On the existence and uniqueness of solution to Volterra equation on a time scale

Abstract Using a global inversion theorem we investigate properties of the following operator V(x)(⋅):=xΔ(⋅)+∫0⋅v(⋅,τ,x,(τ))Δτ,                           x(0)=0, \matrix{\matrix{ V(x)( \cdot ): = {x^\Delta }( \cdot ) + \int_0^ \cdot {v\left( { \cdot ,\tau ,x,\left( \tau \right)} \right)} \Delta \tau , \hfill \cr \,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,x(0) = 0, \hfill \cr}\cr {} \cr } in a time scale setting. Under some assumptions on the nonlinear term v we then show that there exists exactly one solution xy∈W Δ,01,p([0,1]𝕋,𝕉N) {x_y} \in W_{\Delta ,0}^{1,p}\left( {{{[0,1]}_\mathbb{T}},{\mathbb{R}^N}} \right) to the associated integral equation { xΔ(t)+∫0tv(t,τ,x(τ))Δτ=y(t)   for Δ-a.e.   t∈[0.1]𝕋,x(0)=0, \left\{ {\matrix{{{x^\Delta }(t) + \int_0^t {v\left( {t,\tau ,x\left( \tau \right)} \right)} \Delta \tau = y(t)\,\,\,for\,\Delta - a.e.\,\,\,t \in {{[0.1]}_\mathbb{T}},} \cr {x(0) = 0,} \cr } } \right. which is considered on a suitable Sobolev space.