Fujitsu And RIKEN Develop Superconducting Quantum Computer At The RIKEN RQC-Fujitsu Collaboration Center

Fujitsu and RIKEN today announced the successful development of a new 64 qubit superconducting quantum computer at the RIKEN RQC-Fujitsu Collaboration Center. The new quantum computer leverages the technology developed by RIKEN and a consortium of joint research partners including Fujitsu for Japan’s first superconducting quantum computer, which was first revealed to the public in March 2023.

Accompanying this announcement, Fujitsu and RIKEN further revealed the launch of a platform for hybrid quantum computing, which combines the computing power of the newly developed 64 qubit superconducting quantum computer with one of the world's largest (1) 40 qubit quantum computer simulators developed by Fujitsu. Fujitsu and RIKEN will provide the new platform to companies and research institutions that are conducting joint research with Fujitsu and RIKEN from October 5, 2023.

The new hybrid platform enables easy comparison of calculation results of noisy intermediate-scale quantum (NISQ) computers against error-free results from quantum simulators, contributing to accelerated research in areas including performance evaluation of error mitigation algorithms in quantum applications.

Fujitsu and RIKEN are further developing a hybrid quantum algorithm that links superconducting quantum computing with high-performance computing (HPC). By linking a quantum computer with a quantum simulator that runs on an HPC, Fujitsu and RIKEN have succeeded in developing a hybrid quantum algorithm that enables quantum chemistry calculations with greater accuracy than conventional algorithms (CCSD(T)) (2). The two partners plan to include this algorithm in the new platform.

Moving forward, Fujitsu and RIKEN will promote the development of technologies including high-density implementation to realize a 1,000 qubit superconducting quantum computer, as well as technologies to achieve more precise quantum gate operations.

Fujitsu and RIKEN will further provide quantum computing and quantum simulation resources to customers for applications in various fields including finance and drug discovery through this platform and promote R&D activities for quantum applications through joint research to accelerate the practical application of both quantum computing hardware and software.

Leading the way to the age of practical quantum computing

The development of various quantum computing architectures has been progressing at high speed in recent years. The creation of reliable computing results with quantum computers, however, represents an ongoing challenge, as current NISQ systems are still suffering from computing errors due to noise in the surrounding environment.

Experts anticipate that the realization of a practical fault-tolerant quantum computer (FTQC) that can provide reliable, accurate results, will take a decade or longer. In addition, the simultaneous development of quantum applications to realize the practical use of quantum computers once a FTQC is available represents another priority.

Quantum simulators, which can digitally imitate quantum computation, provide a vital bridge toward the development of practical, fault-tolerant quantum computing. Unlike current quantum computers, quantum simulators can perform error-free and long-step (quantum-like) computations as they do not rely on error-prone qubits. However, as quantum simulators only digitally reproduce quantum computation on classical computers, they cannot realize actual quantum acceleration, an expected benefit of practical quantum computers.

To address these issues, Fujitsu and RIKEN have launched a new hybrid quantum computing platform that combines the advantages of superconducting quantum computers and quantum simulators, ultimately contributing to further usage of the superconducting quantum computer developed at the RIKEN RQC-Fujitsu Collaboration Center and the development of new quantum applications.

About the new 64 qubit superconducting quantum computer developed at the RIKEN RQC-Fujitsu Collaboration Center

The new 64 qubit superconducting quantum computer utilized in the new hybrid quantum computing platform leverages the technology of Japan’s first superconducting quantum computer announced by RIKEN in March 2023 as part of the Japanese Ministry of Education, Culture, Sports, Science and Technology’s Quantum Leap Flagship Program (MEXT Q-LEAP) (Team Leader: Yasunobu Nakamura; Grant No. JPMXS 0118068682), and has been developed at the RIKEN RQC-Fujitsu Collaboration Center in cooperation with Nippon Telegraph and Telephone Corporation (NTT) (3). The computer includes an integrated 64 superconducting qubit chip (a central element for the computing functions of quantum computers) and uses a vertical wiring scheme similar to that of RIKEN’s quantum computer, making it scalable for future expansion. It further leverages qubit control software built by NTT to achieve high-precision control of qubits. The new superconducting quantum computer enables calculations of ideally up to 2 64 quantum superposition and entanglement states, which is expected to enable calculations on a scale that have been difficult to achieve with classical computers.

R&D of hybrid quantum algorithms

Fujitsu and RIKEN are further developing hybrid quantum algorithms that link quantum computing and HPC to contribute to the solution of problems in various industries. As part of their current joint research, the two parties have developed a hybrid quantum algorithm in which a quantum simulator performs part of the calculation of an algorithm for a quantum computer. The algorithm enables the calculation of large molecules with high accuracy using quantum algorithms and Density Matrix Embedding Theory (DMET), a quantum chemistry calculation method to divide large molecules into multiple small fragments. Fujitsu and RIKEN applied this algorithm to the calculation of the ground state energy of the H12 molecule (a chain molecule consisting of twelve hydrogen atoms) and combined it with AI-based quantum computation correction technology to mitigate the effects of noise in quantum computers. In this way, Fujitsu and RIKEN for the first time confirmed that energy calculations can be performed with higher accuracy than existing classical algorithms (CCSD(T)). In addition to providing this technology on the new hybrid quantum computing platform in the future, Fujitsu will further work toward the realization of a computing workload broker, an AI-based software that automatically selects from different computing resources and algorithms to offer the optimal solution to customers’ problems.

About the new hybrid quantum computing platform

The new platform is implemented as a scalable cloud architecture by utilizing cloud services such as serverless computing service AWS Lambda provided by Amazon Web Services (4). It offers companies and research institutions collaborating with Fujitsu and RIKEN a seamless access environment for both the quantum computer and quantum simulator via common APIs.

