示例#1
0
def main():
    controller_1 = Controller(controller_ID=2)
    # VitesseDeRotation = 0.5 #Vitesse de rotation (0.5 lent et 5 rapide)
    CoupleMoteur = 0.5
    position= 0

    while True:
        position = position + 0.01
        controller_1.set_position(position=position, max_torque=CoupleMoteur)
        time.sleep(0.01)
def main():
    controller_1 = Controller(controller_ID = 2)
    freq=300
    devider = 80
    while True:

        freq_measure_time = time.time()
        response_data_c1=controller_1.get_data()
        pos_deg_c1 = response_data_c1[MoteusReg.MOTEUS_REG_POSITION]*360
        pos_set_c1=(pos_deg_c1-((pos_deg_c1)%(360/devider)-(360/devider/2)))
        controller_1.set_position(position=pos_set_c1 / 360, max_torque=0.6, kd_scale=0., kp_scale=1)


        sleep = (1/(freq))-(time.time()-freq_measure_time)
        if(sleep<0): sleep = 0
        time.sleep(sleep)
示例#3
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def main():
    controller_1 = Controller(controller_ID=1)
    freq = 300
    while True:
        freq_measure_time = time.time()

        phase = (time.time() * 1) % (2. * math.pi)
        angle_deg = 100.0 / 360 * math.sin(phase)
        velocity_dps = 100.0 / 360 * math.cos(phase)

        controller_1.set_position(position=angle_deg,
                                  max_torque=0.2,
                                  kd_scale=0.2,
                                  get_data=True,
                                  print_data=False)

        # controller_1.set_velocity(velocity=velocity_dps, max_torque=0.5)

        # controller_1.set_torque(torque=torque_Nm)

        sleep = (1 / (freq)) - (time.time() - freq_measure_time)
        if (sleep < 0): sleep = 0
        time.sleep(sleep)
示例#4
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def main():
    controller_knee = Controller(controller_ID=1)
    controller_hip = Controller(controller_ID=2)
    controller_abad = Controller(controller_ID=3)

    kinematics = Kinematics()

    freq = 200

    while True:
        freq_measure_time = time.time()

        x_in, y_in = pyautogui.position()

        MaxX = 80
        MaxY = 100 + 58
        MinX = -120
        MinY = -100 + 58

        y = (y_in - 1440) / 8 + 80 + 58
        x = -x_in / 8 + 80
        z = 250  # -y_in/10+280

        # x = lim(x, MinX, MaxX)
        # y = lim(y, MinY, MaxY)

        print(x, y, z)

        knee, hip, abad = kinematics.ik(x, y, z)

        controller_knee.set_position(position=knee,
                                     max_torque=1,
                                     kd_scale=0.4,
                                     kp_scale=0.8)
        controller_hip.set_position(position=hip,
                                    max_torque=1,
                                    kd_scale=0.4,
                                    kp_scale=0.8)
        controller_abad.set_position(position=abad,
                                     max_torque=1,
                                     kd_scale=0.4,
                                     kp_scale=0.8)

        sleep = (1 / freq) - (time.time() - freq_measure_time)
        if sleep < 0: sleep = 0
        time.sleep(sleep)
示例#5
0
def main():
    controller_knee = Controller(controller_ID=1)
    controller_hip = Controller(controller_ID=2)
    controller_abad = Controller(controller_ID=3)

    kinematics = Kinematics()

    freq = 200

    while True:
        freq_measure_time = time.time()
        phase1 = (time.time() * 10) % (2 * math.pi)
        phase2 = (time.time() * 0.5) % (2 * math.pi)

        x = radius * 1.5 * math.cos(phase1) * math.cos(phase2) - 40
        y = radius * math.cos(phase1) * math.sin(phase2) + 58
        z = 220 + radius * math.sin(phase1)

        knee, hip, abad = kinematics.ik(x, y, z)

        controller_knee.set_position(position=knee,
                                     max_torque=torque,
                                     kd_scale=0.5,
                                     kp_scale=1)
        controller_hip.set_position(position=hip,
                                    max_torque=torque,
                                    kd_scale=0.5,
                                    kp_scale=1)
        controller_abad.set_position(position=abad,
                                     max_torque=torque,
                                     kd_scale=0.5,
                                     kp_scale=1)

