interface – Blog eTechPath https://blog.etechpath.com Tue, 03 Jan 2023 12:37:36 +0000 en-US hourly 1 https://wordpress.org/?v=6.5.5 https://blog.etechpath.com/wp-content/uploads/2017/08/BrandLogo12-150x150.png interface – Blog eTechPath https://blog.etechpath.com 32 32 How to interface DHT11 DHT22 Temperature sensor with Raspberry Pi https://blog.etechpath.com/how-to-interface-dht11-dht22-temperature-sensor-with-raspberry-pi/ https://blog.etechpath.com/how-to-interface-dht11-dht22-temperature-sensor-with-raspberry-pi/#respond Sun, 21 Nov 2021 21:37:39 +0000 https://blog.etechpath.com/?p=541 About:
In this tutorial i will explain how to interface and program DHT11/22 temperature sensor with Raspberry Pi. I have used adafruit python library to program these sensors in python shell.




Things you will need:
Raspberry Pi (any model will work)
DHT11 or DHT22
4k7 Resistor




Circuit Diagram:

Circuit diagram

Python Code:

#!/usr/bin/python
# Name: DHT11/DHT22Interfacing Temperature sensor with raspberry Pi
# Author: Pranay Sawarkar
# Website: www.etechpath.com
# Copyright: Creative Common

import Adafruit_DHT

# sensor = Adafruit_DHT.DHT22
sensor = Adafruit_DHT.DHT11


# Sensor connected to Raspberry Pi GPIO4.
pin = 4

humidity, temperature = Adafruit_DHT.read_retry(sensor, pin)

if humidity is not None and temperature is not None:
    print('Temperature={0:0.1f}*C  Humidity={1:0.1f}%'.format(temperature, humidity))
else:
    print('Failed to capture reading. Please Try again!')

 




Steps:

  1. Connect your temperature sensor to GPIO4 of your raspberry pi  and don’t forget to connect 4k7 pull up resistor between vcc and data output pin. You can use any 4k7 to 10k range resistor for pull up purpose.
  2. Power on your raspberry pi and open terminal.
  3. First we will download and install adafruit library for DHT sensors,
    sudo apt-get update
    git clone https://github.com/adafruit/Adafruit_Python_DHT.git
  4. Install python essential files. (if you are using it for first time)
    sudo apt-get install build-essential python-dev
    sudo python setup.py install
  5. Now your raspberry pi is ready to run the adafruit dht python program,
  6. Copy main python code at home directory in a empty file and name it as dht.py (or download ready dht.py file from download section and copy it to your raspberry pi home directory).
  7. Now you can use bellow command to check the sensor data by running this python program from your raspbery pi terminal,
    sudo python dht.py

    You will get output like this,



 

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How to interface Nextion HMI with Arduino Mega2560 and learn how to use Nextion editor and program tags in Arduino https://blog.etechpath.com/how-to-interface-nextion-hmi-with-arduino-mega2560-and-learn-how-to-use-nextion-editor-and-program-tags-in-arduino/ https://blog.etechpath.com/how-to-interface-nextion-hmi-with-arduino-mega2560-and-learn-how-to-use-nextion-editor-and-program-tags-in-arduino/#comments Wed, 14 Feb 2018 07:00:18 +0000 https://blog.etechpath.com/?p=513 About:
Nextion is a smart hardware HMI (Human Machine Interface) solution published by ITEAD that provides visualization and control interface between human and machine. Nextion HMI comes with simple serial interface and can be easily communicate with Arduino, raspberry pi and other serial Interface compatible hardware’s.
In this post, I will explain how to draw basic HMI screens, setting tag names and reading tags using Arduino.



Circuit Diagram:

NextionHMI_Arduino Mega2560
Circuit Diagram



Nextion HMI Arduino Mega 2560
Prototype




Nextion HMI Designing:
Watch bellow video for complete tutorial on how to operate Nextion HMI graphic designing software.






Arduino Code:
Note: I am using common anode RGB LED for output testing purpose. So I have written this code to operate common anode LED as output. If you want to drive relays instead of LED, you will need to change the code a bit.

