Computational Supremacy of Quantum Eigensolver by Extension of Optimized Binary Configurations

Abstract

We developed a quantum eigensolver (QE) which is based on an extension of optimized binary configurations measured by quantum annealing (QA) on a D-Wave Quantum Annealer (D-Wave QA). This approach performs iterative QA measurements to optimize the eigenstates without the derivation of a classical computer. The computational cost is η M L for full eigenvalues E and of the Hamiltonian H of size L × L, where M and η are the number of QA measurements required to reach the converged and the total annealing time of many QA shots, respectively. Unlike the exact diagonalized (ED) algorithm with L3 iterations on a classical computer, the computation cost is not significantly affected by L and M because η represents a very short time within 10-2 seconds on the D-Wave QA. We selected the tight-binding H that contains the exact E values of all energy states in two systems with metallic and insulating phases. We confirmed that the proposed QE algorithm provides exact solutions within the errors of 5 × 10-3. The QE algorithm will not only show computational supremacy over the ED approach on a classical computer but will also be widely used for various applications such as material and drug design.