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Main Authors: Proctor, Timothy, Tran, Anh, Liu, Xingxin, Dhumuntarao, Aditya, Seritan, Stefan, Green, Alaina, Linke, Norbert M
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2504.12575
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author Proctor, Timothy
Tran, Anh
Liu, Xingxin
Dhumuntarao, Aditya
Seritan, Stefan
Green, Alaina
Linke, Norbert M
author_facet Proctor, Timothy
Tran, Anh
Liu, Xingxin
Dhumuntarao, Aditya
Seritan, Stefan
Green, Alaina
Linke, Norbert M
contents Benchmarks that concisely summarize the performance of many-qubit quantum computers are essential for measuring progress towards the goal of useful quantum computation. In this work, we present a benchmarking framework that is based on quantifying how a quantum computer's performance on quantum circuits varies as a function of features of those circuits, such as circuit depth, width, two-qubit gate density, problem input size, or algorithmic depth. Our featuremetric benchmarking framework generalizes volumetric benchmarking -- a widely-used methodology that quantifies performance versus circuit width and depth -- and we show that it enables richer and more faithful models of quantum computer performance. We demonstrate featuremetric benchmarking with example benchmarks run on IBM Q and IonQ systems of up to 27 qubits, and we show how to produce performance summaries from the data using Gaussian process regression. Our data analysis methods are also of interest in the special case of volumetric benchmarking, as they enable the creation of intuitive two-dimensional capability regions using data from few circuits.
format Preprint
id arxiv_https___arxiv_org_abs_2504_12575
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Featuremetric benchmarking: Quantum computer benchmarks based on circuit features
Proctor, Timothy
Tran, Anh
Liu, Xingxin
Dhumuntarao, Aditya
Seritan, Stefan
Green, Alaina
Linke, Norbert M
Quantum Physics
Machine Learning
Benchmarks that concisely summarize the performance of many-qubit quantum computers are essential for measuring progress towards the goal of useful quantum computation. In this work, we present a benchmarking framework that is based on quantifying how a quantum computer's performance on quantum circuits varies as a function of features of those circuits, such as circuit depth, width, two-qubit gate density, problem input size, or algorithmic depth. Our featuremetric benchmarking framework generalizes volumetric benchmarking -- a widely-used methodology that quantifies performance versus circuit width and depth -- and we show that it enables richer and more faithful models of quantum computer performance. We demonstrate featuremetric benchmarking with example benchmarks run on IBM Q and IonQ systems of up to 27 qubits, and we show how to produce performance summaries from the data using Gaussian process regression. Our data analysis methods are also of interest in the special case of volumetric benchmarking, as they enable the creation of intuitive two-dimensional capability regions using data from few circuits.
title Featuremetric benchmarking: Quantum computer benchmarks based on circuit features
topic Quantum Physics
Machine Learning
url https://arxiv.org/abs/2504.12575