/***************************************************************************************************************
*    Nextion HMI Basic Example : Three Buttons
*    Version 1.0
*    Created By: Pranay Sawarkar
*         Email: admin@blog.etechpath.com
*    All Rights Reserved © 2018 www.etechpath.com
*    
*    Download necessary libraries from the links mentioned in download section in the post,
*    Post Link: https://blog.etechpath.com/how-to-interface-nextion-hmi-with-arduino-mega2560-and-learn-how-to-use-nextion-editor-and-program-tags-in-arduino
*
*************************************************************************************************************************/

#include "Nextion.h"
 
int S1 = 2, S2 = 3, S3 = 4;

NexDSButton bt0 = NexDSButton(0, 2, "bt0");
NexDSButton bt1 = NexDSButton(0, 3, "bt1");
NexDSButton bt2 = NexDSButton(0, 4, "bt2");
 
char buffer[100] = {0};
 
NexTouch *nex_listen_list[] = 
{
    &bt0, &bt1, &bt2,
    NULL
};
void setup(void)
{    
    pinMode(2,OUTPUT);
    pinMode(3,OUTPUT);
    pinMode(4,OUTPUT);
    digitalWrite(S1, HIGH);
    digitalWrite(S2, HIGH);
    digitalWrite(S3, HIGH);
    nexInit();
    bt0.attachPop(bt0PopCallback, &bt0);
    bt1.attachPop(bt1PopCallback, &bt1);
    bt2.attachPop(bt2PopCallback, &bt2);
    dbSerialPrintln("setup done"); 
}
void loop(void)
{   
    nexLoop(nex_listen_list);
}
 
void bt0PopCallback(void *ptr)
{
    uint32_t dual_state;
    NexDSButton *btn = (NexDSButton *)ptr;
    dbSerialPrintln("Callback");
    dbSerialPrint("ptr=");
    dbSerialPrintln((uint32_t)ptr); 
    memset(buffer, 0, sizeof(buffer)); 
    bt0.getValue(&dual_state);
    if(dual_state){digitalWrite(S1, LOW);}else{digitalWrite(S1, HIGH);}
}
void bt1PopCallback(void *ptr)
{
    uint32_t dual_state;
    NexDSButton *btn = (NexDSButton *)ptr;    
    dbSerialPrintln("Callback");
    dbSerialPrint("ptr=");
    dbSerialPrintln((uint32_t)ptr); 
    memset(buffer, 0, sizeof(buffer));   
    bt1.getValue(&dual_state); 
    if(dual_state){digitalWrite(S2, LOW);}else{digitalWrite(S2, HIGH);}
}
void bt2PopCallback(void *ptr)
{
    uint32_t dual_state;
    NexSButton *btn = (NexDSButton *)ptr;
    dbSerialPrintln("Callback");
    dbSerialPrint("ptr=");
    dbSerialPrintln((uint32_t)ptr); 
    memset(buffer, 0, sizeof(buffer));
    bt2.getValue(&dual_state);
    if(dual_state){digitalWrite(S3, LOW);}else{digitalWrite(S3, HIGH);}
}





HMI with Arduino working video:

https://www.youtube.com/watch?v=2RTYilN8xvs



Downloads :

Nextion Library

Nextion HMI file

Nextion TFT file

HMI Images

Arduino Code

 

 

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How to Control MAX7219 LED Matrix with ESP8266 WiFi Module https://blog.etechpath.com/how-to-control-max7219-led-matrix-with-esp8266-wifi-module/ https://blog.etechpath.com/how-to-control-max7219-led-matrix-with-esp8266-wifi-module/#comments Sat, 02 Dec 2017 00:40:20 +0000 https://blog.etechpath.com/?p=496 About this Project:
In this project we will learn how to interfacing ESP8266 module with MAX7219 matrix display to scrolling text message from web user interface. We will use Arduino IDE to program ESP module in this project. I am using MajicDesigns MD_MAX72xx library for running this project, also the code is very similar to included example in the library with some improvements in web user interface html code.




