Snapshot-QAOA: Extending QAOA to Quantum Hamiltonian Simulation

We present Snapshot-QAOA, a variation of the Quantum Approximate Optimization Algorithm (QAOA) that finds approximate minimum energy eigenstates of a large set of quantum Hamiltonians. Traditionally, QAOA targets the task of approximately solving combinatorial optimization problems. Snapshot-QAOA enables a significant expansion of the use case space for QAOA to more general quantum Hamiltonians, where the goal is to approximate the ground-state. Snapshot-QAOA retains the desirable variational-algorithm qualities of QAOA such as a small parameter count and relatively shallow circuit depth. Snapshot-QAOA is thus a better trainable alternative to the (Near Intermediate-Scale Quantum) NISQ-era Variational Quantum Eigensolver (VQE) algorithm, while retaining a significant circuit-depth advantage over the (Quantum Error Corrected) QEC-era Quantum Phase Estimation (QPE) algorithm. Our fundamental approach is inspired by the idea of Trotterization of a continuous-time linear adiabatic anneal schedule. Snapshot-QAOA restricts the QAOA evolution to not phasing out the mixing Hamiltonian completely at the end of the evolution, instead evolving only a partial typical linear QAOA schedule, thus creating a type of snapshot of the typical QAOA evolution. In this way, the cost of the quantum Hamiltonian is encoded by the phase separator to address the diagonal terms in the problem Hamiltonian and by the mixer to address the non-diagonal terms in the problem Hamiltonian. We focus on QAOA with the transverse field mixer, and thus simulations of quantum Hamiltonians that contain single-site Pauli-X terms. By measuring the expectation value of the system in both X and Z-basis, we can estimate the ground-state energy of transverse field quantum Hamiltonians. The accuracy of ground-state energy finding with snapshot-QAOA is evaluated using extensive numerical simulations on a 16 qubit J1-J2 frustrated transverse field Ising model.