the code didnt work so i created example sender and receiver code

2025-03-24 02:29:28 +03:00 · 2025-03-24 02:29:28 +03:00 · 7ae4d9ae5e
commit 7ae4d9ae5e
parent dfbcc976e6
11 changed files with 533 additions and 237 deletions
--- a/example/espnow_receiver_code/espnow_receiver_code.ino
+++ b/example/espnow_receiver_code/espnow_receiver_code.ino
@ -0,0 +1,58 @@
+#include <esp_now.h>
+#include <WiFi.h>
+
+// Structure example to receive data
+// Must match the sender structure
+typedef struct struct_message {
+    int x;
+    int y;
+    bool b;
+} struct_message;
+
+// Create a struct_message called myData
+struct_message myData;
+
+// Callback function that will be executed when data is received
+void OnDataRecv(const esp_now_recv_info_t *esp_now_info, const uint8_t *incomingData, int len) {
+  // Copy incoming data into the myData structure
+  memcpy(&myData, incomingData, sizeof(myData));
+
+  // Print the MAC address of the sender
+  // Serial.print("Received from MAC: ");
+  // for (int i = 0; i < 6; i++) {
+  //   Serial.printf("%02X", esp_now_info->src_addr[i]);
+  //   if (i < 5) Serial.print(":");
+  // }
+  // Serial.println();
+
+  // Print received data
+  // Serial.print("x: ");
+  Serial.print(myData.x);
+  Serial.print(" ");
+  Serial.print(myData.y);
+  Serial.print(" ");
+  Serial.println(myData.b);
+}
+ 
+void setup() {
+  // Initialize Serial Monitor
+  Serial.begin(115200);
+  
+  // Set device as a Wi-Fi Station
+  WiFi.mode(WIFI_STA);
+
+  // Initialize ESP-NOW
+  if (esp_now_init() != ESP_OK) {
+    Serial.println("Error initializing ESP-NOW");
+    return;
+  }
+  
+  // Register callback function to receive data
+  esp_now_register_recv_cb(OnDataRecv);
+
+  Serial.println("Receiver ready. Waiting for data...");
+}
+ 
+void loop() {
+  // Nothing to do here
+}
--- a/example/espnow_sender_code/espnow_sender_code.ino
+++ b/example/espnow_sender_code/espnow_sender_code.ino
@ -0,0 +1,82 @@
+#include <esp_now.h>
+#include <WiFi.h>
+
+// REPLACE WITH THE MAC Address of your receiver - 1C:69:20:E9:13:EC
+uint8_t broadcastAddress[] = {0x1C, 0x69, 0x20, 0xE9, 0x13, 0xEC}; // Replace with actual receiver MAC address
+
+// Define variables to be sent
+typedef struct struct_message {
+    int x;
+    int y;
+    bool b;
+} struct_message;
+
+// Create a struct_message called myData
+struct_message myData;
+
+// Callback when data is sent
+void OnDataSent(const uint8_t *mac_addr, esp_now_send_status_t status) {
+  // Serial.print("Last Packet Send Status: ");
+  // Serial.println(status == ESP_NOW_SEND_SUCCESS ? "Delivery Success" : "Delivery Fail");
+}
+ 
+void setup() {
+
+  // Initialize Serial Monitor
+  Serial.begin(115200);
+
+  pinMode(34, INPUT_PULLUP);
+ 
+  // Set device as a Wi-Fi Station
+  WiFi.mode(WIFI_STA);
+
+  // Initialize ESP-NOW
+  if (esp_now_init() != ESP_OK) {
+    Serial.println("Error initializing ESP-NOW");
+    return;
+  }
+
+  // Register callback function to get the status of transmitted packets
+  esp_now_register_send_cb(OnDataSent);
+  
+  // Register peer information (receiver)
+  esp_now_peer_info_t peerInfo;
+  
+  memcpy(peerInfo.peer_addr, broadcastAddress, sizeof(broadcastAddress));
+  peerInfo.channel = 0;  
+  peerInfo.encrypt = false;
+
+  // Add peer        
+  if (esp_now_add_peer(&peerInfo) != ESP_OK) {
+    Serial.println("Failed to add peer");
+    return;
+  }
+
+  Serial.println("Sender ready. Sending data...");
+}
+ 
+void loop() {
+  
+  // Set values to send (example: read analog pins and digital pin)
+  myData.x = map(analogRead(32), 0, 4095, -100, +100); // Map analog value from pin GPIO32
+  myData.y = map(analogRead(33), 0, 4095, -100, +100); // Map analog value from pin GPIO33
+  myData.b = !digitalRead(34);                        // Read digital value from pin GPIO34
+
+  // Send message via ESP-NOW
+  esp_err_t result = esp_now_send(broadcastAddress, (uint8_t *) &myData, sizeof(myData));
+   
+  if (result == ESP_OK) {
+    // Serial.print("Sent successfully -> ");
+    // Serial.print("x: ");
+    Serial.print(myData.x);
+    Serial.print(" ");
+    Serial.print(myData.y);
+    Serial.print(" ");
+    Serial.println(myData.b);
+    
+   } else {
+     Serial.println("Error sending the data");
+   }
+
+   delay(20); // Small delay between sends to avoid flooding the network
+}
--- a/espnow-car/espnow-car.ino
+++ b/espnow-car/espnow-car.ino
@ -1,194 +1,144 @@
-#include  <Arduino.h>
-#include  "L298N_ESP32.h"
-#include  "Servo_ESP32.h"
+  #include  <Arduino.h>
+  #include  "espnow.h"
+  #include  "motor.h"
+  #include  "servo.h"
+  #include  "fuzzy.h"

