Tight inapproximability of max-LINSAT and implications for decoded quantum interferometry

Abstract

We establish tight inapproximability bounds for max-LINSAT, the problem of maximizing the number of satisfied linear constraints over the finite field Fq, where each constraint accepts r values. Specifically, we prove by a direct reduction from Hastad's theorem that no polynomial-time algorithm can exceed the random-assignment ratio r/q by any constant, assuming P ≠ NP. This threshold coincides with the /m 0 limit of the semicircle law governing decoded quantum interferometry (DQI), where is the decoding radius of the underlying code. Together, these observations delineate the boundary between worst-case hardness and potential quantum advantage, showing that any algorithm surpassing r/q must exploit instance structure beyond what is present in the hard instances produced by PCP reductions.

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