Components:

  1. MAX7219 8×8 LED Matrix
  2. ESP8266 Node MCU
  3. USB Cable for programming and power

Circuit Diagram:

Steps: 

      1. Connect the circuit as shown above.
      2. Install Arduino IDE form arduino website. After that install ESP8266 board and library in Arduino IDE.
      3. Download and install MD_MAX7219 Library from download section for driving MAX7219 matrix. For using this library you will need to edit MAX72xx.h file for configure the type of LED matrix you are using. In this project we are using FC-16 Chinese module.
      4. Download code ino file from download section and open it with Arduino IDE.
      5. You will need to edit WiFi network SSID and Password inside your code before flashing it in ESP module.
        const char* ssid = "your SSID";                   // edit your wifi SSID here
        const char* password = "your Password";            // edit your wifi password here
      6. Select board to NodeMCU and flash the code in ESP module.
      7. Power up the circuit and you will see IP address of your ESP module allocated by your WiFi network on Matrix display. (watch video)



    1. Now open that IP address in any browser connected in same network. And you will see web user interface to enter text.
    2. For detailed procedure of configuring WiFi module with your home network and using web interface, please watch embedded YouTube video linked at the bottom of this page.

Code:

//Link: https://blog.etechpath.com

#include <ESP8266WiFi.h>
#include <MD_MAX72xx.h>
#include <SPI.h>

#define	PRINT_CALLBACK	0
#define DEBUG 0
#define LED_HEARTBEAT 0

#if DEBUG
#define	PRINT(s, v)	{ Serial.print(F(s)); Serial.print(v); }
#define PRINTS(s)   { Serial.print(F(s)); }
#else
#define	PRINT(s, v)
#define PRINTS(s)
#endif

#if LED_HEARTBEAT
#define HB_LED  D2
#define HB_LED_TIME 500 // in milliseconds
#endif

#define	MAX_DEVICES	4

#define	CLK_PIN		D5 // or SCK
#define	DATA_PIN	D7 // or MOSI
#define	CS_PIN		D8 // or SS

// SPI hardware interface
//MD_MAX72XX mx = MD_MAX72XX(CS_PIN, MAX_DEVICES);
#define HARDWARE_TYPE MD_MAX72XX::PAROLA_HW  //edit this as per your LED matrix hardware type
MD_MAX72XX mx = MD_MAX72XX(HARDWARE_TYPE, CS_PIN, MAX_DEVICES);
// Arbitrary pins
//MD_MAX72XX mx = MD_MAX72XX(DATA_PIN, CLK_PIN, CS_PIN, MAX_DEVICES);

// WiFi login parameters - network name and password
const char* ssid = "your SSID";                   // edit your wifi SSID here
const char* password = "your Password";            // edit your wifi password here

// WiFi Server object and parameters
WiFiServer server(80);

// Global message buffers shared by Wifi and Scrolling functions
const uint8_t MESG_SIZE = 255;
const uint8_t CHAR_SPACING = 1;
const uint8_t SCROLL_DELAY = 75;

char curMessage[MESG_SIZE];
char newMessage[MESG_SIZE];
bool newMessageAvailable = false;

char WebResponse[] = "HTTP/1.1 200 OK\nContent-Type: text/html\n\n";

char WebPage[] =
"<!DOCTYPE html>" \
"<html>" \
"<head>" \
"<title>eTechPath MAX7219 ESP8266</title>" \
"<style>" \
"html, body" \ 
"{" \
"width: 600px;" \
"height: 400px;" \
"margin: 0px;" \
"border: 0px;" \
"padding: 10px;" \
"background-color: white;" \
"}" \
"#container " \
"{" \
"width: 100%;" \
"height: 100%;" \
"margin-left: 200px;" \
"border: solid 2px;" \
"padding: 10px;" \
"background-color: #b3cbf2;" \
"}" \          
"</style>"\
"<script>" \
"strLine = \"\";" \
"function SendText()" \
"{" \
"  nocache = \"/&nocache=\" + Math.random() * 1000000;" \
"  var request = new XMLHttpRequest();" \
"  strLine = \"&MSG=\" + document.getElementById(\"txt_form\").Message.value;" \
"  request.open(\"GET\", strLine + nocache, false);" \
"  request.send(null);" \
"}" \
"</script>" \
"</head>" \
"<body>" \
"<div id=\"container\">"\
"<H1><b>WiFi MAX7219 LED Matrix Display</b></H1>" \ 
"<form id=\"txt_form\" name=\"frmText\">" \
"<label>Msg:<input type=\"text\" name=\"Message\" maxlength=\"255\"></label><br><br>" \
"</form>" \
"<br>" \
"<input type=\"submit\" value=\"Send Text\" onclick=\"SendText()\">" \
"<p><b>Visit Us at</b></p>" \ 
"<a href=\"http://www.eTechPath.com\">www.eTechPath.com</a>" \
"</div>" \
"</body>" \
"</html>";

