import gc import time import math import random from pimoroni import Button, PID from motor import Motor, motor2040 from encoder import Encoder, MMME_CPR """ An example of how to move a motor smoothly between random positions, with the help of it's attached encoder and PID control. Press "Boot" to exit the program. """ MOTOR_PINS = motor2040.MOTOR_A # The pins of the motor being profiled ENCODER_PINS = motor2040.ENCODER_A # The pins of the encoder attached to the profiled motor GEAR_RATIO = 50 # The gear ratio of the motor COUNTS_PER_REV = MMME_CPR * GEAR_RATIO # The counts per revolution of the motor's output shaft DIRECTION = 0 # The direction to spin the motor in. NORMAL (0), REVERSED (1) SPEED_SCALE = 5.4 # The scaling to apply to the motor's speed to match its real-world speed UPDATES = 100 # How many times to update the motor per second UPDATE_RATE = 1 / UPDATES TIME_FOR_EACH_MOVE = 1 # The time to travel between each random value UPDATES_PER_MOVE = TIME_FOR_EACH_MOVE * UPDATES PRINT_DIVIDER = 4 # How many of the updates should be printed (i.e. 2 would be every other update) # Multipliers for the different printed values, so they appear nicely on the Thonny plotter SPD_PRINT_SCALE = 20 # Driving Speed multipler POSITION_EXTENT = 180 # How far from zero to move the motor, in degrees INTERP_MODE = 2 # The interpolating mode between setpoints. STEP (0), LINEAR (1), COSINE (2) # PID values POS_KP = 0.14 # Position proportional (P) gain POS_KI = 0.0 # Position integral (I) gain POS_KD = 0.0022 # Position derivative (D) gain # Free up hardware resources ahead of creating a new Encoder gc.collect() # Create a motor and set its speed scale m = Motor(MOTOR_PINS, direction=DIRECTION, speed_scale=SPEED_SCALE, deadzone=0.05) # Create an encoder, using PIO 0 and State Machine 0 enc = Encoder(0, 0, ENCODER_PINS, direction=DIRECTION, counts_per_rev=COUNTS_PER_REV, count_microsteps=True) # Create the user button user_sw = Button(motor2040.USER_SW) # Create PID object for position control pos_pid = PID(POS_KP, POS_KI, POS_KD, UPDATE_RATE) # Enable the motor to get started m.enable() update = 0 print_count = 0 # Set the initial value and create a random end value between the extents start_value = 0.0 end_value = random.uniform(-POSITION_EXTENT, POSITION_EXTENT) # Continually move the motor until the user button is pressed while user_sw.raw() is not True: # Capture the state of the encoder capture = enc.capture() # Calculate how far along this movement to be percent_along = min(update / UPDATES_PER_MOVE, 1.0) if INTERP_MODE == 0: # Move the motor instantly to the end value pos_pid.setpoint = end_value elif INTERP_MODE == 2: # Move the motor between values using cosine pos_pid.setpoint = (((-math.cos(percent_along * math.pi) + 1.0) / 2.0) * (end_value - start_value)) + start_value else: # Move the motor linearly between values pos_pid.setpoint = (percent_along * (end_value - start_value)) + start_value # Calculate the velocity to move the motor closer to the position setpoint vel = pos_pid.calculate(capture.degrees, capture.degrees_per_second) # Set the new motor driving speed m.speed(vel) # Print out the current motor values and their setpoints, but only on every multiple if print_count == 0: print("Pos =", capture.degrees, end=", ") print("Pos SP =", pos_pid.setpoint, end=", ") print("Speed = ", m.speed() * SPD_PRINT_SCALE) # Increment the print count, and wrap it print_count = (print_count + 1) % PRINT_DIVIDER update += 1 # Move along in time # Have we reached the end of this movement? if update >= UPDATES_PER_MOVE: update = 0 # Reset the counter # Set the start as the last end and create a new random end value start_value = end_value end_value = random.uniform(-POSITION_EXTENT, POSITION_EXTENT) time.sleep(UPDATE_RATE) # Disable the servo m.disable()