Toshinari Itoko scite author profile

We improve the quality of quantum circuits on superconducting quantum computing systems, as measured by the quantum volume (QV), with a combination of dynamical decoupling, compiler optimizations, shorter two-qubit gates, and excited state promoted readout. This result shows that the path to larger QV systems requires the simultaneous increase of coherence, control gate fidelities, measurement fidelities, and smarter software which takes into account hardware details, thereby demonstrating the need to continue to co-design the software and hardware stack for the foreseeable future.

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Qiskit: An Open-source Framework for Quantum Computing

Aleksandrowicz¹,

Alexander²,

Barkoutsos³

et al. 2019

274

166

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Artificial intelligence predicts the progression of diabetic kidney disease using big data machine learning

Miyamoto

Yoshimoto

Ono

et al. 2019

Sci Rep

150

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Artificial intelligence (AI) is expected to support clinical judgement in medicine. We constructed a new predictive model for diabetic kidney diseases (DKD) using AI, processing natural language and longitudinal data with big data machine learning, based on the electronic medical records (EMR) of 64,059 diabetes patients. AI extracted raw features from the previous 6 months as the reference period and selected 24 factors to find time series patterns relating to 6-month DKD aggravation, using a convolutional autoencoder. AI constructed the predictive model with 3,073 features, including time series data using logistic regression analysis. AI could predict DKD aggravation with 71% accuracy. Furthermore, the group with DKD aggravation had a significantly higher incidence of hemodialysis than the non-aggravation group, over 10 years (N = 2,900). The new predictive model by AI could detect progression of DKD and may contribute to more effective and accurate intervention to reduce hemodialysis.

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Optimization of quantum circuit mapping using gate transformation and commutation

et al. 2020

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This paper addresses quantum circuit mapping for Noisy Intermediate-Scale Quantum (NISQ) computers. Since NISQ computers constraint two-qubit operations on limited couplings, an input circuit must be transformed into an equivalent output circuit obeying the constraints. The transformation often requires additional gates that can affect the accuracy of running the circuit. Based upon a previous work of quantum circuit mapping that leverages gate commutation rules, this paper shows algorithms that utilize both transformation and commutation rules. Experiments on a standard benchmark dataset confirm the algorithms with more rules can find even better circuit mappings compared with the previously-known best algorithms.

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Demonstration of quantum volume 64 on a superconducting quantum computing system

Jurcevic¹,

Javadi-Abhari²,

Bishop³

et al. 2020

Preprint

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We improve the quality of quantum circuits on superconducting quantum computing systems, as measured by the quantum volume, with a combination of dynamical decoupling, compiler optimizations, shorter two-qubit gates, and excited state promoted readout. This result shows that the path to larger quantum volume systems requires the simultaneous increase of coherence, control gate fidelities, measurement fidelities, and smarter software which takes into account hardware details, thereby demonstrating the need to continue to co-design the software and hardware stack for the foreseeable future.

show abstract

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Toshinari Itoko

Demonstration of quantum volume 64 on a superconducting quantum computing system

Qiskit: An Open-source Framework for Quantum Computing

Artificial intelligence predicts the progression of diabetic kidney disease using big data machine learning

Optimization of quantum circuit mapping using gate transformation and commutation

Demonstration of quantum volume 64 on a superconducting quantum computing system

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