import numpy as np
import __basik__ as bk
if __name__ == '__main__':
print('Setting up simulation...')
np.random.seed(123)
fig, ax = bk.axes_grid(3, 1, scale=2.5)
end_time = 20
lane_length = 5
bk.Queue.clear()
# North:
Nlane_in = bk.Lane(lane_length)
Nlane_out = bk.Lane(lane_length)
NDisplay = bk.RoadDisplay(left_lane=Nlane_out,
right_lane=Nlane_in,
axes=ax[0, 0],
horizontal=False)
Nrate = {end_time: bk.Rate(2)}
Nsource = bk.Source(vehicle_velocity=16.67,
target_node=Nlane_in.IN,
rate_schedule=Nrate)
print('Scheduling Northern arrivals...')
Nsource.setup_arrivals(end_time)
print('..done!')
Nrecord = bk.Record(Nlane_out.OUT)
# South
Slane_in = bk.Lane(lane_length)
Slane_out = bk.Lane(lane_length)
SDisplay = bk.RoadDisplay(left_lane=Slane_in,
right_lane=Slane_out,
axes=ax[2, 0],
bk.VehicleDisplay.speed_up_factor = 10
bk.Vehicle.frames_per_move = 2
bk.VehicleDisplay.SHOW = False # TURN OFF
print('DISPLAY OFF')
print('Setting up simulation...')
np.random.seed(123)
fig,ax = bk.axes_grid(3,3,scale=2.5)
end_time = 21
lane_length = 5
bk.Queue.clear()
# East
Elane_in = bk.Lane(lane_length)
Elane_out = bk.Lane(lane_length)
EDisplay = bk.RoadDisplay(left_lane=Elane_out,
right_lane=Elane_in,
axes=ax[1,2],
horizontal=True)
Erate = {end_time:bk.Rate(0.3)}
Esource = bk.Source(vehicle_velocity = 16.67,
target_node = Elane_in.IN,
rate_schedule=Erate)
print('Scheduling Eastern arrivals...')
Esource.setup_arrivals(end_time)
print('..done!')
Erecord = bk.Record(Elane_out.OUT)
# West
Wlane_in = bk.Lane(lane_length)
Wlane_out = bk.Lane(lane_length)
WDisplay = bk.RoadDisplay(left_lane=Wlane_in,
right_lane=Wlane_out,
axes=ax[1,0],
bk.VehicleDisplay.speed_up_factor = 10
bk.Vehicle.frames_per_move = 2
bk.VehicleDisplay.SHOW = False # TURN OFF
print('DISPLAY OFF')
print('Setting up simulation...')
np.random.seed(123)
fig,ax = bk.axes_grid(3,3,scale=2.5)
end_time = 21
lane_length = 5
bk.Queue.clear()
# North:
Nlane_in = bk.Lane(lane_length)
Nlane_out = bk.Lane(lane_length)
NDisplay = bk.RoadDisplay(left_lane=Nlane_out,
right_lane=Nlane_in,
axes=ax[0,1],
horizontal=False)
Nrate = {end_time:bk.Rate(1.5)}
Nsource = bk.Source(vehicle_velocity = 16.67,
target_node = Nlane_in.IN,
rate_schedule=Nrate)
print('Scheduling Northern arrivals...')
Nsource.setup_arrivals(end_time)
print('..done!')
Nrecord = bk.Record(Nlane_out.OUT)
# East
Elane_in = bk.Lane(lane_length)
Elane_out = bk.Lane(lane_length)
EDisplay = bk.RoadDisplay(left_lane=Elane_out,
right_lane=Elane_in,
axes=ax[1,2],
'''
Produces the type 1 obstruction crossing from Tutorial 7.
'''
import numpy as np
import __basik__ as bk
if __name__ == '__main__':
end_time = 20
np.random.seed(123)
fig, ax = plt.subplots(1, 1)
# Let us create a single lane object
lane = bk.Lane(10)
lane_display = bk.RoadDisplay(left_lane=lane,
right_lane=None,
axes=ax,
horizontal=True)
rate = {end_time: bk.Rate(0.3)}
source = bk.Source(vehicle_velocity=16.67,
target_node=lane.IN,
rate_schedule=rate)
source.setup_arrivals(20)
# Let us schedule three obstructions at some node
lane.nodes[4].schedule_obstructions(start_times=[0, 20], durations=[9, 5])
# Run
bk.Queue.run(end_time)
if __name__ == '__main__':
bk.VehicleDisplay.speed_up_factor = 10
bk.Vehicle.frames_per_move = 2
np.random.seed(123)
bk.Queue.clear()
fig,ax = bk.axes_grid(1,1,scale=5)
end_time = 20
# Let us create a single lane object
lane = bk.Lane(20)
lane_display = bk.RoadDisplay(left_lane=lane,
right_lane=None,
axes=ax[0,0],
horizontal=True,
square_image=False) # removes some detail and gives a road strip
rate = {end_time:bk.Rate(0.5)}
source = bk.Source(vehicle_velocity = 16.67, # INITIAL VELOCITY is 60 km/h
target_node = lane.IN,
rate_schedule=rate)
source.setup_arrivals(20)
# Let us schedule three obstructions at some node
lane.nodes[5].assign_velocity_change(5.55) # change to about 20 km/h
lane.nodes[10].assign_velocity_change(27.77) # change to about 100 km/h
# Run
plt.pause(4)
bk.Queue.run(end_time)