Esempio n. 1
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    def get_closest_landmark_non_move(self, robot_pose, landmark):
        side_range = [-math.radians(70), math.radians(70)]
        min_distance = 100
        min_landmark_id = -1
        for id in landmark:
            # calculate angle robot to landmark
            # マップ原点座標から見たランドマークの位置・姿勢
            map2landmark = almath.Position6D(landmark[id])
            t_map2landmark = almath.transformFromPosition6D(map2landmark)
            # map原点座標から見たロボットの位置・姿勢
            map2robot = almath.position6DFromPose2D(robot_pose)
            t_map2robot = almath.transformFromPosition6D(map2robot)
            # ロボットから見たランドマークの位置・姿勢
            t_robot2landmark = t_map2robot.inverse() * t_map2landmark
            robot2landmark = almath.position6DFromTransform(t_robot2landmark)
            #print(id, robot2landmark, robot2landmark.norm())

            local_angle_xy, local_angle_xz = self._get_angle_vector(
                robot2landmark)

            if (side_range[0] < local_angle_xy < side_range[1]) and (
                    side_range[0] < local_angle_xz < side_range[1]):
                if robot2landmark.norm() < min_distance:
                    min_distance = robot2landmark.norm()
                    min_landmark_id = id
            #print(math.degrees(local_angle_xy))
        return min_landmark_id
Esempio n. 2
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    def approach_home(self):
        x_coord, y_coord, theta = self.services.PositionManager.get_home_pos()
        coord_pod = [x_coord, y_coord, theta]

        p2D_world2robot = almath.Pose2D(
            self.services.ALMotion.getRobotPosition(True))

        p2D_world2target = almath.Pose2D(coord_pod)
        t_world2robot = almath.transformFromPose2D(p2D_world2robot)
        t_world2target = almath.transformFromPose2D(p2D_world2target)
        t_robot2target = t_world2robot.inverse() * t_world2target
        p6D_robot2target = almath.position6DFromTransform(t_robot2target)
        coord_pod = list(p6D_robot2target.toVector())

        coord_home = [
            coord_pod[0] + DISTANCE_FIRST_APPROACH * math.cos(coord_pod[-1]),
            coord_pod[1] + DISTANCE_FIRST_APPROACH * math.sin(coord_pod[-1]),
            coord_pod[-1] + math.pi
        ]

        is_success = False
        if self.services.PositionManager.turn_toward_position(
            [DISTANCE_FIRST_APPROACH, 0]):
            x, y, theta = coord_home
            r, r_theta = self.get_polar_coord([x, y, theta])
            if self.services.ALMotion.moveTo(r, 0, 0, MOVE_CONFIG_HIGH_SPEED):
                is_success = True
                yield self.services.PositionManager.turn_toward_position(
                    [0, 0], _async=True)
        yield stk.coroutines.Return(is_success)
Esempio n. 3
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    def get_closest_landmark(self, robot_pose, landmark):
        distance_info = dict()
        side_range = [-math.radians(70), math.radians(70)]
        for id in landmark:
            # calculate angle robot to landmark
            # マップ原点座標から見たランドマークの位置・姿勢
            map2landmark = almath.Position6D(landmark[id])
            t_map2landmark = almath.transformFromPosition6D(map2landmark)
            # map原点座標から見たロボットの位置・姿勢
            map2robot = almath.position6DFromPose2D(robot_pose)
            t_map2robot = almath.transformFromPosition6D(map2robot)
            # ロボットから見たランドマークの位置・姿勢
            t_robot2landmark = t_map2robot.inverse() * t_map2landmark
            robot2landmark = almath.position6DFromTransform(t_robot2landmark)

            local_angle_xy, local_angle_xz = self._get_angle_vector(
                robot2landmark)

            # 1. xz面において任意の角度内に収まっている
            # TODO この時点でnullが帰ってくる可能性がある
            print(math.degrees(local_angle_xz))
            #if (side_range[0] < local_angle_xz < side_range[1]):
            # ベクトルのノルムを格納する
            distance_info[id] = local_angle_xy  #robot2landmark.norm()

