Microcontroller 101: Difference between revisions

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=09-04-2024 e̅l̅e̅c̅t̅r̅o̅n̅i̅c̅ ̅e̅n̅v̅i̅r̅o̅n̅m̅e̅n̅t̅s̅=
=09-04-24 e͎l͎e͎c͎t͎r͎i͎c͎ t͎r͎i͎c͎k͎s͎=


https://pzwiki.wdka.nl/mw-mediadesign/images/7/7e/Cricket.mp4
==LOLIN 32 Installation party :~)==


sensors and actuators
[[File:Lolin32.jpeg|200px|thumb|left|Wemos LOLIN32 - ESP32]]
[[File:D32 pro v2.0.0 3 16x9.jpg|600px|thumb|center|Pinout LOLIN D32 PRO]]
 
more info about the lolin32 is here: https://www.wemos.cc/en/latest/d32/d32_pro.html


step 1: download [https://www.arduino.cc/en/software Arduino] software


step 2: download [https://www.silabs.com/developers/usb-to-uart-bridge-vcp-drivers?tab=downloads driver] for microcontroller


==introduction to Arduino==
step 3: install driver


===LOLIN 32 Installation party :~)===
_windows: open Device Manager >> find UART device >> right click and update driver >> select driver


[[File:Lolin32.jpeg|200px|thumb|left|Wemos LOLIN32 - ESP32]]
step 4: install esp32 library in the board manager


step 1: download [https://www.arduino.cc/en/software Arduino] software
==Arduino code==


===Hello World!===
===Hello World!===
in the Arduino program, select the correct board (WEMOS LOLIN32) and select the USB port you are using
(if you are unsure, check the listed ports, unplug and see what changed)
<pre>
<pre>
void setup() {
void setup() {
  Serial.begin(115200);
}
}


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}
}
</pre>
</pre>
open the Serial Monitor in your arduino IDE and set it to 115200, the baudrate that has been set in the setup function, to see the printed messages.
=== Simple Led blink example ===
=== Simple Led blink example ===
[[File:LEDBLINK.png|thumb|center|Simple Led Blink Example]]
[[File:LEDBLINKschematics.png|thumb|center|Simple Led Blink Example Schematics]]


<pre>


<pre>
// always use a "preresistor" with the LED, because the 5v coming from the microcontroller is too much
int ledPin = 13;              //the int ledPin is 13
// a LED only consumes ~2.5 volt, the resistor the other volt
//
int ledPin = 23;              //the int ledPin is 13


void setup() {
void setup() {
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}
}
</pre>
</pre>
==== Traffic light example ====
=== Traffic light example ===
 
[[File:Trafficjam.png|thumb|center]]
[[File:Trafficjamschematics.png|thumb|center]]


<pre>
<pre>
int RedLedPin = 13;                //the int RedLedPin is 13
int RedLedPin = 23;                //the int RedLedPin is 13
int GreenLedPin = 12;              //the int GreenLedPin is 12
int GreenLedPin = 22;              //the int GreenLedPin is 12


void setup() {
void setup() {
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</pre>
</pre>


=16-04-24 ⱤØ฿Ø₮Ⱬ=
=== LDR example ===
example with a light resistor.
keep in mind the LDR pin needs to be a pin with a ADC(analog to digital converter), because you check the analog voltage. on the arduino these are the ANALOG IN pins. on the ESP32 the pins with the ADC(check the pinout graphic)


[[File:LDR example.png|thumb|center]]
[[File:LDRschematics.png|thumb|center]]
<pre>
<pre>
#include <CapacitiveSensor.h>
int LDR = 34;                 //the LDR pin
CapacitiveSensor  sensor = CapacitiveSensor(8,11);      
 
long raw;
void setup() {
void setup(){
  Serial.begin(115200);
  sensor.set_CS_AutocaL_Millis(0xFFFFFFFF);   
  pinMode(LDR,INPUT);       //LDR is an INPUT
  Serial.begin(115200);
  Serial.println("raw");
}
}
void loop(){
 
   raw = sensor.capacitiveSensor(10);
void loop() {
   Serial.println(raw);
   int value = analogRead(LDR); // read the analog value of the LDR
   Serial.println(value);       // print the value of the LDR, open serial monitor
   delay(10);
   delay(10);
}
}
</pre>
</pre>


==Theremin==
=== LDR & speaker example ===
[[File:Ldrspeaker.png|thumb|center]]
[[File:Ldrspeakerschematics.png|thumb|center]]
<pre>
<pre>
#include <CapacitiveSensor.h>
int LDR = 34;                //the LDR pin
int speaker = 23;


CapacitiveSensor   sensor = CapacitiveSensor(8,11);
void setup() {
  Serial.begin(115200);
  pinMode(LDR,INPUT);        //LDR is an INPUT
   pinMode(speaker,OUTPUT);       //speaker is a OUTPUT
}


int speaker = 13;               //connect a speaker between pin 13 and GND
void loop() {
long raw;
  int value = analogRead(LDR); // read the analog value of the LDR
  Serial.println(value);      // print the value of the LDR, open serial monitor
  tone(speaker,value);         //create a frequency on the speaker pin; the frequency hertz is the value
  delay(10);
}
</pre>


