Doug Hensley, Francis Edward Su
Published 2001-02-27Version 1
Using the discrepancy metric, we analyze the rate of convergence of a random walk on the circle generated by d rotations, and establish sharp rates that show that badly approximable d-tuples in R^d give rise to walks with the fastest convergence. We use the discrepancy metric because the walk does not converge in total variation. For badly approximable d-tuples, the discrepancy is bounded above and below by (constant)k^(-d/2), where k is the number of steps in the random walk. We show how the constants depend on the d-tuple.
Comments: 7 pages; to appear in DIMACS volume "Unusual Applications of Number Theory"; related work at http://www.math.hmc.edu/~su/papers.html
Journal: DIMACS Ser. Discrete Math. Theoret. Comput. Sci. 64 (2004), 95-101.
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