Self-Consistent Velocity Matching of Probability Flows
We present a discretization-free scalable framework for solving a large class of mass-conserving partial differential equations (PDEs), including the time-dependent Fokker-Planck equation and the Wasserstein gradient flow. The main observation is that the time-varying velocity field of the PDE solut...
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| Format | Journal Article |
| Language | English |
| Published |
31.01.2023
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| Abstract | We present a discretization-free scalable framework for solving a large class
of mass-conserving partial differential equations (PDEs), including the
time-dependent Fokker-Planck equation and the Wasserstein gradient flow. The
main observation is that the time-varying velocity field of the PDE solution
needs to be self-consistent: it must satisfy a fixed-point equation involving
the probability flow characterized by the same velocity field. Instead of
directly minimizing the residual of the fixed-point equation with neural
parameterization, we use an iterative formulation with a biased gradient
estimator that bypasses significant computational obstacles with strong
empirical performance. Compared to existing approaches, our method does not
suffer from temporal or spatial discretization, covers a wider range of PDEs,
and scales to high dimensions. Experimentally, our method recovers analytical
solutions accurately when they are available and achieves superior performance
in high dimensions with less training time compared to alternatives. |
|---|---|
| AbstractList | We present a discretization-free scalable framework for solving a large class
of mass-conserving partial differential equations (PDEs), including the
time-dependent Fokker-Planck equation and the Wasserstein gradient flow. The
main observation is that the time-varying velocity field of the PDE solution
needs to be self-consistent: it must satisfy a fixed-point equation involving
the probability flow characterized by the same velocity field. Instead of
directly minimizing the residual of the fixed-point equation with neural
parameterization, we use an iterative formulation with a biased gradient
estimator that bypasses significant computational obstacles with strong
empirical performance. Compared to existing approaches, our method does not
suffer from temporal or spatial discretization, covers a wider range of PDEs,
and scales to high dimensions. Experimentally, our method recovers analytical
solutions accurately when they are available and achieves superior performance
in high dimensions with less training time compared to alternatives. |
| Author | Hurault, Samuel Solomon, Justin Li, Lingxiao |
| Author_xml | – sequence: 1 givenname: Lingxiao surname: Li fullname: Li, Lingxiao – sequence: 2 givenname: Samuel surname: Hurault fullname: Hurault, Samuel – sequence: 3 givenname: Justin surname: Solomon fullname: Solomon, Justin |
| BackLink | https://doi.org/10.48550/arXiv.2301.13737$$DView paper in arXiv |
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| Snippet | We present a discretization-free scalable framework for solving a large class
of mass-conserving partial differential equations (PDEs), including the... |
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| Title | Self-Consistent Velocity Matching of Probability Flows |
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