electronics projects for creating obstacle detection and distance measuring application as well as various other applications. Here we have brought the simple method to measure the distance with arduino and ultrasonic sensor and how to use ultrasonic sensor with arduino.<br>
int RECV_PIN = A0;//define the pin of IR receiver as A0
 
int LED_PIN=10;//define the pin of LED
'''(2)Specification'''
int a=0;
 
IRrecv irrecv(RECV_PIN);
<br>[[File:0428-74.png|500px|right|frameless|thumb]]<br>
decode_results results;
 
void setup()
* Power Supply :+5V DC
{
* Quiescent Current : <2mA
  Serial.begin(9600);
* Working Current: 15mA
  irrecv.enableIRIn(); // Initialize the IR receiver
* Effectual Angle: <15°
  pinMode(LED_PIN,OUTPUT);//set LED_pin to OUTPUT
* Ranging Distance : 2cm – 400 cm
}
* Resolution : 0.3 cm
void loop() {
* Measuring Angle: 30 degree
  if (irrecv.decode(&results)) {
* Trigger Input Pulse width: 10uS
if(results.value==0xFF02FD &a==0) // according to the above key value, press“OK”on remote control , LED will be controlled
{
    digitalWrite(LED_PIN,HIGH);//LED will be on
a=1;
}
else if(results.value==0xFF02FD &a==1) //press again
{
digitalWrite(LED_PIN,LOW);//LED will go off
a=0;
}
    irrecv.resume(); //receive the next value
  }
}
//*******************************************************
</pre>


Upload code to development board, press“OK”key on remote control to make LED on and off.


'''(3)Equipment'''
=== Project 7: Bluetooth Remote Control ===


<br>[[File:0428-75.png|600px|frameless|thumb]]<br>
(1)Description


'''(4)The principle of ultrasonic sensor'''
<br>[[File:0428-95.png|300px|frameless|thumb]]<br>


As the above picture shown, it is like two eyes. One is transmitting end, the other is receiving end.
Bluetooth, a simple wireless communication module most popular since the last few decades and easy to use are being used in most of the battery-powered devices.<br>
Over the years, there have been many upgrades of Bluetooth standard to keep fulfil the demand of customers and technology according to the need of time and situation.
Over the few years, there are many things changed including data transmission rate, power consumption with wearable and IoT Devices and Security System.<br>
Here we are going to learn about HM-10 BLE 4.0 with Arduino Board. The HM-10 is a readily available Bluetooth 4.0 module. This module is used for establishing wireless data communication. The module is designed by using the Texas Instruments CC2540 or CC2541 Bluetooth low energy (BLE) System on Chip (SoC). <br>


The ultrasonic module will emit the ultrasonic waves after trigger signal. When the ultrasonic waves encounter the object and are reflected back, the module outputs an echo signal, so it can determine the distance of object from the time difference between trigger signal and echo signal.
The t is the time that emitting signal meets obstacle and returns.
and the propagation speed of sound in the air is about 343m/s, therefore,  distance = speed * time, because the ultrasonic wave emits and comes back, which is 2 times of distance, so it needs to be divided by 2, the distance measured by ultrasonic wave = (speed * time)/2


1.Use method and timing chart of ultrasonic module:
(2)Specification
Setting the delay time of Trig pin of SR04 to 10μs at least, which can trigger it to detect distance.
2. After triggering, the module will automatically send eight 40KHz ultrasonic pulses and detect whether there is a signal return. This step will be completed automatically by the module.
3. If the signal returns, the Echo pin will output a high level, and the duration of the high level is the time from the transmission of the ultrasonic wave to the return.


* Bluetooth protocol: Bluetooth Specification V4.0 BLE
* No byte limit in serial port Transceiving
* In open environment, realize 100m ultra-distance communication with iphone4s
* Working frequency: 2.4GHz ISM band
* Modulation method: GFSK(Gaussian Frequency Shift Keying)
* Transmission power: -23dbm, -6dbm, 0dbm, 6dbm, can be modified by AT command.
* Sensitivity: ≤-84dBm at 0.1% BER
* Transmission rate: Asynchronous: 6K bytes ; Synchronous: 6k Bytes
* Security feature: Authentication and encryption
* Supporting service: Central & Peripheral UUID FFE0, FFE1
* Power consumption: Auto sleep mode, stand by current 400uA~800uA, 8.5mA during transmission.
* Power supply: 5V DC
* Working temperature: –5 to +65 Centigrade


<br>[[File:0428-84.png|500px|frameless|thumb]]<br>


Circuit diagram of ultrasonic sensor:
(3)Equipment


<br>[[File:0428-82.png|500px|frameless|thumb]]<br>
<br>[[File:0428-96.png|600px|frameless|thumb]]<br>  


(4)Connection Diagram


'''(5)Connection Diagram'''
* 1. STATE: state test pins, connected to internal LED, generally keep it unconnected.
* 2. RXD: serial interface, receiving terminal.
* 3. TXD: serial interface, transmitting terminal.
* 4. GND: Ground.
* 5. VCC: positive pole of the power source.
* 6. EN/BRK: break connect, it means breaking the Bluetooth connection, generally, keep it unconnected.


<br>[[File:0428-83.png|500px|frameless|thumb]]<br>  
<br>[[File:0428-97.png|500px|frameless|thumb]]<br>  


<br>[[File:0428-85.png|500px|frameless|thumb]]<br>
(5)Test Code


<pre>
/*
keyestudio Mini Tank Robot v2.0
lesson 7.1
bluetooth
http://www.keyestudio.com
*/


'''(6)Test Code'''
char ble_val; //character variable: save the value of Bluetooth reception


<pre>
/*
keyestudio Mini Tank Robot V2
lesson 5
Ultrasonic sensor
http://www.keyestudio.com
*/
int trigPin = 5;    // Trigger
int echoPin = 4;    // Echo
long duration, cm, inches;
void setup() {
void setup() {
  //Serial Port begin
   Serial.begin(9600);
   Serial.begin (9600);
  //Define inputs and outputs
  pinMode(trigPin, OUTPUT);
  pinMode(echoPin, INPUT);
}
}
void loop() {
void loop() {
   // The sensor is triggered by a HIGH pulse of 10 or more microseconds.
   if(Serial.available() > 0) //Judge if there is data in serial buffer
  // Give a short LOW pulse beforehand to ensure a clean HIGH pulse:
   {
  digitalWrite(trigPin, LOW);
    ble_val = Serial.read(); //Read data from serial buffer
  delayMicroseconds(2);
     Serial.println(ble_val); //Print
  digitalWrite(trigPin, HIGH);
   }}
  delayMicroseconds(10);
//*******************************************
  digitalWrite(trigPin, LOW);
  // Read the signal from the sensor: a HIGH pulse whose
  // duration is the time (in microseconds) from the sending
   // of the ping to the reception of its echo off of an object.
  duration = pulseIn(echoPin, HIGH);
  // Convert the time into a distance
  cm = (duration/2) / 29.1;     // Divide by 29.1 or multiply by 0.0343
  inches = (duration/2) / 74;   // Divide by 74 or multiply by 0.0135
   Serial.print(inches);
  Serial.print("in, ");
  Serial.print(cm);
  Serial.print("cm");
  Serial.println();
  delay(250);
}
//****************************************************************
</pre>
</pre>


(7)Test Result
Upload test code on the development board, open serial monitor and set baud rate to 9600. The detected distance will be displayed, unit is cm and inch. Hinder the ultrasonic sensor by hand, the displayed distance value is smaller.


(There will be contradiction between serial communication of code and communication of Bluetooth when uploading code, therefore, don’t link with Bluetooth module before uploading code.)<br>
After uploading code on development board, then insert Bluetooth module, wait for the command from cellphone.<br>


<br>[[File:0428-86.png|500px|frameless|thumb]]<br>  
(6)Download APP
 
<span style=color:red>Allow APP to access “location” in settings of your cellphone when connecting to Bluetooth module.</span>


The code is reading the received signal, and we also need a stuff to send signal. In this project, we send signal to control robot car via cellphone.<br>
Then we need to download the APP.<br>


(8)Code Explanation
'''1.For iOS system'''
int trigPin = 5; this pin is defined pin to transmit ultrasonic waves, generally output.
int echoPin = 4; this is defined as the pin of reception, generally input
cm = (duration/2) / 29.1;  inches = (duration/2) / 74;  by 0.0135
We can calculate the distance by using the following formula:
distance = (traveltime/2) x speed of sound
The speed of sound is: 343m/s = 0.0343 cm/uS = 1/29.1 cm/uS
Or in inches: 13503.9in/s = 0.0135in/uS = 1/74in/uS
We need to divide the traveltime by 2 because we have to take into account that the wave was sent, hit the object, and then returned back to the sensor.
(9)Extension Practice:
We have just measured the distance displayed by the ultrasonic. How about controlling the LED with the measured distance? Let's try it, connect an LED light module to the D10 pin.


<br>[[File:0428-87.png|500px|frameless|thumb]]<br>
Enter APP STORE to search BLE Scanner 4.0, then download it.


<pre>
<br>[[File:0428-98.png|300px|frameless|thumb]]<br>
/*
 
keyestudio Mini Tank Robot V2
'''2.For Android system'''
lesson 5
 
Ultrasonic LED
Enter Google Play to find out BLE Scanner, then download.<br>
http://www.keyestudio.com
And allow APP to access“location”, you could enable “location”in settings of your cellphone.<br>
*/
 
int trigPin = 5;    // Trigger
 
int echoPin = 4;    // Echo
<br>[[File:0428-99.png|300px|frameless|thumb]]<br>
long duration, cm, inches;
 
void setup() {
* 3.After installation, open App and enable “Location and Bluetooth” permission.
  //Serial Port begin
* 4.We take iOS version as example. The operation method of Android version is almost same as it.
  Serial.begin (9600);
* 5.Scan Bluetooth module to get Bluetooth BLE 4.0. Its name is HMSoft.
  //Define inputs and outputs
Then click“connect”to link with Bluetooth and use it.
  pinMode(trigPin, OUTPUT);
 
  pinMode(echoPin, INPUT);
<br>[[File:0428-100.png|300px|frameless|thumb]]<br>
}
 
void loop()
6. After connecting to HMSoft, click it to get multiple options, such as device information, access permission, general and custom service. Choose “CUSTOM SERVICE”
{
 
  // The sensor is triggered by a HIGH pulse of 10 or more microseconds.
<br>[[File:0428-101.png|300px|frameless|thumb]]<br>
  // Give a short LOW pulse beforehand to ensure a clean HIGH pulse:
 
  digitalWrite(trigPin, LOW);
7.Then pop up the following page
  delayMicroseconds(2);
 
  digitalWrite(trigPin, HIGH);
<br>[[File:0428-102.png|300px|frameless|thumb]]<br>
  delayMicroseconds(10);
  digitalWrite(trigPin, LOW);
  // Read the signal from the sensor: a HIGH pulse whose
  // duration is the time (in microseconds) from the sending
  // of the ping to the reception of its echo off of an object.
  duration = pulseIn(echoPin, HIGH);
  // Convert the time into a distance
  cm = (duration/2) / 29.1;    // Divide by 29.1 or multiply by 0.0343
  inches = (duration/2) / 74;  // Divide by 74 or multiply by 0.0135
  Serial.print(inches);
  Serial.print("in, ");
  Serial.print(cm);
  Serial.print("cm");
  Serial.println();
  delay(250);
if (cm>=2 && cm<=10)
digitalWrite(10, HIGH);
delay(1000);
digitalWrite(10, LOW);
delay(1000);
}
//****************************************************************


</pre>
8. Click(Read,Notify,WriteWithoutResponse)to enter the following page


Upload test code to development board and block ultrasonic sensor by hand, then check if LED is on
<br>[[File:0428-103.png|300px|frameless|thumb]]<br>


=== Project 6: IR Reception ===
9.Click Write Value, appear the interface to enter HEX or Text.<br>


(1)Description
<br>[[File:0428-104.png|300px|frameless|thumb]]<br>
There is no doubt that infrared remote control is ubiquitous in daily life. It is used to control various household appliances, such as TVs, stereos, video recorders and satellite signal receivers. Infrared remote control is composed of infrared transmitting and infrared receiving systems, that is, an infrared remote control and infrared receiving module and a single-chip microcomputer capable of decoding.​    
The 38K infrared carrier signal emitted by remote controller is encoded by the encoding chip in the remote controller. It is composed of a section of pilot code, user code, user inverse code, data code, and data inverse code. The time interval of the pulse is used to distinguish whether it is a 0 or 1 signal and the encoding is made up of these 0, 1 signals.
The user code of the same remote control is unchanged. The data code can distinguish the key.
When the remote control button is pressed, the remote control sends out an infrared carrier signal. When the IR receiver receives the signal, the program will decode the carrier signal and determines which key is pressed. The MCU decodes the received 01 signal, thereby judging what key is pressed by the remote control.
Infrared receiver we use is an infrared receiver module. Mainly composed of an infrared receiver head, it is a device that integrates reception, amplification, and demodulation. Its internal IC has completed demodulation, and can achieve from infrared reception to output and be compatible with TTL signals. Additionally, it is suitable for infrared remote control and infrared data transmission. The infrared receiving module made by the receiver has only three pins, signal line, VCC and GND. It is very convenient to communicate with arduino and other microcontrollers.


<br>[[File:0428-88.png|300px|frameless|thumb]]<br>  
10.Open the serial monitor on Arduino,enter a 0 or other character at Text interface.<br>  


<br>[[File:0428-105.png|300px|frameless|thumb]]<br>


(2)Specification
Then click“Write”, open serial monitor to view if there is a “0” signal
<br>[[File:0428-106.png|300px|frameless|thumb]]<br>


<br>[[File:0428-89.png|200px|frameless|thumb]]<br>


* Operating Voltage: 3.3-5V(DC)
(7)Code Explanation
* Interface: 3PIN
* Output Signal: Digital signal
* Receiving Angle: 90 degrees
* Frequency: 38khz
* Receiving Distance: 10m


Serial.available() : The current rest characters when return to buffer area. Generally, this function is used to judge if there is data in buffer. When Serial.available()>0, it means that serial receives the data and can be read<br>
Serial.read():Read a data of a Byte in buffer of serial port, for instance, device sends data to Arduino via serial port, then we could read data by “Serial.read()”
(8)Extension Practice<br>
We could send a command via cellphone to turn on and off a LED. <br>
D10 is connected to a LED, as shown below:<br>


 
<br>[[File:0428-107.png|500px|frameless|thumb]]<br>  
(3)Equipment
 
<br>[[File:0428-90.png|700px|frameless|thumb]]<br>
 
(4)Connection Diagram
 
<br>[[File:0428-91.png|500px|frameless|thumb]]<br>  
 
Respectively link “-”、“+” and S of IR receiver module with G(GND), V(VCC)and A0 of keyestudio development board.
Attention: On the condition that digital ports are not available, analog ports can be regarded as digital ports. A0 equals to D14, A1 is equivalent to digital 15.
 
 
(5)Test Code
 
Firstly import library file of IR receiver module(refer to how to import Arduino library file) before designing code.


<pre>
<pre>
/*
/*
keyestudio Mini Tank Robot V2
keyestudio Mini Tank Robot v2.0
lesson 6
lesson 7.2
IRremote
Bluetooth
http://www.keyestudio.com
http://www.keyestudio.com
*/  
*/  
#include <IRremote.h>    // IRremote library statement
int ledpin=11;
int RECV_PIN = A0;        //define the pins of IR receiver as A0
void setup()
IRrecv irrecv(RECV_PIN);  
{Serial.begin(9600);
decode_results results;  // decode results exist in the “result” of “decode results”
  pinMode(ledpin,OUTPUT);
void setup()
}
{
void loop()
      Serial.begin(9600);   
{ int i;
      irrecv.enableIRIn(); //Enable receiver
  if (Serial.available())
}
  {i=Serial.read();
void loop() {
    Serial.println("DATA RECEIVED:");
  if (irrecv.decode(&results))//decode successfully, receive a set of infrared signals
    if(i=='1')
  {
    { digitalWrite(ledpin,1);
    Serial.println(results.value, HEX);//Wrap word in 16 HEX to output and receive code
      Serial.println("led on");
    irrecv.resume(); // Receive the next value
    }
  }
    if(i=='0')
  delay(100);
    { digitalWrite(ledpin,0);
}
      Serial.println("led off");
//*******************************************************
}}}//*******************************************
 
</pre>
</pre>


<br>[[File:0428-108.png|300px|frameless|thumb]] [[File:0428-105.png|300px|frameless|thumb]]<br>


(6)Test Result
Click “Write” on APP, when you enter 1, LED will be on, when you input 0, LED will be off. (Remember to remove the Bluetooth module after finishing experiment, otherwise, burning code will be affected)


Upload test code, open serial monitor and set baud rate to 9600, point remote control to IR receiver and the corresponding value will be shown, if pressing so long, the error codes will appear.
=== Project 8: Motor Driving and Speed Control ===


<br>[[File:0428-92.png|500px|frameless|thumb]]<br>
(1) Description


Below we have listed out each button value of keyestudio remote control. So you can keep it for reference.
<br>[[File:0428-110.png|300px|frameless|thumb]]<br>
 
There are many ways to drive the motor. Our tank robot uses the most commonly used L298P solution. L298P is an excellent high-power motor driver IC produced by STMicroelectronics. It can directly drive DC motors, two-phase and four-phase stepping motors. The driving current up to 2A, and output terminal of motor adopts eight high-speed Schottky diodes as protection.<br>
We designed a shield based on the circuit of L298p. <br>
The stacked design reduces the technical difficulty of using and driving the motor.<br>
 
(2)Specification
 
Circuit Diagram for L298P Board


<br>[[File:0428-93.png|500px|frameless|thumb]]<br>  
<br>[[File:0428-111.png|500px|frameless|thumb]]<br>
 
* 1)Logic part input voltage: DC5V
* 2)Driving part input voltage: DC 7-12V
* 3)Logic part working current: <36mA
* 4)Driving part working current: <2A
* 5)Maximum power dissipation: 25W (T=75℃)
* 6)Working temperature: -25℃~+130℃
* 7)Control signal input level: high level 2.3V<Vin<5V, low level -0.3V<Vin<1.5V
 
<br>[[File:0428-112.png|500px|frameless|thumb]]<br>
 
(3)Drive Robot to Move
 
Through the above circuit diagram, the direction pin of A motor is D12, and speed pin is D3; D13 is the direction pin of B motor, D11 is speed pin.<br>
We know how to control digital ports according to the following chart.<br>
PWM decides 2 motors to turn so as to drive robot car. The PWM value is in the range of 0-255, the larger the number, the faster the motor rotates.<br>
 
<br>[[File:0428-113.png|500px|frameless|thumb]]<br>
 
(4)Equipment
 
<br>[[File:0428-114.png|700px|frameless|thumb]]<br>  


(7)Code Explanation
(5)Connection Diagram
irrecv.enableIRIn(): after enabling IR decoding, the IR signals will be received, then function“decode()”will check continuously if decode successfully.


irrecv.decode(&results): after decoding successfully, this function will come back to “true”, and keep result in “results”. After decoding a IR signals, run the resume()function and receive the next signal
<br>[[File:04288-2.png|500px|frameless|thumb]]<br>
(8)Extension Practice
We decoded the key value of IR remote control. How about restrain LED by the measured value? We could operate an experiment to affirm. Attach a LED to D10. When keep the pin of IR receiver unchanged, LED will be on when pressing the key of remote control; press again, LED will be off.


<br>[[File:0428-94.png|500px|frameless|thumb]]<br>  
Note: the 4Pin terminal block is marked with silkscreen 1234. The red line of right rear motor is connected to terminal 1, black line is linked with end 2. The red line of left front motor is attached to terminal 3, black line is linked with port 4. <br>  


(6)Test Code


<pre>
<pre>
/* keyestudio Mini Tank Robot V2
/*
lesson 6.2
keyestudio Mini Tank Robot v2.0
IRremote
lesson 8.1
http://www.keyestudio.com
motor driver
http://www.keyestudio.com
*/  
*/  
#include <IRremote.h>
 
int RECV_PIN = A0;//define the pin of IR receiver as A0
#define ML_Ctrl 13  //define the direction control pin of left motor
int LED_PIN=10;//define the pin of LED
#define ML_PWM 11  //define the PWM control pin of left motor
int a=0;
#define MR_Ctrl 12  //define direction control pin of right motor
IRrecv irrecv(RECV_PIN);
#define MR_PWM 3  // define the PWM control pin of right motor
decode_results results;
 
void setup()
void setup()
{
{
   Serial.begin(9600);
   pinMode(ML_Ctrl, OUTPUT);//define direction control pin of left motor as output
   irrecv.enableIRIn(); // Initialize the IR receiver
   pinMode(ML_PWM, OUTPUT);//define PWM control pin of left motor as output
   pinMode(LED_PIN,OUTPUT);//set LED_pin to OUTPUT
   pinMode(MR_Ctrl, OUTPUT);//define direction control pin of right motor as output.
  pinMode(MR_PWM, OUTPUT);//define the PWM control pin of right motor as output
}
}
void loop() {
  if (irrecv.decode(&results)) {
if(results.value==0xFF02FD &a==0) // according to the above key value, press“OK”on remote control , LED will be controlled
{
    digitalWrite(LED_PIN,HIGH);//LED will be on
a=1;
}
else if(results.value==0xFF02FD &a==1) //press again
{
digitalWrite(LED_PIN,LOW);//LED will go off
a=0;
}
    irrecv.resume(); //receive the next value
  }
}
//*******************************************************
</pre>


Upload code to development board, press“OK”key on remote control to make LED on and off.
void loop()
{
  digitalWrite(ML_Ctrl,LOW);//set the direction control pin of left motor to LOW
  analogWrite(ML_PWM,200);//set the PWM control speed of left motor to 200
  digitalWrite(MR_Ctrl,LOW);//set the direction control pin of right motor to LOW
  analogWrite(MR_PWM,200);//set the PWM control speed of right motor to 200
 
  //front
  delay(2000);//delay in 2s
  digitalWrite(ML_Ctrl,HIGH);//set the direction control pin of left motor to HIGH
  analogWrite(ML_PWM,200);//set the PWM control speed of left motor to 200 
digitalWrite(MR_Ctrl,HIGH);//set the direction control pin of right motor to HIGH
  analogWrite(MR_PWM,200);//set the PWM control speed of right motor to 200


=== Project 7: Bluetooth Remote Control ===
  //back
  delay(2000);//delay in 2s
  digitalWrite(ML_Ctrl,HIGH);//set the direction control pin of left motor to HIGH
  analogWrite(ML_PWM,200);//set the PWM control speed of left motor to 200
  digitalWrite(MR_Ctrl,LOW);//set the direction control pin of right motor to LOW
  analogWrite(MR_PWM,200);//set the PWM control speed of right motor to 200


(1)Description
    //left
  delay(2000);//delay in 2s
  digitalWrite(ML_Ctrl,LOW);//set the direction control pin of left motor to LOW
  analogWrite(ML_PWM,200);//set the PWM control speed of left motor to 200
  digitalWrite(MR_Ctrl,HIGH);//set the direction control pin of right motor to HIGH
  analogWrite(MR_PWM,200);//set the PWM control speed of right motor to 200


<br>[[File:0428-95.png|300px|frameless|thumb]]<br>
  //right
  delay(2000);//delay in 2s
  analogWrite(ML_PWM,0);//set the PWM control speed of left motor to 0
  analogWrite(MR_PWM,0);//set the PWM control speed of right motor to 0


Bluetooth, a simple wireless communication module most popular since the last few decades and easy to use are being used in most of the battery-powered devices.
    //stop
Over the years, there have been many upgrades of Bluetooth standard to keep fulfil the demand of customers and technology according to the need of time and situation.
  delay(2000);//delay in 2s
Over the few years, there are many things changed including data transmission rate, power consumption with wearable and IoT Devices and Security System.
}//*****************************************
Here we are going to learn about HM-10 BLE 4.0 with Arduino Board. The HM-10 is a readily available Bluetooth 4.0 module. This module is used for establishing wireless data communication. The module is designed by using the Texas Instruments CC2540 or CC2541 Bluetooth low energy (BLE) System on Chip (SoC).


</pre>


(2)Specification


* Bluetooth protocol: Bluetooth Specification V4.0 BLE
(7)Test Result
* No byte limit in serial port Transceiving
* In open environment, realize 100m ultra-distance communication with iphone4s
* Working frequency: 2.4GHz ISM band
* Modulation method: GFSK(Gaussian Frequency Shift Keying)
* Transmission power: -23dbm, -6dbm, 0dbm, 6dbm, can be modified by AT command.
* Sensitivity: ≤-84dBm at 0.1% BER
* Transmission rate: Asynchronous: 6K bytes ; Synchronous: 6k Bytes
* Security feature: Authentication and encryption
* Supporting service: Central & Peripheral UUID FFE0, FFE1
* Power consumption: Auto sleep mode, stand by current 400uA~800uA, 8.5mA during transmission.
* Power supply: 5V DC
* Working temperature: –5 to +65 Centigrade


Hook up by connection diagram, upload code and power on, smart car goes forward and back for 2s, turns left and right for 2s, stops for 2s and alternately.<br>
(8) Code Explanation<br>
digitalWrite(ML_Ctrl,LOW): the rotation direction of motor is decided by the high/low level and and the pins that decide rotation direction are general pins.<br>
analogWrite(ML_PWM,200): the speed of motor is regulated by PWM, The speed of motor is regulated by PWM, and the pins that decide the speed of motor have to be PWM pins.<br>


(3)Equipment


<br>[[File:0428-96.png|600px|frameless|thumb]]<br>
(9)Extension Practice


(4)Connection Diagram
Hook up in same way
 
* 1. STATE: state test pins, connected to internal LED, generally keep it unconnected.
* 2. RXD: serial interface, receiving terminal.
* 3. TXD: serial interface, transmitting terminal.
* 4. GND: Ground.
* 5. VCC: positive pole of the power source.
* 6. EN/BRK: break connect, it means breaking the Bluetooth connection, generally, keep it unconnected.


<br>[[File:0428-97.png|500px|frameless|thumb]]<br>  
<br>[[File:04288-2.png|500px|frameless|thumb]]<br>  
 
(5)Test Code


<pre>
<pre>
/*
/*
  keyestudio Mini Tank Robot v2.0
  keyestudio Mini Tank Robot v2.0
  lesson 7.1
  lesson 8.2
  bluetooth
  motor driver pwm
http://www.keyestudio.com
http://www.keyestudio.com
*/
*/  
#define ML_Ctrl 13  //define the direction control pin of left motor
#define ML_PWM 11  //define the PWM control pin of left motor
#define MR_Ctrl 12  //define the control pin of right motor
#define MR_PWM 3  //define the PWM control pin of right motor
void setup()
{ pinMode(ML_Ctrl, OUTPUT);//define the direction control pin of left motor as OUTPUT
  pinMode(ML_PWM, OUTPUT);//define the PWM control pin of left motor as OUTPUT
  pinMode(MR_Ctrl, OUTPUT);//define the direction control pin of right motor as OUTPUT
  pinMode(MR_PWM, OUTPUT);//define the PWM control pin of right motor as OUTPUT


char ble_val; //character variable: save the value of Bluetooth reception
void setup() {
  Serial.begin(9600);
}
}
void loop() {
void loop()
   if(Serial.available() > 0) //Judge if there is data in serial buffer
{ digitalWrite(ML_Ctrl,LOW);//Set direction control pin of left motor to LOW
   {
  analogWrite(ML_PWM,100);// Set the PWM control speed of left motor to 100
     ble_val = Serial.read(); //Read data from serial buffer
  digitalWrite(MR_Ctrl,LOW);//Set the direction control pin of right motor to LOW
    Serial.println(ble_val); //Print
  analogWrite(MR_PWM,100);//Set the PWM control speed of right motor to 100
   }}
  //front
//*******************************************
  delay(2000);//define 2s
</pre>
  digitalWrite(ML_Ctrl,HIGH);//Set direction control pin of left motor to HIGH level
 
  analogWrite(ML_PWM,100);//Set the PWM control speed of left motor to 100
  digitalWrite(MR_Ctrl,HIGH);//Set direction control pin of right motor to HIGH level
  analogWrite(MR_PWM,100);//Set the PWM control speed of right motor to 100
  //back
  delay(2000);//define 2s
   digitalWrite(ML_Ctrl,HIGH);//Set direction control pin of left motor to HIGH level
  analogWrite(ML_PWM,100);//Set the PWM control speed of left motor to 100
  digitalWrite(MR_Ctrl,LOW);//Set direction control pin of right motor to LOW level
   analogWrite(MR_PWM,100);//Set the PWM control speed of right motor to 100
     //left
  delay(2000);//define 2s
  digitalWrite(ML_Ctrl,LOW);//set the direction control pin of left motor to LOW
  analogWrite(ML_PWM,100);//set the PWM control speed of left motor to 200
  digitalWrite(MR_Ctrl,HIGH);//set the direction control pin of right motor to HIGH
   analogWrite(MR_PWM,100);//set the PWM control speed of right motor to 100
  //right
  delay(2000);//define 2s
  analogWrite(ML_PWM,0);//set the PWM control speed of left motor to 0
  analogWrite(MR_PWM,0);// set the PWM control speed of right motor to 0


(There will be contradiction between serial communication of code and communication of Bluetooth when uploading code, therefore, don’t link with Bluetooth module before uploading code.)
    //stop
After uploading code on development board, then insert Bluetooth module, wait for the command from cellphone.
  delay(2000);//define 2s
}//******************************************************************


(6)Download APP
</pre>
Upload code successfully, the motors rotate faster.


The code is reading the received signal, and we also need a stuff to send signal. In this project, we send signal to control robot car via cellphone.
=== Project 9: LED Expression Panel ===
Then we need to download the APP.


'''1.For iOS system'''
(1)Description


Enter APP STORE to search BLE Scanner 4.0, then download it.
<br>[[File:0428-120.png|700px|frameless|thumb]]<br>


<br>[[File:0428-98.png|300px|frameless|thumb]]<br>
If we add an expression panel to the robot, it will be amazing. Keyestudio's 8*16 dot matrix can meet your requirements. You can create facial expressions, patterns or other interesting displays yourself. 8*16 LED light board comes with 128 LEDs. The data of the microprocessor (arduino) communicates with the AiP1640 through the two-wire bus interface, so as to control the 128 LEDs on the module, which produce the patterns you need on dot matrix. To facilitate wiring, we also provide a HX-2.54 4Pin wiring.


'''2.For Android system'''


Enter Google Play to find out BLE Scanner, then download.
(2)Specification
And allow APP to access“location”, you could enable “location”in settings of your cellphone.


* Working voltage: DC 3.3-5V
* Power loss: 400mW
* Oscillation frequency: 450KHz     
* Drive current: 200mA
* Working temperature: -40~80℃
* Communication method: two-wire bus


<br>[[File:0428-99.png|300px|frameless|thumb]]<br>
(3)Equipment
 
3.After installation, open App and enable “Location and Bluetooth” permission.
4.We take iOS version as example. The operation method of Android version is almost same as it.
5.Scan Bluetooth module to get Bluetooth BLE 4.0. Its name is HMSoft.
Then click“connect”to link with Bluetooth and use it.


