Advances in Quantum Algorithms and Devices: Bounding Quantum Gate Error Rate Based on Reported Average Fidelity

July 21, 2015
Barry Sanders | University of Calgary

Remarkable experimental advances in quantum computing are exemplified by recent announcements of impressive gate fidelities exceeding 99.9% for single-qubit gates and exceeding 99% for two-qubit gates. These reported high numbers engender optimism that fault-tolerant quantum computing is within reach. Here we convert reported gate fidelity to a bound on worst case quantum gate error rate, which is appropriate to assess progress towards fault-tolerance targets and is greater by orders of magnitude. We prove that this bound scales optimally. Our work demonstrates the huge divide between reported gate fidelities and requisite gate performance.

- Jeff Running

Watch Next

Inside Microsoft Research Asia: Fundamental research powering the future of AI
December 16, 2025
Peng Cheng,

Baining Guo,

Changho Hwang

, et. al.
Data Formulator: Vibe with your data, in control
December 9, 2025
Karen Easterbrook,

Chenglong Wang
Accelerating MRI image reconstruction with Tyger
December 9, 2025
Karen Easterbrook,

Ilyana Rosenberg
Tool-space Interference: An emerging problem for LLM agents
December 9, 2025
Karen Easterbrook,

Tyler Payne
Publicly-verifiable elections
December 9, 2025
Karen Easterbrook,

Josh Benaloh
A brain-inspired agentic architecture to improve planning with LLMs
December 9, 2025
Karen Easterbrook,

Ida Momennejad
From Microfarms to the Moon: A Teen Innovator’s Journey in Robotics
December 9, 2025
Pranav Kumar Redlapalli
Leveraging Loanword Constraints for Improving Machine Translation in Low-resource Settings
November 25, 2025
Felermino Ali
Inside Azure Innovations with Mark Russinovich | Microsoft Ignite 2025
November 19, 2025
Mark Russinovich
Inside Azure innovations with Mark Russinovich | Microsoft Build 2025
May 20, 2025
Mark Russinovich