Simple, Reliable, and Noise-Resilient Continuous-Variable Quantum State Tomography with Convex Optimization
Journal article, 2022

Precise reconstruction of unknown quantum states from measurement data, a process commonly called quantum state tomography, is a crucial component in the development of quantum informa-tion processing technologies. Many different tomography methods have been proposed over the years. Maximum-likelihood estimation is a prominent example, being the most popular method for a long period of time. Recently, more advanced neural-network methods have started to emerge. Here, we go back to basics and present a method for continuous-variable state reconstruction that is both conceptually and prac-tically simple, based on convex optimization. Convex optimization has been used for process tomography and qubit-state tomography, but seems to have been overlooked for continuous-variable quantum-state tomography. We demonstrate high-fidelity reconstruction of an underlying state from data corrupted by thermal noise and imperfect detection, for both homodyne and heterodyne measurements. A major advan-tage over other methods is that convex optimization algorithms are guaranteed to converge to the optimal solution.

Author

Ingrid Strandberg

Chalmers, Microtechnology and Nanoscience (MC2), Quantum Technology

Physical Review Applied

2331-7019 (eISSN)

Vol. 18 4 044041

Areas of Advance

Nanoscience and Nanotechnology

Subject Categories

Probability Theory and Statistics

Control Engineering

Signal Processing

DOI

10.1103/PhysRevApplied.18.044041

More information

Latest update

10/25/2023