-// Motor 1 Pins
-#define   MOTOR1_PIN1     27
-#define   MOTOR1_PIN2     26
-#define   MOTOR1_ENABLE   14
+  #define   terminal    Serial

-// Motor 2 Pins
-#define   MOTOR2_PIN1     25
-#define   MOTOR2_PIN2     33
-#define   MOTOR2_ENABLE   32
+  void setup() {

-// Servo Pins
-#define   SERVO1_PIN      13
-#define   SERVO2_PIN      12
+    // Terminal
+    terminal.begin(115200);

-// Motor Objects
-L298N_ESP32   motor1(MOTOR1_PIN1, MOTOR1_PIN2, MOTOR1_ENABLE, 0);
-L298N_ESP32   motor2(MOTOR2_PIN1, MOTOR2_PIN2, MOTOR2_ENABLE, 1);
+    terminal.println("Hello");

-// Servo Objects
-Servo_ESP32   servo1(SERVO1_PIN, 2, 1000, 2000);
-Servo_ESP32   servo2(SERVO2_PIN, 3, 1000, 2000);
+    // ESPNOW Communications
+    espnow_begin();

-// ESPNOW
-#include  <esp_now.h>
-#include  <WiFi.h>
+    // Initialize Motors
+    motor1.begin();
+    motor2.begin();

-// Packet Data Structure
-struct PacketData {
-    uint8_t X;  // Steering (left/right)
-    uint8_t Y;  // Throttle (forward/backward)
-    bool    B;  // Button
-};
+    // Initialize Servos
+    servo1.begin();
+    servo2.begin();

-// Data Received From Remote
-PacketData data;
-
-// Constants
-const unsigned long MOTOR_ACTION_DELAY = 5000; // Delay between motor actions
-const int SERVO1_START = 10;
-const int SERVO1_END = 170;
-const int SERVO2_START = 20;
-const int SERVO2_END = 160;
-
-enum MotorState {
-    STOPPED,
-    FORWARD_M1,
-    BACKWARD_M1,
-    FORWARD_M2,
-    BACKWARD_M2
-};
-
-MotorState currentMotorState = STOPPED;
-unsigned long motorStateStartTime = 0;
-
-void setup() {
-
-  Serial.begin(115200);
-
-  // Initialize Motors
-  motor1.begin();
-  motor2.begin();
-
-  // Initialize Servos
-  servo1.begin();
-  servo2.begin();
-
-  Serial.println("Initialization complete.");
-
-  // ESP-NOW setup
-  WiFi.mode(WIFI_STA);
-  if (esp_now_init() != ESP_OK) {
-    Serial.println("ESP-NOW init failed");
-    return;
-  }
-
-  // When Receive Data Execute OnDataRecv Function
-  esp_now_register_recv_cb(OnDataRecv);
-
-}
-
-void loop() {
-
-  // Non Blocking Motor control
-  if(millis() - motorStateStartTime >= MOTOR_ACTION_DELAY) {
-
-    motorStateStartTime = millis();
-
-    switch (currentMotorState) {
-
-      case STOPPED:
-        Serial.println("Moving motor 1 forward...");
-        motor1.forward();
-        motor1.setPercentage(75); //PWM set percentage
-        motor2.stop();
-        currentMotorState = FORWARD_M1;
-        break;
-      case FORWARD_M1:
-        Serial.println("Moving motor 1 backward...");
-        motor1.backward();
-        motor1.setPercentage(50); //PWM set percentage
-        motor2.stop();
-        currentMotorState = BACKWARD_M1;
-        break;
-      case BACKWARD_M1:
-        Serial.println("Moving motor 2 forward...");
-        motor1.stop();
-        motor2.forward();
-        motor2.setPercentage(25); //PWM set percentage
-        currentMotorState = FORWARD_M2;
-        break;
-      case FORWARD_M2:
-        Serial.println("Moving motor 2 backward...");
-        motor1.stop();
-        motor2.backward();
-        motor2.setPercentage(100); //PWM set percentage
-        currentMotorState = BACKWARD_M2;
-        break;
-      case BACKWARD_M2:
-        Serial.println("Stopping motors ...");
-        motor1.stop();
-        motor2.stop();
-        currentMotorState = STOPPED;
-        break;
-
-    }
+    // Print Terminal Message
+    // terminal.println("Initialization complete.");
    