char *err2Str(wl_status_t code)
{
  switch (code)
  {
  case WL_IDLE_STATUS:    return("IDLE");           break; // WiFi is in process of changing between statuses
  case WL_NO_SSID_AVAIL:  return("NO_SSID_AVAIL");  break; // case configured SSID cannot be reached
  case WL_CONNECTED:      return("CONNECTED");      break; // successful connection is established
  case WL_CONNECT_FAILED: return("CONNECT_FAILED"); break; // password is incorrect
  case WL_DISCONNECTED:   return("CONNECT_FAILED"); break; // module is not configured in station mode
  default: return("??");
  }
}
uint8_t htoi(char c)
{
  c = toupper(c);
  if ((c >= '0') && (c <= '9')) return(c - '0');
  if ((c >= 'A') && (c <= 'F')) return(c - 'A' + 0xa);
  return(0);
}
boolean getText(char *szMesg, char *psz, uint8_t len)
{
  boolean isValid = false;  // text received flag
  char *pStart, *pEnd;      // pointer to start and end of text
  // get pointer to the beginning of the text
  pStart = strstr(szMesg, "/&MSG=");
  if (pStart != NULL)
  {
    pStart += 6;  // skip to start of data
    pEnd = strstr(pStart, "/&");
    if (pEnd != NULL)
    {
      while (pStart != pEnd)
      {
        if ((*pStart == '%') && isdigit(*(pStart+1)))
        {
          // replace %xx hex code with the ASCII character
          char c = 0;
          pStart++;
          c += (htoi(*pStart++) << 4);
          c += htoi(*pStart++);
          *psz++ = c;
        }
        else
          *psz++ = *pStart++;
      }
      *psz = '\0'; // terminate the string
      isValid = true;
    }
  }
  return(isValid);
}
void handleWiFi(void)
{
  static enum { S_IDLE, S_WAIT_CONN, S_READ, S_EXTRACT, S_RESPONSE, S_DISCONN } state = S_IDLE;
  static char szBuf[1024];
  static uint16_t idxBuf = 0;
  static WiFiClient client;
  static uint32_t timeStart;

  switch (state)
  {
  case S_IDLE:   // initialise
    PRINTS("\nS_IDLE");
    idxBuf = 0;
    state = S_WAIT_CONN;
    break;
  case S_WAIT_CONN:   // waiting for connection
    {
      client = server.available();
      if (!client) break;
      if (!client.connected()) break;
#if DEBUG
      char szTxt[20];
      sprintf(szTxt, "%03d:%03d:%03d:%03d", client.remoteIP()[0], client.remoteIP()[1], client.remoteIP()[2], client.remoteIP()[3]);
      PRINT("\nNew client @ ", szTxt);
#endif
      timeStart = millis();
      state = S_READ;
    }
    break;
  case S_READ: // get the first line of data
    PRINTS("\nS_READ");
    while (client.available())
    {
      char c = client.read();
      if ((c == '\r') || (c == '\n'))
      {
        szBuf[idxBuf] = '\0';
        client.flush();
        PRINT("\nRecv: ", szBuf);
        state = S_EXTRACT;
      }
      else
        szBuf[idxBuf++] = (char)c;
    }
    if (millis() - timeStart > 1000)
    {
      PRINTS("\nWait timeout");
      state = S_DISCONN;
    }
    break;
  case S_EXTRACT: // extract data
    PRINTS("\nS_EXTRACT");
    // Extract the string from the message if there is one
    newMessageAvailable = getText(szBuf, newMessage, MESG_SIZE);
    PRINT("\nNew Msg: ", newMessage);
    state = S_RESPONSE;
    break;
  case S_RESPONSE: // send the response to the client
    PRINTS("\nS_RESPONSE");
    // Return the response to the client (web page)
    client.print(WebResponse);
    client.print(WebPage);
    state = S_DISCONN;
    break;
  case S_DISCONN: // disconnect client
    PRINTS("\nS_DISCONN");
    client.flush();
    client.stop();
    state = S_IDLE;
    break;

