def contains_agent(grid: MultiGrid, pos: Tuple[int, int]):
objs = grid.iter_cell_list_contents(pos)
return any(map(lambda obj: issubclass(type(obj), Agent), objs))
class RoadNetworkModel(Model):
description = (
"A model for simulating Road Network Model"
)
def __init__(self, number_of_cars, width, height, is_odd_even_policy_enabled, is_odd_date, policy_range_time):
# Tick increment
self.tick = 0
# Mean Travel Time
self.mean_travel_time = 0.0
# Odd-Even Policy Enabled
self.is_odd_even_policy_enabled = is_odd_even_policy_enabled
# Set the day of the week
self.is_odd_date = is_odd_date
# Set up Spatial dimension
self.grid = MultiGrid(width, height, True)
# Set up Temporal dimension
self.schedule = SimultaneousActivation(self)
self.running = True
self.policy_range_time = policy_range_time
# Set up peak hours
self.start_peak_hour_1 = PEAK_HOURS["START_PEAK_HOUR_1"] #7
self.end_peak_hour_1 = PEAK_HOURS["END_PEAK_HOUR_1"] #10
self.start_peak_hour_2 = PEAK_HOURS["START_PEAK_HOUR_2"] #4
self.end_peak_hour_2 = PEAK_HOURS["END_PEAK_HOUR_2"] #7
# Car distribution
num_highly_active_cars = math.ceil(ACTIVITY_PROPORTION["HIGHLY_ACTIVE"] * number_of_cars)
num_business_hours_cars = math.ceil(ACTIVITY_PROPORTION["BUSINESS_HOURS"] * number_of_cars)
num_peak_hours_cars = number_of_cars - (num_highly_active_cars + num_business_hours_cars)
# generate road
self.map = MapGenerator()
roadPosition = self.map.get_road_position()
for i in range(len(roadPosition)):
road = Road(i, roadPosition[i], self)
self.grid.place_agent(road, roadPosition[i])
## generate office
officePosition = self.map.get_office_position()
for i in range(len(officePosition)):
office = Office(i, officePosition[i], self)
self.grid.place_agent(office, officePosition[i])
# generate residence
residencePosition = self.map.get_residence_position()
for i in range(len(residencePosition)):
residence = Residence(i, residencePosition[i], self)
self.grid.place_agent(residence, residencePosition[i])
# generate entertainment
entertainmentPosition = self.map.get_entertainment_position()
for i in range(len(entertainmentPosition)):
entertainment = Entertainment(i, entertainmentPosition[i], self)
self.grid.place_agent(entertainment, entertainmentPosition[i])
# generate traffic light
trafficLightPosition = self.map.get_traffic_light_position()
for i in range(len(trafficLightPosition)):
trafficLight = TrafficLight(i, trafficLightPosition[i], self, COLOR["dark_grey"])
self.grid.place_agent(trafficLight, trafficLightPosition[i])
# Get source and destination lists
residence_list = self.map.get_residence_position()
office = self.map.get_office_position()
entertainment = self.map.get_entertainment_position()
# Create destination list based on weekday/weekend proportion
proportion_of_office_workers = 0.65
number_of_office_workers = math.ceil(proportion_of_office_workers * number_of_cars)
number_of_shopper = number_of_cars - number_of_office_workers
office_list = []
while len(office_list) <= number_of_office_workers:
office_list.append(office[self.random.randint(0, len(office) -1)])
entertainment_list = []
while len(entertainment_list) <= number_of_shopper:
entertainment_list.append(entertainment[self.random.randint(0, len(entertainment) - 1)])
office_entertainment_list = office_list + entertainment_list
random.shuffle(residence_list)
layout = self.map.get_layout()
for i in range(number_of_cars):
# determine departure and return time based on activity level
if i <= num_highly_active_cars:
activity_level = "HIGHLY_ACTIVE"
departure_time = 0
return_time = float("inf")
