Title :
A practical architecture for reliable quantum computers
Author :
Oskin, Mark ; Chong, Frederic T. ; Chuang, Isaac L.
Author_Institution :
Washington Univ., Seattle, WA, USA
fDate :
1/1/2002 12:00:00 AM
Abstract :
Quantum computation has advanced to the point where system-level solutions can help close the gap between emerging quantum technologies and real-world computing requirements. Empirical studies of practical quantum architectures are just beginning to appear in the literature. Elementary architectural concepts are still lacking: How do we provide quantum storage, data paths, classical control circuits, parallelism, and system integration? And, crucially, how can we design architectures to reduce error-correction overhead? The authors describe a proposed architecture that uses code teleportation, quantum memory refresh units, dynamic compilation of quantum programs, and scalable error correction to achieve system-level efficiencies. They assert that their work indicates the underlying technology´s reliability is crucial; practical architectures will require quantum technologies with error rates between 10-6 and 10-9
Keywords :
computer architecture; program compilers; quantum computing; reliability; storage management; architectural concepts; classical control circuits; code teleportation; data paths; dynamic compilation; error rates; error-correction overhead; parallelism; practical architecture; quantum architectures; quantum computation; quantum memory refresh units; quantum programs; quantum storage; quantum technologies; real-world computing requirements; reliability; reliable quantum computers; scalable error correction; system integration; system-level solutions; Circuit faults; Computer architecture; Engineering drawings; Error correction codes; Laboratories; Quantum computing; Quantum mechanics; Reliability engineering; Scalability; Systems engineering and theory;
