Skip to main content

2D traffic modeling.

Project description

Autopysta

Autopysta is a Python library for simulating 2D traffic flow on highways. It is written in C++ for high performance and wrapped using SWIG for Python compatibility. The library allows users to create realistic highway traffic scenarios with customizable vehicle behaviors, lane-changing logic, and road configurations.

Platform Support

Autopysta supports Windows, Linux, and macOS. However, the specific Python versions supported on each platform are still under testing and validation. Currently:

  • Windows: Tentatively supports Python 3.8, pending further compatibility testing.
  • Linux and macOS: Compatible with Python 3.8 and later, though compatibility with other versions is being evaluated.

Key Features

  1. Flexible Vehicle Behavior
    Autopysta provides a variety of vehicle models that dictate acceleration, deceleration, and lane-changing dynamics. Examples include:

    • Intelligent Driver Model (IDM)
    • Gipps Model
    • Newell Random Acceleration Model
  2. Vehicle Creation Options
    Users can choose different vehicle creation strategies for each lane, defining how vehicles are added to the simulation.

  3. Customizable Highway Geometry
    Configure highways with parameters such as road length, number of lanes, and merge/diverge points for ramps.


Installing Autopysta from PyPI

If you don’t want to compile from source, you can install Autopysta directly from PyPI (precompiled binaries are available for supported platforms):

pip install autopysta

This will install the latest version of Autopysta and its dependencies, allowing you to skip the manual build process.


Compiling Autopysta from Source

To compile Autopysta from source, you will need to build the C++ components, generate the Python wrappers, and copy the necessary binaries to the appropriate directories.

Prerequisites

Before building from source, ensure you have the following installed:

  • Python (version 3.8 on Windows, 3.8 or higher on Linux/macOS)
  • CMake (for building the C++ components)
  • setuptools and wheel (pip install setuptools wheel)
  • SWIG (for generating Python wrappers)

Steps to Compile Autopysta

  1. Clone the Repository
    Run the following commands to clone the repository and navigate to its directory:

    git clone https://bitbucket.org/rdelpiano/autopysta.git
    cd autopysta
    
  2. Build the Extension
    Use the following command to build the C++ extension:

    python setup.py build_ext
    

    This will:

    1. Use CMake to compile the C++ code.
    2. Generate the autopysta.py wrapper and the platform-specific _autopysta.* shared library.
    3. Copy the generated binaries to:
      1. The root autopysta directory.
      2. The examples/autopysta directory.
  3. Verify the Build
    After building, check the autopysta directory (both in the root and inside examples/) for:

    1. autopysta.py: Python wrapper.
    2. _autopysta.*: Shared library file specific to your platform (e.g., _autopysta.so on Linux/macOS or _autopysta.pyd on Windows).

Running an Example

Once the build is complete, you can run any example provided in the examples directory.

Example: Running the Different Vehicle Creators Example

Navigate to the examples/ directory:

cd examples

Run the different_creators.py (or any other example script):

python different_creators.py

This script simulates traffic with different vehicle creation strategies, as shown in the "Quick Start Example" below.


Quick Start Example: Using Autopysta to Simulate Different Vehicle Creators

Autopysta offers various ways to populate lanes with vehicles, each governed by different driving models and behaviors. Here’s an example of setting up a simulation with different vehicle creators to model distinct traffic conditions.

# ------------------------------------------------------------------------------
# Case Study: Using Different Vehicle Creators
#
# This example demonstrates the use of different vehicle creators to populate 
# lanes with vehicles using distinct driving models. The creators used are:
# 1. `FixedStateCreator`: Generates vehicles with specified spacing and speed.
# 2. `FixedDemandCreator`: Generates vehicles based on a fixed traffic flow rate.
# ------------------------------------------------------------------------------

# Import the library
import autopysta as ap

# Display the current version of autopysta
print(ap.version())

# Define the highway geometry for the simulation. The Geometry object takes:
# 1. `length`: The length of the highway (meters).
# 2. `lanes`: Number of lanes.
# 3. `merge_pos`: Position where a merge ramp ends (0 for no merge ramp).
# 4. `diverge_pos`: Position where a diverge ramp starts (highway length for no diverge ramp).
length = 1000
initial_lanes = 4
merge_position = 300
diverge_position = 700
highway_geometry = ap.Geometry(length, initial_lanes, merge_position, diverge_position)

# Define the driving models for acceleration/deceleration.
# Default parameters are used for both models.
idm_model = ap.idm()
gipps_model = ap.gipps()

# Specify the types of vehicle creators for each lane. The creators define the
# conditions under which vehicles are added to the lanes:
# - `FixedStateCreator`: Generates vehicles based on specified spacing and speed.
# - `FixedDemandCreator`: Generates vehicles based on a fixed flow rate.
# If only one creator is given, it will apply to all lanes. The final parameter 
# is optional, specifying a maximum number of vehicles (default is unlimited).
spacing = 15
speed = 10
flow_rate = 0.5
lane_creators = [
    ap.FixedStateCreator(gipps_model, spacing, speed),  # Lane 1
    ap.FixedDemandCreator(idm_model, flow_rate),        # Lane 2
    ap.FixedStateCreator(idm_model, spacing, speed),    # Lane 3
    ap.FixedDemandCreator(gipps_model, flow_rate),      # Lane 4 (if present)
]