elif i <= num_business_hours_cars:
activity_level = "BUSINESS_HOURS"
departure_time = self.start_peak_hour_1
return_time = float("inf")
else:
activity_level = "PEAK_HOURS"
departure_time = self.random.randint(self.start_peak_hour_1,self.end_peak_hour_1)
return_time = self.random.randint(self.start_peak_hour_2,self.end_peak_hour_2)
plate_number_oddity = self.random.randint(0, 1)
source_x = residence_list[i][0]
source_y = residence_list[i][1]
destination_x = office_entertainment_list[i][0]
destination_y = office_entertainment_list[i][1]
state_fringes = self.map.get_fringes(source_x, source_y)
shortest_distance = float("inf")
car_direction = state_fringes[0][1]
for state_fringe in state_fringes:
current_direction = state_fringe[1] # "^" "v" ">" "<"
if current_direction in DIRECTION:
temp_x = state_fringe[0][0] + DIRECTION[current_direction][0]
temp_y = state_fringe[0][1] + DIRECTION[current_direction][1]
newDist = get_euclidean_distance((temp_x, temp_y), (destination_x, destination_y))
if newDist < shortest_distance:
shortest_distance = newDist
car_direction = current_direction
# all cars are initialised as IDLE
car_state = "IDLE"
car = Car(i, plate_number_oddity,
(source_x,source_y),
(destination_x,destination_y),
car_direction,
car_state,
departure_time,
return_time,
activity_level,
self)
self.grid.place_agent(car, (source_x,source_y))
self.schedule.add(car)
# Data Collection
self.datacollector = DataCollector({
"Idle": number_idle_cars,
"Move": number_move_cars,
"Finished": number_finished_cars,
"SimulationMinutes": simulation_minutes,
"ToOffice": number_office,
"ToResidence": number_residence,
"MeanTravelTime": mean_travel_time,
"StdTravelTime": std_travel_time
})
self.datacollector.collect(self)
def step(self):
self.schedule.step()
self.tick += 1
self.mean_travel_time = np.mean([cell.travel_time for j in range(100) for i in range(100) for cell in self.grid.iter_cell_list_contents((i,j))
if type(cell) is Car])
self.datacollector.collect(self)
# After a day (1440 minutes), stop the simulation
if self.tick >= 1440:
self.running = False
def is_plate_number_oddity_allowed(self, plate_number_oddity=0, xy=(0, 0)):
x, y = xy
# implement odd even policy for avenue only.
if(self.map.is_avenue(x, y)):
if(self.is_odd_date == True): # date is odd
if(plate_number_oddity % 2 == 1): # plate is odd
return True
else:
return False
else: # date is even
if(plate_number_oddity % 2 == 0): # plate is even
return True
else:
return False
else:
return True
def is_odd_even_policy_time(self):
#1 day == 1440 minutes
day_tick = self.tick % 1440
if self.policy_range_time == '7_10_and_16_19':
if day_tick >= (7 * 60) and day_tick <= (10 * 60):
return True
elif day_tick >= (16 * 60) and day_tick <= (19 * 60):
return True
else:
return False
elif self.policy_range_time == '8_11_and_17_20':
if day_tick >= (8 * 60) and day_tick <= (11 * 60):
return True
elif day_tick >= (17 * 60) and day_tick <= (20 * 60):
return True
else:
return False
elif self.policy_range_time == '6_9_and_15_18':
if day_tick >= (6 * 60) and day_tick <= (9 * 60):
return True
elif day_tick >= (15 * 60) and day_tick <= (18 * 60):
return True
else:
return False
elif self.policy_range_time == '8_9_and_17_18':
if day_tick >= (8 * 60) and day_tick <= (9 * 60):
return True
elif day_tick >= 17 * 60 and day_tick <= 18 * 60:
return True
else:
return False
elif self.policy_range_time == '6_11_and_15_20':
if day_tick >= (6 * 60) and day_tick <= (11 * 60):
return True
elif day_tick >= (15 * 60) and day_tick <= (20 * 60):
return True
else:
return False
else:
return False
