A Unified Approach for Coupled Beam Optics in Accelerators
Abstract
Coupled beam optics can be geometrically described in terms of invariant eigenmode planes of a stable symplectic ``one-turn'' map M∈ Sp(4). We show that the non-uniqueness of symplectically normalized bases within each eigenmode plane constitutes an in-plane gauge freedom Sp(2)× Sp(2), and that many coupled-optics parametrizations differ primarily by gauge choice. Building on this fact, we identify basis-independent descriptors of lattice and beam optics and introduce bounded, gauge-invariant coupling parameters or fractions uk,inv computed from orthogonal projectors onto the eigenmode planes. To obtain smooth s-dependent optics functions and consistent mode labeling, we present a unifying and practical approach based on an SO(2) continuity gauge (Procrustes alignment), together with diagnostics for stability and invariance. We further relate Edwards--Teng, Mais--Ripken, Lebedev--Bogacz, Wolski, and Sagan--Rubin parametrizations as gauge-equivalent representations within the respective Sp(2)× Sp(2) gauge freedom. Numerical examples of coupled lattices and beam optics illustrate the proposed invariants and show how representation-dependent scalar coupling parameters (e.g.\ in the Lebedev--Bogacz gauge) can leave their nominal bounds while uk,inv, defined here, remain bounded and physically interpretable.
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