/************************************************************************* Copyright (c) 2007, Sergey Bochkanov (ALGLIB project). Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: - Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. - Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer listed in this license in the documentation and/or other materials provided with the distribution. - Neither the name of the copyright holders nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. *************************************************************************/ using System; class spline3 { /************************************************************************* This subroutine builds linear spline coefficients table. Input parameters: X - spline nodes, array[0..N-1] Y - function values, array[0..N-1] N - points count, N>=2 Output parameters: C - coefficients table. Used by SplineInterpolation and other subroutines from this file. -- ALGLIB PROJECT -- Copyright 24.06.2007 by Bochkanov Sergey *************************************************************************/ public static void buildlinearspline(double[] x, double[] y, int n, ref double[] c) { int i = 0; int tblsize = 0; x = (double[])x.Clone(); y = (double[])y.Clone(); System.Diagnostics.Debug.Assert(n>=2, "BuildLinearSpline: N<2!"); // // Sort points // heapsortpoints(ref x, ref y, n); // // Fill C: // C[0] - length(C) // C[1] - type(C): // 3 - general cubic spline // C[2] - N // C[3]...C[3+N-1] - x[i], i = 0...N-1 // C[3+N]...C[3+N+(N-1)*4-1] - coefficients table // tblsize = 3+n+(n-1)*4; c = new double[tblsize-1+1]; c[0] = tblsize; c[1] = 3; c[2] = n; for(i=0; i<=n-1; i++) { c[3+i] = x[i]; } for(i=0; i<=n-2; i++) { c[3+n+4*i+0] = y[i]; c[3+n+4*i+1] = (y[i+1]-y[i])/(x[i+1]-x[i]); c[3+n+4*i+2] = 0; c[3+n+4*i+3] = 0; } } /************************************************************************* This subroutine builds cubic spline coefficients table. Input parameters: X - spline nodes, array[0..N-1] Y - function values, array[0..N-1] N - points count, N>=2 BoundLType - boundary condition type for the left boundary BoundL - left boundary condition (first or second derivative, depending on the BoundLType) BoundRType - boundary condition type for the right boundary BoundR - right boundary condition (first or second derivative, depending on the BoundRType) Output parameters: C - coefficients table. Used by SplineInterpolation and other subroutines from this file. The BoundLType/BoundRType parameters can have the following values: * 0, which corresponds to the parabolically terminated spline (BoundL/BoundR are ignored). * 1, which corresponds to the first derivative boundary condition * 2, which corresponds to the second derivative boundary condition -- ALGLIB PROJECT -- Copyright 23.06.2007 by Bochkanov Sergey *************************************************************************/ public static void buildcubicspline(double[] x, double[] y, int n, int boundltype, double boundl, int boundrtype, double boundr, ref double[] c) { double[] a1 = new double[0]; double[] a2 = new double[0]; double[] a3 = new double[0]; double[] b = new double[0]; double[] d = new double[0]; int i = 0; int tblsize = 0; double delta = 0; double delta2 = 0; double delta3 = 0; x = (double[])x.Clone(); y = (double[])y.Clone(); System.Diagnostics.Debug.Assert(n>=2, "BuildCubicSpline: N<2!"); System.Diagnostics.Debug.Assert(boundltype==0 | boundltype==1 | boundltype==2, "BuildCubicSpline: incorrect