  }

-  //Non Blocking Servos
-  static unsigned long servoTimer = 0;
-  static int servo1Pos = SERVO1_START;
-  static int servo2Pos = SERVO2_START;
-  static bool servoForward = true;
-  unsigned long currentTime = millis();
+  void loop() {

-  if(currentTime - servoTimer >= 20) { // Adjust for speed
+    terminal.print(data.X);   // 0% to 100%
+    terminal.print(" ");
+    terminal.print(data.Y);
+    terminal.print(" ");
+    terminal.println(data.B);

-    servoTimer = currentTime;
+    delay(20);

-    if (servoForward) {
-      servo1Pos++;
-      if (servo1Pos >= SERVO1_END) {
-        servoForward = false;
-      }
-    } else {
-      servo1Pos--;
-      if (servo1Pos <= SERVO1_START) {
-        servoForward = true;
-      }
-    }
+    // // Non Blocking Motor control
+    // if(millis() - motorStateStartTime >= MOTOR_ACTION_DELAY) {

-    servo1.write(servo1Pos);
+    //   motorStateStartTime = millis();
+
+    //   switch(currentMotorState) {
+
+    //     case STOPPED:
+    //       Serial.println("Moving motor 1 forward...");
+    //       motor1.forward();
+    //       motor1.setPercentage(75); //PWM set percentage
+    //       motor2.stop();
+    //       currentMotorState = FORWARD_M1;
+    //       break;
+    //     case FORWARD_M1:
+    //       Serial.println("Moving motor 1 backward...");
+    //       motor1.backward();
+    //       motor1.setPercentage(50); //PWM set percentage
+    //       motor2.stop();
+    //       currentMotorState = BACKWARD_M1;
+    //       break;
+    //     case BACKWARD_M1:
+    //       Serial.println("Moving motor 2 forward...");
+    //       motor1.stop();
+    //       motor2.forward();
+    //       motor2.setPercentage(25); //PWM set percentage
+    //       currentMotorState = FORWARD_M2;
+    //       break;
+    //     case FORWARD_M2:
+    //       Serial.println("Moving motor 2 backward...");
+    //       motor1.stop();
+    //       motor2.backward();
+    //       motor2.setPercentage(100); //PWM set percentage
+    //       currentMotorState = BACKWARD_M2;
+    //       break;
+    //     case BACKWARD_M2:
+    //       Serial.println("Stopping motors ...");
+    //       motor1.stop();
+    //       motor2.stop();
+    //       currentMotorState = STOPPED;
+    //       break;
+
+    //   }
+
+    // }
+
+    // // Non Blocking Servos
+    // static unsigned long servoTimer = 0;
+    // static int servo1Pos = SERVO1_START;
+    // static int servo2Pos = SERVO2_START;
+    // static bool servoForward = true;
+    // unsigned long currentTime = millis();
+
+    // if(currentTime - servoTimer >= 20) { // Adjust for speed
+
+    //   servoTimer = currentTime;
+
+    //   if (servoForward) {
+    //     servo1Pos++;
+    //     if (servo1Pos >= SERVO1_END) {
+    //       servoForward = false;
+    //     }
+    //   } else {
+    //     servo1Pos--;
+    //     if (servo1Pos <= SERVO1_START) {
+    //       servoForward = true;
+    //     }
+    //   }
+
+    //   servo1.write(servo1Pos);
+
+    // }
+
+    // // Non Blocking Servos
+    // static unsigned long servoTimer2 = 0;
+    // static int servo2Pos2 = SERVO2_START;
+    // static bool servoForward2 = true;
+    // unsigned long currentTime2 = millis();
+
+    // if(currentTime2 - servoTimer2 >= 20) { // Adjust for speed
+
+    //   servoTimer2 = currentTime2;
+
+    //   if (servoForward2) {
+    //     servo2Pos2++;
+    //     if (servo2Pos2 >= SERVO2_END) {
+    //       servoForward2 = false;
+    //     }
+    //   } else {
+    //     servo2Pos2--;
+    //     if (servo2Pos2 <= SERVO2_START) {
+    //       servoForward2 = true;
+    //     }
+    //   }
+
+    //   servo2.write(servo2Pos2);
+
+    // }

