Quantitative fixed-point theorems with verifiable hypotheses: rates and stability

Abstract

Let (X,) be a complete metric space and let C⊂eq X be a closed invariant set. We study fixed points of maps T C C governed by a verifiable contractive modulus. The modulus is encoded by a contractive gauge ω and a certified constant =0<r Rω(r)/r<1 on a computable working radius R. From this datum we derive explicit a priori bounds (xn,x) (n;,δ0) for Picard iterates, a residual-to-error estimate, and a quantitative data dependence bound (x,y) (1-)-1x∈ C(Tx,Sx). We further treat inexact evaluations ( xn+1,T xn) ηn and obtain certified resilience bounds with the same stability factor. The framework applies to Hammerstein--Volterra integral equations and to boundary value problems via Green operators, where kernel bounds yield certified convergence rates.