Averaging on the Bures-Wasserstein manifold: dimension-free convergence of gradient descent

Add code
Jun 16, 2021
Jason M. Altschuler, Sinho Chewi, Patrik Gerber, Austin J. Stromme
Figure 1 for Averaging on the Bures-Wasserstein manifold: dimension-free convergence of gradient descent
Figure 2 for Averaging on the Bures-Wasserstein manifold: dimension-free convergence of gradient descent
Figure 3 for Averaging on the Bures-Wasserstein manifold: dimension-free convergence of gradient descent
Figure 4 for Averaging on the Bures-Wasserstein manifold: dimension-free convergence of gradient descent

Share this with someone who'll enjoy it:

Twitter IconFacebook IconLinkedin IconWhatsapp IconMessenger Icon

We study first-order optimization algorithms for computing the barycenter of Gaussian distributions with respect to the optimal transport metric. Although the objective is geodesically non-convex, Riemannian GD empirically converges rapidly, in fact faster than off-the-shelf methods such as Euclidean GD and SDP solvers. This stands in stark contrast to the best-known theoretical results for Riemannian GD, which depend exponentially on the dimension. In this work, we prove new geodesic convexity results which provide stronger control of the iterates, yielding a dimension-free convergence rate. Our techniques also enable the analysis of two related notions of averaging, the entropically-regularized barycenter and the geometric median, providing the first convergence guarantees for Riemannian GD for these problems.

* 48 pages, 8 figures  
View paper onarxiv iconopen_review iconOpenReview

Share this with someone who'll enjoy it:

Twitter IconFacebook IconLinkedin IconWhatsapp IconMessenger Icon