<br>[[File:0428-100.png|300px|frameless|thumb]]<br>  
<br>[[File:0428-121.png|700px|frameless|thumb]]<br>  


6. After connecting to HMSoft, click it to get multiple options, such as device information, access permission, general and custom service. Choose “CUSTOM SERVICE”
(4)8*16 Dot Matrix Display


<br>[[File:0428-101.png|300px|frameless|thumb]]<br>
Circuit Graphic


7.Then pop up the following page
<br>[[File:0428-122.png|700px|frameless|thumb]]<br>


<br>[[File:0428-102.png|300px|frameless|thumb]]<br>  
The principle of 8*16 dot matrix:<br>  
How to control each led light of 8*16 dot matrix? We know that a byte has 8 bits, each bit is 0 or 1. When a bit is 0, turn off LED and when a bit is 0, turn on LED. <br> Thereby, one byte can control the LED in a row of dot matrix, so 16 bytes can control 16 columns of led lights, that is, 8*16 dot matrix.<br>  


8. Click(Read,Notify,WriteWithoutResponse)to enter the following page
Interface Description and Communication Protocol:<br>
The data of the microprocessor (arduino) communicates with the AiP1640 through the two-wire bus interface.<br>
The communication protocol diagram is shown below:
(SCLK) is SCL, (DIN) is SDA:


<br>[[File:0428-103.png|300px|frameless|thumb]]<br>  
<br>[[File:0428-123.png|700px|frameless|thumb]]<br>  


9.Click Write Value, appear the interface to enter HEX or Text.
①The starting condition for data input: SCL is high level and SDA changes from high to low.<br>
②For data command setting, there are methods as shown in the figure below. <br>
In our sample program, select the way to add 1 to the address automatically, the binary value is 0100 0000 and the corresponding hexadecimal value is 0x40.<br>


<br>[[File:0428-104.png|300px|frameless|thumb]]<br>  
<br>[[File:0428-124.png|700px|frameless|thumb]]<br>  


10.Open the serial monitor on Arduino,enter a 0 or other character at Text interface.
③For address command setting, the address can be selected as shown below.
The first 00H is selected in our sample program, and the binary number 1100 0000 corresponds to the hexadecimal 0xc0


<br>[[File:0428-105.png|300px|frameless|thumb]]<br>  
<br>[[File:0428-125.png|700px|frameless|thumb]]<br>  


Then click“Write”, open serial monitor to view if there is a “0” signal
* ④The requirement for data input is that SCL is high level when inputting data, the signal on SDA must remain unchanged. Only when the clock signal on SCL is low level, the signal on SDA can be altered. The data input is low-order first, high-order is behind
<br>[[File:0428-106.png|300px|frameless|thumb]]<br>
* ⑤ The condition to end data transmission is that when SCL is low, SDA is low, and when SCL is high, the SDA level also becomes high.
* ⑥ Display control, set different pulse width, the pulse width can be selected as shown below
* In the example, we choose pulse width 4/16, and the hexadecimal corresponds to 1000 1010 is 0x8A




(7)Code Explanation
<br>[[File:0428-126.png|700px|frameless|thumb]]<br>


Serial.available() : The current rest characters when return to buffer area. Generally, this function is used to judge if there is data in buffer. When Serial.available()>0, it means that serial receives the data and can be read
4. Introduction for Modulus Tool
Serial.read():Read a data of a Byte in buffer of serial port, for instance, device sends data to Arduino via serial port, then we could read data by “Serial.read()”
(8)Extension Practice
We could send a command via cellphone to turn on and off a LED.
D10 is connected to a LED, as shown below:


<br>[[File:0428-107.png|500px|frameless|thumb]]<br>
The online version of dot matrix modulus tool:
http://dotmatrixtool.com/#


<pre>
①Open links to enter the following page.
/*
keyestudio Mini Tank Robot v2.0
lesson 7.2
Bluetooth
http://www.keyestudio.com
*/
int ledpin=11;
void setup()
{Serial.begin(9600);
pinMode(ledpin,OUTPUT);
}
void loop()
{ int i;
  if (Serial.available())
  {i=Serial.read();
    Serial.println("DATA RECEIVED:");
    if(i=='1')
    { digitalWrite(ledpin,1);
      Serial.println("led on");
    }
    if(i=='0')
    { digitalWrite(ledpin,0);
      Serial.println("led off");
}}}//*******************************************
</pre>


<br>[[File:0428-108.png|300px|frameless|thumb]] [[File:0428-105.png|300px|frameless|thumb]]<br>
<br>[[File:0428-127.png|700px|frameless|thumb]]<br>  


Click “Write” on APP, when you enter 1, LED will be on, when you input 0, LED will be off. (Remember to remove the Bluetooth module after finishing experiment, otherwise, burning code will be affected)
②The dot matrix is 8*16 in this project, so set the height to 8, width to 16, as shown below.


=== Project 8: Motor Driving and Speed Control ===
<br>[[File:0428-128.png|700px|frameless|thumb]]<br>


(1) Description
③ Generate hexadecimal data from the pattern
As shown below, press the left mouse button to select, the right button to cancel, draw the pattern you want, click Generate, and the hexadecimal data we need will be produced.


<br>[[File:0428-110.png|300px|frameless|thumb]]<br>  
<br>[[File:0428-129.png|700px|frameless|thumb]]<br>  


There are many ways to drive the motor. Our tank robot uses the most commonly used L298P solution. L298P is an excellent high-power motor driver IC produced by STMicroelectronics. It can directly drive DC motors, two-phase and four-phase stepping motors. The driving current up to 2A, and output terminal of motor adopts eight high-speed Schottky diodes as protection.
We designed a shield based on the circuit of L298p.
The stacked design reduces the technical difficulty of using and driving the motor.


(2)Specification
(5)Connection Diagram


Circuit Diagram for L298P Board
<br>[[File:0428-130.png|700px|frameless|thumb]]<br>


<br>[[File:0428-111.png|500px|frameless|thumb]]<br>


* 1)Logic part input voltage: DC5V
Wiring note: The GND, VCC, SDA, and SCL of the 8x16 LED panel are respectively connected to -(GND), + (VCC), A4 and A5 of the keyestudio sensor expansion board for two-wire serial communication. (Note: This pin is connected to arduino IIC, but this module is not IIC communication, it can be linked with any two pins.)
* 2)Driving part input voltage: DC 7-12V
* 3)Logic part working current: <36mA
* 4)Driving part working current: <2A
* 5)Maximum power dissipation: 25W (T=75℃)
* 6)Working temperature: -25℃~+130℃
* 7)Control signal input level: high level 2.3V<Vin<5V, low level -0.3V<Vin<1.5V


<br>[[File:0428-112.png|500px|frameless|thumb]]<br>


(3)Drive Robot to Move
(6)Test Code


Through the above circuit diagram, the direction pin of A motor is D12, and speed pin is D3; D13 is the direction pin of B motor, D11 is speed pin.
The code that shows smile face
We know how to control digital ports according to the following chart.
PWM decides 2 motors to turn so as to drive robot car. The PWM value is in the range of 0-255, the larger the number, the faster the motor rotates.
 
<br>[[File:0428-113.png|500px|frameless|thumb]]<br>
 
(4)Equipment
 
<br>[[File:0428-114.png|700px|frameless|thumb]]<br>
 
(5)Connection Diagram
 
<br>[[File:0428-115.png|500px|frameless|thumb]]<br>
 
Note: the 4Pin terminal block is marked with silkscreen 1234. The red line of right rear motor is connected to terminal 1, black line is linked with end 2. The red line of left front motor is attached to terminal 3, black line is linked with port 4.
 
(6)Test Code


<pre>
<pre>
/*
/*
  keyestudio Mini Tank Robot v2.0
  keyestudio Mini Tank Robot v2.0
  lesson 8.1
  lesson 9.1
  motor driver
  Matrix  face
  http://www.keyestudio.com
  http://www.keyestudio.com
*/  
*/  
//the data of smiley from modulus tool
unsigned char smile[] = {0x00, 0x00, 0x1c, 0x02, 0x02, 0x02, 0x5c, 0x40, 0x40, 0x5c, 0x02, 0x02, 0x02, 0x1c, 0x00, 0x00};


#define ML_Ctrl 13 //define the direction control pin of left motor
#define SCL_Pin  A5 //Set clock pin to A5
#define ML_PWM 11  //define the PWM control pin of left motor
#define SDA_Pin  A4 //Set data pin to A4
#define MR_Ctrl 12 //define direction control pin of right motor
#define MR_PWM 3  // define the PWM control pin of right motor


void setup()
void setup(){
  //Set pin to output
  pinMode(SCL_Pin,OUTPUT);
  pinMode(SDA_Pin,OUTPUT);
  //clear the display
  //matrix_display(clear);
}
void loop(){
  matrix_display(smile);  // display smile face
}
// the function for dot matrix display
void matrix_display(unsigned char matrix_value[])
{
{
   pinMode(ML_Ctrl, OUTPUT);//define direction control pin of left motor as output
   IIC_start(); // use the function of the data transmission start condition
   pinMode(ML_PWM, OUTPUT);//define PWM control pin of left motor as output
  IIC_send(0xc0);  //select address
   pinMode(MR_Ctrl, OUTPUT);//define direction control pin of right motor as output.
 
   pinMode(MR_PWM, OUTPUT);//define the PWM control pin of right motor as output
  for(int i = 0;i < 16;i++) //pattern data has 16 bits
   {
    IIC_send(matrix_value[i]); //convey the pattern data
  }
 
   IIC_end();   //end the transmission of pattern data 
  IIC_start();
   IIC_send(0x8A); //display control, set pulse width to 4/16 s
  IIC_end();
}
}


void loop()
//the condition to start conveying data
{  
void IIC_start()
   digitalWrite(ML_Ctrl,LOW);//set the direction control pin of left motor to LOW
{
  analogWrite(ML_PWM,200);//set the PWM control speed of left motor to 200
  digitalWrite(SCL_Pin,HIGH);
  digitalWrite(MR_Ctrl,LOW);//set the direction control pin of right motor to LOW
  delayMicroseconds(3);
  analogWrite(MR_PWM,200);//set the PWM control speed of right motor to 200
  digitalWrite(SDA_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,LOW);
  delayMicroseconds(3);
}
//Convey data
void IIC_send(unsigned char send_data)
{
   for(char i = 0;i < 8;i++)  //Each byte has 8 bits 8bit for every character
  {
      digitalWrite(SCL_Pin,LOW); // pull down clock pin SCL_Pin to change the signal of SDA
      delayMicroseconds(3);
      if(send_data & 0x01)  //set high and low level of SDA_Pin according to 1 or 0 of every bit
      {
        digitalWrite(SDA_Pin,HIGH);
      }
      else
      {
        digitalWrite(SDA_Pin,LOW);
      }
      delayMicroseconds(3);
      digitalWrite(SCL_Pin,HIGH); //pull up the clock pin SCL_Pin to stop transmission
      delayMicroseconds(3);
      send_data = send_data >> 1;  // detect bit by bit, shift the data to the right by one
  }
}


  //front
//The sign of ending data transmission
   delay(2000);//delay in 2s
void IIC_end()
  digitalWrite(ML_Ctrl,HIGH);//set the direction control pin of left motor to HIGH
{
   analogWrite(ML_PWM,200);//set the PWM control speed of left motor to 200 
   digitalWrite(SCL_Pin,LOW);
digitalWrite(MR_Ctrl,HIGH);//set the direction control pin of right motor to HIGH
  delayMicroseconds(3);
   analogWrite(MR_PWM,200);//set the PWM control speed of right motor to 200
  digitalWrite(SDA_Pin,LOW);
  delayMicroseconds(3);
  digitalWrite(SCL_Pin,HIGH);
   delayMicroseconds(3);
  digitalWrite(SDA_Pin,HIGH);
   delayMicroseconds(3);
}
//******************************************************


  //back
</pre>
  delay(2000);//delay in 2s
  digitalWrite(ML_Ctrl,HIGH);//set the direction control pin of left motor to HIGH
  analogWrite(ML_PWM,200);//set the PWM control speed of left motor to 200
  digitalWrite(MR_Ctrl,LOW);//set the direction control pin of right motor to LOW
  analogWrite(MR_PWM,200);//set the PWM control speed of right motor to 200


    //left
(7)Test Result<br>
  delay(2000);//delay in 2s
Wire according to connection diagram. The DIP switch is dialed to right end and power on, the smile face appears on dot matrix.<br>
  digitalWrite(ML_Ctrl,LOW);//set the direction control pin of left motor to LOW
<br>[[File:0428-131.png|500px|frameless|thumb]]<br>
  analogWrite(ML_PWM,200);//set the PWM control speed of left motor to 200
  digitalWrite(MR_Ctrl,HIGH);//set the direction control pin of right motor to HIGH
  analogWrite(MR_PWM,200);//set the PWM control speed of right motor to 200


  //right
  delay(2000);//delay in 2s
  analogWrite(ML_PWM,0);//set the PWM control speed of left motor to 0
  analogWrite(MR_PWM,0);//set the PWM control speed of right motor to 0


    //stop
(8)Extension Practice
  delay(2000);//delay in 2s
}//*****************************************


</pre>
We use the modulo tool (http://dotmatrixtool.com/#)to make the dot matrix alternately display start, go front and stop patterns then clear the patterns, the time interval is 2000 milliseconds.


<br>[[File:0428-132.png|500px|frameless|thumb]]<br>


(7)Test Result
Get the graphical code to be displayed via modulus tool<br>


Hook up by connection diagram, upload code and power on, smart car goes forward and back for 2s, turns left and right for 2s, stops for 2s and alternately.
* Start:
(8) Code Explanation
* 0x01,0x02,0x04,0x08,0x10,0x20,0x40,0x80,0x80,0x40,0x20,0x10,0x08,0x04,0x02,0x01
digitalWrite(ML_Ctrl,LOW): the rotation direction of motor is decided by the high/low level and and the pins that decide rotation direction are general pins.
* Go front:
analogWrite(ML_PWM,200): the speed of motor is regulated by PWM, The speed of motor is regulated by PWM, and the pins that decide the speed of motor have to be PWM pins.
* 0x00,0x00,0x00,0x00,0x00,0x24,0x12,0x09,0x12,0x24,0x00,0x00,0x00,0x00,0x00,0x00
* Go back:
* 0x00,0x00,0x00,0x00,0x00,0x24,0x48,0x90,0x48,0x24,0x00,0x00,0x00,0x00,0x00,0x00
* Turn left:
* 0x00,0x00,0x00,0x00,0x00,0x00,0x44,0x28,0x10,0x44,0x28,0x10,0x44,0x28,0x10,0x00
* Turn left:
* 0x00,0x10,0x28,0x44,0x10,0x28,0x44,0x10,0x28,0x44,0x00,0x00,0x00,0x00,0x00,0x00
* Stop:
* 0x2E,0x2A,0x3A,0x00,0x02,0x3E,0x02,0x00,0x3E,0x22,0x3E,0x00,0x3E,0x0A,0x0E,0x00
* Clear the displayed code:0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00


 
The code that the multiple patterns shift:
(9)Extension Practice
 
Hook up in same way
 
<br>[[File:0428-115.png|500px|frameless|thumb]]<br>


<pre>
<pre>
/*
/* keyestudio Mini Tank Robot v2.0
keyestudio Mini Tank Robot v2.0
  lesson 9.2
  lesson 8.2
  Matrix loop
  motor driver pwm
  http://www.keyestudio.com
  http://www.keyestudio.com
*/  
*/  
#define ML_Ctrl 13  //define the direction control pin of left motor
//Array, used to store the data of the pattern, can be calculated by yourself or obtained from the modulus tool
#define ML_PWM 11  //define the PWM control pin of left motor
unsigned char start01[] =
#define MR_Ctrl 12 //define the control pin of right motor
{0x01,0x02,0x04,0x08,0x10,0x20,0x40,0x80,0x80,0x40,0x20,0x10,0x08,0x04,0x02,0x01};
#define MR_PWM 3  //define the PWM control pin of right motor
unsigned char front[] =
void setup()
{0x00,0x00,0x00,0x00,0x00,0x24,0x12,0x09,0x12,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
{ pinMode(ML_Ctrl, OUTPUT);//define the direction control pin of left motor as OUTPUT
unsigned char back[] =
   pinMode(ML_PWM, OUTPUT);//define the PWM control pin of left motor as OUTPUT
{0x00,0x00,0x00,0x00,0x00,0x24,0x48,0x90,0x48,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
   pinMode(MR_Ctrl, OUTPUT);//define the direction control pin of right motor as OUTPUT
unsigned char left[] =
   pinMode(MR_PWM, OUTPUT);//define the PWM control pin of right motor as OUTPUT
{0x00,0x00,0x00,0x00,0x00,0x00,0x44,0x28,0x10,0x44,0x28,0x10,0x44,0x28,0x10,0x00};
 
unsigned char right[] =
{0x00,0x10,0x28,0x44,0x10,0x28,0x44,0x10,0x28,0x44,0x00,0x00,0x00,0x00,0x00,0x00};
unsigned char STOP01[] =
{0x2E,0x2A,0x3A,0x00,0x02,0x3E,0x02,0x00,0x3E,0x22,0x3E,0x00,0x3E,0x0A,0x0E,0x00};
unsigned char clear[] =
{0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00};
#define SCL_Pin  A5 //Set clock pin to A5
#define SDA_Pin  A4  //Set data pin to A4
void setup(){
  //Set pins to output
   pinMode(SCL_Pin,OUTPUT);
   pinMode(SDA_Pin,OUTPUT);
  //Clear the display
   matrix_display(clear);
}
}
void loop()
void loop(){
{ digitalWrite(ML_Ctrl,LOW);//Set direction control pin of left motor to LOW
  matrix_display(start01);  // Display start pattern
   analogWrite(ML_PWM,100);// Set the PWM control speed of left motor to 100
  delay(2000);
   digitalWrite(MR_Ctrl,LOW);//Set the direction control pin of right motor to LOW
  matrix_display(front);    //Front pattern
   analogWrite(MR_PWM,100);//Set the PWM control speed of right motor to 100
  delay(2000);
   //front
  matrix_display(STOP01);   //Stop pattern
   delay(2000);//define 2s
  delay(2000);
   digitalWrite(ML_Ctrl,HIGH);//Set direction control pin of left motor to HIGH level
   matrix_display(clear);   //Clear the display Clear the screen
   analogWrite(ML_PWM,100);//Set the PWM control speed of left motor to 100
   delay(2000);
   digitalWrite(MR_Ctrl,HIGH);//Set direction control pin of right motor to HIGH level
}
   analogWrite(MR_PWM,100);//Set the PWM control speed of right motor to 100
// This function is used to display of dot matrix
  //back
void matrix_display(unsigned char matrix_value[])
   delay(2000);//define 2s
{
   digitalWrite(ML_Ctrl,HIGH);//Set direction control pin of left motor to HIGH level
   IIC_start(); //call the function that data transmission start 
   analogWrite(ML_PWM,100);//Set the PWM control speed of left motor to 100
   IIC_send(0xc0);  //Choose address
   digitalWrite(MR_Ctrl,LOW);//Set direction control pin of right motor to LOW level
 
   analogWrite(MR_PWM,100);//Set the PWM control speed of right motor to 100
   for(int i = 0;i < 16;i++) //pattern data has 16 bits
    //left
   {
   delay(2000);//define 2s
    IIC_send(matrix_value[i]); //data to convey patterns
  digitalWrite(ML_Ctrl,LOW);//set the direction control pin of left motor to LOW
  }
  analogWrite(ML_PWM,100);//set the PWM control speed of left motor to 200
   IIC_end();   //end the transmission of pattern dataEnd
  digitalWrite(MR_Ctrl,HIGH);//set the direction control pin of right motor to HIGH
  IIC_start();
  analogWrite(MR_PWM,100);//set the PWM control speed of right motor to 100
   IIC_send(0x8A); //display control, set pulse width to 4/16
  //right
   IIC_end();
   delay(2000);//define 2s
}
   analogWrite(ML_PWM,0);//set the PWM control speed of left motor to 0
//The condition starting to transmit data
   analogWrite(MR_PWM,0);// set the PWM control speed of right motor to 0
void IIC_start()
 
{
    //stop
  digitalWrite(SCL_Pin,HIGH);
   delay(2000);//define 2s
   delayMicroseconds(3);
}//******************************************************************
   digitalWrite(SDA_Pin,HIGH);
 
   delayMicroseconds(3);
   digitalWrite(SDA_Pin,LOW);
   delayMicroseconds(3);
}
//Convey data
void IIC_send(unsigned char send_data)
{
   for(char i = 0;i < 8;i++) //Each byte has 8 bits
  {
      digitalWrite(SCL_Pin,LOW); //pull down clock pin SCL Pin to change the signals of SDA     
delayMicroseconds(3);
      if(send_data & 0x01)  //set high and low level of SDA_Pin according to 1 or 0 of every bit
      {
        digitalWrite(SDA_Pin,HIGH);
      }
      else
      {
        digitalWrite(SDA_Pin,LOW);
      }
      delayMicroseconds(3);
      digitalWrite(SCL_Pin,HIGH); //pull up clock pin SCL_Pin to stop transmitting data
      delayMicroseconds(3);
      send_data = send_data >> 1;  //detect bit by bit, so shift the data right by one
  }}
//The sign that data transmission ends
void IIC_end()
{
  digitalWrite(SCL_Pin,LOW);
   delayMicroseconds(3);
   digitalWrite(SDA_Pin,LOW);
  delayMicroseconds(3);
   digitalWrite(SCL_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,HIGH);
   delayMicroseconds(3);}
//*****************************************************
</pre>
</pre>


Upload code successfully, the servo turns slowly.
Upload code on development board, 8*16 dot matrix display go front and back and stop patterns, alternately.


=== Project 9: LED Expression Panel ===
<br>[[File:0428-117.png|400px|frameless|thumb]][[File:0428-118.png|400px|frameless|thumb]][[File:0428-119.png|400px|frameless|thumb]]<br>
 
=== Project 10: Light Follow Robot ===


(1)Description
(1)Description


<br>[[File:0428-120.png|700px|frameless|thumb]]<br>  
[[File:0428-137.png|500px|frameless|thumb]]<br>


If we add an expression panel to the robot, it will be amazing. Keyestudio's 8*16 dot matrix can meet your requirements. You can create facial expressions, patterns or other interesting displays yourself. 8*16 LED light board comes with 128 LEDs. The data of the microprocessor (arduino) communicates with the AiP1640 through the two-wire bus interface, so as to control the 128 LEDs on the module, which produce the patterns you need on dot matrix. To facilitate wiring, we also provide a HX-2.54 4Pin wiring.
We’ve introduce how to use various sensors, modules. <br>
In this lesson, we combine with hardware knowledge -- photoresistor module, motor driving, to build a light-following robot!<br>
Just need to use 2 photoresistor modules to detect the light intensity at the both side of robot. Read the analog value to rotate the 2 motors, thus drive the tank robot run. <br>




(2)Specification
The specific logic of light following robot is shown as the table below:<br>


* Working voltage: DC 3.3-5V
[[File:0428-133.png|500px|frameless|thumb]]<br>
* Power loss: 400mW
* Oscillation frequency: 450KHz     
* Drive current: 200mA
* Working temperature: -40~80℃
* Communication method: two-wire bus


(3)Equipment
[[File:0428-134.png|500px|frameless|thumb]]<br>


<br>[[File:0428-121.png|700px|frameless|thumb]]<br>
We make a flow chart based on the above logic table, as shown below:


(4)8*16 Dot Matrix Display
(2)Connection Diagram


Circuit Graphic
[[File:04288-24.png|500px|frameless|thumb]]<br>


<br>[[File:0428-122.png|700px|frameless|thumb]]<br>  
Hook-up Attention:
The 4Pin terminal block is marked with silkscreen 1234. The red line of right rear motor is connected to terminal 1, black line is linked with end 2. The red line of left front motor is attached to terminal 3, black line is linked with port 4. <br>  


The principle of 8*16 dot matrix:
How to control each led light of 8*16 dot matrix? We know that a byte has 8 bits, each bit is 0 or 1. When a bit is 0, turn off LED and when a bit is 0, turn on LED. Thereby, one byte can control the LED in a row of dot matrix, so 16 bytes can control 16 columns of led lights, that is, 8*16 dot matrix.


Interface Description and Communication Protocol:
[[File:0428-136.png|500px|frameless|thumb]]<br>
The data of the microprocessor (arduino) communicates with the AiP1640 through the two-wire bus interface.
The communication protocol diagram is shown below:
(SCLK) is SCL, (DIN) is SDA:
 
<br>[[File:0428-123.png|700px|frameless|thumb]]<br>  


①The starting condition for data input: SCL is high level and SDA changes from high to low.
②For data command setting, there are methods as shown in the figure below
In our sample program, select the way to add 1 to the address automatically, the binary value is 0100 0000 and the corresponding hexadecimal value is 0x40


<br>[[File:0428-124.png|700px|frameless|thumb]]<br>
(3)Test Code


③For address command setting, the address can be selected as shown below.
<pre>
The first 00H is selected in our sample program, and the binary number 1100 0000 corresponds to the hexadecimal 0xc0
 
 
/*
<br>[[File:0428-125.png|700px|frameless|thumb]]<br>  
keyestudio Mini Tank Robot v2.0
 
lesson 10
④The requirement for data input is that SCL is high level when inputting data, the signal on SDA must remain unchanged. Only when the clock signal on SCL is low level, the signal on SDA can be altered. The data input is low-order first, high-order is behind
Light-following tank
⑤ The condition to end data transmission is that when SCL is low, SDA is low, and when SCL is high, the SDA level also becomes high.
http://www.keyestudio.com
⑥ Display control, set different pulse width, the pulse width can be selected as shown below
*/  
In the example, we choose pulse width 4/16, and the hexadecimal corresponds to 1000 1010 is 0x8A
#define light_L_Pin A1  //define the pin of left photo resistor
 
#define light_R_Pin A2  //define the pin of right photo resistor
 
#define ML_Ctrl 13  //define the direction control pin of left motor
<br>[[File:0428-126.png|700px|frameless|thumb]]<br>
#define ML_PWM 11  //define the PWM control pin of left motor
 
#define MR_Ctrl 12  //define the direction control pin of right motor
4. Introduction for Modulus Tool
#define MR_PWM 3  //define the PWM control pin of right motor
 
int left_light;
The online version of dot matrix modulus tool:
int right_light;
http://dotmatrixtool.com/#
void setup(){
 
  Serial.begin(9600);
①Open links to enter the following page.
  pinMode(light_L_Pin, INPUT);
 
  pinMode(light_R_Pin, INPUT);
<br>[[File:0428-127.png|700px|frameless|thumb]]<br>
  pinMode(ML_Ctrl, OUTPUT);
 
  pinMode(ML_PWM, OUTPUT);
②The dot matrix is 8*16 in this project, so set the height to 8, width to 16, as shown below.
  pinMode(MR_Ctrl, OUTPUT);
 
  pinMode(MR_PWM, OUTPUT);
<br>[[File:0428-128.png|700px|frameless|thumb]]<br>
}
 
void loop(){
③ Generate hexadecimal data from the pattern
  left_light = analogRead(light_L_Pin);
As shown below, press the left mouse button to select, the right button to cancel, draw the pattern you want, click Generate, and the hexadecimal data we need will be produced.
  right_light = analogRead(light_R_Pin);
 
  Serial.print("left_light_value = ");
<br>[[File:0428-129.png|700px|frameless|thumb]]<br>
  Serial.println(left_light);
 
  Serial.print("right_light_value = ");
 
  Serial.println(right_light);
(5)Connection Diagram
  if (left_light > 650 && right_light > 650) //the value detected photo resistor,go front
 
  {
<br>[[File:0428-130.png|700px|frameless|thumb]]<br>
    Car_front();
 
  }
 
  else if (left_light > 650 && right_light <= 650) //the value detected photo resistor,turn left
Wiring note: The GND, VCC, SDA, and SCL of the 8x16 LED panel are respectively connected to -(GND), + (VCC), A4 and A5 of the keyestudio sensor expansion board for two-wire serial communication. (Note: This pin is connected to arduino IIC, but this module is not IIC communication, it can be linked with any two pins.)
  {
 
    Car_left();
 
  }
(6)Test Code
   else if (left_light <= 650 && right_light > 650) //the value detected photo resistor,turn right
 
   {
The code that shows smile face
    Car_right();
 
   }
<pre>
   else  //other situations, stop
/*
   {
keyestudio Mini Tank Robot v2.0
    Car_Stop();
lesson 9.1
  }
Matrix  face
http://www.keyestudio.com
*/
//the data of smiley from modulus tool
unsigned char smile[] = {0x00, 0x00, 0x1c, 0x02, 0x02, 0x02, 0x5c, 0x40, 0x40, 0x5c, 0x02, 0x02, 0x02, 0x1c, 0x00, 0x00};
 
#define SCL_Pin  A5 //Set clock pin to A5
#define SDA_Pin  A4  //Set data pin to A4
 
void setup(){
   //Set pin to output
   pinMode(SCL_Pin,OUTPUT);
   pinMode(SDA_Pin,OUTPUT);
   //clear the display
   //matrix_display(clear);
}
}
void loop(){
void Car_front()
  matrix_display(smile);  // display smile face
}
// the function for dot matrix display
void matrix_display(unsigned char matrix_value[])
{
{
   IIC_start(); // use the function of the data transmission start condition
   digitalWrite(MR_Ctrl,LOW);
   IIC_send(0xc0); //select address
   analogWrite(MR_PWM,200);
 
   digitalWrite(ML_Ctrl,LOW);
   for(int i = 0;i < 16;i++) //pattern data has 16 bits
   analogWrite(ML_PWM,200);
  {
    IIC_send(matrix_value[i]); //convey the pattern data
  }
 
   IIC_end();  //end the transmission of pattern data 
  IIC_start();
  IIC_send(0x8A);  //display control, set pulse width to 4/16 s
  IIC_end();
}
}
 
void Car_left()
//the condition to start conveying data
void IIC_start()
{
{
   digitalWrite(SCL_Pin,HIGH);
   digitalWrite(MR_Ctrl,LOW);
   delayMicroseconds(3);
   analogWrite(MR_PWM,200);
   digitalWrite(SDA_Pin,HIGH);
   digitalWrite(ML_Ctrl,HIGH);
   delayMicroseconds(3);
   analogWrite(ML_PWM,200);
  digitalWrite(SDA_Pin,LOW);
  delayMicroseconds(3);
}
}
//Convey data
void Car_right()
void IIC_send(unsigned char send_data)
{
{
   for(char i = 0;i < 8;i++)  //Each byte has 8 bits 8bit for every character
   digitalWrite(MR_Ctrl,HIGH);
  {
  analogWrite(MR_PWM,200);
      digitalWrite(SCL_Pin,LOW); // pull down clock pin SCL_Pin to change the signal of SDA
  digitalWrite(ML_Ctrl,LOW);
      delayMicroseconds(3);
  analogWrite(ML_PWM,200);
      if(send_data & 0x01)  //set high and low level of SDA_Pin according to 1 or 0 of every bit
      {
        digitalWrite(SDA_Pin,HIGH);
      }
      else
      {
        digitalWrite(SDA_Pin,LOW);
      }
      delayMicroseconds(3);
      digitalWrite(SCL_Pin,HIGH); //pull up the clock pin SCL_Pin to stop transmission
      delayMicroseconds(3);
      send_data = send_data >> 1;  // detect bit by bit, shift the data to the right by one
  }
}
}
 
void Car_Stop()
//The sign of ending data transmission
void IIC_end()
{
{
   digitalWrite(SCL_Pin,LOW);
   digitalWrite(MR_Ctrl,LOW);
   delayMicroseconds(3);
   analogWrite(MR_PWM,0);
   digitalWrite(SDA_Pin,LOW);
   digitalWrite(ML_Ctrl,LOW);
   delayMicroseconds(3);
   analogWrite(ML_PWM,0);
  digitalWrite(SCL_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,HIGH);
  delayMicroseconds(3);
}
}
//******************************************************
//****************************************************************
 
</pre>
</pre>


(7)Test Result
(4)Test Result
Wire according to connection diagram. The DIP switch is dialed to right end and power on, the smile face appears on dot matrix.
<br>[[File:0428-131.png|500px|frameless|thumb]]<br>


Upload code on keyestudio V4.0 development board, DIP switch is dialed to right end and power on, the smart robot follows light to move.