BoundLType!"); System.Diagnostics.Debug.Assert(boundrtype==0 | boundrtype==1 | boundrtype==2, "BuildCubicSpline: incorrect BoundRType!"); a1 = new double[n-1+1]; a2 = new double[n-1+1]; a3 = new double[n-1+1]; b = new double[n-1+1]; // // Special case: // * N=2 // * parabolic terminated boundary condition on both ends // if( n==2 & boundltype==0 & boundrtype==0 ) { // // Change task type // boundltype = 2; boundl = 0; boundrtype = 2; boundr = 0; } // // // Sort points // heapsortpoints(ref x, ref y, n); // // Left boundary conditions // if( boundltype==0 ) { a1[0] = 0; a2[0] = 1; a3[0] = 1; b[0] = 2*(y[1]-y[0])/(x[1]-x[0]); } if( boundltype==1 ) { a1[0] = 0; a2[0] = 1; a3[0] = 0; b[0] = boundl; } if( boundltype==2 ) { a1[0] = 0; a2[0] = 2; a3[0] = 1; b[0] = 3*(y[1]-y[0])/(x[1]-x[0])-0.5*boundl*(x[1]-x[0]); } // // Central conditions // for(i=1; i<=n-2; i++) { a1[i] = x[i+1]-x[i]; a2[i] = 2*(x[i+1]-x[i-1]); a3[i] = x[i]-x[i-1]; b[i] = 3*(y[i]-y[i-1])/(x[i]-x[i-1])*(x[i+1]-x[i])+3*(y[i+1]-y[i])/(x[i+1]-x[i])*(x[i]-x[i-1]); } // // Right boundary conditions // if( boundrtype==0 ) { a1[n-1] = 1; a2[n-1] = 1; a3[n-1] = 0; b[n-1] = 2*(y[n-1]-y[n-2])/(x[n-1]-x[n-2]); } if( boundrtype==1 ) { a1[n-1] = 0; a2[n-1] = 1; a3[n-1] = 0; b[n-1] = boundr; } if( boundrtype==2 ) { a1[n-1] = 1; a2[n-1] = 2; a3[n-1] = 0; b[n-1] = 3*(y[n-1]-y[n-2])/(x[n-1]-x[n-2])+0.5*boundr*(x[n-1]-x[n-2]); } // // Solve // solvetridiagonal(a1, a2, a3, b, n, ref d); // // Now problem is reduced to the cubic Hermite spline // buildhermitespline(x, y, d, n, ref c); } /************************************************************************* This subroutine builds cubic Hermite spline coefficients table. Input parameters: X - spline nodes, array[0..N-1] Y - function values, array[0..N-1] D - derivatives, array[0..N-1] N - points count, N>=2 Output parameters: C - coefficients table. Used by SplineInterpolation and other subroutines from this file. -- ALGLIB PROJECT -- Copyright 23.06.2007 by Bochkanov Sergey *************************************************************************/ public static void buildhermitespline(double[] x, double[] y, double[] d, int n, ref double[] c) { int i = 0; int tblsize = 0; double delta = 0; double delta2 = 0; double delta3 = 0; x = (double[])x.Clone(); y = (double[])y.Clone(); d = (double[])d.Clone(); System.Diagnostics.Debug.Assert(n>=2, "BuildHermiteSpline: N<2!"); // // Sort points // heapsortdpoints(ref x, ref y, ref d, n); // // Fill C: // C[0] - length(C) // C[1] - type(C): // 3 - general cubic spline // C[2] - N // C[3]...C[3+N-1] - x[i], i = 0...N-1 // C[3+N]...C[3+N+(N-1)*4-1] - coefficients table // tblsize = 3+n+(n-1)*4; c = new double[tblsize-1+1]; c[0] = tblsize; c[1] = 3; c[2] = n; for(i=0; i<=n-1; i++) { c[3+i] = x[i]; } for(i=0; i<=n-2; i++) { delta = x[i+1]-x[i]; delta2 = AP.Math.Sqr(delta); delta3 = delta*delta2; c[3+n+4*i+0] = y[i]; c[3+n+4*i+1] = d[i]; c[3+n+4*i+2] = (3*(y[i+1]-y[i])-2*d[i]*delta-d[i+1]*delta)/delta2; c[3+n+4*i+3] = (2*(y[i]-y[i+1])+d[i]*delta+d[i+1]*delta)/delta3; } } /************************************************************************* This subroutine builds Akima spline coefficients table. Input parameters: X - spline nodes, array[0..N-1] Y - function values, array[0..N-1] N - points count, N>=5 Output parameters: C - coefficients table. Used by SplineInterpolation and other subroutines from this file. -- ALGLIB PROJECT -- Copyright 24.06.2007 by Bochkanov Sergey *************************************************************************/ public