Steve Flammia: Sparse Quantum Codes with (Almost) Good Distance

Channel:
United States QuICS
Subscribers:
2,450
Published on ● Video Link: https://www.youtube.com/watch?v=upjxgei0ER4


Duration: 53:21
194 views
0

Steve Flammia (University of Sydney)
Sparse Quantum Codes with (Almost) Good Distance
QuICS Workshop on the Frontiers of Quantum Information and Computer Science (September 29, 2015)

Sparse error correcting codes, where every parity check involves only a small (constant) number of bits, have become ubiquitous because they can be generated easily and decoded efficiently, even when a constant fraction of bits are in error.

These properties do not carry over easily to the quantum case, however. In this talk, I will discuss a family of quantum sparse codes that can correct a nearly constant fraction of errors. The codes are sparse enough that each syndrome measurement involves just three qubits at a time. The construction is very general, and proceeds by transforming any other quantum code into a sparse one. The price we pay for this transformation is some extra qubits and that the new code is a more general subsystem code. If time permits, I will also discuss the connection between these new codes and the physics of self-correcting quantum memories.

Joint work with D. Bacon, A. Harrow, and J. Shi (arXiv:1411.3334).



Other Videos By QuICS


2016-10-20Akihiro Mizutani: Towards Secure QKD with Testable Assumptions on Modulation Devices
2016-10-20Thomas Jennewein: Implementing Free-Space QKD Systems Between Moving Platforms
2015-10-06Daniel Nagaj: Very Entangled Spin Chains
2015-10-06Martin Roetteler: Reversible Circuit Compilation with Space Constraints
2015-10-06Daniel Gottesman: Stabilizer Codes for Prime Power Qudits
2015-10-06Norbert Schuch: Topological Phase Transitions in Tensor Networks: A Holographic Perspective
2015-10-06Debbie Leung: On the Power of PPT-preserving and Non-signalling Codes
2015-10-06Aram Harrow: Quantum Adiabatic Optimization Versus Quantum Monte Carlo
2015-10-06Michael Bremner: Average-case Complexity Vs. Approx. Simulation of Commuting Quantum Computations
2015-10-06Chris Monroe: Time to Build a Real Quantum Computer
2015-10-06Steve Flammia: Sparse Quantum Codes with (Almost) Good Distance
2015-10-06Robin Kothari: Quantum Linear Systems Algorithms with Exponentially Improved Dependence on Precision
2015-10-06Eddie Farhi: A Quantum Approximate Optimization Algorithm
2015-10-06Seth Lloyd: Universal Deep Quantum Learning
2015-10-06Mark Zhandry: Quantum Query Solvability: A Refinement of Quantum Query Complexity and Applications
2015-10-06Jeongwan Haah: Optimal Tomography of Quantum States
2015-10-06David Gosset: Gapped and Gapless Phases of Frustration-free Spin-1/2 chains
2015-10-06Beni Yoshida: Classifying Fault-tolerant Logical Gates by Group Cohomology (or SPT Phases)
2015-10-06Mark Zhandry: Quantum Query Solvability: A Refinement of Quantum Query Complexity and Applications
2015-10-06Mario Szegedy: Issues Concerning the Area Law in Quantum Physics
2015-10-06Lorenza Viola: Fixed-point Engineering in Quasi-local Open-system Dynamics