        # 2. xy面においてベクトル同士のなす角がすべてのランドマークに対して最小か
        #    1.でフィルタしたランドマークリストを元に角度が小さい順にソートする
        #min_k = min(d, key=d.get)
        #min_landmark_id = min(distance_info, key=distance_info.get)
        distance_info = sorted(distance_info.items(), key=lambda x: x[1])
        print(distance_info)
        return distance_info
Esempio n. 4
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    def get_home_position(self, params):
        p6Ds = self.detect_with_try_params_list(params)
        p6Ds_list = {}
        params_list = []
        if not isinstance(params, list):
            params_list.append(dict(DEFAULT_PARAMS))
        else:
            params_list = params

        id_list = []
        for tmp_params in params_list:
            id_list += tmp_params["ids"]
        for ids in id_list:
            try:
                p6D_world2target = almath.Position6D(p6Ds[ids]["world2target"])
                t_world2target = almath.transformFromPosition6D(
                    p6D_world2target)
                self.logger.info("@@@ TARGET IN WORLD %s" % p6D_world2target)

                p2D_world2robot = almath.Pose2D(
                    self.ALMotion.getRobotPosition(True))
                t_world2robot = almath.transformFromPose2D(p2D_world2robot)
                self.logger.info("@@@ ROBOT POSITION %s" % p2D_world2robot)

                t_robot2target = t_world2robot.inverse() * t_world2target
                p6D_robot2target = almath.position6DFromTransform(
                    t_robot2target)
                self.logger.info("@@@ TARGET IN ROBOT %s" % p6D_robot2target)
                p6Ds_list[ids] = list(p6D_robot2target.toVector())
            except Exception as e:
                pass
        return p6Ds_list
Esempio n. 5
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    def find_home(self, research_360_activated=False):
        "returns (coords) of any code it finds, or (None)."
        distance_pod = None
        mode_search = False
        if not self.services.PositionManager:
            yield stk.coroutines.Return(None)
        if self.pod_pos_in_world and not research_360_activated:
            pod_future = self.services.PositionManager.turn_toward_position(
                [-1.0, 0], _async=True)
            yield pod_future
            distance_pod = self.services.PositionManager.get_dist_from_robot(
                -0.70, 0)
            pod_future = self.services.ALTracker._lookAtWithEffector(
                [distance_pod, 0, 0], 2, 2, 0.1, 0, _async=True)
            yield pod_future
        else:
            mode_search = True
        pod_future = None
        if mode_search:
            pod_future = self.search_home()
            yield pod_future
            self.logger.info(repr(pod_future.value()))
        else:
            yield self.services.ALRecharge.setUseTrackerSearcher(False,
                                                                 _async=True)
            pod_future = qi. async (self.services.ALRecharge.lookForStation)
            self.future_sleep = stk.coroutines.sleep(5)
            yield self.future_sleep
            if pod_future.isRunning():
                self.services.ALRecharge.stopAll()
                yield stk.coroutines.Return(None)
        if pod_future:
            coord_pod = pod_future.value()
            if coord_pod and coord_pod[1] and len(coord_pod[1]) == 3:
                p2D_world2robot = almath.Pose2D(
                    self.services.ALMotion.getRobotPosition(True))
                coord_pod = coord_pod[1]
                self.services.PositionManager.init_position_with_coord(
                    coord_pod)
                self.pod_pos_in_world = [0.0, 0.0]
                p2D_world2target = almath.Pose2D(coord_pod)
                t_world2robot = almath.transformFromPose2D(p2D_world2robot)
                t_world2target = almath.transformFromPose2D(p2D_world2target)
                t_robot2target = t_world2robot.inverse() * t_world2target
                p6D_robot2target = almath.position6DFromTransform(
                    t_robot2target)
                coord_pod = list(p6D_robot2target.toVector())

                coord_home = [
                    coord_pod[0] + DISTANCE_FROM_POD * math.cos(coord_pod[-1]),
                    coord_pod[1] + DISTANCE_FROM_POD * math.sin(coord_pod[-1]),
                    coord_pod[-1]
                ]
                yield stk.coroutines.Return(coord_home)
        yield stk.coroutines.Return(None)
Esempio n. 6
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def arm_dist(motionProxy,effectorName,x,y,z):
    # arm transformation in robot space
    arm_transform = motionProxy.getTransform(effectorName,2,True)
    robot2Arm = almath.Transform(almath.vectorFloat(arm_transform))
    rot=almath.position6DFromTransform(robot2Arm)
    print effectorName,"position",robot2Arm.r1_c4,robot2Arm.r2_c4,robot2Arm.r3_c4
    mx,my,mz=rot.wx,rot.wy,rot.wz
    x_d,y_d,z_d=x-robot2Arm.r1_c4,y-robot2Arm.r2_c4,z-robot2Arm.r3_c4
    print "distances update:"
    print x_d,y_d,z_d
    return [x_d,y_d,z_d],mx
Esempio n. 7
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def CalculateDistanceNew(Weight,Alpha,Beta,IP,PORT,landmarkTheoreticalSize):
    currentCamera = "CameraBottom"
    memoryProxy = ALProxy("ALMemory", IP,PORT)
    motionProxy=ALProxy("ALMotion",IP,PORT)
    angularSize = (Weight/ 640.0) * 60.97 * almath.PI / 180
    distanceFromCameraToLandmark = landmarkTheoreticalSize / (2 * math.tan(angularSize / 2))
    # Get current camera position in NAO space.
    transform = motionProxy.getTransform(currentCamera, 2, True)
    print "transform=",transform
    transformList = almath.vectorFloat(transform)
    robotToCamera = almath.Transform(transformList)
    # Compute the rotation to point towards the landmark.
    cameraToLandmarkRotationTransform = almath.Transform_from3DRotation(0, Beta, Alpha)