=== Poti example ===
[[File:Poti.png|thumb|center]]
[[File:Potischematics.png|thumb|center]]
<pre>
int poti = 34;                //the poti pin


void setup(){
void setup() {
  sensor.set_CS_AutocaL_Millis(0xFFFFFFFF);   
  Serial.begin(115200);
  Serial.begin(115200);
  pinMode(poti,INPUT);       //poti is an INPUT
  Serial.println("raw");
}
}
void loop(){
 
   raw = sensor.capacitiveSensor(10);                 //lowest  450 & highest 750
void loop() {
  raw = min(raw, 750);                              //max value of raw is 750
   int value = analogRead(poti); // read the analog value of the poti
   raw = max(raw, 10);                               //min value of raw is 10
   Serial.println(value);       // print the value of the poti, open serial monitor
  long speakerValue = map(raw,450,750,100,4000);    //scales to value from 450 and 750 to 100 and 4000
   delay(10);
   tone(speaker,speakerValue);                        //plays the frequency (raw) on port 13(speaker)
  Serial.print(raw);
  Serial.print(" ");
  Serial.println(speakerValue);
 
}
}
</pre>
</pre>


==Capactive sensor as button==
=== Poti & speaker example ===
[[File:Potispeaker.png|thumb|center]]
[[File:Potispeakerschematics.png|thumb|center]]
<pre>
<pre>
#include <CapacitiveSensor.h>
//keep in mind you can only use a mini speaker. for bigger speakers you need an amplifier.
int poti = 34;                //the pto pin
int speaker = 23;


CapacitiveSensor   sensor = CapacitiveSensor(8,11);
void setup() {
  Serial.begin(115200);
  pinMode(poti,INPUT);        //poti is an INPUT
  pinMode(speaker,OUTPUT);        //speaker is a OUTPUT
}
 
void loop() {
   int value = analogRead(poti); // read the analog value of the poti
  Serial.println(value);      // print the value of the poti, open serial monitor
  tone(speaker,value);        //create a frequency on the speaker pin; the frequency hertz is the value
  delay(10);
}
</pre>


int speaker = 13;
=== Button & alarm example ===
long raw;
[[File:Buttonspeaker.png|thumb|center]]
[[File:Buttonschematics.png|thumb|center]]
<pre>
int button = 34;
int speaker = 23;


void setup() {
  Serial.begin(115200);  //make usb connection
  pinMode(button, INPUT);    //button is an INPUT
  pinMode(speaker, OUTPUT);    //speaker is an OUTPUT


void setup(){
  sensor.set_CS_AutocaL_Millis(0xFFFFFFFF);   
  Serial.begin(115200);
  Serial.println("raw");
}
}
void loop(){
 
   raw = sensor.capacitiveSensor(10);         //lowest  450 & highest 750
void loop() {
   if(raw > 600){                             //if raw is bigger than 600
   bool value = digitalRead(button);   //read the digital value of button
     Serial.println("touched");               //print "touched"
   if(button){
    tone(speaker,440);                       //play a tone with 440 hz
     Serial.println("start alarm");
    delay(1000);                             //stop 1000 second
    for(int repeter = 0; repeter<5; repeter++){  //repeat 5 times
    noTone(speaker);                         //stop playing the tone
      for(int frequency = 500; frequency<1200; frequency++){    //count from 500 to 1200
        tone(speaker, fequency);   //generate the frequency on the speaker pin
        delay(5);
      }
      notone(speaker);   //turn off the speaker pin
      delay(500);         //
    }
  }else{
    Serial.println("button not pressed");
   }
   }
  delay(10);
 
}
}
</pre>
</pre>


==Servo motor movement between 0 and 90 degrees==
=16-04-24 ๓໐t໐rŞ + ŞēຖŞ໐rŞ = r໐๖໐t=
==sensors==
===humidity===
[[File:Dht22.jpg|200px]]
the DHT22 humidity sensor :)
<pre>
<pre>
//this example controls a standard servo motor and moves it between 0 and 90 degrees
#include <DHT.h>;
//the servo has three different wires
//the red wire is plus and connected to 5v
//the brown wire is minus and connected to GND
//the orange wire is the signal wire and connected to pin 3 (remember the ~-symbol - it means PWM)


#include <Servo.h>
//Constants
#define DHTPIN 21    // what pin we're connected to
#define DHTTYPE DHT22  // DHT 22  (AM2302)
DHT dht(DHTPIN, DHTTYPE); //// Initialize DHT sensor for normal 16mhz Arduino




//Variables
int chk;
float hum;  //Stores humidity value
float temp; //Stores temperature value


Servo theServo;  
void setup()
{
    Serial.begin(9600);
dht.begin();


void setup() {
  Serial.begin(115200);
  theServo.attach(3); 
}
}


void loop() {
void loop()
  for(int i = 0; i < 90; i++){
{
     theServo.write(i);
    //Read data and store it to variables hum and temp
     Serial.println(i);
    hum = dht.readHumidity();
     delay(50);
     temp= dht.readTemperature();
  }
    //Print temp and humidity values to serial monitor
  for(int i = 90; i > 0; i--){
     Serial.print("Humidity: ");
     theServo.write(i);
     Serial.print(hum);
     Serial.println(i);
    Serial.print(" %, Temp: ");
     delay(10);  
     Serial.print(temp);
  }
     Serial.println(" Celsius");
     delay(2000); //Delay 2 sec.
}
}
</pre>
</pre>


