Ks0183 keyestudio Multi-purpose Shield V1: Difference between revisions

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==Introduction==
==Introduction==
Multi-purpose Shield V1 is a learning board based on Arduino. No need for soldering and connection.Download the program to complete experiment.  
Multi-purpose Shield V1 is a learning board based on Arduino. No need for soldering and connection.Download the program to complete experiment. <br>
It is multi-purpose and we offer code libraries of all modules that have been tested. You can use them directly.  
It is multi-purpose and we offer code libraries of all modules that have been tested. You can use them directly. <br>
There are extension ports on the shield to help you to complete other experiments.
There are extension ports on the shield to help you to complete other experiments.<br>
<br>
<br>


<br>[[File:KS0183 (2).jpg|500px|frameless|thumb]]<br>


==Specification==
==Specification==
Line 39: Line 38:
== Hookup Guide==
== Hookup Guide==
Simply plug the shield into UNO R3 board.
Simply plug the shield into UNO R3 board.
==Connection Diagram==
Upload program to keyestudio UNO R3 BOARD, and plug this shield into UNO R3 BOARD.<br>
<br>[[File:ks0183-1.png|500px|frameless|thumb]]<br>
<br>[[File:ks0183-1.png|500px|frameless|thumb]]<br>




==Upload the Code==
==Upload the Code==
Note: Before compile the code, do remember to add the necessary libraries inside the libraries directory of Arduino IDE.
Note: Before compile the code, do remember to add the necessary libraries inside the libraries directory of Arduino IDE.<br>
You can download all the libraries from the link here:  
You can download all the libraries from the link here: <br>
https://drive.google.com/open?id=1Fsr5NW8Ez8ziYh0jVmiviS9ldvR9NDei
https://drive.google.com/open?id=1Fsr5NW8Ez8ziYh0jVmiviS9ldvR9NDei<br>
You can click here to download the code or directly copy the code below.
You can [https://drive.google.com/open?id=1UQF9_II_Y10PdQY6PQcMzXncld6LpOrW click here] to download the code or directly copy the code below.


<pre>
<pre>
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</pre>
</pre>


<br>
== Test Result==
== Test Result==
Done uploading the code to the board, the power led 2 is normally on, open the serial monitor and set the baud rate to 9600.
Done uploading the code to the board, the power led 2 is normally on, open the serial monitor and set the baud rate to 9600.<br>
Aimed at the IR receiver, press the buttons on IR remote control, you should see the decoding value of button is displayed on the monitor.  
Aimed at the IR receiver, press the buttons on IR remote control, you should see the decoding value of button is displayed on the monitor. <br>
Do not press too long, or else appear the data error like FFFFFF.  <br>
Do not press too long, or else appear the data error like FFFFFF.  <br>
<br>[[File:ks0183 FF.png|500px|frameless|thumb]]<br>
If press the SW1 button, passive buzzer beeps and then RGB LED will emit the red, green and blue light in sequence. Also the red led3 and blue led 4 light up, circularly.
<br>[[File:KS0183 Connect.png|500px|frameless|thumb]]<br>


If press the SW2 button, passive buzzer stops beeping and LEDs not light.<br>
Then open the serial monitor and set the baud rate to 9600. Press the SW2 button again, the serial monitor will display the data shown below.
<br>[[File:ks0183 Display.png|500px|frameless|thumb]]<br>




From the data shown on the monitor, you can get the details as follows:<br>
The first column is status OK. <br>
The second column is the humidity value measured by DHT11 sensor;<br>
The third column is the temperature value measured by DHT11 sensor;<br>
The fourth column is the analog value measured by potentiometer, in the range of 0-1023;<br>
The fifth column is the analog value measured by photocell. The stronger the light is, the greater the value is.<br>
The sixth column is the analog value measured by LM35 temperature sensor, which can be used to calculate the specific temperature value.<br>
<br>


==Resources ==
==Resources ==
Line 235: Line 247:
'''PDF Format:''' <br>
'''PDF Format:''' <br>
https://drive.google.com/open?id=1JpWm7bxEAxZNm8ZbqsUbIhkTi0n7U4bY
https://drive.google.com/open?id=1JpWm7bxEAxZNm8ZbqsUbIhkTi0n7U4bY
<br>


==Get One Now ==
==Get One Now ==
'''Official Website'''
'''Official Website'''<br>
 
http://www.keyestudio.com/keyestudio-multi-purpose-shield-v1.html
http://www.keyestudio.com/keyestudio-multi-purpose-shield-v1.html




[[Category: Shield]]
[[Category: Shield]]

Revision as of 16:19, 21 September 2018

Keyestudio UNO R3 Board

Introduction

Multi-purpose Shield V1 is a learning board based on Arduino. No need for soldering and connection.Download the program to complete experiment.
It is multi-purpose and we offer code libraries of all modules that have been tested. You can use them directly.
There are extension ports on the shield to help you to complete other experiments.


Specification

  • Compatible with main controllers such as UNO R3 and MEGA2560.
  • Comes with 2 LED indicators to show the program status.
  • Comes with 2 switches for external interrupt experiment.
  • Comes with a reset button
  • Comes with DHT11 sensor for measuring temperature and humidity.
  • Comes with a potentiometer for analog input
  • Comes with a passive buzzer for alarm.
  • Comes with a full-color RGB LED
  • Comes with a photocell to detect the brightness of light
  • Comes with LM35D temperature sensor
  • Comes with an infrared receiver
  • 2digital pins(D7 and D8)
  • 1 analog pin(A3)
  • One IIC interface
  • One TTL serial pin


Details

  • Dimensions: 69mm*53mm*19mm
  • Weight: 21g


thumb


Interface Instruction


thumb


Hookup Guide

Simply plug the shield into UNO R3 board.
thumb


Upload the Code

Note: Before compile the code, do remember to add the necessary libraries inside the libraries directory of Arduino IDE.
You can download all the libraries from the link here:
https://drive.google.com/open?id=1Fsr5NW8Ez8ziYh0jVmiviS9ldvR9NDei
You can click here to download the code or directly copy the code below.