(8)Extension Practice
=== Project 11: Ultrasonic Avoid Tank ===
 
 
[[File:0428-138.png|500px|frameless|thumb]]<br>
 
(1)Description
 
In this program, the ultrasonic sensor detects the distance of obstacle to send signals that control the robot car. Next, let’s show you how to make an obstacle avoidance car. <br>
 
The specific logic of ultrasonic avoiding robot is as shown below:
 
[[File:0428-137.png|500px|frameless|thumb]]<br>
 
(2)Flow chart


We use the modulo tool (http://dotmatrixtool.com/#)to make the dot matrix alternately display start, go front and stop patterns then clear the patterns, the time interval is 2000 milliseconds.
[[File:0428-139.png|500px|frameless|thumb]]<br>
[[File:0428-140.png|500px|frameless|thumb]]<br>


<br>[[File:0428-132.png|500px|frameless|thumb]]<br>
(3)Connection Diagram:


Get the graphical code to be displayed via modulus tool
[[File:04288-25.png|500px|frameless|thumb]]<br>


Start:
Note: “-”、“+” and “S” pins of servo are respectively attached to G(GND), V(VCC)and D9 of expansion board. The VCC, Trig, Echo and Gnd of ultrasonic sensor are linked with 5v(V), 5(S), Echo and Gnd(G) of expansion board.
0x01,0x02,0x04,0x08,0x10,0x20,0x40,0x80,0x80,0x40,0x20,0x10,0x08,0x04,0x02,0x01
Go front:
0x00,0x00,0x00,0x00,0x00,0x24,0x12,0x09,0x12,0x24,0x00,0x00,0x00,0x00,0x00,0x00
Go back:
0x00,0x00,0x00,0x00,0x00,0x24,0x48,0x90,0x48,0x24,0x00,0x00,0x00,0x00,0x00,0x00
Turn left:
0x00,0x00,0x00,0x00,0x00,0x00,0x44,0x28,0x10,0x44,0x28,0x10,0x44,0x28,0x10,0x00
Turn left:
0x00,0x10,0x28,0x44,0x10,0x28,0x44,0x10,0x28,0x44,0x00,0x00,0x00,0x00,0x00,0x00
Stop:
0x2E,0x2A,0x3A,0x00,0x02,0x3E,0x02,0x00,0x3E,0x22,0x3E,0x00,0x3E,0x0A,0x0E,0x00
Clear the displayed code:0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00


The code that the multiple patterns shift:
(4)Test Code:


<pre>
<pre>
/* keyestudio Mini Tank Robot v2.0
 
  lesson 9.2
/*
  Matrix loop
keyestudio Mini Tank Robot v2.0
  lesson 11
  ultrasonic_avoid_tank
  http://www.keyestudio.com
  http://www.keyestudio.com
*/  
*/
//Array, used to store the data of the pattern, can be calculated by yourself or obtained from the modulus tool
int random2;
unsigned char start01[] =
int a;
{0x01,0x02,0x04,0x08,0x10,0x20,0x40,0x80,0x80,0x40,0x20,0x10,0x08,0x04,0x02,0x01};
int a1;
unsigned char front[] =
int a2;
{0x00,0x00,0x00,0x00,0x00,0x24,0x12,0x09,0x12,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
#define ML_Ctrl 13  //define the direction control pin of left motor
unsigned char back[] =
#define ML_PWM 11  //define PWM control pin of left motor
{0x00,0x00,0x00,0x00,0x00,0x24,0x48,0x90,0x48,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
#define MR_Ctrl 12  //define the direction control pin of right motor
unsigned char left[] =
#define MR_PWM 3  //define PWM control pin of right motor
{0x00,0x00,0x00,0x00,0x00,0x00,0x44,0x28,0x10,0x44,0x28,0x10,0x44,0x28,0x10,0x00};
 
unsigned char right[] =
#define Trig 5  //ultrasonic trig Pin
{0x00,0x10,0x28,0x44,0x10,0x28,0x44,0x10,0x28,0x44,0x00,0x00,0x00,0x00,0x00,0x00};
#define Echo 4 //ultrasonic echo Pin
unsigned char STOP01[] =
int distance;
{0x2E,0x2A,0x3A,0x00,0x02,0x3E,0x02,0x00,0x3E,0x22,0x3E,0x00,0x3E,0x0A,0x0E,0x00};
#define servoPin 9 //servo Pin
unsigned char clear[] =
int pulsewidth;
{0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00};
/************the function to run motor**************/
#define SCL_Pin  A5 //Set clock pin to A5
void Car_front()
#define SDA_Pin  A4 //Set data pin to A4
{
void setup(){
   digitalWrite(MR_Ctrl,LOW);
   //Set pins to output
  analogWrite(MR_PWM,200);
   pinMode(SCL_Pin,OUTPUT);
  digitalWrite(ML_Ctrl,LOW);
   pinMode(SDA_Pin,OUTPUT);
  analogWrite(ML_PWM,200);
   //Clear the display
}
   matrix_display(clear);
void Car_back()
{
   digitalWrite(MR_Ctrl,HIGH);
   analogWrite(MR_PWM,200);
   digitalWrite(ML_Ctrl,HIGH);
   analogWrite(ML_PWM,200);
}
}
void loop(){
void Car_left()
  matrix_display(start01);  // Display start pattern
  delay(2000);
  matrix_display(front);    //Front pattern
  delay(2000);
  matrix_display(STOP01);  //Stop pattern
  delay(2000);
  matrix_display(clear);    //Clear the display Clear the screen
  delay(2000);
}
// This function is used to display of dot matrix
void matrix_display(unsigned char matrix_value[])
{
{
   IIC_start(); //call the function that data transmission start  IIC_send(0xc0);  //Choose address
   digitalWrite(MR_Ctrl,LOW);
    
   analogWrite(MR_PWM,255);
  for(int i = 0;i < 16;i++) //pattern data has 16 bits
   digitalWrite(ML_Ctrl,HIGH);
  {
   analogWrite(ML_PWM,255);
    IIC_send(matrix_value[i]); //data to convey patterns
  }
   IIC_end();  //end the transmission of pattern dataEnd
  IIC_start();
   IIC_send(0x8A);  //display control, set pulse width to 4/16
  IIC_end();
}
}
//The condition starting to transmit data
void Car_right()
void IIC_start()
{
{
   digitalWrite(SCL_Pin,HIGH);
   digitalWrite(MR_Ctrl,HIGH);
   delayMicroseconds(3);
   analogWrite(MR_PWM,255);
  digitalWrite(SDA_Pin,HIGH);
   digitalWrite(ML_Ctrl,LOW);
  delayMicroseconds(3);
   analogWrite(ML_PWM,255);
   digitalWrite(SDA_Pin,LOW);
   delayMicroseconds(3);
}
}
//Convey data
void Car_Stop()
void IIC_send(unsigned char send_data)
{
{
   for(char i = 0;i < 8;i++)  //Each byte has 8 bits
   digitalWrite(MR_Ctrl,LOW);
   {
  analogWrite(MR_PWM,0);
      digitalWrite(SCL_Pin,LOW); //pull down clock pin SCL Pin to change the signals of SDA     
   digitalWrite(ML_Ctrl,LOW);
delayMicroseconds(3);
  analogWrite(ML_PWM,0);
      if(send_data & 0x01)  //set high and low level of SDA_Pin according to 1 or 0 of every bit
}
      {
 
        digitalWrite(SDA_Pin,HIGH);
//The function to control servo
      }
void procedure(int myangle) {
      else
  for (int i = 0; i <= 50; i = i + (1)) {
      {
    pulsewidth = myangle * 11 + 500;
        digitalWrite(SDA_Pin,LOW);
    digitalWrite(servoPin,HIGH);
      }
    delayMicroseconds(pulsewidth);
      delayMicroseconds(3);
    digitalWrite(servoPin,LOW);
      digitalWrite(SCL_Pin,HIGH); //pull up clock pin SCL_Pin to stop transmitting data
    delay((20 - pulsewidth / 1000));
      delayMicroseconds(3);
   }
      send_data = send_data >> 1;  //detect bit by bit, so shift the data right by one
}
   }}
//The function to control ultrasonic sensor
//The sign that data transmission ends
float checkdistance() {
void IIC_end()
   digitalWrite(Trig, LOW);
{
   delayMicroseconds(2);
   digitalWrite(SCL_Pin,LOW);
   digitalWrite(Trig, HIGH);
   delayMicroseconds(3);
   delayMicroseconds(10);
   digitalWrite(SDA_Pin,LOW);
   digitalWrite(Trig, LOW);
   delayMicroseconds(3);
   float distance = pulseIn(Echo, HIGH) / 58.00; //58.20, that is, 2*29.1=58.2
   digitalWrite(SCL_Pin,HIGH);
   delay(10);
   delayMicroseconds(3);
   return distance;
   digitalWrite(SDA_Pin,HIGH);
}
   delayMicroseconds(3);}  
  //****************************************************************
//*****************************************************
void setup(){
</pre>
  pinMode(servoPin, OUTPUT);
 
  procedure(90); //set servo to 90°
Upload code on development board, 8*16 dot matrix display go front and back and stop patterns, alternately.
 
<br>[[File:0428-117.png|400px|frameless|thumb]][[File:0428-118.png|400px|frameless|thumb]][[File:0428-119.png|400px|frameless|thumb]]<br>
 
=== Project 10: Light Follow Robot ===
 
(1)Description
 
[[File:0428-137.png|500px|frameless|thumb]]<br>
 
We’ve introduce how to use various sensors, modules.
In this lesson, we combine with hardware knowledge -- photoresistor module, motor driving, to build a light-following robot!
Just need to use 2 photoresistor modules to detect the light intensity at the both side of robot. Read the analog value to rotate the 2 motors, thus drive the tank robot run.
 
 
The specific logic of light following robot is shown as the table below:
 
[[File:0428-133.png|500px|frameless|thumb]]<br>
 
[[File:0428-134.png|500px|frameless|thumb]]<br>
 
We make a flow chart based on the above logic table, as shown below:
 
(2)Connection Diagram
 
[[File:0428-135.png|500px|frameless|thumb]]<br>
 
Hook-up Attention:
The 4Pin terminal block is marked with silkscreen 1234. The red line of right rear motor is connected to terminal 1, black line is linked with end 2. The red line of left front motor is attached to terminal 3, black line is linked with port 4.
 
 
[[File:0428-136.png|500px|frameless|thumb]]<br>
 
 
(3)Test Code
 
<pre>
    
    
/*
   pinMode(Trig, OUTPUT);
keyestudio Mini Tank Robot v2.0
   pinMode(Echo, INPUT);
lesson 10
   pinMode(ML_Ctrl, OUTPUT);
Light-following tank
http://www.keyestudio.com
*/
#define light_L_Pin A1  //define the pin of left photo resistor
#define light_R_Pin A2  //define the pin of right photo resistor
#define ML_Ctrl 13  //define the direction control pin of left motor
#define ML_PWM 11  //define the PWM control pin of left motor
#define MR_Ctrl 12  //define the direction control pin of right motor
#define MR_PWM 3  //define the PWM control pin of right motor
int left_light;
int right_light;
void setup(){
  Serial.begin(9600);
   pinMode(light_L_Pin, INPUT);
   pinMode(light_R_Pin, INPUT);
   pinMode(ML_Ctrl, OUTPUT);
   pinMode(ML_PWM, OUTPUT);
   pinMode(ML_PWM, OUTPUT);
   pinMode(MR_Ctrl, OUTPUT);
   pinMode(MR_Ctrl, OUTPUT);
Line 1,960: Line 2,077:
}
}
void loop(){
void loop(){
   left_light = analogRead(light_L_Pin);
   random2 = random(1, 100);
   right_light = analogRead(light_R_Pin);
   a = checkdistance(); //assign the front distance detected by ultrasonic sensor to variable a
  Serial.print("left_light_value = ");
    
  Serial.println(left_light);
   if (a < 20) //when the front distance detected is less than 20
  Serial.print("right_light_value = ");
  Serial.println(right_light);
  if (left_light > 650 && right_light > 650) //the value detected photo resistor,go front
  { 
    Car_front();
   }
   else if (left_light > 650 && right_light <= 650) //the value detected photo resistor,turn left
   {
   {
    Car_left();
      Car_Stop();  //robot stops
  }
      delay(500); //delay in 500ms
  else if (left_light <= 650 && right_light > 650) //the value detected photo resistor,turn right
      procedure(160);  //Ultrasonic platform turns left
  {
      for (int j = 1; j <= 10; j = j + (1)) { //for statement, the data will be more accurate if ultrasonic sensor detect a few times.
    Car_right();
        a1 = checkdistance()//assign the left distance detected by ultrasonic sensor to variable a1
  }  
      }
  else //other situations, stop
      delay(300);
  {
      procedure(20); //Ultrasonic platform turns right
    Car_Stop();
      for (int k = 1; k <= 10; k = k + (1)) {
  }
        a2 = checkdistance(); //assign the right distance detected by ultrasonic sensor to variable a2
}
      }
void Car_front()
     
{
      if (a1 < 50 || a2 < 50) //robot will turn to the longer distance side when left or right distance is less than 50cm.
  digitalWrite(MR_Ctrl,LOW);
      {
  analogWrite(MR_PWM,200);
        if (a1 > a2) //left distance is greater than right side     
  digitalWrite(ML_Ctrl,LOW);
        {
  analogWrite(ML_PWM,200);
          procedure(90); //Ultrasonic platform turns back to right ahead       
}
Car_left();  //robot turns left
void Car_left()
          delay(500);  //turn left for 500ms
{
          Car_front(); //go front
  digitalWrite(MR_Ctrl,LOW);
        }
  analogWrite(MR_PWM,200);
        else
  digitalWrite(ML_Ctrl,HIGH);
        {
   analogWrite(ML_PWM,200);
          procedure(90);
          Car_right(); //robot turns right
          delay(500);
          Car_front(); //go front
        }
      }  
      else  //If both side is greater than or equal to 50cm, turn left or right randomly
      {
        if ((long) (random2) % (long) (2) == 0)  //When the random number is even
        {
          procedure(90);
          Car_left(); //tank robot turns left
          delay(500);
          Car_front(); //go front
        }
        else
        {
          procedure(90);
          Car_right(); //robot turns right
          delay(500);
          Car_front(); //go front
      }
    }
  }
   else  //If the front distance is greater than or equal to 20cm, robot car will go front
  {
      Car_front(); //go front
  }
}
}
void Car_right()
   //****************************************************************
{
 
  digitalWrite(MR_Ctrl,HIGH);
  analogWrite(MR_PWM,200);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,200);
}
void Car_Stop()
{
  digitalWrite(MR_Ctrl,LOW);
   analogWrite(MR_PWM,0);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,0);
}
//****************************************************************
</pre>
</pre>


(4)Test Result


Upload code on keyestudio V4.0 development board, DIP switch is dialed to right end and power on, the smart robot follows light to move.
(5)Test Result
 
Upload code successfully, DIP switch is dialed to right end and power on, tank robot goes forward. It can automatically avoid barrier.


=== Project 11: Ultrasonic Avoid Tank ===  
=== Project 12: Ultrasonic Follow Tank ===  
 


[[File:0428-138.png|500px|frameless|thumb]]<br>


(1)Description
(1)Description
In this program, the ultrasonic sensor detects the distance of obstacle to send signals that control the robot car. Next, let’s show you how to make an obstacle avoidance car.


The specific logic of ultrasonic avoiding robot is as shown below:
[[File:0428-143.png|500px|frameless|thumb]]<br>
 
In project 11, we made an obstacle avoidance car. In fact, we only need to alter a test code to transform an obstacle avoidance car into following car. In this lesson, we will make an ultrasonic follow robot. The ultrasonic sensor detects the distance between smart car and the obstacle to drive tank car to move.
 
The specific logic of ultrasonic follow robot is as shown below:


[[File:0428-137.png|500px|frameless|thumb]]<br>
[[File:0428-144.png|500px|frameless|thumb]]<br>


(2)Flow chart
(2)Flow chart


[[File:0428-139.png|500px|frameless|thumb]]<br>
[[File:0428-146.png|500px|frameless|thumb]]<br>
[[File:0428-140.png|500px|frameless|thumb]]<br>


(3)Connection Diagram:
(3)Connection Diagram


[[File:0428-141.png|500px|frameless|thumb]]<br>
[[File:04288-26.png|500px|frameless|thumb]]<br>


Note: “-”、“+” and “S” pins of servo are respectively attached to G(GND), V(VCC)and D9 of expansion board. The VCC, Trig, Echo and Gnd of ultrasonic sensor are linked with 5v(V), 5(S), Echo and Gnd(G) of expansion board.
Wire-up note:


(4)Test Code:
[[File:0428-145.png|500px|frameless|thumb]]<br>
 
(4)Test Code


<pre>
<pre>
 
/*
/*
  keyestudio Mini Tank Robot v2.0
  keyestudio Mini Tank Robot v2.0
  lesson 11
  lesson 12
  ultrasonic_avoid_tank
  ultrasonic follow tank
  http://www.keyestudio.com
  http://www.keyestudio.com
*/
*/  
int random2;
//Array, used to store the data of the pattern, can be calculated by yourself or obtained from the modulus tool
int a;
unsigned char start01[] = {0x01,0x02,0x04,0x08,0x10,0x20,0x40,0x80,0x80,0x40,0x20,0x10,0x08,0x04,0x02,0x01};
int a1;
unsigned char front[] = {0x00,0x00,0x00,0x00,0x00,0x24,0x12,0x09,0x12,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
int a2;
unsigned char back[] = {0x00,0x00,0x00,0x00,0x00,0x24,0x48,0x90,0x48,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
unsigned char left[] = {0x00,0x00,0x00,0x00,0x00,0x00,0x44,0x28,0x10,0x44,0x28,0x10,0x44,0x28,0x10,0x00};
unsigned char right[] = {0x00,0x10,0x28,0x44,0x10,0x28,0x44,0x10,0x28,0x44,0x00,0x00,0x00,0x00,0x00,0x00};
unsigned char STOP01[] = {0x2E,0x2A,0x3A,0x00,0x02,0x3E,0x02,0x00,0x3E,0x22,0x3E,0x00,0x3E,0x0A,0x0E,0x00};
unsigned char clear[] = {0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00};
#define SCL_Pin  A5  //Set clock pin to A5
#define SDA_Pin  A4  //Set data pin to A4
 
#define ML_Ctrl 13  //define the direction control pin of left motor
#define ML_Ctrl 13  //define the direction control pin of left motor
#define ML_PWM 11  //define PWM control pin of left motor
#define ML_PWM 11  //define PWM control pin of left motor
#define MR_Ctrl 12  //define the direction control pin of right motor
#define MR_Ctrl 12  //define the direction control pin of right motor
#define MR_PWM 3  //define PWM control pin of right motor
#define MR_PWM 3  //define PWM control pin of right motor
#define Trig 5  //ultrasonic trig Pin
#define Trig 5  //ultrasonic trig Pin
#define Echo 4  //ultrasonic echo Pin
#define Echo 4  //ultrasonic echo Pin
int distance;
int distance;
int pulsewidth;
#define servoPin 9  //servo Pin
#define servoPin 9  //servo Pin
int pulsewidth;
void setup(){
/************the function to run motor**************/
  Serial.begin(9600);
void Car_front()
  pinMode(SCL_Pin,OUTPUT);
{
  pinMode(SDA_Pin,OUTPUT);
  matrix_display(clear); //Clear the display
  matrix_display(start01);  //display start pattern
  pinMode(servoPin, OUTPUT);
  procedure(90); //set servo to 90°
  pinMode(Trig, OUTPUT);
  pinMode(Echo, INPUT);
  pinMode(ML_Ctrl, OUTPUT);
  pinMode(ML_PWM, OUTPUT);
  pinMode(MR_Ctrl, OUTPUT);
  pinMode(MR_PWM, OUTPUT);
}
void loop(){
  distance = checkdistance();  //assign the distance detected by ultrasonic sensor to distance
  if (distance >= 20 && distance <= 60) //range to go front
  {
    Car_front();
  }
  else if (distance > 10 && distance < 20)  //range to stop
  {
    Car_Stop();
  }
  else if (distance <= 10)  //range to go back
  {
    Car_back();
  }
  else  //other situations, stop
  {
    Car_Stop();
  }
}
/***********the function for motor running****************/
void Car_front()
{
   digitalWrite(MR_Ctrl,LOW);
   digitalWrite(MR_Ctrl,LOW);
   analogWrite(MR_PWM,200);
   analogWrite(MR_PWM,200);
Line 2,083: Line 2,249:
{
{
   digitalWrite(MR_Ctrl,LOW);
   digitalWrite(MR_Ctrl,LOW);
   analogWrite(MR_PWM,255);
   analogWrite(MR_PWM,200);
   digitalWrite(ML_Ctrl,HIGH);
   digitalWrite(ML_Ctrl,HIGH);
   analogWrite(ML_PWM,255);
   analogWrite(ML_PWM,200);
}
}
void Car_right()
void Car_right()
{
{
   digitalWrite(MR_Ctrl,HIGH);
   digitalWrite(MR_Ctrl,HIGH);
   analogWrite(MR_PWM,255);
   analogWrite(MR_PWM,200);
   digitalWrite(ML_Ctrl,LOW);
   digitalWrite(ML_Ctrl,LOW);
   analogWrite(ML_PWM,255);
   analogWrite(ML_PWM,200);
}
}
void Car_Stop()
void Car_Stop()
Line 2,102: Line 2,268:
}
}


//The function to control servo
/******************dot matrix********************/
void procedure(int myangle) {
// the function for dot matrix display
   for (int i = 0; i <= 50; i = i + (1)) {
void matrix_display(unsigned char matrix_value[])
    pulsewidth = myangle * 11 + 500;
{
    digitalWrite(servoPin,HIGH);
  IIC_start(); // call the function that data transmission start
    delayMicroseconds(pulsewidth);
  IIC_send(0xc0);  //Choose address
    digitalWrite(servoPin,LOW);
 
    delay((20 - pulsewidth / 1000));
   for(int i = 0;i < 16;i++) //pattern data has 16 bits
  {
    IIC_send(matrix_value[i]); //data to convey patterns
   }
   }
  IIC_end();  //end to convey data pattern
 
  IIC_start();
  IIC_send(0x8A);  //select pulse width4/16, control display
  IIC_end();
}
}
//The function to control ultrasonic sensor
 
float checkdistance() {
//The condition starting to transmit data
   digitalWrite(Trig, LOW);
void IIC_start()
   delayMicroseconds(2);
{
   digitalWrite(Trig, HIGH);
   digitalWrite(SCL_Pin,HIGH);
   delayMicroseconds(10);
   delayMicroseconds(3);
   digitalWrite(Trig, LOW);
   digitalWrite(SDA_Pin,HIGH);
   float distance = pulseIn(Echo, HIGH) / 58.00;  //58.20, that is, 2*29.1=58.2
   delayMicroseconds(3);
  delay(10);
   digitalWrite(SDA_Pin,LOW);
  return distance;
   delayMicroseconds(3);
}
}
  //****************************************************************
 
void setup(){
// transmit data
  pinMode(servoPin, OUTPUT);
void IIC_send(unsigned char send_data)
  procedure(90); //set servo to 90°
{
 
   for(char i = 0;i < 8;i++) //Each byte has 8 bits
  pinMode(Trig, OUTPUT);
  pinMode(Echo, INPUT);
  pinMode(ML_Ctrl, OUTPUT);
  pinMode(ML_PWM, OUTPUT);
  pinMode(MR_Ctrl, OUTPUT);
  pinMode(MR_PWM, OUTPUT);
}
void loop(){
   random2 = random(1, 100);
  a = checkdistance(); //assign the front distance detected by ultrasonic sensor to variable a
 
  if (a < 20) //when the front distance detected is less than 20
   {
   {
       Car_Stop();  //robot stops
       digitalWrite(SCL_Pin,LOW);  //pull down clock pin SCL Pin to change the signals of SDA     
      delay(500); //delay in 500ms
delayMicroseconds(3);
       procedure(160); //Ultrasonic platform turns left
       if(send_data & 0x01)  //set high and low level of SDA_Pin according to 1 or 0 of every bit
       for (int j = 1; j <= 10; j = j + (1)) { //for statement, the data will be more accurate if ultrasonic sensor detect a few times.
       {
         a1 = checkdistance(); //assign the left distance detected by ultrasonic sensor to variable a1
         digitalWrite(SDA_Pin,HIGH);
       }
       }
       delay(300);
       else
      procedure(20); //Ultrasonic platform turns right
       {
       for (int k = 1; k <= 10; k = k + (1)) {
         digitalWrite(SDA_Pin,LOW);
         a2 = checkdistance(); //assign the right distance detected by ultrasonic sensor to variable a2
       }
       }
        
       delayMicroseconds(3);
      if (a1 < 50 || a2 < 50) //robot will turn to the longer distance side when left or right distance is less than 50cm.
       digitalWrite(SCL_Pin,HIGH); //pull up clock pin SCL_Pin to stop transmitting data
       {
      delayMicroseconds(3);
        if (a1 > a2) //left distance is greater than right side     
      send_data = send_data >> 1;  // detect bit by bit, so move the data right by one
        {
  }
          procedure(90); //Ultrasonic platform turns back to right ahead       
}
Car_left(); //robot turns left
//The sign that data transmission ends
          delay(500);  //turn left for 500ms
void IIC_end()
          Car_front(); //go front
{
        }
  digitalWrite(SCL_Pin,LOW);
        else
  delayMicroseconds(3);
        {
  digitalWrite(SDA_Pin,LOW);
          procedure(90);
  delayMicroseconds(3);
          Car_right(); //robot turns right
  digitalWrite(SCL_Pin,HIGH);
          delay(500);
  delayMicroseconds(3);
          Car_front();  //go front
  digitalWrite(SDA_Pin,HIGH);
        }
   delayMicroseconds(3);
      }  
      else  //If both side is greater than or equal to 50cm, turn left or right randomly
      {
        if ((long) (random2) % (long) (2) == 0)  //When the random number is even
        {
          procedure(90);
          Car_left(); //tank robot turns left
          delay(500);
          Car_front(); //go front
        }
        else
        {
          procedure(90);
          Car_right(); //robot turns right
          delay(500);
          Car_front(); //go front
      }
    }
   }
  else  //If the front distance is greater than or equal to 20cm, robot car will go front
  {
      Car_front(); //go front
  }
}
}
   //****************************************************************
/***************end dot matrix display******************/
//The function to control servo
void procedure(int myangle) {
   for (int i = 0; i <= 50; i = i + (1)) {
    pulsewidth = myangle * 11 + 500;
    digitalWrite(servoPin,HIGH);
    delayMicroseconds(pulsewidth);
    digitalWrite(servoPin,LOW);
    delay((20 - pulsewidth / 1000));
  }}
//The function to control ultrasonic sensor function controlling ultrasonic
float checkdistance() {
  digitalWrite(Trig, LOW);
  delayMicroseconds(2);
  digitalWrite(Trig, HIGH);
  delayMicroseconds(10);
  digitalWrite(Trig, LOW);
  float distance = pulseIn(Echo, HIGH) / 58.20;  //58.20, that is , 2*29.1=58.2
  delay(10);
  return distance;
}
//****************************************************************


</pre>
</pre>


(5)Test Result
(5)Test Result


Upload code successfully, DIP switch is dialed to right end and power on, tank robot goes forward. It can automatically avoid barrier.
Upload code successfully, DIP switch is dialed to right end, the servo rotates to 90°, “V” is shown on 8X16 LED panel and smart car moves as the obstacle moves.


=== Project 12: Ultrasonic Follow Tank ===  
=== Project 13: IR Remote Robot Tank ===  


[[File:0428-148.png|500px|frameless|thumb]]<br>


(1)Description
'''(1)Description'''


[[File:0428-143.png|500px|frameless|thumb]]<br>
IR remote control is one of most ubiquitous control, applied in TV, electric fan and some household appliances. In this project, we will make an IR remote smart car. And we’ve known every key value on IR remote control. Thus, we could control smart car via and display the patterns on dot matrix via corresponding key value


In project 11, we made an obstacle avoidance car. In fact, we only need to alter a test code to transform an obstacle avoidance car into following car. In this lesson, we will make an ultrasonic follow robot. The ultrasonic sensor detects the distance between smart car and the obstacle to drive tank car to move.
The specific logic of infrared remote control robot is shown below:


The specific logic of ultrasonic follow robot is as shown below:
[[File:0428-149.png|500px|frameless|thumb]]<br>
[[File:0428-150.png|500px|frameless|thumb]]<br>


[[File:0428-144.png|500px|frameless|thumb]]<br>


(2)Flow chart
'''(2)Flow Chart'''
 
[[File:0428-151.png|500px|frameless|thumb]]<br>
 


[[File:0428-146.png|500px|frameless|thumb]]<br>


(3)Connection Diagram
'''(3)Connection Diagram'''


[[File:0428-147.png|500px|frameless|thumb]]<br>
[[File:04288-27.png|500px|frameless|thumb]]<br>


Wire-up note:
Attention:GND,VCC, SDA, SCL of 8x16 LED panel are respectively linked with -(GND), +(VCC), SDA ,SCL. And “-”、“+” and S of IR receiver module are attached to G(GND), V(VCC) and A0 on sensor shield. On the condition of insufficient digital ports, the analog ports can be treat as digital ports. A0 equals to digital 14, A1 is like digital 15.