  default:  state = S_IDLE;
  }
}
void scrollDataSink(uint8_t dev, MD_MAX72XX::transformType_t t, uint8_t col)
// Callback function for data that is being scrolled off the display
{
#if PRINT_CALLBACK
  Serial.print("\n cb ");
  Serial.print(dev);
  Serial.print(' ');
  Serial.print(t);
  Serial.print(' ');
  Serial.println(col);
#endif
}
uint8_t scrollDataSource(uint8_t dev, MD_MAX72XX::transformType_t t)
// Callback function for data that is required for scrolling into the display
{
  static enum { S_IDLE, S_NEXT_CHAR, S_SHOW_CHAR, S_SHOW_SPACE } state = S_IDLE;
  static char		*p;
  static uint16_t	curLen, showLen;
  static uint8_t	cBuf[8];
  uint8_t colData = 0;
  // finite state machine to control what we do on the callback
  switch (state)
  {
  case S_IDLE: // reset the message pointer and check for new message to load
    PRINTS("\nS_IDLE");
    p = curMessage;      // reset the pointer to start of message
    if (newMessageAvailable)  // there is a new message waiting
    {
      strcpy(curMessage, newMessage); // copy it in
      newMessageAvailable = false;
    }
    state = S_NEXT_CHAR;
    break;
  case S_NEXT_CHAR: // Load the next character from the font table
    PRINTS("\nS_NEXT_CHAR");
    if (*p == '\0')
      state = S_IDLE;
    else
    {
      showLen = mx.getChar(*p++, sizeof(cBuf) / sizeof(cBuf[0]), cBuf);
      curLen = 0;
      state = S_SHOW_CHAR;
    }
    break;
  case S_SHOW_CHAR:	// display the next part of the character
    PRINTS("\nS_SHOW_CHAR");
    colData = cBuf[curLen++];
    if (curLen < showLen)
      break;
    // set up the inter character spacing
    showLen = (*p != '\0' ? CHAR_SPACING : (MAX_DEVICES*COL_SIZE)/2);
    curLen = 0;
    state = S_SHOW_SPACE;
    // fall through
  case S_SHOW_SPACE:	// display inter-character spacing (blank column)
    PRINT("\nS_ICSPACE: ", curLen);
    PRINT("/", showLen);
    curLen++;
    if (curLen == showLen)
      state = S_NEXT_CHAR;
    break;
  default:
    state = S_IDLE;
  }
  return(colData);
}
void scrollText(void)
{
  static uint32_t	prevTime = 0;
  // Is it time to scroll the text?
  if (millis() - prevTime >= SCROLL_DELAY)
  {
    mx.transform(MD_MAX72XX::TSL);	// scroll along - the callback will load all the data
    prevTime = millis();			// starting point for next time
  }
}
void setup()
{
#if DEBUG
  Serial.begin(115200);
  PRINTS("\n[MD_MAX72XX WiFi Message Display]\nType a message for the scrolling display from your internet browser");
#endif
#if LED_HEARTBEAT
  pinMode(HB_LED, OUTPUT);
  digitalWrite(HB_LED, LOW);
#endif
  // Display initialisation
  mx.begin();
  mx.setShiftDataInCallback(scrollDataSource);
  mx.setShiftDataOutCallback(scrollDataSink);
  curMessage[0] = newMessage[0] = '\0';
  // Connect to and initialise WiFi network
  PRINT("\nConnecting to ", ssid);
  WiFi.begin(ssid, password);
  while (WiFi.status() != WL_CONNECTED)
  {
    PRINT("\n", err2Str(WiFi.status()));
    delay(500);
  }
  PRINTS("\nWiFi connected");
  // Start the server
  server.begin();
  PRINTS("\nServer started");
  // Set up first message as the IP address
  sprintf(curMessage, "%03d:%03d:%03d:%03d", WiFi.localIP()[0], WiFi.localIP()[1], WiFi.localIP()[2], WiFi.localIP()[3]);
  PRINT("\nAssigned IP ", curMessage);
}
void loop()
{
#if LED_HEARTBEAT
  static uint32_t timeLast = 0;
  if (millis() - timeLast >= HB_LED_TIME)
  {
    digitalWrite(HB_LED, digitalRead(HB_LED) == LOW ? HIGH : LOW);
    timeLast = millis();
  }
#endif
  handleWiFi();
  scrollText();
}

Downloads:

  1. Arduino IDE
  2. ESP8266 Arduino Library
  3. MajicDesigns MD_MAX7219 Library
  4. Code.ino

Video:

How to solve mirror image and orientation problems of matrix display if you are using old MD_MAX72xx library.

