KS0077(78,79)Super Learning Kit for Arduino
Introduction
keyestudio super learning kit is suitable for Arduino enthusiasts. This kit includes 32 projects with detailed tutorials, starting from the basics to more complex projects. Different from other kits, it adds some functional modules, such as RFID, temperature and humidity module. There is connection diagram and code for each project, making it easy for you to learn.
Component List
NOTE KS0077 Kit Not Includes Main board; KS0078 Kit Includes V4.0 board; KS0079 KIT Includes MEGA 2560 board.
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:
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.
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.
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.
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.
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 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.
Keyestudio MEGA 2560 Board
Keyestudio Mega 2560 R3 is a microcontroller board based on the ATMEGA2560-16AU , fully compatible with ARDUINO MEGA 2560 R3. 图
It has 54 digital input/output pins (of which 15 can be used as PWM outputs), 16 analog inputs, 4 UARTs (hardware serial ports), a 16 MHz crystal oscillator, a USB connection, a power jack, 1 ICSP header, and a reset button. The built-in ICSP port can burn the firmware for ATMEGA2560-16AU directly. This chip is burnt the firmware well before leaving the factory, therefore, we hardly use it. We can power on by USB wire, DC head and Vin GND pins. To facilitate wiring, a 0.5 m USB wire is provided for you.
图
Specialized Functions of Some Pins: 1. Serial Communication: D0 (RX0) and D1 (TX1); Serial 1: D19 (RX1) and D18 (TX1); Serial 2: D17 (RX2) and D16 (TX2); Serial 3: D15 (RX3) and D14 (TX3). Used to receive (RX) and transmit (TX) TTL serial data. Pins 0 and 1 are also connected to the corresponding pins of the CP2102 USB-to-TTL Serial chip. 2. PWM Pins (Pulse-Width Modulation): D2 to D13, and D44 to D46. Provide 8-bit PWM output with the analogWrite() function. 3. External Interrupts: D2 (interrupt 0), D3 (interrupt 1), D18 (interrupt 5), D19 (interrupt 4), D20 (interrupt 3), and D21 (interrupt 2). These pins can be configured to trigger an interrupt on a low level, a rising or falling edge, or a change in level. See the attachInterrupt() function for details. 4. SPI communication: D53 (SS), D52 (SCK), D51 (MOSI), D50 (MISO). These pins support SPI communication using theSPI library. The SPI pins are also broken out on the ICSP header, which is physically compatible with the Arduino Uno. 5. IIC communication: D20 (SDA); D21 (SCL). Support TWI communication using the Wire library.
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.
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.
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:
There is a DRIVERS folder in Arduino software installed package(
), 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)
Open device manager, we will find the yellow exclamation mark disappear. The driver of CP2102 is installed successfully.
Arduino IDE Setting
Click
icon,open Arduino IDE.
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)
Then select the correct COM port (you can see the corresponding COM port after the driver is successfully installed)
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:
Set board and COM port, the corresponding board and COM port are shown on the lower right of IDE.
Click 
to start compiling the program, check errors.
Click 
to upload the program, upload successfully.
Upload the program successfully, the onboard LED lights on for 1s, lights off for 1s. Congratulation, you finish the first program.
Add Project Libraries
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.
How to Install a Library ?
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:
Step 2: Enter it to find out libraries folder which is the library file of Arduino.
Step 3 Next to find out the “libraries” folder of this kit(seen in the link https://fs.keyestudio.com/KS0077-78-79)
You just need to replicate and paste above libraries into the libraries folder of Arduino IDE.
Then the libraries of this kit are installed successfully, as shown below
Note the Arduino software download and the driver installation of keyetudio Mega 2560 R3 board is similar to arduino V4.0 board.
Project Details
Project 1: Hello World
1.Introduction
As for starters, we will begin with something simple. In this project, you only need an Arduino and a USB Cable to start the "Hello World!" experiment. It is not only a communication test of your Arduino and PC, but also a primer project for you to have your first try in the Arduino world!
2.Hardware Required
- V4.0 Board or MEGA 2650 Board*1
- USB cable*1
3.Sample Code
After installing driver for Arduino, let's open Arduino software and compile code that enables Arduino to print "Hello World!" under your instruction. Of course, you can compile code for Arduino to continuously echo "Hello World!" without instruction. A simple If () statement will do the instruction trick. when Arduino gets an instruction and then to print "Hello World!”.
/* keyestudio super learning kit Project 1 Hello World http//www.keyestudio.com
- /
int val;//define variable val void setup() { Serial.begin(9600);// set the baud rate at 9600 . } void loop() {
val=Serial.read();// read the instruction or character from PC to Arduino, and assign them to Val.
if(val=='R')// determine if the instruction or character received is “R”.
{ // if it’s “R”,
Serial.println("Hello World!");// display“Hello World!”string.
}}//
///////////////////////////////////////////////////////////////
4.Test Result
Click to open the serial monitor, input an “R”, PC will receive the information from Arduino Hello World!
After choosing the proper port, the experiment is easy for you!
Project 2: LED Blinking
1.Introduction
Blinking LED experiment is quite simple. In the "Hello World!" program, we have come across LED. This time, we are going to connect an LED to one of the digital pins rather than using LED13 soldered to the board. Apart from an Arduino and a USB cable, you will need extra parts as below
2.Hardware Required
- V4.0 Board or MEGA 2650 Board*1
- Red M5 LED*1
- 220Ω Resistor*1
- Breadboard*1
- Breadboard Jumper Wire*2
- USB cable*1
3.Little Knowledge
LED is a type of semiconductor called "Light Emitting Diode "which is an electronic device made of semiconductor materials (silicon, selenium, germanium, etc.). It is dubbed indicator, digital and word display in circuit and device. It has positive and negative poles. The short leg is negative pole, the long one is positive pole.
Resistor:Resistor is the electronic component in the circuit, which limits and regulates current flow. Its unit is (Ω). The units larger than ohms are kiloohms (KΩ) and megaohms (MΩ). When in use, in addition to the size of the resistance, you must also pay attention to its power. In the project, the leads at both ends of the resistor should be bent at a 90° angle to fit the breadboard properly. If the lead is too long, it can be cut to an appropriate length.
A breadboard is used to build and test circuits quickly before finalizing any circuit design. The breadboard has many holes into which circuit components like ICs and resistors can be inserted. A typical breadboard is shown below:
The bread board has strips of metal which run underneath the board and connect the holes on the top of the board. The metal strips are laid out as shown below. Note that the top and bottom rows of holes are connected horizontally while the remaining holes are connected vertically.
To use the bread board, the legs of components are placed in the holes. Each set of holes connected by a metal a strip underneath forms anode
4.Circuit Connection
We follow below diagram from the experimental schematic link. Here we use digital pin 10. We connect LED to a 220 ohm resistor to avoid high current damaging the LED.
Connection for V4.0
Connection for 2560
5.Sample Code
/* keyestudio super learning kit Project 2 Blink http//www.keyestudio.com
- /
int ledPin = 10; // define digital pin 10. void setup() { pinMode(ledPin, OUTPUT);// define pin with LED connected as output. } void loop() { digitalWrite(ledPin, HIGH); // set the LED on. delay(1000); // wait for a second. digitalWrite(ledPin, LOW); // set the LED off. delay(1000); // wait for a second } //////////////////////////////////////////////////////////////////
6.Test Result
After uploading this program, in the experiment, you will see the LED connected to pin 10 turning on and off, with an interval of approximate one second. In this way, blinking LED experiment is now completed. Thank you!
For projects in detail, please navigate link: