def __init__(
            self, ulog: ULog, innov_flags: Dict[str, float], control_mode_flags: Dict[str, float],
            check_type: CheckType = CheckType.UNDEFINED, check_id: str = '',
            test_ratio_name: Optional[str] = '', innov_fail_names: Optional[List[str]] = None):
        """
        :param ulog:
        :param innov_flags:
        :param check_type:
        :param check_id:
        :param test_ratio_name:
        :param innov_fail_names:
        """
        super(EstimatorCheck, self).__init__(
            ulog, check_type=check_type)
        self._innov_flags = innov_flags
        self._control_mode_flags = control_mode_flags
        self._check_id = check_id
        self._test_ratio_name = test_ratio_name
        self._innov_fail_names = innov_fail_names
        if self._innov_fail_names is None:
            self._innov_fail_names = list()

        self._in_air_detector_no_ground_effects = InAirDetector(
            ulog, min_flight_time_seconds=params.iad_min_flight_duration_seconds(),
            in_air_margin_seconds=params.iad_in_air_margin_seconds())

        if check_id in ['magnetometer', 'height', 'yaw', 'optical_flow']:
            self._in_air_detector = self._in_air_detector_no_ground_effects
        else:
            self._in_air_detector = InAirDetector(
                ulog, min_flight_time_seconds=params.iad_min_flight_duration_seconds())
示例#2
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 def __init__(self, ulog: ULog):
     """
     :param ulog:
     """
     super().__init__(ulog, check_type=CheckType.IMU_VIBRATION_STATUS)
     self._in_air_detector_no_ground_effects = InAirDetector(
         ulog,
         min_flight_time_seconds=params.iad_min_flight_duration_seconds(),
         in_air_margin_seconds=params.iad_in_air_margin_seconds(),
     )
def multiple_take_offs(ulog):
    """
    tests whether multiple take offs can be handled by the in air detector.
    :param ulog:
    :param ts_length:
    :return:
    """
    ts_length = ulog.get_dataset(
        'vehicle_land_detected').data['landed'].shape[0]
    ulog.get_dataset('vehicle_land_detected').data['landed'] = np.zeros(
        ts_length, dtype=int)
    ulog.get_dataset('vehicle_land_detected').data['landed'][int(ts_length /
                                                                 2)] = 1
    ulog.get_dataset('vehicle_land_detected').data['landed'][int(ts_length /
                                                                 2 + 2)] = 1
    ulog.get_dataset('vehicle_land_detected').data['landed'][int(
        3 * ts_length / 4)] = 1
    ulog.get_dataset('vehicle_land_detected').data['landed'][int(ts_length /
                                                                 4)] = 1
    in_air_detector = InAirDetector(ulog,
                                    min_flight_time_seconds=0.0,
                                    in_air_margin_seconds=0.0)
    airtimes_no_margin = in_air_detector.airtimes

    assert len(airtimes_no_margin) == 5

    in_air_detector = InAirDetector(ulog,
                                    min_flight_time_seconds=2.0,
                                    in_air_margin_seconds=2.0)

    airtimes_margin = in_air_detector.airtimes

    margin_difference_take_off = airtimes_margin[
        0].take_off - airtimes_no_margin[0].take_off  # 2
    margin_difference_landing = airtimes_no_margin[
        0].landing - airtimes_margin[0].landing  # 2

    assert len(airtimes_margin) == 4
    assert 1.99 < margin_difference_take_off < 2.01, \
        'margin is not applied correctly'
    assert 1.99 < margin_difference_landing < 2.01, \
        'margin is not applied correctly'
示例#4
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def calculate_stat_from_signal(
        data: Dict[str, np.ndarray], dataset: str, variable: str,
        in_air_det: InAirDetector, stat_function: Callable) -> float:
    """
    :param data:
    :param variable:
    :param in_air_detector:
    :return:
    """

    return float(stat_function(data[variable][in_air_det.get_airtime(dataset)]))
示例#5
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 def __init__(self, ulog: ULog):
     """
     :param ulog:
     """
     super(IMU_Output_Predictor_Check,
           self).__init__(ulog,
                          check_type=CheckType.IMU_OUTPUT_PREDICTOR_STATUS)
     self._in_air_detector_no_ground_effects = InAirDetector(
         ulog,
         min_flight_time_seconds=params.iad_min_flight_duration_seconds(),
         in_air_margin_seconds=params.iad_in_air_margin_seconds())
示例#6
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 def __init__(self, ulog: ULog):
     """
     :param ulog:
     """
     super().__init__(ulog, check_type=CheckType.IMU_BIAS_STATUS)
     self._in_air_detector_no_ground_effects = InAirDetector(
         ulog,
         min_flight_time_seconds=params.iad_min_flight_duration_seconds(),
         in_air_margin_seconds=params.iad_in_air_margin_seconds(),
     )
     messages = {elem.name for elem in self.ulog.data_list}
     self._estimator_states_msg = ("estimator_states" if "estimator_states"
                                   in messages else "estimator_status")
def original_take_offs(ulog):
    """