        sleep = (1 / freq) - (time.time() - freq_measure_time)
        if sleep < 0: sleep = 0
        time.sleep(sleep)
示例#6
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def main():
    controller_knee = Controller(controller_ID=1)
    controller_hip = Controller(controller_ID=2)
    controller_abad = Controller(controller_ID=3)

    kinematics = Kinematics()

    freq = 200
    period = 60 / 173

    jump_duration = 0.1
    idle_duration = 0.1  # 0.35

    jump_torque = 2  #2
    land_torque = 1.5  #1.2

    jump_stance_low = 220
    jump_stance_high = 290

    retract_duration = period - jump_duration - idle_duration
    begin_time = time.time()
    x = 0
    y = 0
    x_rand_prev = 0
    y_rand_prev = 0

    i = 0

    while i < 100:
        i = i + 1
        knee, hip, abad = kinematics.ik(0, 58, 200)
        controller_knee.set_position(position=knee,
                                     max_torque=jump_torque,
                                     kd_scale=0.8,
                                     kp_scale=0.7)
        controller_hip.set_position(position=hip,
                                    max_torque=jump_torque,
                                    kd_scale=0.8,
                                    kp_scale=0.7)
        controller_abad.set_position(position=abad,
                                     max_torque=jump_torque,
                                     kd_scale=0.8,
                                     kp_scale=0.7)
        time.sleep(0.01)

    while True:
        while True:
            y_rand = 58  #50*math.cos(time.time()/0.8) +48#random.randrange(58-30, 58+30)
            x_rand = 0  #60*math.sin(time.time()/0.8) - 30 # random.randrange(-41, -40)
            controller_knee.get_data(print_data=True)
            controller_hip.get_data(print_data=True)
            print(x_rand, y_rand)
            print(" ")
            break
            '''
            if ((y_rand-y_rand_prev)**2+(x_rand-x_rand_prev)**2)**(1/2)>60:
                print(f't: {time.time():.2f} x: {x_rand:.2f} x_prev {x_rand_prev:.2f} y: {x_rand:.2f} y_prev {x_rand_prev:.2f}')
                break'''

        phase = 0
        #print('NEW')
        while phase < (period - 1 / freq):
            #print(phase)
            freq_measure_time = time.time()
            phase = (time.time() - begin_time) % (period)

            if phase <= jump_duration:
                jump_phase = phase / jump_duration
                x = x_rand_prev
                y = y_rand_prev
                z = (jump_stance_low +
                     (30 / 150 * (128 - y))) + ((jump_stance_high - 40 / 150 *
                                                 ((y**2 + x**2)**(1 / 2))) -
                                                (jump_stance_low +
                                                 (30 / 150 *
                                                  (128 - y)))) * jump_phase

                knee, hip, abad = kinematics.ik(x, y, z)

                controller_knee.set_position(position=knee,
                                             max_torque=jump_torque,
                                             kd_scale=0.01,
                                             kp_scale=1)
                controller_hip.set_position(position=hip,
                                            max_torque=jump_torque,
                                            kd_scale=0.01,
                                            kp_scale=1)
                controller_abad.set_position(position=abad,
                                             max_torque=jump_torque,
                                             kd_scale=0.01,
                                             kp_scale=1)

            if (period - retract_duration) > phase >= jump_duration:
                idle_phase = (
                    phase - jump_duration) / idle_duration  # normalize to 0-1

                x = x_rand_prev + (x_rand - x_rand_prev) * idle_phase
                y = y_rand_prev + (y_rand - y_rand_prev) * idle_phase
                z = (jump_stance_high - 40 / 150 *
                     (((y_rand)**2 + x_rand**2)**(1 / 2)))

                knee, hip, abad = kinematics.ik(x, y, z)

                controller_knee.set_position(position=knee,
                                             max_torque=jump_torque,
                                             kd_scale=0.1,
                                             kp_scale=1)
                controller_hip.set_position(position=hip,
                                            max_torque=jump_torque,
                                            kd_scale=0.1,
                                            kp_scale=1)
                controller_abad.set_position(position=abad,
                                             max_torque=jump_torque,
                                             kd_scale=0.5,
                                             kp_scale=1)

            if phase > (period - retract_duration):