#include <IRremote.h>
#include <dht11.h>
dht11 DHT;
#define DHT11_PIN 4

//buzzer pin
int buzzer = 5;

//button pins
int KEY2 = 2;
int KEY3 = 3;

//pin definition of flowing light
int led5 = 13;
int led4 = 12;
int led3 = 11;
int led2 = 10;
int led1 = 9;

int RECV_PIN = 6; //define input pin on Arduino
IRrecv irrecv(RECV_PIN);
decode_results results;

char i=0,flag=2; 
void setup ()
{
  Serial.begin(9600);

  irrecv.enableIRIn(); // Start the receiver

  attachInterrupt(0, falling0, FALLING);
  attachInterrupt(1, falling1, FALLING);

  pinMode(buzzer,OUTPUT);
  digitalWrite(buzzer,HIGH);

  pinMode(led1,OUTPUT);
  pinMode(led2,OUTPUT);
  pinMode(led3,OUTPUT); 
  pinMode(led4,OUTPUT);
  pinMode(led5,OUTPUT);
  for(char i=9;i<14;i++)
   digitalWrite(i,LOW);    
}

void loop()
{
  if(flag==0)
  {
  buzzer_();                //testing buzzer
  led_display();            //testing LED
  }
  if(flag==1)
  { 
  Serial.println("status,  Hum(%),  Tem(C)      analog_val      light_val     lm35_val");
  DHT11();
  Serial.print("");
  analog();                //testing analog input
  Serial.print("");
  Light();
  Serial.print("");
  LM35();
  Serial.println("");
  delay(800);
  }
  if(flag!=0 & flag!=1)
  {
    if (irrecv.decode(&results))
     {
       Serial.println(results.value, HEX);
       irrecv.resume(); // Receive the next value
     }  
  }
}

void DHT11()
{
int chk;
chk = DHT.read(DHT11_PIN);    // READ DATA
switch (chk)
  {
    case DHTLIB_OK:  
                Serial.print("OK        "); 
                Serial.print(DHT.humidity,1);
                Serial.print("");
                Serial.print(DHT.temperature,1);
                break;
    case DHTLIB_ERROR_CHECKSUM: 
                Serial.print("Checksum error        "); 
                break;
    case DHTLIB_ERROR_TIMEOUT: 
                Serial.print("Time out error        "); 
                break;
    default: 
                Serial.print("Unknown error         "); 
                break;
  }
}

void buzzer_(void)
{
 char i;  
 for(i=0;i<80;i++)// output a frequency sound
 { 
  digitalWrite(buzzer,LOW);// sound
  delay(1);//delay1ms 
  digitalWrite(buzzer,HIGH);//not sound
  delay(1);//ms delay 
 } 
 for(i=0;i<100;i++)// output a frequency sound
 { 
  digitalWrite(buzzer,LOW);// sound
  digitalWrite(buzzer,HIGH);//not sound
  delay(2);//2ms delay 
 }
}

void led_display()
{
 digitalWrite(led1,HIGH);
 delay(500);
 digitalWrite(led1,LOW);
 digitalWrite(led2,HIGH);
 delay(500);
 digitalWrite(led2,LOW);
 digitalWrite(led3,HIGH);
 delay(500);
 digitalWrite(led3,LOW);
 digitalWrite(led4,HIGH);
 delay(500);
 digitalWrite(led4,LOW);
 digitalWrite(led5,HIGH);
 delay(500);
 digitalWrite(led5,LOW);
}

void analog()
{
int val;
val=analogRead(A0);
Serial.print(val);
}

void Light()
{
int val;
val=analogRead(A1);
Serial.print(val);
}

void LM35()
{
int val;
val=analogRead(A2);
Serial.print(val);
}

void falling0()
{
flag=0;
}
void falling1()
{
flag=1;
}


Test Result

Done uploading the code to the board, the power led 2 is normally on, open the serial monitor and set the baud rate to 9600.
Aimed at the IR receiver, press the buttons on IR remote control, you should see the decoding value of button is displayed on the monitor.
Do not press too long, or else appear the data error like FFFFFF.

thumb

If press the SW1 button, passive buzzer beeps and then RGB LED will emit the red, green and blue light in sequence. Also the red led3 and blue led 4 light up, circularly.
thumb


If press the SW2 button, passive buzzer stops beeping and LEDs not light.
Then open the serial monitor and set the baud rate to 9600. Press the SW2 button again, the serial monitor will display the data shown below.
thumb


From the data shown on the monitor, you can get the details as follows:
The first column is status OK.
The second column is the humidity value measured by DHT11 sensor;
The third column is the temperature value measured by DHT11 sensor;
The fourth column is the analog value measured by potentiometer, in the range of 0-1023;
The fifth column is the analog value measured by photocell. The stronger the light is, the greater the value is.
The sixth column is the analog value measured by LM35 temperature sensor, which can be used to calculate the specific temperature value.

Resources

Download Address of Libraries:
https://drive.google.com/open?id=1uq5r1EiJnRwRkjKRFLdxZYzkREg8r6BI

PDF Format:
https://drive.google.com/open?id=1JpWm7bxEAxZNm8ZbqsUbIhkTi0n7U4bY

Get One Now

Official Website
http://www.keyestudio.com/keyestudio-multi-purpose-shield-v1.html