The two parties anticipate that the new platform will enable flexible switching between quantum computing and quantum simulation necessary for the development of hybrid algorithms that use both classical and quantum computers, such as the Variational Quantum Eigensolver (VQE) algorithm for molecular energy calculation in quantum chemistry or quantum machine learning algorithms in finance. Fujitsu and RIKEN further expect that the new platform can be linked to external quantum chemistry calculation libraries in the future.

The new hybrid platform enables easy comparison of calculation results of noisy intermediate-scale quantum (NISQ) computers against error-free results from quantum simulators, contributing to accelerated research in areas including performance evaluation of error mitigation algorithms in quantum applications.

Fujitsu and RIKEN are further developing a hybrid quantum algorithm that links superconducting quantum computing with high-performance computing (HPC). By linking a quantum computer with a quantum simulator that runs on an HPC, Fujitsu and RIKEN have succeeded in developing a hybrid quantum algorithm that enables quantum chemistry calculations with greater accuracy than conventional algorithms (CCSD(T)) (2). The two partners plan to include this algorithm in the new platform.

Moving forward, Fujitsu and RIKEN will promote the development of technologies including high-density implementation to realize a 1,000 qubit superconducting quantum computer, as well as technologies to achieve more precise quantum gate operations.

Fujitsu and RIKEN will further provide quantum computing and quantum simulation resources to customers for applications in various fields including finance and drug discovery through this platform and promote R&D activities for quantum applications through joint research to accelerate the practical application of both quantum computing hardware and software.

Leading the way to the age of practical quantum computing

The development of various quantum computing architectures has been progressing at high speed in recent years. The creation of reliable computing results with quantum computers, however, represents an ongoing challenge, as current NISQ systems are still suffering from computing errors due to noise in the surrounding environment.

Experts anticipate that the realization of a practical fault-tolerant quantum computer (FTQC) that can provide reliable, accurate results, will take a decade or longer. In addition, the simultaneous development of quantum applications to realize the practical use of quantum computers once a FTQC is available represents another priority.

Quantum simulators, which can digitally imitate quantum computation, provide a vital bridge toward the development of practical, fault-tolerant quantum computing. Unlike current quantum computers, quantum simulators can perform error-free and long-step (quantum-like) computations as they do not rely on error-prone qubits. However, as quantum simulators only digitally reproduce quantum computation on classical computers, they cannot realize actual quantum acceleration, an expected benefit of practical quantum computers.

To address these issues, Fujitsu and RIKEN have launched a new hybrid quantum computing platform that combines the advantages of superconducting quantum computers and quantum simulators, ultimately contributing to further usage of the superconducting quantum computer developed at the RIKEN RQC-Fujitsu Collaboration Center and the development of new quantum applications.

About the new 64 qubit superconducting quantum computer developed at the RIKEN RQC-Fujitsu Collaboration Center

The new 64 qubit superconducting quantum computer utilized in the new hybrid quantum computing platform leverages the technology of Japan’s first superconducting quantum computer announced by RIKEN in March 2023 as part of the Japanese Ministry of Education, Culture, Sports, Science and Technology’s Quantum Leap Flagship Program (MEXT Q-LEAP) (Team Leader: Yasunobu Nakamura; Grant No. JPMXS 0118068682), and has been developed at the RIKEN RQC-Fujitsu Collaboration Center in cooperation with Nippon Telegraph and Telephone Corporation (NTT) (3). The computer includes an integrated 64 superconducting qubit chip (a central element for the computing functions of quantum computers) and uses a vertical wiring scheme similar to that of RIKEN’s quantum computer, making it scalable for future expansion. It further leverages qubit control software built by NTT to achieve high-precision control of qubits. The new superconducting quantum computer enables calculations of ideally up to 2 64 quantum superposition and entanglement states, which is expected to enable calculations on a scale that have been difficult to achieve with classical computers.

R&D of hybrid quantum algorithms

Fujitsu and RIKEN are further developing hybrid quantum algorithms that link quantum computing and HPC to contribute to the solution of problems in various industries. As part of their current joint research, the two parties have developed a hybrid quantum algorithm in which a quantum simulator performs part of the calculation of an algorithm for a quantum computer. The algorithm enables the calculation of large molecules with high accuracy using quantum algorithms and Density Matrix Embedding Theory (DMET), a quantum chemistry calculation method to divide large molecules into multiple small fragments. Fujitsu and RIKEN applied this algorithm to the calculation of the ground state energy of the H12 molecule (a chain molecule consisting of twelve hydrogen atoms) and combined it with AI-based quantum computation correction technology to mitigate the effects of noise in quantum computers. In this way, Fujitsu and RIKEN for the first time confirmed that energy calculations can be performed with higher accuracy than existing classical algorithms (CCSD(T)). In addition to providing this technology on the new hybrid quantum computing platform in the future, Fujitsu will further work toward the realization of a computing workload broker, an AI-based software that automatically selects from different computing resources and algorithms to offer the optimal solution to customers’ problems.

About the new hybrid quantum computing platform

The new platform is implemented as a scalable cloud architecture by utilizing cloud services such as serverless computing service AWS Lambda provided by Amazon Web Services (4). It offers companies and research institutions collaborating with Fujitsu and RIKEN a seamless access environment for both the quantum computer and quantum simulator via common APIs.

The two parties anticipate that the new platform will enable flexible switching between quantum computing and quantum simulation necessary for the development of hybrid algorithms that use both classical and quantum computers, such as the Variational Quantum Eigensolver (VQE) algorithm for molecular energy calculation in quantum chemistry or quantum machine learning algorithms in finance. Fujitsu and RIKEN further expect that the new platform can be linked to external quantum chemistry calculation libraries in the future.

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