The Structure of the Frechet Derivative in Banach Spaces

Eva Matouskova, Charles Stegall, stegall@bayou.uni-linz.ac.at

21 March 2001

No description available.

Frechet derivative, Banach spaces

Local Ill-Posedness and Source Conditions of Operator Equations in Hilbert Spaces

Hofmann, B., Scherzer, O.

30 October 1998

The characterization of the local ill-posedness and the local degree of nonlinearity are of particular importance for the stable solution of nonlinear ill-posed problems. We present assertions concerning the interdependence between the ill-posedness of the nonlinear problem and its linearization. Moreover, we show that the concept of the degree of nonlinearity com bined with source conditions can be used to characterize the local ill-posedness and to derive a posteriori estimates for nonlinear ill-posed problems. A posteriori estimates are widely used in finite element and multigrid methods for the solution of nonlinear partial differential equations, but these techniques are in general not applicable to inverse an ill-posed problems. Additionally we show for the well-known Landweber method and the iteratively regularized Gauss-Newton method that they satisfy a posteriori estimates under source conditions; this can be used to prove convergence rates results.

nonlinear operator equations

ill-posedness

Frechet derivative

source conditions

stability estimates

ill-posedness measurres

a posteriori estimates

MSC 65J15

MSC 65J20

MSC 47H15

MSC 47H17

ddc:510

On Ill-Posedness and Local Ill-Posedness of Operator Equations in Hilbert Spaces

Hofmann, B.

30 October 1998

In this paper, we study ill-posedness concepts of nonlinear and linear inverse problems in a Hilbert space setting. We define local ill-posedness of a nonlinear operator equation $F(x) = y_0$ in a solution point $x_0$ and the interplay between the nonlinear problem and its linearization using the Frechet derivative $F\acent(x_0)$ . To find an appropriate ill-posedness concept for the linarized equation we define intrinsic ill-posedness for linear operator equations $Ax = y$ and compare this approach with the ill-posedness definitions due to Hadamard and Nashed.

Nonlinear inverse problems

oerator equations

ill-posedness

stability estimates

local ill-posedness

Frechet derivative

linearized problem

compact operators

integral equations

parameter identification

MSC 65J20

MSC 47H15

MSC 65J10

MSC 65J15

MSC 65R30

MSC 45G10

ddc:510

Local Ill-Posedness and Source Conditions of Operator Equations in Hilbert Spaces

Hofmann, B., Scherzer, O.

30 October 1998

The characterization of the local ill-posedness and the local degree of nonlinearity are of particular importance for the stable solution of nonlinear ill-posed problems. We present assertions concerning the interdependence between the ill-posedness of the nonlinear problem and its linearization. Moreover, we show that the concept of the degree of nonlinearity com bined with source conditions can be used to characterize the local ill-posedness and to derive a posteriori estimates for nonlinear ill-posed problems. A posteriori estimates are widely used in finite element and multigrid methods for the solution of nonlinear partial differential equations, but these techniques are in general not applicable to inverse an ill-posed problems. Additionally we show for the well-known Landweber method and the iteratively regularized Gauss-Newton method that they satisfy a posteriori estimates under source conditions; this can be used to prove convergence rates results.

info:eu-repo/classification/ddc/510

ddc:510

On Ill-Posedness and Local Ill-Posedness of Operator Equations in Hilbert Spaces: On Ill-Posedness and Local Ill-Posedness of OperatorEquations in Hilbert Spaces

Hofmann, B.

30 October 1998

In this paper, we study ill-posedness concepts of nonlinear and linear inverse problems in a Hilbert space setting. We define local ill-posedness of a nonlinear operator equation $F(x) = y_0$ in a solution point $x_0$ and the interplay between the nonlinear problem and its linearization using the Frechet derivative $F\acent(x_0)$ . To find an appropriate ill-posedness concept for the linarized equation we define intrinsic ill-posedness for linear operator equations $Ax = y$ and compare this approach with the ill-posedness definitions due to Hadamard and Nashed.

info:eu-repo/classification/ddc/510

ddc:510

Nonlinear inverse problems

oerator equations

ill-posedness

stability estimates

local ill-posedness

Frechet derivative

linearized problem

compact operators

integral equations

parameter identification

MSC 65J20

MSC 47H15

MSC 65J10

MSC 65J15

MSC 65R30

MSC 45G10