Exemplo n.º 1
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def get_airports_from_icao_code(departure_airport_icao_code, destination_airport_icao_code):
    with open_database_session() as session:
        departure_airport = Airport.airport_from_icao_code(
            session, departure_airport_icao_code)
        destination_airport = Airport.airport_from_icao_code(
            session, destination_airport_icao_code)
        return departure_airport, destination_airport
Exemplo n.º 2
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    def _check_intersections_related_to_airports(self, departure_airport,
                                                 destination_airport):
        intersections = []

        sections = self._sections_from_airports(departure_airport,
                                                destination_airport)
        longitude_based = Airport.should_be_longitude_based(
            departure_airport, destination_airport)
        follow_ascending_order = Airport.follow_ascending_order(
            departure_airport, destination_airport)

        bbox = bounding_box_related_to_airports(departure_airport,
                                                destination_airport)
        sorting_key = (lambda x: reference_point(x, longitude_based))
        sorting_reverse = (not follow_ascending_order)
        cells = self._stsc.cells_within_bounding_box(
            bbox, sorting_key=sorting_key, sorting_reverse=sorting_reverse)

        if not cells or not sections:
            return intersections

        iter_sections, iter_cells = iter(sections), iter(cells)
        section, cell = next(iter_sections), next(iter_cells)

        def move_section_iterator(section, cell):
            return ((follow_ascending_order and section.section_point <
                     reference_point(cell, longitude_based))
                    or (not follow_ascending_order and section.section_point >
                        reference_point(cell, longitude_based)))

        while True:
            try:
                distance = (ObstacleDetector.distance_between_section_and_cell(
                    section, cell))

                if distance < cell.radius:
                    intersection = (ObstacleDetector.
                                    _intersection_between_section_and_cell(
                                        section, cell))
                    if intersection.flight_ids:
                        intersections.append(intersection)
                    section = next(iter_sections)
                else:
                    if move_section_iterator(section, cell):
                        # section is placed before cell
                        section = next(iter_sections)
                    else:
                        cell = next(iter_cells)
            except StopIteration:
                break

        merged_intersections = self.merge_intersections_with_the_same_convection_cell(
            intersections)
        logger.debug(
            'Found following intersections {0} from departure {1} to destination {2}'
            .format(merged_intersections, departure_airport,
                    destination_airport))

        return merged_intersections
Exemplo n.º 3
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def _check_multiple_intersections(departure_airport,
                                  destination_airport,
                                  convection_cells,
                                  algorithm_name=None,
                                  **kwargs):
    intersections = []

    algorithm = ALGORITHM_MAP[algorithm_name]
    sections = algorithm.sections_from_airports(
        departure_airport,
        destination_airport,
        **kwargs,
    )

    longitude_based = Airport.should_be_longitude_based(
        departure_airport, destination_airport)
    follow_ascending_order = Airport.follow_ascending_order(
        departure_airport, destination_airport)

    convection_cells.sort(key=(lambda x: reference_point(x, longitude_based)),
                          reverse=(not follow_ascending_order))

    if not sections or not convection_cells:
        return intersections

    iter_sections, iter_cells = iter(sections), iter(convection_cells)
    section, cell = next(iter_sections), next(iter_cells)

    def should_move_section_iterator(section, cell):
        return (
            (follow_ascending_order and
             section.section_point < reference_point(cell, longitude_based)) or
            (not follow_ascending_order and
             section.section_point > reference_point(cell, longitude_based)))

    while True:
        try:
            distance = distance_between_section_and_cell(section, cell)

            if distance < cell.radius:
                impact = measure_impact_convection_cell_on_section(
                    section, cell)
                if impact:
                    intersection = Intersection(cell, departure_airport,
                                                destination_airport, impact)
                    intersections.append(intersection)
                cell = next(iter_cells)
            else:
                if should_move_section_iterator(section, cell):
                    # section is placed before cell, move cell
                    section = next(iter_sections)
                else:
                    cell = next(iter_cells)
        except StopIteration:
            break