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How to control RGB LED wirelessly using ESP8266 WiFi web interface https://blog.etechpath.com/how-to-control-rgb-led-wirelessly-using-esp8266-wifi-web-interface/ https://blog.etechpath.com/how-to-control-rgb-led-wirelessly-using-esp8266-wifi-web-interface/#comments Tue, 21 Nov 2017 22:59:50 +0000 https://blog.etechpath.com/?p=476 About:

In this project we are going to control 1 watt RGB full color LED diode using WiFi module ESP8266-01. You can use any WiFi enabled device to access web interface to control this RGB LED. Watch video at the bottom of this page.




Things you will need: 

  • 1W RGB LED
  • ESP-01  WiFi module
  • 10Ω Resistance
  • ASM1117 3.3v  (or any 3.3v voltage source)
  • USB to TTL converter (for programming esp-01)
  • Momentary push button (optional)
  • Android / Apple / Windows  Phone or any WiFi enabled Laptop / Desktop (to control RGB LED)

Circuit Diagram for programming ESP-01 : 

esp-01_circuit

Steps :

    1. Connect the circuit on breadboard as shown in above circuit diagram for programming ESP-01 WiFi module. You must use only 3.3v logic setting in TTL device.
    2. In this tutorial we will used Arduino IDE to download code into ESP module. So, install Arduino IDE and add supporting board manager and ESP library into it. (Download links are given in download section)



  1. Download and save source code on your computer and open it up using Arduino IDE.
  2. Connect USB to TTL module to your computer.
  3. Open Arduino IDE – Select board ‘Generic ESP8266 Module’ – Select Port of your TTL device (Here’s How to)
  4. Open downloaded code.ino file into arduino and upload the code into ESP module by pressing upload button.
  5. After uploading, Disconnect the ESP module from USB-TTL module and connect it to RGB LED as shown in bellow diagram.

Circuit Diagram for connecting RGB LED:

Steps: 

    1. Connect the final circuit as shown in above diagram and power it up using 5v battery or wall adapter.
    2. ESP module will boot up and LED light will show fade effect in all three colors at startup.



  1. Then open your device WiFi in discovery mode and you will see a new WiFi access point, named as RGB in discovery list.
  2. Connect that WiFi access point, Open any web browser in that device and open ip address 192.168.1.1 , thats it, you will see a colorful RGB control screen to control your wireless RGB LED.
        Note: Do not feed more than 3.3v to ESP-01 module

Source Code : 

/* RGB web server with ESP8266-01 (ESP-01)
* There are only 2 GPIOs available in ESP-01: 0 and 2
* but RX and TX can also be used as: 3 and 1
* Wiring Circuit 
* 0=Red (GPIO0) D3
* 2=Green (GPIO2) D4
* 3=Blue (GPIO3) Rx
* www.etechpath.com
*/

#include <ESP8266WiFi.h>
#include <DNSServer.h>
#include <ESP8266WebServer.h>

const char *ssid = "RGB";
//Uncomment below line if you wish to set a password for ESP wifi network...
// const char *password = "87654321";  

const byte DNS_PORT = 53;
IPAddress apIP(192, 168, 1, 1);   //IP address of your ESP 
DNSServer dnsServer;
ESP8266WebServer webServer(80);