==automatic trash can - servo motor connected capactive sensor==
===sound===
[[File:Sound sensorky.jpg|200px]]
 
KY-037 Sound Detection Sensor Module :::;;-))
<pre>
<pre>
#include <Servo.h>
int sensorPin = 21;    // select the input pin for the potentiometer a0 on board, D1 pinout not connected
#include <CapacitiveSensor.h>
int sensorValue = 0;  // variable to store the value coming from the sensor
 


CapacitiveSensor  sensor = CapacitiveSensor(8,11); 


Servo theServo;
long raw;


void setup() {
void setup() {
   Serial.begin(115200);
   // declare the ledPin as an OUTPUT:
  theServo.attach(3); 
   Serial.begin(9600);
  sensor.set_CS_AutocaL_Millis(0xFFFFFFFF);   
   pinMode(22, OUTPUT); //
   Serial.begin(115200);
   Serial.println("raw");
}
}


void loop() {
void loop() {
   raw = sensor.capacitiveSensor(10);    //lowest  450 & highest 750
   // read the value from the sensor:
   if(raw > 600){                       //if raw is bigger than 600
  sensorValue = analogRead(sensorPin);     
     open();                             //do void open
  // turn the ledPin on
     delay(4000);                       //wait for 4 seconds
  Serial.println(sensorValue);
     close();                           //close void opne
 
 
 
 
   if (sensorValue>448) {
     Serial.println("high detected");
    digitalWrite(22, HIGH);
    Serial.println("Blink On");
     delay(2000);
     digitalWrite(22, LOW);
 
   }
   }
}
   else {
 
     digitalWrite(22, LOW);
void open(){
  //open
   for(int i = 0; i < 90; i++){         //count from 0 to 90
    theServo.write(i);                  //move the servo from 0 to 90
    Serial.println(i);
     delay(50);
   }
   }
}
}


void close(){
  //close
  for(int i = 90; i > 0; i--){
    theServo.write(i);
    Serial.println(i);
    delay(10);   
  }
}
</pre>
</pre>


==trash can controlled by serial commands==
===soil moisture===
[[File:Soil moisture sensor.jpg|200px]]
Capacitive Soil Moisture Sensor Module :~)
 
<pre>
<pre>
//in this sketch the servo is controlled by serial commands from the computer
const int dry = 595; // Value for dry sensor
//if you send the letter "o" to the arudino it will execute "void open()"
const int wet = 239; // Value for wet sensor
//if you send the letter "c" to the arduino it will execute "void close()"
#include <Servo.h>  //import the servo library


Servo theServo;    //create a servo
void setup() {
 
   Serial.begin(9600); // Initialize serial communication
void setup() {  
   Serial.begin(115200);           //serial connection
  theServo.attach(3);              //theServo is at port 3 (remeber the ~(PWM)-Symbol
}
}


void loop() {
void loop() {
   if(Serial.available()){        //if there is a serial command comming
   int sensorVal = analogRead(26); // Read moisture sensor value from pin A0
    char command = Serial.read();   //read the serial command
 
    if(command == 'o'){            //is the command and 'o'
  int percentageHumidity = map(sensorVal, wet, dry, 0, 100); // Convert sensor value to percentage
      open();                       //do void open
 
    }
  Serial.print(percentageHumidity); // Print percentage humidity value
    if(command == 'c'){
  Serial.println("%"); // Print % symbol
      close();
  delay(100); // Delay for stability
    }
  }
}
}


void open(){         
</pre>
  //open
 
  for(int i = 0; i < 90; i++){                //count from 0 to 90 with int i
===sonar distance===
    theServo.write(i);                       //i is the servo position
[[File:Sonar sensor.png|200px]]
    Serial.println(i);                       //print the servo position to the serial monitor
 
    delay(50);                               //wait for 50 milliseconds
<pre>
  }
*/
// defines pins numbers
const int trigPin = 21;
const int echoPin = 14;
// defines variables
long duration;
int distance;
void setup() {
  pinMode(trigPin, OUTPUT); // Sets the trigPin as an Output
  pinMode(echoPin, INPUT); // Sets the echoPin as an Input
  Serial.begin(9600); // Starts the serial communication
}
}
 
void loop() {
void close(){
   // Clears the trigPin
   //close
  digitalWrite(trigPin, LOW);
   for(int i = 90; i > 0; i--){
  delayMicroseconds(2);
    theServo.write(i);
   // Sets the trigPin on HIGH state for 10 micro seconds
    Serial.println(i);
  digitalWrite(trigPin, HIGH);
    delay(10);  
  delayMicroseconds(10);
  }
  digitalWrite(trigPin, LOW);
  // Reads the echoPin, returns the sound wave travel time in microseconds
  duration = pulseIn(echoPin, HIGH);
  // Calculating the distance
  distance = duration * 0.034 / 2;
  // Prints the distance on the Serial Monitor
  Serial.print("Distance: ");
  Serial.println(distance);
}
}
</pre>
</pre>
==Potentiometer opening the trash can==
 
