Exemplo n.º 1
0
def rk4(f, h, n, x0, t0):
    t = [t0]
    for j in range(n - 1):
        t.append(t[j] + h)

    numCars = len(x0.lanes[0])
    cars = [[[Car(pos=0, vel=0, c="b") for _ in range(len(x0.lanes[0]))]
             for _ in range(n)] for _ in range(len(x0.lanes))]
    for i, lane in enumerate(x0.lanes):
        cars[i][0] = lane
    # Iteration Loop
    for i in range(1, n):
        for lane in range(len(x0.lanes)):
            # Move leading car forward at constant speed
            leadingCar = cars[lane][i - 1][0]
            cars[lane][i][
                0].position = leadingCar.position + leadingCar.velocity * h
            cars[lane][i][0].velocity = leadingCar.velocity
            cars[lane][i][0].length = leadingCar.length
            # Move other cars forward using RK4 with IDM
            for j in range(1, numCars):
                c = cars[lane][i - 1][j]
                c1 = cars[lane][i - 1][j - 1]

                k1 = f(c, c1, t[i - 1])

                tempC = map(add, [c.position, c.velocity],
                            [h / 2.0 * el for el in k1])
                c = Car(pos=tempC[0], vel=tempC[1], c=c.color)
                k2 = f(c, c1, t[i - 1] + h / 2.0)

                tempC = map(add, [c.position, c.velocity],
                            [h / 2.0 * el for el in k2])
                c = Car(pos=tempC[0], vel=tempC[1], c=c.color)
                k3 = f(c, c1, t[i - 1] + h / 2.0)

                tempC = map(add, [c.position, c.velocity],
                            [h * el for el in k3])
                c = Car(pos=tempC[0], vel=tempC[1], c=c.color)
                k4 = f(c, c1, t[i - 1] + h)

                k2 = [2.0 * el for el in k2]
                k3 = [2.0 * el for el in k3]

                step = [h / 6.0 * el for el in (map(sum, zip(k1, k2, k3, k4)))]
                temp = map(add, [
                    cars[lane][i - 1][j].position,
                    cars[lane][i - 1][j].velocity
                ], step)
                cars[lane][i][j].position = temp[0]
                cars[lane][i][j].velocity = temp[1]

    return cars, t
Exemplo n.º 2
0
def example():
    car = Car("PBD-7541")
    car.canBeOnRoad("04-03-2018", "09:35")
    car.canBeOnRoad("05-03-2018", "08:07")

    car2 = Car("PBI-7055")
    car2.canBeOnRoad("05-03-2018", "08:07")
    car2.canBeOnRoad("07-03-2018", "17:45")
Exemplo n.º 3
0
 def create_vehicle(self, vehicle_type):
     if vehicle_type == "Машина":
         self.order_vehicle(vehicle_type)
         return Car()
     elif vehicle_type == "Велосипед":
         self.order_vehicle(vehicle_type)
         return Bike()
Exemplo n.º 4
0
    def __init__(self, num_cars, screen, center):
        pygame.sprite.Sprite.__init__(self)
        initial_vel = 200.
        self.center_of_circle = center
        self.radius = 200