static void buildakimaspline(double[] x, double[] y, int n, ref double[] c) { int i = 0; double[] d = new double[0]; double[] w = new double[0]; double[] diff = new double[0]; x = (double[])x.Clone(); y = (double[])y.Clone(); System.Diagnostics.Debug.Assert(n>=5, "BuildAkimaSpline: N<5!"); // // Sort points // heapsortpoints(ref x, ref y, n); // // Prepare W (weights), Diff (divided differences) // w = new double[n-2+1]; diff = new double[n-2+1]; for(i=0; i<=n-2; i++) { diff[i] = (y[i+1]-y[i])/(x[i+1]-x[i]); } for(i=1; i<=n-2; i++) { w[i] = Math.Abs(diff[i]-diff[i-1]); } // // Prepare Hermite interpolation scheme // d = new double[n-1+1]; for(i=2; i<=n-3; i++) { if( Math.Abs(w[i-1])+Math.Abs(w[i+1])!=0 ) { d[i] = (w[i+1]*diff[i-1]+w[i-1]*diff[i])/(w[i+1]+w[i-1]); } else { d[i] = ((x[i+1]-x[i])*diff[i-1]+(x[i]-x[i-1])*diff[i])/(x[i+1]-x[i-1]); } } d[0] = diffthreepoint(x[0], x[0], y[0], x[1], y[1], x[2], y[2]); d[1] = diffthreepoint(x[1], x[0], y[0], x[1], y[1], x[2], y[2]); d[n-2] = diffthreepoint(x[n-2], x[n-3], y[n-3], x[n-2], y[n-2], x[n-1], y[n-1]); d[n-1] = diffthreepoint(x[n-1], x[n-3], y[n-3], x[n-2], y[n-2], x[n-1], y[n-1]); // // Build Akima spline using Hermite interpolation scheme // buildhermitespline(x, y, d, n, ref c); } /************************************************************************* This subroutine calculates the value of the spline at the given point X. Input parameters: C - coefficients table. Built by BuildLinearSpline, BuildHermiteSpline, BuildCubicSpline, BuildAkimaSpline. X - point Result: S(x) -- ALGLIB PROJECT -- Copyright 23.06.2007 by Bochkanov Sergey *************************************************************************/ public static double splineinterpolation(ref double[] c, double x) { double result = 0; int n = 0; int l = 0; int r = 0; int m = 0; System.Diagnostics.Debug.Assert((int)Math.Round(c[1])==3, "SplineInterpolation: incorrect C!"); n = (int)Math.Round(c[2]); // // Binary search in the [ x[0], ..., x[n-2] ] (x[n-1] is not included) // l = 3; r = 3+n-2+1; while( l!=r-1 ) { m = (l+r)/2; if( c[m]>=x ) { r = m; } else { l = m; } } // // Interpolation // x = x-c[l]; m = 3+n+4*(l-3); result = c[m]+x*(c[m+1]+x*(c[m+2]+x*c[m+3])); return result; } /************************************************************************* This subroutine differentiates the spline. Input parameters: C - coefficients table. Built by BuildLinearSpline, BuildHermiteSpline, BuildCubicSpline, BuildAkimaSpline. X - point Result: S - S(x) DS - S'(x) D2S - S''(x) -- ALGLIB PROJECT -- Copyright 24.06.2007 by Bochkanov Sergey *************************************************************************/ public static void splinedifferentiation(ref double[] c, double x, ref double s, ref double ds, ref double d2s) { int n = 0; int l = 0; int r = 0; int m = 0; System.Diagnostics.Debug.Assert((int)Math.Round(c[1])==3, "SplineInterpolation: incorrect C!"); n = (int)Math.Round(c[2]); // // Binary search // l = 3; r = 3+n-2+1; while( l!