  }

-  //Non Blocking Servos
-  static unsigned long servoTimer2 = 0;
-  static int servo2Pos2 = SERVO2_START;
-  static bool servoForward2 = true;
-  unsigned long currentTime2 = millis();

-  if(currentTime2 - servoTimer2 >= 20) { // Adjust for speed
-
-    servoTimer2 = currentTime2;
-
-    if (servoForward2) {
-      servo2Pos2++;
-      if (servo2Pos2 >= SERVO2_END) {
-        servoForward2 = false;
-      }
-    } else {
-      servo2Pos2--;
-      if (servo2Pos2 <= SERVO2_START) {
-        servoForward2 = true;
-      }
-    }
-
-    servo2.write(servo2Pos2);
-
-  }
-
-}
-
-// ESP-NOW callback
-void OnDataRecv(const esp_now_recv_info *info, const uint8_t *data, int len) {
-  if (len == sizeof(PacketData)) {
-    memcpy(&data, data, sizeof(PacketData));
-  }
-}
 
--- a/espnow-car/espnow.h
+++ b/espnow-car/espnow.h
@ -0,0 +1,44 @@
+  
+  // ESPNOW
+  #include  <esp_now.h>
+  #include  <WiFi.h>
+
+  // Packet Data Structure
+  struct PacketData {
+      uint8_t X;  // Steering (left/right)
+      uint8_t Y;  // Throttle (forward/backward)
+      bool    B;  // Button
+  };
+
+  // Data Received From Remote
+  PacketData data;
+
+  // ESP-NOW callback
+  void OnDataRecv(const esp_now_recv_info *info, const uint8_t *data, int len) {
+    if (len == sizeof(PacketData)) {
+      memcpy(&data, data, sizeof(PacketData));
+    }
+  }
+
+  // Function To Start ESPNOW
+  void espnow_begin() {
+
+    // ESP-NOW setup
+    WiFi.mode(WIFI_STA);
+    if (esp_now_init() != ESP_OK) {
+      Serial.println("ESP-NOW init failed");
+      return;
+    }
+
+    delay(100);
+
+    // Print MAC Address
+    Serial.println(WiFi.macAddress());
+
+    delay(2000);
+
+    // When Receive Data Execute OnDataRecv Function
+    esp_now_register_recv_cb(OnDataRecv);
+
+  }
+
--- a/espnow-car/fuzzy.h
+++ b/espnow-car/fuzzy.h
@ -0,0 +1,65 @@
+#ifndef FUZZY_H
+#define FUZZY_H
+
+  #include <Arduino.h>
+  #include <algorithm>
+
+  // Rear servo configuration
+  const int REAR_MIN = 52;
+  const int REAR_MAX = 140;
+  const int REAR_STRAIGHT = 95;
+
+  // Fuzzy logic functions
+  float triangularMF(float x, float a, float b, float c) {
+    return std::max(std::min((x - a) / (b - a), (c - x) / (c - b)), 0.0f);
+  }
+
+  float calculateCentroid(float* memberships, float* angles, int size) {
+
+    float sumMembership = 0;
+    float sumProduct = 0;
+    for (int i = 0; i < size; i++) {
+      sumMembership += memberships[i];
+      sumProduct += memberships[i] * angles[i];
+    }
+
+    return sumProduct / sumMembership;
+
+  }
+
+  float fuzzyRearSteering(float accelX, float accelY) {
+
+    // Define membership functions for inputs
+    float accelNeg = triangularMF(accelX, -1, -0.5, 0);
+    float accelZero = triangularMF(accelX, -0.5, 0, 0.5);
+    float accelPos = triangularMF(accelX, 0, 0.5, 1);
+
+    float rotSmall = triangularMF(accelY, -1, -0.5, 0);
+    float rotMedium = triangularMF(accelY, -0.5, 0, 0.5);
+    float rotLarge = triangularMF(accelY, 0, 0.5, 1);
+
+    // Define rule base
+    float ruleStrengths[9];
+    ruleStrengths[0] = std::min(accelNeg, rotSmall);   // Right
+    ruleStrengths[1] = std::min(accelNeg, rotMedium);  // Straight
+    ruleStrengths[2] = std::min(accelNeg, rotLarge);   // Left
+    ruleStrengths[3] = std::min(accelZero, rotSmall);  // Straight
+    ruleStrengths[4] = std::min(accelZero, rotMedium); // Straight
+    ruleStrengths[5] = std::min(accelZero, rotLarge);  // Left
+    ruleStrengths[6] = std::min(accelPos, rotSmall);   // Left
+    ruleStrengths[7] = std::min(accelPos, rotMedium);  // Straight
+    ruleStrengths[8] = std::min(accelPos, rotLarge);   // Right
+
+    // Define output angles (adjusted for rear servo range)
+    float outputAngles[9] = {
+      REAR_MAX, REAR_STRAIGHT, REAR_MIN,  // Right, Straight, Left
+      REAR_STRAIGHT, REAR_STRAIGHT, REAR_MIN,  // Straight, Straight, Left
+      REAR_MIN, REAR_STRAIGHT, REAR_MAX  // Left, Straight, Right
+    };
+
+    // Defuzzification using centroid method
+    return calculateCentroid(ruleStrengths, outputAngles, 9);
+
+  }
+
+#endif
--- a/espnow-car/l298n_esp32.h
+++ b/espnow-car/l298n_esp32.h
@ -1,3 +1,4 @@
+
 #ifndef L298N_ESP32_h
 #define L298N_ESP32_h