        self.cars = [
            Car(KeyBoardController(),
                None,
                None,
                initial_position=self.center_of_circle +
                self.radius * np.array([
                    np.cos(2 * np.pi * i / num_cars),
                    np.sin(2 * np.pi * i / num_cars)
                ]),
                initial_heading=2 * np.pi * i / (num_cars) + np.pi / 2,
                initial_velocity=initial_vel) for i in range(num_cars)
        ]
        for car in self.cars:
            car.steering_angle = 0.01
        self.cars_viz = [
            Vehicle_Visual(self.cars[i], screen,
                           "green_car.png" if i == 0 else "red_car.png")
            for i in range(num_cars)
        ]
Exemplo n.º 5
0
 def test(self, **kwargs):
     func = kwargs['function']
     if func == 'create_parking_lot':
         get_parking_lot(kwargs["slot_count"])
         return
     elif func == 'assign_vehicle_slot':
         lot = get_parking_lot(3)
         ret = lot.assign_vehicle_slot(
             Car(kwargs["vehicle_reg_no"], kwargs["vehicle_color"]))
     elif func == 'release_vehicle':
         lot = get_parking_lot(3)
         ret = lot.release_vehicle(kwargs['slot_number'])
     elif func == 'slot_numbers_for_cars_with_colour':
         lot = get_parking_lot(3)
         ret = lot.slot_numbers_for_cars_with_colour(
             kwargs['vehicle_color'])
         print "success output:%s" % ret
         return
     elif func == 'slot_number_for_registration_number':
         lot = get_parking_lot(3)
         ret = lot.slot_number_for_registration_number(
             kwargs['vehicle_reg_no'])
         print "success output:%s" % ret
         return
     elif func == 'registration_numbers_for_cars_with_colour':
         lot = get_parking_lot(3)
         ret = lot.registration_numbers_for_cars_with_colour(
             kwargs['vehicle_color'])
         print "success output:%s" % ret
         return
     if ret != kwargs['Expected Answer']:
         print "Expected Answer is %s, got %s" % (kwargs['Expected Answer'],
                                                  ret)
     else:
         print "success"
Exemplo n.º 6
0
 def create_vehicle(self, vehicle_type):
     if vehicle_type == "Car":
         self.order_vehicle(vehicle_type)
         return Car()
     elif vehicle_type == "Bike":
         self.order_vehicle(vehicle_type)
         return Bike()
Exemplo n.º 7
0
def rk4(f, x, x1, t, h):
    try:
        k1 = f(x, x1, t)
        tempC = map(add, [x.position, x.velocity], [h / 2.0 * el for el in k1])
        c = Car(pos=tempC[0], vel=tempC[1], c=x.color)
        k2 = f(c, x1, t + h / 2.0)
        tempC = map(add, [c.position, c.velocity], [h / 2.0 * el for el in k2])
        c = Car(pos=tempC[0], vel=tempC[1], c=c.color)
        k3 = f(c, x1, t + h / 2.0)
        tempC = map(add, [c.position, c.velocity], [h * el for el in k3])
        c = Car(pos=tempC[0], vel=tempC[1], c=c.color)
        k4 = f(c, x1, t + h)
        k2 = [2.0 * el for el in k2]
        k3 = [2.0 * el for el in k3]
        step = [h / 6.0 * el for el in (map(sum, zip(k1, k2, k3, k4)))]
        if step[1] >= -1 * bsafe:
            return step
        else:
            return [None, None]
    except:
        return [None, None]
Exemplo n.º 8
0
 def park(self, arg):
     reg_number = arg[0]
     color = arg[1]
     vehicle = Car()
     vehicle.set_registration(reg_number)
     vehicle.set_color(color)
     parking_slot_available = self.get_next_available()
     if parking_slot_available is False:
         print("Sorry, parking lot is full")
     else:
         is_parked = parking_slot_available.park_vehicle(vehicle)
         if is_parked:
             try:
                 slot_popped = heapq.heappop(self.slots_available)
                 v_color = slot_popped.parked_car.get_color()
                 v_reg_number = slot_popped.parked_car.get_registration()
                 v_slot = slot_popped.parking_slot_id
                 try:
                     self.slots_occupied["reg_numbers"][
                         v_reg_number] = slot_popped
                     if v_color not in self.slots_occupied["colors"]:
                         self.slots_occupied["colors"][v_color] = set()
                     self.slots_occupied["colors"][v_color].add(slot_popped)
                     self.slots_occupied["slots"][v_slot] = slot_popped
                 except KeyError:
                     print("Error in finding the values!")
                 except Exception as e:
                     print(e)
                     print("Error in occupying slot!")
                 print("Allocated slot number: {}".format(v_slot))
             except IndexError:
                 print("Error in parking")
Exemplo n.º 9
0
    def __init__(self, num_cars, screen, center):
        pygame.sprite.Sprite.__init__(self)
        initial_vel = np.array((200., 0))

        self.center_of_circle = center
        self.radius = 200
        desired_distance = self.radius * 2 * np.pi / num_cars

