Induced Quantum Divergence: A New Lens on Communication and Source Coding

TL;DR

This paper introduces the induced divergence, a new quantum divergence measure that simplifies analysis and yields tighter bounds in quantum communication and state redistribution tasks.

Contribution

It proposes a novel quantum divergence based on a parent relative entropy, extending the position-based decoding lemma and improving bounds in quantum information protocols.

Findings

Improves lower bounds on distillable communication rate.

Provides sharper bounds on quantum state redistribution costs.

Refines analysis of single-shot quantum information protocols.

Abstract

This paper introduces the induced divergence, a new quantum divergence measure that replaces the hypothesis testing divergence in position-based decoding, simplifying the analysis of quantum communication and state redistribution while yielding tighter achievability bounds. Derived from a parent quantum relative entropy, it retains key properties such as data processing inequality and L\"owner monotonicity. Like the hypothesis testing divergence, it depends on a smoothing parameter and interpolates between the parent relative entropy (as the smoothing parameter approaches one) and the min-relative entropy (as it approaches zero), the latter holding when applied to the sandwiched R\'enyi relative entropy of order $\alpha\in[0,2]$. This framework refines the position-based decoding lemma, extending its applicability to a broader class of states and improving decoding success probabilities. Two key applications are considered: classical communication over quantum channels, where the induced divergence improves lower bounds on the distillable communication rate, and quantum state redistribution, where it leads to sharper bounds on communication costs. These results provide new insights into fundamental single-shot quantum information protocols and enhance existing analytical techniques.