示例#1
0
def main():

    # import blocks and controller
    from pyctrl.rc.mip import Controller
    from pyctrl.block.container import Container, Input, Output
    from pyctrl.block.system import System, Subtract, Differentiator, Sum, Gain
    from pyctrl.block.nl import ControlledCombination, Product
    from pyctrl.block import Fade, Printer
    from pyctrl.system.ss import DTSS
    from pyctrl.block.logic import CompareAbsWithHysterisis, SetFilter, State
    from rcpy.gpio import GRN_LED, PAUSE_BTN
    from rcpy.led import red

    # export json?
    export_json = True

    # create mip
    mip = Controller()

    # phi is the average of the encoders
    mip.add_signal('phi')
    mip.add_filter('phi', Sum(gain=0.5), ['encoder1', 'encoder2'], ['phi'])

    # phi dot
    mip.add_signal('phi_dot')
    mip.add_filter('phi_dot', Differentiator(), ['clock', 'phi'], ['phi_dot'])

    # phi dot and steer reference
    mip.add_signals('phi_dot_reference', 'phi_dot_reference_fade')
    mip.add_signals('steer_reference', 'steer_reference_fade')

    # add fade in filter
    mip.add_filter('fade', Fade(target=[0, 0.5], period=5),
                   ['clock', 'phi_dot_reference', 'steer_reference'],
                   ['phi_dot_reference_fade', 'steer_reference_fade'])

    # state-space matrices
    A = np.array([[0.913134, 0.0363383], [-0.0692862, 0.994003]])
    B = np.array([[0.00284353, -0.000539063], [0.00162443, -0.00128745]])
    C = np.array([[-383.009, 303.07]])
    D = np.array([[-1.22015, 0]])

    B = 2 * np.pi * (100 / 7.4) * np.hstack((-B, B[:, 1:]))
    D = 2 * np.pi * (100 / 7.4) * np.hstack((-D, D[:, 1:]))

    ssctrl = DTSS(A, B, C, D)

    # state-space controller
    mip.add_signals('pwm')
    mip.add_filter('controller', System(model=ssctrl),
                   ['theta_dot', 'phi_dot', 'phi_dot_reference_fade'], ['pwm'])

    # enable pwm only if about small_angle
    mip.add_signals('small_angle', 'small_angle_pwm')
    mip.add_filter('small_angle_pwm', Product(), ['small_angle', 'pwm'],
                   ['small_angle_pwm'])

    # steering biasing
    mip.add_filter(
        'steer', ControlledCombination(),
        ['steer_reference_fade', 'small_angle_pwm', 'small_angle_pwm'],
        ['pwm1', 'pwm2'])

    # set references
    mip.set_signal('phi_dot_reference', 0)
    mip.set_signal('steer_reference', 0.5)

    # add supervisor actions on a timer
    # actions are inside a container so that they are executed all at once
    mip.add_timer('supervisor',
                  Container(), ['theta'], ['small_angle', 'is_running'],
                  period=0.5,
                  repeat=True)

    mip.add_signals('timer/supervisor/theta', 'timer/supervisor/small_angle')

    mip.add_source('timer/supervisor/theta', Input(), ['theta'])

    mip.add_sink('timer/supervisor/small_angle', Output(), ['small_angle'])

    mip.add_sink('timer/supervisor/is_running', Output(), ['is_running'])

    # add small angle sensor
    mip.add_filter(
        'timer/supervisor/is_angle_small',
        CompareAbsWithHysterisis(threshold=0.11,
                                 hysterisis=0.09,
                                 offset=-0.07,
                                 state=(State.LOW, )), ['theta'],
        ['small_angle'])

    # reset controller and fade
    mip.add_sink(
        'timer/supervisor/reset_controller',
        SetFilter(label=['/controller', '/fade'], on_rise={'reset': True}),
        ['small_angle'])

    # add green led
    mip.add_sink('timer/supervisor/green_led', ('pyctrl.rc.led', 'LED'),
                 ['small_angle'],
                 kwargs={'pin': GRN_LED},
                 enable=True)

    # add pause button on a timer
    mip.add_source('timer/supervisor/pause_button',
                   ('pyctrl.rc.button', 'Button'), ['is_running'],
                   kwargs={
                       'pin': PAUSE_BTN,
                       'invert': True
                   },
                   enable=True)