    # Compute the translation to reach the landmark.
    cameraToLandmarkTranslationTransform = almath.Transform(distanceFromCameraToLandmark, 0, 0)

    # Combine all transformations to get the landmark position in NAO space.
    robotToLandmark = robotToCamera * cameraToLandmarkRotationTransform * cameraToLandmarkTranslationTransform
    print "x " + str(robotToLandmark.r1_c4) + " (in meters)"
    print "y " + str(robotToLandmark.r2_c4) + " (in meters)"
    print "z " + str(robotToLandmark.r3_c4) + " (in meters)"
    print "robotToLandmark=",robotToLandmark
    # 从机器人端读取相关传感器的角度和位置数据
    headAgl = motionProxy.getAngles(["HeadYaw", "HeadPitch"], True)
    # ColumnAglY = Alpha + headAgl[0]     #水平方向角度差
    # print "ColumnAglY=",ColumnAglY
    # Position3D=almath.Position3D(robotToLandmark.r1_c4,robotToLandmark.r2_c4,robotToLandmark.r3_c4)
    # Position6D=almath.Position6D(0,0,0,0,0,0)
    # almath.position6DFromPosition3DInPlace(Position3D,Position6D)
    Position6D=almath.position6DFromTransform(robotToLandmark)
    # position6D=almath.vectorFloat(Position6D)
    # ColumnAglY=position6D
    print "Position6D.wz=",Position6D.wz
    print "Position6D",Position6D
    # print "type of Position6D=",type(Position6D)
    ColumnAglY=Position6D.wz
    # print "ColumnAglY=",ColumnAglY
    return robotToLandmark.r1_c4*1000,robotToLandmark.r2_c4*1000,robotToLandmark.r3_c4*1000,ColumnAglY     #传出Torso_X和Torso_Y的毫米值
Esempio n. 8
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    def calc_marker(self):
        print("calculation marker information")
        start_time = time.time()

        try:
            self.image_remote = self.camera.getImageRemote(self.subscriber_id)
        except Exception as message:
            self.unsubscribe()
            print(str(message))
        if not self.image_remote:
            self.unsubscribe()
            raise Exception("No data in image")
        camera = self.params["camera"]
        camera_name = CAMERAS[camera]
        seconds = self.image_remote[4]
        micro_seconds = self.image_remote[5]
        t_world2camera = almath.Transform(
            self.motion._getSensorTransformAtTime(
                camera_name, seconds * 10e8 + micro_seconds * 10e2))
        t_robot2camera = almath.Transform(
            self.motion.getTransform(camera_name, 2, True))
        resolution = self.params["resolution"]
        x, y = CAMERA_DATAS_AT_RESOLUTION[resolution]["image_size"]
        color_space, channels = self.params["color_space_and_channels"]
        image = numpy.frombuffer(self.image_remote[6],
                                 dtype=numpy.uint8).reshape(y, x, channels)
        if self.params["color"] and color_space == vd.kBGRColorSpace:
            print("Thresholding image...")
            lower_b = tuple([int(val) for val in self.params["color"]])
            upper_b = (255, 255, 255)
            image = cv2.inRange(image, lower_b, upper_b)
            print("Thresholding image done")

        p6Ds = dict()
        corners, ids, rejectedImgPoints = cv2.aruco.detectMarkers(
            image, self.params["dictionary"])

        result = False
        if ids is not None:
            try:
                if [328] in ids:
                    count = 0
                    for _id in ids:
                        print(_id)
                        if _id == [328]:
                            break
                        count = count + 1

                    rvecs, tvecs, _ = cv2.aruco.estimatePoseSingleMarkers(corners, \
                                                                          self.params["size"], \
                                                                          CAMERA_DATAS_AT_RESOLUTION[resolution]["matrix"], \
                                                                          CAMERA_DISTORTION_COEFF)

                    tvec = tvecs[count][0]
                    x, y, z = tvec[2], -tvec[0], -tvec[1]
                    p3d_camera2target = almath.Position3D(x, y, z)