        self.cars = [
            Car(CircularPlatoonController(npl.norm(initial_vel),
                                          desired_distance,
                                          self.center_of_circle, self.radius,
                                          None),
                None,
                None,
                initial_position=self.center_of_circle +
                self.radius * np.array([
                    np.cos(2 * np.pi * i / num_cars),
                    np.sin(2 * np.pi * i / num_cars)
                ]),
                initial_heading=2 * np.pi * i / (num_cars) + np.pi / 2,
                initial_velocity=initial_vel) for i in range(num_cars)
        ]
        steering_angle = 0.01
        for i in range(0, len(self.cars) - 1):
            car = self.cars[i]
            car.steering_angle = steering_angle
            car.controller.next_car = self.cars[i + 1]
        self.cars[-1].controller.next_car = self.cars[0]
        self.cars[-1].steering_angle = steering_angle

        self.cars_viz = [
            Vehicle_Visual(self.cars[i], screen,
                           "green_car.png" if i == 0 else "red_car.png")
            for i in range(num_cars)
        ]
Exemplo n.º 10
0
	def run_cmd(self, line):
		args = line.split(" ")
		cmd = args[0]
		if cmd == "create_parking_lot":
			self.lot = ParkingLot(args[1])
			return "Created a parking lot with %s slots"%args[1]
		if not self.lot:
			raise Exception("Parking Lot is not created")

		if cmd == "park":
			return self.lot.assign_vehicle_slot(Car(args[1], args[2]))

		if cmd == "leave":
			return self.lot.release_vehicle(args[1])
		if cmd == "status":
			return self.lot.get_status()
		if cmd == "registration_numbers_for_cars_with_colour":
			return self.lot.registration_numbers_for_cars_with_colour(args[1])

		if cmd == "slot_number_for_registration_number":
			return self.lot.slot_number_for_registration_number(args[1])
		if cmd == "slot_numbers_for_cars_with_colour":
			return self.lot.slot_numbers_for_cars_with_colour(args[1])
		return "cmd %s is not valid"%cmd
Exemplo n.º 11
0
class TestCar(TestCase):

    def setUp(self):
        self.car = Car("PBD-7541")

    def test_canBeOnRoad_weekend(self):
        self.assertTrue(self.car.canBeOnRoad("04-03-2018", "8:30"))
        self.assertTrue(self.car.canBeOnRoad("03-03-2018", "8:30"))

    def test_canBeOnRoad_weekday_morning(self):
        self.assertTrue(self.car.canBeOnRoad("05-03-2018", "9:45"))

    def test_canBeOnRoad_weekday_afternoon(self):
        self.assertTrue(self.car.canBeOnRoad("05-03-2018", "15:00"))

    def test_canBeOnRoad_weekday(self):
        self.assertTrue(self.car.canBeOnRoad("07-03-2018", "9:45"))

    def test_cannotBeOnRoad_weekday_morning(self):
        self.assertFalse(self.car.canBeOnRoad("05-03-2018", "08:45"))

    def test_cannotBeOnRoad_weekday_afternoon(self):
        self.assertFalse(self.car.canBeOnRoad("05-03-2018", "18:00"))

    def test_canBeOnRoad_invalid_date_time(self):
        self.assertRaises(ValueError, self.car.canBeOnRoad, "date", "time")

    def test_canBeOnRoad_invalid_date(self):
        self.assertRaises(ValueError, self.car.canBeOnRoad, "date", "8:30")

    def test_canBeOnRoad_invalid_time(self):
        self.assertRaises(FormatError, self.car.canBeOnRoad, "05-03-2018", "time")

    def test_canBeOnRoad_invalid_date_format(self):
        self.assertRaises(ValueError, self.car.canBeOnRoad, "03/03/2018", "8:30")

    def test_canBeOnRoad_invalid_time_format(self):
        self.assertRaises(FormatError, self.car.canBeOnRoad, "05-03-2018", "8h30")
Exemplo n.º 12
0
 def populate_west(self):
     if random.randint(0, 20) == 0:
         self.west.enqueue(Car())
Exemplo n.º 13
0
 def populate_north(self):
     if random.randint(0, 9) == 0:
         self.north.enqueue(Car())
Exemplo n.º 14
0
        time = 0
        light = "green"
        while time < 3600:
            self.populate_north()
            self.populate_west()
            if time % 10 == 0:
                if light == "green":
                    light = "red"
                else:
                    light = "green"
            if light == "green":
                self.north.dequeue()