[[File:0428-145.png|500px|frameless|thumb]]<br>


(4)Test Code
(4)Test Code


<pre>
<pre>
/*
 
/*
  keyestudio Mini Tank Robot v2.0
  keyestudio Mini Tank Robot v2.0
  lesson 12
  lesson 13
  ultrasonic follow tank
  IR remote tank
  http://www.keyestudio.com
  http://www.keyestudio.com
*/  
*/
 
#include <IRremoteTank.h>
IRrecv irrecv(A0);  //set IRrecv irrecv to A0
decode_results results;
long ir_rec;  //save the IR value received
 
//Array, used to store the data of the pattern, can be calculated by yourself or obtained from the modulus tool
//Array, used to store the data of the pattern, can be calculated by yourself or obtained from the modulus tool
unsigned char start01[] = {0x01,0x02,0x04,0x08,0x10,0x20,0x40,0x80,0x80,0x40,0x20,0x10,0x08,0x04,0x02,0x01};
unsigned char start01[] = {0x01,0x02,0x04,0x08,0x10,0x20,0x40,0x80,0x80,0x40,0x20,0x10,0x08,0x04,0x02,0x01};
Line 2,250: Line 2,417:
#define ML_PWM 11  //define PWM control pin of left motor
#define ML_PWM 11  //define PWM control pin of left motor
#define MR_Ctrl 12  //define the direction control pin of right motor
#define MR_Ctrl 12  //define the direction control pin of right motor
#define MR_PWM 3   //define PWM control pin of right motor
#define MR_PWM 3   //define PWM control pin of right motor
#define Trig 5  //ultrasonic trig Pin
 
#define Echo 4  //ultrasonic echo Pin
#define servoPin 9 //pin of servo
int distance;
int pulsewidth; //save the pulse width value of servo
int pulsewidth;
 
#define servoPin 9  //servo Pin
void setup(){
void setup(){
   Serial.begin(9600);
   Serial.begin(9600);
   pinMode(SCL_Pin,OUTPUT);
   irrecv.enableIRIn(); //Initialize the IR reception library
  pinMode(SDA_Pin,OUTPUT);
    
  matrix_display(clear); //Clear the display
  matrix_display(start01);  //display start pattern
   pinMode(servoPin, OUTPUT);
  procedure(90); //set servo to 90°
  pinMode(Trig, OUTPUT);
  pinMode(Echo, INPUT);
   pinMode(ML_Ctrl, OUTPUT);
   pinMode(ML_Ctrl, OUTPUT);
   pinMode(ML_PWM, OUTPUT);
   pinMode(ML_PWM, OUTPUT);
   pinMode(MR_Ctrl, OUTPUT);
   pinMode(MR_Ctrl, OUTPUT);
   pinMode(MR_PWM, OUTPUT);
   pinMode(MR_PWM, OUTPUT);
 
  pinMode(SCL_Pin,OUTPUT);
  pinMode(SDA_Pin,OUTPUT);
  matrix_display(clear); //Clear Screen
  matrix_display(start01);  //show start picture
 
  pinMode(servoPin, OUTPUT);
  procedure(90);  //Servo rotates to 90°
}
}
void loop(){
void loop(){
   distance = checkdistance();  //assign the distance detected by ultrasonic sensor to distance
   if (irrecv.decode(&results)) //receive the IR remote value
  if (distance >= 20 && distance <= 60) //range to go front
   {
   {
     Car_front();
     ir_rec=results.value;
    String type="UNKNOWN";
    String typelist[14]={"UNKNOWN", "NEC", "SONY", "RC5", "RC6", "DISH", "SHARP", "PANASONIC", "JVC", "SANYO", "MITSUBISHI", "SAMSUNG", "LG", "WHYNTER"};
    if(results.decode_type>=1&&results.decode_type<=13){
      type=typelist[results.decode_type];
    }
    Serial.print("IR TYPE:"+type+"  ");
    Serial.println(ir_rec,HEX);
    irrecv.resume();
   }
   }
   else if (distance > 10 && distance < 20) //range to stop
    
  if (ir_rec == 0xFF629D) //Go forward
   {
   {
     Car_Stop();
     Car_front();
    matrix_display(front);  //Display front image
   }
   }
   else if (distance <= 10)  //range to go back
   if (ir_rec == 0xFFA857)  //Robot car goes back
   {
   {
     Car_back();
     Car_back();
    matrix_display(front);  //Go back
   }
   }
   else  //other situations, stop
   if (ir_rec == 0xFF22DD)  //Robot car turns left
   {
   {
     Car_Stop();
     Car_T_left();
    matrix_display(left);  //Display left-turning image
   }
   }
  if (ir_rec == 0xFFC23D)  //Robot car turns right
  {
    Car_T_right();
    matrix_display(right);  //Display right-turning image
  }
  if (ir_rec == 0xFF02FD)  //Robot car stops
  {
    Car_Stop();
    matrix_display(STOP01);  //show stop image
  }
  if (ir_rec == 0xFF30CF)  //robot car rotates anticlockwise
  {
    Car_left();
    matrix_display(left);  //show anticlockwise rotation picture
  }
  if (ir_rec == 0xFF7A85)  //robot car rotates clockwise
  {
    Car_right();
    matrix_display(right);  //show clockwise rotation picture
}
}
}
/***********the function for motor running****************/
/******************Control Servo*******************/
void Car_front()
void procedure(int myangle) {
{
   for (int i = 0; i <= 50; i = i + (1)) {
   digitalWrite(MR_Ctrl,LOW);
    pulsewidth = myangle * 11 + 500;
  analogWrite(MR_PWM,200);
    digitalWrite(servoPin,HIGH);
  digitalWrite(ML_Ctrl,LOW);
    delayMicroseconds(pulsewidth);
  analogWrite(ML_PWM,200);
    digitalWrite(servoPin,LOW);
}
    delay((20 - pulsewidth / 1000));
void Car_back()
   }
{
  digitalWrite(MR_Ctrl,HIGH);
  analogWrite(MR_PWM,200);
  digitalWrite(ML_Ctrl,HIGH);
   analogWrite(ML_PWM,200);
}
}
void Car_left()
 
/******************Dot Matrix****************/
// this function is used for dot matrix display
void matrix_display(unsigned char matrix_value[])
{
{
  digitalWrite(MR_Ctrl,LOW);
   IIC_start();
  analogWrite(MR_PWM,200);
  digitalWrite(ML_Ctrl,HIGH);
  analogWrite(ML_PWM,200);
}
void Car_right()
{
  digitalWrite(MR_Ctrl,HIGH);
  analogWrite(MR_PWM,200);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,200);
}
void Car_Stop()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,0);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,0);
}
 
/******************dot matrix********************/
// the function for dot matrix display
void matrix_display(unsigned char matrix_value[])
{
   IIC_start(); // call the function that data transmission start
   IIC_send(0xc0);  //Choose address
   IIC_send(0xc0);  //Choose address
 
  for(int i = 0;i < 16;i++) //The picture has 16 bits
  for(int i = 0;i < 16;i++) //pattern data has 16 bits
   {
   {
     IIC_send(matrix_value[i]); //data to convey patterns
     IIC_send(matrix_value[i]); //data to convey patterns
   }
   }
   IIC_end();  //end to convey data pattern
   IIC_end();  //end to convey data pattern
    
    
   IIC_start();
   IIC_start();
   IIC_send(0x8A);  //select pulse width4/16, control display
   IIC_send(0x8A);  //display control, set pulse width to 4/16
   IIC_end();
   IIC_end();
}
}
Line 2,356: Line 2,528:
   delayMicroseconds(3);
   delayMicroseconds(3);
}
}
 
//传输数据
// transmit data
void IIC_send(unsigned char send_data)
void IIC_send(unsigned char send_data)
{
{
   for(char i = 0;i < 8;i++)  //Each byte has 8 bits
   for(char i = 0;i < 8;i++)  //Each byte has 8 bits 8bits for every character
   {
   {
       digitalWrite(SCL_Pin,LOW);  //pull down clock pin SCL Pin to change the signals of SDA       
       digitalWrite(SCL_Pin,LOW);  //pull down clock pin SCL Pin to change the signals of SDA       
delayMicroseconds(3);
      delayMicroseconds(3);
       if(send_data & 0x01)  //set high and low level of SDA_Pin according to 1 or 0 of every bit
       if(send_data & 0x01)  //set high and low level of SDA_Pin according to 1 or 0 of every bit
       {
       {
Line 2,390: Line 2,561:
   delayMicroseconds(3);
   delayMicroseconds(3);
}
}
/***************end dot matrix display******************/
/***************the function to run motor***************/
//The function to control servo
void Car_front()
void procedure(int myangle) {
{
  for (int i = 0; i <= 50; i = i + (1)) {
   digitalWrite(MR_Ctrl,LOW);
    pulsewidth = myangle * 11 + 500;
   analogWrite(MR_PWM,200);
    digitalWrite(servoPin,HIGH);
   digitalWrite(ML_Ctrl,LOW);
    delayMicroseconds(pulsewidth);
   analogWrite(ML_PWM,200);
    digitalWrite(servoPin,LOW);
    delay((20 - pulsewidth / 1000));
  }}
//The function to control ultrasonic sensor function controlling ultrasonic
float checkdistance() {
   digitalWrite(Trig, LOW);
   delayMicroseconds(2);
  digitalWrite(Trig, HIGH);
  delayMicroseconds(10);
   digitalWrite(Trig, LOW);
   float distance = pulseIn(Echo, HIGH) / 58.20;  //58.20, that is , 2*29.1=58.2
  delay(10);
  return distance;
}
}
//****************************************************************
void Car_back()
 
{
</pre>
  digitalWrite(MR_Ctrl,HIGH);
 
  analogWrite(MR_PWM,200);
(5)Test Result
  digitalWrite(ML_Ctrl,HIGH);
 
  analogWrite(ML_PWM,200);
Upload code successfully, DIP switch is dialed to right end, the servo rotates to 90°, “V” is shown on 8X16 LED panel and smart car moves as the obstacle moves.
}
void Car_left()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,255);
  digitalWrite(ML_Ctrl,HIGH);
  analogWrite(ML_PWM,255);
}
void Car_right()
{
  digitalWrite(MR_Ctrl,HIGH);
  analogWrite(MR_PWM,255);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,255);
}
void Car_Stop()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,0);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,0);
}
void Car_T_left()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,255);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,180);
}
void Car_T_right()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,180);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,255);
}
//****************************************************************


=== Project 13: IR Remote Robot Tank ===
</pre>


[[File:0428-148.png|500px|frameless|thumb]]<br>


'''(1)Description'''
(5)Test Result


IR remote control is one of most ubiquitous control, applied in TV, electric fan and some household appliances. In this project, we will make an IR remote smart car. And we’ve known every key value on IR remote control. Thus, we could control smart car via and display the patterns on dot matrix via corresponding key value


The specific logic of infrared remote control robot is shown below:
Upload code successfully and power on, the smart robot can be controlled by IR remote, at same time, the corresponding pattern is shown on 8X16 LED panel.


[[File:0428-149.png|500px|frameless|thumb]]<br>
===Project 14: Bluetooth Control Robot ===
[[File:0428-150.png|500px|frameless|thumb]]<br>


[[File:0428-153.png|500px|frameless|thumb]]<br>


'''(2)Flow Chart'''


[[File:0428-151.png|500px|frameless|thumb]]<br>
(1)Description


We’ve learned the basic knowledge of Bluetooth, in this lesson, we will make a Bluetooth remote smart car. In the experiment, we default the HM-10 Bluetooth module as a Slave and the cellphone as a Host. <br>
keyes BT car is an APP rolled out by keyestudio team. You could control the robot car by it readily.<br>
There is a guide to how to download and install APP in the document as for your reference. The interface is shown below.<br>
<br>


[[File:0428-154.png|500px|frameless|thumb]]<br>


'''(3)Connection Diagram'''


[[File:0428-152.png|500px|frameless|thumb]]<br>
'''APP DOWNLOAD'''


Attention:GND,VCC, SDA, SCL of 8x16 LED panel are respectively linked with -(GND), +(VCC), SDA ,SCL. And “-”、“+” and S of IR receiver module are attached to G(GND), V(VCC) and A0 on sensor shield. On the condition of insufficient digital ports, the analog ports can be treat as digital ports. A0 equals to digital 14, A1 is like digital 15.
https://play.google.com/store/apps/details?id=com.keyestudio.tankcar3




(4)Test Code
(2)Test Code


<pre>
<pre>
Line 2,452: Line 2,647:
/*
/*
  keyestudio Mini Tank Robot v2.0
  keyestudio Mini Tank Robot v2.0
  lesson 13
  lesson 14.1
  IR remote tank
  bluetooth test
  http://www.keyestudio.com
  http://www.keyestudio.com
*/
*/
#include <IRremote.h>
char ble_val; //character variables, used to save the value of Bluetooth reception
IRrecv irrecv(A0);  //set IRrecv irrecv to A0
void setup() {
decode_results results;
  Serial.begin(9600);
long ir_rec;  //save the IR value received
}
void loop() {
  if(Serial.available() > 0)  //judge if there is data in buffer area
  { ble_val = Serial.read();  //read the data from serial buffer
    Serial.println(ble_val);  //print out
  }}
</pre>


//Array, used to store the data of the pattern, can be calculated by yourself or obtained from the modulus tool
 
Pull off the Bluetooth module, upload test code, reconnect Bluetooth module, open serial monitor and set baud rate to 9600. Point at Bluetooth module and press keys on APP, the corresponding character is shown below.
 
 
[[File:Ks0446图片97.png|500px|frameless|thumb]]<br>
 
 
The detected character and corresponding function:
 
[[File:0428-156.png|800px|frameless|thumb]]<br>
 
 
In compliance with the above table, we make a flow chart to assist you to understand well. The flow chart is below:
 
[[File:0428-157.png|700px|frameless|thumb]]<br>
 
(3)Connection Diagram
 
[[File:04288-28.png|500px|frameless|thumb]]<br>
 
 
Wiring Attention:
 
[[File:0428-158.png|500px|frameless|thumb]]<br>
 
(4)Test Code
 
<span style=color:red> <big>Note: Remove the Bluetooth module before uploading test code, otherwise, you will fail to upload test code</big></span>
 
<pre>
/*
keyestudio Robot Car v2.0
lesson 14.2
bluetooth car
http://www.keyestudio.com
*/
 
//Array, used to store the data of pattern, can be calculated by yourself or obtained from the modulus tool
unsigned char start01[] = {0x01,0x02,0x04,0x08,0x10,0x20,0x40,0x80,0x80,0x40,0x20,0x10,0x08,0x04,0x02,0x01};
unsigned char start01[] = {0x01,0x02,0x04,0x08,0x10,0x20,0x40,0x80,0x80,0x40,0x20,0x10,0x08,0x04,0x02,0x01};
unsigned char front[] = {0x00,0x00,0x00,0x00,0x00,0x24,0x12,0x09,0x12,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
unsigned char front[] = {0x00,0x00,0x00,0x00,0x00,0x24,0x12,0x09,0x12,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
Line 2,472: Line 2,710:
#define SDA_Pin  A4  //Set data pin to A4
#define SDA_Pin  A4  //Set data pin to A4


#define ML_Ctrl 13  // define the direction control pin of left motor
#define ML_Ctrl 13  //define direction control pin of left motor
#define ML_PWM 11  //define PWM control pin of left motor
#define ML_PWM 11  //define PWM control pin of left motor
#define MR_Ctrl 12  //define the direction control pin of right motor
#define MR_Ctrl 12  //define direction control pin of right motor
#define MR_PWM 3    //define PWM control pin of right motor
#define MR_PWM 3    //define PWM control pin of right motor


#define servoPin 9 //pin of servo
char bluetooth_val; //save the value of Bluetooth reception
int pulsewidth; // save the pulse width value of servo


void setup(){
void setup(){
   Serial.begin(9600);
   Serial.begin(9600);
  irrecv.enableIRIn();  //Initialize the IR reception library
    
    
  pinMode(SCL_Pin,OUTPUT);
  pinMode(SDA_Pin,OUTPUT);
  matrix_display(clear);    //Clear the display
  matrix_display(start01);  //display start pattern
   pinMode(ML_Ctrl, OUTPUT);
   pinMode(ML_Ctrl, OUTPUT);
   pinMode(ML_PWM, OUTPUT);
   pinMode(ML_PWM, OUTPUT);
   pinMode(MR_Ctrl, OUTPUT);
   pinMode(MR_Ctrl, OUTPUT);
   pinMode(MR_PWM, OUTPUT);
   pinMode(MR_PWM, OUTPUT);
 
  pinMode(SCL_Pin,OUTPUT);
  pinMode(SDA_Pin,OUTPUT);
  matrix_display(clear); //Clear the display
  matrix_display(start01);  //show start pattern
 
  pinMode(servoPin, OUTPUT);
  procedure(90);  //servo rotates to 90°
}
}


void loop(){
void loop(){
   if (irrecv.decode(&results)) //receive the IR remote value
   if (Serial.available())
   {
   {
     ir_rec=results.value;
     bluetooth_val = Serial.read();
    String type="UNKNOWN";
     Serial.println(bluetooth_val);
    String typelist[14]={"UNKNOWN", "NEC", "SONY", "RC5", "RC6", "DISH", "SHARP", "PANASONIC", "JVC", "SANYO", "MITSUBISHI", "SAMSUNG", "LG", "WHYNTER"};
    if(results.decode_type>=1&&results.decode_type<=13){
      type=typelist[results.decode_type];
    }
    Serial.print("IR TYPE:"+type+"  ");
     Serial.println(ir_rec,HEX);
    irrecv.resume();
   }
   }
    
   switch (bluetooth_val)  
  if (ir_rec == 0xFF629D) //forward instruction
   {
   {
    Car_front();
    case 'F':  //forward command
    matrix_display(front);  //display forward sign
        Car_front();
  }
        matrix_display(front);  // show forward design
  if (ir_rec == 0xFFA857)  //back instruction
        break;
  {
    case 'B':  //Back command
    Car_back();
        Car_back();
    matrix_display(front);  //show back pattern
        matrix_display(back); //show back pattern
        break;
    case 'L':  // left-turning instruction
        Car_left();
        matrix_display(left);  //show “left-turning” sign
        break;
    case 'R':  //right-turning instruction
        Car_right();
        matrix_display(right);  //display right-turning sign
      break;
    case 'S':  //stop command
        Car_Stop();
        matrix_display(STOP01);  //show stop picture
        break;
   }
   }
   if (ir_rec == 0xFF22DD)   //left-turning instruction
}
 
/**************The function of dot matrix****************/
//this function is used for dot matrix display
void matrix_display(unsigned char matrix_value[])
{
  IIC_start();
   IIC_send(0xc0);  //Choose address
 
  for(int i = 0;i < 16;i++) //pattern data has 16 bits
   {
   {
    Car_T_left();
    IIC_send(matrix_value[i]); //data to convey patterns
    matrix_display(left);  //display left-turning sign
   }
   }
  if (ir_rec == 0xFFC23D)  //right-turning instruction
   IIC_end();  //end to convey data pattern
  {
    
    Car_T_right();
   IIC_start();
    matrix_display(right);  //display right-turning pattern
   IIC_send(0x8A);  //display control, set pulse width to 4/16
  }
  if (ir_rec == 0xFF02FD)  //stop instruction
  {
    Car_Stop();
    matrix_display(STOP01);  //show stop pattern
  }
  if (ir_rec == 0xFF30CF)  //the command to turn left
  {
    Car_left();
    matrix_display(left);  //display left-turning pattern
  }
  if (ir_rec == 0xFF7A85)  //the command to turn right
 
  {
    Car_right();
    matrix_display(right);  //display right-turning pattern
}
}
/******************The function to control servo***********/
void procedure(int myangle) {
  for (int i = 0; i <= 50; i = i + (1)) {
    pulsewidth = myangle * 11 + 500;
    digitalWrite(servoPin,HIGH);
    delayMicroseconds(pulsewidth);
    digitalWrite(servoPin,LOW);
    delay((20 - pulsewidth / 1000));
  }
}
 
/******************Function for dot matrix***************/
// this function is used for dot matrix display
void matrix_display(unsigned char matrix_value[])
{
  IIC_start();
  IIC_send(0xc0);  //Choose address
  for(int i = 0;i < 16;i++) //pattern data has 16 bits
  {
    IIC_send(matrix_value[i]); //data to convey patterns
  }
   IIC_end();  //end to convey data pattern
    
   IIC_start();
   IIC_send(0x8A);  //display control, set pulse width to 4/16
   IIC_end();
   IIC_end();
}
}
//The condition starting to transmit data
//The condition starting to transmit data
void IIC_start()
void IIC_start()
Line 2,587: Line 2,789:
   delayMicroseconds(3);
   delayMicroseconds(3);
}
}
//convey data
//transmit data
void IIC_send(unsigned char send_data)
void IIC_send(unsigned char send_data)
{
{
   for(char i = 0;i < 8;i++)  //Each byte has 8 bits 8bits for every character
   for(char i = 0;i < 8;i++)  //Each byte has 8 bits
   {
   {
       digitalWrite(SCL_Pin,LOW);  //pull down clock pin SCL Pin to change the signals of SDA       
       digitalWrite(SCL_Pin,LOW);  //pull down clock pin SCL Pin to change the signals of SDA       
delayMicroseconds(3);
      delayMicroseconds(3);
       if(send_data & 0x01)  //set high and low level of SDA_Pin according to 1 or 0 of every bit
       if(send_data & 0x01)  //set high and low level of SDA_Pin according to 1 or 0 of every bit
       {
       {
Line 2,605: Line 2,807:
       digitalWrite(SCL_Pin,HIGH); //pull up clock pin SCL_Pin to stop transmitting data
       digitalWrite(SCL_Pin,HIGH); //pull up clock pin SCL_Pin to stop transmitting data
       delayMicroseconds(3);
       delayMicroseconds(3);
       send_data = send_data >> 1;  // detect bit by bit, so move the data right by one
       send_data = send_data >> 1;  // Detect bit by bit, so move the data right by one
   }
   }
}
}
Line 2,620: Line 2,822:
   delayMicroseconds(3);
   delayMicroseconds(3);
}
}
/***************the function to run motor***************/
/*************the function to run motor**************/
void Car_front()
void Car_front()
{
{
Line 2,670: Line 2,872:
   analogWrite(ML_PWM,255);
   analogWrite(ML_PWM,255);
}
}
  //****************************************************************


</pre>
</pre>


(5)Test Result
(5)Test Result


Upload code successfully, DIP switch is dialed to right end and power on. After connecting Bluetooth, we could drive smart car to move by Bluetooth App.


Upload code successfully and power on, the smart robot can be controlled by IR remote, at same time, the corresponding pattern is shown on 8X16 LED panel.
[[File:0428-160.png|500px|frameless|thumb]]<br>


===Project 14: Bluetooth Control Robot ===  
=== Project 15: Multi-purpose Robot Car ===  


[[File:0428-153.png|500px|frameless|thumb]]<br>
[[File:0428-162.png|500px|frameless|thumb]]<br>




(1)Description
(1)Description


We’ve learned the basic knowledge of Bluetooth, in this lesson, we will make a Bluetooth remote smart car. In the experiment, we default the HM-10 Bluetooth module as a Slave and the cellphone as a Host.  
In previous projects, the tank car only performs single function, however, in this lesson, we integrate all of function to control smart car via Bluetooth control.
keyes BT car is an APP rolled out by keyestudio team. You could control the robot car by it readily.
Here is a simple flow chart of multi-purpose robot car as for your reference.
There is a guide to how to download and install APP in the document as for your reference. The interface is shown below.


[[File:0428-163.png|500px|frameless|thumb]]<br>


[[File:0428-154.png|500px|frameless|thumb]]<br>
(2)Connection Diagram
 
[[File:04288-29.png|800px|frameless|thumb]]<br>
 
Attention:Confirm that every component is connected.
 
Wire-up Guide:


[[File:0428-165.png|500px|frameless|thumb]]<br>


[[File:0428-166.png|500px|frameless|thumb]]<br>


(2)Test Code
[[File:0428-167.png|500px|frameless|thumb]]<br>


<pre>
[[File:0428-173.png|500px|frameless|thumb]]<br>


/*
keyestudio Mini Tank Robot v2.0
lesson 14.1
bluetooth test
http://www.keyestudio.com
*/
char ble_val; //character variables, used to save the value of Bluetooth reception
void setup() {
  Serial.begin(9600);
}
void loop() {
  if(Serial.available() > 0)  //judge if there is data in buffer area
  { ble_val = Serial.read();  //read the data from serial buffer
    Serial.println(ble_val);  //print out
  }}
</pre>




Pull off the Bluetooth module, upload test code, reconnect Bluetooth module, open serial monitor and set baud rate to 9600. Point at Bluetooth module and press keys on APP, the corresponding character is shown below.
[[File:0428-174.png|500px|frameless|thumb]]<br>


[[File:0428-175.png|500px|frameless|thumb]]<br>


[[File:Ks0446图片97.png|500px|frameless|thumb]]<br>
[[File:0428-176.png|500px|frameless|thumb]]<br>




The detected character and corresponding function:


[[File:0428-156.png|800px|frameless|thumb]]<br>




In compliance with the above table, we make a flow chart to assist you to understand well. The flow chart is below:
(3)Test Code


[[File:0428-157.png|700px|frameless|thumb]]<br>
<pre>
    /*
keyestudio Mini Tank Robot v2.0
lesson 15
multiple functions
http://www.keyestudio.com
*/


(3)Connection Diagram
//Array, used to store the data of the pattern, can be calculated by yourself or obtained from the modulus tool
 
unsigned char start01[] = {0x01,0x02,0x04,0x08,0x10,0x20,0x40,0x80,0x80,0x40,0x20,0x10,0x08,0x04,0x02,0x01};
[[File:0428-161.png|500px|frameless|thumb]]<br>
unsigned char front[] = {0x00,0x00,0x00,0x00,0x00,0x24,0x12,0x09,0x12,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
 
unsigned char back[] = {0x00,0x00,0x00,0x00,0x00,0x24,0x48,0x90,0x48,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
 
Wiring Attention:
 
[[File:0428-158.png|500px|frameless|thumb]]<br>
 
 
 
(4)Test Code
 
Note: Remove the Bluetooth module before uploading test code, otherwise, you will fail to upload test code
 
<pre>
/*
keyestudio Robot Car v2.0
lesson 14.2
bluetooth car
http://www.keyestudio.com
*/
 
//Array, used to store the data of pattern, can be calculated by yourself or obtained from the modulus tool
unsigned char start01[] = {0x01,0x02,0x04,0x08,0x10,0x20,0x40,0x80,0x80,0x40,0x20,0x10,0x08,0x04,0x02,0x01};
unsigned char front[] = {0x00,0x00,0x00,0x00,0x00,0x24,0x12,0x09,0x12,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
unsigned char back[] = {0x00,0x00,0x00,0x00,0x00,0x24,0x48,0x90,0x48,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
unsigned char left[] = {0x00,0x00,0x00,0x00,0x00,0x00,0x44,0x28,0x10,0x44,0x28,0x10,0x44,0x28,0x10,0x00};
unsigned char left[] = {0x00,0x00,0x00,0x00,0x00,0x00,0x44,0x28,0x10,0x44,0x28,0x10,0x44,0x28,0x10,0x00};
unsigned char right[] = {0x00,0x10,0x28,0x44,0x10,0x28,0x44,0x10,0x28,0x44,0x00,0x00,0x00,0x00,0x00,0x00};
unsigned char right[] = {0x00,0x10,0x28,0x44,0x10,0x28,0x44,0x10,0x28,0x44,0x00,0x00,0x00,0x00,0x00,0x00};
Line 2,769: Line 2,947:
#define ML_PWM 11  //define PWM control pin of left motor
#define ML_PWM 11  //define PWM control pin of left motor
#define MR_Ctrl 12  //define direction control pin of right motor
#define MR_Ctrl 12  //define direction control pin of right motor
#define MR_PWM 3   //define PWM control pin of right motor
#define MR_PWM 3   //define PWM control pin of right motor
 
#define Trig 5  //ultrasonic trig Pin
#define Echo 4  //ultrasonic echo Pin
int distance; //save the distance value detected by ultrasonic, follow function
int random2; //save the variable of random numberssave the variable of random numbers
//save the distance value detected by ultrasonic, obstacle avoidance function
int a; 
int a1;
int a2;


char bluetooth_val; //save the value of Bluetooth reception
#define servoPin 9  //servo Pin
int pulsewidth;


void setup(){
#define light_L_Pin A1   //define the pin of left photo resistor sensor
  Serial.begin(9600);
#define light_R_Pin A2   //define the pin of right photo resistor sensor
    
int left_light;
   pinMode(SCL_Pin,OUTPUT);
int right_light;
  pinMode(SDA_Pin,OUTPUT);
  matrix_display(clear);    //Clear the display
  matrix_display(start01); //display start pattern


char bluetooth_val; //save the value of Bluetooth reception
int flag;  //flag variable, it is used to entry and exist function
void setup(){
  Serial.begin(9600);
  pinMode(Trig, OUTPUT);
  pinMode(Echo, INPUT);
   pinMode(ML_Ctrl, OUTPUT);
   pinMode(ML_Ctrl, OUTPUT);
   pinMode(ML_PWM, OUTPUT);
   pinMode(ML_PWM, OUTPUT);
   pinMode(MR_Ctrl, OUTPUT);
   pinMode(MR_Ctrl, OUTPUT);
   pinMode(MR_PWM, OUTPUT);
   pinMode(MR_PWM, OUTPUT);
 
  pinMode(servoPin, OUTPUT);
  procedure(90); //set servo to 90°
pinMode(SCL_Pin,OUTPUT);
  pinMode(SDA_Pin,OUTPUT);
  matrix_display(clear);    //Clear the display
  matrix_display(start01);  //display start pattern
  pinMode(light_L_Pin, INPUT);
  pinMode(light_R_Pin, INPUT);
}
}


