Quality Coefficients for Interferometric Phase Linking

In multi-temporal InSAR, phase linking refers to the estimation of a single-reference interferometric phase history from the information contained in the coherence matrix of a distributed scatterer. Since the phase information in the coherence matrix is typically inconsistent, the extent to which the estimated phase history captures it must be assessed to exclude unreliable pixels from further processing. We introduce three quality criteria in the form of coefficients, for threshold-based pixel selection: a coefficient based on closure phase that quantifies the internal consistency of the phase information in the coherence matrix; a goodness-of-fit coefficient that quantifies how well a resulting phase history estimate approximates the phase information according to the characteristic optimization model of a given phase linking method; and an ambiguity coefficient that compares the goodness of fit of the original estimate with that of an orthogonal alternative. We formulate the phase linking methods and these criteria within a unified mathematical framework and discuss computational and algorithmic aspects. Unlike existing goodness-of-fit indicators, the proposed coefficients are normalized to the unit interval with explicit noise-floor correction, improving interpretability across stacks of different size. Experiments on TerraSAR-X data over Visp, Switzerland, indicate that the closure phase coefficient effectively pre-screens stable areas, the goodness-of-fit coefficient aligns with and systematically generalizes established quality indicators, and the ambiguity coefficient flags solutions that fit well but are unstable. Together, the coefficients enable systematic pixel selection and quality control in the interferometric processing of distributed scatterers.