    return intersections
Exemplo n.º 4
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def _gen_departure_destination_airports(airport_tracking_list):
    if airport_tracking_list is None:
        yield from _gen_default_airport_tracking_list()
    else:
        for departure_airport_code, destination_airport_code in airport_tracking_list:
            departure_airport = Airport.airport_from_icao_code(
                session, departure_airport_code)
            destination_airport = Airport.airport_from_icao_code(
                session, destination_airport_code)
            yield departure_airport, destination_airport
Exemplo n.º 5
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    def check_obstacles_related_to_flight_location(self, prev_flight_location,
                                                   curr_flight_location):
        '''Check for obstacles in current flight location'''
        logger.debug(
            'Check for weather obstacle in current flight location {0}'.format(
                curr_flight_location))

        flight = prev_flight_location.flight
        flight_plan = flight.flight_plan
        airports = ObstacleDetector.DepartureAndDestinationAirports(
            flight_plan.departure_airport, flight_plan.destination_airport)
        normalized_flight_locations_ = normalized_flight_locations(
            [prev_flight_location, curr_flight_location])

        if not normalized_flight_locations_:
            return []

        normalized_flight_location = normalized_flight_locations_[0]
        curr_flight_ids = self.flight_ids_in_the_same_airway_of_normalized_flight_location(
            normalized_flight_location, airports)

        longitude_based = Airport.should_be_longitude_based(*airports)
        follow_ascending_order = Airport.follow_ascending_order(*airports)
        intersections = self.check_intersections_related_to_airports(*airports)

        intersection_index = 0

        def move_intersection_iterator(flight_location, intersection):
            return ((follow_ascending_order and reference_point(
                flight_location, longitude_based) > reference_point(
                    intersection.convection_cell, longitude_based))
                    or (not follow_ascending_order and reference_point(
                        flight_location, longitude_based) < reference_point(
                            intersection.convection_cell, longitude_based)))

        while intersection_index < len(intersections):
            intersection = intersections[intersection_index]
            if not move_intersection_iterator(normalized_flight_location,
                                              intersection):
                break
            intersection_index += 1

        obstacles = []
        for index in range(intersection_index, len(intersections)):
            cell, next_flight_ids = intersections[index]
            how_likely = ObstacleDetector.likelihood_of_encounter_obstacle(
                curr_flight_ids, next_flight_ids)
            obstacle = Obstacle(curr_flight_location, cell, how_likely)
            obstacles.append(obstacle)

        logger.debug(
            'Found the following obstacles {0} for flight location {1}'.format(
                obstacles, curr_flight_location))

        return obstacles
Exemplo n.º 6
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def check_for_intersections(departure_airport, destination_airport,
                            convection_cell):
    intersections = []

    sections = Section.sections_from_airports(departure_airport,
                                              destination_airport)

    clusters_freq = [len(set(s.labels)) for s in sections]
    print('clusters found')
    print(clusters_freq)

    longitude_based = Airport.should_be_longitude_based(
        departure_airport, destination_airport)
    follow_ascending_order = Airport.follow_ascending_order(
        departure_airport, destination_airport)

    cells = [convection_cell]  # TODO: maybe use more than one cell
    iter_sections, iter_cells = iter(sections), iter(cells)
    section, cell = next(iter_sections), next(iter_cells)

    def move_section_iterator(section, cell):
        return (
            (follow_ascending_order and
             section.section_point < reference_point(cell, longitude_based)) or
            (not follow_ascending_order and
             section.section_point > reference_point(cell, longitude_based)))

    while True:
        try:
            distance = (ObstacleDetector.distance_between_section_and_cell(
                section, cell))

            if distance < cell.radius:
                intersection = (intersection_between_section_and_cell(
                    section, cell))
                if intersection.flight_ids:
                    intersections.append(intersection)
                section = next(iter_sections)
            else:
                if move_section_iterator(section, cell):
                    # section is placed before cell
                    section = next(iter_sections)
                else:
                    cell = next(iter_cells)
        except StopIteration:
            break

