Domain Adaptation with Optimal Transport on the Manifold of SPD matrices
About
In this paper, we address the problem of Domain Adaptation (DA) using Optimal Transport (OT) on Riemannian manifolds. We model the difference between two domains by a diffeomorphism and use the polar factorization theorem to claim that OT is indeed optimal for DA in a well-defined sense, up to a volume preserving map. We then focus on the manifold of Symmetric and Positive-Definite (SPD) matrices, whose structure provided a useful context in recent applications. We demonstrate the polar factorization theorem on this manifold. Due to the uniqueness of the weighted Riemannian mean, and by exploiting existing regularized OT algorithms, we formulate a simple algorithm that maps the source domain to the target domain. We test our algorithm on two Brain-Computer Interface (BCI) data sets and observe state of the art performance.
Related benchmarks
| Task | Dataset | Result | Rank | |
|---|---|---|---|---|
| BCI classification | Hinss2021 (inter-session) | Balanced Accuracy42 | 16 | |
| BCI classification | Hinss inter-subject 2021 | Balanced Accuracy40.4 | 16 | |
| BCI classification | Lee 2019 (inter-session) | Balanced Accuracy0.656 | 11 | |
| BCI classification | BNCI2014001 (inter-session) | Balanced Accuracy66.8 | 11 | |
| BCI classification | BNCI2015001 (inter-session) | Balanced Acc77.5 | 11 | |
| BCI classification | BNCI2015001 (inter-subject) | Balanced Accuracy63.3 | 11 | |
| BCI classification | Lehner 2021 (inter-session) | Balanced Accuracy63 | 11 | |
| BCI classification | Stieger 2021 (inter-subject) | Balanced Accuracy42.1 | 11 | |
| BCI classification | BNCI2014001 (inter-subject) | Balanced Accuracy38.6 | 11 | |
| BCI classification | Stieger 2021 (inter-session) | Balanced Acc50.3 | 11 |