working Arni controller

3 years ago · df911dcfb0
parent 259ea914ff
commit df911dcfb0
5 changed files with 378 additions and 26 deletions
--- a/bluetooth/esp32/arni/README.md
+++ b/bluetooth/esp32/arni/README.md
@ -0,0 +1,28 @@
 # Arni
 This code supports using an ESP32 and the Dabble ios app to control 2 hoverboard motors
 driven by an Odrive.
 ## Install
 ```
 upy put  bluetooth/esp32/arni/ble_advertising.py ble_advertising.py
 upy put bluetooth/esp32/arni/robot.py robot.py
 upy put bluetooth/esp32/ble_arni_odrive_controller.py main.py
 ```
 Confirm with `upy ls`
 ## Usage
 With the ESP32 and Odrive powered on open the Dabble and connect. This
 does not support Joystick yet. This is a work in progress
 ### Buttons
 |Key       |Action                                                   |
 |----------|---------------------------------------------------------|
 |Select    |Toggles Odrive idle / loop control states                |
 |Start     |Performs an Odrive AXIS_STATE_ENCODER_OFFSET_CALIBRATION |
 |          |                                                         |
 |          |                                                         |
--- a/bluetooth/esp32/arni/ble_advertising.py
+++ b/bluetooth/esp32/arni/ble_advertising.py
@ -0,0 +1,93 @@
 # Helpers for generating BLE advertising payloads.
 from micropython import const
 import struct
 import bluetooth
 # Advertising payloads are repeated packets of the following form:
 #   1 byte data length (N + 1)
 #   1 byte type (see constants below)
 #   N bytes type-specific data
 _ADV_TYPE_FLAGS = const(0x01)
 _ADV_TYPE_NAME = const(0x09)
 _ADV_TYPE_UUID16_COMPLETE = const(0x3)
 _ADV_TYPE_UUID32_COMPLETE = const(0x5)
 _ADV_TYPE_UUID128_COMPLETE = const(0x7)
 _ADV_TYPE_UUID16_MORE = const(0x2)
 _ADV_TYPE_UUID32_MORE = const(0x4)
 _ADV_TYPE_UUID128_MORE = const(0x6)
 _ADV_TYPE_APPEARANCE = const(0x19)
 # Generate a payload to be passed to gap_advertise(adv_data=...).
 def advertising_payload(limited_disc=False, br_edr=False, name=None, services=None, appearance=0):
    payload = bytearray()
    def _append(adv_type, value):
        nonlocal payload
        payload += struct.pack("BB", len(value) + 1, adv_type) + value
    _append(
        _ADV_TYPE_FLAGS,
        struct.pack("B", (0x01 if limited_disc else 0x02) + (0x18 if br_edr else 0x04)),
    )
    if name:
        _append(_ADV_TYPE_NAME, name)
    if services:
        for uuid in services:
            b = bytes(uuid)
            if len(b) == 2:
                _append(_ADV_TYPE_UUID16_COMPLETE, b)
            elif len(b) == 4:
                _append(_ADV_TYPE_UUID32_COMPLETE, b)
            elif len(b) == 16:
                _append(_ADV_TYPE_UUID128_COMPLETE, b)
    # See org.bluetooth.characteristic.gap.appearance.xml
    if appearance:
        _append(_ADV_TYPE_APPEARANCE, struct.pack("<h", appearance))
    return payload
 def decode_field(payload, adv_type):
    i = 0
    result = []
    while i + 1 < len(payload):
        if payload[i + 1] == adv_type:
            result.append(payload[i + 2 : i + payload[i] + 1])
        i += 1 + payload[i]
    return result
 def decode_name(payload):
    n = decode_field(payload, _ADV_TYPE_NAME)
    return str(n[0], "utf-8") if n else ""
 def decode_services(payload):
    services = []
    for u in decode_field(payload, _ADV_TYPE_UUID16_COMPLETE):
