Simulation of Non-Hermitian Hamiltonians with Bivariate Quantum Signal Processing
Abstract
We achieve query-optimal quantum simulations of non-Hermitian Hamiltonians Heff = HR + iHI, where HR is Hermitian and HI 0, using a bivariate extension of quantum signal processing (QSP) with non-commuting signal operators. The algorithm encodes the interaction-picture Dyson series as a polynomial on the bitorus, implemented through a structured multivariable QSP (M-QSP) circuit. A constant-ratio condition guarantees scalar angle-finding for M-QSP circuits with arbitrary non-commuting signal operators. A degree-preserving sum-of-squares spectral factorization permits scalar complementary polynomials in two variables. Angles are deterministically calculated in a classical precomputation step, running in O(dR · dI) classical operations. Operator norms αR\,,βI contribute additively with query complexity O((αR + βI)T + (1/)/(1/)) matching an information-theoretic lower bound in the separate-oracle model, where HR and HI are accessed through independent block encodings. The postselection success probability is e-2βI T\|e-iHeffT|ψ0\|2· (1 - O()), decomposing into a state-dependent factor \|e-iHeffT|ψ0\|2 from the intrinsic barrier and an e-2βI T overhead from polynomial block-encoding.
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