Counting gates, moving qubits: Evaluating the execution cost of quantum circuits

Rodney Van Meter

doi:10.1109/ATS.2012.67

Counting gates, moving qubits: Evaluating the execution cost of quantum circuits

Rodney Van Meter

Faculty of Environment and Information Studies

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

1 Citation (Scopus)

Abstract

Quantum algorithms can be written down in several forms, one of the most common is the quantum circuit representation using discrete gates. The challenge in assessing the computational cost then becomes counting those gates, with realistic costs assigned to each gate. Moreover, interacting pairs of qubits inside most quantum computers will require moving qubits. In many architectures, this will involve cellular automaton-like swapping of qubits. In general, the depth will be described in number of quantum error correction (QEC) cycles, while the total cost will be space-time ''volume'' consisting of the number of qubits involved over that set of QEC cycles. This implies that accurate estimates can be made only in the context of a particular architecture and error correction mechanism.

Original language	English
Title of host publication	Proceedings - 2012 IEEE 21st Asian Test Symposium, ATS 2012
Pages	50-54
Number of pages	5
DOIs	https://doi.org/10.1109/ATS.2012.67
Publication status	Published - 2012
Event	2012 IEEE 21st Asian Test Symposium, ATS 2012 - Niigatta, Japan Duration: 2012 Nov 19 → 2012 Nov 22

Publication series

Name	Proceedings of the Asian Test Symposium
ISSN (Print)	1081-7735

Other

Other	2012 IEEE 21st Asian Test Symposium, ATS 2012
Country/Territory	Japan
City	Niigatta
Period	12/11/19 → 12/11/22

Keywords

Compilation
Optimization
Quantum computation

ASJC Scopus subject areas

Electrical and Electronic Engineering

Access to Document

10.1109/ATS.2012.67

Cite this

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title = "Counting gates, moving qubits: Evaluating the execution cost of quantum circuits",

abstract = "Quantum algorithms can be written down in several forms, one of the most common is the quantum circuit representation using discrete gates. The challenge in assessing the computational cost then becomes counting those gates, with realistic costs assigned to each gate. Moreover, interacting pairs of qubits inside most quantum computers will require moving qubits. In many architectures, this will involve cellular automaton-like swapping of qubits. In general, the depth will be described in number of quantum error correction (QEC) cycles, while the total cost will be space-time ''volume'' consisting of the number of qubits involved over that set of QEC cycles. This implies that accurate estimates can be made only in the context of a particular architecture and error correction mechanism.",

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N2 - Quantum algorithms can be written down in several forms, one of the most common is the quantum circuit representation using discrete gates. The challenge in assessing the computational cost then becomes counting those gates, with realistic costs assigned to each gate. Moreover, interacting pairs of qubits inside most quantum computers will require moving qubits. In many architectures, this will involve cellular automaton-like swapping of qubits. In general, the depth will be described in number of quantum error correction (QEC) cycles, while the total cost will be space-time ''volume'' consisting of the number of qubits involved over that set of QEC cycles. This implies that accurate estimates can be made only in the context of a particular architecture and error correction mechanism.

AB - Quantum algorithms can be written down in several forms, one of the most common is the quantum circuit representation using discrete gates. The challenge in assessing the computational cost then becomes counting those gates, with realistic costs assigned to each gate. Moreover, interacting pairs of qubits inside most quantum computers will require moving qubits. In many architectures, this will involve cellular automaton-like swapping of qubits. In general, the depth will be described in number of quantum error correction (QEC) cycles, while the total cost will be space-time ''volume'' consisting of the number of qubits involved over that set of QEC cycles. This implies that accurate estimates can be made only in the context of a particular architecture and error correction mechanism.

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KW - Optimization

KW - Quantum computation

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M3 - Conference contribution

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BT - Proceedings - 2012 IEEE 21st Asian Test Symposium, ATS 2012

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ER -

Counting gates, moving qubits: Evaluating the execution cost of quantum circuits

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Keywords

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