Path4GMNS is an open-source, cross-platform, lightweight, and fast Python path engine for networks encoded in GMNS. Besides finding static shortest paths for simple analyses, its main functionality is to provide an efficient and flexible framework for column-based (path-based) modeling and applications in transportation (e.g., activity-based demand modeling). Path4GMNS supports, in short,
Path4GMNS also serves as an API to the C++-based DTALite to conduct various multimodal traffic assignments including,
We highly recommend that you go through the above Tutorial, no matter you are one of the existing users or new to Path4GMNS.
Path4GMNS has been published on PyPI, and can be installed using
$ pip install path4gmns
[!IMPORTANT] v0.9.9 comes with bug fixes, new functionality, and performance improvement. Please discard all old versions.
[!NOTE] ODME is now available with v0.9.9.
[!CAUTION] Any version prior to v0.9.4 will generate INCORRECT simulation results.
[!CAUTION] Calling DTALite and synthesizing zones and OD demand are not functioning for v0.9.5 and v0.9.6.
[!CAUTION] Zone and demand synthesis is PROBLEMATIC for any version before v0.9.9.
The Python modules are written in Python 3.x, which is the minimum requirement to explore the most of Path4GMNS. Some of its functions require further run-time support, which we will go through along with the corresponding Use Cases.
Li, P. and Zhou, X. (2024, October 17). Path4GMNS. Retrieved from https://github.com/jdlph/Path4GMNS
Any contributions are welcomed including advise new applications of Path4GMNS, enhance documentation and docstrings in the source code, refactor and/or optimize the source code, report and/or resolve potential issues/bugs, suggest and/or add new functionalities, etc.
Path4GMNS has a very simple workflow setup, i.e., master for release (on both GitHub and PyPI) and dev for development. If you would like to work directly on the source code (and probably the documentation), please make sure that the destination branch of your pull request is dev, i.e., all potential changes/updates shall go to the dev branch before merging into master for release.
You are encouraged to join our Discord Channel for the latest update and more discussions.
Lu, C. C., Mahmassani, H. S., Zhou, X. (2009). Equivalent gap function-based reformulation and solution algorithm for the dynamic user equilibrium problem. Transportation Research Part B: Methodological, 43, 345-364.
Jayakrishnan, R., Tsai, W. K., Prashker, J. N., Rajadyaksha, S. (1994). A Faster Path-Based Algorithm for Traffic Assignment (Working Paper UCTC No. 191). The University of California Transportation Center.
Bertsekas, D., Gafni, E. (1983). Projected Newton methods and optimization of multicommodity flows. IEEE Transactions on Automatic Control, 28(12), 1090–1096.