DS1 spectrogram: Wasserstein Residuals: Learning Gradient Flows from Population Dynamics

Wasserstein Residuals: Learning Gradient Flows from Population Dynamics

2607.04738

Authors

Markus Heinonen,Yair Shenfeld,Ricardo Baptista,Daniel Waxman,Dmitry Batenkov

Abstract

Reconstructing population dynamics is a central problem in the physical and data sciences. Often, the dynamics are modeled as a Wasserstein gradient flow (WGF): a curve of distributions driven by an energy functional.

Though there are multiple mathematical characterizations of a WGF, the dominant algorithmic approach relies on the Jordan--Kinderlehrer--Otto (JKO) scheme. JKO-based methods are inflexible to time discretisation and require solving costly optimal transport problems.

We take a residual approach, enforcing the continuity equations via a non-negative loss function whose minimum is the WGF. Combined with a data-fitting divergence, this gives a single global objective.

This perspective unifies several existing methods and leads to a new particle-based method, stitching, that is simulation-free and robust to large gaps between observations. We demonstrate that the stitching method achieves state-of-the-art performance across trajectory inference benchmarks.

For code see github.com/BasisResearch/wasserstein-residuals.

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