Line 2,795: Line 2,995:
   switch (bluetooth_val)  
   switch (bluetooth_val)  
   {
   {
    case 'F':  //forward command
    case 'F':  //Forward instruction
        Car_front();
      Car_front();
        matrix_display(front);  // show forward design
      matrix_display(front);  //display forward pattern
        break;
      break;
    case 'B':  //Back command
    case 'B':  //Back instruction
        Car_back();
      Car_back();
        matrix_display(back);  //show back pattern
      matrix_display(back);  // display back pattern
        break;
      break;
    case 'L':  // left-turning instruction
    case 'L':  //left-turning instruction
        Car_left();
      Car_left();
        matrix_display(left);  //show “left-turning” sign
      matrix_display(left);  //show left-turning pattern
        break;
      break;
    case 'R':  //right-turning instruction
    case 'R':  //right-turning instruction
        Car_right();
      Car_right();
        matrix_display(right);  //display right-turning sign       break;
      matrix_display(right);  //show right-turning pattern
    case 'S':  //stop command
       break;
        Car_Stop();
    case 'S':  //stop instruction
        matrix_display(STOP01);  //show stop picture
      Car_Stop();
        break;
      matrix_display(STOP01);  //display stop pattern
  }
      break;
}
  case 'Y':
 
      matrix_display(start01);  //show start pattern
/**************The function of dot matrix****************/
      follow();
//this function is used for dot matrix display
      break;
void matrix_display(unsigned char matrix_value[])
  case 'U':
{
      matrix_display(start01); //show start pattern
  IIC_start();
      avoid();
  IIC_send(0xc0); //Choose address
      break;
 
  case 'X':
  for(int i = 0;i < 16;i++) //pattern data has 16 bits
      matrix_display(start01); //show start pattern
  {
      light_track();
    IIC_send(matrix_value[i]); //data to convey patterns
      break;
  }
   }}
  IIC_end();   //end to convey data pattern
/*****************Obstacle Avoidance Function**************/
 
void avoid()  
  IIC_start();
  IIC_send(0x8A); //display control, set pulse width to 4/16
   IIC_end();
}
//The condition starting to transmit data
void IIC_start()
{
{
   digitalWrite(SCL_Pin,HIGH);
   flag = 0; //the design that enter obstacle avoidance function
  delayMicroseconds(3);
   while (flag == 0)  
  digitalWrite(SDA_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,LOW);
  delayMicroseconds(3);
}
//transmit data
void IIC_send(unsigned char send_data)
{
   for(char i = 0;i < 8;i++) //Each byte has 8 bits
   {
   {
      digitalWrite(SCL_Pin,LOW);  //pull down clock pin SCL Pin to change the signals of SDA      delayMicroseconds(3);
    random2 = random(1, 100);
       if(send_data & 0x01)  //set high and low level of SDA_Pin according to 1 or 0 of every bit
    a = checkdistance();  //assign the front distance detected by ultrasonic sensor to variable a
       {
   
         digitalWrite(SDA_Pin,HIGH);
    if (a < 20) //when the front distance detected is less than 20cm
    {
      Car_Stop();  //robot stops
      delay(200); //delay in 200ms
        
      procedure(160);  //Ultrasonic platform turns left
      for (int j = 1; j <= 10; j = j + (1)) { ///for statement, the data will be more accurate if ultrasonic sensor detect a few times.
        a1 = checkdistance(); //assign the left distance detected by ultrasonic sensor to variable a1
      }
      delay(200);
      procedure(20); //Ultrasonic platform turns right
       for (int k = 1; k <= 10; k = k + (1)) {
         a2 = checkdistance(); //assign the right distance detected by ultrasonic sensor to variable a2
       }
       }
       else
       if (a1 < 50 || a2 < 50)  //robot will turn to the longer distance side when left or right distance is less than 50cm.if the left or right distance is less than 50cm, the robot will turn to the greater distance
       {
       {
         digitalWrite(SDA_Pin,LOW);
         if (a1 > a2) //left distance is greater than right
      }
        {
      delayMicroseconds(3);
          procedure(90);  //Ultrasonic platform turns back to right ahead ultrasonic platform turns front
      digitalWrite(SCL_Pin,HIGH); //pull up clock pin SCL_Pin to stop transmitting data
          Car_left();  //robot turns left
      delayMicroseconds(3);
          delay(500);  //turn left 500ms
       send_data = send_data >> 1; // Detect bit by bit, so move the data right by one
          Car_front(); //go forward
  }
        }  
}
        else
//The sign that data transmission ends
        {
void IIC_end()
          procedure(90);
{
          Car_right(); //robot turns right
  digitalWrite(SCL_Pin,LOW);
          delay(500);
  delayMicroseconds(3);
          Car_front(); //go forward
  digitalWrite(SDA_Pin,LOW);
        }
  delayMicroseconds(3);
       }
   digitalWrite(SCL_Pin,HIGH);
      else  //both distance on two side is greater than or equal to 50cm, turn randomly
   delayMicroseconds(3);
      {
   digitalWrite(SDA_Pin,HIGH);
        if ((long) (random2) % (long) (2) == 0) //when the random number is even
  delayMicroseconds(3);
        {
}
          procedure(90);
/*************the function to run motor**************/
          Car_left(); //robot turns left
void Car_front()
          delay(500);
{
          Car_front(); //go forward
   digitalWrite(MR_Ctrl,LOW);
        }
   analogWrite(MR_PWM,200);
        else
  digitalWrite(ML_Ctrl,LOW);
        {
  analogWrite(ML_PWM,200);
          procedure(90);
}
          Car_right(); //robot turns right
void Car_back()
          delay(500);
{
          Car_front(); ///go forward
  digitalWrite(MR_Ctrl,HIGH);
      } } }
  analogWrite(MR_PWM,200);
   else  //If the front distance is greater than or equal to 20cm, robot car will go front
  digitalWrite(ML_Ctrl,HIGH);
  {
  analogWrite(ML_PWM,200);
      Car_front(); //go forward
}
   }
void Car_left()
  // receive the Bluetooth value to end the obstacle avoidance function
{
  if (Serial.available())
  digitalWrite(MR_Ctrl,LOW);
   {
  analogWrite(MR_PWM,255);
    bluetooth_val = Serial.read();
  digitalWrite(ML_Ctrl,HIGH);
    if (bluetooth_val == 'S') //receive S
  analogWrite(ML_PWM,255);
    {
}
      flag = 1; //when assign 1 to flag, end loop
void Car_right()
    }}}}
{
/*******************Follow****************/
  digitalWrite(MR_Ctrl,HIGH);
void follow() {
  analogWrite(MR_PWM,255);
   flag = 0;
  digitalWrite(ML_Ctrl,LOW);
   while (flag == 0) {
  analogWrite(ML_PWM,255);
    distance = checkdistance(); //assign the distance detected by ultrasonic sensor to distance
}
    if (distance >= 20 && distance <= 60) //the range to go front
void Car_Stop()
    {
{
      Car_front();
  digitalWrite(MR_Ctrl,LOW);
    }
  analogWrite(MR_PWM,0);
    else if (distance > 10 && distance < 20) //the range to stop
  digitalWrite(ML_Ctrl,LOW);
    {
  analogWrite(ML_PWM,0);
      Car_Stop();
}
    }
void Car_T_left()
    else if (distance <= 10) // the range to go back
{
    {
   digitalWrite(MR_Ctrl,LOW);
      Car_back();
   analogWrite(MR_PWM,255);
    }
   digitalWrite(ML_Ctrl,LOW);
    else  //other situations, stop
   analogWrite(ML_PWM,180);
    {
}
      Car_Stop();
void Car_T_right()
    }
{
    if (Serial.available())
   digitalWrite(MR_Ctrl,LOW);
    {
   analogWrite(MR_PWM,180);
      bluetooth_val = Serial.read();
   digitalWrite(ML_Ctrl,LOW);
      if (bluetooth_val == 'S')  
   analogWrite(ML_PWM,255);
      {
        flag = 1; //end loop
      }}}}
//The function to control ultrasonic sensor the function controlling ultrasonic sensor
float checkdistance() {
   digitalWrite(Trig, LOW);
   delayMicroseconds(2);
   digitalWrite(Trig, HIGH);
   delayMicroseconds(10);
   digitalWrite(Trig, LOW);
   float distance = pulseIn(Echo, HIGH) / 58.00; //58.20 means 2*29.1=58.2
   delay(10);
   return distance;
}
}
//The function to control servo the function controlling servo
void procedure(int myangle) {
  for (int i = 0; i <= 50; i = i + (1)) {
    pulsewidth = myangle * 11 + 500;
    digitalWrite(servoPin,HIGH);
    delayMicroseconds(pulsewidth);
    digitalWrite(servoPin,LOW);
    delay((20 - pulsewidth / 1000));
  }}


</pre>
/****************Light Follow******************/
 
void light_track() {
(5)Test Result
  flag = 0;
 
  while (flag == 0) {
Upload code successfully, DIP switch is dialed to right end and power on. After connecting Bluetooth, we could drive smart car to move by Bluetooth App.
    left_light = analogRead(light_L_Pin);
 
    right_light = analogRead(light_R_Pin);
[[File:0428-160.png|500px|frameless|thumb]]<br>
    if (left_light > 650 && right_light > 650) //the value detected by photo resistor, go forward
 
    { 
=== Project 15: Multi-purpose Robot Car ===  
      Car_front();
    }
 
    else if (left_light > 650 && right_light <= 650)  //the value detected by photo resistor, turn left
[[File:0428-162.png|500px|frameless|thumb]]<br>
    {
 
      Car_left();
 
    }
(1)Description
    else if (left_light <= 650 && right_light > 650) //the value detected by photo resistor, turn right
 
    {
In previous projects, the tank car only performs single function, however, in this lesson, we integrate all of function to control smart car via Bluetooth control.
      Car_right();
Here is a simple flow chart of multi-purpose robot car as for your reference.
    }
 
    else  //other situations, stop
[[File:0428-163.png|500px|frameless|thumb]]<br>
    {
 
      Car_Stop();
(2)Connection Diagram
    }
 
    if (Serial.available())
[[File:0428-164.png|800px|frameless|thumb]]<br>
    {
 
      bluetooth_val = Serial.read();
Attention:Confirm that every component is connected.
      if (bluetooth_val == 'S') {
 
        flag = 1;
Wire-up Guide:
    }}}}
 
/***************Dot Matrix *****************/
[[File:0428-165.png|500px|frameless|thumb]]<br>
// this function is used for dot matrix display
 
void matrix_display(unsigned char matrix_value[])
[[File:0428-166.png|500px|frameless|thumb]]<br>
{
 
  IIC_start();
[[File:0428-167.png|500px|frameless|thumb]]<br>
  IIC_send(0xc0);  //Choose address
 
 
[[File:0428-173.png|500px|frameless|thumb]]<br>
  for(int i = 0;i < 16;i++) //pattern data has 16 bits
 
  {
 
    IIC_send(matrix_value[i]); //convey the pattern data
 
  }
[[File:0428-174.png|500px|frameless|thumb]]<br>
  IIC_end();  //end the transmission of pattern data
 
  IIC_start();
[[File:0428-175.png|500px|frameless|thumb]]<br>
  IIC_send(0x8A); //display control, set pulse width to 4/16
 
  IIC_end();
[[File:0428-176.png|500px|frameless|thumb]]<br>
}
 
//The condition starting to transmit data
 
void IIC_start()
 
{
 
  digitalWrite(SCL_Pin,HIGH);
 
  delayMicroseconds(3);
(3)Test Code
  digitalWrite(SDA_Pin,HIGH);
 
  delayMicroseconds(3);
<pre>
  digitalWrite(SDA_Pin,LOW);
  /*
  delayMicroseconds(3);
keyestudio Mini Tank Robot v2.0
}
lesson 15
//convey data
multiple functions
void IIC_send(unsigned char send_data)
  http://www.keyestudio.com
{
*/
  for(char i = 0;i < 8;i++) //each byte has 8 bits
 
   {
//Array, used to store the data of the pattern, can be calculated by yourself or obtained from the modulus tool
      digitalWrite(SCL_Pin,LOW); //pull down clock pin SCL Pin to change the signals of SDA
unsigned char start01[] = {0x01,0x02,0x04,0x08,0x10,0x20,0x40,0x80,0x80,0x40,0x20,0x10,0x08,0x04,0x02,0x01};
      delayMicroseconds(3);
unsigned char front[] = {0x00,0x00,0x00,0x00,0x00,0x24,0x12,0x09,0x12,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
      if(send_data & 0x01)  //set high and low level of SDA_Pin according to 1 or 0 of every bit
unsigned char back[] = {0x00,0x00,0x00,0x00,0x00,0x24,0x48,0x90,0x48,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
      {
unsigned char left[] = {0x00,0x00,0x00,0x00,0x00,0x00,0x44,0x28,0x10,0x44,0x28,0x10,0x44,0x28,0x10,0x00};
        digitalWrite(SDA_Pin,HIGH);
unsigned char right[] = {0x00,0x10,0x28,0x44,0x10,0x28,0x44,0x10,0x28,0x44,0x00,0x00,0x00,0x00,0x00,0x00};
      }
unsigned char STOP01[] = {0x2E,0x2A,0x3A,0x00,0x02,0x3E,0x02,0x00,0x3E,0x22,0x3E,0x00,0x3E,0x0A,0x0E,0x00};
      else
unsigned char clear[] = {0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00};
      {
#define SCL_Pin  A5  //Set clock pin to A5
        digitalWrite(SDA_Pin,LOW);
#define SDA_Pin  A4  //Set data pin to A4
      }
 
      delayMicroseconds(3);
#define ML_Ctrl 13 //define direction control pin of left motor
      digitalWrite(SCL_Pin,HIGH); //pull up clock pin SCL_Pin to stop transmitting data
#define ML_PWM 11   //define PWM control pin of left motor
      delayMicroseconds(3);
#define MR_Ctrl 12 //define direction control pin of right motor
      send_data = send_data >> 1;  // detect bit by bit, so move the data right by one
#define MR_PWM 3   //define PWM control pin of right motor
   }}
 
//The sign that data transmission ends
#define Trig 5  //ultrasonic trig Pin
void IIC_end()
#define Echo 4  //ultrasonic echo Pin
{
int distance; //save the distance value detected by ultrasonic, follow function
  digitalWrite(SCL_Pin,LOW);
int random2; //save the variable of random numberssave the variable of random numbers
  delayMicroseconds(3);
//save the distance value detected by ultrasonic, obstacle avoidance function
  digitalWrite(SDA_Pin,LOW);
int a; 
  delayMicroseconds(3);
int a1;
  digitalWrite(SCL_Pin,HIGH);
int a2;
   delayMicroseconds(3);
 
   digitalWrite(SDA_Pin,HIGH);
#define servoPin 9  //servo Pin
   delayMicroseconds(3);
int pulsewidth;
}
 
/*************the function to run motor*************/
#define light_L_Pin A1  //define the pin of left photo resistor sensor
void Car_front()
#define light_R_Pin A2   //define the pin of right photo resistor sensor
{
int left_light;
   digitalWrite(MR_Ctrl,LOW);
int right_light;
   analogWrite(MR_PWM,200);
 
   digitalWrite(ML_Ctrl,LOW);
char bluetooth_val; //save the value of Bluetooth reception
   analogWrite(ML_PWM,200);
int flag; //flag variable, it is used to entry and exist function
}
void setup(){
void Car_back()
   Serial.begin(9600);
{
   pinMode(Trig, OUTPUT);
   digitalWrite(MR_Ctrl,HIGH);
   pinMode(Echo, INPUT);
   analogWrite(MR_PWM,200);
   pinMode(ML_Ctrl, OUTPUT);
  digitalWrite(ML_Ctrl,HIGH);
   pinMode(ML_PWM, OUTPUT);
   analogWrite(ML_PWM,200);
   pinMode(MR_Ctrl, OUTPUT);
}
   pinMode(MR_PWM, OUTPUT);
void Car_left()
 
{
   pinMode(servoPin, OUTPUT);
   digitalWrite(MR_Ctrl,LOW);
   procedure(90); //set servo to 90°
   analogWrite(MR_PWM,255);
pinMode(SCL_Pin,OUTPUT);
   digitalWrite(ML_Ctrl,HIGH);
   pinMode(SDA_Pin,OUTPUT);
   analogWrite(ML_PWM,255);
   matrix_display(clear);   //Clear the display
   matrix_display(start01); //display start pattern
   pinMode(light_L_Pin, INPUT);
   pinMode(light_R_Pin, INPUT);
}
}
 
void Car_right()
void loop(){
{
  if (Serial.available())
   digitalWrite(MR_Ctrl,HIGH);
  {
    bluetooth_val = Serial.read();
    Serial.println(bluetooth_val);
  }
  switch (bluetooth_val)
  {
    case 'F':  //Forward instruction
      Car_front();
      matrix_display(front);  //display forward pattern
      break;
    case 'B':  //Back instruction
      Car_back();
      matrix_display(back);  // display back pattern
      break;
    case 'L':  //left-turning instruction
      Car_left();
      matrix_display(left);  //show left-turning pattern
      break;
    case 'R':  //right-turning instruction
      Car_right();
      matrix_display(right);  //show right-turning pattern
      break;
    case 'S':  //stop instruction
      Car_Stop();
      matrix_display(STOP01);  //display stop pattern
      break;
  case 'Y':
      matrix_display(start01);  //show start pattern
      follow();
      break;
  case 'U':
      matrix_display(start01);  //show start pattern
      avoid();
      break;
  case 'X':
      matrix_display(start01);  //show start pattern
      light_track();
      break;
  }}
/*****************Obstacle Avoidance Function**************/
void avoid()
{
  flag = 0;  //the design that enter obstacle avoidance function
  while (flag == 0)
  {
    random2 = random(1, 100);
    a = checkdistance();  //assign the front distance detected by ultrasonic sensor to variable a
   
    if (a < 20) //when the front distance detected is less than 20cm
    {
      Car_Stop();  //robot stops
      delay(200); //delay in 200ms
     
      procedure(160);  //Ultrasonic platform turns left
      for (int j = 1; j <= 10; j = j + (1)) { ///for statement, the data will be more accurate if ultrasonic sensor detect a few times.
        a1 = checkdistance();  //assign the left distance detected by ultrasonic sensor to variable a1
      }
      delay(200);
      procedure(20); //Ultrasonic platform turns right
      for (int k = 1; k <= 10; k = k + (1)) {
        a2 = checkdistance(); //assign the right distance detected by ultrasonic sensor to variable a2
      }
      if (a1 < 50 || a2 < 50)  //robot will turn to the longer distance side when left or right distance is less than 50cm.if the left or right distance is less than 50cm, the robot will turn to the greater distance
      {
        if (a1 > a2) //left distance is greater than right
        {
          procedure(90);  //Ultrasonic platform turns back to right ahead ultrasonic platform turns front
          Car_left();  //robot turns left
          delay(500);  //turn left 500ms
          Car_front(); //go forward
        }
        else
        {
          procedure(90);
          Car_right(); //robot turns right
          delay(500);
          Car_front();  //go forward
        }
      }
      else  //both distance on two side is greater than or equal to 50cm, turn randomly
      {
        if ((long) (random2) % (long) (2) == 0)  //when the random number is even
        {
          procedure(90);
          Car_left(); //robot turns left
          delay(500);
          Car_front(); //go forward
        }
        else
        {
          procedure(90);
          Car_right(); //robot turns right
          delay(500);
          Car_front(); ///go forward
      } } }
  else  //If the front distance is greater than or equal to 20cm, robot car will go front
  {
      Car_front(); //go forward
  }
  // receive the Bluetooth value to end the obstacle avoidance function
  if (Serial.available())
  {
    bluetooth_val = Serial.read();
    if (bluetooth_val == 'S')  //receive S
    {
      flag = 1;  //when assign 1 to flag, end loop
    }}}}
/*******************Follow****************/
void follow() {
  flag = 0;
  while (flag == 0) {
    distance = checkdistance();  //assign the distance detected by ultrasonic sensor to distance
    if (distance >= 20 && distance <= 60) //the range to go front
    {
      Car_front();
    }
    else if (distance > 10 && distance < 20)  //the range to stop
    {
      Car_Stop();
    }
    else if (distance <= 10)  // the range to go back
    {
      Car_back();
    }
    else  //other situations, stop
    {
      Car_Stop();
    }
    if (Serial.available())
    {
      bluetooth_val = Serial.read();
      if (bluetooth_val == 'S')
      {
        flag = 1;  //end loop
      }}}}
//The function to control ultrasonic sensor the function controlling ultrasonic sensor
float checkdistance() {
  digitalWrite(Trig, LOW);
  delayMicroseconds(2);
  digitalWrite(Trig, HIGH);
  delayMicroseconds(10);
  digitalWrite(Trig, LOW);
  float distance = pulseIn(Echo, HIGH) / 58.00;  //58.20 means 2*29.1=58.2
  delay(10);
  return distance;
}
//The function to control servo the function controlling servo
void procedure(int myangle) {
  for (int i = 0; i <= 50; i = i + (1)) {
    pulsewidth = myangle * 11 + 500;
    digitalWrite(servoPin,HIGH);
    delayMicroseconds(pulsewidth);
    digitalWrite(servoPin,LOW);
    delay((20 - pulsewidth / 1000));
  }}
 
/****************Light Follow******************/
void light_track() {
  flag = 0;
  while (flag == 0) {
    left_light = analogRead(light_L_Pin);
    right_light = analogRead(light_R_Pin);
    if (left_light > 650 && right_light > 650) //the value detected by photo resistor, go forward
    { 
      Car_front();
    }
    else if (left_light > 650 && right_light <= 650)  //the value detected by photo resistor, turn left
    {
      Car_left();
    }
    else if (left_light <= 650 && right_light > 650) //the value detected by photo resistor, turn right
    {
      Car_right();
    }
    else  //other situations, stop
    {
      Car_Stop();
    }
    if (Serial.available())
    {
      bluetooth_val = Serial.read();
      if (bluetooth_val == 'S') {
        flag = 1;
    }}}}
/***************Dot Matrix *****************/
// this function is used for dot matrix display
void matrix_display(unsigned char matrix_value[])
{
  IIC_start();
  IIC_send(0xc0);  //Choose address
 
  for(int i = 0;i < 16;i++) //pattern data has 16 bits
  {
    IIC_send(matrix_value[i]); //convey the pattern data
  }
  IIC_end();  //end the transmission of pattern data
  IIC_start();
  IIC_send(0x8A);  //display control, set pulse width to 4/16
  IIC_end();
}
//The condition starting to transmit data
void IIC_start()
{
  digitalWrite(SCL_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,LOW);
  delayMicroseconds(3);
}
//convey data
void IIC_send(unsigned char send_data)
{
  for(char i = 0;i < 8;i++)  //each byte has 8 bits
  {
      digitalWrite(SCL_Pin,LOW);  //pull down clock pin SCL Pin to change the signals of SDA      delayMicroseconds(3);
      if(send_data & 0x01)  //set high and low level of SDA_Pin according to 1 or 0 of every bit
      {
        digitalWrite(SDA_Pin,HIGH);
      }
      else
      {
        digitalWrite(SDA_Pin,LOW);
      }
      delayMicroseconds(3);
      digitalWrite(SCL_Pin,HIGH); //pull up clock pin SCL_Pin to stop transmitting data
      delayMicroseconds(3);
      send_data = send_data >> 1;  // detect bit by bit, so move the data right by one
  }}
//The sign that data transmission ends
void IIC_end()
{
  digitalWrite(SCL_Pin,LOW);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,LOW);
  delayMicroseconds(3);
  digitalWrite(SCL_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,HIGH);
  delayMicroseconds(3);
}
/*************the function to run motor*************/
void Car_front()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,200);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,200);
}
void Car_back()
{
  digitalWrite(MR_Ctrl,HIGH);
  analogWrite(MR_PWM,200);
  digitalWrite(ML_Ctrl,HIGH);
  analogWrite(ML_PWM,200);
}
void Car_left()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,255);
  digitalWrite(ML_Ctrl,HIGH);
  analogWrite(ML_PWM,255);
}
void Car_right()
{
   digitalWrite(MR_Ctrl,HIGH);
   analogWrite(MR_PWM,255);
   analogWrite(MR_PWM,255);
   digitalWrite(ML_Ctrl,LOW);
   digitalWrite(ML_Ctrl,LOW);
Line 3,333: Line 3,281:
   analogWrite(ML_PWM,255);
   analogWrite(ML_PWM,255);
}
}


</pre>
</pre>
Line 3,347: Line 3,296:
== 9. Resources ==   
== 9. Resources ==   
                                            
                                            
Wiki page: https://wiki.keyestudio.com/Main_Page<br>
Wiki page:https://wiki.keyestudio.com/Ks0428_keyestudio_Mini_Tank_Robot_V2


Official website: https://keyestudio.com/<br>
Official website: https://keyestudio.com/<br>
Assembly Video Link: http://video.keyestudio.com/ks0428/<br>
Assembly Video Link: http://video.keyestudio.com/ks0428/<br>


If you want to try with Mixly software, enter https://fs.keyestudio.com/KS0428 please to try.<br>
If you want to try with Mixly software, enter https://fs.keyestudio.com/KS0428.<br>

Latest revision as of 11:17, 17 June 2024

Thanks for your support on our products, we will continue to provide you better quality and service!

*About keyestudio

Keyestudio is a best-selling brand owned by KEYES Corporation, our product lines range from controller boards, shields and sensor modules to smart car and complete starter kits for Arduino, Raspberry Pi and BBC micro:bit, which designed for customers of any level to learn electronics and programming knowledge. All of our products comply with international quality standards and are greatly appreciated in a variety of different markets throughout the world.
You can obtain the details and the latest information through visiting the following web sites:http://www.keyestudio.com

*References and After-sales Service

1.Download Profile:https://fs.keyestudio.com/KS0428
2.Feel free to contact us please, if there is missing part or you encounter some troubles. Welcome to send email to us:service@keyestudio.com.
We will update projects and products continuously based on your sincere advice.

*Warning

1.This product contains tiny parts(screws, copper pillars), keep it out of reach of children under 7 years old please.
2. This product contains conductive parts (control board and electronic module). Please operate according to the requirements of this tutorial. Improper operation may cause overheating and damage parts. Do not touch and immediately disconnect the circuit power.


*Copyright

The keyestudio trademark and logo are the copyright of KEYES DIY ROBOT co.,LTD. All products under keyestudio brand can’t be copied, sold and resold without authorization by anyone or company. If you’re interested in our items, please contact to our sales representatives: fennie@keyestudio.com


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Introduction

Nowadays, technological education such as VR, kids programming, and artificial intelligence, has become mainstream in educational industry. Thereby, people attach importance to STEAM education. Arduino is pretty notable in Maker education.

So what is Arduino? Arduino is an open-source electronics platform based on easy-to-use hardware and software. Arduino boards are able to read inputs - light on a sensor, a finger on a button, or a Twitter message - and turn it into an output - activating a motor, turning on an LED, publishing something online. Based on this, Keyestudio team has designed a mini tank robot. The tank robot has a processor which is programmable using the Arduino IDE, to mapped its pins to sensors and actuators by a shield that plug in the processor, it reads sensors and controls the actuators and decides how to operate.

15 learning projects, from simple to complex, will guide you how to make a smart tank robot on you own and introduce the detailed knowledge about sensors and modules.
Simultaneously, it is the best choice if you intend to obtain a DIY robot for learning programming, entertainment and competition requirement.


Features

1.Multi-purpose: Obstacle avoidance, follow, IR remote control, Bluetooth control, light following, ultrasonic follow and displayed face emoticons.
2.Simple assembly: No soldering circuit required, complete assembly easily.
3. High Tenacity:Aluminum alloy bracket, metal motors, high quality wheels and tracks.
4. High extension: expand other sensors and modules through motor driver shield and sensor shield
5. Multiple controls: IR remote control, App control(IOS and Android system)
6.Basic programming:C language code of Arduino IDE.

Specification

  • Working voltage: 5v
  • Input voltage: 7-12V
  • Maximum output current: 2A
  • Maximum power dissipation: 25W (T=75℃)
  • Motor speed: 5V 200 rpm/min
  • Motor drive mode: dual H bridge drive (L298P)
  • Ultrasonic induction angle: <15 degrees
  • Ultrasonic detection distance: 2cm-400cm
  • Infrared remote control distance: 10 meters (measured)
  • Bluetooth remote control distance: 50 meters (measured)

Product List

Make sure no any parts missing please when you get this robot kit. And if it is, please feel free to contact us.

Please tear off the protective film on the acrylic board before mounting the kit
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QQ图片20210422152554.png|

Assembly Guide

Note: Remove the Bluetooth module before uploading test code, otherwise, you will fail to upload test code

Note: Peel the plastic film off the board first when installing the smart car. To be honest, we never intend to send wood to you.

After making an inventory all the parts in this kit, then we need to mount the tank robot. Let’s install smart car in compliance with the following instructions.

Step 1: Install Bottom Motor

Prepare the parts as follows:

  • M4 Nut * 2
  • Metal Motor *2
  • Metal Holder *2
  • Copper Coupler *2
  • Blue Supportive Parts *2
  • M4*12MM Inner Hex Screw * 2
  • M1.5 Hex Key Nickel Plated Allen Wrench *1
  • M3 Hex Key Nickel Plated Allen Wrench *1
  • M2.5 Hex Key Nickel Plated Allen Wrench *1
  • M3*8MM Inner Hex Screw * 4


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Step 2: Install Driver Wheel

Prepare the parts as follows:

  • M4*12MM Inner Hex Screw * 2
  • M4*50MM Inner Hex Screw * 2
  • Tank Load-bearing Wheel * 2
  • Flange Bearing * 4
  • Copper Bush *2
  • Caterpillar Band *2
  • M4 Self-locking Nut * 2
  • M3 Hex Key Nickel Plated Allen Wrench *1


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Step 3: Install the Battery Holder

Prepare the parts as follows:


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  • Battery Holder *1
  • M3 Nut * 2
  • Blue Metal holder *2
  • M4 Nut *8
  • M3*10MM Flat Head Screw * 2
  • M4*40MM Inner Hex Screw *4
  • M2.5 Hex Key Nickel Plated Allen Wrench*1
  • M3 Hex Key Nickel Plated Allen Wrench *1
  • M3*25MM Inner Hex Screw *4

Finish the mount process. Go to fix the metal holder on the motor wheel with four M4*40MM inner hex screws and four M4 nuts.
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Step 4: Mount Acrylic Board and Sensors

  • Acrylic Board * 2
  • L- type Black Bracket *1
  • Photocell Sensor *2
  • IR Receiver Module *1
  • 8X16 LED Panel *1
  • M2 Nut *4
  • M3 Nut *10
  • M3*6MM Inner Hex Screw * 8
  • M2.5 Hex Key Allen Wrench *1
  • M3*12MM Round Head Screw *7
  • M3*10MM Hexagon Copper Bush *8
  • M2*10MM Round Head Screw * 4


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Step 5: Install the Servo Platform

Prepare the parts as follows:

  • Servo *1
  • Black Gimbal *1
  • Cable Tie *2
  • M2x8 Round Head Cross Tapping Screw *2
  • Ultrasonic Sensor *1
  • M2*4 Screw *1
  • M1.2*5 Screw *4


Note: for convenient debugging, keep the ultrasonic module straight ahead and the angle of servo motor 90°. Therefore, we need to set servo to 90° before installing the servo platform.


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You can find M1.2*5 Screws inside the bag of Plastic Platform.


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Step 6: Install Sensors and Boards

Prepare the parts as follows:

  • M3*6MM Round Head Screw *12
  • L298P Shield *1
  • V4.0 Board *1
  • V5 Sensor Shield *1
  • Screwdriver *1
  • Bluetooth Module *1


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Step 7: Hook-up Guide


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Step 8: Wire up LED Panel


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Step 9: install all parts of Acrylic plate
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Step 10: Final Renderings


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Note: Remove the Bluetooth module before uploading test code, otherwise, you will fail to upload test code.

Install Arduino IDE and Driver

Download software

When we get control board, we need to download Arduino IDE and driver firstly. You could download Arduino IDE from the official website: https://www.arduino.cc/, click the SOFTWARE on the browse bar, click “DOWNLOADS” to enter download page, as shown below:


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There are various versions for Arduino, just download a suitable version for your system, we will take WINDOWS system as an example to show you how to download and install.


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There are two versions for WINDOWS system, one is installed version, another one is download version, you just need to download file to computer directly and unzip it. These two versions can be used normally. Choose one and download on your computer.


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You just need to click JUST DOWNLOAD, then click the downloaded file to install it. And when the ZIP file is downloaded, you can directly unzip and start it.

Keyestudio V4.0 Development Board

We need to know keyestudio V4.0 development board, as a core of this smart car.


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keyestudio V4.0 development board is an Arduino uno-compatible board, which is based on ATmega328P MCU, and with a cp2102 Chip as a UART-to-USB converter.  


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It has 14 digital input/output pins (of which 6 can be used as PWM outputs), 6 analog inputs, a 16 MHz quartz crystal, a USB connection, a power jack, 2 ICSP headers and a reset button.


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It contains everything needed to support the microcontroller; simply connect it to a computer with a USB cable or power it via an external DC power jack (DC 7-12V) or via female headers Vin/ GND(DC 7-12V) to get started.


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Installing driver

Let’s install the driver of keyestudio PLUS control board. The USB-TTL chip on PLUS board adopts CP2102 serial chip. The driver program of this chip is included in Arduino 1.8 version and above, which is convenient. Plug on USB port of board, the computer can recognize the hardware and automatically install the driver of CP2102.

