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- /*
- Controlling a servo position using a potentiometer (variable resistor)
- by Michal Rinott <http://people.interaction-ivrea.it/m.rinott>
- modified on 8 Nov 2013
- by Scott Fitzgerald
- modified for the ESP32 on March 2017
- by John Bennett
-
- see http://www.arduino.cc/en/Tutorial/Knob for a description of the original code
- * Different servos require different pulse widths to vary servo angle, but the range is
- * an approximately 500-2500 microsecond pulse every 20ms (50Hz). In general, hobbyist servos
- * sweep 180 degrees, so the lowest number in the published range for a particular servo
- * represents an angle of 0 degrees, the middle of the range represents 90 degrees, and the top
- * of the range represents 180 degrees. So for example, if the range is 1000us to 2000us,
- * 1000us would equal an angle of 0, 1500us would equal 90 degrees, and 2000us would equal 1800
- * degrees.
- *
- * Circuit: (using an ESP32 Thing from Sparkfun)
- * Servo motors have three wires: power, ground, and signal. The power wire is typically red,
- * the ground wire is typically black or brown, and the signal wire is typically yellow,
- * orange or white. Since the ESP32 can supply limited current at only 3.3V, and servos draw
- * considerable power, we will connect servo power to the VBat pin of the ESP32 (located
- * near the USB connector). THIS IS ONLY APPROPRIATE FOR SMALL SERVOS.
- *
- * We could also connect servo power to a separate external
- * power source (as long as we connect all of the grounds (ESP32, servo, and external power).
- * In this example, we just connect ESP32 ground to servo ground. The servo signal pins
- * connect to any available GPIO pins on the ESP32 (in this example, we use pin 18.
- *
- * In this example, we assume a Tower Pro SG90 small servo connected to VBat.
- * The published min and max for this servo are 500 and 2400, respectively.
- * These values actually drive the servos a little past 0 and 180, so
- * if you are particular, adjust the min and max values to match your needs.
- */
- // Include the ESP32 Arduino Servo Library instead of the original Arduino Servo Library
- #include <ESP32Servo.h>
- Servo myservo; // create servo object to control a servo
- // Possible PWM GPIO pins on the ESP32: 0(used by on-board button),2,4,5(used by on-board LED),12-19,21-23,25-27,32-33
- int servoPin = 18; // GPIO pin used to connect the servo control (digital out)
- // Possible ADC pins on the ESP32: 0,2,4,12-15,32-39; 34-39 are recommended for analog input
- int potPin = 34; // GPIO pin used to connect the potentiometer (analog in)
- int ADC_Max = 4096; // This is the default ADC max value on the ESP32 (12 bit ADC width);
- // this width can be set (in low-level oode) from 9-12 bits, for a
- // a range of max values of 512-4096
-
- int val; // variable to read the value from the analog pin
- void setup()
- {
- // Allow allocation of all timers
- ESP32PWM::allocateTimer(0);
- ESP32PWM::allocateTimer(1);
- ESP32PWM::allocateTimer(2);
- ESP32PWM::allocateTimer(3);
- myservo.setPeriodHertz(50);// Standard 50hz servo
- myservo.attach(servoPin, 500, 2400); // attaches the servo on pin 18 to the servo object
- // using SG90 servo min/max of 500us and 2400us
- // for MG995 large servo, use 1000us and 2000us,
- // which are the defaults, so this line could be
- // "myservo.attach(servoPin);"
- }
- void loop() {
- val = analogRead(potPin); // read the value of the potentiometer (value between 0 and 1023)
- val = map(val, 0, ADC_Max, 0, 180); // scale it to use it with the servo (value between 0 and 180)
- myservo.write(val); // set the servo position according to the scaled value
- delay(200); // wait for the servo to get there
- }
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