                    rvec = rvecs[count][0]
                    wx, wy, wz = rvec[2], -rvec[0], -rvec[1]
                    proj_rvec, _ = cv2.Rodrigues(numpy.array([wx, wy, wz]))

                    r_camera2target = almath.Rotation(proj_rvec.flatten())
                    t_camera2target = almath.transformFromRotationPosition3D(
                        r_camera2target, p3d_camera2target)

                    r3d_correction = almath.Rotation3D(0., 3 * math.pi / 2, 0)

                    t_corretion = almath.transformFromRotation3D(
                        r3d_correction)
                    t_world2target = t_world2camera * t_camera2target * t_corretion
                    t_robot2target = t_robot2camera * t_camera2target * t_corretion

                    p6D_world2target = almath.position6DFromTransform(
                        t_world2target)
                    p6D_robot2target = almath.position6DFromTransform(
                        t_robot2target)

                    print("[x,y,theta] = [{},{},{}]".format(
                        p6D_robot2target.x, p6D_robot2target.y,
                        math.degrees(p6D_robot2target.wz)))

                    #p6Ds[ids] = {
                    #    "robot2target": list(p6D_robot2target.toVector())
                    #"world2target": list(p6D_world2target.toVector())
                    #}
                    result = True
                print("ID:" + str(ids))
            except Exception as message:
                print("failed: {}".format(str(message)))
                self.unsubscribe()
        else:
            result = False
            print("No Marker")
        delta_time = time.time() - start_time
        return result
Esempio n. 9
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    def _detect_markers(self, params, image, t_world2camera, timestamp):
        t = time.time()
        # self.logger.info("_detect_markers...")
        p6Ds = dict()
        corners, ids, rejectedImgPoints = cv2.aruco.detectMarkers(
            image, params["dictionary"])

        try:
            ids = [int(_id) for _id in ids.flatten()]
        except Exception as e:
            raise Exception("No markers found")

        # self.logger.info("@@@@@@@@@ IDs: %s" % ids)
        if ids:
            if params["ids"]:
                id_indices = [
                    indice for (indice, _id) in enumerate(ids)
                    if _id in set(params["ids"]).intersection(set(ids))
                ]
            else:
                id_indices = [indice for (indice, _id) in enumerate(ids)]

            # self.logger.info("@@@@@@@@@ IDs indices: %s" % id_indices)

            if id_indices:
                resolution = params["resolution"]
                rvecs, tvecs, _ = cv2.aruco.estimatePoseSingleMarkers(corners, \
                                                                        params["size"], \
                                                                        CAMERA_DATAS_AT_RESOLUTION[resolution]["matrix"], \
                                                                        CAMERA_DISTORTION_COEFF)
                for indice in id_indices:
                    # switch from opencv coordinates to NAOqi coordinates
                    tvec = tvecs[indice][0]  # translation vectors
                    x, y, z = tvec[2], -tvec[0], -tvec[1]
                    p3d_camera2target = almath.Position3D(x, y, z)

                    rvec = rvecs[indice][0]  # rotation vectors
                    wx, wy, wz = rvec[2], -rvec[0], -rvec[1]
                    proj_rvec, _ = cv2.Rodrigues(numpy.array([wx, wy, wz]))

                    r_camera2target = almath.Rotation(proj_rvec.flatten())
                    t_camera2target = almath.transformFromRotationPosition3D(
                        r_camera2target, p3d_camera2target)

                    if params["position"] == "floor":
                        r3d_correction = almath.Rotation3D(
                            0., math.pi / 2,
                            0.)  # we have 90° on y axis that is invalid
                    elif params["position"] == "wall":
                        r3d_correction = almath.Rotation3D(
                            0., math.pi,
                            0.)  # we have 180° on y axis that is invalid

                    t_correction = almath.transformFromRotation3D(
                        r3d_correction)
                    t_world2target = t_world2camera * t_camera2target * t_correction

                    p6D_world2target = almath.position6DFromTransform(
                        t_world2target)
                    self.logger.info(
                        "@@@@@@@@@ ID: %s - P6D_WORLD2TARGET: %s" %
                        (ids[indice], p6D_world2target))

                    p6Ds[ids[indice]] = {
                        "world2target": list(p6D_world2target.toVector()),
                        "timestamp": timestamp,
                    }
            else:
                raise Exception("No markers with IDs %s found" % params["ids"])

