Faster quantum linear system solver beyond the condition number

Abstract

The spectral condition number is a widely adopted measure of worst-case cost for quantum linear system solvers. Yet it can significantly overestimate the actual runtime for a typical problem instance. We present two quantum algorithms that produce the normalized solution |x of linear system Ax=| b to accuracy ε with complexity independent of the condition number κ= A-1. We focus on the standard input model where A is accessed through a block encoding and | b is prepared by a unitary. But we also introduce an affine dilation model that encodes A and | b jointly, allowing further refinements of the query complexity. Our truncation-based solver makes an optimal number of queries to | b and O(κeffpolylog(κeffε)) queries to A. We prove a family of upper bounds on the effective condition number, including κeff≤(A A)-t/2|x1/tε1/t for positive even integer t and κeff≤ A-1(A A)-(t-1)/2|x1/tε1/t for positive odd t, overcoming the κ-barrier. Our filtering-based solver is extremely simple with a favorable runtime prefactor. In particular, the solver has query complexity 6 A-1|xε(1ε) to leading order when the solution norm is known. We then present a similarly simple solution norm estimator with the same asymptotic cost up to logarithmic factors. Our quantum linear system solvers thus substantially improve a recent algorithm of Li, enabling faster quantum linear system solving beyond the condition number.

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