# Define the lane-changing model. To disable lane changing, use `no_lch`.
lane_change_model = ap.lcm_gipps()

# Initialize the Simulation object with the defined settings. The simulation is
# set to run for 80 seconds with a timestep of 0.1 seconds.
# No vehicles are predefined, so we use an empty list.
# We set verbose mode to get some extra output and see the shape of the geometry
total_time = 80
vehicles=[]
time_step = 0.1
verbose = True
simulation = ap.Simulation(
    lane_change_model,
    total_time,
    highway_geometry,
    lane_creators,
    vehicles,
    time_step
)


# Run the simulation. The `run()` method returns a `Results` object containing
# trajectory data from the simulation.
simulation_results = simulation.run()

# The `plot_x_vs_t` method generates trajectory plots. It can be used to plot
# all lanes or specific lanes, as shown below.
plotting = True
if plotting:
    simulation_results.plot_x_vs_t()       # Plot all lanes
    simulation_results.plot_x_vs_t(lane=1) # Plot only lane 1
    simulation_results.plot_x_vs_t(lane=2) # Plot only lane 2
    simulation_results.plot_x_vs_t(lane=3) # Plot only lane 3
    simulation_results.plot_x_vs_t(lane=4) # Plot only lane 4 (if applicable)

Explanation of the Simulation Example

  • Geometry Setup: Creates a highway with a length of 1000 meters and 4 lanes. The highway includes a merge ramp at 300 meters and a diverge ramp at 700.
  • Vehicle Models: The IDM, Gipps, and Newell Random Acceleration models are assigned to control vehicle dynamics. Different models can represent various driving styles or traffic conditions.
  • Lane Creators: Vehicles are added based on either a fixed spacing (FixedStateCreator) or a flow rate (FixedDemandCreator). This allows the simulation of both congested and free-flowing traffic conditions.
  • Lane-Changing Logic: The lane-change model (lcm_gipps) handles vehicle lane changes based on the surrounding traffic conditions, with optional parameters for enabling or disabling lane changes.
  • Simulation Execution: The simulation runs for a set period, returning vehicle trajectories for analysis.

Additional Features

  • Verbose Mode: Enables detailed output during the simulation, useful for understanding and troubleshooting the behavior of individual vehicles.
  • Plotting: The plot_x_vs_t() method generates time-space plots for vehicle trajectories, providing a visual representation of the simulation results.

Platform-Specific Details

  • Linux and macOS: Autopysta uses .so shared libraries and works with Python 3.8+.
  • Windows: Only Python 3.8 is supported due to DLL handling requirements. Autopysta uses .pyd files on Windows.

Autopysta provides an efficient and flexible framework for traffic simulation, making it suitable for research, experimentation, and traffic model development. 🚦

Project details


Download files

Download the file for your platform. If you're not sure which to choose, learn more about installing packages.

Source Distribution

autopysta-0.0.31.4.tar.gz (105.8 kB view details)

Uploaded Source

Built Distribution

autopysta-0.0.31.4-cp310-cp310-manylinux_2_17_x86_64.manylinux2014_x86_64.whl (857.6 kB view details)

Uploaded CPython 3.10 manylinux: glibc 2.17+ x86-64

File details

Details for the file autopysta-0.0.31.4.tar.gz.

File metadata

  • Download URL: autopysta-0.0.31.4.tar.gz
  • Upload date:
  • Size: 105.8 kB
  • Tags: Source
  • Uploaded using Trusted Publishing? No
  • Uploaded via: twine/5.1.1 CPython/3.13.0

File hashes

Hashes for autopysta-0.0.31.4.tar.gz
Algorithm Hash digest
SHA256 d5011459e2479dda769d73bef5a6f690dd75b3d28fb6b0a468140a80564a236d
MD5 15bdee1a94450a5c234a504a582d1bb1
BLAKE2b-256 9acf5c6de3a8eca68d413ef90e2820f5d7372c8cbd635eeb094df7cd6d0155a5

See more details on using hashes here.

File details

Details for the file autopysta-0.0.31.4-cp310-cp310-manylinux_2_17_x86_64.manylinux2014_x86_64.whl.

File metadata

File hashes

Hashes for autopysta-0.0.31.4-cp310-cp310-manylinux_2_17_x86_64.manylinux2014_x86_64.whl
Algorithm Hash digest
SHA256 39d11b5768295ab56ad7dda63ba66210b7926cbdc9a6469bd3829f1309f5bee5
MD5 7cccdd6b4cf764a6755e0e059bf42c71
BLAKE2b-256 f2455683407337dc4c1cf8c5ecd9222638274d31038326ab79bfd53877706b31

See more details on using hashes here.

Supported by

AWS AWS Cloud computing and Security Sponsor Datadog Datadog Monitoring Fastly Fastly CDN Google Google Download Analytics Microsoft Microsoft PSF Sponsor Pingdom Pingdom Monitoring Sentry Sentry Error logging StatusPage StatusPage Status page