                retract_phase = (phase - jump_duration - idle_duration
                                 ) / retract_duration  # normalize to 0-1
                x = x_rand
                y = y_rand
                z = (jump_stance_high - 40 / 150 *
                     (((y_rand)**2 + x_rand**2)**(1 / 2))) - (
                         (jump_stance_high - 40 / 150 *
                          (((y_rand)**2 + x_rand**2)**(1 / 2))) -
                         (jump_stance_low + (30 / 150 *
                                             (128 - y)))) * retract_phase

                knee, hip, abad = kinematics.ik(x, y, z)

                controller_knee.set_position(position=knee,
                                             max_torque=land_torque,
                                             kd_scale=0.8,
                                             kp_scale=0.4)
                controller_hip.set_position(position=hip,
                                            max_torque=land_torque,
                                            kd_scale=0.8,
                                            kp_scale=0.4)
                controller_abad.set_position(position=abad,
                                             max_torque=land_torque,
                                             kd_scale=0.8,
                                             kp_scale=1)

            sleep = (1 / freq) - (time.time() - freq_measure_time)
            if sleep < 0: sleep = 0
            time.sleep(sleep)
            #print(f'freq: {1 / (time.time() - freq_measure_time):.1f}')
        x_rand_prev = x_rand
        y_rand_prev = y_rand
示例#7
0
def main():
    controller_knee = Controller(controller_ID=1)
    controller_hip = Controller(controller_ID=2)
    controller_abad = Controller(controller_ID=3)

    kinematics = Kinematics()
    filter = 20

    freq = 200
    period = 1.5
    robot_knee_torque = 0
    robot_hip_torque = 0
    robot_abad_torque = 0
    homing_speed = 2

    while 1:
        freq_measure_time = time.time()

        if (robot_hip_torque < 0.4):

            response_data_hip = controller_hip.set_position(
                position=math.nan,
                velocity=homing_speed,
                max_torque=0.5,
                kd_scale=0.2,
                get_data=True,
                print_data=False)
            robot_hip_rot_org = response_data_hip[
                MoteusReg.MOTEUS_REG_POSITION]
            robot_hip_torque = (response_data_hip[MoteusReg.MOTEUS_REG_TORQUE]
                                + filter * robot_hip_torque) / (filter + 1)

        else:
            hip_home_offset = robot_hip_rot_org
            print("hip:", hip_home_offset)
            break

        sleep = (1 / freq) - (time.time() - freq_measure_time)
        if sleep < 0: sleep = 0
        time.sleep(sleep)

    while 1:
        freq_measure_time = time.time()

        if (robot_knee_torque > -0.4):
            response_data_knee = controller_knee.set_position(
                position=math.nan,
                velocity=-homing_speed,
                max_torque=0.5,
                kd_scale=0.2,
                get_data=True,
                print_data=False)
            controller_hip.set_position(position=math.nan,
                                        velocity=0.1,
                                        max_torque=0.8,
                                        kd_scale=0.2)

            robot_knee_rot_org = response_data_knee[
                MoteusReg.MOTEUS_REG_POSITION]
            robot_knee_torque = (
                response_data_knee[MoteusReg.MOTEUS_REG_TORQUE] +
                filter * robot_knee_torque) / (filter + 1)

        else:
            knee_home_offset = robot_knee_rot_org
            print("knee:", knee_home_offset)
            break

    while 1:
        freq_measure_time = time.time()

        if (robot_abad_torque > -0.3):
            response_data_abad = controller_abad.set_position(
                position=math.nan,
                velocity=-homing_speed,
                max_torque=0.4,
                kd_scale=0.2,
                get_data=True,
                print_data=False)
            controller_hip.set_position(position=hip_home_offset - 1,
                                        max_torque=0.5,
                                        kd_scale=1)
            controller_knee.set_position(position=math.nan,
                                         velocity=math.nan,
                                         max_torque=0.8,
                                         kd_scale=0.2)
            robot_abad_rot_org = response_data_abad[
                MoteusReg.MOTEUS_REG_POSITION]
            robot_abad_torque = (
                response_data_abad[MoteusReg.MOTEUS_REG_TORQUE] +
                filter * robot_abad_torque) / (filter + 1)

        else:
            abad_home_offset = robot_abad_rot_org
            print("abad:", abad_home_offset)
            break

    while 1:
        freq_measure_time = time.time()