--- a/espnow-car/motor.h
+++ b/espnow-car/motor.h
@ -0,0 +1,31 @@
+
+  // Libraries
+  #include  "l298n_esp32.h"
+
+  // Motor 1 Pins
+  #define   MOTOR1_PIN1     27
+  #define   MOTOR1_PIN2     26
+  #define   MOTOR1_ENABLE   14
+
+  // Motor 2 Pins
+  #define   MOTOR2_PIN1     25
+  #define   MOTOR2_PIN2     33
+  #define   MOTOR2_ENABLE   32
+
+  // Motor State
+  enum MotorState {
+      STOPPED,
+      FORWARD_M1,
+      BACKWARD_M1,
+      FORWARD_M2,
+      BACKWARD_M2
+  };
+
+  // Motor Variables
+  MotorState          currentMotorState   = STOPPED;
+  unsigned long       motorStateStartTime = 0;
+  const unsigned long MOTOR_ACTION_DELAY  = 5000; // Delay between motor actions
+
+  // Motor Objects
+  L298N_ESP32   motor1(MOTOR1_PIN1, MOTOR1_PIN2, MOTOR1_ENABLE, 0);
+  L298N_ESP32   motor2(MOTOR2_PIN1, MOTOR2_PIN2, MOTOR2_ENABLE, 1);
--- a/espnow-car/servo.h
+++ b/espnow-car/servo.h
@ -0,0 +1,17 @@
+
+  // Servo Library
+  #include  "Servo_ESP32.h"
+
+  // Servo Pins
+  #define   SERVO1_PIN      13
+  #define   SERVO2_PIN      12
+
+  // Servo Objects
+  Servo_ESP32   servo1(SERVO1_PIN, 2, 1000, 2000);
+  Servo_ESP32   servo2(SERVO2_PIN, 3, 1000, 2000);
+
+  // Constants
+  const int SERVO1_START  = 10;
+  const int SERVO1_END    = 170;
+  const int SERVO2_START  = 20;
+  const int SERVO2_END    = 160;
--- a/espnow-car/servo_esp32.h
+++ b/espnow-car/servo_esp32.h
@ -1,74 +1,78 @@
-#ifndef Servo_ESP32_h
-#define Servo_ESP32_h

