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Autori principali: Pope, Jeremie, Ghosh, Swaroop
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2509.19241
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author Pope, Jeremie
Ghosh, Swaroop
author_facet Pope, Jeremie
Ghosh, Swaroop
contents Improvements to the functionality of modern Noisy Intermediate-Scale Quantum (NISQ) computers have coincided with an increase in the total number of physical qubits. Quantum programmers do not commonly design circuits that directly utilize these qubits; instead, they rely on various software suites to algorithmically transpile the circuit into one compatible with a target machine's architecture. For connectivity-constrained superconducting architectures in particular, the chosen syntheses, layout, and routing algorithms used to transpile a circuit drastically change the average utilization patterns of physical qubits. In this paper, we analyze average qubit utilization of a quantum hardware as a means to identify how various transpiler configurations change utilization patterns. We present the preliminary results of this analysis using IBM's 27-qubit Falcon R4 architecture on the Qiskit platform for a subset of qubits, gate distributions, and optimization configurations. We found a persistent bias towards trivial mapping, which can be addressed through increased optimization provided that the overall utilization of an architecture remains below a certain threshold. As a result, some qubits are overused whereas other remain underused. The implication of our study are many-fold namely, (a) potential reduction in calibration overhead by focusing on overused qubits, (b) refining optimization, mapping and routing algorithms to maximize the hardware utilization and (c) pricing underused qubits at low rate to motivate their usage and improve hardware throughput (applicable in multi-tenant environments).
format Preprint
id arxiv_https___arxiv_org_abs_2509_19241
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Not All Qubits are Utilized Equally
Pope, Jeremie
Ghosh, Swaroop
Quantum Physics
Emerging Technologies
Improvements to the functionality of modern Noisy Intermediate-Scale Quantum (NISQ) computers have coincided with an increase in the total number of physical qubits. Quantum programmers do not commonly design circuits that directly utilize these qubits; instead, they rely on various software suites to algorithmically transpile the circuit into one compatible with a target machine's architecture. For connectivity-constrained superconducting architectures in particular, the chosen syntheses, layout, and routing algorithms used to transpile a circuit drastically change the average utilization patterns of physical qubits. In this paper, we analyze average qubit utilization of a quantum hardware as a means to identify how various transpiler configurations change utilization patterns. We present the preliminary results of this analysis using IBM's 27-qubit Falcon R4 architecture on the Qiskit platform for a subset of qubits, gate distributions, and optimization configurations. We found a persistent bias towards trivial mapping, which can be addressed through increased optimization provided that the overall utilization of an architecture remains below a certain threshold. As a result, some qubits are overused whereas other remain underused. The implication of our study are many-fold namely, (a) potential reduction in calibration overhead by focusing on overused qubits, (b) refining optimization, mapping and routing algorithms to maximize the hardware utilization and (c) pricing underused qubits at low rate to motivate their usage and improve hardware throughput (applicable in multi-tenant environments).
title Not All Qubits are Utilized Equally
topic Quantum Physics
Emerging Technologies
url https://arxiv.org/abs/2509.19241