        d = time.time() - t
        self.logger.info("_detect_markers done %s" % d)
        return p6Ds
Esempio n. 10
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    def find_home(self, research_360_activated=False):
        "returns (coords) of any code it finds, or (None)."
        distance_big_aruco = None
        distance_small_aruco = None
        id_aruco = 128
        mode_search = False
        if not self.services.PositionManager:
            self.logger.info("no PositionManager")
            yield stk.coroutines.Return(None)

        if self.aruco_pos_in_world and not research_360_activated:
            distance_big_aruco = self.services.PositionManager.get_dist_from_robot(
                0, 0)
            distance_small_aruco = self.services.PositionManager.get_dist_from_robot(
                0.56, 0)
            if distance_big_aruco > 0.60:
                aruco_future = self.services.PositionManager.turn_toward_position(\
                                                    [0, 0],
                                                    _async=True)
                yield aruco_future
                aruco_future = self.services.ALTracker._lookAtWithEffector(
                    [distance_big_aruco, 0, 0], 2, 2, 0.1, 0, _async=True)
                yield aruco_future
                id_aruco = 128
            elif distance_small_aruco > 0.40:
                aruco_future = self.services.PositionManager.turn_toward_position(\
                                                    [1.0, 0],
                                                    _async=True)
                yield aruco_future
                aruco_future = self.services.ALTracker._lookAtWithEffector(
                    [distance_small_aruco, 0, 0], 2, 2, 0.1, 0, _async=True)
                yield aruco_future
                id_aruco = 448
            else:
                yield stk.coroutines.Return(None)
        else:
            self.logger.info("Lost mode")
            mode_search = True
        try:
            aruco_future = None
            if mode_search:
                aruco_future = yield self.search_home()
            else:
                print "DBG done moving, now scanning"
                aruco_future = yield self.services.DXAruco.get_home_position_in_world(
                    DEFAULT_PARAMS[id_aruco], _async=True)
            if aruco_future:
                self.logger.info(aruco_future)
                if id_aruco in aruco_future:
                    self.logger.info("id_aruco")
                    self.logger.info(id_aruco)
                else:
                    self.logger.info("id_aruco")
                    [id_aruco] = [tmp for tmp in [128, 448] if tmp != id_aruco]
                    self.logger.info(id_aruco)

                if id_aruco in aruco_future:
                    self.logger.info(aruco_future)
                    coord_aruco = aruco_future[id_aruco]
                    coord_home_pos = None
                    if len(coord_aruco) == 6:
                        coord_aruco = [
                            coord_aruco[0], coord_aruco[1], coord_aruco[-1]
                        ]
                    coord_home_pos = coord_aruco
                    p2D_world2robot = almath.Pose2D(
                        self.services.ALMotion.getRobotPosition(True))
                    p2D_world2target = almath.Pose2D(coord_aruco)
                    t_world2robot = almath.transformFromPose2D(p2D_world2robot)
                    t_world2target = almath.transformFromPose2D(
                        p2D_world2target)
                    t_robot2target = t_world2robot.inverse() * t_world2target
                    p6D_robot2target = almath.position6DFromTransform(
                        t_robot2target)
                    coord_aruco = list(p6D_robot2target.toVector())
                    x, y, theta = [
                        coord_aruco[0], coord_aruco[1], coord_aruco[-1]
                    ]

                    coord_home = None
                    if id_aruco == 128:
                        theta += math.radians(-135)
                        coord_home = [x, y, theta]
                        coord_home_pos = [
                            coord_home_pos[0], coord_home_pos[1],
                            coord_home_pos[-1] + math.radians(-135)
                        ]
                    else:
                        theta += math.radians(135)
                        coord_home = [
                            x - DISTANCE_FROM_SMALL_ARUCO * math.cos(theta),
                            y - DISTANCE_FROM_SMALL_ARUCO * math.sin(theta),
                            theta
                        ]
                        coord_home_pos = [
                            coord_home_pos[0] - DISTANCE_FROM_SMALL_ARUCO *
                            math.cos(coord_home_pos[-1] + math.radians(135)),
                            coord_home_pos[1] - DISTANCE_FROM_SMALL_ARUCO *
                            math.sin(coord_home_pos[-1] + math.radians(135)),
                            coord_home_pos[-1] + math.radians(135)
                        ]
                    if coord_home_pos != None:
                        self.services.PositionManager.init_position_with_coord(
                            coord_home_pos)
                        self.aruco_pos_in_world = [0.0, 0.0]
                    self.logger.info("coord " + repr(coord_home))
                    yield stk.coroutines.Return([coord_home, id_aruco])
                    return
        except Exception as error_msg:
            self.logger.warning("No aruco with the id " + repr(id_aruco) +
                                " found.")
            # Now continue at the next head angle
        yield stk.coroutines.Return(None)