What question did this study set out to answer?

To explore how symmetry-controlled protocol design affects parameter identifiability in dynamical-decoupling noise spectroscopy.

June 3, 2026Open Access

Symmetry-Controlled Rank Transition in Dynamical-Decoupling Identifiability

Key Points

To explore how symmetry-controlled protocol design affects parameter identifiability in dynamical-decoupling noise spectroscopy.
Geometric formulation of parameter identifiability introduced using projected Fisher information.
Numerical results evaluated to demonstrate rank transitions in observable projectors related to symmetry control.
Exact kernel equivalence established for identifying unidentifiable parameter directions.
Identifiable directions emerge beyond the observable horizon defined by symmetry-controlled design.
Numerical evaluations showed a unique correspondence between lifted Fisher mode and release of symmetry-protected null direction.

Abstract

We present a geometric formulation of parameter identifiability in dynamical-decoupling noise spectroscopy based on the projected Fisher information. The key result is an exact kernel equivalence, ker⁡Iθ, eff=ker⁡ (PobsKθ) I, ₄₅₅ = (P₎₁ₒK_) kerIθ, eff=ker (PobsKθ), which identifies unidentifiable parameter directions as those invisible to the observable protocol subspace. We show that symmetry-controlled protocol design induces rank transitions in the observable projector, defining an observable horizon where new identifiable directions can emerge. Numerical results demonstrate that the lifted Fisher mode corresponds uniquely to the release of a symmetry-protected null direction. The framework separates geometric identifiability (rank structure) from quantitative sensitivity, providing a model-independent link between control symmetry and estimation limits.

Symmetry-Controlled Rank Transition in Dynamical-Decoupling Identifiability

Key Points

Abstract

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