        controller_hip.set_position(position=hip_home_offset - 1.3,
                                    max_torque=0.3,
                                    kd_scale=1)
        controller_knee.set_position(position=knee_home_offset + 0.19,
                                     max_torque=0.3,
                                     kd_scale=0.7)
        controller_abad.set_position(position=abad_home_offset + 1.4,
                                     max_torque=0.3,
                                     kd_scale=0.7)

        sleep = (1 / freq) - (time.time() - freq_measure_time)
        if sleep < 0: sleep = 0
        time.sleep(sleep)
def main():
    #############################################   SETUP PARAMETERS   ################################################
    pull_duration = 0.07  # First part of the cycle - over this amount of time the motor pulls the cable with full Troque
    release_duration = 0.15  # next part of the cycle - a gradual release starting at max torque ending at standby_torque
    duty_cycle = 0.8  #duty cycle of the test
    max_torque = 3  #maximum torque exerted by the motor
    standbay_torque = 0.05  #between pulls the motor still exerts some torque - to keep the cable tight
    ###################################################################################################################

    c = Controller(controller_ID=1)  #create controller object
    c.command_stop()  #comand_stop cleares anny errors/faults in the controller
    max_measured_velocity = 0  #this variable stores the max measured rotational velocity of the motor and is used for safety and can be observed as an erformance indicator
    counter = 0  #if you had to interrupt testing and need to start again but not count from 0 - input the number starting number you want here.
    time_zero = time.time()
    previous_phase = 0  #variable used to detect switching from one cycle to the next
    while True:
        phase = (time.time() - time_zero) % (
            duty_cycle
        )  #what is happening during the cycle depends on the phase value. Phase is in seconds

        #below - the behaviour of the system is dependent on the value of phase - in different value ranges different behaviours are triggered
        if phase < pull_duration:
            #initiall full torque pull
            measurements = c.set_position(
                position=0,
                max_torque=4,
                ff_torque=max_torque,
                kp_scale=0,
                kd_scale=0,
                get_data=True,
                print_data=False
            )  #measurements are collected to extract velocity - which if too high stops the system (safety)
        elif phase >= pull_duration and phase <= pull_duration + release_duration:
            #gradual release
            release_phase = (
                (pull_duration + release_duration - phase) / release_duration
            )  #value normalized from 1 to 0.
            torque = standbay_torque + (
                max_torque - standbay_torque
            ) * release_phase  #torque ges from max_torque to standby_torque
            measurements = c.set_position(
                position=0,
                max_torque=4,
                ff_torque=torque,
                kp_scale=0,
                kd_scale=0,
                get_data=True,
                print_data=False
            )  #measurements are collected to extract velocity - which if too high stops the system (safety)
        else:
            measurements = c.set_position(
                position=0,
                max_torque=4,
                ff_torque=standbay_torque,
                kp_scale=0,
                kd_scale=0.1,
                get_data=True,
                print_data=False
            )  #measurements are collected to extract velocity - which if too high stops the system (safety)

        if max_measured_velocity < abs(
                measurements[MoteusReg.MOTEUS_REG_VELOCITY]):  #for diagnostics
            max_measured_velocity = abs(
                measurements[MoteusReg.MOTEUS_REG_VELOCITY])
            print("Max velocity that occured so far: " +
                  str(abs(measurements[MoteusReg.MOTEUS_REG_VELOCITY])))
        if max_measured_velocity > 25: break

        if (previous_phase > phase):  #code for counting phase cycles
            counter = counter + 1
            print("Temperature = " +
                  str(measurements[MoteusReg.MOTEUS_REG_TEMP_C]) +
                  "  Counter = " + str(counter))
        previous_phase = phase

    c.set_position(
        position=0,
        velocity=0,
        max_torque=1,
        ff_torque=0,
        kp_scale=0,
        kd_scale=1,
        get_data=True,
        print_data=False
    )  #if there is a break in the loop above - the velocity limit is exceeded - this command stops the rotr
示例#9
0
def main():
    controller_1 = Controller(controller_ID=1)
    controller_2 = Controller(controller_ID=2)
    freq=600

    response_data_c1 = controller_1.get_data()
    pos_deg_c1 = response_data_c1[MoteusReg.MOTEUS_REG_POSITION]
    vel_dps_c1 = response_data_c1[MoteusReg.MOTEUS_REG_VELOCITY]

    response_data_c2 = controller_2.get_data()
    pos_deg_c2 = response_data_c2[MoteusReg.MOTEUS_REG_POSITION]
    vel_dps_c2 = response_data_c2[MoteusReg.MOTEUS_REG_VELOCITY]

    filter_pos = 0.1
    filter_vel = 5# 4
    multiplyer = 1
    kp_scale = 0.2
    kd_scale = 1
    max_torque = 1

    response_data_c1 = controller_1.get_data()
    response_data_c2 = controller_2.get_data()

    while True:


        # response_data_c1 = controller_1.get_data()
        # pos_deg_c1 = response_data_c1[MoteusReg.MOTEUS_REG_POSITION]*360
        # vel_dps_c1 = response_data_c1[MoteusReg.MOTEUS_REG_VELOCITY] * 360
        #
        # response_data_c2 = controller_2.get_data()
        # pos_deg_c2 = -response_data_c2[MoteusReg.MOTEUS_REG_POSITION] * 360-110
        # vel_dps_c2 = -response_data_c2[MoteusReg.MOTEUS_REG_VELOCITY] * 360
        #
        #
        # controller_1.set_position(position=(pos_deg_c2)/ 360, velocity=vel_dps_c2/360,  max_torque=0.5, kd_scale=0.2, kp_scale=1)
        # controller_2.set_position(position=(-pos_deg_c1-110) / 360, velocity=-vel_dps_c1/360, max_torque=0.5, kd_scale=0.2, kp_scale=1)

        freq_measure_time = time.time()



        pos_deg_c1 = (pos_deg_c1*filter_pos + response_data_c1[MoteusReg.MOTEUS_REG_POSITION])/(filter_pos+1)
        vel_dps_c1 = (vel_dps_c1*filter_vel + response_data_c1[MoteusReg.MOTEUS_REG_VELOCITY])/(filter_vel+1)


        pos_deg_c2 = (pos_deg_c2*filter_pos + response_data_c2[MoteusReg.MOTEUS_REG_POSITION])/(filter_pos+1)
        vel_dps_c2 = (vel_dps_c2*filter_vel + response_data_c2[MoteusReg.MOTEUS_REG_VELOCITY])/(filter_vel+1)

        response_data_c1 = controller_1.set_position(position=(pos_deg_c2 / multiplyer),
                                                     velocity=vel_dps_c2 / multiplyer, max_torque=max_torque,
                                                     kd_scale=kd_scale, kp_scale=kp_scale, get_data=True)
        response_data_c2 = controller_2.set_position(position=(multiplyer * pos_deg_c1),
                                                     velocity=vel_dps_c1 * multiplyer, max_torque=max_torque,
                                                     kd_scale=kd_scale, kp_scale=kp_scale, get_data=True)




        print(f'pos c1: {pos_deg_c1:.1f} pos c2: {pos_deg_c2:.1f}')

        sleep = (1/(freq))-(time.time()-freq_measure_time)
        if(sleep<0): sleep = 0
        time.sleep(sleep)
示例#10
0
def main():
    controller_knee = Controller(controller_ID = 1)
    controller_hip = Controller(controller_ID = 2)
    controller_abad = Controller(controller_ID=3)

    response_data_c1 = controller_knee.get_data()
    robot_knee_rot = response_data_c1[MoteusReg.MOTEUS_REG_POSITION]
    response_data_c2 = controller_hip.get_data()
    robot_hip_rot = response_data_c2[MoteusReg.MOTEUS_REG_POSITION]
    kinematics = Kinematics(robot_knee_rot, robot_hip_rot)


    freq=300
    period =1

    jump_duration = 0.1
    idle_duration = 0.2 # 0.35


    jump_torque = 2
    land_torque = 1.4

    jump_stance_low = 70
    jump_stance_high = 280
    x_pos = 0

    retract_duration = period - jump_duration - idle_duration
    begin_time=time.time()


    while True:
        freq_measure_time = time.time()
        phase = (time.time()-begin_time+idle_duration+jump_duration) % (period)

        if phase <= jump_duration:
            jump_phase = phase/jump_duration
            x = -x_pos
            z = jump_stance_low + (jump_stance_high-jump_stance_low)*jump_phase


            if kinematics.if_ik_possible(x, z):
                robot_hip_rot, robot_knee_rot = kinematics.ik(x, z)