-#include <Arduino.h>
+  #ifndef Servo_ESP32_h
+  #define Servo_ESP32_h

-class Servo_ESP32 {
-private:
-    uint8_t servoPin;
-    uint8_t pwmChannel;
-    int minPulseWidth;
-    int maxPulseWidth;
-    int currentAngle;
-    const int freq = 50;  // 50Hz for standard servos
-    const int resolution = 16; // 16-bit resolution for smoother control
-    bool _invert = false;
-    uint8_t _min_pos = 0;
-    uint8_t _max_pos = 180;
-    uint8_t _init_pos = 90;
-    uint8_t _prv_pos = 0;
+  #include <Arduino.h>

-    bool verify(uint8_t input) {
+  class Servo_ESP32 {
+
+    private:
+
+      uint8_t servoPin;
+      uint8_t pwmChannel;
+      int minPulseWidth;
+      int maxPulseWidth;
+      int currentAngle;
+      const int freq = 50;  // 50Hz for standard servos
+      const int resolution = 16; // 16-bit resolution for smoother control
+      bool _invert = false;
+      uint8_t _min_pos = 0;
+      uint8_t _max_pos = 180;
+      uint8_t _init_pos = 90;
+      uint8_t _prv_pos = 0;
+
+      bool verify(uint8_t input) {
        if (input != _prv_pos) {
-            _prv_pos = input;
-            return true;
+          _prv_pos = input;
+          return true;
        }
        return false;
-    }
+      }

-public:
-    Servo_ESP32() {}
-    Servo_ESP32(uint8_t pin, uint8_t channel, int minPulse = 500, int maxPulse = 2500) :
-        servoPin(pin), pwmChannel(channel), minPulseWidth(minPulse), maxPulseWidth(maxPulse), currentAngle(0) {}
+    public:

-    void begin() {
+      Servo_ESP32() {}
+
+      Servo_ESP32(uint8_t pin, uint8_t channel, int minPulse = 500, int maxPulse = 2500) : servoPin(pin), pwmChannel(channel), minPulseWidth(minPulse), maxPulseWidth(maxPulse), currentAngle(0) {}
+
+      void begin() {
        ledcAttachChannel(pwmChannel, freq, resolution, servoPin); // Correct order: channel, freq, resolution, pin
        write(_init_pos);
-    }
+      }

-    void setPin(uint8_t pin) {
+      void setPin(uint8_t pin) {
        servoPin = pin;
-    }
+      }

-    void invert() {
+      void invert() {
        _invert = !_invert;
-    }
+      }

-    void setMin(uint8_t start) {
+      void setMin(uint8_t start) {
        _min_pos = start;
-    }
+      }

-    void setMax(uint8_t stop) {
+      void setMax(uint8_t stop) {
        _max_pos = stop;
-    }
+      }

-    void setInit(uint8_t init) {
+      void setInit(uint8_t init) {
        _init_pos = init;
-    }
+      }

-    void goMax() {
+      void goMax() {
        write(_max_pos);
-    }
+      }

-    void goMin() {
+      void goMin() {
        write(_min_pos);
-    }
+      }

-    void goInit() {
+      void goInit() {
        write(_init_pos);
-    }
+      }

-    void write(int angle) {
+      void write(int angle) {
        if (!verify(angle)) return;
        currentAngle = _invert ? 180 - angle : angle;
        currentAngle = constrain(currentAngle, 0, 180);
@ -76,29 +80,30 @@ public:
            minPulseWidth,
            maxPulseWidth);
        ledcWrite(pwmChannel, dutyCycle);
-    }
+      }

-    int read() {
+      int read() {
        return currentAngle;
-    }
+      }

-    void move(uint8_t pos) {
+      void move(uint8_t pos) {
        pos = constrain(pos, _min_pos, _max_pos);
        write(pos);
-    }
+      }

-    void percent(uint8_t pos) {
+      void percent(uint8_t pos) {
        pos = map(pos, 0, 100, _min_pos, _max_pos);
        write(pos);
-    }
+      }

-    void override(uint8_t pos) {
+      void override(uint8_t pos) {
        write(pos);
-    }
+      }

-    // Add these functions to access the private attributes
-    uint8_t getMin() const { return _min_pos; }
-    uint8_t getMax() const { return _max_pos; }
-};
+      // Add these functions to access the private attributes
+      uint8_t getMin() const { return _min_pos; }
+      uint8_t getMax() const { return _max_pos; }

