mirror of
https://github.com/NGSolve/netgen.git
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352 lines
7.5 KiB
C++
352 lines
7.5 KiB
C++
/***************************************************************************/
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/* */
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/* Problem: Liniensuche */
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/* */
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/* Programmautor: Joachim Schöberl */
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/* Matrikelnummer: 9155284 */
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/* */
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/* Algorithmus nach: */
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/* */
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/* Optimierung I, Gfrerer, WS94/95 */
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/* Algorithmus 2.1: Liniensuche Problem (ii) */
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/* */
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/***************************************************************************/
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#include <mystdlib.h>
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#include <myadt.hpp> // min, max, sqr
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#include <linalg.hpp>
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#include "opti.hpp"
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namespace netgen
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{
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const double eps0 = 1E-15;
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// Liniensuche
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double MinFunction :: Func (const Vector & /* x */) const
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{
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cerr << "Func of MinFunction called" << endl;
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return 0;
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}
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void MinFunction :: Grad (const Vector & /* x */, Vector & /* g */) const
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{
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cerr << "Grad of MinFunction called" << endl;
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}
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double MinFunction :: FuncGrad (const Vector & x, Vector & g) const
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{
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cerr << "Grad of MinFunction called" << endl;
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return 0;
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/*
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int n = x.Size();
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static Vector xr;
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static Vector xl;
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xr.SetSize(n);
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xl.SetSize(n);
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double eps = 1e-6;
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double fl, fr;
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for (int i = 1; i <= n; i++)
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{
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xr.Set (1, x);
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xl.Set (1, x);
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xr.Elem(i) += eps;
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fr = Func (xr);
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xl.Elem(i) -= eps;
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fl = Func (xl);
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g.Elem(i) = (fr - fl) / (2 * eps);
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}
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double f = Func(x);
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// (*testout) << "f = " << f << " grad = " << g << endl;
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return f;
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*/
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}
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double MinFunction :: FuncDeriv (const Vector & x, const Vector & dir, double & deriv) const
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{
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Vector g(x.Size());
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double f = FuncGrad (x, g);
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deriv = (g * dir);
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// (*testout) << "g = " << g << ", dir = " << dir << ", deriv = " << deriv << endl;
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return f;
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}
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void MinFunction :: ApproximateHesse (const Vector & x,
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DenseMatrix & hesse) const
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{
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int n = x.Size();
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int i, j;
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static Vector hx;
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hx.SetSize(n);
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double eps = 1e-6;
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double f, f11, f12, f21, f22;
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for (i = 0; i < n; i++)
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{
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for (j = 0; j < i; j++)
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{
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hx = x;
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hx(i) = x(i) + eps;
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hx(j) = x(j) + eps;
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f11 = Func(hx);
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hx(i) = x(i) + eps;
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hx(j) = x(j) - eps;
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f12 = Func(hx);
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hx(i) = x(i) - eps;
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hx(j) = x(j) + eps;
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f21 = Func(hx);
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hx(i) = x(i) - eps;
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hx(j) = x(j) - eps;
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f22 = Func(hx);
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hesse(i, j) = hesse(j, i) =
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(f11 + f22 - f12 - f21) / (2 * eps * eps);
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}
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hx = x;
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f = Func(x);
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hx(i) = x(i) + eps;
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f11 = Func(hx);
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hx(i) = x(i) - eps;
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f22 = Func(hx);
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hesse(i, i) = (f11 + f22 - 2 * f) / (eps * eps);
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}
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// (*testout) << "hesse = " << hesse << endl;
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}
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/// Line search, modified Mangasarien conditions
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void lines (Vector & x, // i: initial point of line-search
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Vector & xneu, // o: solution, if successful
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Vector & p, // i: search direction
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double & f, // i: function-value at x
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// o: function-value at xneu, iff ifail = 0
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Vector & g, // i: gradient at x
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// o: gradient at xneu, iff ifail = 0
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const MinFunction & fun, // function to minimize
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const OptiParameters & par,
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double & alphahat, // i: initial value for alpha_hat
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// o: solution alpha iff ifail = 0
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double fmin, // i: lower bound for f
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double mu1, // i: Parameter mu_1 of Alg.2.1
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double sigma, // i: Parameter sigma of Alg.2.1
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double xi1, // i: Parameter xi_1 of Alg.2.1
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double xi2, // i: Parameter xi_1 of Alg.2.1
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double tau, // i: Parameter tau of Alg.2.1