===water sensor===
[[File:Water sensor.JPG|200px]]
https://lastminuteengineers.com/water-level-sensor-arduino-tutorial/
 
<pre>
<pre>
//in this sketch the servo is controlled by an potentiometer
// Sensor pins
//a potentiometer is a variable resistor that can be changed by rotation
#define sensorPower 7
#include <Servo.h>  //import the servo library
#define sensorPin A0


Servo theServo;    //create a servo
// Value for storing water level
int val = 0;


void setup() {  
void setup() {
  Serial.begin(115200);           //serial connection
// Set D7 as an OUTPUT
  theServo.attach(3);             //theServo is at port 3 (remeber the ~(PWM)-Symbol
pinMode(sensorPower, OUTPUT);
// Set to LOW so no power flows through the sensor
digitalWrite(sensorPower, LOW);
Serial.begin(9600);
}
}


void loop() {
void loop() {
  int value = analogRead(A0);     //read the analog pin A0 the value is between 0 and 1023
//get the reading from the function below and print it
  value = map(value,0,1023,0,180); //adjust value from 0 to 1023 to 0 and 180 because the servo works with degrees
int level = readSensor();
  theServo.write(value);
Serial.print("Water level: ");
Serial.println(level);
delay(1000);
}
 
//This is a function used to get the reading
int readSensor() {
digitalWrite(sensorPower, HIGH); // Turn the sensor ON
delay(10); // wait 10 milliseconds
val = analogRead(sensorPin); // Read the analog value form sensor
digitalWrite(sensorPower, LOW); // Turn the sensor OFF
return val; // send current reading
}
}
</pre>
</pre>


==painting machine==
==sensor readings as motor control==
 
to merge, the poti value needs to be replaced with the new sensor value, and the map max value adjusted
 
 
DHT merge:


<pre>
<pre>
//in this sketch one poti controls one servo
#include <DHT.h>;
#include <Servo.h>
#include <ESP32Servo.h> //this
 
Servo twister; //this
//Constants
#define DHTPIN 21    // what pin we're connected to
#define DHTTYPE DHT22  // DHT 22  (AM2302)
DHT dht(DHTPIN, DHTTYPE); //// Initialize DHT sensor for normal 16mhz Arduino


Servo jointOne;


void setup() {
//Variables
  Serial.begin(115200);
int chk;
  Serial.println("start");
float hum;  //Stores humidity value
  jointOne.attach(10);
float temp; //Stores temperature value
 
void setup()
{
    Serial.begin(9600);
    dht.begin();
    twister.attach(25); //this
}
}


void loop() {
void loop()
  int value = analogRead(A0);
{
  value = map(value, 0, 1023, 0, 180);
    //Read data and store it to variables hum and temp
  jointOne.write(value);
    hum = dht.readHumidity();
  delay(10);
    temp= dht.readTemperature();
    //Print temp and humidity values to serial monitor
    Serial.print("Humidity: ");
    Serial.print(hum);
    Serial.print(" %, Temp: ");
    Serial.print(temp);
    Serial.println(" Celsius");
    delay(2000); //Delay 2 sec.
   
    int degree = map(temp, 0, 36, 0, 180); //this, update temp with your value
    twister.write(degree);
 
}
}
</pre>
</pre>


==Motor control ==
=23-04-24 l͓̽i͓̽n͓̽k͓̽i͓̽n͓̽g͓̽ t͓̽h͓̽e͓̽ r͓̽e͓̽a͓̽l͓̽m͓̽s͓̽=
 
https://github.com/espressif/arduino-esp32/blob/master/libraries/WiFi/examples/WiFiAccessPoint/WiFiAccessPoint.ino
 
Using the ESP32 to create a hotspot and serve a simple webpage on http://192.168.4.1/ when connected.
 
<pre>
<pre>
//connect the dc-motor to the motorshield motor port 1
/*
//connect a external power source
  WiFiAccessPoint.ino creates a WiFi access point and provides a web server on it.
#include <Adafruit_MotorShield.h>
 
  Steps:
  1. Connect to the access point "yourAp"
  2. Point your web browser to http://192.168.4.1/H to turn the LED on or http://192.168.4.1/L to turn it off
    OR
    Run raw TCP "GET /H" and "GET /L" on PuTTY terminal with 192.168.4.1 as IP address and 80 as port
 
  Created for arduino-esp32 on 04 July, 2018
  by Elochukwu Ifediora (fedy0)
*/
#include <WiFi.h>
#include <WiFiClient.h>
#include <WiFiAP.h>
 
#define LED_BUILTIN 23  // Set the GPIO pin where you connected your test LED or comment this line out if your dev board has a built-in LED
 
// Set these to your desired credentials.
const char *ssid = "joseph";
const char *password = "knierzinger";


