Hamiltonian Simulation by Qubitization

Abstract

We present the problem of approximating the time-evolution operator e-iHt to error ε, where the Hamiltonian H=( G|I)U(|GI) is the projection of a unitary oracle U onto the state |G created by another unitary oracle. Our algorithm solves this with a query complexity O(t+(1/ε)) to both oracles that is optimal with respect to all parameters in both the asymptotic and non-asymptotic regime, and also with low overhead, using at most two additional ancilla qubits. This approach to Hamiltonian simulation subsumes important prior art considering Hamiltonians which are d-sparse or a linear combination of unitaries, leading to significant improvements in space and gate complexity, such as a quadratic speed-up for precision simulations. It also motivates useful new instances, such as where H is a density matrix. A key technical result is `qubitization', which uses the controlled version of these oracles to embed any H in an invariant SU(2) subspace. A large class of operator functions of H can then be computed with optimal query complexity, of which e-iHt is a special case.