Abstract
We use Pontryagin's minimum principle to optimize variational quantum algorithms. We show that for a fixed computation time, the optimal evolution has a bang-bang (square pulse) form, both for closed and open quantum systems with Markovian decoherence. Our findings support the choice of evolution ansatz in the recently proposed Quantum Approximate Optimization Algorithm. Focusing on the Sherrington-Kirkpatrick spin-glass as an example, we find a system-size independent distribution of the duration of pulses, with characteristic time scale set by the inverse of the coupling constants in the Hamiltonian. The optimality of the bang-bang protocols and the characteristic time scale of the pulses provide an efficient parameterization of the protocol and inform the search for effective hybrid (classical and quantum) schemes for tackling combinatorial optimization problems. For the particular systems we study, we find numerically that the optimal nonadiabatic bang-bang protocols outperform conventional quantum annealing in the presence of weak white additive external noise and weak coupling to a thermal bath modeled with the Redfield master equation.
Highlights
Quantum annealing (QA) aims to solve computational problems by using a guided quantum drive
Using Pontryagin’s minimum principle of optimal control, we show that the optimal protocol for variational quantum algorithm (VQA) has a “bang-bang” form
We start by verifying for small system sizes and short annealing times that the optimal annealing protocol is bang-bang, by using a Metropolis Monte Carlo (MC) algorithm, which makes no assumptions about the nature of the protocol
Summary
Quantum annealing (QA) aims to solve computational problems by using a guided quantum drive. The adiabatic trajectory is not the only path for reaching the ground state of a final Hamiltonian that encodes the solution of the computational problem. VQA is essentially an adaptive feedback control [32,33] of a quantum system with the objective function encoding the solution of a computational problem; see Fig. 1(a). It utilizes a hybrid system composed of a classical computer that searches for the optimal variational protocol using measurements done on a quantum machine that generates the final states.
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