Adafruit_MotorShield AFMS = Adafruit_MotorShield();
WiFiServer server(80);
Adafruit_DCMotor *myMotor = AFMS.getMotor(1);




void setup() {
void setup() {
   Serial.begin(115200);        
  pinMode(LED_BUILTIN, OUTPUT);
   AFMS.begin();
 
   myMotor->setSpeed(200);
   Serial.begin(115200);
   myMotor->run(RELEASE);
   Serial.println();
  Serial.println("Configuring access point...");
 
  // You can remove the password parameter if you want the AP to be open.
  // a valid password must have more than 7 characters
  if (!WiFi.softAP(ssid, password)) {
    log_e("Soft AP creation failed.");
    while(1);
  }
  IPAddress myIP = WiFi.softAPIP();
  Serial.print("AP IP address: ");
  Serial.println(myIP);
   server.begin();
 
   Serial.println("Server started");
}
}


void loop() {
  WiFiClient client = server.available();  // listen for incoming clients
  int sensorValue = analogRead(34);
  if (client) {                            // if you get a client,
    Serial.println("New Client.");          // print a message out the serial port
    String currentLine = "";                // make a String to hold incoming data from the client
    while (client.connected()) {            // loop while the client's connected
      if (client.available()) {            // if there's bytes to read from the client,
        char c = client.read();            // read a byte, then
        Serial.write(c);                    // print it out the serial monitor
        if (c == '\n') {                    // if the byte is a newline character


void loop() {
          // if the current line is blank, you got two newline characters in a row.
  myMotor->run(FORWARD);    //forward
          // that's the end of the client HTTP request, so send a response:
  myMotor->setSpeed(255);   //max speed
          if (currentLine.length() == 0) {
  delay(2000);  
            // HTTP headers always start with a response code (e.g. HTTP/1.1 200 OK)
            // and a content-type so the client knows what's coming, then a blank line:
            client.println("HTTP/1.1 200 OK");
            client.println("Content-type:text/html");
            client.println();


  myMotor->run(RELEASE);     //break
            // the content of the HTTP response follows the header:
  delay(2000);  
            client.print("<meta http-equiv='refresh' content='0.1'>");
            client.print("<style>body{background-color:red;}</style><br>");
            int objectValue = map(sensorValue, 0, 4096, 0, 200);
            client.print("<style>.object{background-color:black;}</style><br>");
            client.print("<style>.object{width: 400px;height:400px;}</style><br>");
            client.print("<style>.object{border-radius:"+String(objectValue)+"px; }</style><br>");


  myMotor->run(BACKWARD);   //backward
            client.print("<h1>eviltwin data " + String(sensorValue) + "</h1><br>");
  myMotor->setSpeed(255);   //max speed
            client.print("<div class='object'></div><br>");
  delay(2000);  
            client.print("Click <a href=\"/H\">here</a> to turn ON the LED.<br>");
            client.print("Click <a href=\"/L\">here</a> to turn OFF the LED.<br>");


  myMotor->run(RELEASE);     //break  
            // The HTTP response ends with another blank line:
  delay(2000);  
            client.println();
            // break out of the while loop:
            break;
          } else {    // if you got a newline, then clear currentLine:
            currentLine = "";
          }
        } else if (c != '\r') {  // if you got anything else but a carriage return character,
          currentLine += c;     // add it to the end of the currentLine
        }


        // Check to see if the client request was "GET /H" or "GET /L":
        if (currentLine.endsWith("GET /H")) {
          digitalWrite(LED_BUILTIN, HIGH);              // GET /H turns the LED on
        }
        if (currentLine.endsWith("GET /L")) {
          digitalWrite(LED_BUILTIN, LOW);                // GET /L turns the LED off
        }
      }
    }
    // close the connection:
    client.stop();
    Serial.println("Client Disconnected.");
  }
}
}
</pre>
</pre>
=23-04-24 l͓̽i͓̽n͓̽k͓̽i͓̽n͓̽g͓̽ t͓̽h͓̽e͓̽ r͓̽e͓̽a͓̽l͓̽m͓̽s͓̽=

Latest revision as of 13:14, 3 July 2024


ḿ̬̏ͤͅỉ͔͖̜͌c͕͗ͤ̕̕r̴̨̦͕̝o̯̱̊͊͢c͕͗ͤ̕̕o̯̱̊͊͢ṇ̤͛̒̍t̲̂̓ͩ̑r̴̨̦͕̝o̯̱̊͊͢l̙͖̑̾ͣl̙͖̑̾ͣẹ̿͋̒̕r̴̨̦͕̝ 1̨̹̦͍̀0̗̜͕̅̃1̨̹̦͍̀
                                                                 

09-04-24 e͎l͎e͎c͎t͎r͎i͎c͎ t͎r͎i͎c͎k͎s͎

LOLIN 32 Installation party :~)

Wemos LOLIN32 - ESP32
Pinout LOLIN D32 PRO

more info about the lolin32 is here: https://www.wemos.cc/en/latest/d32/d32_pro.html

step 1: download Arduino software

step 2: download driver for microcontroller

step 3: install driver

_windows: open Device Manager >> find UART device >> right click and update driver >> select driver

step 4: install esp32 library in the board manager

Arduino code

Hello World!

in the Arduino program, select the correct board (WEMOS LOLIN32) and select the USB port you are using (if you are unsure, check the listed ports, unplug and see what changed)

void setup() {
  Serial.begin(115200);
}

void loop() {
  Serial.println("Hello World!");   //sends a message to the computer
}

open the Serial Monitor in your arduino IDE and set it to 115200, the baudrate that has been set in the setup function, to see the printed messages.

