Regularity, Phase Transitions, and Uniform Inference for Proximal Counterfactual Quantile Processes

Abstract

This paper develops semiparametric theory for counterfactual distribution, quantile, and lower-tail risk processes under unmeasured confounding using proximal negative-control proxies. Rather than treating each threshold as a separate proximal mean problem with outcome 1\Y y\, we study the continuum of inverse problems indexed by y. For each treatment arm a, the counterfactual CDF Fa(y)=P\Y(a) y\ is represented by the primal bridge equation Ta ha,y=ga,y and the linear functional (h)=E\h(W,X)\. The dual bridge qa solves Ta*qa=1, equivalently E[ 1(A=a)qa(Z,X)-1 W,X]=0. We show that this dual equation, together with the minimal residual-moment condition required for the influence function to lie in L2(P0), is the exact regularity boundary in a threshold-saturated observed-data proximal bridge model: Fa(y) is pathwise differentiable if and only if a regular square-integrable dual bridge exists. The canonical gradient is \[ ha,y(W,X)-Fa(y)+ 1(A=a)qa(Z,X)\ 1(Y y)-ha,y(W,X)\. \] A singular-system characterization gives a Picard-type phase transition: root-n regular estimation is possible exactly when Σja,j2/sa,j2<∞ and the residual moment is finite. Outside this region, finite-dimensional efficiency bounds diverge under residual-noise nondegeneracy, and Gaussian inverse benchmarks yield slower minimax rates. We further establish efficient CDF-process inference, cross-fitted uniform doubly robust expansions, finite-rank weak-proxy rate conditions, density-free simultaneous quantile bands by inversion of CDF bands, and lower-tail CVaR inference via a shortfall representation. The estimators rely on closed-form linear algebra, convex Tikhonov regularization, and isotonic projection for shape enforcement.