3 code implementations • 13 Jan 2020 • Peter J. Karalekas, Nikolas A. Tezak, Eric C. Peterson, Colm A. Ryan, Marcus P. da Silva, Robert S. Smith
In order to support near-term applications of quantum computing, a new compute paradigm has emerged--the quantum-classical cloud--in which quantum computers (QPUs) work in tandem with classical computers (CPUs) via a shared cloud infrastructure.
Quantum Physics Emerging Technologies
no code implementations • 9 Dec 2019 • Deanna M. Abrams, Nicolas Didier, Blake R. Johnson, Marcus P. da Silva, Colm A. Ryan
More expressive gate sets can significantly reduce the gate depth of generic circuits.
Quantum Physics
1 code implementation • 15 Dec 2017 • J. S. Otterbach, R. Manenti, N. Alidoust, A. Bestwick, M. Block, B. Bloom, S. Caldwell, N. Didier, E. Schuyler Fried, S. Hong, P. Karalekas, C. B. Osborn, A. Papageorge, E. C. Peterson, G. Prawiroatmodjo, N. Rubin, Colm A. Ryan, D. Scarabelli, M. Scheer, E. A. Sete, P. Sivarajah, Robert S. Smith, A. Staley, N. Tezak, W. J. Zeng, A. Hudson, Blake R. Johnson, M. Reagor, M. P. da Silva, C. Rigetti
Machine learning techniques have led to broad adoption of a statistical model of computing.
Quantum Physics
no code implementations • 1 Nov 2012 • Seth T. Merkel, Jay M. Gambetta, John A. Smolin, S. Poletto, A. D. Córcoles, B. R. Johnson, Colm A. Ryan, M. Steffen
The essential ingredient is to define a likelihood function that assumes nothing about the gates used for preparation and measurement.
Quantum Physics
