Hamiltonian simulation with nearly optimal dependence on spectral norm

Abstract

We present a quantum algorithm for approximating the real time evolution e-iHt of an arbitrary d-sparse Hamiltonian to error ε, given black-box access to the positions and b-bit values of its non-zero matrix entries. The complexity of our algorithm is O((td\|H\|1 → 2)1+o(1)/εo(1)) queries and a factor O(b) more gates, which is shown to be optimal up to subpolynomial factors through a matching query lower bound. This provides a polynomial speedup in sparsity for the common case where the spectral norm \|H\|\|H\|1 → 2 is known, and generalizes previous approaches which achieve optimal scaling, but with respect to more restrictive parameters. By exploiting knowledge of the spectral norm, our algorithm solves the black-box unitary implementation problem -- O(d1/2+o(1)) queries suffice to approximate any d-sparse unitary in the black-box setting, which matches the quantum search lower bound of (d) queries and improves upon prior art [Berry and Childs, QIP 2010] of O(d2/3) queries. Combined with known techniques, we also solve systems of sparse linear equations with condition number using O(( d)1+o(1)/εo(1)) queries, which is a quadratic improvement in sparsity.