A Performance Model for Estimating the Cost of Scaling to Practical Quantum Advantage

Results of cost analysis for the Hubbard model.

Abstract

We present a simple performance model to estimate the qubit-count and runtime associated with large-scale error-corrected quantum computations. Our estimates extrapolate current usage costs of quantum computers and show that computing the ground state of the 2D Hubbard model, which is widely believed to be an early candidate for practical quantum advantage, could start at a million dollars. Our model shows a clear cost advantage of up to four orders of magnitude for quantum processors based on superconducting technology compared to ion trap devices. Our analysis shows that usage costs, while substantial, will not necessarily block the road to practical quantum advantage. Furthermore, the combined effects of algorithmic improvements, more efficient error correction codes, and R&D cost amortization are likely to lead to orders of magnitude reductions in cost.

Publication
SC-W ‘23: Proceedings of the SC ‘23 Workshops of The International Conference on High Performance Computing, Network, Storage, and Analysis
Daan Camps
Daan Camps
Researcher in Advanced Technologies Group

My research interests include quantum algorithms, numerical linear algebra, tensor factorization methods and machine learning. I’m particularly interested in studying the interface between HPC and quantum computing.

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