Programmable generation of arbitrary continuous-variable anharmonicities and nonlinear couplings

TL;DR

This paper introduces TGIFS, a hybrid CV-DV method for synthesizing arbitrary non-Gaussian operations, enabling complex anharmonicities and multi-mode couplings in continuous-variable quantum systems.

Contribution

It presents a novel Fourier synthesis approach that extends bosonic quantum signal processing to multi-mode systems, broadening the scope of CV quantum simulations.

Findings

Enables implementation of arbitrary non-Gaussian operations in CV systems.

Allows simulation of complex phenomena like lattice gauge theories and quantum chaos.

Provides a new toolbox for CV circuit compilation.

Abstract

Harmonic oscillators are promising continuous-variable (CV) quantum resources because their infinite-dimensional Hilbert spaces allow for resource-efficient quantum computing and simulation. To reach their full potential, CV platforms need to be able to efficiently implement non-Gaussian operations. Bosonic quantum-signal-processing schemes have emerged as attractive methods to construct arbitrary non-Gaussian operations; however, these schemes are restricted to single modes, i.e., the implementation of anharmonic potentials. Here, we introduce trigonometric-gate-implemented Fourier synthesis (TGIFS), a method for implementing arbitrary non-Gaussian operations applicable to both single- and multi-mode systems, allowing the generation of both anharmonicities and nonlinear multi-mode couplings. TGIFS synthesizes a target Hamiltonian by decomposing it into a Fourier series whose terms are implemented via bosonic quantum signal processing, which uses a discrete-variable (DV) system to induce a nonlinearity in the CV system. Our hybrid CV-DV protocol allows for the direct simulation of a broad range of CV phenomena (such as those in lattice gauge theory, chemical dynamics, and quantum chaos) and provides a richer toolbox for CV circuit compilation.