If install unsuccessfully, or you intend to install manually, open the device manager of computer. Right click Computer----- Properties----- Device Manager.


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There is a yellow exclamation mark on the page, which implies installing the driver of CP2102 unsuccessfully. Then we double click the hardware and update the driver.


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Click “OK” to enter the following page, click “browse my computer for updated driver software”, find out the installed or downloaded ARDUINO software. As shown below:


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There is a DRIVERS folder in Arduino software installed package(thumb), open driver folder and you can see the driver of CP210X series chips.


We click “Browse”, then find out the driver folder, or you could enter “driver” to search in rectangular box, then click “next”, the driver will be installed successfully. (I place Arduino software folder on the desktop, you could follow my way)


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Open device manager, we will find the yellow exclamation mark disappear. The driver of CP2102 is installed successfully.
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Install other visions of driver

If your development board is Arduino UNO board, install the driver as follows:
Step 1: Plug in the development board, click Computer----- Properties----- Device Manager, you could see the unknown device is shown.


0428---100.png

Step 2: Update the driver


0428---101.png

Step 3: click“browse my computer for updated driver software”


0428---102.png
Step 4: find out the folder where the ARDUINO software is installed, click drivers folder and tap“Next”
0428---103.png

Step 5: the driver is installed successfully.


0428---104.png

The device manager shows the serial port of Arduino.
0428---105.png


Arduino IDE Setting

Click0486-12.png icon,open Arduino IDE.
0085=14.png

To avoid the errors when uploading the program to the board, you need to select the correct Arduino board that matches the board connected to your computer. Then come back to the Arduino software, you should click Tools→Board, select the board. (as shown below)
0085=15.png


Then select the correct COM port (you can see the corresponding COM port after the driver is successfully installed)


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Before uploading the program to the board, let’s demonstrate the function of each symbol in the Arduino IDE toolbar.

A- Used to verify whether there is any compiling mistakes or not.
B- Used to upload the sketch to your Arduino board.
C- Used to create shortcut window of a new sketch.
D- Used to directly open an example sketch.
E- Used to save the sketch.
F- Used to send the serial data received from board to the serial monitor.

Start your first program

Open the file to select Example, choose BLINK from BASIC, as shown below:



048610png.png


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Set board and COM port, the corresponding board and COM port are shown on the lower right of IDE.


048612png.png

Click 0486-20.png to start compiling the program, check errors.


048613png.png

Click 0486-23.pngto upload the program, upload successfully.


048614png.png

Upload the program successfully, the onboard LED lights on for 1s, lights off for 1s. Congratulation, you finish the first program.



How to Add a Library?

What are Libraries ?
Libraries are a collection of code that makes it easy for you to connect to a sensor,display, module, etc.
For example, the built-in LiquidCrystal library helps talk to LCD displays. There are hundreds of additional libraries available on the Internet for download.
The built-in libraries and some of these additional libraries are listed in the reference.

Here we will introduce the most simple way for you to add libraries .
Step 1:After downloading well the Arduino IDE, you can right-click the icon of Arduino IDE.
Find the option "Open file location" shown as below:


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Step 2: Enter it to find out libraries folder which is the library file of Arduino.


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Step 3:Next to find out the“libraries”of tank robot(seen in the link: https://fs.keyestudio.com/KS0428), you just need to replicate and paste into the libraries folder of Arduino IDE.


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Then the libraries of tank robot are installed successfully, as shown below:
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Projects

Project 1: LED Blink

(1)Description
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For the starter and enthusiast, this is a fundamental program---LED Blink.
LED, the abbreviation of light emitting diodes, consist of Ga, As, P, N chemical compound and so on. The LED can flash diverse color by altering the delay time in the test code. When in control, power on GND and VCC, the LED will be on if S end is high level; nevertheless, it will go off.

(2)Specification


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  • Control interface: digital port
  • Working voltage: DC 3.3-5V
  • Pin spacing: 2.54mm
  • LED display color: red

(3)Equipment


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(4) V5 Sensor Shield
There will be troublesome when we combine Arduino development boards with numerous sensors. However, the V5 sensor shield, compatible with Arduino development board, address this problem perfectly. Just stack V5 board on it. This sensor shield can be inserted into 3pin sensor modules and breaks out some some communication pins, like serial, IIC, and SPI communication as well.

Pins Description
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Connection Diagram:


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Seen from the above diagram, LED is linked with D2

(5) Test Code

/*
 keyestudio Mini Tank Robot V2
 lesson 1.1
 Blink
 http://www.keyestudio.com
*/
void setup()
 { 
    pinMode(2, OUTPUT);// initialize digital pin 2 as an output.
}
void loop() // the loop function runs over and over again forever

{
   digitalWrite(2, HIGH); // turn the LED on (HIGH is the voltage level)
   delay(1000); // wait for a second
   digitalWrite(2, LOW); // turn the LED off by making the voltage LOW
   delay(1000); // wait for a second
}
//****************************************************************

(6) Test Result

(There will be contradict about serial communication between code and Bluetooth when uploading code, therefore, don’t link with Bluetooth module before uploading code.) Upload the program on the development board, LED flicker with the interval of 1s.


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(7)Code Explanation

pinMode(2,OUTPUT) - Set pin2 to OUTPUT

digitalWrite(2,HIGH) - When set pin2 to HIGH level(output 5V) or to LOW level(output 0V)

(8)Extension Practice We succeed to blink LED. Next, let’s observe what LED will change if we modify pins and delay time.


Connection Diagram


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We’ve altered pins and connected LED to D10.

Test Code:


/*
 keyestudio Mini Tank Robot V2
 lesson 1.2
 delay
 http://www.keyestudio.com
*/
void setup() {  // initialize digital pin 10 as an output.
   pinMode(10, OUTPUT);
}
// the loop function runs over and over again forever
void loop() {
   digitalWrite(10, HIGH); // turn the LED on (HIGH is the voltage level)
   delay(100); // wait for 0.1 second
   digitalWrite(10, LOW); // turn the LED off by making the voltage LOW
   delay(100); // wait for 0.1 second
}
//****************************************************************

The LED flickers faster than before through the test result, therefore, pins and delay time affect flash frequency.

Project 2: Adjust LED Brightness

(1)Description In previous lesson, we control LED on and off and make it blink. In this project, we will control LED brightness through PWM to simulate breathing effect. Similarly, you can change the step length and delay time in the code so as to demonstrate different breathing effect. PWM is a means of controlling the analog output via digital means. Digital control is used to generate square waves with different duty cycles (a signal that constantly switches between high and low levels) to control the analog output.In general, the input voltage of port are 0V and 5V. What if the 3V is required? Or what if switch among 1V, 3V and 3.5V? We can’t change resistor constantly. For this situation, we need to control by PWM.


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For the Arduino digital port voltage output, there are only LOW and HIGH, which correspond to the voltage output of 0V and 5V. You can define LOW as 0 and HIGH as 1, and let the Arduino output five hundred 0 or 1 signals within 1 second. If output five hundred 1, that is 5V; if all of which is 1, that is 0V. If output 010101010101 in this way then the output port is 2.5V, which is like showing movie. The movie we watch are not completely continuous. It actually outputs 25 pictures per second. In this case, the human can’t tell it, neither does PWM. If want different voltage, need to control the ratio of 0 and 1. The more 0,1 signals output per unit time, the more accurately control.


(2) Specification

  • Control interface: digital port
  • Working voltage: DC 3.3-5V
  • Pin spacing: 2.54mm
  • Display color: red


(3) Equipment
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(4) Connection Diagram
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(5) Test Code

/*
 keyestudio Mini Tank Robot V2
 lesson 2.1
 pwm
 http://www.keyestudio.com
*/
int ledPin = 10; // Define the LED pin at D10
int value;
void setup () 
{
pinMode (ledPin, OUTPUT); // initialize ledpin as an output.
}
void loop () 
{
for (value = 0; value <255; value = value + 1)
{
analogWrite (ledPin, value); // LED lights gradually light up
delay (5); // delay 5MS
}
for (value = 255; value> 0; value = value-1)
{
analogWrite (ledPin, value); // LED gradually goes out
delay (5); // delay 5MS
}}//**********************************************************

(6)Test Result

Upload test code successfully, LED gradually becomes brighter then darker, like human breath, rather than light on and off immediately.

(7)Code Explanation

When we need to repeat some statements, we could use FOR statement.
FOR statement format is shown below:


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FOR cyclic sequence: Round 1:1 → 2 → 3 → 4 Round 2:2 → 3 → 4 … Until number 2 is not established, “for”loop is over, After knowing this order, go back to code: for (int value = 0; value < 255; value=value+1){

       ...

} for (int value = 255; value >0; value=value-1){

      ...

}

The two“for”statements make value increase from 0 to 255, then reduce from 255 to 0, then increase to 255,....infinitely loop There is a new function in the following ----- analogWrite() We know that digital port only has two state of 0 and 1. So how to send an analog value to a digital value? Here,this function is needed. Let’s observe the Arduino board and find 6 pins marked“~”which can output PWM signals.

Function format as follows: analogWrite(pin,value) analogWrite() is used to write an analog value from 0~255 for PWM port, so the value is in the range of 0~255. Attention that you only write the digital pins with PWM function, such as pin 3, 5, 6, 9, 10, 11.
PWM is a technology to obtain analog quantity through digital method. Digital control forms a square wave, and the square wave signal only has two states of turning on and off (that is, high or low levels). By controlling the ratio of the duration of turning on and off, a voltage varying from 0 to 5V can be simulated. The time turning on(academically referred to as high level) is called pulse width, so PWM is also called pulse width modulation.
Through the following five square waves, let’s acknowledge more about PWM.


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In the above figure, the green line represents a period, and value of analogWrite() corresponds to a percentage which is called Duty Cycle as well. Duty cycle implies that high-level duration is divided by low-level duration in a cycle. From top to bottom, the duty cycle of first square wave is 0% and its corresponding value is 0. The LED brightness is lowest, that is, turn off. The more time high level lasts, the brighter the LED.
Therefore, the last duty cycle is 100%, which correspond to 255, LED is brightest. 25% means darker.
PWM mostly is used for adjusting the LED brightness or rotation speed of motor.
It plays vital role in controlling smart robot car. I believe that you can’t wait to enter next project.


(8) Extension Practice:

Let’s modify the value of delay and remain the pin unchanged, then observe how LED changes.

/*
 keyestudio Mini Tank Robot V2
 lesson 2.2
 pwm-slow
 http://www.keyestudio.com
*/
int ledPin = 10; // Define the LED pin at D10
int value;
void setup () 
{
pinMode (ledPin, OUTPUT); // initialize ledpin as an output.
}
void loop () 
{
for (value = 0; value <255; value = value + 1)
{
analogWrite (ledPin, value); // LED lights gradually light up
delay (30); // delay 30MS
}
for (value = 255; value> 0; value = value-1)
{
analogWrite (ledPin, value); // LED gradually goes out
delay (30); // delay 30MS
}}//**********************************************************

Upload code on the development board and LED gradually get brighter then darker.

Project 3: Photoresistor Sensor


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(1)Description

The photoresistor is a special resistor made of semiconductor materials such as CdS or Selenide septum. The surface is also coated with moisture-proof resin, which has a photoconductive effect. It is sensitive to ambient light. Its resistance varies from different light intensities.

We use the characteristics of the photo-resistor to design the circuit and generate the photo-resistor module.
Connecting the signal pin of photocell module to Analog port, when the stronger the light intensity, the greater the voltage of analog port, the greater the analog value is.
On the contrary, the weaker the light intensity, the smaller the voltage of analog port, the smaller the analog value is. Based on that, we can use the photocell module to read the analog value, so get the ambient light intensity.

(2)Specification


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  • Resistance:5K ohm-0.5Mohm
  • Interface Type: analog
  • Working Voltage: 3.3V-5V
  • Easy installation: with screw fixing holes
  • Pin spacing: 2.54mm

(3)Equipment


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Connection Diagram:


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The two photoresistor sensors are linked with A1 and A2, then finish the experiment via photoresistor connected to A1. Then finish the following experiment via photoresistor connected A1. Let’s read its analog value.


(4)Test Code


/*
 keyestudio Mini Tank Robot V2
 lesson 3.1
 photocell
 http://www.keyestudio.com
*/
int sensorPin = A1;    // select the input pin for the photocell
int sensorValue = 0;  // variable to store the value coming from the sensor
void setup() {
Serial.begin(9600);
}
void loop() {
sensorValue = analogRead(sensorPin);  // read the value from the sensor:
Serial.println(sensorValue);  //Serial port prints the resistance value
delay(500);
}
//******************************************************

(5)Test Result


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Upload code on development board, open serial monitor, check if its value diminishes when covering photoresistor. However, the value increases when uncovered.

(6)Code Explanation analogRead(sensorPin):read the analog value of photoresistor via analog ports. Serial.begin(9600): Initialize the serial port, baud rate of serial communication is 9600 Serial.println : Serial port prints and word wrap.


(7)Extension Practice We’ve known how to read the value of photoresistor. Let’s combine photoresistor with LED and view the status of LED.


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PWM restrains the brightness, so LED is linked with PWM pins, connect LED to pin 10, keep pin of photoresistor unchanged, then design the code:

/*keyestudio Mini Tank Robot V2
lesson 3.2
photocell-analog output
http://www.keyestudio.com
*/
int analogInPin = A1;  // Analog input pin that the photocell is attached to
int analogOutPin = 10; // Analog output pin that the LED is attached to
int sensorValue = 0;        // value read from the pot
int outputValue = 0;        // value output to the PWM (analog out)
void setup() {
Serial.begin(9600);
 }
void loop() {
  // read the analog in value:
  sensorValue = analogRead(analogInPin);
  // map it to the range of the analog out:
  outputValue = map(sensorValue, 0, 1023, 0, 255);
  // change the analog out value:
  analogWrite(analogOutPin, outputValue);
  // wait 2 milliseconds before the next loop for the analog-to-digital
  // converter to settle after the last reading:
 Serial.println(sensorValue);  //serial port prints the value of photoresistor
delay(2);
}
//***************************************************************

Upload code, press it by hand and see the the LED brightness.


Project 4: Servo Control

(1)Description


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Servo motor is a position control rotary actuator. It mainly consists of housing, circuit board, core-less motor, gear and position sensor. Its working principle is that the servo receives the signal sent by MCU or receiver and produces a reference signal with a period of 20ms and width of 1.5ms, then compares the acquired DC bias voltage to the voltage of the potentiometer and obtain the voltage difference output.

When the motor speed is constant, the potentiometer is driven to rotate through the cascade reduction gear, which leads that the voltage difference is 0, and the motor stops rotating. Generally, the angle range of servo rotation is 0° --180 °

The rotation angle of servo motor is controlled by regulating the duty cycle of PWM (Pulse-Width Modulation) signal. The standard cycle of PWM signal is 20ms (50Hz). Theoretically, the width is distributed between 1ms-2ms, but in fact, it's between 0.5ms-2.5ms. The width corresponds the rotation angle from 0° to 180°. But note that for different brand motor, the same signal may have different rotation angle. 


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The corresponding servo angles are shown below:
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(2)Specification

  • Working voltage: DC 4.8V ~ 6V
  • Operating angle range: about 180 ° (at 500 → 2500 μsec)
  • Pulse width range: 500 → 2500 μsec
  • No-load speed: 0.12 ± 0.01 sec / 60 (DC 4.8V) 0.1 ± 0.01 sec / 60 (DC 6V)
  • No-load current: 200 ± 20mA (DC 4.8V) 220 ± 20mA (DC 6V)
  • Stopping torque: 1.3 ± 0.01kg · cm (DC 4.8V) 1.5 ± 0.1kg · cm (DC 6V)
  • Stop current: ≦ 850mA (DC 4.8V) ≦ 1000mA (DC 6V)
  • Standby current: 3 ± 1mA (DC 4.8V) 4 ± 1mA (DC 6V)


(3)Equipment


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(4)Connection Diagram:


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Wiring note: the brown line of servo is linked with Gnd(G), the red line is connected to 5v(V) and orange line is attached to digital 9.

The servo have to be connected to external power, due to its high demand for driving servo current. Generally, the current of development board is not enough. If without connected power, the development board could be burnt.


(5)Test Code1

/*
keyestudio Mini Tank Robot V2
lesson 4.1
Servo
http://www.keyestudio.com
*/
#define servoPin 9  //servo Pin
int pos; //angle variable of servo
int pulsewidth; // pulse width variable of servo
void setup() {
  pinMode(servoPin, OUTPUT);  //set servo pin to OUTPUT
  procedure(0); //set the angle of servo to 0°
}
void loop() {
  for (pos = 0; pos <= 180; pos += 1) { // goes from 0 degrees to 180 degrees
    // in steps of 1 degree
    procedure(pos);              // tell servo to go to position in variable 'pos'
    delay(15);                   //control the rotation speed of servo
  }
  for (pos = 180; pos >= 0; pos -= 1) { // goes from 180 degrees to 0 degrees
    procedure(pos);              // tell servo to go to position in variable 'pos'
    delay(15);                    
  }
}
// function to control servo
void procedure(int myangle) {
  pulsewidth = myangle * 11 + 500;  //calculate the value of pulse width
  digitalWrite(servoPin,HIGH);
  delayMicroseconds(pulsewidth);   //The duration of high level is pulse width
  digitalWrite(servoPin,LOW);
  delay((20 - pulsewidth / 1000));  // the cycle is 20ms, the low level last for the rest of time
}
//********************************************************************

Upload code successfully, servo swings back in the range of 0° to 180°

There is another guide for restraining servo---- servo library file, the following link of official website is for your reference. https://www.arduino.cc/en/Reference/Servo

Servo library file

(6)Test Code2

/*
 keyestudio Mini Tank Robot V2
 lesson 4.2
 servo
 http://www.keyestudio.com
*/
#include <Servo.h>
Servo myservo;  // create servo object to control a servo
// twelve servo objects can be created on most boards
int pos = 0;    // variable to store the servo position
void setup() {
  myservo.attach(9);  // attaches the servo on pin 9 to the servo object
}
void loop() {
  for (pos = 0; pos <= 180; pos += 1) { // goes from 0 degrees to 180 degrees
    // in steps of 1 degree
    myservo.write(pos);              // tell servo to go to position in variable 'pos'
    delay(15);                       // waits 15ms for the servo to reach the position
  }
  for (pos = 180; pos >= 0; pos -= 1) { // goes from 180 degrees to 0 degrees
    myservo.write(pos);              // tell servo to go to position in variable 'pos'
    delay(15);                       // waits 15ms for the servo to reach the position
  }
}
//****************************************************************

(7)Test Result

Upload code successfully and power on, servo rotates in the range of 0° to 180°. The result is same. We usually control it by library file.

(8)Code Explanation

Arduino comes with #include <Servo.h> (servo function and statement) The following are some common statements of the servo function: 1. attach(interface)——Set servo interface, port 9 and 10 are available

3.write(angle)——The statement to set rotation angle of servo, the angle range is from 0° to 180° 3. read()——The statement to read angle of servo, read the command value of “write()” 4. Note: The above written format is “servo variable name, specific statement()”, for instance: myservo.attach(9)

Project 5: Ultrasonic Sensor

(1)Description


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The HC-SR04 ultrasonic sensor uses sonar to determine distance to an object like bats do. It offers excellent non-contact range detection with high accuracy and stable readings in an easy-to-use package. It comes complete with ultrasonic transmitter and receiver modules.
The HC-SR04 or the ultrasonic sensor is being used in a wide range of electronics projects for creating obstacle detection and distance measuring application as well as various other applications. Here we have brought the simple method to measure the distance with arduino and ultrasonic sensor and how to use ultrasonic sensor with arduino.

(2)Specification


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  • Power Supply :+5V DC
  • Quiescent Current : <2mA
  • Working Current: 15mA
  • Effectual Angle: <15°
  • Ranging Distance : 2cm – 400 cm
  • Resolution : 0.3 cm
  • Measuring Angle: 30 degree
  • Trigger Input Pulse width: 10uS


(3)Equipment


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(4)The principle of ultrasonic sensor

As the above picture shown, it is like two eyes. One is transmitting end, the other is receiving end.

The ultrasonic module will emit the ultrasonic waves after trigger signal. When the ultrasonic waves encounter the object and are reflected back, the module outputs an echo signal, so it can determine the distance of object from the time difference between trigger signal and echo signal. The t is the time that emitting signal meets obstacle and returns. and the propagation speed of sound in the air is about 343m/s, therefore, distance = speed * time, because the ultrasonic wave emits and comes back, which is 2 times of distance, so it needs to be divided by 2, the distance measured by ultrasonic wave = (speed * time)/2

1.Use method and timing chart of ultrasonic module: Setting the delay time of Trig pin of SR04 to 10μs at least, which can trigger it to detect distance. 2. After triggering, the module will automatically send eight 40KHz ultrasonic pulses and detect whether there is a signal return. This step will be completed automatically by the module. 3. If the signal returns, the Echo pin will output a high level, and the duration of the high level is the time from the transmission of the ultrasonic wave to the return.



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Circuit diagram of ultrasonic sensor:


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(5)Connection Diagram


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(6)Test Code

/*
 keyestudio Mini Tank Robot V2
 lesson 5
 Ultrasonic sensor
 http://www.keyestudio.com
*/ 
int trigPin = 5;    // Trigger
int echoPin = 4;    // Echo
long duration, cm, inches;
void setup() {
  //Serial Port begin
  Serial.begin (9600);
  //Define inputs and outputs
  pinMode(trigPin, OUTPUT);
  pinMode(echoPin, INPUT);
}
void loop() {
  // The sensor is triggered by a HIGH pulse of 10 or more microseconds.
  // Give a short LOW pulse beforehand to ensure a clean HIGH pulse:
  digitalWrite(trigPin, LOW);
  delayMicroseconds(2);
  digitalWrite(trigPin, HIGH);
  delayMicroseconds(10);
  digitalWrite(trigPin, LOW);
   // Read the signal from the sensor: a HIGH pulse whose
  // duration is the time (in microseconds) from the sending
  // of the ping to the reception of its echo off of an object.
  duration = pulseIn(echoPin, HIGH);
   // Convert the time into a distance
  cm = (duration/2) / 29.1;     // Divide by 29.1 or multiply by 0.0343
  inches = (duration/2) / 74;   // Divide by 74 or multiply by 0.0135
  Serial.print(inches);
  Serial.print("in, ");
  Serial.print(cm);
  Serial.print("cm");
  Serial.println();
  delay(250);
}
//****************************************************************

(7)Test Result Upload test code on the development board, open serial monitor and set baud rate to 9600. The detected distance will be displayed, unit is cm and inch. Hinder the ultrasonic sensor by hand, the displayed distance value is smaller.



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(8)Code Explanation int trigPin = 5; this pin is defined pin to transmit ultrasonic waves, generally output. int echoPin = 4; this is defined as the pin of reception, generally input cm = (duration/2) / 29.1; inches = (duration/2) / 74; by 0.0135 We can calculate the distance by using the following formula: distance = (traveltime/2) x speed of sound The speed of sound is: 343m/s = 0.0343 cm/uS = 1/29.1 cm/uS Or in inches: 13503.9in/s = 0.0135in/uS = 1/74in/uS We need to divide the traveltime by 2 because we have to take into account that the wave was sent, hit the object, and then returned back to the sensor. (9)Extension Practice: We have just measured the distance displayed by the ultrasonic. How about controlling the LED with the measured distance? Let's try it, connect an LED light module to the D10 pin.


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/*
 keyestudio Mini Tank Robot V2
 lesson 5
 Ultrasonic LED
 http://www.keyestudio.com
*/ 
int trigPin = 5;    // Trigger
int echoPin = 4;    // Echo
long duration, cm, inches;
void setup() {
  //Serial Port begin
  Serial.begin (9600);
  //Define inputs and outputs
  pinMode(trigPin, OUTPUT);
  pinMode(echoPin, INPUT);
}
 void loop() 
{
  // The sensor is triggered by a HIGH pulse of 10 or more microseconds.
  // Give a short LOW pulse beforehand to ensure a clean HIGH pulse:
  digitalWrite(trigPin, LOW);
  delayMicroseconds(2);
  digitalWrite(trigPin, HIGH);
  delayMicroseconds(10);
  digitalWrite(trigPin, LOW);
  // Read the signal from the sensor: a HIGH pulse whose
  // duration is the time (in microseconds) from the sending
  // of the ping to the reception of its echo off of an object.
  duration = pulseIn(echoPin, HIGH);
  // Convert the time into a distance
  cm = (duration/2) / 29.1;     // Divide by 29.1 or multiply by 0.0343
  inches = (duration/2) / 74;   // Divide by 74 or multiply by 0.0135
  Serial.print(inches);
  Serial.print("in, ");
  Serial.print(cm);
  Serial.print("cm");
  Serial.println();
  delay(250);
if (cm>=2 && cm<=10)
digitalWrite(10, HIGH);
delay(1000);
digitalWrite(10, LOW);
delay(1000);
}
//****************************************************************

Upload test code to development board and block ultrasonic sensor by hand, then check if LED is on

Project 6: IR Reception

(1)Description
There is no doubt that infrared remote control is ubiquitous in daily life. It is used to control various household appliances, such as TVs, stereos, video recorders and satellite signal receivers. Infrared remote control is composed of infrared transmitting and infrared receiving systems, that is, an infrared remote control and infrared receiving module and a single-chip microcomputer capable of decoding.​    
The 38K infrared carrier signal emitted by remote controller is encoded by the encoding chip in the remote controller. It is composed of a section of pilot code, user code, user inverse code, data code, and data inverse code. The time interval of the pulse is used to distinguish whether it is a 0 or 1 signal and the encoding is made up of these 0, 1 signals.
The user code of the same remote control is unchanged. The data code can distinguish the key.
When the remote control button is pressed, the remote control sends out an infrared carrier signal. When the IR receiver receives the signal, the program will decode the carrier signal and determines which key is pressed. The MCU decodes the received 01 signal, thereby judging what key is pressed by the remote control.
Infrared receiver we use is an infrared receiver module. Mainly composed of an infrared receiver head, it is a device that integrates reception, amplification, and demodulation. Its internal IC has completed demodulation, and can achieve from infrared reception to output and be compatible with TTL signals. Additionally, it is suitable for infrared remote control and infrared data transmission. The infrared receiving module made by the receiver has only three pins, signal line, VCC and GND. It is very convenient to communicate with arduino and other microcontrollers.


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(2)Specification


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  • Operating Voltage: 3.3-5V(DC)
  • Interface: 3PIN
  • Output Signal: Digital signal
  • Receiving Angle: 90 degrees
  • Frequency: 38khz
  • Receiving Distance: 10m


(3)Equipment


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(4)Connection Diagram


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Respectively link “-”、“+” and S of IR receiver module with G(GND), V(VCC)and A0 of keyestudio development board.
Attention: On the condition that digital ports are not available, analog ports can be regarded as digital ports. A0 equals to D14, A1 is equivalent to digital 15.


(5)Test Code

Firstly import library file of IR receiver module(refer to how to import Arduino library file) before designing code.

/*
keyestudio Mini Tank Robot V2
lesson 6
IRremote
http://www.keyestudio.com
*/ 
#include <IRremoteTank.h>     // IRremote library statement
int RECV_PIN = A0;        //define the pins of IR receiver as A0
IRrecv irrecv(RECV_PIN);   
decode_results results;   // decode results exist in the “result” of “decode results”
void setup()  
	{  
      Serial.begin(9600);  
      irrecv.enableIRIn(); //Enable receiver
	}  
 void loop() {  
	  if (irrecv.decode(&results))//decode successfully, receive a set of infrared signals
	  {  
	    Serial.println(results.value, HEX);//Wrap word in 16 HEX to output and receive code 
	    irrecv.resume(); // Receive the next value
	  }  
	  delay(100);  
	}  
//*******************************************************


(6)Test Result

Upload test code, open serial monitor and set baud rate to 9600, point remote control to IR receiver and the corresponding value will be shown, if pressing so long, the error codes will appear.


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Below we have listed out each button value of keyestudio remote control. So you can keep it for reference.


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(7)Code Explanation
irrecv.enableIRIn(): after enabling IR decoding, the IR signals will be received, then function“decode()”will check continuously if decode successfully.

irrecv.decode(&results): after decoding successfully, this function will come back to “true”, and keep result in “results”. After decoding a IR signals, run the resume()function and receive the next signal (8)Extension Practice We decoded the key value of IR remote control. How about restrain LED by the measured value? We could operate an experiment to affirm. Attach a LED to D10. When keep the pin of IR receiver unchanged, LED will be on when pressing the key of remote control; press again, LED will be off.


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/* keyestudio Mini Tank Robot V2
lesson 6.2
IRremote
http://www.keyestudio.com
*/ 
#include <IRremoteTank.h>
int RECV_PIN = A0;//define the pin of IR receiver as A0
int LED_PIN=10;//define the pin of LED
int a=0;
IRrecv irrecv(RECV_PIN);
decode_results results;
void setup()
{
  Serial.begin(9600);
  irrecv.enableIRIn(); // Initialize the IR receiver 
  pinMode(LED_PIN,OUTPUT);//set LED_pin to OUTPUT
}
void loop() {
  if (irrecv.decode(&results)) {
if(results.value==0xFF02FD &a==0) // according to the above key value, press“OK”on remote control , LED will be controlled
{
    digitalWrite(LED_PIN,HIGH);//LED will be on
a=1;
}
else if(results.value==0xFF02FD &a==1) //press again
{
digitalWrite(LED_PIN,LOW);//LED will go off
a=0;
}
    irrecv.resume(); //receive the next value
  }
}
//*******************************************************

Upload code to development board, press“OK”key on remote control to make LED on and off.

Project 7: Bluetooth Remote Control

(1)Description


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Bluetooth, a simple wireless communication module most popular since the last few decades and easy to use are being used in most of the battery-powered devices.
Over the years, there have been many upgrades of Bluetooth standard to keep fulfil the demand of customers and technology according to the need of time and situation. Over the few years, there are many things changed including data transmission rate, power consumption with wearable and IoT Devices and Security System.
Here we are going to learn about HM-10 BLE 4.0 with Arduino Board. The HM-10 is a readily available Bluetooth 4.0 module. This module is used for establishing wireless data communication. The module is designed by using the Texas Instruments CC2540 or CC2541 Bluetooth low energy (BLE) System on Chip (SoC).


(2)Specification

  • Bluetooth protocol: Bluetooth Specification V4.0 BLE
  • No byte limit in serial port Transceiving
  • In open environment, realize 100m ultra-distance communication with iphone4s
  • Working frequency: 2.4GHz ISM band
  • Modulation method: GFSK(Gaussian Frequency Shift Keying)
  • Transmission power: -23dbm, -6dbm, 0dbm, 6dbm, can be modified by AT command.
  • Sensitivity: ≤-84dBm at 0.1% BER
  • Transmission rate: Asynchronous: 6K bytes ; Synchronous: 6k Bytes
  • Security feature: Authentication and encryption
  • Supporting service: Central & Peripheral UUID FFE0, FFE1
  • Power consumption: Auto sleep mode, stand by current 400uA~800uA, 8.5mA during transmission.
  • Power supply: 5V DC
  • Working temperature: –5 to +65 Centigrade


(3)Equipment


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(4)Connection Diagram

  • 1. STATE: state test pins, connected to internal LED, generally keep it unconnected.
  • 2. RXD: serial interface, receiving terminal.
  • 3. TXD: serial interface, transmitting terminal.
  • 4. GND: Ground.
  • 5. VCC: positive pole of the power source.
  • 6. EN/BRK: break connect, it means breaking the Bluetooth connection, generally, keep it unconnected.


