ARQUIN: Architectures for Multinode Superconducting Quantum Computers

James Ang; Gabriella Carini; Yanzhu Chen; Isaac Chuang; Michael Demarco; Sophia Economou; Alec Eickbusch; Andrei Faraon; Kai Mei Fu; Steven Girvin; Michael Hatridge; Andrew Houck; Paul Hilaire; Kevin Krsulich; Ang Li; Chenxu Liu; Yuan Liu; Margaret Martonosi; David McKay; Jim Misewich; Mark Ritter; Robert Schoelkopf; Samuel Stein; Sara Sussman; Hong Tang; Wei Tang; Teague Tomesh; Norm Tubman; Chen Wang; Nathan Wiebe; Yongxin Yao; Dillon Yost; Yiyu Zhou

doi:10.1145/3674151

ARQUIN: Architectures for Multinode Superconducting Quantum Computers

James Ang, Gabriella Carini, Yanzhu Chen, Isaac Chuang, Michael Demarco, Sophia Economou, Alec Eickbusch, Andrei Faraon, Kai Mei Fu, Steven Girvin, Michael Hatridge, Andrew Houck, Paul Hilaire, Kevin Krsulich, Ang Li, Chenxu Liu, Yuan Liu, Margaret Martonosi, David McKay, Jim MisewichMark Ritter, Robert Schoelkopf, Samuel Stein, Sara Sussman, Hong Tang, Wei Tang, Teague Tomesh, Norm Tubman, Chen Wang, Nathan Wiebe, Yongxin Yao, Dillon Yost, Yiyu Zhou

Research output: Contribution to journal › Article › peer-review

11 Scopus citations

Abstract

Many proposals to scale quantum technology rely on modular or distributed designs wherein individual quantum processors, called nodes, are linked together to form one large multinode quantum computer (MNQC). One scalable method to construct an MNQC is using superconducting quantum systems with optical interconnects. However, internode gates in these systems may be two to three orders of magnitude noisier and slower than local operations. Surmounting the limitations of internode gates will require improvements in entanglement generation, use of entanglement distillation, and optimized software and compilers. Still, it remains unclear what performance is possible with current hardware and what performance algorithms require. In this article, we employ a systems analysis approach to quantify overall MNQC performance in terms of hardware models of internode links, entanglement distillation, and local architecture. We show how to navigate tradeoffs in entanglement generation and distillation in the context of algorithm performance, lay out how compilers and software should balance between local and internode gates, and discuss when noisy quantum internode links have an advantage over purely classical links. We find that a factor of 10–100× better link performance is required and introduce a research roadmap for the co-design of hardware and software towards the realization of early MNQCs. While we focus on superconducting devices with optical interconnects, our approach is general across MNQC implementations.

Original language	English (US)
Article number	19
Journal	ACM Transactions on Quantum Computing
Volume	5
Issue number	3
DOIs	https://doi.org/10.1145/3674151
State	Published - Sep 19 2024

All Science Journal Classification (ASJC) codes

Computational Theory and Mathematics
Computer Science (miscellaneous)
Theoretical Computer Science
Statistical and Nonlinear Physics

Keywords

Quantum computing
distributed quantum computing
multinode quantum computing
quantum computing architecture
transduction

Access to Document

10.1145/3674151

Cite this

Ang, J., Carini, G., Chen, Y., Chuang, I., Demarco, M., Economou, S., Eickbusch, A., Faraon, A., Fu, K. M., Girvin, S., Hatridge, M., Houck, A., Hilaire, P., Krsulich, K., Li, A., Liu, C., Liu, Y., Martonosi, M., McKay, D., ... Zhou, Y. (2024). ARQUIN: Architectures for Multinode Superconducting Quantum Computers. ACM Transactions on Quantum Computing, 5(3), Article 19. https://doi.org/10.1145/3674151

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title = "ARQUIN: Architectures for Multinode Superconducting Quantum Computers",

abstract = "Many proposals to scale quantum technology rely on modular or distributed designs wherein individual quantum processors, called nodes, are linked together to form one large multinode quantum computer (MNQC). One scalable method to construct an MNQC is using superconducting quantum systems with optical interconnects. However, internode gates in these systems may be two to three orders of magnitude noisier and slower than local operations. Surmounting the limitations of internode gates will require improvements in entanglement generation, use of entanglement distillation, and optimized software and compilers. Still, it remains unclear what performance is possible with current hardware and what performance algorithms require. In this article, we employ a systems analysis approach to quantify overall MNQC performance in terms of hardware models of internode links, entanglement distillation, and local architecture. We show how to navigate tradeoffs in entanglement generation and distillation in the context of algorithm performance, lay out how compilers and software should balance between local and internode gates, and discuss when noisy quantum internode links have an advantage over purely classical links. We find that a factor of 10–100× better link performance is required and introduce a research roadmap for the co-design of hardware and software towards the realization of early MNQCs. While we focus on superconducting devices with optical interconnects, our approach is general across MNQC implementations.",

keywords = "Quantum computing, distributed quantum computing, multinode quantum computing, quantum computing architecture, transduction",