                controller_hip.set_position(position=robot_hip_rot, max_torque=jump_torque, kd_scale=0.4, kp_scale=1)
                controller_knee.set_position(position=robot_knee_rot, max_torque=jump_torque, kd_scale=0.4, kp_scale=1)

        if (period - retract_duration) > phase >= jump_duration:
            idle_phase = (phase - jump_duration) / idle_duration  # normalize to 0-1

            x = -x_pos-0*idle_phase
            z = jump_stance_high

            # z = jump_stance_high - 10 - 40 * idle_phase
            # if idle_phase<0.25:
            #     x=-60*(idle_phase*4) -15
            # elif idle_phase<0.5:
            #     x=60-120*(idle_phase*2-0.5) -15
            # else:
            #     x=-60+60* (idle_phase * 4 - 3) -15


            if kinematics.if_ik_possible(x, z):
                robot_hip_rot, robot_knee_rot = kinematics.ik(x, z)

                controller_hip.set_position(position=robot_hip_rot, max_torque=jump_torque, kd_scale=0.2, kp_scale=1)
                controller_knee.set_position(position=robot_knee_rot, max_torque=jump_torque, kd_scale=0.2, kp_scale=1)
            else:
                print(x,z)

        if phase > (period-retract_duration):

            retract_phase = (phase - jump_duration-idle_duration) / retract_duration # normalize to 0-1
            x = -x_pos + 0*(1-retract_phase)
            z = jump_stance_high - (jump_stance_high-jump_stance_low) * retract_phase

            if kinematics.if_ik_possible(x, z):
                robot_hip_rot, robot_knee_rot = kinematics.ik(x, z)

                controller_hip.set_position(position=robot_hip_rot, max_torque=land_torque, kd_scale=1, kp_scale=0.3)
                controller_knee.set_position(position=robot_knee_rot, max_torque=land_torque, kd_scale=1, kp_scale=0.3)








        # if kinematics.if_ik_possible(x, z):
        #     robot_hip_rot_calculated, robot_knee_rot_calculated = kinematics.ik(x, z)
        #
        #     response_data_c1 = controller_knee.get_data()
        #     robot_knee_rot_measured = response_data_c1[MoteusReg.MOTEUS_REG_POSITION]
        #     response_data_c2 = controller_hip.get_data()
        #     robot_hip_rot_measured = response_data_c2[MoteusReg.MOTEUS_REG_POSITION]
        #
        #     #print(robot_hip_rot_calculated, robot_hip_rot_measured, robot_knee_rot_calculated, robot_hip_rot_measured)
        #
        #     controller_hip.set_position(position=robot_hip_rot_calculated, max_torque=1.5, kd_scale=0.8, kp_scale=1.2)
        #     controller_knee.set_position(position=robot_knee_rot_calculated, max_torque=1.5, kd_scale=0.8, kp_scale=1.2)



        sleep = (1/freq)-(time.time()-freq_measure_time)
        if sleep < 0: sleep = 0
        time.sleep(sleep)
def main():
    c = Controller(controller_ID=1)
    pos = 0
    while True:
        pos = pos + 0.0003
        c.set_position(position=0, max_torque=3, kp_scale=1, kd_scale=0.8)
示例#12
0
def main():
    controller_knee = Controller(controller_ID=1)
    controller_hip = Controller(controller_ID=2)
    controller_abad = Controller(controller_ID=3)
    kinematics = Kinematics()
    freq = 300

    #PID
    kd_scale_air = 0.3  #D
    kp_scale_air = 1  #P

    kd_scale_ground = 0.6  # D
    kp_scale_ground = 0.6  # P
    torque = 1

    period = 0.5

    #time proportins
    ground = 15
    ret = 4
    lift = 8
    descend = 10

    #geometry - [mm]
    direction_deg = 30
    stride = 0

    ground_z = 250
    air_z = ground_z - 65
    y_zero = 58

    begin_time = time.time()

    while True:

        stride = math.sin(((time.time() * 0.5) % (2 * math.pi))) * 50 + 50
        print(stride)

        if stride >= 30:
            sin_scaler = 0.76
        else:
            sin_scaler = stride / 45