Simple Led blink example

Simple Led Blink Example
Simple Led Blink Example Schematics

// always use a "preresistor" with the LED, because the 5v coming from the microcontroller is too much
// a LED only consumes ~2.5 volt, the resistor the other volt
// 
 
int ledPin = 23;               //the int ledPin is 13

void setup() {
  pinMode(ledPin,OUTPUT);      //ledPin is a OUTPUT
}

void loop() {
  digitalWrite(ledPin,HIGH);   //turns pin 13 on
  delay(500);                  //stops the loop for 500 milliseconds
  digitalWrite(ledPin,LOW);    //turns pin 13 off
  delay(500);                  //stops the loop for 500 milliseconds
}

Traffic light example

Trafficjam.png
Trafficjamschematics.png
int RedLedPin = 23;                 //the int RedLedPin is 13
int GreenLedPin = 22;               //the int GreenLedPin is 12

void setup() {
  pinMode(RedLedPin,OUTPUT);        //ledPin is a OUTPUT
  pinMode(GreenLedPin,OUTPUT);      //ledPin is a OUTPUT

}

void loop() {
  digitalWrite(GreenLedPin,HIGH);   //turns green led  on
  delay(5000);                      //stops the loop for 5000 milliseconds
  for(int i = 0; i < 5; i++){       //this for loop gets 5 times repeated
    digitalWrite(GreenLedPin,LOW);  //turns green led off
    delay(500);                     //stops the loop for 500 milliseconds
    digitalWrite(GreenLedPin,HIGH); //turns green led off
    delay(500);                     //stops the loop for 500 milliseconds
  }
  digitalWrite(GreenLedPin,LOW);    //turns green led off
  digitalWrite(RedLedPin,HIGH);     //turns red led on
  delay(5000);                      //stops the loop for 5000 milliseconds
  digitalWrite(RedLedPin,LOW);      //turns red led on
}

LDR example

example with a light resistor. keep in mind the LDR pin needs to be a pin with a ADC(analog to digital converter), because you check the analog voltage. on the arduino these are the ANALOG IN pins. on the ESP32 the pins with the ADC(check the pinout graphic)

LDR example.png
LDRschematics.png
int LDR = 34;                 //the LDR pin

void setup() {
  Serial.begin(115200);
  pinMode(LDR,INPUT);        //LDR is an INPUT
}

void loop() {
  int value = analogRead(LDR); // read the analog value of the LDR
  Serial.println(value);       // print the value of the LDR, open serial monitor
  delay(10);
}

LDR & speaker example

Ldrspeaker.png
Ldrspeakerschematics.png
int LDR = 34;                 //the LDR pin
int speaker = 23;

void setup() {
  Serial.begin(115200);
  pinMode(LDR,INPUT);        //LDR is an INPUT
  pinMode(speaker,OUTPUT);        //speaker is a OUTPUT
}

void loop() {
  int value = analogRead(LDR); // read the analog value of the LDR
  Serial.println(value);       // print the value of the LDR, open serial monitor
  tone(speaker,value);         //create a frequency on the speaker pin; the frequency hertz is the value
  delay(10);
}

Poti example

Poti.png
Potischematics.png
int poti = 34;                 //the poti pin

void setup() {
  Serial.begin(115200);
  pinMode(poti,INPUT);        //poti is an INPUT
}

void loop() {
  int value = analogRead(poti); // read the analog value of the poti
  Serial.println(value);       // print the value of the poti, open serial monitor
  delay(10);
}

Poti & speaker example

Potispeaker.png
Potispeakerschematics.png
//keep in mind you can only use a mini speaker. for bigger speakers you need an amplifier. 
int poti = 34;                 //the pto pin
int speaker = 23;

void setup() {
  Serial.begin(115200);
  pinMode(poti,INPUT);        //poti is an INPUT
  pinMode(speaker,OUTPUT);        //speaker is a OUTPUT
}

void loop() {
  int value = analogRead(poti); // read the analog value of the poti
  Serial.println(value);       // print the value of the poti, open serial monitor
  tone(speaker,value);         //create a frequency on the speaker pin; the frequency hertz is the value
  delay(10);
}

Button & alarm example

Buttonspeaker.png
Buttonschematics.png
int button = 34;
int speaker = 23;

void setup() {
  Serial.begin(115200);   //make usb connection
  pinMode(button, INPUT);    //button is an INPUT
  pinMode(speaker, OUTPUT);    //speaker is an OUTPUT

}

void loop() {
  bool value = digitalRead(button);    //read the digital value of button
  if(button){
    Serial.println("start alarm");
    for(int repeter = 0; repeter<5; repeter++){   //repeat 5 times
      for(int frequency = 500; frequency<1200; frequency++){    //count from 500 to 1200
        tone(speaker, fequency);    //generate the frequency on the speaker pin
        delay(5);
      }
      notone(speaker);    //turn off the speaker pin
      delay(500);         //
    }
  }else{
    Serial.println("button not pressed");
  }
}