    # print controller
    print(mip.info('all'))

    # export json?
    if export_json:

        from pyctrl.flask import JSONEncoder

        # export controller as json
        json = JSONEncoder(sort_keys=True, indent=4).encode(mip)
        with open('rc_mip_balance.json', 'w') as f:
            f.write(json)

    fd = sys.stdin.fileno()
    old_settings = termios.tcgetattr(fd)
    try:

        print("""
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
*                       M I P   B A L A N C E                       *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
""")

        print("""
Hold your MIP upright to start balancing

Use your keyboard to control the mip:

* UP and DOWN arrows move forward and back
* LEFT and RIGHT arrows steer
* / stops forward motion
* . stops steering
* SPACE resets forward motion and steering

""")

        # reset everything
        mip.set_source('clock', reset=True)
        mip.set_source('encoder1', reset=True)
        mip.set_source('encoder2', reset=True)
        mip.set_filter('controller', reset=True)
        mip.set_source('inclinometer', reset=True)

        # turn on red led
        red.on()

        # start the controller
        mip.start()

        print("Press Ctrl-C or press the <PAUSE> button to exit")

        # fire thread to update velocities
        thread = threading.Thread(target=get_arrows, args=(mip, fd))
        thread.daemon = False
        thread.start()

        # and wait until controller dies
        mip.join()

        # print message
        print("\nDone with balancing")

    except KeyboardInterrupt:

        print("\nBalancing aborted")

    finally:

        # turn off red led
        red.off()

        # make sure it exits
        mip.set_state(pyctrl.EXITING)

        print("Press any key to exit")

        thread.join()

        termios.tcsetattr(fd, termios.TCSADRAIN, old_settings)
示例#2
0
def main():

    # import blocks and controller
    from pyctrl.rc.mip import Controller
    from pyctrl.block.container import Container, Input, Output
    from pyctrl.block.system import System, Subtract, Differentiator, Sum, Gain
    from pyctrl.block.nl import ControlledCombination, Product
    from pyctrl.block import Fade, Printer
    from pyctrl.system.ss import DTSS
    from pyctrl.block.logic import CompareAbsWithHysterisis, SetFilter, State
    from rcpy.gpio import GRN_LED, PAUSE_BTN
    from rcpy.led import red

    # export json?
    export_json = True

    # create mip
    mip = Controller()

    # phi is the average of the encoders
    mip.add_signal('phi')
    mip.add_filter('phi', Sum(gain=0.5), ['encoder1', 'encoder2'], ['phi'])

    # phi dot
    mip.add_signal('phi_dot')
    mip.add_filter('phi_dot', Differentiator(), ['clock', 'phi'], ['phi_dot'])

    # phi dot and steer reference
    mip.add_signals('pwm', 'pwm_fade')
    mip.add_signals('steer_reference', 'steer_reference_fade')

    # add fade in filter
    mip.add_filter('fade', Fade(target=[0, 0.5],
                                period=5), ['clock', 'pwm', 'steer_reference'],
                   ['pwm_fade', 'steer_reference_fade'])

    # steering biasing
    mip.add_filter('steer', ControlledCombination(),
                   ['steer_reference_fade', 'pwm_fade', 'pwm_fade'],
                   ['pwm1', 'pwm2'])

    # set references
    mip.set_signal('steer_reference', 0.5)

    # print controller
    print(mip.info('all'))

    # export json?
    if export_json:

        from pyctrl.flask import JSONEncoder

        # export controller as json
        json = JSONEncoder(sort_keys=True, indent=4).encode(mip)
        with open('rc_mip_drive.json', 'w') as f:
            f.write(json)

    fd = sys.stdin.fileno()
    old_settings = termios.tcgetattr(fd)
    try:

        print("""
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
*                         M I P   D R I V E                         *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
""")

        print("""
Use your keyboard to drive the mip as a car:

* UP and DOWN arrows move forward and back
* LEFT and RIGHT arrows steer
* / stops forward motion
* . stops steering
* SPACE resets forward motion and steering

""")

        # reset everything
        mip.set_source('clock', reset=True)
        mip.set_source('encoder1', reset=True)
        mip.set_source('encoder2', reset=True)
        mip.set_source('inclinometer', reset=True)