        start_x = 0.5 * stride
        end_x = -stride + start_x

        sum = ground + lift + ret + descend

        ground_end = (ground / sum) * period
        lift_end = ((ground + lift) / sum) * period
        return_end = ((ground + lift + ret) / sum) * period
        descend_end = ((ground + lift + ret + descend) / sum) * period

        ground_duration = ground_end
        lift_duration = lift_end - ground_end
        return_duration = return_end - lift_end
        descend_duration = descend_end - return_end

        direction = direction_deg / 360 * math.pi * 2

        freq_measure_time = time.time()
        phase = (time.time() - begin_time + lift_duration +
                 ground_duration) % period

        if phase <= ground_end:
            ground_phase = phase / ground_duration

            x = math.cos(direction) * (start_x +
                                       (end_x - start_x) * ground_phase)
            y = y_zero + math.sin(direction) * (
                start_x + (end_x - start_x) * ground_phase)
            z = ground_z + (ground_z - ground_z) * ground_phase

            if kinematics.if_ik_possible(x, y, z):
                knee, hip, abad = kinematics.ik(x, y, z)

                controller_knee.set_position(position=knee,
                                             max_torque=torque,
                                             kd_scale=kd_scale_ground,
                                             kp_scale=kp_scale_ground)
                controller_hip.set_position(position=hip,
                                            max_torque=torque,
                                            kd_scale=kd_scale_ground,
                                            kp_scale=kp_scale_ground)
                controller_abad.set_position(position=abad,
                                             max_torque=torque,
                                             kd_scale=kd_scale_ground,
                                             kp_scale=kp_scale_ground)
            else:
                print(x, z)

        if ground_end < phase <= lift_end:
            lift_phase = (phase -
                          ground_end) / lift_duration  # normalize to 0-1

            x = math.cos(direction) * (end_x + (sin_scaler *
                                                (ground_z - air_z)) *
                                       (-math.sin(lift_phase * math.pi)))
            y = y_zero + math.sin(direction) * (
                end_x + (sin_scaler * (ground_z - air_z)) *
                (-math.sin(lift_phase * math.pi)))
            z = ground_z + (air_z - ground_z) * (
                math.sin(lift_phase * math.pi - math.pi / 2) / 2 + 0.5)

            if kinematics.if_ik_possible(x, y, z):
                knee, hip, abad = kinematics.ik(x, y, z)

                controller_knee.set_position(
                    position=knee,
                    max_torque=torque,
                    kd_scale=kd_scale_ground -
                    (kd_scale_ground - kd_scale_air) * lift_phase,
                    kp_scale=kp_scale_ground -
                    (kp_scale_ground - kp_scale_air) * lift_phase)
                controller_hip.set_position(
                    position=hip,
                    max_torque=torque,
                    kd_scale=kd_scale_ground -
                    (kd_scale_ground - kd_scale_air) * lift_phase,
                    kp_scale=kp_scale_ground -
                    (kp_scale_ground - kp_scale_air) * lift_phase)
                controller_abad.set_position(
                    position=abad,
                    max_torque=torque,
                    kd_scale=kd_scale_ground -
                    (kd_scale_ground - kd_scale_air) * lift_phase,
                    kp_scale=kp_scale_ground -
                    (kp_scale_ground - kp_scale_air) * lift_phase)
            else:
                print(x, z)

        if lift_end < phase <= return_end:
            return_phase = (phase -
                            lift_end) / return_duration  # normalize to 0-1

            x = math.cos(direction) * (end_x +
                                       (start_x - end_x) * return_phase)
            y = y_zero + math.sin(direction) * (
                end_x + (start_x - end_x) * return_phase)
            z = air_z

            if kinematics.if_ik_possible(x, y, z):
                knee, hip, abad = kinematics.ik(x, y, z)

                controller_knee.set_position(position=knee,
                                             max_torque=torque,
                                             kd_scale=kd_scale_air,
                                             kp_scale=kp_scale_air)
                controller_hip.set_position(position=hip,
                                            max_torque=torque,
                                            kd_scale=kd_scale_air,
                                            kp_scale=kp_scale_air)
                controller_abad.set_position(position=abad,
                                             max_torque=torque,
                                             kd_scale=kd_scale_air,
                                             kp_scale=kp_scale_air)
            else:
                print(x, z)

        if return_end < phase <= descend_end:

            descend_phase = (phase -
                             return_end) / descend_duration  # normalize to 0-1