        services.append(bluetooth.UUID(struct.unpack("<h", u)[0]))
    for u in decode_field(payload, _ADV_TYPE_UUID32_COMPLETE):
        services.append(bluetooth.UUID(struct.unpack("<d", u)[0]))
    for u in decode_field(payload, _ADV_TYPE_UUID128_COMPLETE):
        services.append(bluetooth.UUID(u))
    return services
 def demo():
    payload = advertising_payload(
        name="micropython esp32",
        services=[bluetooth.UUID(0x181A), bluetooth.UUID("6E400001-B5A3-F393-E0A9-E50E24DCCA9E")],
    )
    print(payload)
    print(decode_name(payload))
    print(decode_services(payload))
 if __name__ == "__main__":
    demo()
--- a/bluetooth/esp32/arni/ble_arni_odrive_controller.py
+++ b/bluetooth/esp32/arni/ble_arni_odrive_controller.py
@ -1,10 +1,13 @@
 # This module demonstrates uses the Nordic UART Service (NUS) to interpret gamepad
 import bluetooth
 from machine import UART
 from micropython import const
 # Arni
 from ble_advertising import advertising_payload
 from robot import ArniRobot, RobotController
-from micropython import const
+__version__ = "0.1.0"
 _IRQ_CENTRAL_CONNECT = const(1)
 _IRQ_CENTRAL_DISCONNECT = const(2)
@ -97,9 +100,16 @@ class BLEUART:
        self._ble.gap_advertise(interval_us, adv_data=self._payload)
-def demo():
+
 def main():
    import time
    robot_uart = UART(2, baudrate=115200, tx=17, rx=16)
    arni = ArniRobot(robot_uart)
    robot_controller = RobotController(arni)
    # BT
    ble = bluetooth.BLE()
    uart = BLEUART(ble)
@ -107,9 +117,12 @@ def demo():
        # Assumes Unicode text data is being sent.
        # print("rx: ", uart.read().decode().strip())
        data = uart.read()
-        print(type(data))
+        # print("Recieved {} bytes of data".format(data))
-        print(len(data))
+        # for count, v in enumerate(data):
-        print(data)
+        #     print("Index: {0} | Value: {1} | Binary: {2} | Hex: {3}".format(count,v,bin(v), hex(v)))
        if len(data) == 8:
            print("Recieved {} data".format(data))
            robot_controller.interpret((data[5],data[6]))
    # Will execute this function on every received packet
    uart.irq(handler=on_rx)
@ -126,4 +139,4 @@ def demo():
 if __name__ == "__main__":
-    demo()
+    main()
--- a/bluetooth/esp32/arni/robot.py
+++ b/bluetooth/esp32/arni/robot.py
@ -0,0 +1,164 @@
 import time
 # from machine import UART
 # ARn
 ARNI_INITIAL_VELOCITY = 0.5
 # ODrive Constants
 AXIS_STATE_UNDEFINED = 0
 AXIS_STATE_IDLE = 1
 AXIS_STATE_STARTUP_SEQUENCE = 2
 AXIS_STATE_FULL_CALIBRATION_SEQUENCE = 3
 AXIS_STATE_MOTOR_CALIBRATION = 4
 AXIS_STATE_SENSORLESS_CONTROL = 5
 AXIS_STATE_ENCODER_INDEX_SEARCH = 6
 AXIS_STATE_ENCODER_OFFSET_CALIBRATION = 7
 AXIS_STATE_CLOSED_LOOP_CONTROL = 8
 # DABBLE BITS
 # BUTTONS
 DABBLE_START_BIT = 0
 DABBLE_SELECT_BIT = 1
 DABBLE_TRIANGLE_BIT = 2
 DABBLE_CIRCLE_BIT = 3
 DABBLE_CROSS_BIT = 4
 DABBLE_SQUARE_BIT = 5
 # ARROW PAD
 DABBLE_UP_BIT = 0
 DABBLE_DOWN_BIT = 1
 DABBLE_LEFT_BIT = 2
 DABBLE_RIGHT_BIT = 3
 # Globals
 # uart = UART(2, baudrate=115200, tx=17, rx=16)
 current_global_velocity = ARNI_INITIAL_VELOCITY  # Will be changed by controller during operation
 class RobotController:
    def __init__(self, robot):
        self.robot = robot
    def interpret(self, dabble_bytes):
        """
        Interprets a tuples of bytes received from the Dabble BLE gamepad module.