    return intersections
Exemplo n.º 7
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def get_airport_from_airport_data(airport_data):
    return Airport(icao_code=airport_data['icao'],
                   name=airport_data['name'],
                   latitude=round(airport_data['latitude'], 3),
                   longitude=round(airport_data['longitude'], 3),
                   altitude=convert_feet_to_meters(airport_data['altitude']),
                   iata_code=airport_data['iata']
                   if not pd.isnull(airport_data['iata']) else None,
                   country=airport_data['country'])
Exemplo n.º 8
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def convection_cells_stats(convection_cell_ids):
    global session

    with open_database_session() as session:
        BSB = Airport.airport_from_icao_code(session, 'SBBR')
        GRU = Airport.airport_from_icao_code(session, 'SBGR')

        print('create intersections table from', BSB, 'to', GRU)
        # create_intersections_table(session, convection_cell_ids, BSB, GRU)
        print('#' * 20)
        print()

        print('create intersections table from', GRU, 'to', BSB)
        create_intersections_table(session, convection_cell_ids, GRU, BSB)
        print('#' * 20)
        print()

        print('generate flights vs convection cells charts')
        plot_flights_vs_convection_cells(session, convection_cell_ids)
Exemplo n.º 9
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def _normalize_from_section_points(flight_locations, section_points):
    normalized_flight_locations = []
    fl = flight_locations[0]
    flight = fl.flight
    flight_plan = flight.flight_plan

    longitude_based = Airport.should_be_longitude_based(
        flight_plan.departure_airport, flight_plan.destination_airport)
    follow_ascending_order = Airport.follow_ascending_order(
        flight_plan.departure_airport, flight_plan.destination_airport)

    section_points_iterator = iter(section_points)
    mid_point = next(section_points_iterator)

    flight_locations.sort(
        key=(lambda fl: fl.longitude if longitude_based else fl.latitude),
        reverse=(not follow_ascending_order),
    )

    for prev_location, curr_location in zip(flight_locations,
                                            flight_locations[1:]):
        try:
            while _check_mid_point_before_flight_location(
                    mid_point, prev_location, longitude_based,
                    follow_ascending_order):
                mid_point = next(section_points_iterator)
        except StopIteration:
            logger.error(
                'Invalid set of flight locations {0!r} and {1!r} of flight {2!r}'
                .format(prev_location, curr_location, flight))
            break  # leave the outer for loop

        if _check_mid_point_within_flight_locations(mid_point, prev_location,
                                                    curr_location,
                                                    longitude_based):
            normalized_flight_location = _normalize_flight_location(
                mid_point, prev_location, curr_location, longitude_based)
            normalized_flight_locations.append(normalized_flight_location)

    logger.debug(
        'Reduce {0} flight locations to {1} normalized flight locations'.
        format(len(flight_locations), len(normalized_flight_locations)))
    return normalized_flight_locations
Exemplo n.º 10
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def _get_flight_addresses_from_airports(departure_airport, destination_airport):
    '''Return flight ICAO24 addresses from departure airport to destination airport'''
    global session

    callsigns = Airport.callsigns_from_airports(
        session, departure_airport, destination_airport)
    bbox = bounding_box_related_to_airports(
        departure_airport, destination_airport)
    addresses = _get_addresses_from_callsigns_inside_bounding_box(callsigns, bbox)    
    logger.debug('Flight addresses found from {0!r} to {1!r}: {2}'.format(
        departure_airport, destination_airport, addresses))
    return addresses
Exemplo n.º 11
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def normalize_from_airports(session, departure_airport, destination_airport):
    '''Return SORTED normalized flight locations from departure airport to destination airport'''
    normalized_flight_locations = [
        normalized_flight_location
        for flight_plan in (FlightPlan.flight_plans_from_airports(
            session, departure_airport, destination_airport))
        for normalized_flight_location in (
            normalize_from_flight_plan(flight_plan))
    ]

