Machine learning enables completely automatic tuning of a quantum device faster than human experts

Moon, Hyun-Joo; Lennon, Dominic T.; Kirkpatrick, James; Esbroeck, N.M. van; Camenzind, Leon C.; Yu, Liuqi; Vigneau, Florian; Zumbühl, Dominik M.; Briggs, G. Andrew D.; Osborne, Michael A.; Sejdinović, Dino; Laird, E.; Ares, Natalia

doi:10.1038/s41467-020-17835-9

Cited by 71 publications

(62 citation statements)

References 23 publications

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“…1a. We ran the DRL algorithm in two different regions of gate voltage space, I and II, which are centred in the coordinates from our super coarse tuning algorithm 36 . We ran the algorithm ten times in each region.…”

Section: Resultsmentioning

confidence: 99%

“…However, quantum dot devices are subject to variability, and many measurements are required to characterise each device and find the conditions for qubit operation. Machine learning has been used to automate the tuning of devices from scratch, known as super coarse tuning [34][35][36] , the identification of single or double quantum dot regimes, known as coarse tuning 37,38 , and the tuning of the inter-dot tunnel couplings and other device parameters, referred to as fine tuning [39][40][41] .…”

Section: Introductionmentioning

confidence: 99%

“…1b. A super coarse tuning algorithm allows us to choose a set of promising gate voltages and focus on exploring the current map as a function of two gates, for example the two barrier gates 36 . This is the gate voltage space our DRL agent will navigate.…”

Section: Introductionmentioning

confidence: 99%

“…Our DRL algorithm takes the gate voltage coordinates found by our previous super coarse tuning algorithm 36 , and divides the gate voltage space corresponding to the unmeasured current map into blocks. The size of the blocks is chosen such that they can fully contain bias triangles (blocks are shown as a white grid in Fig.…”

Section: Introductionmentioning

confidence: 99%

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Deep reinforcement learning for efficient measurement of quantum devices

et al. 2021

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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.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Deep reinforcement learning for efficient measurement of quantum devices

et al. 2021

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“…Overall, our results suggest that large quantum dots may prove useful as tunable inter-qubit couplers to realize two-dimensional qubit networks. However, the large number of gate voltages that need to be tuned and synchronized is currently challenging for our manual tuneup procedures, and motivates the development of superhuman automation 36 .…”

Section: Discussionmentioning

confidence: 99%

Simultaneous operation of singlet-triplet qubits

Fedele

Chatterjee

Kuemmeth

2019

2019 Silicon Nanoelectronics Workshop (SNW)

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Evolutionary Computation for Adaptive Quantum Device Design

et al. 2021

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As noisy intermediate‐scale quantum (NISQ) devices grow in number of qubits, determining good or even adequate parameter configurations for a given application, or for device calibration, becomes a cumbersome task. An evolutionary algorithm is presented here which allows for the automatic tuning of the parameters of any arrangement of coupled qubits, to perform a given task with high fidelity. The algorithm's use is exemplified with the generation of schemes for the distribution of quantum states and the design of multi‐qubit gates. The algorithm is demonstrated to converge very rapidly, yielding unforeseeable designs of quantum devices that perform their required tasks with excellent fidelities. Given these promising results, practical scalability, and application versatility, the approach has the potential to become a powerful technique to aid the design and calibration of NISQ devices.

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Machine learning enables completely automatic tuning of a quantum device faster than human experts

Cited by 71 publications

References 23 publications

Deep reinforcement learning for efficient measurement of quantum devices

Deep reinforcement learning for efficient measurement of quantum devices

Simultaneous operation of singlet-triplet qubits

Evolutionary Computation for Adaptive Quantum Device Design

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