Add PWM motor control and refactor engine update
Introduce ENA pins for both motors and implement rpmToPwm and setMotor. Replace extensive Serial debug prints with concise motor‑drive logic in Engine::update. Consolidate sonar pins into a single TRIG_AND_ECHO_PIN. Update pinMode calls in the sketch to configure the new ENA pins.
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@@ -8,8 +8,7 @@ const byte AUTH_UID[4] = { 145, 136, 97, 102 };
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const byte AUTH_UID_SIZE = sizeof(AUTH_UID);
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// // Odległościomierz
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// const int TRIG_PIN = 6;
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// const int ECHO_PIN = 5;
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const int TRIG_AND_ECHO_PIN = 3;
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const long SONAR_MAX_DIST_CM = 400;
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@@ -30,7 +29,12 @@ const uint8_t BRAKE_PIN = A2;
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const uint8_t THROTTLE_PIN = A3;
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// Silniki
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// Prawy silnik
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const int IN_1 = 9;
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const int IN_2 = 8;
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const int ENA_1 = 5;
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// Lewy silnik
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const int IN_3 = 4;
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const int IN_4 = 3;
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const int IN_4 = 2;
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const int ENA_2 = 6;
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+19
-46
@@ -1,4 +1,5 @@
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#include "Engine.h"
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#include "Config.h"
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using namespace EngineConsts;
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Engine::Engine(uint8_t throttlePin,
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@@ -6,82 +7,41 @@ Engine::Engine(uint8_t throttlePin,
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uint8_t brakePin)
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: _throttlePin(throttlePin), _clutchPin(clutchPin), _brakePin(brakePin) {}
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void Engine::begin() {
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}
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void Engine::begin() {}
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float Engine::readNormalized(uint8_t pin) const {
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return analogRead(pin) / 1023.0f;
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}
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void Engine::update(float dt, uint8_t gearIdx) {
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// Serial.println("----------------");
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const float throttle = readNormalized(_throttlePin);
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// Serial.print("Throttle: ");
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// Serial.println(throttle);
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const float clutch = readNormalized(_clutchPin);
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// Serial.print("Clutch: ");
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// Serial.println(clutch);
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const float brake = readNormalized(_brakePin);
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// Serial.print("Brake: ");
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// Serial.println(brake);
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const float targetRPM = RPM_IDLE + throttle * (RPM_MAX - RPM_IDLE);
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// Serial.print("targetRPM: ");
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// Serial.println(targetRPM);
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const float wheelRPM = (_speedMs / (2.0f * PI * WHEEL_RADIUS)) * 60.0f;
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// Serial.print("wheelRPM: ");
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// Serial.println(wheelRPM);
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const float gearRatio = GEAR_RATIO[gearIdx];
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// Serial.print("gearRatio: ");
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// Serial.println(gearRatio);
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const float drivenRPM = wheelRPM * fabs(gearRatio) * FINAL_DRIVE;
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// Serial.print("drivenRPM: ");
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// Serial.println(drivenRPM);
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_engineRPM = clutch * drivenRPM + (1.0f - clutch) * targetRPM;
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// Serial.print("_engineRPM: ");
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// Serial.println(_engineRPM);
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_engineRPM = constrain(_engineRPM, RPM_IDLE, 7500.0f);
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// Serial.print("_engineRPM (constrain): ");
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// Serial.println(_engineRPM);
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const float engineForce = (_engineRPM / RPM_MAX) * (1.0f - clutch) * ENGINE_FORCE_FACTOR;
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// Serial.print("engineForce: ");
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// Serial.println(engineForce);
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const float brakeForce = brake * BRAKE_FORCE_MAX;
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// Serial.print("brakeForce: ");
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// Serial.println(brakeForce);
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const float dragForce = 0.5f * DRAG_COEFF * FRONTAL_AREA * (_speedMs * _speedMs);
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// Serial.print("dragForce: ");
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// Serial.println(dragForce);
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const int direction = (gearIdx == -1) ? -1 : 1;
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// Serial.print("direction: ");
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// Serial.println(direction);
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const float netForce = direction * engineForce - brakeForce - dragForce;
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// Serial.print("netForce: ");
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// Serial.println(netForce);
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const float acceleration = netForce / CAR_MASS;
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// Serial.print("acceleration: ");
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// Serial.println(acceleration);
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_speedMs += acceleration * dt;
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if (_speedMs < 0.0f) _speedMs = 0.0f;
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// Serial.print("_speedMs: ");
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// Serial.println(_speedMs);
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// delay(1000);
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setMotor(IN_3, IN_4, ENA_2, targetRPM, false);
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bool reverseWheel = (gearIdx == -1);
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setMotor(IN_1, IN_2, ENA_1, wheelRPM * 10.0f, reverseWheel);
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}
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int Engine::getRPM() const {
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@@ -91,3 +51,16 @@ int Engine::getRPM() const {
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int Engine::getSpeedKmh() const {
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return static_cast<int>((_speedMs * 3.6f) + 0.5f);
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}
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uint8_t Engine::rpmToPwm(float rpm) {
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rpm = constrain(rpm, 0.0f, RPM_MAX);
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return static_cast<uint8_t>(roundf(rpm / RPM_MAX * 255.0f));
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}
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void Engine::setMotor(uint8_t inA, uint8_t inB, uint8_t ena,
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float rpm, bool reverse) {
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digitalWrite(inA, reverse ? LOW : HIGH);
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digitalWrite(inB, reverse ? HIGH : LOW);
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analogWrite(ena, rpmToPwm(rpm));
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}
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@@ -36,6 +36,9 @@ public:
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int getRPM() const;
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int getSpeedKmh() const;
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uint8_t rpmToPwm(float rpm);
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void setMotor(uint8_t inA, uint8_t inB, uint8_t ena, float rpm, bool reverse = false);
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private:
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const uint8_t _throttlePin;
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const uint8_t _clutchPin;
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+5
-1
@@ -22,6 +22,10 @@ void setup() {
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pinMode(IN_1, OUTPUT);
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pinMode(IN_2, OUTPUT);
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pinMode(ENA_1, OUTPUT);
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pinMode(IN_3, OUTPUT);
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pinMode(IN_4, OUTPUT);
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pinMode(ENA_2, OUTPUT);
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rfid.begin();
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display.begin(LCD_COLS, LCD_ROWS);
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@@ -38,7 +42,7 @@ void loop() {
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carEnabled = !carEnabled;
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Serial.print("Auto działa: ");
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Serial.println(carEnabled);
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display.startOrEnd(carEnabled);0
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display.startOrEnd(carEnabled);
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};
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if (carEnabled) {
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