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(5)Test Code

/*
 keyestudio Mini Tank Robot v2.0
 lesson 7.1
 bluetooth 
http://www.keyestudio.com
*/

char ble_val; //character variable: save the value of Bluetooth reception

void setup() {
  Serial.begin(9600);
}
void loop() {
  if(Serial.available() > 0)  //Judge if there is data in serial buffer
  {
    ble_val = Serial.read();  //Read data from serial buffer
    Serial.println(ble_val);  //Print
  }}
//*******************************************


(There will be contradiction between serial communication of code and communication of Bluetooth when uploading code, therefore, don’t link with Bluetooth module before uploading code.)
After uploading code on development board, then insert Bluetooth module, wait for the command from cellphone.

(6)Download APP

Allow APP to access “location” in settings of your cellphone when connecting to Bluetooth module.

The code is reading the received signal, and we also need a stuff to send signal. In this project, we send signal to control robot car via cellphone.
Then we need to download the APP.

1.For iOS system

Enter APP STORE to search BLE Scanner 4.0, then download it.


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2.For Android system

Enter Google Play to find out BLE Scanner, then download.
And allow APP to access“location”, you could enable “location”in settings of your cellphone.



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  • 3.After installation, open App and enable “Location and Bluetooth” permission.
  • 4.We take iOS version as example. The operation method of Android version is almost same as it.
  • 5.Scan Bluetooth module to get Bluetooth BLE 4.0. Its name is HMSoft.

Then click“connect”to link with Bluetooth and use it.


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6. After connecting to HMSoft, click it to get multiple options, such as device information, access permission, general and custom service. Choose “CUSTOM SERVICE”


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7.Then pop up the following page


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8. Click(Read,Notify,WriteWithoutResponse)to enter the following page


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9.Click Write Value, appear the interface to enter HEX or Text.


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10.Open the serial monitor on Arduino,enter a 0 or other character at Text interface.


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Then click“Write”, open serial monitor to view if there is a “0” signal
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(7)Code Explanation

Serial.available() : The current rest characters when return to buffer area. Generally, this function is used to judge if there is data in buffer. When Serial.available()>0, it means that serial receives the data and can be read
Serial.read():Read a data of a Byte in buffer of serial port, for instance, device sends data to Arduino via serial port, then we could read data by “Serial.read()” (8)Extension Practice
We could send a command via cellphone to turn on and off a LED.
D10 is connected to a LED, as shown below:


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/*
 keyestudio Mini Tank Robot v2.0
 lesson 7.2
 Bluetooth 
 http://www.keyestudio.com
*/ 
int ledpin=11;
void setup()
{Serial.begin(9600);
 pinMode(ledpin,OUTPUT);
}
void loop()
{ int i;
  if (Serial.available())
  {i=Serial.read();
    Serial.println("DATA RECEIVED:");
    if(i=='1')
    { digitalWrite(ledpin,1);
      Serial.println("led on");
    }
    if(i=='0')
    { digitalWrite(ledpin,0);
      Serial.println("led off");
}}}//*******************************************


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Click “Write” on APP, when you enter 1, LED will be on, when you input 0, LED will be off. (Remember to remove the Bluetooth module after finishing experiment, otherwise, burning code will be affected)

Project 8: Motor Driving and Speed Control

(1) Description


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There are many ways to drive the motor. Our tank robot uses the most commonly used L298P solution. L298P is an excellent high-power motor driver IC produced by STMicroelectronics. It can directly drive DC motors, two-phase and four-phase stepping motors. The driving current up to 2A, and output terminal of motor adopts eight high-speed Schottky diodes as protection.
We designed a shield based on the circuit of L298p.
The stacked design reduces the technical difficulty of using and driving the motor.

(2)Specification

Circuit Diagram for L298P Board


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  • 1)Logic part input voltage: DC5V
  • 2)Driving part input voltage: DC 7-12V
  • 3)Logic part working current: <36mA
  • 4)Driving part working current: <2A
  • 5)Maximum power dissipation: 25W (T=75℃)
  • 6)Working temperature: -25℃~+130℃
  • 7)Control signal input level: high level 2.3V<Vin<5V, low level -0.3V<Vin<1.5V


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(3)Drive Robot to Move

Through the above circuit diagram, the direction pin of A motor is D12, and speed pin is D3; D13 is the direction pin of B motor, D11 is speed pin.
We know how to control digital ports according to the following chart.
PWM decides 2 motors to turn so as to drive robot car. The PWM value is in the range of 0-255, the larger the number, the faster the motor rotates.


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(4)Equipment


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(5)Connection Diagram


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Note: the 4Pin terminal block is marked with silkscreen 1234. The red line of right rear motor is connected to terminal 1, black line is linked with end 2. The red line of left front motor is attached to terminal 3, black line is linked with port 4.

(6)Test Code

/*
 keyestudio Mini Tank Robot v2.0
 lesson 8.1
 motor driver
 http://www.keyestudio.com
*/ 

#define ML_Ctrl 13  //define the direction control pin of left motor
#define ML_PWM 11   //define the PWM control pin of left motor
#define MR_Ctrl 12  //define direction control pin of right motor
#define MR_PWM 3   // define the PWM control pin of right motor

void setup()
{
  pinMode(ML_Ctrl, OUTPUT);//define direction control pin of left motor as output
  pinMode(ML_PWM, OUTPUT);//define PWM control pin of left motor as output
  pinMode(MR_Ctrl, OUTPUT);//define direction control pin of right motor as output.
  pinMode(MR_PWM, OUTPUT);//define the PWM control pin of right motor as output
}

void loop()
{ 
  digitalWrite(ML_Ctrl,LOW);//set the direction control pin of left motor to LOW
  analogWrite(ML_PWM,200);//set the PWM control speed of left motor to 200
  digitalWrite(MR_Ctrl,LOW);//set the direction control pin of right motor to LOW
  analogWrite(MR_PWM,200);//set the PWM control speed of right motor to 200

  //front
  delay(2000);//delay in 2s
   digitalWrite(ML_Ctrl,HIGH);//set the direction control pin of left motor to HIGH
  analogWrite(ML_PWM,200);//set the PWM control speed of left motor to 200  
digitalWrite(MR_Ctrl,HIGH);//set the direction control pin of right motor to HIGH
  analogWrite(MR_PWM,200);//set the PWM control speed of right motor to 200

   //back
  delay(2000);//delay in 2s 
  digitalWrite(ML_Ctrl,HIGH);//set the direction control pin of left motor to HIGH
  analogWrite(ML_PWM,200);//set the PWM control speed of left motor to 200
  digitalWrite(MR_Ctrl,LOW);//set the direction control pin of right motor to LOW
  analogWrite(MR_PWM,200);//set the PWM control speed of right motor to 200

    //left
  delay(2000);//delay in 2s
   digitalWrite(ML_Ctrl,LOW);//set the direction control pin of left motor to LOW
  analogWrite(ML_PWM,200);//set the PWM control speed of left motor to 200
  digitalWrite(MR_Ctrl,HIGH);//set the direction control pin of right motor to HIGH
  analogWrite(MR_PWM,200);//set the PWM control speed of right motor to 200

   //right
  delay(2000);//delay in 2s
  analogWrite(ML_PWM,0);//set the PWM control speed of left motor to 0
  analogWrite(MR_PWM,0);//set the PWM control speed of right motor to 0

    //stop
  delay(2000);//delay in 2s
}//*****************************************


(7)Test Result

Hook up by connection diagram, upload code and power on, smart car goes forward and back for 2s, turns left and right for 2s, stops for 2s and alternately.
(8) Code Explanation
digitalWrite(ML_Ctrl,LOW): the rotation direction of motor is decided by the high/low level and and the pins that decide rotation direction are general pins.
analogWrite(ML_PWM,200): the speed of motor is regulated by PWM, The speed of motor is regulated by PWM, and the pins that decide the speed of motor have to be PWM pins.


(9)Extension Practice

Hook up in same way


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/*
 keyestudio Mini Tank Robot v2.0
 lesson 8.2
 motor driver pwm
 http://www.keyestudio.com
*/ 
#define ML_Ctrl 13  //define the direction control pin of left motor
#define ML_PWM 11   //define the PWM control pin of left motor
#define MR_Ctrl 12  //define the control pin of right motor
#define MR_PWM 3   //define the PWM control pin of right motor
void setup()
{ pinMode(ML_Ctrl, OUTPUT);//define the direction control pin of left motor as OUTPUT
  pinMode(ML_PWM, OUTPUT);//define the PWM control pin of left motor as OUTPUT
  pinMode(MR_Ctrl, OUTPUT);//define the direction control pin of right motor as OUTPUT
  pinMode(MR_PWM, OUTPUT);//define the PWM control pin of right motor as OUTPUT

}
void loop()
{ digitalWrite(ML_Ctrl,LOW);//Set direction control pin of left motor to LOW
  analogWrite(ML_PWM,100);// Set the PWM control speed of left motor to 100
  digitalWrite(MR_Ctrl,LOW);//Set the direction control pin of right motor to LOW
  analogWrite(MR_PWM,100);//Set the PWM control speed of right motor to 100
  //front
  delay(2000);//define 2s
  digitalWrite(ML_Ctrl,HIGH);//Set direction control pin of left motor to HIGH level
  analogWrite(ML_PWM,100);//Set the PWM control speed of left motor to 100
  digitalWrite(MR_Ctrl,HIGH);//Set direction control pin of right motor to HIGH level
  analogWrite(MR_PWM,100);//Set the PWM control speed of right motor to 100
   //back
  delay(2000);//define 2s
  digitalWrite(ML_Ctrl,HIGH);//Set direction control pin of left motor to HIGH level
  analogWrite(ML_PWM,100);//Set the PWM control speed of left motor to 100
  digitalWrite(MR_Ctrl,LOW);//Set direction control pin of right motor to LOW level
  analogWrite(MR_PWM,100);//Set the PWM control speed of right motor to 100
    //left
  delay(2000);//define 2s
   digitalWrite(ML_Ctrl,LOW);//set the direction control pin of left motor to LOW
  analogWrite(ML_PWM,100);//set the PWM control speed of left motor to 200
  digitalWrite(MR_Ctrl,HIGH);//set the direction control pin of right motor to HIGH
  analogWrite(MR_PWM,100);//set the PWM control speed of right motor to 100
   //right
  delay(2000);//define 2s
  analogWrite(ML_PWM,0);//set the PWM control speed of left motor to 0
  analogWrite(MR_PWM,0);// set the PWM control speed of right motor to 0

    //stop
  delay(2000);//define 2s
}//******************************************************************

Upload code successfully, the motors rotate faster.

Project 9: LED Expression Panel

(1)Description


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If we add an expression panel to the robot, it will be amazing. Keyestudio's 8*16 dot matrix can meet your requirements. You can create facial expressions, patterns or other interesting displays yourself. 8*16 LED light board comes with 128 LEDs. The data of the microprocessor (arduino) communicates with the AiP1640 through the two-wire bus interface, so as to control the 128 LEDs on the module, which produce the patterns you need on dot matrix. To facilitate wiring, we also provide a HX-2.54 4Pin wiring.


(2)Specification

  • Working voltage: DC 3.3-5V
  • Power loss: 400mW
  • Oscillation frequency: 450KHz
  • Drive current: 200mA
  • Working temperature: -40~80℃
  • Communication method: two-wire bus

(3)Equipment


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(4)8*16 Dot Matrix Display

Circuit Graphic


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The principle of 8*16 dot matrix:
How to control each led light of 8*16 dot matrix? We know that a byte has 8 bits, each bit is 0 or 1. When a bit is 0, turn off LED and when a bit is 0, turn on LED.
Thereby, one byte can control the LED in a row of dot matrix, so 16 bytes can control 16 columns of led lights, that is, 8*16 dot matrix.

Interface Description and Communication Protocol:
The data of the microprocessor (arduino) communicates with the AiP1640 through the two-wire bus interface.
The communication protocol diagram is shown below:

(SCLK) is SCL, (DIN) is SDA:


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①The starting condition for data input: SCL is high level and SDA changes from high to low.
②For data command setting, there are methods as shown in the figure below.
In our sample program, select the way to add 1 to the address automatically, the binary value is 0100 0000 and the corresponding hexadecimal value is 0x40.


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③For address command setting, the address can be selected as shown below. The first 00H is selected in our sample program, and the binary number 1100 0000 corresponds to the hexadecimal 0xc0


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  • ④The requirement for data input is that SCL is high level when inputting data, the signal on SDA must remain unchanged. Only when the clock signal on SCL is low level, the signal on SDA can be altered. The data input is low-order first, high-order is behind
  • ⑤ The condition to end data transmission is that when SCL is low, SDA is low, and when SCL is high, the SDA level also becomes high.
  • ⑥ Display control, set different pulse width, the pulse width can be selected as shown below
  • In the example, we choose pulse width 4/16, and the hexadecimal corresponds to 1000 1010 is 0x8A



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4. Introduction for Modulus Tool

The online version of dot matrix modulus tool: http://dotmatrixtool.com/#

①Open links to enter the following page.


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②The dot matrix is 8*16 in this project, so set the height to 8, width to 16, as shown below.


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③ Generate hexadecimal data from the pattern As shown below, press the left mouse button to select, the right button to cancel, draw the pattern you want, click Generate, and the hexadecimal data we need will be produced.


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(5)Connection Diagram


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Wiring note: The GND, VCC, SDA, and SCL of the 8x16 LED panel are respectively connected to -(GND), + (VCC), A4 and A5 of the keyestudio sensor expansion board for two-wire serial communication. (Note: This pin is connected to arduino IIC, but this module is not IIC communication, it can be linked with any two pins.)


(6)Test Code

The code that shows smile face

/*
 keyestudio Mini Tank Robot v2.0
 lesson 9.1
 Matrix  face
 http://www.keyestudio.com
*/ 
//the data of smiley from modulus tool
unsigned char smile[] = {0x00, 0x00, 0x1c, 0x02, 0x02, 0x02, 0x5c, 0x40, 0x40, 0x5c, 0x02, 0x02, 0x02, 0x1c, 0x00, 0x00};

#define SCL_Pin  A5  //Set clock pin to A5
#define SDA_Pin  A4  //Set data pin to A4

void setup(){
  //Set pin to output
  pinMode(SCL_Pin,OUTPUT);
  pinMode(SDA_Pin,OUTPUT);
  //clear the display
  //matrix_display(clear);
}
void loop(){
  matrix_display(smile);  // display smile face
}
// the function for dot matrix display
void matrix_display(unsigned char matrix_value[])
{
  IIC_start();  // use the function of the data transmission start condition
  IIC_send(0xc0);  //select address
  
  for(int i = 0;i < 16;i++) //pattern data has 16 bits
  {
     IIC_send(matrix_value[i]); //convey the pattern data
  }

  IIC_end();   //end the transmission of pattern data  
  IIC_start();
  IIC_send(0x8A);  //display control, set pulse width to 4/16 s
  IIC_end();
}

//the condition to start conveying data
void IIC_start()
{
  digitalWrite(SCL_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,LOW);
  delayMicroseconds(3);
}
//Convey data
void IIC_send(unsigned char send_data)
{
  for(char i = 0;i < 8;i++)  //Each byte has 8 bits 8bit for every character
  {
      digitalWrite(SCL_Pin,LOW);  // pull down clock pin SCL_Pin to change the signal of SDA
      delayMicroseconds(3);
      if(send_data & 0x01)  //set high and low level of SDA_Pin according to 1 or 0 of every bit
      {
        digitalWrite(SDA_Pin,HIGH);
      }
      else
      {
        digitalWrite(SDA_Pin,LOW);
      }
      delayMicroseconds(3);
      digitalWrite(SCL_Pin,HIGH); //pull up the clock pin SCL_Pin to stop transmission
      delayMicroseconds(3);
      send_data = send_data >> 1;  // detect bit by bit, shift the data to the right by one
  }
}

//The sign of ending data transmission
void IIC_end()
{
  digitalWrite(SCL_Pin,LOW);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,LOW);
  delayMicroseconds(3);
  digitalWrite(SCL_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,HIGH);
  delayMicroseconds(3);
}
//******************************************************

(7)Test Result
Wire according to connection diagram. The DIP switch is dialed to right end and power on, the smile face appears on dot matrix.

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(8)Extension Practice

We use the modulo tool (http://dotmatrixtool.com/#)to make the dot matrix alternately display start, go front and stop patterns then clear the patterns, the time interval is 2000 milliseconds.


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Get the graphical code to be displayed via modulus tool

  • Start:
  • 0x01,0x02,0x04,0x08,0x10,0x20,0x40,0x80,0x80,0x40,0x20,0x10,0x08,0x04,0x02,0x01
  • Go front:
  • 0x00,0x00,0x00,0x00,0x00,0x24,0x12,0x09,0x12,0x24,0x00,0x00,0x00,0x00,0x00,0x00
  • Go back:
  • 0x00,0x00,0x00,0x00,0x00,0x24,0x48,0x90,0x48,0x24,0x00,0x00,0x00,0x00,0x00,0x00
  • Turn left:
  • 0x00,0x00,0x00,0x00,0x00,0x00,0x44,0x28,0x10,0x44,0x28,0x10,0x44,0x28,0x10,0x00
  • Turn left:
  • 0x00,0x10,0x28,0x44,0x10,0x28,0x44,0x10,0x28,0x44,0x00,0x00,0x00,0x00,0x00,0x00
  • Stop:
  • 0x2E,0x2A,0x3A,0x00,0x02,0x3E,0x02,0x00,0x3E,0x22,0x3E,0x00,0x3E,0x0A,0x0E,0x00
  • Clear the displayed code:0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00

The code that the multiple patterns shift:

/* keyestudio Mini Tank Robot v2.0
 lesson 9.2
 Matrix loop
 http://www.keyestudio.com
*/ 
//Array, used to store the data of the pattern, can be calculated by yourself or obtained from the modulus tool
unsigned char start01[] = 
{0x01,0x02,0x04,0x08,0x10,0x20,0x40,0x80,0x80,0x40,0x20,0x10,0x08,0x04,0x02,0x01};
unsigned char front[] = 
{0x00,0x00,0x00,0x00,0x00,0x24,0x12,0x09,0x12,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
unsigned char back[] = 
{0x00,0x00,0x00,0x00,0x00,0x24,0x48,0x90,0x48,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
unsigned char left[] = 
{0x00,0x00,0x00,0x00,0x00,0x00,0x44,0x28,0x10,0x44,0x28,0x10,0x44,0x28,0x10,0x00};
unsigned char right[] = 
{0x00,0x10,0x28,0x44,0x10,0x28,0x44,0x10,0x28,0x44,0x00,0x00,0x00,0x00,0x00,0x00};
unsigned char STOP01[] = 
{0x2E,0x2A,0x3A,0x00,0x02,0x3E,0x02,0x00,0x3E,0x22,0x3E,0x00,0x3E,0x0A,0x0E,0x00};
unsigned char clear[] = 
{0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00};
#define SCL_Pin  A5  //Set clock pin to A5
#define SDA_Pin  A4  //Set data pin to A4
void setup(){
  //Set pins to output
  pinMode(SCL_Pin,OUTPUT);
  pinMode(SDA_Pin,OUTPUT);
  //Clear the display
  matrix_display(clear);
}
void loop(){
  matrix_display(start01);  // Display start pattern
  delay(2000);
  matrix_display(front);    //Front pattern
  delay(2000);
  matrix_display(STOP01);   //Stop pattern
  delay(2000);
  matrix_display(clear);    //Clear the display Clear the screen
  delay(2000);
}
// This function is used to display of dot matrix
void matrix_display(unsigned char matrix_value[])
{
  IIC_start();  //call the function that data transmission start  
  IIC_send(0xc0);  //Choose address
  
  for(int i = 0;i < 16;i++) //pattern data has 16 bits
  {
     IIC_send(matrix_value[i]); //data to convey patterns 
  }
  IIC_end();   //end the transmission of pattern dataEnd
  IIC_start();
  IIC_send(0x8A);  //display control, set pulse width to 4/16
  IIC_end();
}
//The condition starting to transmit data
void IIC_start()
{
  digitalWrite(SCL_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,LOW);
  delayMicroseconds(3);
}
//Convey data
void IIC_send(unsigned char send_data)
{
  for(char i = 0;i < 8;i++)  //Each byte has 8 bits
  {
      digitalWrite(SCL_Pin,LOW);  //pull down clock pin SCL Pin to change the signals of SDA      
delayMicroseconds(3);
      if(send_data & 0x01)  //set high and low level of SDA_Pin according to 1 or 0 of every bit
      {
        digitalWrite(SDA_Pin,HIGH);
      }
      else
      {
        digitalWrite(SDA_Pin,LOW);
      }
      delayMicroseconds(3);
      digitalWrite(SCL_Pin,HIGH); //pull up clock pin SCL_Pin to stop transmitting data
      delayMicroseconds(3);
      send_data = send_data >> 1;  //detect bit by bit, so shift the data right by one
  }}
//The sign that data transmission ends
void IIC_end()
{
  digitalWrite(SCL_Pin,LOW);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,LOW);
  delayMicroseconds(3);
  digitalWrite(SCL_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,HIGH);
  delayMicroseconds(3);} 
//*****************************************************

Upload code on development board, 8*16 dot matrix display go front and back and stop patterns, alternately.


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Project 10: Light Follow Robot

(1)Description

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We’ve introduce how to use various sensors, modules.
In this lesson, we combine with hardware knowledge -- photoresistor module, motor driving, to build a light-following robot!
Just need to use 2 photoresistor modules to detect the light intensity at the both side of robot. Read the analog value to rotate the 2 motors, thus drive the tank robot run.


The specific logic of light following robot is shown as the table below:

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We make a flow chart based on the above logic table, as shown below:

(2)Connection Diagram

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Hook-up Attention: The 4Pin terminal block is marked with silkscreen 1234. The red line of right rear motor is connected to terminal 1, black line is linked with end 2. The red line of left front motor is attached to terminal 3, black line is linked with port 4.


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(3)Test Code

  
/*
 keyestudio Mini Tank Robot v2.0
 lesson 10
 Light-following tank
 http://www.keyestudio.com
*/ 
#define light_L_Pin A1   //define the pin of left photo resistor
#define light_R_Pin A2   //define the pin of right photo resistor
#define ML_Ctrl 13  //define the direction control pin of left motor
#define ML_PWM 11   //define the PWM control pin of left motor
#define MR_Ctrl 12  //define the direction control pin of right motor
#define MR_PWM 3   //define the PWM control pin of right motor
int left_light; 
int right_light;
void setup(){
  Serial.begin(9600);
  pinMode(light_L_Pin, INPUT);
  pinMode(light_R_Pin, INPUT);
  pinMode(ML_Ctrl, OUTPUT);
  pinMode(ML_PWM, OUTPUT);
  pinMode(MR_Ctrl, OUTPUT);
  pinMode(MR_PWM, OUTPUT);
}
void loop(){
  left_light = analogRead(light_L_Pin);
  right_light = analogRead(light_R_Pin);
  Serial.print("left_light_value = ");
  Serial.println(left_light);
  Serial.print("right_light_value = ");
  Serial.println(right_light);
  if (left_light > 650 && right_light > 650) //the value detected photo resistor,go front
  {  
    Car_front();
  } 
  else if (left_light > 650 && right_light <= 650)  //the value detected photo resistor,turn left
  {
    Car_left();
  } 
  else if (left_light <= 650 && right_light > 650) //the value detected photo resistor,turn right
  {
    Car_right();
  } 
  else  //other situations, stop
  {
    Car_Stop();
  }
}
void Car_front()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,200);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,200);
}
void Car_left()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,200);
  digitalWrite(ML_Ctrl,HIGH);
  analogWrite(ML_PWM,200);
}
void Car_right()
{
  digitalWrite(MR_Ctrl,HIGH);
  analogWrite(MR_PWM,200);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,200);
}
void Car_Stop()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,0);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,0);
}
//****************************************************************

(4)Test Result

Upload code on keyestudio V4.0 development board, DIP switch is dialed to right end and power on, the smart robot follows light to move.

Project 11: Ultrasonic Avoid Tank

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(1)Description

In this program, the ultrasonic sensor detects the distance of obstacle to send signals that control the robot car. Next, let’s show you how to make an obstacle avoidance car.

The specific logic of ultrasonic avoiding robot is as shown below:

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(2)Flow chart

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(3)Connection Diagram:

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Note: “-”、“+” and “S” pins of servo are respectively attached to G(GND), V(VCC)and D9 of expansion board. The VCC, Trig, Echo and Gnd of ultrasonic sensor are linked with 5v(V), 5(S), Echo and Gnd(G) of expansion board.

(4)Test Code:


/*
 keyestudio Mini Tank Robot v2.0
 lesson 11
 ultrasonic_avoid_tank
 http://www.keyestudio.com
*/
int random2;
int a;
int a1;
int a2;
#define ML_Ctrl 13  //define the direction control pin of left motor
#define ML_PWM 11   //define PWM control pin of left motor
#define MR_Ctrl 12  //define the direction control pin of right motor
#define MR_PWM 3   //define PWM control pin of right motor

#define Trig 5  //ultrasonic trig Pin
#define Echo 4  //ultrasonic echo Pin
int distance;
#define servoPin 9  //servo Pin
int pulsewidth;
/************the function to run motor**************/
void Car_front()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,200);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,200);
}
void Car_back()
{
  digitalWrite(MR_Ctrl,HIGH);
  analogWrite(MR_PWM,200);
  digitalWrite(ML_Ctrl,HIGH);
  analogWrite(ML_PWM,200);
}
void Car_left()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,255);
  digitalWrite(ML_Ctrl,HIGH);
  analogWrite(ML_PWM,255);
}
void Car_right()
{
  digitalWrite(MR_Ctrl,HIGH);
  analogWrite(MR_PWM,255);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,255);
}
void Car_Stop()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,0);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,0);
}

//The function to control servo
void procedure(int myangle) {
  for (int i = 0; i <= 50; i = i + (1)) {
    pulsewidth = myangle * 11 + 500;
    digitalWrite(servoPin,HIGH);
    delayMicroseconds(pulsewidth);
    digitalWrite(servoPin,LOW);
    delay((20 - pulsewidth / 1000));
  }
}
//The function to control ultrasonic sensor
float checkdistance() {
  digitalWrite(Trig, LOW);
  delayMicroseconds(2);
  digitalWrite(Trig, HIGH);
  delayMicroseconds(10);
  digitalWrite(Trig, LOW);
  float distance = pulseIn(Echo, HIGH) / 58.00;  //58.20, that is, 2*29.1=58.2
  delay(10);
  return distance;
}
  //****************************************************************
void setup(){
  pinMode(servoPin, OUTPUT);
  procedure(90); //set servo to 90°
  
  pinMode(Trig, OUTPUT);
  pinMode(Echo, INPUT);
  pinMode(ML_Ctrl, OUTPUT);
  pinMode(ML_PWM, OUTPUT);
  pinMode(MR_Ctrl, OUTPUT);
  pinMode(MR_PWM, OUTPUT);
}
void loop(){
  random2 = random(1, 100);
  a = checkdistance();  //assign the front distance detected by ultrasonic sensor to variable a
  
  if (a < 20) //when the front distance detected is less than 20 
  {
      Car_Stop();  //robot stops
      delay(500); //delay in 500ms
      procedure(160);  //Ultrasonic platform turns left
      for (int j = 1; j <= 10; j = j + (1)) { //for statement, the data will be more accurate if ultrasonic sensor detect a few times.
        a1 = checkdistance();  //assign the left distance detected by ultrasonic sensor to variable a1
      }
      delay(300);
      procedure(20); //Ultrasonic platform turns right
      for (int k = 1; k <= 10; k = k + (1)) {
        a2 = checkdistance(); //assign the right distance detected by ultrasonic sensor to variable a2
      }
      
      if (a1 < 50 || a2 < 50)  //robot will turn to the longer distance side when left or right distance is less than 50cm. 
      {
        if (a1 > a2) //left distance is greater than right side      
        {
          procedure(90);  //Ultrasonic platform turns back to right ahead         
Car_left();  //robot turns left
          delay(500);  //turn left for 500ms
          Car_front(); //go front
        } 
        else 
        {
          procedure(90);
          Car_right(); //robot turns right
          delay(500);
          Car_front();  //go front
        }
      } 
      else  //If both side is greater than or equal to 50cm, turn left or right randomly
      {
        if ((long) (random2) % (long) (2) == 0)  //When the random number is even
        {
          procedure(90);
          Car_left(); //tank robot turns left
          delay(500);
          Car_front(); //go front
        } 
        else 
        {
          procedure(90);
          Car_right(); //robot turns right
          delay(500);
          Car_front(); //go front
       }
     }
  } 
  else  //If the front distance is greater than or equal to 20cm, robot car will go front
  {
      Car_front(); //go front
  }
}
  //****************************************************************


(5)Test Result

Upload code successfully, DIP switch is dialed to right end and power on, tank robot goes forward. It can automatically avoid barrier.

Project 12: Ultrasonic Follow Tank

(1)Description

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In project 11, we made an obstacle avoidance car. In fact, we only need to alter a test code to transform an obstacle avoidance car into following car. In this lesson, we will make an ultrasonic follow robot. The ultrasonic sensor detects the distance between smart car and the obstacle to drive tank car to move.