        # turn on red led
        red.on()

        # start the controller
        mip.start()

        print("Press Ctrl-C or press the <PAUSE> button to exit")

        # fire thread to update velocities
        thread = threading.Thread(target=get_arrows, args=(mip, fd))
        thread.daemon = False
        thread.start()

        # and wait until controller dies
        mip.join()

        # print message
        print("\nDone with driving")

    except KeyboardInterrupt:

        print("\nDriving aborted")

    finally:

        # turn off red led
        red.off()

        # make sure it exits
        mip.set_state(pyctrl.EXITING)

        print("Press any key to exit")

        thread.join()

        termios.tcsetattr(fd, termios.TCSADRAIN, old_settings)
示例#3
0
def _test_mip_balance():

    import numpy as np
    from pyctrl import Controller
    from pyctrl.block.container import Container, Input, Output
    from pyctrl.block.system import System, Subtract, Differentiator, Sum, Gain
    from pyctrl.block.nl import ControlledCombination, Product
    from pyctrl.block import Fade, Printer
    from pyctrl.system.ss import DTSS
    from pyctrl.block.logic import CompareAbsWithHysterisis, SetFilter, State

    GRN_LED = 61
    PAUSE_BTN = 62

    # create mip
    mip = Controller()

    # add signals
    mip.add_signals('theta', 'theta_dot', 'encoder1', 'encoder2', 'pwm1',
                    'pwm2')

    # phi is the average of the encoders
    mip.add_signal('phi')
    mip.add_filter('phi', Sum(gain=0.5), ['encoder1', 'encoder2'], ['phi'])

    # phi dot
    mip.add_signal('phi_dot')
    mip.add_filter('phi_dot', Differentiator(), ['clock', 'phi'], ['phi_dot'])

    # phi dot and steer reference
    mip.add_signals('phi_dot_reference', 'phi_dot_reference_fade')
    mip.add_signals('steer_reference', 'steer_reference_fade')

    # add fade in filter
    mip.add_filter('fade', Fade(target=[0, 0.5], period=5),
                   ['clock', 'phi_dot_reference', 'steer_reference'],
                   ['phi_dot_reference_fade', 'steer_reference_fade'])

    # state-space matrices
    A = np.array([[0.913134, 0.0363383], [-0.0692862, 0.994003]])
    B = np.array([[0.00284353, -0.000539063], [0.00162443, -0.00128745]])
    C = np.array([[-383.009, 303.07]])
    D = np.array([[-1.22015, 0]])

    B = 2 * np.pi * (100 / 7.4) * np.hstack((-B, B[:, 1:]))
    D = 2 * np.pi * (100 / 7.4) * np.hstack((-D, D[:, 1:]))

    ssctrl = DTSS(A, B, C, D)

    # state-space controller
    mip.add_signals('pwm')
    mip.add_filter('controller', System(model=ssctrl),
                   ['theta_dot', 'phi_dot', 'phi_dot_reference_fade'], ['pwm'])

    # enable pwm only if about small_angle
    mip.add_signals('small_angle', 'small_angle_pwm')
    mip.add_filter('small_angle_pwm', Product(), ['small_angle', 'pwm'],
                   ['small_angle_pwm'])

    # steering biasing
    mip.add_filter(
        'steer', ControlledCombination(),
        ['steer_reference_fade', 'small_angle_pwm', 'small_angle_pwm'],
        ['pwm1', 'pwm2'])

    # set references
    mip.set_signal('phi_dot_reference', 0)
    mip.set_signal('steer_reference', 0.5)

    # add supervisor actions on a timer
    # actions are inside a container so that they are executed all at once
    mip.add_timer('supervisor',
                  Container(), ['theta'], ['small_angle', 'is_running'],
                  period=0.5,
                  repeat=True)

    mip.add_signals('timer/supervisor/theta', 'timer/supervisor/small_angle',
                    'timer/supervisor/is_running')

    mip.add_source('timer/supervisor/theta', Input(), ['theta'])

    mip.add_sink('timer/supervisor/small_angle', Output(), ['small_angle'])

    mip.add_sink('timer/supervisor/is_running', Output(), ['is_running'])