=r-1 ) { m = (l+r)/2; if( c[m]>=x ) { r = m; } else { l = m; } } // // Differentiation // x = x-c[l]; m = 3+n+4*(l-3); s = c[m]+x*(c[m+1]+x*(c[m+2]+x*c[m+3])); ds = c[m+1]+2*x*c[m+2]+3*AP.Math.Sqr(x)*c[m+3]; d2s = 2*c[m+2]+6*x*c[m+3]; } /************************************************************************* This subroutine makes the copy of the spline. Input parameters: C - coefficients table. Built by BuildLinearSpline, BuildHermiteSpline, BuildCubicSpline, BuildAkimaSpline. Result: CC - spline copy -- ALGLIB PROJECT -- Copyright 29.06.2007 by Bochkanov Sergey *************************************************************************/ public static void splinecopy(ref double[] c, ref double[] cc) { int s = 0; int i_ = 0; s = (int)Math.Round(c[0]); cc = new double[s-1+1]; for(i_=0; i_<=s-1;i_++) { cc[i_] = c[i_]; } } /************************************************************************* This subroutine unpacks the spline into the coefficients table. Input parameters: C - coefficients table. Built by BuildLinearSpline, BuildHermiteSpline, BuildCubicSpline, BuildAkimaSpline. X - point Result: Tbl - coefficients table, unpacked format, array[0..N-2, 0..5]. For I = 0...N-2: Tbl[I,0] = X[i] Tbl[I,1] = X[i+1] Tbl[I,2] = C0 Tbl[I,3] = C1 Tbl[I,4] = C2 Tbl[I,5] = C3 On [x[i], x[i+1]] spline is equals to: S(x) = C0 + C1*t + C2*t^2 + C3*t^3 t = x-x[i] -- ALGLIB PROJECT -- Copyright 29.06.2007 by Bochkanov Sergey *************************************************************************/ public static void splineunpack(ref double[] c, ref int n, ref double[,] tbl) { int i = 0; System.Diagnostics.Debug.Assert((int)Math.Round(c[1])==3, "SplineUnpack: incorrect C!"); n = (int)Math.Round(c[2]); tbl = new double[n-2+1, 5+1]; // // Fill // for(i=0; i<=n-2; i++) { tbl[i,0] = c[3+i]; tbl[i,1] = c[3+i+1]; tbl[i,2] = c[3+n+4*i]; tbl[i,3] = c[3+n+4*i+1]; tbl[i,4] = c[3+n+4*i+2]; tbl[i,5] = c[3+n+4*i+3]; } } /************************************************************************* This subroutine performs linear transformation of the spline argument. Input parameters: C - coefficients table. Built by BuildLinearSpline, BuildHermiteSpline, BuildCubicSpline, BuildAkimaSpline. A, B- transformation coefficients: x = A*t + B Result: C - transformed spline -- ALGLIB PROJECT -- Copyright 30.06.2007 by Bochkanov Sergey *************************************************************************/ public static void splinelintransx(ref double[] c, double a, double b) { int i = 0; int n = 0; double v = 0; double dv = 0; double d2v = 0; double[] x = new double[0]; double[] y = new double[0]; double[] d = new double[0]; System.Diagnostics.Debug.Assert((int)Math.Round(c[1])==3, "SplineLinTransX: incorrect C!"); n = (int)Math.Round(c[2]); // // Special case: A=0 // if( a==0 ) { v = splineinterpolation(ref c, b); for(i=0; i<=n-2; i++) { c[3+n+4*i] = v; c[3+n+4*i+1] = 0; c[3+n+4*i+2] = 0; c[3+n+4*i+3] = 0; } return; } // // General case: A<>0. // Unpack, X, Y, dY/dX. // Scale and pack again. // x = new double[n-1+1]; y = new double[n-1+1]; d = new double[n-1+1]; for(i=0; i<=n-1; i++) { x[i] = c[3+i]; splinedifferentiation(ref c, x[i], ref v, ref dv, ref d2v); x[i] = (x[i]-b)/a; y[i] = v; d[i] = a*dv; } buildhermitespline(x, y, d, n, ref c); } /************************************************************************* This subroutine performs linear transformation of the spline. Input parameters: C - coefficients table. Built by BuildLinearSpline, BuildHermiteSpline, BuildCubicSpline, BuildAkimaSpline. A, B- transformation coefficients: S2(x) = A*S(x) + B Result: C - transformed spline -- ALGLIB PROJECT -- Copyright 30.06.2007 by Bochkanov Sergey *************************************************************************/ public static void splinelintransy(ref double[] c, double a, double b) { int i = 0; int n = 0; double v = 0; double dv = 0; double d2v = 0; double[] x = new double[0]; double[] y = new double[0]; double[] d = new double[0]; System.Diagnostics.Debug.Assert((int)Math.Round(c[1])==3, "SplineLinTransX: incorrect C!"); n = (int)Math.Round(c[2]); // // Special case: A=0 // for(i=0; i<=n-2; i++) { c[3+n+4*i] = a*c[3+n+4*i]+b; c[3+n+4*i+1] = a*c[3+n+4*i+1]; c[3+n+4*i+2] = a*c[3+n+4*i+2]; c[3+n+4*i+3] = a*c[3+n+4*i+3]; } } /************************************************************************* This subroutine integrates the spline. Input parameters: C - coefficients table. Built by BuildLinearSpline, BuildHermiteSpline, BuildCubicSpline, BuildAkimaSpline. X - right bound of the integration interval [a, x] Result: integral(S(t)dt,a,x) -- ALGLIB PROJECT -- Copyright 23.06.2007 by Bochkanov Sergey *************************************************************************/ public static double splineintegration(ref double[] c, double x) { double result = 0; int n = 0; int i = 0; int l = 0; int r = 0; int m = 0; double w = 0; System.Diagnostics.Debug.Assert((int)Math.Round(c[1])==3, "SplineIntegration: incorrect C!"); n = (int)Math.Round(c[2]); // // Binary search in the [ x[0], ..., x[n-2] ] (x[n-1] is not included) // l = 3; r = 3+n-2+1; while( l!=r-1 ) { m = (l+r)/2; if( c[m]>=x ) { r = m; } else { l = m; } } // // Integration // result = 0; for(i=3; i<=l-1; i++) { w = c[i+1]-c[i]; m = 3+n+4*(i-3); result = result+c[m]*w; result = result+c[m+1]*AP.Math.Sqr(w)/2; result = result+c[m+2]*AP.Math.Sqr(w)*w/3; result = result+c[m+3]*AP.Math.Sqr(AP.Math.Sqr(w))/4; } w = x-c[l]; m = 3+n+4*(l-3); result = result+c[m]*w; result = result+c[m+1]*AP.Math.Sqr(w)/2; result = result+c[m+2]*AP.Math.Sqr(w)*w/3; result = result+c[m+3]*AP.Math.Sqr(AP.Math.Sqr(w))/4; return result; } /************************************************************************* Obsolete subroutine, left for backward compatibility. *************************************************************************/ public static void spline3buildtable(int n, int diffn, double[] x, double[] y, double boundl, double boundr, ref double[,] ctbl) { bool c = new bool(); int e = 0; int g = 0; double tmp = 0; int nxm1 = 0; int i = 0; int j = 0; double dx = 0; double dxj = 0; double dyj = 0; double dxjp1 = 0; double dyjp1 = 0; double dxp = 0; double dyp = 0; double yppa = 0; double yppb = 0; double pj = 0; double b1 = 0; double b2 = 0; double b3 = 0; double b4 = 0; x = (double[])x.Clone(); y = (double[])y.Clone(); n = n-1; g = (n+1)/2; do { i = g; do { j = i-g; c = true; do { if( x[j]<=x[j+g] ) { c = false; } else { tmp = x[j]; x[j] = x[j+g]; x[j+g] = tmp; tmp = y[j]; y[j] = y[j+g]; y[j+g] = tmp; } j = j-1; } while( j>=0 & c ); i = i+1; } while( i<=n ); g = g/2; } while( g>0 ); ctbl = new double[4+1, n+1]; n = n+1; if( diffn==1 ) { b1 = 1; b2 = 6/(x[1]-x[0])*((y[1]-y[0])/(x[1]-x[0])-boundl); b3 = 1; b4 = 6/(x[n-1]-x[n-2])*(boundr-(y[n-1]-y[n-2])/(x[n-1]-x[n-2])); } else { b1 = 0; b2 = 2*boundl; b3 = 0; b4 = 2*boundr; } nxm1 = n-1; if( n>=2 ) { if( n>2 ) { dxj = x[1]-x[0]; dyj = y[1]-y[0]; j = 2; while( j<=nxm1 ) { dxjp1 = x[j]-x[j-1]; dyjp1 = y[j]-y[j-1]; dxp = dxj+dxjp1; ctbl[1,j-1] = dxjp1/dxp; ctbl[2,j-1] = 1-ctbl[1,j-1]; ctbl[3,j-1] = 6*(dyjp1/dxjp1-dyj/dxj)/dxp; dxj = dxjp1; dyj = dyjp1; j = j+1; } } ctbl[1,0] = -(b1/2); ctbl[2,0] = b2/2; if( n!