    # sort flight locations
    longitude_based = Airport.should_be_longitude_based(
        departure_airport, destination_airport)
    follow_ascending_order = Airport.follow_ascending_order(
        departure_airport, destination_airport)

    normalized_flight_locations.sort(key=(lambda fl: fl.longitude
                                          if longitude_based else fl.latitude),
                                     reverse=(not follow_ascending_order))

    return normalized_flight_locations
Exemplo n.º 12
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def track_en_route_flights_by_airports(
    departure_airport_code, destination_airport_code, round_trip_mode=False):
    '''Keep track of current flights information from departure airport to destination airport.'''
    global session 

    logger.info('Track flight addresses from {0} to {1} in {2} mode'.format(
        departure_airport_code, destination_airport_code, 'round trip' if round_trip_mode else 'one way'))
    
    address_to_flight = {}
    count_iterations = 0
    
    with open_database_session() as session:
        departure_airport = Airport.airport_from_icao_code(session, departure_airport_code)
        destination_airport = Airport.airport_from_icao_code(session, destination_airport_code)
        
        while count_iterations < ITERATIONS_LIMIT_TO_SEARCH_FLIGHTS:
            time.sleep(SLEEP_TIME_TO_GET_FLIGHT_IN_SECS)
            if _should_update_flight_addresses(count_iterations):
                addresses = _update_flight_addresses(
                    departure_airport, destination_airport, round_trip_mode)
            _update_flights(address_to_flight, addresses)
            count_iterations += 1
Exemplo n.º 13
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def normalize_from_flight_locations(
        flight_locations,
        partition_interval=FLIGHT_PATH_PARTITION_INTERVAL_IN_DEGREES):
    '''Normalize flight locatins FROM SPECIFIC FLIGHT'''
    if not flight_locations:
        return flight_locations

    fl = flight_locations[0]
    flight_plan = fl.flight.flight_plan

    section_points = Airport._section_points_from_airports(
        flight_plan.departure_airport, flight_plan.destination_airport,
        partition_interval)
    return _normalize_from_section_points(flight_locations, section_points)
Exemplo n.º 14
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    def sections_from_airports(departure_airport, destination_airport,
                               **kwargs):
        '''Return sections from flight locations'''
        min_entries_per_section = kwargs.get('min_entries_per_section',
                                             NUMBER_ENTRIES_PER_SECTION)

        key = (
            departure_airport.icao_code,
            destination_airport.icao_code,
            min_entries_per_section,
        )

        if key not in Section.cache:
            with open_database_session() as session:
                flight_locations = normalizer.normalize_from_airports(
                    session, departure_airport, destination_airport)

            # section should be longitude based
            longitude_based = Airport.should_be_longitude_based(
                departure_airport, destination_airport)

            sections = []
            if not flight_locations:
                return sections

            prev_flight_location = flight_locations[0]
            section_flight_locations = [prev_flight_location]

            for curr_flight_location in flight_locations[1:]:
                if Section._flight_locations_are_part_of_the_same_section(
                        prev_flight_location, curr_flight_location,
                        longitude_based):
                    section_flight_locations.append(curr_flight_location)
                else:
                    if len(section_flight_locations
                           ) >= min_entries_per_section:
                        section = Section.from_flight_locations(
                            section_flight_locations)
                        sections.append(section)
                    section_flight_locations = [curr_flight_location]
                prev_flight_location = curr_flight_location

            Section.cache[key] = sections

        # return cached results
        return Section.cache[key]
Exemplo n.º 15
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    def _section_of_normalized_flight_location(self,
                                               normalized_flight_location,
                                               departure_airport,
                                               destination_airport):
        sections = self._sections_from_airports(departure_airport,
                                                destination_airport)
        longitude_based = Airport.should_be_longitude_based(
            departure_airport, destination_airport)

        def is_normalized_flight_location_inside_section(
                normalize_flight_locations, section):
            return (float(section.section_point) == float(
                reference_point(normalized_flight_location, longitude_based)))

        for section in sections:
            if is_normalized_flight_location_inside_section(
                    normalize_flight_locations, section):
                return section
        return None