        Translates data into ArniRobot commands.
        :param values: A two byte tuple
            values[0] contains button data
            values[1] contains arrow pad data
        :return:
        """
        self._interpret_buttons(dabble_bytes[0])
        self._interpret_arrows(dabble_bytes[1])
    def _interpret_buttons(self, button_byte):
        if button_byte & (1 << DABBLE_START_BIT):
            self.robot.init_motors()
        elif button_byte & (1 << DABBLE_SELECT_BIT):
            if self.robot.active:
                self.robot.set_idle()
            else:
                self.robot.set_active()
    def _interpret_arrows(self, arrow_byte):
        if arrow_byte & (1 << DABBLE_UP_BIT):
            self.robot.forward()
        elif arrow_byte & (1 << DABBLE_DOWN_BIT):
            self.robot.reverse()
        elif arrow_byte & (1 << DABBLE_LEFT_BIT):
            self.robot.left()
        elif arrow_byte & (1 << DABBLE_RIGHT_BIT):
            self.robot.right()
        else:
            self.robot.stop()
 class ArniRobot:
    def __init__(self, uart, vel=None):
        self._uart = uart
        self._vel = vel if vel else ARNI_INITIAL_VELOCITY
        self.active = False
        self.initialized = False
    def get(self, value):
        """Read value from odrive config.
        Example:
            arni.get('vbus_voltage')
        """
        self._uart.write("r {0}\n".format(value))
        if not self._uart.any():
            time.sleep_ms(100)
        value = self._uart.read()
        if value:
            value = value.decode('ascii')
        return value or ''
    def init_motors(self):
        """Runs index ops and sets control loop.
        Must be run with the motors not under load.
        """
        # AXIS_STATE_ENCODER_OFFSET_CALIBRATION = 7
        self._uart.write('w axis0.requested_state 7\nw axis1.requested_state 7\n')
        self.initialized = True
    def forward(self):
        """Move forward."""
        return self._uart.write('v 0 {0} 0\nv 1 -{0} 0\n'.format(self._vel))
    def reverse(self):
        """Reverse move."""
        return self._uart.write('v 0 -{0} 0\nv 1 {0} 0\n'.format(self._vel))
    def stop(self):
        """All stop."""
        return self._uart.write('v 0 0 0\nv 1 0 0\n')
    def right(self):
        """Hard turn right."""
        return self._uart.write('v 0 0 0\nv 1 -{0} 0\n'.format(self._vel))
    def left(self):
        """Hard turn left."""
        return self._uart.write('v 0 {0} 0\nv 1 0 0\n'.format(self._vel))
    def right_forward(self):
        """Right turn while moving forward."""
        return self._uart.write('v 0 {0} 0\nv 1 -{1} 0\n'.format(self._vel / 2, self._vel))
    def right_reverse(self):
        """Right turn while moving in reverse."""
        return self._uart.write('v 0 -{0} 0\nv 1 {1} 0\n'.format(self._vel / 2, self._vel))
    def left_forward(self):
        """Left turn while moving forward."""
        return self._uart.write('v 0 {0} 0\nv 1 -{1} 0\n'.format(self._vel, self._vel / 2))
    def left_reverse(self):
        """Right turn while moving in reverse."""
        return self._uart.write('v 0 -{0} 0\nv 1 {0} 0\n'.format(self._vel, self._vel / 2))
    def set_idle(self):
        """Set motor control to idle."""