    # add small angle sensor
    mip.add_filter(
        'timer/supervisor/is_angle_small',
        CompareAbsWithHysterisis(threshold=0.11,
                                 hysterisis=0.09,
                                 offset=-0.07,
                                 state=(State.LOW, )), ['theta'],
        ['small_angle'])

    # reset controller and fade
    mip.add_sink(
        'timer/supervisor/reset_controller',
        SetFilter(label=['/controller', '/fade'], on_rise={'reset': True}),
        ['small_angle'])

    # add pause button on a timer
    mip.add_source('timer/supervisor/pause_button',
                   ('pyctrl.block', 'Constant'), ['is_running'],
                   kwargs={'value': 0},
                   enable=True)

    from pyctrl.flask import JSONEncoder, JSONDecoder

    json1 = JSONEncoder(sort_keys=True, indent=4).encode(mip)

    obj = JSONDecoder().decode(json1)

    json2 = JSONEncoder(sort_keys=True, indent=4).encode(obj)

    assert json1 == json2

    print('json = \n{}'.format(json1))
示例#4
0
def main():

    # import blocks and controller
    from pyctrl.rc.mip import Controller
    from pyctrl.block.system import System, Subtract, Differentiator, Sum, Gain
    from pyctrl.block.nl import ControlledCombination
    from pyctrl.block import Logger, ShortCircuit
    from pyctrl.block.logic import CompareAbs
    from pyctrl.system.ss import DTSS

    # create mip
    mip = Controller()

    # phi is the average of the encoders
    mip.add_signal('phi')
    mip.add_filter('phi', Sum(gain=0.5), ['encoder1', 'encoder2'], ['phi'])

    # phi dot
    mip.add_signal('phi_dot')
    mip.add_filter('phi_dot', Differentiator(), ['clock', 'phi'], ['phi_dot'])

    # phi dot reference
    mip.add_signal('phi_dot_reference')

    # state-space matrices
    A = np.array([[0.913134, 0.0363383], [-0.0692862, 0.994003]])
    B = np.array([[0.00284353, -0.000539063], [0.00162443, -0.00128745]])
    C = np.array([[-383.009, 303.07]])
    D = np.array([[-1.22015, 0]])

    B = 2 * np.pi * (100 / 7.4) * np.hstack((-B, B[:, 1:]))
    D = 2 * np.pi * (100 / 7.4) * np.hstack((-D, D[:, 1:]))

    ssctrl = DTSS(A, B, C, D)

    # state-space controller
    mip.add_signals('pwm')
    mip.add_filter('controller', System(model=ssctrl),
                   ['theta_dot', 'phi_dot', 'phi_dot_reference'], ['pwm'])

    # steering biasing
    mip.add_signal('steer_reference')
    mip.add_filter('steer', ControlledCombination(),
                   ['steer_reference', 'pwm', 'pwm'], ['pwm1', 'pwm2'])

    # set references
    mip.set_signal('phi_dot_reference', 0)
    mip.set_signal('steer_reference', 0.5)

    # add kill switch
    mip.add_filter('kill', CompareAbs(threshold=0.2), ['theta'],
                   ['is_running'])

    # print controller
    print(mip.info('all'))

    fd = sys.stdin.fileno()
    old_settings = termios.tcgetattr(fd)
    try:

        print("""
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
*                       M I P   B A L A N C E                       *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
""")

        input('Hold your MIP upright and hit <ENTER> to start balancing')

        print("""
Use your keyboard to control the mip:

* UP and DOWN arrows move forward and back
* LEFT and RIGHT arrows steer
* / stops forward motion
* . stops steering
* SPACE resets forward motion and steering

""")

        # reset everything
        mip.set_source('clock', reset=True)
        mip.set_source('encoder1', reset=True)
        mip.set_source('encoder2', reset=True)
        mip.set_filter('controller', reset=True)
        mip.set_source('inclinometer', reset=True)

        # start the controller
        mip.start()

        print("Press Ctrl-C to exit")

        # fire thread to update velocities
        thread = threading.Thread(target=get_arrows, args=(mip, fd))
        thread.daemon = True
        thread.start()

        # and wait until controller dies
        mip.join()

    except KeyboardInterrupt:

        print("> Balancing aborted")
        mip.set_state(pyctrl.EXITING)

    finally:
        termios.tcsetattr(fd, termios.TCSADRAIN, old_settings)