16-04-24 ๓໐t໐rŞ + ŞēຖŞ໐rŞ = r໐๖໐t

sensors

humidity

Dht22.jpg the DHT22 humidity sensor :)

#include <DHT.h>;

//Constants
#define DHTPIN 21     // what pin we're connected to
#define DHTTYPE DHT22   // DHT 22  (AM2302)
DHT dht(DHTPIN, DHTTYPE); //// Initialize DHT sensor for normal 16mhz Arduino


//Variables
int chk;
float hum;  //Stores humidity value
float temp; //Stores temperature value

void setup()
{
    Serial.begin(9600);
	dht.begin();

}

void loop()
{
    //Read data and store it to variables hum and temp
    hum = dht.readHumidity();
    temp= dht.readTemperature();
    //Print temp and humidity values to serial monitor
    Serial.print("Humidity: ");
    Serial.print(hum);
    Serial.print(" %, Temp: ");
    Serial.print(temp);
    Serial.println(" Celsius");
    delay(2000); //Delay 2 sec.
}

sound

Sound sensorky.jpg

KY-037 Sound Detection Sensor Module :::;;-))

int sensorPin = 21;    // select the input pin for the potentiometer a0 on board, D1 pinout not connected
int sensorValue = 0;  // variable to store the value coming from the sensor




void setup() {
  // declare the ledPin as an OUTPUT:
  Serial.begin(9600);
  pinMode(22, OUTPUT); // 
}


void loop() {
  // read the value from the sensor:
  sensorValue = analogRead(sensorPin);    
  // turn the ledPin on
  Serial.println(sensorValue);




  if (sensorValue>448) {
    Serial.println("high detected");
    digitalWrite(22, HIGH);
    Serial.println("Blink On");
    delay(2000);
    digitalWrite(22, LOW);
   
  }
  else {
    digitalWrite(22, LOW);
  }
}

soil moisture

Soil moisture sensor.jpg Capacitive Soil Moisture Sensor Module :~)

const int dry = 595; // Value for dry sensor
const int wet = 239; // Value for wet sensor

void setup() {
  Serial.begin(9600); // Initialize serial communication
}

void loop() {
  int sensorVal = analogRead(26); // Read moisture sensor value from pin A0

  int percentageHumidity = map(sensorVal, wet, dry, 0, 100); // Convert sensor value to percentage

  Serial.print(percentageHumidity); // Print percentage humidity value
  Serial.println("%"); // Print % symbol
  delay(100); // Delay for stability
}

sonar distance

Sonar sensor.png

*/
// defines pins numbers
const int trigPin = 21;
const int echoPin = 14;
// defines variables
long duration;
int distance;
void setup() {
  pinMode(trigPin, OUTPUT); // Sets the trigPin as an Output
  pinMode(echoPin, INPUT); // Sets the echoPin as an Input
  Serial.begin(9600); // Starts the serial communication
}
void loop() {
  // Clears the trigPin
  digitalWrite(trigPin, LOW);
  delayMicroseconds(2);
  // Sets the trigPin on HIGH state for 10 micro seconds
  digitalWrite(trigPin, HIGH);
  delayMicroseconds(10);
  digitalWrite(trigPin, LOW);
  // Reads the echoPin, returns the sound wave travel time in microseconds
  duration = pulseIn(echoPin, HIGH);
  // Calculating the distance
  distance = duration * 0.034 / 2;
  // Prints the distance on the Serial Monitor
  Serial.print("Distance: ");
  Serial.println(distance);
}

water sensor

Water sensor.JPG https://lastminuteengineers.com/water-level-sensor-arduino-tutorial/

// Sensor pins
#define sensorPower 7
#define sensorPin A0

// Value for storing water level
int val = 0;

void setup() {
	// Set D7 as an OUTPUT
	pinMode(sensorPower, OUTPUT);
	
	// Set to LOW so no power flows through the sensor
	digitalWrite(sensorPower, LOW);
	
	Serial.begin(9600);
}

void loop() {
	//get the reading from the function below and print it
	int level = readSensor();
	
	Serial.print("Water level: ");
	Serial.println(level);
	
	delay(1000);
}

//This is a function used to get the reading
int readSensor() {
	digitalWrite(sensorPower, HIGH);	// Turn the sensor ON
	delay(10);							// wait 10 milliseconds
	val = analogRead(sensorPin);		// Read the analog value form sensor
	digitalWrite(sensorPower, LOW);		// Turn the sensor OFF
	return val;							// send current reading
}

sensor readings as motor control

to merge, the poti value needs to be replaced with the new sensor value, and the map max value adjusted


DHT merge:

#include <DHT.h>;
#include <ESP32Servo.h> //this

Servo twister; //this
//Constants
#define DHTPIN 21     // what pin we're connected to
#define DHTTYPE DHT22   // DHT 22  (AM2302)
DHT dht(DHTPIN, DHTTYPE); //// Initialize DHT sensor for normal 16mhz Arduino


