Dynamical Systems Method (DSM) for solving nonlinear operator equations in Banach spaces

Abstract

Let F(u)=h be an operator equation in a Banach space X, \|F'(u)-F'(v)\|≤ ω(\|u-v\|), where ω∈ C([0,∞)), ω(0)=0, ω(r)>0 if r>0, ω(r) is strictly growing on [0,∞). Denote A(u):=F'(u), where F'(u) is the Fr\'echet derivative of F, and Aa:=A+aI. Assume that (*) \|A-1a(u)\|≤ c1|a|b, |a|>0, b>0, a∈ L. Here a may be a complex number, and L is a smooth path on the complex a-plane, joining the origin and some point on the complex a-plane, 0<|a|<ε0, where ε0>0 is a small fixed number, such that for any a∈ L estimate (*) holds. It is proved that the DSM (Dynamical Systems Method) u(t)=-A-1a(t)(u(t))[F(u(t))+a(t)u(t)-f], u(0)=u0,\ u=d udt, converges to y as t +∞, where a(t)∈ L, F(y)=f, r(t):=|a(t)|, and r(t)=c4(t+c2)-c3, where cj>0 are some suitably chosen constants, j=2,3,4. Existence of a solution y to the equation F(u)=f is assumed. It is also assumed that the equation F(wa)+awa-f=0 is uniquely solvable for any f∈ X, a∈ L, and |a| 0,a∈ L\|wa-y\|=0.