New Algebrization Barriers to Circuit Lower Bounds via Communication Complexity of Missing-String

Abstract

The *algebrization barrier*, proposed by Aaronson and Wigderson (STOC '08, ToCT '09), captures the limitations of many complexity-theoretic techniques based on arithmetization. Notably, several circuit lower bounds that overcome the relativization barrier (Buhrman--Fortnow--Thierauf, CCC '98; Vinodchandran, TCS '05; Santhanam, STOC '07, SICOMP '09) remain subject to the algebrization barrier. In this work, we establish several new algebrization barriers to circuit lower bounds by studying the communication complexity of the following problem, called XOR-Missing-String: For m < 2n/2, Alice gets a list of m strings x1, …, xm∈\0, 1\n, Bob gets a list of m strings y1, …, ym∈\0, 1\n, and the goal is to output a string s∈\0, 1\n that is not equal to xi yj for any i, j∈ [m]. 1. We construct an oracle A1 and its multilinear extension A1 such that PostBPEA1 has linear-size A1-oracle circuits on infinitely many input lengths. 2. We construct an oracle A2 and its multilinear extension A2 such that BPEA2 has linear-size A2-oracle circuits on all input lengths. 3. Finally, we study algebrization barriers to circuit lower bounds for MAE. Buhrman, Fortnow, and Thierauf proved a *sub-half-exponential* circuit lower bound for MAE via algebrizing techniques. Toward understanding whether the half-exponential bound can be improved, we define a natural subclass of MAE that includes their hard MAE language, and prove the following result: For every *super-half-exponential* function h(n), we construct an oracle A3 and its multilinear extension A3 such that this natural subclass of MA EA3 has h(n)-size A3-oracle circuits on all input lengths.

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