author = "James Ang and Gabriella Carini and Yanzhu Chen and Isaac Chuang and Michael Demarco and Sophia Economou and Alec Eickbusch and Andrei Faraon and Fu, \{Kai Mei\} and Steven Girvin and Michael Hatridge and Andrew Houck and Paul Hilaire and Kevin Krsulich and Ang Li and Chenxu Liu and Yuan Liu and Margaret Martonosi and David McKay and Jim Misewich and Mark Ritter and Robert Schoelkopf and Samuel Stein and Sara Sussman and Hong Tang and Wei Tang and Teague Tomesh and Norm Tubman and Chen Wang and Nathan Wiebe and Yongxin Yao and Dillon Yost and Yiyu Zhou",

note = "Publisher Copyright: {\textcopyright} 2024 Copyright held by the owner/author(s). Publication rights licensed to ACM.",

year = "2024",

month = sep,

day = "19",

doi = "10.1145/3674151",

language = "English (US)",

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Ang, J, Carini, G, Chen, Y, Chuang, I, Demarco, M, Economou, S, Eickbusch, A, Faraon, A, Fu, KM, Girvin, S, Hatridge, M, Houck, A, Hilaire, P, Krsulich, K, Li, A, Liu, C, Liu, Y, Martonosi, M, McKay, D, Misewich, J, Ritter, M, Schoelkopf, R, Stein, S, Sussman, S, Tang, H, Tang, W, Tomesh, T, Tubman, N, Wang, C, Wiebe, N, Yao, Y, Yost, D & Zhou, Y 2024, 'ARQUIN: Architectures for Multinode Superconducting Quantum Computers', ACM Transactions on Quantum Computing, vol. 5, no. 3, 19. https://doi.org/10.1145/3674151

TY - JOUR

T1 - ARQUIN

T2 - Architectures for Multinode Superconducting Quantum Computers

AU - Ang, James

AU - Carini, Gabriella

AU - Chen, Yanzhu

AU - Chuang, Isaac

AU - Demarco, Michael

AU - Economou, Sophia

AU - Eickbusch, Alec

AU - Faraon, Andrei

AU - Fu, Kai Mei

AU - Girvin, Steven

AU - Hatridge, Michael

AU - Houck, Andrew

AU - Hilaire, Paul

AU - Krsulich, Kevin

AU - Li, Ang

AU - Liu, Chenxu

AU - Liu, Yuan

AU - Martonosi, Margaret

AU - McKay, David

AU - Misewich, Jim

AU - Ritter, Mark

AU - Schoelkopf, Robert

AU - Stein, Samuel

AU - Sussman, Sara

AU - Tang, Hong

AU - Tang, Wei

AU - Tomesh, Teague

AU - Tubman, Norm

AU - Wang, Chen

AU - Wiebe, Nathan

AU - Yao, Yongxin

AU - Yost, Dillon

AU - Zhou, Yiyu

PY - 2024/9/19

Y1 - 2024/9/19

N2 - Many proposals to scale quantum technology rely on modular or distributed designs wherein individual quantum processors, called nodes, are linked together to form one large multinode quantum computer (MNQC). One scalable method to construct an MNQC is using superconducting quantum systems with optical interconnects. However, internode gates in these systems may be two to three orders of magnitude noisier and slower than local operations. Surmounting the limitations of internode gates will require improvements in entanglement generation, use of entanglement distillation, and optimized software and compilers. Still, it remains unclear what performance is possible with current hardware and what performance algorithms require. In this article, we employ a systems analysis approach to quantify overall MNQC performance in terms of hardware models of internode links, entanglement distillation, and local architecture. We show how to navigate tradeoffs in entanglement generation and distillation in the context of algorithm performance, lay out how compilers and software should balance between local and internode gates, and discuss when noisy quantum internode links have an advantage over purely classical links. We find that a factor of 10–100× better link performance is required and introduce a research roadmap for the co-design of hardware and software towards the realization of early MNQCs. While we focus on superconducting devices with optical interconnects, our approach is general across MNQC implementations.

AB - Many proposals to scale quantum technology rely on modular or distributed designs wherein individual quantum processors, called nodes, are linked together to form one large multinode quantum computer (MNQC). One scalable method to construct an MNQC is using superconducting quantum systems with optical interconnects. However, internode gates in these systems may be two to three orders of magnitude noisier and slower than local operations. Surmounting the limitations of internode gates will require improvements in entanglement generation, use of entanglement distillation, and optimized software and compilers. Still, it remains unclear what performance is possible with current hardware and what performance algorithms require. In this article, we employ a systems analysis approach to quantify overall MNQC performance in terms of hardware models of internode links, entanglement distillation, and local architecture. We show how to navigate tradeoffs in entanglement generation and distillation in the context of algorithm performance, lay out how compilers and software should balance between local and internode gates, and discuss when noisy quantum internode links have an advantage over purely classical links. We find that a factor of 10–100× better link performance is required and introduce a research roadmap for the co-design of hardware and software towards the realization of early MNQCs. While we focus on superconducting devices with optical interconnects, our approach is general across MNQC implementations.

KW - Quantum computing

KW - distributed quantum computing

KW - multinode quantum computing

KW - quantum computing architecture

KW - transduction

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ARQUIN: Architectures for Multinode Superconducting Quantum Computers

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