Litcius/Paper detail

Deep reinforcement learning for efficient measurement of quantum devices

V. Nguyen, S. B. Orbell, D. T. Lennon, H. Moon, F. Vigneau, L. C. Camenzind, L. Yu, D. M. Zumbühl, G. A. D. Briggs, M. A. Osborne, D. Sejdinovic, N. Ares

2021npj Quantum Information33 citationsDOIOpen Access PDF

Abstract

Abstract Deep reinforcement learning is an emerging machine-learning approach that can teach a computer to learn from their actions and rewards similar to the way humans learn from experience. It offers many advantages in automating decision processes to navigate large parameter spaces. This paper proposes an approach to the efficient measurement of quantum devices based on deep reinforcement learning. We focus on double quantum dot devices, demonstrating the fully automatic identification of specific transport features called bias triangles. Measurements targeting these features are difficult to automate, since bias triangles are found in otherwise featureless regions of the parameter space. Our algorithm identifies bias triangles in a mean time of <30 min, and sometimes as little as 1 min. This approach, based on dueling deep Q-networks, can be adapted to a broad range of devices and target transport features. This is a crucial demonstration of the utility of deep reinforcement learning for decision making in the measurement and operation of quantum devices.

Topics & Concepts

Reinforcement learningComputer scienceDeep learningQuantumArtificial intelligenceRange (aeronautics)Focus (optics)Quantum computerIdentification (biology)Measurement deviceOutcome (game theory)Measure (data warehouse)AlgorithmReinforcementTheoretical computer scienceComputer engineeringMachine learningQuantum Computing Algorithms and ArchitectureQuantum and electron transport phenomenaNeural Networks and Reservoir Computing