Implementing a custom sensor

GenericSensor is a new class of the SimpleFOClibrary that simplifies the implementation of new sensors. With this class you are able to add a custom sensor to your code and link it to the motor in one arduino file.

Step 1. Implement the function reading your sensor

Basically all that you need to do in your arduino code is implement a function that reads your sensor and returns an angle in radians in between 0 and 2PI:

float readMySensorCallback(){
 // read my sensor
 // return the angle value in radians in between 0 and 2PI
 return ...;
}

additionally you can optionally implement a function that initialises your sensor

void initMySensorCallback(){
  // do the init
}

Step 2. Instantiate `GenericSensor` class

To initialize the sensor class you need to provide it the pointer to your function reading the sensor, and optionally the pointer to the function that initialises your sensor.

// GenericSensor class constructor
//  - readCallback pointer to the function reading the sensor angle
//  - initCallback pointer to the function initialising the sensor (optional)
GenericSensor sensor = GenericSensor(readMySensorCallback, initMySensorCallback);

Step 3. Using your sensor in real-time

There are two ways to use sensors implemented within this library:

As motor position sensor for FOC algorithm
As standalone position sensor

Standalone sensor

You can use your sensor as a standalone sensor. To get the sensor angle and velocity at any given time you can use the public methods:

class GenericSensor{
 public:
    // shaft velocity getter
    float getVelocity();
	  // shaft angle getter
    float getAngle();
}

Here is a quick example:

#include <SimpleFOC.h>

float readMySensorCallback(){
 // read my sensor
 // return the angle value in radians in between 0 and 2PI
 return ...;
}

void initMySensorCallback(){
  // do the init
}

// create the sensor
GenericSensor sensor = GenericSensor(readMySensorCallback, initMySensorCallback);

void setup() {
  // monitoring port
  Serial.begin(115200);

  // initialize sensor hardware
  sensor.init();

  Serial.println("My sensor ready");
  _delay(1000);
}

void loop() {
  // IMPORTANT - call as frequently as possible
  // update the sensor values 
  sensor.update();
  // display the angle and the angular velocity to the terminal
  Serial.print(sensor.getAngle());
  Serial.print("\t");
  Serial.println(sensor.getVelocity());
}

Position sensor for FOC algorithm

To use the sensor with the foc algorithm implemented in this library, once when you have initialized sensor.init(), you just have to link it to the BLDC motor by executing:

motor.linkSensor(&sensor);

So in general your code will look something like this:

#include <SimpleFOC.h>

float readMySensorCallback(){
 // read my sensor
 // return the angle value in radians in between 0 and 2PI
 return ...;
}

void initMySensorCallback(){
  // do the init
}

// create the sensor
GenericSensor sensor = GenericSensor(readMySensorCallback, initMySensorCallback);

....
BLDCMotor motor = ....
...

void setup() {
   ....
  // initialize sensor hardware
  sensor.init();
  // link to the motor
  motor.linkSensor(&sensor);
  ...
  motor.initFOC();
  ...
}
void loop() {
  ....
}

New sensor support full example - ESP32 hardware encoder

Here is an example code implementing a hardware counter based encoder implementation based on the ESP32 architecture that the SimpleFOClibrary doesn’t support by default. To setup the counters and all the hardware parameters here we use the library ESP32Encoder and the full code of the example is as follows:

#include <SimpleFOC.h>
#include <ESP32Encoder.h>

// create the ESP32Encoder class
ESP32Encoder encoder;
// define the sensor cpr (500x4)
int64_t cpr = 2000;
// function intialising the sensor
void initMySensorCallback(){
  // use pin 25 and 26 (Arduino pins 2,3) for the encoder
  encoder.attachFullQuad(25, 26);
}
// function reading the encoder 
float readMySensorCallback(){
  // return the value in between 0 - 2PI
  float a = ((float)(encoder.getCount()%cpr)*_2PI/((float)cpr));
  return a > 0 ? a : a + _2PI;
}
// create the generic sensor
GenericSensor sensor = GenericSensor(readMySensorCallback, initMySensorCallback);

// BLDC motor & driver instance
BLDCMotor motor = BLDCMotor(11);
BLDCDriver3PWM driver = BLDCDriver3PWM(16, 27, 5, 12); // (Arduino pins 5,6,10,8)


// commander communication instance
Commander command = Commander(Serial);
void doMotor(char* cmd){ command.motor(&motor, cmd); }

void setup() {

  // initialize sensor hardware
  sensor.init();
  // link the motor to the sensor
  motor.linkSensor(&sensor);

  // driver config
  // power supply voltage [V]
  driver.voltage_power_supply = 12;
  driver.init();
  // link driver
  motor.linkDriver(&driver);

  // set control loop type to be used
  motor.controller = MotionControlType::torque;

  // use monitoring with serial for motor init
  // monitoring port
  Serial.begin(115200);
  // comment out if not needed
  motor.useMonitoring(Serial);

  // initialise motor
  motor.init();
  // align encoder and start FOC
  motor.initFOC();

  // subscribe motor to the commander
  command.add('M', doMotor, "motor");

  _delay(1000);
}


void loop() {
  // iterative setting FOC phase voltage
  motor.loopFOC();

  // iterative function setting the outter loop target
  motor.move();

  // user communication
  command.run();
}