Quantum Neuromorphic Computing with Reservoir Computing Networks

Ghosh, Sanjib; Nakajima, Kohei; Krisnanda, Tanjung; Fujii, Keisuke; Liew, Timothy Chi Hin

doi:10.1002/qute.202100053

Cited by 35 publications

(19 citation statements)

References 144 publications

(174 reference statements)

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“…Many types of PRCs have recently been proposed. Their physical resources are widely diverse, varying from photonics [6] and spintronics [7], nanomaterials, [8] quantum [9,10], and solid-state devices [11] to mechanics [12] and biological materials [13]. Among the others, nanomaterials have the ability to form complex networks and are expected to realize highly integrated RC chips.…”

Section: Introductionmentioning

confidence: 99%

Performance of reservoir computing in a random network of single-walled carbon nanotubes complexed with polyoxometalate

Akai‐Kasaya

Takeshima

Kan

et al. 2022

Neuromorph. Comput. Eng.

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Molecular neuromorphic devices are composed of a random and extremely dense network of single-walled carbon nanotubes (SWNTs) complexed with polyoxometalate (POM). Such devices are expected to have the rudimentary ability of reservoir computing (RC), which utilizes signal response dynamics and a certain degree of network complexity. In this study, we performed RC using multiple signals collected from a SWNT/POM random network. The signals showed a nonlinear response with wide diversity originating from the network complexity. The performance of RC was evaluated for various tasks such as waveform reconstruction, a nonlinear autoregressive model, and memory capacity. The obtained results indicated its high capability as a nonlinear dynamical system, capable of information processing incorporated into edge computing in future technologies.

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Section: Introductionmentioning

confidence: 99%

Performance of reservoir computing in a random network of single-walled carbon nanotubes complexed with polyoxometalate

Akai‐Kasaya

Takeshima

Kan

et al. 2022

Neuromorph. Comput. Eng.

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“…In contrast, a quantum reservoir computer, which is a form of quantum neural network, can operate even with uncontrolled connections [389] . This is a huge advantage for physical implementation [390,391] . Here, exciton polaritons can be an excellent platform to realize a quantum reservoir computer as a hardware.…”

Section: Discussionmentioning

confidence: 99%

Microcavity exciton polaritons at room temperature

Ghosh

Zhao

et al. 2022

Photonics Insights

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The quest for realizing novel fundamental physical effects and practical applications in ambient conditions has led to tremendous interest in microcavity exciton polaritons working in the strong coupling regime at room temperature. In the past few decades, a wide range of novel semiconductor systems supporting robust exciton polaritons have emerged, which has led to the realization of various fascinating phenomena and practical applications. This paper aims to review recent theoretical and experimental developments of exciton polaritons operating at room temperature, and includes a comprehensive theoretical background, descriptions of intriguing phenomena observed in various physical systems, as well as accounts of optoelectronic applications. Specifically, an in-depth review of physical systems achieving room temperature exciton polaritons will be presented, including the early development of ZnO and GaN microcavities and other emerging systems such as organics, halide perovskite semiconductors, carbon nanotubes, and transition metal dichalcogenides. Finally, a perspective of outlooking future developments will be elaborated.

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“…Quantum computers are beginning to reach a level at which their output states are too complex to be analyzed by classical means 1 , suggesting that machine learning techniques which directly process quantum data are expected to become an increasingly important tool to efficiently characterize and benchmark quantum hardware. Examples of specific applications thereof include the principal component analysis of density matrices 21 , quantum autoencoders 22 – 24 , the certification of Hamiltonian dynamics 25 , 26 , and the detection of entanglement correlations in quantum many-body states 10 , 11 , 27 – 29 .…”

Section: Introductionmentioning

confidence: 99%

Realizing quantum convolutional neural networks on a superconducting quantum processor to recognize quantum phases

et al. 2022

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Quantum computing crucially relies on the ability to efficiently characterize the quantum states output by quantum hardware. Conventional methods which probe these states through direct measurements and classically computed correlations become computationally expensive when increasing the system size. Quantum neural networks tailored to recognize specific features of quantum states by combining unitary operations, measurements and feedforward promise to require fewer measurements and to tolerate errors. Here, we realize a quantum convolutional neural network (QCNN) on a 7-qubit superconducting quantum processor to identify symmetry-protected topological (SPT) phases of a spin model characterized by a non-zero string order parameter. We benchmark the performance of the QCNN based on approximate ground states of a family of cluster-Ising Hamiltonians which we prepare using a hardware-efficient, low-depth state preparation circuit. We find that, despite being composed of finite-fidelity gates itself, the QCNN recognizes the topological phase with higher fidelity than direct measurements of the string order parameter for the prepared states.

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Quantum Neuromorphic Computing with Reservoir Computing Networks

Cited by 35 publications

References 144 publications

Performance of reservoir computing in a random network of single-walled carbon nanotubes complexed with polyoxometalate

Performance of reservoir computing in a random network of single-walled carbon nanotubes complexed with polyoxometalate

Microcavity exciton polaritons at room temperature

Realizing quantum convolutional neural networks on a superconducting quantum processor to recognize quantum phases

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