TU4.R2.1

Quantum Channel Simulation in Fidelity is no more difficult than State Splitting

Michael Xuan Cao, Rahul Jain, Marco Tomamichel, National University of Singapore, Singapore
Session:
Quantum Shannon Theory 3
Track:
6: Quantum Information and Coding Theory
Location:
Ypsilon I-II-III
Presentation Time:
Tue, 9 Jul, 16:05 - 16:25
Session Chair:
Mario Berta,
Abstract
Characterizing the minimal communication needed for quantum channel simulation is a fundamental task in the quantum information theory. In this paper, we show that, in fidelity, the quantum channel simulation can be directly achieved via quantum state splitting without using a technique known as the de~Finetti reduction, and thus provide a pair of tighter one-shot bounds. This opens up new potentials for higher-order analysis. Using the bounds, we also recover the quantum reverse Shannon theorem in a much simpler way.
Session TU4.R2
TU4.R2.1: Quantum Channel Simulation in Fidelity is no more difficult than State Splitting
Michael Xuan Cao, Rahul Jain, Marco Tomamichel, National University of Singapore, Singapore
TU4.R2.2: Quantum Soft Covering and Decoupling with Relative Entropy Criterion
Xingyi He, Touheed Atif, S. Sandeep Pradhan, University of Michigan, United States
TU4.R2.3: Entanglement sharing across a damping-dephasing channel
Vikesh Siddhu, IBM Research India and IBM Quantum, IBM T.J. Watson Research Center, Yorktown Heights, NY, India; Dina Abdelhadi, École polytechnique fédérale de Lausanne, Switzerland; Tomas Jochym-O’Connor, IBM Quantum, Almaden Research Center, San Jose, CA and IBM Quantum, IBM T.J. Watson Research Center, Yorktown Heights, NY, United States; John Smolin, IBM Quantum, IBM T.J. Watson Research Center, Yorktown Heights, United States
TU4.R2.4: Simulation of Separable Quantum Measurements on Bipartite States via Likelihood POVMs
Arun Padakandla, EURECOM, France; Naqueeb Warsi, Indian Statistical Institute, India
Resources
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