            time += 1


s = Simulation()
s.north.enqueue(Car())
s.north.enqueue(Car())
s.north.enqueue(Car())
s.north.enqueue(Car())
s.north.enqueue(Car())
s.north.enqueue(Car())
s.north.enqueue(Car())
s.north.enqueue(Car())
s.north.enqueue(Car())
s.north.enqueue(Car())
print(s.north.size())

s.process_north()
print(s.north.size())
Exemplo n.º 15
0
    background_perfect = pygame.Surface(screen.get_size())
    background_perfect.fill((0, 0, 0))
    dt = 0.1

    # loop til done
    done = False

    clock = pygame.time.Clock()
    controller = KeyBoardController()
    center = np.array((screen_width / 2., screen_height / 2))
    pm = 300
    vel = 200
    steering_angle = 0.007
    car1 = Car(controller,
               None,
               None,
               initial_velocity=(vel, 0),
               initial_position=center + np.array([-pm, 0.]))
    car2 = Car(controller,
               None,
               None,
               initial_velocity=(vel, 0),
               initial_position=center + np.array([pm, 0.]))
    car3 = Car(controller,
               None,
               None,
               initial_velocity=(vel, 0),
               initial_position=center + np.array([0., -pm]))
    car4 = Car(controller,
               None,
               None,
Exemplo n.º 16
0
 def setUp(self):
     self.car = Car("PBD-7541")
Exemplo n.º 17
0
                cars[lane][i][j].position = temp[0]
                cars[lane][i][j].velocity = temp[1]

    return cars, t


lanes = []
for lane in range(3):
    lanes.append([])
    for pos in drange(0, 10000, 50):
        if pos == 0:
            v = v0
        else:
            v = v0 + random.uniform(-10, 10)
        p = pos + random.uniform(0, 0)
        c = Car(pos=-1 * p, vel=v, c="blue")
        lanes[lane].append(c)

lanes[0][0].velocity = 33.0
lanes[1][0].velocity = 33.0
lanes[2][0].velocity = 33.0
road = Road(lanes)

data, t = rk4(IDM, delT, iterations, road, 0.0)
'''
vs = []
for iteration in data[0]:
	velocities = []
	for car in iteration:
		velocities.append(car.velocity)
	vs.append(sum(velocities)/float(len(iteration)))
Exemplo n.º 18
0
def test_get_type_of_vehicle():
    car_vehicle = Car("toyota", 1, "red", curr_time)
    assert car_vehicle.get_type() == "Car"
Exemplo n.º 19
0
from Vehicle import Car

"""
Pico y placa predictor program that can
be run on command line 
"""


if __name__ == "__main__":
    plate = input("Enter plate number: ")
    date = input("Enter date: ")
    time = input("Enter time: ")
    car = Car(plate)
    car.canBeOnRoad(date, time)

Exemplo n.º 20
0
def generate_trajectory(f, h, n, x0, t0):
    # SETUP
    num_lanes = len(x0)
    t = [t0]
    for j in range(n - 1):
        t.append(t[j] + h)
    cars = [[[Car(pos=0, vel=0, c="b") for _ in range(len(x0[0]))]
             for _ in range(n)] for _ in range(len(x0))]
    for i, lane in enumerate(x0):
        cars[i][0] = lane

    print "Generating Trajectory..."
    widgets = [
        'Percent Done: ',
        Percentage(), ' ',
        AnimatedMarker(), ' ',
        ETA()
    ]
    bar = ProgressBar(widgets=widgets, maxval=n).start()
    # Iteration Loop
    for i in range(1, n):
        bar.update(i)
        # DETERMINE WHICH CARS SWITCH
        laneChanges = []
        for l, car in enumerate([el[i - 1][0] for el in cars]):
            cars[l][i][0].position = car.position
            cars[l][i][0].velocity = car.velocity
        for j in range(1, max_num_cars([el[i - 1] for el in cars])):
            for lane in range(num_lanes):
                if j < len(cars[lane][i - 1]):
                    if j < len(cars[lane][i]):
                        cars[lane][i][j].position = cars[lane][i -
                                                               1][j].position
                        cars[lane][i][j].velocity = cars[lane][i -
                                                               1][j].velocity
                    else:
                        cars[lane][i].append(
                            Car(pos=cars[lane][i - 1][j].position,
                                vel=cars[lane][i - 1][j].velocity,
                                c=cars[lane][i - 1][j].color))
                    c = cars[lane][i][j]
                    c_leading = cars[lane][i][j - 1]

