Ancilla-Depth Phase Diagrams for Quantum Reference-Frame Comparison
Abstract
Comparing two noisy quantum reference frames as statistical experiments depends on the dimension of the ancillary memory available to the decision procedure. For finite-dimensional channels A and B with invertible A, we show that exact simulation of all measurements assisted by an r-dimensional ancilla is equivalent to r-positivity of the unique factor Gamma = BA-1. The hierarchy can be realized by physical channel pairs: every unital, trace-preserving map that is k-positive but not (k+1)-positive embeds as the factor between the channels Da and Gamma composed with Da on an exact interval determined by the smallest Choi eigenvalue. For depolarizing source and target channels Da and Db, including negative and singular source parameters, the phase boundary is Da r Db -1/(dr-1) ≤ b/a ≤ 1 for a≠ 0. We derive closed formulas for the restricted level-r deficiency and for the distance to every physical post-processing, δphys(Dba)=(1-1/d2)dist(b,Ia), where Ia=conv\a,-a/(d2-1)\. The largest physical conversion cost hidden from all tests through level k is (d-k)/[d(d2-1)]. An untouched m-level spectator changes the first detecting external level from k+1 to k/m+1. A transpose--depolarizing construction shows that the separation is not confined to depolarizing factors. The results quantify the distinction between ancilla-restricted statistical simulation and implementation by a single quantum channel.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.