Update to allow up to 3 expression pedals

code.py

@@ -1,8 +1,8 @@
 ################################################################################
 #
-# Pi-Pico-ExpressionPedal2Midi
+# Pi-Pico-ExpressionPedal2Midi (Multiple Pedals)
 #
-# using USB midi. Midi messages are sent simultaneoulsy to UART1 and USB.
+# Using USB midi. Midi messages are sent simultaneoulsy to UART1 and USB.
 # Set desired midi channel, change control, and maximum and minimum values
 #
 # Upon run/power on, move expresson pedal from maximum to minimum to calibrate
@@ -30,69 +30,67 @@ from adafruit_midi.pitch_bend import PitchBend
 from adafruit_midi.control_change import ControlChange
 
 # Midi output settings
-midi_channel = 1  # Target midi channel to write to
+midi_channel = 1  # Target midi channel
-cc = 1  # Target Control Change number - Expression Pedal
-cc_min = 0  # Minimum desired CC output - 0 - 127
-cc_max = 127  # Maximum desired CC output - 0 - 127
 
 # Expression pedal settings
 logarithmic = True  # Expression pedal logarithmic or linear. Set to False for linear
 log_base = 100  # This value changes the feel of the log curve
 
 # Required percentage of expression pedal movement for calibration
-exp_pedal_calibration_percent = 80 # 0 - 100
+exp_pedal_calibration_percent = 80  # 0 - 100
+
+# Define expression pedals
+expression_pedals = [
+    # Set expression pedal midi control change number, and min/max values
+    {"pin": board.GP26, "cc": 1, cc_min: 0, cc_max: 127}, # Pedal 1. Pin 31
+    {"pin": board.GP27, "cc": 2, cc_min: 0, cc_max: 127}, # Pedal 2. Pin 32
+    {"pin": board.GP28, "cc": 3, cc_min: 0, cc_max: 127}  # Peadl 3. Pin 34
+]
 
 # Devices
 led = digitalio.DigitalInOut(board.LED)
 led.direction = digitalio.Direction.OUTPUT
-exp = analogio.AnalogIn(board.GP26)  # Expression pedal device on pin 31
 uart = busio.UART(tx=board.GP4, rx=board.GP5, baudrate=31250, timeout=0.001)  # UART Midi device on pin 6
 uart_midi = adafruit_midi.MIDI(midi_out=uart, out_channel=midi_channel - 1)
 usb_midi = adafruit_midi.MIDI(
-	midi_out=usb_midi.ports[1], out_channel=midi_channel - 1)
+    midi_out=usb_midi.ports[1], out_channel=midi_channel - 1)
+
+# Initialize expression pedals
+exp_values = [analogio.AnalogIn(pedal["pin"]) for pedal in expression_pedals]
+exp_previous = [exp.value for exp in exp_values]
+exp_min = [65535 for _ in expression_pedals]
+exp_max = [1e-6 for _ in expression_pedals]
+exp_calibration_threshold = [int(abs(exp_max[i] - exp_min[i]) * exp_pedal_calibration_percent / 100) for i in range(len(expression_pedals))]
 
 # This function translates the expression pedal value to the equivalent CC value
-def translate(exp_val):
+def translate(exp_val, exp_min, exp_max, cc_min, cc_max):
     if logarithmic:
-	    scaled_val = math.log(exp_val, log_base)  # Apply logarithmic scaling
+        scaled_val = math.log(exp_val, log_base)  # Apply logarithmic scaling
-	    return int((((scaled_val - math.log(exp_min, log_base)) * (cc_max - cc_min)) / (math.log(exp_max, log_base) - math.log(exp_min, log_base))) + cc_min)
+        return int((((scaled_val - math.log(exp_min, log_base)) * (cc_max - cc_min)) / (math.log(exp_max, log_base) - math.log(exp_min, log_base))) + cc_min)
     else:
-	    return int((((exp_val - exp_min) * (cc_max - cc_min)) / (exp_max - exp_min)) + cc_min)
+        return int((((exp_val - exp_min) * (cc_max - cc_min)) / (exp_max - exp_min)) + cc_min)
 
-# Initialise variables
+# Main loop
-offset = 1e-6  # Small offset to avoid log(0) error
-
-# Set these to reverse thresholds to enable calibration
-exp_min = 65535
-exp_max = offset
-
-exp_calibration_threshold = int(abs(exp_max - exp_min) * exp_pedal_calibration_percent / 100)
-cc_ratio = 1/(cc_max - cc_min)  # Calculate number of possible CC values
-exp_previous = exp.value
-
-if exp_previous == 0:
-    exp_previous = offset
-
-# main loop
 while True:
-    exp_current = exp.value
+    for i, exp in enumerate(exp_values):
-    if exp_current == 0:
+        exp_current = exp.value
-        exp_current = offset
+        if exp_current == 0:
+            exp_current = 1e-6  # Small offset to avoid log(0) error
 
-    # Only process if the change ratio is greater than the possible number of CC values
+        # Only process if the change ratio is greater than the possible number of CC values
-    if abs(exp_current - exp_previous) / exp_max > cc_ratio:
+        if abs(exp_current - exp_previous[i]) / exp_max[i] > 1/(cc_max[i] - cc_min[i]):
-        if exp_current > exp_max:
+            if exp_current > exp_max[i]:
-            exp_max = exp_current
+                exp_max[i] = exp_current
-        elif exp_current < exp_min:
+            elif exp_current < exp_min[i]:
-            exp_min = exp_current
+                exp_min[i] = exp_current
-        exp_previous = exp_current
+            exp_previous[i] = exp_current
 
-        # Only send midi when calibration threshold has been reached
+            # Only send midi when calibration threshold has been reached
-        if exp_max - exp_min > exp_calibration_threshold:
+            if exp_max[i] - exp_min[i] > exp_calibration_threshold[i]:
-            led.value = True  # Turn led on
+                led.value = True  # Turn led on
-            cc_val = translate(exp_current)
+                cc_val = translate(exp_current, exp_min[i], exp_max[i], cc_min[i], cc_max[i])
-            uart_midi.send(ControlChange(cc, cc_val))
+                uart_midi.send(ControlChange(expression_pedals[i]["cc"], cc_val))
-            usb_midi.send(ControlChange(cc, cc_val))
+                usb_midi.send(ControlChange(expression_pedals[i]["cc"], cc_val))
-            led.value = False  # Turn led off
+                led.value = False  # Turn led off
-            print("Writing Midi Channel: {}, ControlChange: {}, Value {}. Exp Pedal: cur: {}, min: {}, max: {}".format(
+                print("Pedal {}: Writing Midi Channel: {}, ControlChange: {}, Value {}. Exp Pedal: cur: {}, min: {}, max: {}".format(
-                midi_channel, cc, cc_val, exp_current, exp_min, exp_max))
+                    i + 1, midi_channel, expression_pedals[i]["cc"], cc_val, exp_current, exp_min[i], exp_max[i]))