Mark Howard: Application of a resource theory for magic states to fault-tolerant quantum computing

Channel:
Microsoft Research
Subscribers:
345,000
Published on ● Video Link: https://www.youtube.com/watch?v=uMGaXEx5p3I


Duration: 36:02
947 views
19

Motivated by their necessity for most fault-tolerant quantum computation schemes, we formulate a resource theory for magic states. We first show that robustness of magic is a well-behaved magic monotone that operationally quantifies the classical simulation overhead for a Gottesman-Knill type scheme using ancillary magic states. Our framework subsequently finds immediate application in the task of synthesizing non-Clifford gates using magic states. When magic states are interspersed with Clifford gates, Pauli measurements and stabilizer ancillas - the most general synthesis scenario - then the class of synthesizable unitaries is hard to characterize. Our techniques can place non-trivial lower bounds on the number of magic states required for implementing a given target unitary. Guided by these results we have found new and optimal examples of such synthesis.



Other Videos By Microsoft Research


2017-01-31A complete characterization of unitary quantum space
2017-01-31David Reutter: Biunitary constructions in quantum information
2017-01-31Fernando Brandao: Quantum speed-ups for semidefinite programming
2017-01-31Joseph M. Renes: Belief propagation decoding of quantum channels by passing quantum messages
2017-01-31Anupam Prakash: Quantum recommendation systems
2017-01-31Garnet Chan: Simulating quantum systems on classical computers
2017-01-31Rigetti Computing Software Demo: Forest
2017-01-31Frank Verstraete: The entanglement of distillation for gauge theories
2017-01-31Aram Harrow: Sequential measurements, disturbance and property testing
2017-01-31Carlo Sparaciari: A resource theory for work and heat
2017-01-31Mark Howard: Application of a resource theory for magic states to fault-tolerant quantum computing
2017-01-31John Preskill: Quantum information and spacetime (II)
2017-01-31Anurag Anshu: Separations in communication complexity using cheat sheets and information complexity
2017-01-31Florian Speelman: Quantum homomorphic encryption for polynomial-sized circuits (Best Student Paper)
2017-01-31John Preskill: Quantum information and spacetime (I)
2017-01-31Earl Campbell: Unifying gate-synthesis and magic state distillation
2017-01-31Zhengfeng Ji: Compression of quantum multi-prover interactive proofs
2017-01-31Fang Song: Zero-knowledge proof systems for QMA
2017-01-31Norbert Schuch: Matrix product states and tensor networks (I)
2017-01-31Norbert Schuch: Matrix product states and tensor networks (II)
2017-01-31Steve Flammia: Debugging the next generation of quantum devices (I)


Tags:
microsoft research