A python library to add 3D sound to a Sumo traffic simulation.
Project description
SumoSound
SumoSound is a Python package which uses Sumo's TraCI API and PyOpenAL to generate vehicle sounds in a 3D environment. PyOpenAL calculates the proper volume, doppler shift, and stereo (or surround sound) output. The package comes with some built-in default sound effects, but is fully customizable, and can calculate the sounds from the point of view of either a stationary ego position or one of the vehicles in the simulation.
Installation
Simply clone this repository and add it to your Python path. You can then import the library
import SumoSound
Dependencies
- Sumo TraCI
- PyOpenAL
Usage
See the example script sound_test.py for an example.
In general, you just need to define an Ego
object (either of the Ego
class or a
subclass of it), pass this Ego
object to a Simulation
object, and then call
update()
on the Simulation
object once per simulation step. Everything else
should be handled automatically.
Documentation
Ego
An Ego
object defines the position, velocity, and orientation of the listener.
There are 3 ego types: Stationary Ego, Ego Vehicle, and Ego Vehicle with Manually-Calculated Speed.
Stationary Ego (Ego
)
The position, velocity, and orientation of a stationary ego are controlled with the methods set_position()
,
set_velocity()
, and set_angle()
. The ego will default to a location of (0, 0, 0) facing east with
zero velocity.
ego = SumoSound.Ego()
Ego Vehicle (EgoVehicle
)
The position, velocity, and orientation of an ego vehicle are synced via TraCI with the vehicle with the given ID.
These properties are automatically updated every time step by the Simulation
object.
ego = SumoSound.EgoVehicle("vehicleID")
Ego Vehicle with Manually-Calculated Speed (EgoVehicleManualSpeed
)
The same as an EgoVehicle
, but the vehicle speed is calculated based on the ego position in the previous and
current simulation time steps. This is useful if the ego vehicle is being controlled externally and the speed property
is incorrect or undefined.
ego = SumoSound.EgoVehicleManualSpeed("vehicleID")
Simulation
A Simulation
object keeps track of all of the vehicles in the Sumo simulation via TraCI, updating the sound
sources and listener position as necessary. An ego must be passed to the constructor of the Simulation
object.
simulation = SumoSound.Simulation(ego)
Additional parameters are available as well. Most notably, the argument vehicle_class_map
can be used to tell
SumoSound which subclass of Vehicle
to use for each Sumo vehicleClass. By default, the dict
DEFAULT_VEHICLE_CLASS_MAP
is used. For more information on defining custom vehicle types, see the next section.
The method update()
must be called every simulation step.
while True:
traci.simulationStep()
simulation.update()
Vehicle
A Vehicle
object keeps track of one or more sound sources associated with the vehicle type. SumoSound comes with a
number of pre-defined vehicle types which are selected automatically by the Simulation
object based on the Sumo
vehicleClass property of each vehicle. Custom vehicle types can be created by simply sub-classing the Vehicle
class. The gain of each vehicle sound can be automatically actuated by a signal. By default, the speed and acceleration
of the vehicle are available as signals, but custom signals can also be created.
class CustomVehicle(SumoSound.Vehicle):
def __init__(self, id, engine_sound_file="path/to/file.wav",
tire_sound_file="path/to/file.wav",
horn_sound_file="path/to/file.wav"):
super().__init__(id)
self.horn = False # define a custom signal called "horn"
# add an engine sound to the vehicle, actuated by the vehicle acceleration
engine_sound = SumoSound.VehicleSound(engine_sound_file, base_gain=0.5)
self.add_sound(engine_sound, "acceleration", response_curve=[(0, 0.5), (2.5, 1)])
# add a tire sound to the vehicle, actuated by the vehicle speed
tire_sound = SumoSound.VehicleSound(tire_sound_file, base_gain=2)
self.add_sound(tire_sound, "speed", response_curve=[(0, 0), (28, 1)])
# add a horn sound to the vehicle, actuated by the custom signal "horn"
horn_sound = SumoSound.VehicleSound(horn_sound_file, base_gain=2)
self.add_sound(horn_sound, "horn", response_curve=[(False, 0), (True, 1)])
The argument response_curve
of the method add_sound()
is a list of (signal_value, gain)
tuples, which
are interpolated as necessary to calculate the sound gain from the signal value.
To associate the custom vehicle type with a vehicle class, the vehicle_class_map
argument of the Simulation
constructor must be passed a custom dict containing the desired mapping, or the default dict can be modified before
creating the Simulation object.
# map the custom vehicle type to the Sumo vehicleClass "passenger"
SumoSound.DEFAULT_VEHICLE_CLASS_MAP["passenger"] = CustomVehicle
simulation = SumoSound.Simulation(ego)
In order to use the custom signal to actuate the sound, simply set the signal to the desired value, and everything will be automatically handled the next time the simulation is updated.
simulation.vehicles["vehicleID"].horn = True
Contribution
Issues and pull requests are welcome.
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