-#endif
+  };
+
+  #endif
--- a/espnow-remote/espnow-remote.ino
+++ b/espnow-remote/espnow-remote.ino
@ -5,6 +5,9 @@
  // HEADER FILE
  #include  "header.h"

+  // REPLACE WITH YOUR RECEIVER MAC ADDRESS - 1C:69:20:E9:13:EC
+  // uint8_t receiverMacAddress[] = {0x1C, 0x69, 0x20, 0xE9, 0x13, 0xEC};  // 1C:69:20:E9:13:EC
+
 //==========================================================
 //  SETUP
 //==========================================================
@ -13,10 +16,41 @@
  void setup() {
    
    Serial.begin(115200);
+
+    Serial.println();
+    Serial.println(WiFi.macAddress());
+    WiFi.mode(WIFI_STA);
+    delay(5000);
+
    JY.setPin(X_AXIS_PIN, Y_AXIS_PIN, SWITCH_PIN);
    JY.begin();
+
    // StartWireless();  // Initialize ESP-NOW

+    // Init ESP-NOW
+    if(esp_now_init() != ESP_OK) {
+      Serial.println("Error initializing ESP-NOW");
+      return;
+    } else {
+      Serial.println("Succes: Initialized ESP-NOW");
+    }
+
+    esp_now_register_send_cb(OnDataSent);
+    
+    // Register peer
+    esp_now_peer_info_t peerInfo;
+    memcpy(peerInfo.peer_addr, receiverMacAddress, 6);
+    peerInfo.channel = 0;  
+    peerInfo.encrypt = false;
+    
+    // Add peer        
+    if(esp_now_add_peer(&peerInfo) != ESP_OK) {
+      Serial.println("Failed to add peer");
+      return;
+    } else {
+      Serial.println("Succes: Added peer");
+    } 
+
  }

 //==========================================================
@ -26,15 +60,24 @@
  // LOOP
  void loop() {
    
-    JD.X = map(average(JY.readX(), 10), 0, 4095, 0, 255);  // Map to 0-255
-    JD.Y = map(average(JY.readY(), 10), 0, 4095, 0, 255);  // Map to 0-255
-    JD.B = JY.readB();
+    JD.X = map(analogRead(32), 0, 4095, 0, 100); //map(average(JY.readX(), 10), 0, 4095, 0, 255);  // Map to 0-255
+    JD.Y = map(analogRead(33), 0, 4095, 0, 100); //map(average(JY.readY(), 10), 0, 4095, 0, 255);  // Map to 0-255
+    JD.B = digitalRead(34); //JY.readB();

    Serial.print(JD.X); Serial.print(" "); 
    Serial.print(JD.Y); Serial.print(" "); 
    Serial.println(!JD.B);

    // SendData(JD);  // Uncomment to send data
+
+    esp_err_t result = esp_now_send(receiverMacAddress, (uint8_t *) &JD, sizeof(JD));
+    if (result == ESP_OK) {
+      // Serial.println("Sent with success");
+    } else {
+      // Serial.println("Error sending the data");
+    }
+
+
    delay(20);

  }
--- a/espnow-remote/header.h
+++ b/espnow-remote/header.h
@ -6,9 +6,9 @@
  #include  "joystic.h"

  // JOYSTIC PIN DEFINITION
-  #define   X_AXIS_PIN    32  // ADC1_CH4 (Valid)
-  #define   Y_AXIS_PIN    33  // ADC1_CH5 (Valid)
-  #define   SWITCH_PIN    34  // Changed from 25 (now ADC1_CH6)
+  #define X_AXIS_PIN    32  // ADC1_CH4 (Valid)
+  #define Y_AXIS_PIN    33  // ADC1_CH5 (Valid)
+  #define SWITCH_PIN    34  // Changed from 25 (now ADC1_CH6)

  // DATA STRUCTURE
  struct JoysticData {
@ -36,7 +36,7 @@
  // THE RECEIVER MAC ADDRESS
  // 1C:69:20:E9:13:EC
  
-  // REPLACE WITH YOUR RECEIVER MAC ADDRESS
+  // REPLACE WITH YOUR RECEIVER MAC ADDRESS - 1C:69:20:E9:13:EC
  uint8_t receiverMacAddress[] = {0x1C, 0x69, 0x20, 0xE9, 0x13, 0xEC};  // 1C:69:20:E9:13:EC
    
  // CALLBACK WHEN DATA IS SENT