The specific logic of ultrasonic follow robot is as shown below:

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(2)Flow chart

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(3)Connection Diagram

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Wire-up note:

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(4)Test Code

 /*
 keyestudio Mini Tank Robot v2.0
 lesson 12
 ultrasonic follow tank
 http://www.keyestudio.com
*/ 
//Array, used to store the data of the pattern, can be calculated by yourself or obtained from the modulus tool
unsigned char start01[] = {0x01,0x02,0x04,0x08,0x10,0x20,0x40,0x80,0x80,0x40,0x20,0x10,0x08,0x04,0x02,0x01};
unsigned char front[] = {0x00,0x00,0x00,0x00,0x00,0x24,0x12,0x09,0x12,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
unsigned char back[] = {0x00,0x00,0x00,0x00,0x00,0x24,0x48,0x90,0x48,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
unsigned char left[] = {0x00,0x00,0x00,0x00,0x00,0x00,0x44,0x28,0x10,0x44,0x28,0x10,0x44,0x28,0x10,0x00};
unsigned char right[] = {0x00,0x10,0x28,0x44,0x10,0x28,0x44,0x10,0x28,0x44,0x00,0x00,0x00,0x00,0x00,0x00};
unsigned char STOP01[] = {0x2E,0x2A,0x3A,0x00,0x02,0x3E,0x02,0x00,0x3E,0x22,0x3E,0x00,0x3E,0x0A,0x0E,0x00};
unsigned char clear[] = {0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00};
#define SCL_Pin  A5  //Set clock pin to A5
#define SDA_Pin  A4  //Set data pin to A4

#define ML_Ctrl 13  //define the direction control pin of left motor
#define ML_PWM 11   //define PWM control pin of left motor
#define MR_Ctrl 12  //define the direction control pin of right motor
#define MR_PWM 3   //define PWM control pin of right motor
#define Trig 5  //ultrasonic trig Pin
#define Echo 4  //ultrasonic echo Pin
int distance;
int pulsewidth;
#define servoPin 9  //servo Pin
void setup(){
  Serial.begin(9600);
  pinMode(SCL_Pin,OUTPUT);
  pinMode(SDA_Pin,OUTPUT);
  matrix_display(clear); //Clear the display
  matrix_display(start01);  //display start pattern
  pinMode(servoPin, OUTPUT);
  procedure(90); //set servo to 90°
  pinMode(Trig, OUTPUT);
  pinMode(Echo, INPUT);
  pinMode(ML_Ctrl, OUTPUT);
  pinMode(ML_PWM, OUTPUT);
  pinMode(MR_Ctrl, OUTPUT);
  pinMode(MR_PWM, OUTPUT);
}
void loop(){
  distance = checkdistance();  //assign the distance detected by ultrasonic sensor to distance
  if (distance >= 20 && distance <= 60) //range to go front
  {
    Car_front();
  }
  else if (distance > 10 && distance < 20)  //range to stop
  {
    Car_Stop();
  }
  else if (distance <= 10)  //range to go back
  {
    Car_back();
  }
  else  //other situations, stop
  {
    Car_Stop();
  }
}
/***********the function for motor running****************/
void Car_front()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,200);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,200);
}
void Car_back()
{
  digitalWrite(MR_Ctrl,HIGH);
  analogWrite(MR_PWM,200);
  digitalWrite(ML_Ctrl,HIGH);
  analogWrite(ML_PWM,200);
}
void Car_left()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,200);
  digitalWrite(ML_Ctrl,HIGH);
  analogWrite(ML_PWM,200);
}
void Car_right()
{
  digitalWrite(MR_Ctrl,HIGH);
  analogWrite(MR_PWM,200);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,200);
}
void Car_Stop()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,0);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,0);
}

/******************dot matrix********************/
// the function for dot matrix display
void matrix_display(unsigned char matrix_value[])
{
  IIC_start(); // call the function that data transmission start
  IIC_send(0xc0);  //Choose address
  
  for(int i = 0;i < 16;i++) //pattern data has 16 bits
  {
     IIC_send(matrix_value[i]); //data to convey patterns
  }

  IIC_end();   //end to convey data pattern
  
  IIC_start();
  IIC_send(0x8A);  //select pulse width4/16, control display
  IIC_end();
}

//The condition starting to transmit data
void IIC_start()
{
  digitalWrite(SCL_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,LOW);
  delayMicroseconds(3);
}

// transmit data
void IIC_send(unsigned char send_data)
{
  for(char i = 0;i < 8;i++)  //Each byte has 8 bits
  {
      digitalWrite(SCL_Pin,LOW);  //pull down clock pin SCL Pin to change the signals of SDA      
delayMicroseconds(3);
      if(send_data & 0x01)  //set high and low level of SDA_Pin according to 1 or 0 of every bit
      {
        digitalWrite(SDA_Pin,HIGH);
      }
      else
      {
        digitalWrite(SDA_Pin,LOW);
      }
      delayMicroseconds(3);
      digitalWrite(SCL_Pin,HIGH); //pull up clock pin SCL_Pin to stop transmitting data
      delayMicroseconds(3);
      send_data = send_data >> 1;  // detect bit by bit, so move the data right by one
  }
}
//The sign that data transmission ends
void IIC_end()
{
  digitalWrite(SCL_Pin,LOW);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,LOW);
  delayMicroseconds(3);
  digitalWrite(SCL_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,HIGH);
  delayMicroseconds(3);
}
/***************end dot matrix display******************/
//The function to control servo
void procedure(int myangle) {
  for (int i = 0; i <= 50; i = i + (1)) {
    pulsewidth = myangle * 11 + 500;
    digitalWrite(servoPin,HIGH);
    delayMicroseconds(pulsewidth);
    digitalWrite(servoPin,LOW);
    delay((20 - pulsewidth / 1000));
  }}
//The function to control ultrasonic sensor function controlling ultrasonic
float checkdistance() {
  digitalWrite(Trig, LOW);
  delayMicroseconds(2);
  digitalWrite(Trig, HIGH);
  delayMicroseconds(10);
  digitalWrite(Trig, LOW);
  float distance = pulseIn(Echo, HIGH) / 58.20;  //58.20, that is , 2*29.1=58.2
  delay(10);
  return distance;
}
//****************************************************************

(5)Test Result

Upload code successfully, DIP switch is dialed to right end, the servo rotates to 90°, “V” is shown on 8X16 LED panel and smart car moves as the obstacle moves.

Project 13: IR Remote Robot Tank

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(1)Description

IR remote control is one of most ubiquitous control, applied in TV, electric fan and some household appliances. In this project, we will make an IR remote smart car. And we’ve known every key value on IR remote control. Thus, we could control smart car via and display the patterns on dot matrix via corresponding key value

The specific logic of infrared remote control robot is shown below:

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(2)Flow Chart

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(3)Connection Diagram

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Attention:GND,VCC, SDA, SCL of 8x16 LED panel are respectively linked with -(GND), +(VCC), SDA ,SCL. And “-”、“+” and S of IR receiver module are attached to G(GND), V(VCC) and A0 on sensor shield. On the condition of insufficient digital ports, the analog ports can be treat as digital ports. A0 equals to digital 14, A1 is like digital 15.


(4)Test Code


/*
 keyestudio Mini Tank Robot v2.0
 lesson 13
 IR remote tank
 http://www.keyestudio.com
*/

#include <IRremoteTank.h>
IRrecv irrecv(A0);  //set IRrecv irrecv to A0
decode_results results;
long ir_rec;  //save the IR value received

//Array, used to store the data of the pattern, can be calculated by yourself or obtained from the modulus tool
unsigned char start01[] = {0x01,0x02,0x04,0x08,0x10,0x20,0x40,0x80,0x80,0x40,0x20,0x10,0x08,0x04,0x02,0x01};
unsigned char front[] = {0x00,0x00,0x00,0x00,0x00,0x24,0x12,0x09,0x12,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
unsigned char back[] = {0x00,0x00,0x00,0x00,0x00,0x24,0x48,0x90,0x48,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
unsigned char left[] = {0x00,0x00,0x00,0x00,0x00,0x00,0x44,0x28,0x10,0x44,0x28,0x10,0x44,0x28,0x10,0x00};
unsigned char right[] = {0x00,0x10,0x28,0x44,0x10,0x28,0x44,0x10,0x28,0x44,0x00,0x00,0x00,0x00,0x00,0x00};
unsigned char STOP01[] = {0x2E,0x2A,0x3A,0x00,0x02,0x3E,0x02,0x00,0x3E,0x22,0x3E,0x00,0x3E,0x0A,0x0E,0x00};
unsigned char clear[] = {0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00};
#define SCL_Pin  A5  //Set clock pin to A5
#define SDA_Pin  A4  //Set data pin to A4

#define ML_Ctrl 13  //define the direction control pin of left motor
#define ML_PWM 11   //define PWM control pin of left motor
#define MR_Ctrl 12  //define the direction control pin of right motor
#define MR_PWM 3    //define PWM control pin of right motor

#define servoPin 9 //pin of servo
int pulsewidth; //save the pulse width value of servo

void setup(){
  Serial.begin(9600);
  irrecv.enableIRIn();  //Initialize the IR reception library
  
  pinMode(ML_Ctrl, OUTPUT);
  pinMode(ML_PWM, OUTPUT);
  pinMode(MR_Ctrl, OUTPUT);
  pinMode(MR_PWM, OUTPUT);
  
  pinMode(SCL_Pin,OUTPUT);
  pinMode(SDA_Pin,OUTPUT);
  matrix_display(clear); //Clear Screen
  matrix_display(start01);  //show start picture
  
  pinMode(servoPin, OUTPUT);
  procedure(90);  //Servo rotates to 90°
}

void loop(){
  if (irrecv.decode(&results)) //receive the IR remote value
  {
    ir_rec=results.value;
    String type="UNKNOWN";
    String typelist[14]={"UNKNOWN", "NEC", "SONY", "RC5", "RC6", "DISH", "SHARP", "PANASONIC", "JVC", "SANYO", "MITSUBISHI", "SAMSUNG", "LG", "WHYNTER"};
    if(results.decode_type>=1&&results.decode_type<=13){
      type=typelist[results.decode_type];
    }
    Serial.print("IR TYPE:"+type+"  ");
    Serial.println(ir_rec,HEX);
    irrecv.resume();
  }
  
  if (ir_rec == 0xFF629D) //Go forward
  {
    Car_front();
    matrix_display(front);  //Display front image
  }
  if (ir_rec == 0xFFA857)  //Robot car goes back
  {
    Car_back();
    matrix_display(front);  //Go back
  }
  if (ir_rec == 0xFF22DD)   //Robot car turns left
  {
    Car_T_left();
    matrix_display(left);  //Display left-turning image
  }
  if (ir_rec == 0xFFC23D)   //Robot car turns right
  {
    Car_T_right();
    matrix_display(right);  //Display right-turning image
  }
  if (ir_rec == 0xFF02FD)   //Robot car stops
  { 
    Car_Stop();
    matrix_display(STOP01);  //show stop image
  }
  if (ir_rec == 0xFF30CF)   //robot car rotates anticlockwise
  {
    Car_left();
    matrix_display(left);  //show anticlockwise rotation picture
  }
  if (ir_rec == 0xFF7A85)  //robot car rotates clockwise
  {
    Car_right();
    matrix_display(right);  //show clockwise rotation picture
 }
}
/******************Control Servo*******************/
void procedure(int myangle) {
  for (int i = 0; i <= 50; i = i + (1)) {
    pulsewidth = myangle * 11 + 500;
    digitalWrite(servoPin,HIGH);
    delayMicroseconds(pulsewidth);
    digitalWrite(servoPin,LOW);
    delay((20 - pulsewidth / 1000));
  }
}

/******************Dot Matrix****************/
// this function is used for dot matrix display 
void matrix_display(unsigned char matrix_value[])
{
  IIC_start();
  IIC_send(0xc0);  //Choose address
   for(int i = 0;i < 16;i++) //The picture has 16 bits
  {
     IIC_send(matrix_value[i]); //data to convey patterns
  }
  IIC_end();   //end to convey data pattern
  
  IIC_start();
  IIC_send(0x8A);  //display control, set pulse width to 4/16
  IIC_end();
}

//The condition starting to transmit data
void IIC_start()
{
  digitalWrite(SCL_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,LOW);
  delayMicroseconds(3);
}
//传输数据
void IIC_send(unsigned char send_data)
{
  for(char i = 0;i < 8;i++)  //Each byte has 8 bits 8bits for every character
  {
      digitalWrite(SCL_Pin,LOW);  //pull down clock pin SCL Pin to change the signals of SDA      
      delayMicroseconds(3);
      if(send_data & 0x01)  //set high and low level of SDA_Pin according to 1 or 0 of every bit
      {
        digitalWrite(SDA_Pin,HIGH);
      }
      else
      {
        digitalWrite(SDA_Pin,LOW);
      }
      delayMicroseconds(3);
      digitalWrite(SCL_Pin,HIGH); //pull up clock pin SCL_Pin to stop transmitting data
      delayMicroseconds(3);
      send_data = send_data >> 1;  // detect bit by bit, so move the data right by one
  }
}
//The sign that data transmission ends
void IIC_end()
{
  digitalWrite(SCL_Pin,LOW);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,LOW);
  delayMicroseconds(3);
  digitalWrite(SCL_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,HIGH);
  delayMicroseconds(3);
}
/***************the function to run motor***************/
void Car_front()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,200);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,200);
}
void Car_back()
{
  digitalWrite(MR_Ctrl,HIGH);
  analogWrite(MR_PWM,200);
  digitalWrite(ML_Ctrl,HIGH);
  analogWrite(ML_PWM,200);
}
void Car_left()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,255);
  digitalWrite(ML_Ctrl,HIGH);
  analogWrite(ML_PWM,255);
}
void Car_right()
{
  digitalWrite(MR_Ctrl,HIGH);
  analogWrite(MR_PWM,255);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,255);
}
void Car_Stop()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,0);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,0);
}
void Car_T_left()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,255);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,180);
}
void Car_T_right()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,180);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,255);
}
 //****************************************************************


(5)Test Result


Upload code successfully and power on, the smart robot can be controlled by IR remote, at same time, the corresponding pattern is shown on 8X16 LED panel.

Project 14: Bluetooth Control Robot

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(1)Description

We’ve learned the basic knowledge of Bluetooth, in this lesson, we will make a Bluetooth remote smart car. In the experiment, we default the HM-10 Bluetooth module as a Slave and the cellphone as a Host.
keyes BT car is an APP rolled out by keyestudio team. You could control the robot car by it readily.
There is a guide to how to download and install APP in the document as for your reference. The interface is shown below.

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APP DOWNLOAD

https://play.google.com/store/apps/details?id=com.keyestudio.tankcar3


(2)Test Code


/*
 keyestudio Mini Tank Robot v2.0
 lesson 14.1
 bluetooth test
 http://www.keyestudio.com
*/
char ble_val; //character variables, used to save the value of Bluetooth reception
void setup() {
  Serial.begin(9600);
}
void loop() {
  if(Serial.available() > 0)  //judge if there is data in buffer area
  { ble_val = Serial.read();  //read the data from serial buffer
    Serial.println(ble_val);  //print out
  }}


Pull off the Bluetooth module, upload test code, reconnect Bluetooth module, open serial monitor and set baud rate to 9600. Point at Bluetooth module and press keys on APP, the corresponding character is shown below.


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The detected character and corresponding function:

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In compliance with the above table, we make a flow chart to assist you to understand well. The flow chart is below:

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(3)Connection Diagram

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Wiring Attention:

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(4)Test Code

Note: Remove the Bluetooth module before uploading test code, otherwise, you will fail to upload test code

/*
 keyestudio Robot Car v2.0
 lesson 14.2
 bluetooth car
 http://www.keyestudio.com
*/

//Array, used to store the data of pattern, can be calculated by yourself or obtained from the modulus tool
unsigned char start01[] = {0x01,0x02,0x04,0x08,0x10,0x20,0x40,0x80,0x80,0x40,0x20,0x10,0x08,0x04,0x02,0x01};
unsigned char front[] = {0x00,0x00,0x00,0x00,0x00,0x24,0x12,0x09,0x12,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
unsigned char back[] = {0x00,0x00,0x00,0x00,0x00,0x24,0x48,0x90,0x48,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
unsigned char left[] = {0x00,0x00,0x00,0x00,0x00,0x00,0x44,0x28,0x10,0x44,0x28,0x10,0x44,0x28,0x10,0x00};
unsigned char right[] = {0x00,0x10,0x28,0x44,0x10,0x28,0x44,0x10,0x28,0x44,0x00,0x00,0x00,0x00,0x00,0x00};
unsigned char STOP01[] = {0x2E,0x2A,0x3A,0x00,0x02,0x3E,0x02,0x00,0x3E,0x22,0x3E,0x00,0x3E,0x0A,0x0E,0x00};
unsigned char clear[] = {0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00};
#define SCL_Pin  A5  //Set clock pin to A5
#define SDA_Pin  A4  //Set data pin to A4

#define ML_Ctrl 13  //define direction control pin of left motor
#define ML_PWM 11   //define PWM control pin of left motor
#define MR_Ctrl 12  //define direction control pin of right motor
#define MR_PWM 3    //define PWM control pin of right motor

char bluetooth_val; //save the value of Bluetooth reception

void setup(){
  Serial.begin(9600);
  
  pinMode(SCL_Pin,OUTPUT);
  pinMode(SDA_Pin,OUTPUT);
  matrix_display(clear);    //Clear the display
  matrix_display(start01);  //display start pattern

  pinMode(ML_Ctrl, OUTPUT);
  pinMode(ML_PWM, OUTPUT);
  pinMode(MR_Ctrl, OUTPUT);
  pinMode(MR_PWM, OUTPUT);
}

void loop(){
  if (Serial.available())
  {
    bluetooth_val = Serial.read();
    Serial.println(bluetooth_val);
  }
  switch (bluetooth_val) 
  {
     case 'F':  //forward command
        Car_front();
        matrix_display(front);  // show forward design
        break;
     case 'B':  //Back command
        Car_back();
        matrix_display(back);  //show back pattern
        break;
     case 'L':  // left-turning instruction
        Car_left();
        matrix_display(left);  //show “left-turning” sign 
        break;
     case 'R':  //right-turning instruction
        Car_right();
        matrix_display(right);  //display right-turning sign
       break;
     case 'S':  //stop command
        Car_Stop();
        matrix_display(STOP01);  //show stop picture
        break;
  }
}

/**************The function of dot matrix****************/
//this function is used for dot matrix display
void matrix_display(unsigned char matrix_value[])
{
  IIC_start();
  IIC_send(0xc0);  //Choose address
  
  for(int i = 0;i < 16;i++) //pattern data has 16 bits
  {
     IIC_send(matrix_value[i]); //data to convey patterns
  }
  IIC_end();   //end to convey data pattern
  
  IIC_start();
  IIC_send(0x8A);  //display control, set pulse width to 4/16
  IIC_end();
}
//The condition starting to transmit data
void IIC_start()
{
  digitalWrite(SCL_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,LOW);
  delayMicroseconds(3);
}
//transmit data
void IIC_send(unsigned char send_data)
{
  for(char i = 0;i < 8;i++)  //Each byte has 8 bits
  {
      digitalWrite(SCL_Pin,LOW);  //pull down clock pin SCL Pin to change the signals of SDA      
      delayMicroseconds(3);
      if(send_data & 0x01)  //set high and low level of SDA_Pin according to 1 or 0 of every bit
      {
        digitalWrite(SDA_Pin,HIGH);
      }
      else
      {
        digitalWrite(SDA_Pin,LOW);
      }
      delayMicroseconds(3);
      digitalWrite(SCL_Pin,HIGH); //pull up clock pin SCL_Pin to stop transmitting data
      delayMicroseconds(3);
      send_data = send_data >> 1;  // Detect bit by bit, so move the data right by one
  }
}
//The sign that data transmission ends
void IIC_end()
{
  digitalWrite(SCL_Pin,LOW);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,LOW);
  delayMicroseconds(3);
  digitalWrite(SCL_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,HIGH);
  delayMicroseconds(3);
}
/*************the function to run motor**************/
void Car_front()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,200);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,200);
}
void Car_back()
{
  digitalWrite(MR_Ctrl,HIGH);
  analogWrite(MR_PWM,200);
  digitalWrite(ML_Ctrl,HIGH);
  analogWrite(ML_PWM,200);
}
void Car_left()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,255);
  digitalWrite(ML_Ctrl,HIGH);
  analogWrite(ML_PWM,255);
}
void Car_right()
{
  digitalWrite(MR_Ctrl,HIGH);
  analogWrite(MR_PWM,255);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,255);
}
void Car_Stop()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,0);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,0);
}
void Car_T_left()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,255);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,180);
}
void Car_T_right()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,180);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,255);
}
  //****************************************************************

(5)Test Result

Upload code successfully, DIP switch is dialed to right end and power on. After connecting Bluetooth, we could drive smart car to move by Bluetooth App.

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Project 15: Multi-purpose Robot Car

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(1)Description

In previous projects, the tank car only performs single function, however, in this lesson, we integrate all of function to control smart car via Bluetooth control. Here is a simple flow chart of multi-purpose robot car as for your reference.

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(2)Connection Diagram

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Attention:Confirm that every component is connected.

Wire-up Guide:

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(3)Test Code

    /*
 keyestudio Mini Tank Robot v2.0
 lesson 15
 multiple functions
 http://www.keyestudio.com
*/

//Array, used to store the data of the pattern, can be calculated by yourself or obtained from the modulus tool
unsigned char start01[] = {0x01,0x02,0x04,0x08,0x10,0x20,0x40,0x80,0x80,0x40,0x20,0x10,0x08,0x04,0x02,0x01};
unsigned char front[] = {0x00,0x00,0x00,0x00,0x00,0x24,0x12,0x09,0x12,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
unsigned char back[] = {0x00,0x00,0x00,0x00,0x00,0x24,0x48,0x90,0x48,0x24,0x00,0x00,0x00,0x00,0x00,0x00};
unsigned char left[] = {0x00,0x00,0x00,0x00,0x00,0x00,0x44,0x28,0x10,0x44,0x28,0x10,0x44,0x28,0x10,0x00};
unsigned char right[] = {0x00,0x10,0x28,0x44,0x10,0x28,0x44,0x10,0x28,0x44,0x00,0x00,0x00,0x00,0x00,0x00};
unsigned char STOP01[] = {0x2E,0x2A,0x3A,0x00,0x02,0x3E,0x02,0x00,0x3E,0x22,0x3E,0x00,0x3E,0x0A,0x0E,0x00};
unsigned char clear[] = {0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00};
#define SCL_Pin  A5  //Set clock pin to A5
#define SDA_Pin  A4  //Set data pin to A4

#define ML_Ctrl 13  //define direction control pin of left motor
#define ML_PWM 11   //define PWM control pin of left motor
#define MR_Ctrl 12  //define direction control pin of right motor
#define MR_PWM 3   //define PWM control pin of right motor

#define Trig 5  //ultrasonic trig Pin
#define Echo 4  //ultrasonic echo Pin
int distance; //save the distance value detected by ultrasonic, follow function
int random2; //save the variable of random numberssave the variable of random numbers
//save the distance value detected by ultrasonic, obstacle avoidance function
int a;  
int a1;
int a2;

#define servoPin 9  //servo Pin
int pulsewidth;

#define light_L_Pin A1   //define the pin of left photo resistor sensor
#define light_R_Pin A2   //define the pin of right photo resistor sensor
int left_light;
int right_light;

char bluetooth_val; //save the value of Bluetooth reception
int flag;  //flag variable, it is used to entry and exist function
void setup(){
  Serial.begin(9600);
  pinMode(Trig, OUTPUT);
  pinMode(Echo, INPUT);
  pinMode(ML_Ctrl, OUTPUT);
  pinMode(ML_PWM, OUTPUT);
  pinMode(MR_Ctrl, OUTPUT);
  pinMode(MR_PWM, OUTPUT);
  
  pinMode(servoPin, OUTPUT);
  procedure(90); //set servo to 90°
 pinMode(SCL_Pin,OUTPUT);
  pinMode(SDA_Pin,OUTPUT);
  matrix_display(clear);    //Clear the display
  matrix_display(start01);  //display start pattern
  pinMode(light_L_Pin, INPUT);
  pinMode(light_R_Pin, INPUT);
}

void loop(){
  if (Serial.available())
  {
    bluetooth_val = Serial.read();
    Serial.println(bluetooth_val);
  }
  switch (bluetooth_val) 
  {
    case 'F':  //Forward instruction 
      Car_front();
      matrix_display(front);  //display forward pattern
      break;
    case 'B':  //Back instruction
      Car_back();
      matrix_display(back);  // display back pattern
      break;
    case 'L':  //left-turning instruction
      Car_left();
      matrix_display(left);  //show left-turning pattern
      break;
    case 'R':  //right-turning instruction
      Car_right();
      matrix_display(right);  //show right-turning pattern
      break;
    case 'S':  //stop instruction
      Car_Stop();
      matrix_display(STOP01);  //display stop pattern
      break;
   case 'Y':
      matrix_display(start01);  //show start pattern
      follow();
      break;
   case 'U':
      matrix_display(start01);  //show start pattern
      avoid();
      break;
   case 'X':
      matrix_display(start01);  //show start pattern
      light_track();
      break;
  }}
/*****************Obstacle Avoidance Function**************/
void avoid() 
{
  flag = 0;  //the design that enter obstacle avoidance function
  while (flag == 0) 
  {
    random2 = random(1, 100);
    a = checkdistance();  //assign the front distance detected by ultrasonic sensor to variable a
    
    if (a < 20) //when the front distance detected is less than 20cm
    {
      Car_Stop();  //robot stops
      delay(200); //delay in 200ms
      
      procedure(160);  //Ultrasonic platform turns left
      for (int j = 1; j <= 10; j = j + (1)) { ///for statement, the data will be more accurate if ultrasonic sensor detect a few times.
        a1 = checkdistance();  //assign the left distance detected by ultrasonic sensor to variable a1
      }
      delay(200);
      procedure(20); //Ultrasonic platform turns right
      for (int k = 1; k <= 10; k = k + (1)) {
        a2 = checkdistance(); //assign the right distance detected by ultrasonic sensor to variable a2
      }
      if (a1 < 50 || a2 < 50)  //robot will turn to the longer distance side when left or right distance is less than 50cm.if the left or right distance is less than 50cm, the robot will turn to the greater distance
      {
        if (a1 > a2) //left distance is greater than right
        {
          procedure(90);  //Ultrasonic platform turns back to right ahead ultrasonic platform turns front
          Car_left();  //robot turns left
          delay(500);  //turn left 500ms
          Car_front(); //go forward
        } 
        else 
        {
          procedure(90);
          Car_right(); //robot turns right
          delay(500);
          Car_front();  //go forward
        }
      } 
      else  //both distance on two side is greater than or equal to 50cm, turn randomly
      {
        if ((long) (random2) % (long) (2) == 0)  //when the random number is even
        {
          procedure(90);
          Car_left(); //robot turns left
          delay(500);
          Car_front(); //go forward
        } 
        else 
        {
          procedure(90);
          Car_right(); //robot turns right
          delay(500);
          Car_front(); ///go forward
       } } } 
  else  //If the front distance is greater than or equal to 20cm, robot car will go front
  {
      Car_front(); //go forward
  }
  // receive the Bluetooth value to end the obstacle avoidance function
  if (Serial.available())
  {
    bluetooth_val = Serial.read();
    if (bluetooth_val == 'S')  //receive S
    {
      flag = 1;  //when assign 1 to flag, end loop
    }}}}
/*******************Follow****************/
void follow() {
  flag = 0;
  while (flag == 0) {
    distance = checkdistance();  //assign the distance detected by ultrasonic sensor to distance
    if (distance >= 20 && distance <= 60) //the range to go front
    {
      Car_front();
    }
    else if (distance > 10 && distance < 20)  //the range to stop
    {
      Car_Stop();
    }
    else if (distance <= 10)  // the range to go back
    {
      Car_back();
    }
    else  //other situations, stop
    {
      Car_Stop();
    }
    if (Serial.available())
    {
      bluetooth_val = Serial.read();
      if (bluetooth_val == 'S') 
      {
        flag = 1;  //end loop
      }}}}
//The function to control ultrasonic sensor the function controlling ultrasonic sensor
float checkdistance() {
  digitalWrite(Trig, LOW);
  delayMicroseconds(2);
  digitalWrite(Trig, HIGH);
  delayMicroseconds(10);
  digitalWrite(Trig, LOW);
  float distance = pulseIn(Echo, HIGH) / 58.00;  //58.20 means 2*29.1=58.2
  delay(10);
  return distance;
}
//The function to control servo the function controlling servo
void procedure(int myangle) {
  for (int i = 0; i <= 50; i = i + (1)) {
    pulsewidth = myangle * 11 + 500;
    digitalWrite(servoPin,HIGH);
    delayMicroseconds(pulsewidth);
    digitalWrite(servoPin,LOW);
    delay((20 - pulsewidth / 1000));
  }}

/****************Light Follow******************/
void light_track() {
  flag = 0;
  while (flag == 0) {
    left_light = analogRead(light_L_Pin);
    right_light = analogRead(light_R_Pin);
    if (left_light > 650 && right_light > 650) //the value detected by photo resistor, go forward
    {  
      Car_front();
    } 
    else if (left_light > 650 && right_light <= 650)  //the value detected by photo resistor, turn left
    {
      Car_left();
    } 
    else if (left_light <= 650 && right_light > 650) //the value detected by photo resistor, turn right
    {
      Car_right();
    } 
    else  //other situations, stop
    {
      Car_Stop();
    }
    if (Serial.available())
    {
      bluetooth_val = Serial.read();
      if (bluetooth_val == 'S') {
        flag = 1;
     }}}}
/***************Dot Matrix *****************/
// this function is used for dot matrix display 
void matrix_display(unsigned char matrix_value[])
{
  IIC_start();
  IIC_send(0xc0);  //Choose address
  
  for(int i = 0;i < 16;i++) //pattern data has 16 bits
  {
     IIC_send(matrix_value[i]); //convey the pattern data
  }
  IIC_end();   //end the transmission of pattern data
  IIC_start();
  IIC_send(0x8A);  //display control, set pulse width to 4/16
  IIC_end();
}
//The condition starting to transmit data
void IIC_start()
{
  digitalWrite(SCL_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,LOW);
  delayMicroseconds(3);
}
//convey data
void IIC_send(unsigned char send_data)
{
  for(char i = 0;i < 8;i++)  //each byte has 8 bits
  {
      digitalWrite(SCL_Pin,LOW);  //pull down clock pin SCL Pin to change the signals of SDA
      delayMicroseconds(3);
      if(send_data & 0x01)  //set high and low level of SDA_Pin according to 1 or 0 of every bit
      {
        digitalWrite(SDA_Pin,HIGH);
      }
      else
      {
        digitalWrite(SDA_Pin,LOW);
      }
      delayMicroseconds(3);
      digitalWrite(SCL_Pin,HIGH); //pull up clock pin SCL_Pin to stop transmitting data
      delayMicroseconds(3);
      send_data = send_data >> 1;  // detect bit by bit, so move the data right by one
  }}
//The sign that data transmission ends
void IIC_end()
{
  digitalWrite(SCL_Pin,LOW);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,LOW);
  delayMicroseconds(3);
  digitalWrite(SCL_Pin,HIGH);
  delayMicroseconds(3);
  digitalWrite(SDA_Pin,HIGH);
  delayMicroseconds(3);
}
/*************the function to run motor*************/
void Car_front()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,200);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,200);
}
void Car_back()
{
  digitalWrite(MR_Ctrl,HIGH);
  analogWrite(MR_PWM,200);
  digitalWrite(ML_Ctrl,HIGH);
  analogWrite(ML_PWM,200);
}
void Car_left()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,255);
  digitalWrite(ML_Ctrl,HIGH);
  analogWrite(ML_PWM,255);
}
void Car_right()
{
  digitalWrite(MR_Ctrl,HIGH);
  analogWrite(MR_PWM,255);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,255);
}
void Car_Stop()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,0);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,0);
}
void Car_T_left()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,255);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,180);
}
void Car_T_right()
{
  digitalWrite(MR_Ctrl,LOW);
  analogWrite(MR_PWM,180);
  digitalWrite(ML_Ctrl,LOW);
  analogWrite(ML_PWM,255);
}


(4)Test Result

Note:Remove the Bluetooth module before uploading test code, otherwise, you will fail to upload test code. Reconnect Bluetooth module after uploading test code

Upload test code successfully, insert Bluetooth module, power on, and connect to Bluetooth. The tank robot can show distinct function by App.

Alright, the whole projects are finished. Please feel free to contact us if you confront some problems. There are some hot-selling items below. You could log in our website to browse them if you’re interested.

9. Resources

Wiki page:https://wiki.keyestudio.com/Ks0428_keyestudio_Mini_Tank_Robot_V2

Official website: https://keyestudio.com/
Assembly Video Link: http://video.keyestudio.com/ks0428/

If you want to try with Mixly software, enter https://fs.keyestudio.com/KS0428.