            x = math.cos(direction) * (start_x + (sin_scaler *
                                                  (ground_z - air_z)) *
                                       (math.sin(descend_phase * math.pi)))
            y = y_zero + math.sin(direction) * (
                start_x + (sin_scaler * (ground_z - air_z)) *
                (math.sin(descend_phase * math.pi)))
            z = air_z + (ground_z - air_z) * (
                math.sin(descend_phase * math.pi - math.pi / 2) / 2 + 0.5)

            if kinematics.if_ik_possible(x, y, z):
                knee, hip, abad = kinematics.ik(x, y, z)

                controller_knee.set_position(
                    position=knee,
                    max_torque=torque,
                    kd_scale=kd_scale_air +
                    (kd_scale_ground - kd_scale_air) * descend_phase,
                    kp_scale=kp_scale_air +
                    (kp_scale_ground - kp_scale_air) * descend_phase)
                controller_hip.set_position(
                    position=hip,
                    max_torque=torque,
                    kd_scale=kd_scale_air +
                    (kd_scale_ground - kd_scale_air) * descend_phase,
                    kp_scale=kp_scale_air +
                    (kp_scale_ground - kp_scale_air) * descend_phase)
                controller_abad.set_position(
                    position=abad,
                    max_torque=torque,
                    kd_scale=kd_scale_air +
                    (kd_scale_ground - kd_scale_air) * descend_phase,
                    kp_scale=kp_scale_air +
                    (kp_scale_ground - kp_scale_air) * descend_phase)
            else:
                print(x, z)

        sleep = (1 / freq) - (time.time() - freq_measure_time)
        if sleep < 0: sleep = 0
        time.sleep(sleep)
示例#13
0
def main():
    controller_knee = Controller(controller_ID=1)
    controller_hip = Controller(controller_ID=2)
    controller_abad = Controller(controller_ID=3)

    kinematics = Kinematics()

    freq = 200
    knee = math.nan
    hip = math.nan
    abad = math.nan
    velocity_knee = 0
    velocity_hip = 0
    velocity_abad = 0

    tq = 0
    while True:

        freq_measure_time = time.time()

        x = 0
        y = 0
        z = 0

        data_knee = controller_knee.set_position(position=knee,
                                                 velocity=velocity_knee / 2,
                                                 max_torque=1.5 * tq,
                                                 kd_scale=0.2 * tq,
                                                 kp_scale=1.4 * tq,
                                                 get_data=True)
        data_hip = controller_hip.set_position(position=hip,
                                               velocity=velocity_hip / 2,
                                               max_torque=0.8 * tq,
                                               kd_scale=0.2 * tq,
                                               kp_scale=1.4 * tq,
                                               get_data=True)
        data_abad = controller_abad.set_position(position=abad,
                                                 velocity=velocity_abad / 2,
                                                 max_torque=0.8 * tq,
                                                 kd_scale=0.2 * tq,
                                                 kp_scale=1.4 * tq,
                                                 get_data=True)
        tq = 0

        x, y, z = kinematics.fk(data_knee[MoteusReg.MOTEUS_REG_POSITION],
                                data_hip[MoteusReg.MOTEUS_REG_POSITION],
                                data_abad[MoteusReg.MOTEUS_REG_POSITION])

        if z > 240:
            z = -((z - 240)) * 1.5 + z
            tq = 1
        if z < 160:
            z = -((z - 160)) * 1.5 + z
            tq = 1
        if y > 108:
            y = -((y - 108)) * 1.5 + y
            tq = 1
        if y < -8:
            y = -((y + 8)) * 1.5 + y
            tq = 1
        if x > 80:
            x = -((x - 80)) * 1.5 + x
            tq = 1
        if x < -100:
            x = -((x + 100)) * 1.5 + x
            tq = 1

        knee, hip, abad = kinematics.ik(x, y, z)
        velocity_knee = data_knee[MoteusReg.MOTEUS_REG_VELOCITY]
        velocity_hip = data_hip[MoteusReg.MOTEUS_REG_VELOCITY]
        velocity_abad = data_abad[MoteusReg.MOTEUS_REG_VELOCITY]

        sleep = (1 / freq) - (time.time() - freq_measure_time)
        if sleep < 0: sleep = 0
        time.sleep(sleep)