Complexity of zigzag sampling algorithm for strongly log-concave distributions
Publication
, Journal Article
Lu, J; Wang, L
Published in: Stat Comput
December 20, 2020
We study the computational complexity of zigzag sampling algorithm for strongly log-concave distributions. The zigzag process has the advantage of not requiring time discretization for implementation, and that each proposed bouncing event requires only one evaluation of partial derivative of the potential, while its convergence rate is dimension independent. Using these properties, we prove that the zigzag sampling algorithm achieves $\varepsilon$ error in chi-square divergence with a computational cost equivalent to $O\bigl(κ^2 d^\frac{1}{2}(\log\frac{1}{\varepsilon})^{\frac{3}{2}}\bigr)$ gradient evaluations in the regime $κ\ll \frac{d}{\log d}$ under a warm start assumption, where $κ$ is the condition number and $d$ is the dimension.
Duke Scholars
Published In
Stat Comput
Publication Date
December 20, 2020
Volume
32
Start / End Page
48
Citation
APA
Chicago
ICMJE
MLA
NLM
Lu, J., & Wang, L. (2020). Complexity of zigzag sampling algorithm for strongly log-concave distributions. Stat Comput, 32, 48.
Lu, Jianfeng, and Lihan Wang. “Complexity of zigzag sampling algorithm for strongly log-concave distributions.” Stat Comput 32 (December 20, 2020): 48.
Lu J, Wang L. Complexity of zigzag sampling algorithm for strongly log-concave distributions. Stat Comput. 2020 Dec 20;32:48.
Lu, Jianfeng, and Lihan Wang. “Complexity of zigzag sampling algorithm for strongly log-concave distributions.” Stat Comput, vol. 32, Dec. 2020, p. 48.
Lu J, Wang L. Complexity of zigzag sampling algorithm for strongly log-concave distributions. Stat Comput. 2020 Dec 20;32:48.
Published In
Stat Comput
Publication Date
December 20, 2020
Volume
32
Start / End Page
48