Riemannian Continuous Normalizing Flows
About
Normalizing flows have shown great promise for modelling flexible probability distributions in a computationally tractable way. However, whilst data is often naturally described on Riemannian manifolds such as spheres, torii, and hyperbolic spaces, most normalizing flows implicitly assume a flat geometry, making them either misspecified or ill-suited in these situations. To overcome this problem, we introduce Riemannian continuous normalizing flows, a model which admits the parametrization of flexible probability measures on smooth manifolds by defining flows as the solution to ordinary differential equations. We show that this approach can lead to substantial improvements on both synthetic and real-world data when compared to standard flows or previously introduced projected flows.
Related benchmarks
| Task | Dataset | Result | Rank | |
|---|---|---|---|---|
| Density Estimation | Volcano (test) | NLL-6.05 | 14 | |
| Spatio-temporal Density Estimation | Earthquake (EQ) (test) | NLL0.19 | 10 | |
| Density Estimation | Earthquakes NGDC/WDS, 2022a (test) | Negative Log-Likelihood0.14 | 8 | |
| Density Estimation | Floods (test) | NLL1.11 | 8 | |
| Density Estimation | Wildfires EOSDIS, 2020 (test) | NLL-0.8 | 8 | |
| Density Estimation | Flood (test) | NLL0.9 | 6 | |
| Density Estimation | FIRE (test) | NLL-0.66 | 6 | |
| Distribution Generation | Volcano | Negative Log-Likelihood (NLL)-0.97 | 6 | |
| Distribution Generation | Earthquake | NLL0.19 | 6 | |
| Distribution Generation | Flood | NLL0.9 | 6 |