    :param ulog:
    :return:
    """
    in_air_detector = InAirDetector(ulog,
                                    min_flight_time_seconds=0.0,
                                    in_air_margin_seconds=0.0)
    airtimes = in_air_detector.airtimes

    assert len(airtimes) == 1
    assert 3.7 < airtimes[0].take_off < 3.8  # 3.797098
    assert 403.9 < airtimes[-1].landing < 404.0  # 403.945201
def take_off_at_second_time_stamp(ulog):
    """
    tests whether
    :param ulog:
    :param ts_length:
    :return:
    """
    ts_length = ulog.get_dataset(
        'vehicle_land_detected').data['landed'].shape[0]
    ulog.get_dataset('vehicle_land_detected').data['landed'] = np.zeros(
        ts_length, dtype=int)
    ulog.get_dataset('vehicle_land_detected').data['landed'][0] = 1
    in_air_detector = InAirDetector(ulog,
                                    min_flight_time_seconds=0.0,
                                    in_air_margin_seconds=0.0)
    airtimes = in_air_detector.airtimes
    assert len(airtimes) == 1
def always_on_ground(ulog):
    """

    :param ulog:
    :return:
    """
    ts_length = ulog.get_dataset(
        'vehicle_land_detected').data['landed'].shape[0]
    ulog.get_dataset('vehicle_land_detected').data['landed'] = np.ones(
        ts_length, dtype=int)
    in_air_detector = InAirDetector(ulog,
                                    min_flight_time_seconds=0.0,
                                    in_air_margin_seconds=0.0)
    first_take_off = in_air_detector.take_off
    airtimes = in_air_detector.airtimes

    assert first_take_off is None, 'The first take_off is not None.'
    assert len(airtimes) == 0
def always_in_air(ulog):
    """

    :param ulog:
    :return:
    """
    ts_length = ulog.get_dataset(
        'vehicle_land_detected').data['landed'].shape[0]
    ulog.get_dataset('vehicle_land_detected').data['landed'] = np.zeros(
        ts_length, dtype=int)
    in_air_detector = InAirDetector(ulog,
                                    min_flight_time_seconds=0.0,
                                    in_air_margin_seconds=0.0)
    airtimes = in_air_detector.airtimes

    assert len(airtimes) == 1
    assert airtimes[
        0].take_off <= 0.0  # for this log the landed timestamp happends to be
    #  earlier than the start timestamp
    assert 405.9 < airtimes[0].landing <= 406.0  # 405.969268
示例#11
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def calculate_windowed_mean_per_airphase(
        data: Dict[str, np.ndarray], dataset: str, variable: str,
        in_air_det: InAirDetector, threshold: Optional[float] = None,
        window_len_s: float = 30.0) -> List[Tuple[Airtime, np.ndarray]]:
    """
    calculates a windowed mean for a thresholded signal. This is needs to be done per airphase,
    as otherwise ground effects might influcence the signal.
    :param data:
    :param variable:
    :param in_air_detector:
    :param stat_function:
    :param window_len_s:
    :return:
    """

    windowed_stats = []

    for airtime, at_indices in zip(in_air_det.airtimes, in_air_det.get_airtime_per_phase(dataset)):

        duration_s = airtime.landing - airtime.take_off
        window_len = int((window_len_s / duration_s) * len(at_indices))
        if (window_len % 2) == 0:
            window_len += 1

        if len(at_indices) > 0:
            window_len_after_s = duration_s * (window_len / float(len(at_indices)))

            input_signal = data[variable][at_indices]
            if threshold is not None:
                input_signal = 100.0 * (input_signal > threshold)

            smoothed_air_phase = smooth_1d_boundaries(
                input_signal, window_len=window_len, mode='valid', mean_for_short_signals=True)

            smoothed_airtime = Airtime(
                take_off=airtime.take_off + min(window_len_after_s, duration_s) / 2.0,
                landing=airtime.landing - min(window_len_after_s, duration_s) / 2.0)

            windowed_stats.append((smoothed_airtime, smoothed_air_phase))

    return windowed_stats