//Webpage html Code
String webpage = ""
"<!DOCTYPE html><html><head><title>RGB control eTechPath.com</title><meta name='mobile-web-app-capable' content='yes' />"
"<meta name='viewport' content='width=device-width' /></head><body style='margin: 0px; padding: 0px;'>"
"<canvas id='colorspace'></canvas>"
"</body>"
"<script type='text/javascript'>"
"(function () {"
" var canvas = document.getElementById('colorspace');"
" var ctx = canvas.getContext('2d');"
" function drawCanvas() {"
" var colours = ctx.createLinearGradient(0, 0, window.innerWidth, 0);"
" for(var i=0; i <= 360; i+=10) {"
" colours.addColorStop(i/360, 'hsl(' + i + ', 100%, 50%)');"
" }"
" ctx.fillStyle = colours;"
" ctx.fillRect(0, 0, window.innerWidth, window.innerHeight);"
" var luminance = ctx.createLinearGradient(0, 0, 0, ctx.canvas.height);"
" luminance.addColorStop(0, '#ffffff');"
" luminance.addColorStop(0.05, '#ffffff');"
" luminance.addColorStop(0.5, 'rgba(0,0,0,0)');"
" luminance.addColorStop(0.95, '#000000');"
" luminance.addColorStop(1, '#000000');"
" ctx.fillStyle = luminance;"
" ctx.fillRect(0, 0, ctx.canvas.width, ctx.canvas.height);"
" }"
" var eventLocked = false;"
" function handleEvent(clientX, clientY) {"
" if(eventLocked) {"
" return;"
" }"
" function colourCorrect(v) {"
" return Math.round(1023-(v*v)/64);"
" }"
" var data = ctx.getImageData(clientX, clientY, 1, 1).data;"
" var params = ["
" 'r=' + colourCorrect(data[0]),"
" 'g=' + colourCorrect(data[1]),"
" 'b=' + colourCorrect(data[2])"
" ].join('&');"
" var req = new XMLHttpRequest();"
" req.open('POST', '?' + params, true);"
" req.send();"
" eventLocked = true;"
" req.onreadystatechange = function() {"
" if(req.readyState == 4) {"
" eventLocked = false;"
" }"
" }"
" }"
" canvas.addEventListener('click', function(event) {"
" handleEvent(event.clientX, event.clientY, true);"
" }, false);"
" canvas.addEventListener('touchmove', function(event){"
" handleEvent(event.touches[0].clientX, event.touches[0].clientY);"
"}, false);"
" function resizeCanvas() {"
" canvas.width = window.innerWidth;"
" canvas.height = window.innerHeight;"
" drawCanvas();"
" }"
" window.addEventListener('resize', resizeCanvas, false);"
" resizeCanvas();"
" drawCanvas();"
" document.ontouchmove = function(e) {e.preventDefault()};"
" })();"
"</script></html>";
void handleRoot() 
{
// Serial.println("handle root..");
String red = webServer.arg(0); // read RGB arguments
String green = webServer.arg(1);  // read RGB arguments
String blue = webServer.arg(2);  // read RGB arguments

//for common anode
analogWrite(0, red.toInt());
analogWrite(2, green.toInt());
analogWrite(3, blue.toInt());
//for common cathode
//analogWrite(0,1023 - red.toInt());
//analogWrite(2,1023 - green.toInt());
//analogWrite(3,1023 - blue.toInt());
webServer.send(200, "text/html", webpage);
}
void setup() 
{
pinMode(0, OUTPUT);
pinMode(2, OUTPUT);
pinMode(3, OUTPUT);

analogWrite(0, 1023);
analogWrite(2, 1023);
analogWrite(3, 1023);
delay(1000);
WiFi.mode(WIFI_AP);
WiFi.softAPConfig(apIP, apIP, IPAddress(255, 255, 255, 0));
WiFi.softAP(ssid);
dnsServer.start(DNS_PORT, "rgb", apIP);
webServer.on("/", handleRoot);
webServer.begin();
testRGB();
}
void loop() 
{
dnsServer.processNextRequest();
webServer.handleClient();
}
void testRGB() 
{ 
// fade in and out of Red, Green, Blue
analogWrite(0, 1023); // Red off
analogWrite(2, 1023); // Green off
analogWrite(3, 1023); // Blue off

fade(0); // Red fade effect
fade(2); // Green fade effect
fade(3); // Blue fade effect
}
void fade(int pin) 
{
for (int u = 0; u < 1024; u++) 
{
analogWrite(pin, 1023 - u);
delay(1);
}
for (int u = 0; u < 1024; u++) 
{
analogWrite(pin, u);
delay(1);
}
}

 





Downloads:

  1. Code.ino
  2. Arduino IDE
  3. ESP8266 Board link for IDE board manager
  4. ESP8266 Arduino Library

 

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