def airSimCommunicator(self):
        while (self.remaining > 0):
            time.sleep(0.02)
            self.remaining -= 0.02

            kpDur = numpy.array([self.f(xi) for xi in self.keyPressDurations])

            max_ = numpy.sqrt(numpy.sqrt(500))
            throttle = (kpDur[0] - kpDur[1]) / max_ * 0.5
            yaw = (kpDur[2] - kpDur[3]) / max_ * 0.5
            pitch = (kpDur[4] - kpDur[5]) / max_ * 0.5
            roll = (kpDur[6] - kpDur[7]) / max_ * 0.5

            rcdata = airsim.RCData(0,
                                   pitch=pitch,
                                   roll=roll,
                                   throttle=throttle,
                                   yaw=yaw,
                                   is_initialized=True,
                                   is_valid=True)
            global client
            client.moveByRC(rcdata)

            # debug
            self.historicalValues = numpy.c_[self.historicalValues,
                                             [throttle, yaw, pitch, roll]]
Exemple #2
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    def _step(self, action):
        assert self.action_space.contains(
            action), "%r (%s) invalid" % (action, type(action))

        self.addToLog('action', action)

        self.stepN += 1

        airgym.moveByRC(rcdata=airsim.RCData(roll=action[0],
                                             pitch=action[1],
                                             yaw=action[2],
                                             throttle=action[3],
                                             is_initialized=True,
                                             is_valid=True))
        collided = airgym.take_action(action)

        now = airgym.getPosition()
        track = airgym.goal_direction(self.goal, now)

        if collided == True:
            done = True
            reward = -100.0
            distance = np.sqrt(
                np.power((self.goal[0] - now.x_val), 2) +
                np.power((self.goal[1] - now.y_val), 2))
        elif collided == 99:
            done = True
            reward = 0.0
            distance = np.sqrt(
                np.power((self.goal[0] - now.x_val), 2) +
                np.power((self.goal[1] - now.y_val), 2))
        else:
            done = False
            reward, distance = self.computeReward(now, track)

        # Youuuuu made it
        if distance < 3:
            done = True
            reward = 100.0

        self.addToLog('reward', reward)
        rewardSum = np.sum(self.allLogs['reward'])
        self.addToLog('distance', distance)
        self.addToLog('track', track)

        # Terminate the episode on large cumulative amount penalties,
        # since drone probably got into an unexpected loop of some sort
        if rewardSum < -100:
            done = True

        sys.stdout.write(
            "\r\x1b[K{}/{}==>reward/depth: {:.1f}/{:.1f}   \t {:.0f}  {:.0f}".
            format(self.episodeN, self.stepN, reward, rewardSum, track,
                   action))
        sys.stdout.flush()

        info = {"x_pos": now.x_val, "y_pos": now.y_val}
        self.state = airgym.getMultirotorState()

        return self.state, reward, done, info
Exemple #3
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def thread_obdelava(q):
    global hist
    global histVhod
    global done

    chunkN = 0

    while(True):
        try:
            data = q.get()

            vhod = normaliziraj_vektorsko(numpy.fromstring(data, numpy.int16))
            vhod = vhod.flatten()[0:vhod.size:2]
            # najprej iscemo prvi vzorec manjsi od -0.5, nato alterniramo med manjsi/vecji
            vecOd05 = False
            threshhold = -0.5
            downs = numpy.zeros(9)
            ups = numpy.zeros(9)
            kanal = 0
            for i in range(0, CHUNK, 1):
                if (kanal >= 9):
                    break
                if (vecOd05):
                    if (vhod[i] > threshhold):
                        ups[kanal] = i
                        #prepare for next
                        kanal += 1
                        vecOd05 = False
                        i += 5
                else:
                    if (vhod[i] < threshhold):
                        downs[kanal] = i
                        # prepare for next
                        vecOd05 = True
                        i += 5
            kanali = numpy.zeros(8)
            for i in range(0, 8, 1):
                kanali[i] = downs[i + 1] - ups[i]
            
            MAX_KANAL = 71
            MIN_KANAL = 26
            RANGE = MAX_KANAL - MIN_KANAL
            global client
            # throttle = (kanali[2] - MIN_KANAL)/RANGE-0.5
            # print(throttle)
            client.moveByRC(rcdata=airsim.RCData(throttle=(kanali[2] - MIN_KANAL)/RANGE-0.5, yaw=(kanali[3] - MIN_KANAL)/RANGE-0.5, pitch=(
                kanali[1] - MIN_KANAL)/RANGE - 0.5, roll=(kanali[0] - MIN_KANAL)/RANGE - 0.5, is_initialized=True, is_valid=True))

            hist = numpy.c_[hist, kanali.T]
            for k in range(CHUNK):
                histVhod[k + chunkN * CHUNK] = vhod[k]

            chunkN += 1
            q.task_done()
        except Exception as e:
            logging.exception("error get")
            break

    return None
For connecting to the AirSim drone environment and testing API functionality
"""
import setup_path
import airsim

import os
import tempfile
import pprint

# connect to the AirSim simulator
client = airsim.MultirotorClient()
client.confirmConnection()
client.enableApiControl(True)
client.armDisarm(True)

state = client.getMultirotorState()
s = pprint.pformat(state)
print("state: %s" % s)

client.moveByManualAsync(vx_max=1E6, vy_max=1E6, z_min=-1E6, duration=1E10)
airsim.wait_key(
    'Manual mode is setup. Press any key to send RC data to takeoff')

client.moveByRC(rcdata=airsim.RCData(
    pitch=0.0, throttle=1.0, is_initialized=True, is_valid=True))

airsim.wait_key('Set Yaw and pitch to 0.5')

client.moveByRC(rcdata=airsim.RCData(
    roll=1100, throttle=2000, yaw=0.0, is_initialized=True, is_valid=True))
Exemple #5
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            if (thread_obd is not None):
                done = True
                thread_obd.join()

                q.join()

                al = autolander.AutoLander(0.55, 13, 0.4)

            altitude = client.simGetVehiclePose().z_val
            historicalAltitudes.append(altitude)
            now = timer()
            al.addHeightMeasurement(now - start, altitude)
            throttle = al.thrust / 13 - 0.5
            client.moveByRC(
                airsim.RCData(throttle=throttle,
                              is_initialized=True,
                              is_valid=True))
            time.sleep(0.002)

    stream.stop_stream()
    stream.close()
    p.terminate()
    keyRecorder.poor_mans_destructor()

    plt.plot(histVhod)
    plt.show()

    plt.plot(historicalAltitudes)
    plt.show()

    for i in range(8):