                    nn = nearest_neighbor(cars, lane, i - 1, c)
                    if nn != None:
                        # Calculate Incentive
                        anprime = rk4(f, nn[0], c, t[i - 1], h)[1]
                        if anprime != None and anprime >= -1 * bsafe:
                            acprime = rk4(f, c, cars[nn[2]][i - 1][nn[1] - 1],
                                          t[i - 1], h)[1]
                            ac = rk4(f, c, c_leading, t[i], h)[1]
                            an = rk4(f, cars[nn[2]][i - 1][nn[1]],
                                     cars[nn[2]][i - 1][nn[1] - 1], t[i - 1],
                                     h)[1]
                            if acprime != None and ac != None and an != None:
                                if j < len(cars[lane][i - 1]) - 1:
                                    c_following = cars[lane][i - 1][j + 1]
                                    aoprime = rk4(f, c_following, c_leading,
                                                  t[i - 1], h)[1]
                                    ao = rk4(f, c_following, c, t[i], h)[1]
                                else:
                                    aoprime = 0.0
                                    ao = 0.0
                                if aoprime != None and ao != None:
                                    incentive = (acprime - ac) + polite * (
                                        (anprime - an) + (aoprime - ao))
                                    if incentive > ath:
                                        alreadyMovedTo = False
                                        for change in laneChanges:
                                            if change["car_to"] == nn[0]:
                                                alreadyMovedTo = True
                                        if alreadyMovedTo == False:
                                            laneChanges.append({
                                                "lane_from": lane,
                                                "lane_to": nn[2],
                                                "car_to": nn[0],
                                                "car": c
                                            })

        # Make changes
        for change in laneChanges:
            for k, CAR in enumerate(cars[change["lane_to"]][i]):
                if CAR == change["car_to"]:
                    cars[change["lane_to"]][i].insert(k, change["car"])
                    for x, C in enumerate(cars[change["lane_from"]][i]):
                        if C == change["car"]:
                            del cars[change["lane_from"]][i][x]
                    break

        # Removes Cars with pos = 0, vel = 0
        for l, lane in enumerate([el[i] for el in cars]):
            cars[l][i] = [
                c for c in cars[l][i] if c != Car(pos=0.0, vel=0.0, c=c.color)
            ]

        # MOVE CARS FORWARD
        for lane in range(num_lanes):
            numCars = len(cars[lane][i])
            # Move leading car forward at constant speed
            leadingCar = cars[lane][i][0]
            cars[lane][i][
                0].position = leadingCar.position + leadingCar.velocity * h
            cars[lane][i][0].velocity = leadingCar.velocity
            cars[lane][i][0].length = leadingCar.length
            # Move other cars forward using RK4 with IDM
            for j in range(1, numCars):
                c = cars[lane][i][j]
                c_leading = cars[lane][i][j - 1]
                step = rk4(f, c, c_leading, t[i - 1], h)
                if step != [None, None]:
                    if step[1] + cars[lane][i][j].velocity <= SL:
                        if j < len(cars[lane][i]):
                            cars[lane][i][j].position += step[0]
                            cars[lane][i][j].velocity += step[1]
                        else:
                            p = cars[lane][i][j].position + step[0]
                            v = cars[lane][i][j].velocity + step[1]
                            cars[lane][i].append(Car(p, v, c.color))
    bar.finish()
    return cars, t
Exemplo n.º 21
0
from Vehicle import Vehicle
from Vehicle import Car
from Vehicle import Handicap
from parkingSpace import parkingSpots
car1 = Car(123)
handicapped1 = Handicap(234)
handicapped2 = Handicap(34)

p = parkingSpots()
p.park(car1)
p.park(handicapped1)
p.park(handicapped2)