        self.stop()
        self.active = False
        return self._uart.write('w axis0.requested_state {0})\nw axis1.requested_state {0}\n'.format(AXIS_STATE_IDLE))
    def set_active(self):
        """Set motor control to closed loop control."""
        if not self.initialized:
            print("Robot motors have not been initialized. Initialize motors before entering control loop.")
        self.active = True
        return self._uart.write('w axis0.requested_state {0})\nw axis1.requested_state {0}\n'.format(AXIS_STATE_CLOSED_LOOP_CONTROL))
    def set_velocity(self, velocity):
        """Set motor velocity."""
        self._vel = velocity
        return self._vel
 # arni = ArniRobot(uart)
 # controller = RobotController(arni)
--- a/uart/odrive_uart.py
+++ b/uart/odrive_uart.py
@ -1,10 +1,10 @@
 import time
 from machine import UART
-#
+# ARn
 ARNI_INITIAL_VELOCITY = 0.5
-#
+# ODrive Constants
 AXIS_STATE_UNDEFINED = 0
 AXIS_STATE_IDLE = 1
 AXIS_STATE_STARTUP_SEQUENCE = 2
@ -15,10 +15,63 @@ AXIS_STATE_ENCODER_INDEX_SEARCH = 6
 AXIS_STATE_ENCODER_OFFSET_CALIBRATION = 7
 AXIS_STATE_CLOSED_LOOP_CONTROL = 8
 # DABBLE BITS
 # BUTTONS
 DABBLE_START_BIT = 0
 DABBLE_SELECT_BIT = 1
 DABBLE_TRIANGLE_BIT = 2
 DABBLE_CIRCLE_BIT = 3
 DABBLE_CROSS_BIT = 4
 DABBLE_SQUARE_BIT = 5
 # ARROW PAD
 DABBLE_UP_BIT = 0
 DABBLE_DOWN_BIT = 1
 DABBLE_LEFT_BIT = 2
 DABBLE_RIGHT_BIT = 3
 # Globals
 uart = UART(2, baudrate=115200, tx=17, rx=16)
 current_global_velocity = ARNI_INITIAL_VELOCITY  # Will be changed by controller during operation
 class RobotController:
    def __init__(self, robot):
        self.robot = robot
    def interpret(self, dabble_bytes):
        """
        Interprets a tuples of bytes received from the Dabble BLE gamepad module.
        Translates data into ArniRobot commands.
        :param values: A two byte tuple
            values[0] contains button data
            values[1] contains arrow pad data
        :return:
        """
        self._interpret_buttons(dabble_bytes[0])
        self._interpret_arrows(dabble_bytes[1])
    def _interpret_buttons(self, button_byte):
        if button_byte & (1 << DABBLE_START_BIT):
            self.robot.init_motors()
        elif button_byte & (1 << DABBLE_SELECT_BIT):
            if self.robot.active:
                self.robot.set_idle()
            else:
                self.robot.set_active()
    def _interpret_arrows(self, arrow_byte):
        if arrow_byte & (1 << DABBLE_UP_BIT):
            self.robot.forward()
        elif arrow_byte & (1 << DABBLE_DOWN_BIT):
            self.robot.reverse()
        elif arrow_byte & (1 << DABBLE_LEFT_BIT):
            self.robot.left()
        elif arrow_byte & (1 << DABBLE_RIGHT_BIT):
            self.robot.right()
        else:
            self.robot.stop()
 class ArniRobot:
@ -35,10 +88,10 @@ class ArniRobot:
        Example:
            arni.get('vbus_voltage')
        """
-        uart.write("r {0}\n".format(value))
+        self._uart.write("r {0}\n".format(value))
-        if not uart.any():
+        if not self._uart.any():
            time.sleep_ms(100)
-        value = uart.read()
+        value = self._uart.read()
        if value:
            value = value.decode('ascii')
        return value or ''
@ -49,50 +102,50 @@ class ArniRobot:
        Must be run with the motors not under load.
