Exact Solution to the Chow-Robbins Game for almost all n, using the Catalan Triangle
Abstract
The payoff in the Chow-Robbins coin-tossing game is the proportion of heads when you stop. Knowing when to stop to maximize expectation was addressed by Chow and Robbins(1965), who proved there exist integers kn such that it is optimal to stop when heads minus tails reaches this. Finding kn exactly was unsolved except for finitely many cases by computer. We show kn = α n \,\, - 1/2\,\, + \,\,( - 2ζ ( - 1/2) ) α π n - 1/4 for almost all n, where α is the Shepp-Walker constant.This comes from our estimate βn = α n \,\, - 1/2\,\, + \,\,( - 2ζ ( - 1/2) ) α π n - 1/4 + O( n - 7/24 ) of real numbers defined by Dvoretzky(1967) for a more general Value function which is continuous in its first argument and easier to analyze. An O(n - 1/4) dependence was conjectured by Christensen and Fischer(2022) from numerical evidence. Our proof uses moments involving Catalan and Catalan triangle numbers which appear in a tree resulting from backward induction, and a generalized backward induction principle. It was motivated by an idea of H\"aggstr\"om and W\"astlund(2013) to use backward induction of upper and lower Value bounds from a horizon, which they used numerically to settle a few cases. Christensen and Fischer, with much better bounds, settled many more cases. We use Skorohod's embedding to get simple upper and lower bounds from the Brownian analog; our upper bound is the one found by Christensen and Fischer in a different way. We use them first for many more examples, but the new idea is to use them algebraically in the tree, with feedback to get a sharper Value estimate near the border, to settle almost all n.
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