Efficient Quantum Access Model for Sparse Structured Matrices using Linear Combination of Things (2507.03714v1)

Abstract: We develop a novel approach for Linear combination of unitaries (LCU) type decomposition for structured sparse matrices. Such matrices frequently arise during numerical solution of partial differential equations which are ubiquitous in science and engineering. LCU is a versatile quantum algorithmic primitive that plays an important role in context of both variational quantum algorithms (VQA) and fully fault-tolerant ones, and has been applied to a diverse range of problems. Conventionally, Pauli basis is used for LCU decomposition, which however in worst case can result in number of LCU terms that scale quadratically with respect to the matrix size. We show that by using an alternate basis one can better exploit the sparsity and underlying structure of matrix leading to number of tensor product terms which scale only logarithmically with respect to the matrix size. We develop numerical and semi-analytical approaches for computing sigma basis decomposition for an arbitrary matrix. Given this new basis is comprised of non-unitary operators, we employ the concept of unitary completion to design efficient quantum circuits for evaluation of the expectation values of operators composed of tensor product of elements from sigma basis which can be used for cost function evaluation in VQAs. We also develop an approach for block encoding of arbitrary operator given its decomposition in sigma basis which could be used in variety of fully fault-tolerant algorithms. We compare our approach with other related concepts in the literature including unitary dilation and provide numerical illustrations on several PDE examples.