        """
        # AXIS_STATE_ENCODER_OFFSET_CALIBRATION = 7
-        uart.write('w axis0.requested_state 7\nw axis1.requested_state 7\n')
+        self._uart.write('w axis0.requested_state 7\nw axis1.requested_state 7\n')
        self.initialized = True
    def forward(self):
        """Move forward."""
-        return uart.write('v 0 {0} 0\nv 1 -{0} 0\n'.format(self._vel))
+        return self._uart.write('v 0 {0} 0\nv 1 -{0} 0\n'.format(self._vel))
    def reverse(self):
        """Reverse move."""
-        return uart.write('v 0 -{0} 0\nv 1 {0} 0\n'.format(self._vel))
+        return self._uart.write('v 0 -{0} 0\nv 1 {0} 0\n'.format(self._vel))
    def stop(self):
        """All stop."""
-        return uart.write('v 0 0 0\nv 1 0 0\n')
+        return self._uart.write('v 0 0 0\nv 1 0 0\n')
    def right(self):
        """Hard turn right."""
-        return uart.write('v 0 0 0\nv 1 -{0} 0\n'.format(self._vel))
+        return self._uart.write('v 0 0 0\nv 1 -{0} 0\n'.format(self._vel))
    def left(self):
        """Hard turn left."""
-        return uart.write('v 0 {0} 0\nv 1 0 0\n'.format(self._vel))
+        return self._uart.write('v 0 {0} 0\nv 1 0 0\n'.format(self._vel))
    def right_forward(self):
        """Right turn while moving forward."""
-        return uart.write('v 0 {0} 0\nv 1 -{1} 0\n'.format(self._vel / 2, self._vel))
+        return self._uart.write('v 0 {0} 0\nv 1 -{1} 0\n'.format(self._vel / 2, self._vel))
    def right_reverse(self):
        """Right turn while moving in reverse."""
-        return uart.write('v 0 -{0} 0\nv 1 {1} 0\n'.format(self._vel / 2, self._vel))
+        return self._uart.write('v 0 -{0} 0\nv 1 {1} 0\n'.format(self._vel / 2, self._vel))
    def left_forward(self):
        """Left turn while moving forward."""
-        return uart.write('v 0 {0} 0\nv 1 -{1} 0\n'.format(self._vel, self._vel / 2))
+        return self._uart.write('v 0 {0} 0\nv 1 -{1} 0\n'.format(self._vel, self._vel / 2))
    def left_reverse(self):
        """Right turn while moving in reverse."""
-        return uart.write('v 0 -{0} 0\nv 1 {0} 0\n'.format(self._vel, self._vel / 2))
+        return self._uart.write('v 0 -{0} 0\nv 1 {0} 0\n'.format(self._vel, self._vel / 2))
    def set_idle(self):
        """Set motor control to idle."""
        self.stop()
        self.active = False
-        return uart.write('w axis0.requested_state {0})\nw axis1.requested_state {0}\n'.format(AXIS_STATE_IDLE))
+        return self._uart.write('w axis0.requested_state {0})\nw axis1.requested_state {0}\n'.format(AXIS_STATE_IDLE))
    def set_active(self):
        """Set motor control to closed loop control."""
@ -100,7 +153,7 @@ class ArniRobot:
            print("Robot motors have not been initialized. Initialize motors before entering control loop.")
        self.active = True
-        return uart.write('w axis0.requested_state {0})\nw axis1.requested_state {0}\n'.format(AXIS_STATE_CLOSED_LOOP_CONTROL))
+        return self._uart.write('w axis0.requested_state {0})\nw axis1.requested_state {0}\n'.format(AXIS_STATE_CLOSED_LOOP_CONTROL))
    def set_velocity(self, velocity):
        """Set motor velocity."""
@ -108,3 +161,4 @@ class ArniRobot:
        return self._vel
 arni = ArniRobot(uart)
 controller = RobotController(arni)