Weyl's Relations, Integrable Matrix Models and Quantum Computation

Abstract

Starting from a generalization of Weyl's relations in finite dimension N, we show that the Heisenberg commutation relations can be satisfied in a specific N-1 dimensional subspace, and display a linear map for projecting operators to this subspace. This setup is used to construct a hierarchy of parameter-dependent commuting matrices in N dimensions. This family of commuting matrices is then related to Type-1 matrices representing quantum integrable models. The commuting matrices find an interesting application in quantum computation, specifically in Grover's database search problem. Each member of the hierarchy serves as a candidate Hamiltonian for quantum adiabatic evolution and, in some cases, achieves higher fidelity than standard choices -- thus offering improved performance.