Paths Beyond Local Search: A Tight Bound for Randomized Fixed-Point Computation

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Abstract

In 1983, Aldous proved that randomization can speedup local search. For example, it reduces the query complexity of local search over grid \left[ {1:n} \right]^d from \Theta (n^{d - 1} ) to {\rm O}(d^{1/2} n^{d/2} ). It remains open whether randomization helps fixed-point computation. Inspired by the recent advances on the complexity of equilibrium computation, we solve this open problem by giving an asymptotically tight bound of (\Omega (n))^{d - 1} on the randomized query complexity for computing a fixed point of a discrete Brouwer function over grid \left[ {1:n} \right]^d Our result can be extended to the black-box query model for Sperner's Lemma in any dimension. It also yields a tight bound for the computation of d-dimensional approximate Brouwer fixed points as defined by Scarf and by Hirsch, Papadimitriou, and Vavasis. Since the randomized query complexity of global optimization over \left[ {1:n} \right]^d is \Theta (n^d ), the randomized query model over \left[ {1:n} \right]^d strictly separates these three important search problems: Global optimization is harder than fixed-point computation, and fixed-point computation is harder than local search. Our result indeed demonstrates that randomization does not help much in fixed-point computation in the black-box query model. Our randomized lower bound matches the deterministic complexity of this problem, which is \Theta (n^{d - 1} ).