Saved in:
Bibliographic Details
Main Authors: Teegarden, Darrell, Casey, Allison, Serpa, F. Gino, Becker, Patrick, Brahme, Asmita, Kataria, Saanvi, Lopata, Paul
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2601.09943
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866909990885785600
author Teegarden, Darrell
Casey, Allison
Serpa, F. Gino
Becker, Patrick
Brahme, Asmita
Kataria, Saanvi
Lopata, Paul
author_facet Teegarden, Darrell
Casey, Allison
Serpa, F. Gino
Becker, Patrick
Brahme, Asmita
Kataria, Saanvi
Lopata, Paul
contents Quantum Computing (QC) has evolved from a few custom quantum computers, which were only accessible to their creators, to an array of commercial quantum computers that can be accessed on the cloud by anyone. Accessing these cloud quantum computers requires a complex chain of tools that facilitate connecting, programming, simulating algorithms, estimating resources, submitting quantum computing jobs, retrieving results, and more. Some steps in the chain are hardware dependent and subject to change as both hardware and software tools, such as available gate sets and optimizing compilers, evolve. Understanding the trade-offs inherent in this process is essential for evaluating the power and utility of quantum computers. ARLIS has been systematically investigating these environments to understand these complexities. The work presented here is a detailed summary of three months of using such quantum programming environments. We show metadata obtained from these environments, including the connection metrics to the different services, the execution of algorithms, the testing of the effects of varying the number of qubits, comparisons to simulations, execution times, and cost. Our objective is to provide concrete data and insights for those who are exploring the potential of quantum computing. It is not our objective to present any new algorithms or optimize performance on any particular machine or cloud platform; rather, this work is focused on providing a consistent view of a single algorithm executed using out-of-the-box settings and tools across machines, cloud platforms, and time. We present insights only available from these carefully curated data.
format Preprint
id arxiv_https___arxiv_org_abs_2601_09943
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Three Months in the Life of Cloud Quantum Computing
Teegarden, Darrell
Casey, Allison
Serpa, F. Gino
Becker, Patrick
Brahme, Asmita
Kataria, Saanvi
Lopata, Paul
Quantum Physics
Quantum Computing (QC) has evolved from a few custom quantum computers, which were only accessible to their creators, to an array of commercial quantum computers that can be accessed on the cloud by anyone. Accessing these cloud quantum computers requires a complex chain of tools that facilitate connecting, programming, simulating algorithms, estimating resources, submitting quantum computing jobs, retrieving results, and more. Some steps in the chain are hardware dependent and subject to change as both hardware and software tools, such as available gate sets and optimizing compilers, evolve. Understanding the trade-offs inherent in this process is essential for evaluating the power and utility of quantum computers. ARLIS has been systematically investigating these environments to understand these complexities. The work presented here is a detailed summary of three months of using such quantum programming environments. We show metadata obtained from these environments, including the connection metrics to the different services, the execution of algorithms, the testing of the effects of varying the number of qubits, comparisons to simulations, execution times, and cost. Our objective is to provide concrete data and insights for those who are exploring the potential of quantum computing. It is not our objective to present any new algorithms or optimize performance on any particular machine or cloud platform; rather, this work is focused on providing a consistent view of a single algorithm executed using out-of-the-box settings and tools across machines, cloud platforms, and time. We present insights only available from these carefully curated data.
title Three Months in the Life of Cloud Quantum Computing
topic Quantum Physics
url https://arxiv.org/abs/2601.09943