Clifford Gate Optimisation and T Gate Scheduling: Using Queueing Models for Topological Assemblies
Abstract
Clifford gates play a role in the optimisation of Clifford+T circuits. Reducing the count and the depth of Clifford gates, as well as the optimal scheduling of T gates, influence the hardware and the time costs of executing quantum circuits. This work focuses on circuits protected by the surface quantum error-correcting code. The result of compiling a quantum circuit for the surface code is called a topological assembly. We use queuing theory to model a part of the compiled assemblies, evaluate the models, and make the empiric observation that at least for certain Clifford+T circuits (e.g. adders), the assembly's execution time does not increase when the available hardware is restricted. This is an interesting property, because it shows that T gate scheduling and Clifford gate optimisation have the potential to save both hardware and execution time.
Cite
@article{arxiv.1906.06400,
title = {Clifford Gate Optimisation and T Gate Scheduling: Using Queueing Models for Topological Assemblies},
author = {Alexandru Paler and Robert Basmadjian},
journal= {arXiv preprint arXiv:1906.06400},
year = {2019}
}
Comments
accepted at 15th IEEE / ACM International Symposium on Nanoscale Architectures, 17-19 July, 2019, Qingdao, China