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double tau1, // i: Parameter tau_1 of Alg.2.1
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double tau2, // i: Parameter tau_2 of Alg.2.1
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int & ifail) // o: 0 on success
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// -1 bei termination because lower limit fmin
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// 1 bei illegal termination due to different reasons
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{
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double phi0, phi0prime, phi1, phi1prime, phihatprime;
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double alpha1, alpha2, alphaincr, c;
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char flag = 1;
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long it;
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alpha1 = 0;
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alpha2 = 1e50;
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phi0 = phi1 = f;
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phi0prime = g * p;
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if (phi0prime > 0)
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{
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ifail = 1;
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return;
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}
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ifail = 1; // Markus
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phi1prime = phi0prime;
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// (*testout) << "phi0prime = " << phi0prime << endl;
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// it = 100000l;
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it = 0;
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while (it++ <= par.maxit_linsearch)
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{
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xneu.Set2 (1, x, alphahat, p);
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// f = fun.FuncGrad (xneu, g);
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// f = fun.Func (xneu);
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f = fun.FuncDeriv (xneu, p, phihatprime);
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// (*testout) << "lines, f = " << f << " phip = " << phihatprime << endl;
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if (f < fmin)
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{
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ifail = -1;
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break;
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}
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if (alpha2 - alpha1 < eps0 * alpha2)
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{
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ifail = 0;
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break;
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}
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// (*testout) << "i = " << it << " al = " << alphahat << " f = " << f << " fprime " << phihatprime << endl;;
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if (f - phi0 > mu1 * alphahat * phi1prime + eps0 * fabs (phi0))
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{
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flag = 0;
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alpha2 = alphahat;
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c =
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(f - phi1 - phi1prime * (alphahat-alpha1)) /
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sqr (alphahat-alpha1);
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alphahat = alpha1 - 0.5 * phi1prime / c;
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if (alphahat > alpha2)
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alphahat = alpha1 + 1/(4*c) *
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( (sigma+mu1) * phi0prime - 2*phi1prime
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+ sqrt (sqr(phi1prime - mu1 * phi0prime) -
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4 * (phi1 - phi0 - mu1 * alpha1 * phi0prime) * c));
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alphahat = max2 (alphahat, alpha1 + tau * (alpha2 - alpha1));
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alphahat = min2 (alphahat, alpha2 - tau * (alpha2 - alpha1));
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// (*testout) << " if-branch" << endl;
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}
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else
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{
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/*
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f = fun.FuncGrad (xneu, g);
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phihatprime = g * p;
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*/
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f = fun.FuncDeriv (xneu, p, phihatprime);
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if (phihatprime < sigma * phi0prime * (1 + eps0))
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{
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if (phi1prime < phihatprime)
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// Approximationsfunktion ist konvex
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alphaincr = (alphahat - alpha1) * phihatprime /
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(phi1prime - phihatprime);
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else
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alphaincr = 1e99; // MAXDOUBLE;
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if (flag)
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{
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alphaincr = max2 (alphaincr, xi1 * (alphahat-alpha1));
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alphaincr = min2 (alphaincr, xi2 * (alphahat-alpha1));
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}
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else
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{
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alphaincr = max2 (alphaincr, tau1 * (alpha2 - alphahat));
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alphaincr = min2 (alphaincr, tau2 * (alpha2 - alphahat));
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}
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alpha1 = alphahat;
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alphahat += alphaincr;
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phi1 = f;
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phi1prime = phihatprime;
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}
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else
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{
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ifail = 0; // Erfolg !!
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break;
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}
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// (*testout) << " else, " << endl;
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}
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}
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// (*testout) << "linsearch: it = " << it << " ifail = " << ifail << endl;
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fun.FuncGrad (xneu, g);
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if (it < 0)
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ifail = 1;
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// (*testout) << "fail = " << ifail << endl;
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}
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void SteepestDescent (Vector & x, const MinFunction & fun,
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const OptiParameters & par)
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{
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int it, n = x.Size();
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Vector xnew(n), p(n), g(n), g2(n);
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double val, alphahat;
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int fail;
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val = fun.FuncGrad(x, g);
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alphahat = 1;
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// testout << "f = ";
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for (it = 0; it < 10; it++)
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{
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// testout << val << " ";
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// p = -g;
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p.Set (-1, g);
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lines (x, xnew, p, val, g, fun, par, alphahat, -1e5,
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0.1, 0.1, 1, 10, 0.1, 0.1, 0.6, fail);
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x = xnew;
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}
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// testout << endl;
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}
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}
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