=2 ) { j = 2; while( j<=nxm1 ) { pj = ctbl[2,j-1]*ctbl[1,j-2]+2; ctbl[1,j-1] = -(ctbl[1,j-1]/pj); ctbl[2,j-1] = (ctbl[3,j-1]-ctbl[2,j-1]*ctbl[2,j-2])/pj; j = j+1; } } yppb = (b4-b3*ctbl[2,nxm1-1])/(b3*ctbl[1,nxm1-1]+2); i = 1; while( i<=nxm1 ) { j = n-i; yppa = ctbl[1,j-1]*yppb+ctbl[2,j-1]; dx = x[j]-x[j-1]; ctbl[3,j-1] = (yppb-yppa)/dx/6; ctbl[2,j-1] = yppa/2; ctbl[1,j-1] = (y[j]-y[j-1])/dx-(ctbl[2,j-1]+ctbl[3,j-1]*dx)*dx; yppb = yppa; i = i+1; } for(i=1; i<=n; i++) { ctbl[0,i-1] = y[i-1]; ctbl[4,i-1] = x[i-1]; } } } /************************************************************************* Obsolete subroutine, left for backward compatibility. *************************************************************************/ public static double spline3interpolate(int n, ref double[,] c, double x) { double result = 0; int i = 0; int l = 0; int half = 0; int first = 0; int middle = 0; n = n-1; l = n; first = 0; while( l>0 ) { half = l/2; middle = first+half; if( c[4,middle]x[i-1]; isdescending = isdescending & x[i]=x[t-1] ) { t = 1; } else { tmp = x[k-1]; x[k-1] = x[t-1]; x[t-1] = tmp; tmp = y[k-1]; y[k-1] = y[t-1]; y[t-1] = tmp; t = k; } } i = i+1; } while( i<=n ); i = n-1; do { tmp = x[i]; x[i] = x[0]; x[0] = tmp; tmp = y[i]; y[i] = y[0]; y[0] = tmp; t = 1; while( t!=0 ) { k = 2*t; if( k>i ) { t = 0; } else { if( kx[k-1] ) { k = k+1; } } if( x[t-1]>=x[k-1] ) { t = 0; } else { tmp = x[k-1]; x[k-1] = x[t-1]; x[t-1] = tmp; tmp = y[k-1]; y[k-1] = y[t-1]; y[t-1] = tmp; t = k; } } } i = i-1; } while( i>=1 ); } /************************************************************************* Internal subroutine. Heap sort. *************************************************************************/ private static void heapsortdpoints(ref double[] x, ref double[] y, ref double[] d, int n) { int i = 0; int j = 0; int k = 0; int t = 0; double tmp = 0; bool isascending = new bool(); bool isdescending = new bool(); // // Test for already sorted set // isascending = true; isdescending = true; for(i=1; i<=n-1; i++) { isascending = isascending & x[i]>x[i-1]; isdescending = isdescending & x[i]=x[t-1] ) { t = 1; } else { tmp = x[k-1]; x[k-1] = x[t-1]; x[t-1] = tmp; tmp = y[k-1]; y[k-1] = y[t-1]; y[t-1] = tmp; tmp = d[k-1]; d[k-1] = d[t-1]; d[t-1] = tmp; t = k; } } i = i+1; } while( i<=n ); i = n-1; do { tmp = x[i]; x[i] = x[0]; x[0] = tmp; tmp = y[i]; y[i] = y[0]; y[0] = tmp; tmp = d[i]; d[i] = d[0]; d[0] = tmp; t = 1; while( t!=0 ) { k = 2*t; if( k>i ) { t = 0; } else { if( kx[k-1] ) { k = k+1; } } if( x[t-1]>=x[k-1] ) { t = 0; } else { tmp = x[k-1]; x[k-1] = x[t-1]; x[t-1] = tmp; tmp = y[k-1]; y[k-1] = y[t-1]; y[t-1] = tmp; tmp = d[k-1]; d[k-1] = d[t-1]; d[t-1] = tmp; t = k; } } } i = i-1; } while( i>=1 ); } /************************************************************************* Internal subroutine. Tridiagonal solver. *************************************************************************/ private static void solvetridiagonal(double[] a, double[] b, double[] c, double[] d, int n, ref double[] x) { int k = 0; double t = 0; a = (double[])a.Clone(); b = (double[])b.Clone(); c = (double[])c.Clone(); d = (double[])d.Clone(); x = new double[n-1+1]; a[0] = 0; c[n-1] = 0; for(k=1; k<=n-1; k++) { t = a[k]/b[k-1]; b[k] = b[k]-t*c[k-1]; d[k] = d[k]-t*d[k-1]; } x[n-1] = d[n-1]/b[n-1]; for(k=n-2; k>=0; k--) { x[k] = (d[k]-c[k]*x[k+1])/b[k]; } } /************************************************************************* Internal subroutine. Three-point differentiation *************************************************************************/ private static double diffthreepoint(double t, double x0, double f0, double x1, double f1, double x2, double f2) { double result = 0; double a = 0; double b = 0; t = t-x0; x1 = x1-x0; x2 = x2-x0; a = (f2-f0-x2/x1*(f1-f0))/(AP.Math.Sqr(x2)-x1*x2); b = (f1-f0-a*AP.Math.Sqr(x1))/x1; result = 2*a*t+b; return result; } }