//Variables
int chk;
float hum;  //Stores humidity value
float temp; //Stores temperature value

void setup()
{
    Serial.begin(9600);
    dht.begin();
    twister.attach(25); //this
	
}

void loop()
{
    //Read data and store it to variables hum and temp
    hum = dht.readHumidity();
    temp= dht.readTemperature();
    //Print temp and humidity values to serial monitor
    Serial.print("Humidity: ");
    Serial.print(hum);
    Serial.print(" %, Temp: ");
    Serial.print(temp);
    Serial.println(" Celsius");
    delay(2000); //Delay 2 sec.
     
    int degree = map(temp, 0, 36, 0, 180); //this, update temp with your value
    twister.write(degree);

}

23-04-24 l͓̽i͓̽n͓̽k͓̽i͓̽n͓̽g͓̽ t͓̽h͓̽e͓̽ r͓̽e͓̽a͓̽l͓̽m͓̽s͓̽

https://github.com/espressif/arduino-esp32/blob/master/libraries/WiFi/examples/WiFiAccessPoint/WiFiAccessPoint.ino

Using the ESP32 to create a hotspot and serve a simple webpage on http://192.168.4.1/ when connected.

/*
  WiFiAccessPoint.ino creates a WiFi access point and provides a web server on it.

  Steps:
  1. Connect to the access point "yourAp"
  2. Point your web browser to http://192.168.4.1/H to turn the LED on or http://192.168.4.1/L to turn it off
     OR
     Run raw TCP "GET /H" and "GET /L" on PuTTY terminal with 192.168.4.1 as IP address and 80 as port

  Created for arduino-esp32 on 04 July, 2018
  by Elochukwu Ifediora (fedy0)
*/
#include <WiFi.h>
#include <WiFiClient.h>
#include <WiFiAP.h>

#define LED_BUILTIN 23   // Set the GPIO pin where you connected your test LED or comment this line out if your dev board has a built-in LED

// Set these to your desired credentials.
const char *ssid = "joseph";
const char *password = "knierzinger";

WiFiServer server(80);


void setup() {
  pinMode(LED_BUILTIN, OUTPUT);

  Serial.begin(115200);
  Serial.println();
  Serial.println("Configuring access point...");

  // You can remove the password parameter if you want the AP to be open.
  // a valid password must have more than 7 characters
  if (!WiFi.softAP(ssid, password)) {
    log_e("Soft AP creation failed.");
    while(1);
  }
  IPAddress myIP = WiFi.softAPIP();
  Serial.print("AP IP address: ");
  Serial.println(myIP);
  server.begin();

  Serial.println("Server started");
}

void loop() {
  WiFiClient client = server.available();   // listen for incoming clients
  int sensorValue = analogRead(34); 
  if (client) {                             // if you get a client,
    Serial.println("New Client.");           // print a message out the serial port
    String currentLine = "";                // make a String to hold incoming data from the client
    while (client.connected()) {            // loop while the client's connected
      if (client.available()) {             // if there's bytes to read from the client,
        char c = client.read();             // read a byte, then
        Serial.write(c);                    // print it out the serial monitor
        if (c == '\n') {                    // if the byte is a newline character

          // if the current line is blank, you got two newline characters in a row.
          // that's the end of the client HTTP request, so send a response:
          if (currentLine.length() == 0) {
            // HTTP headers always start with a response code (e.g. HTTP/1.1 200 OK)
            // and a content-type so the client knows what's coming, then a blank line:
            client.println("HTTP/1.1 200 OK");
            client.println("Content-type:text/html");
            client.println();

            // the content of the HTTP response follows the header:
            client.print("<meta http-equiv='refresh' content='0.1'>");
            client.print("<style>body{background-color:red;}</style><br>");
            int objectValue = map(sensorValue, 0, 4096, 0, 200);
            client.print("<style>.object{background-color:black;}</style><br>");
            client.print("<style>.object{width: 400px;height:400px;}</style><br>");
            client.print("<style>.object{border-radius:"+String(objectValue)+"px; }</style><br>");

            client.print("<h1>eviltwin data " + String(sensorValue) + "</h1><br>");
            client.print("<div class='object'></div><br>");
            client.print("Click <a href=\"/H\">here</a> to turn ON the LED.<br>");
            client.print("Click <a href=\"/L\">here</a> to turn OFF the LED.<br>");

            // The HTTP response ends with another blank line:
            client.println();
            // break out of the while loop:
            break;
          } else {    // if you got a newline, then clear currentLine:
            currentLine = "";
          }
        } else if (c != '\r') {  // if you got anything else but a carriage return character,
          currentLine += c;      // add it to the end of the currentLine
        }

        // Check to see if the client request was "GET /H" or "GET /L":
        if (currentLine.endsWith("GET /H")) {
          digitalWrite(LED_BUILTIN, HIGH);               // GET /H turns the LED on
        }
        if (currentLine.endsWith("GET /L")) {
          digitalWrite(LED_BUILTIN, LOW);                // GET /L turns the LED off
        }
      }
    }
    // close the connection:
    client.stop();
    Serial.println("Client Disconnected.");
  }
}