Negative Quasi-Probability and Contextuality in Classical Simulations of Quantum Processes
นินนาท แดงเนียม
Center for Quantum Information and Control
Mahidol University, 29 December 2014
University of New Mexico
Quantum Supremacy
Post-1994 Universal quantum computation, DQC1, IQP computing, Boson-Sampling...
Quantum Supremacy
What separates classical mundanity and quantum supremacy?
Important for both foundational and practical reasons
- Exponentially many complex numbers?
- Interference?
Quantum Supremacy
- Negative probability?
- Nonlocality?
- Entanglement?
Discord?
Entanglement is Not Enough
Matrix product state formalism enables simulation of states with little entanglement.
Entanglement is a stronger-than-classical correlation studied intensively since the advent of quantum information science.
Entanglement is Not Enough
Teleportation circuit (with input states in the computational basis) can be simulated efficiently on a classical computer!
Entanglement is Not Enough
Strong simulation of qudit Clifford circuits
- Heisenberg-Weyl operators
- Clifford operators = Normalizer of Weyl-Heisenberg operators
- Stabilizer states = Orbit of the computational basis state under Clifford operations
Entanglement is Not Enough
Specifying (qubit) stabilizer states only requires
bits
Stabilizer generators
Each Weyl-Heisenberg operator
Entanglement is Not Enough
Physics explanation: there is a hidden variable representation in which stabilizer circuits do not generate "negative probability"
Quasi-Probability Representations
A QPR consists of a frame F, a dual frame D (Hermitian (possibly overcomplete) bases) and a 1-1 map from operators to distributions
so that the Born rule becomes the law of total probability
D can be defined by the reconstruction formula
Allow classical simulation techniques when W is non-negative!
Quasi-Probability Representations
The discrete Wigner representation
- Hudson's theorem: a pure state is non-negative if and only if it is a stabilizer state.
- Clifford operations act as permutations, in particular they preserve positivity.
- There are doubly exponentially more stabilizer states in n d-dimensional Wigner representation than in a single d^n-dimensional Wigner representation
Simulation of Clifford circuits with positive Wigner representation
Veitch et al., Negative Quasi-Probability as a Resource for Quantum Computation
Weak simulation
Simulation of Clifford circuits with positive Wigner representation
Veitch et al., Negative Quasi-Probability as a Resource for Quantum Computation
Contextuality
Mermin-Peres square
- Measurement contextuality
- Preparation contextuality = Occurrence of negative quasi-probability
Take-Home Messages
Negative Wigner representation hence contextuality is necessary for universal quantum computation in the circuit model.
Phase space techniques and quantum foundations extend and explain results in quantum information science.
Quantum information science provides operational meaning of "quantumness" in negative Wigner representation in quantum optics
Related Works
- Measurement-based quantum computation
- Similar result in rebit (real qubit) quantum computation
- Continuous class of simulatable states?
Thank You!
Negative quasi-probability and contextuality in classical simulations of quantum processes
By Ninnat Dangniam
Negative quasi-probability and contextuality in classical simulations of quantum processes
CRUQI, Physics department, Mahidol University, 29 Dec 2014, Special seminar in quantum optics and quantum information
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