Composite QDrift-Product Formulas for Quantum and Classical Simulations in Real and Imaginary Time

Abstract

Recent work has shown that it can be advantageous to implement a composite channel that partitions the Hamiltonian H for a given simulation problem into subsets A and B such that H=A+B, where the terms in A are simulated with a Trotter-Suzuki channel and the B terms are randomly sampled via the QDrift algorithm. Here we show that this approach holds in imaginary time, making it a candidate classical algorithm for quantum Monte-Carlo calculations. We upper-bound the induced Schatten-1 1 norm on both imaginary-time QDrift and Composite channels. Another recent result demonstrated that simulations of Hamiltonians containing geometrically-local interactions for systems defined on finite lattices can be improved by decomposing H into subsets that contain only terms supported on that subset of the lattice using a Lieb-Robinson argument. Here, we provide a quantum algorithm by unifying this result with the composite approach into ``local composite channels" and we upper bound the diamond distance. We provide exact numerical simulations of algorithmic cost by counting the number of gates of the form e-iHj t and e-Hj β to meet a certain error tolerance ε. We show constant factor advantages for a variety of interesting Hamiltonians, the maximum of which is a ≈ 20 fold speedup that occurs for a simulation of Jellium.