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C# spline1dinterpolant类代码示例

原作者: [db:作者] 来自: [db:来源] 收藏 邀请

本文整理汇总了C#中spline1dinterpolant的典型用法代码示例。如果您正苦于以下问题:C# spline1dinterpolant类的具体用法?C# spline1dinterpolant怎么用?C# spline1dinterpolant使用的例子?那么恭喜您, 这里精选的类代码示例或许可以为您提供帮助。



spline1dinterpolant类属于命名空间,在下文中一共展示了spline1dinterpolant类的20个代码示例,这些例子默认根据受欢迎程度排序。您可以为喜欢或者感觉有用的代码点赞,您的评价将有助于我们的系统推荐出更棒的C#代码示例。

示例1: spline1dbuildlinear

        /*************************************************************************
        This subroutine builds linear spline interpolant

        INPUT PARAMETERS:
            X   -   spline nodes, array[0..N-1]
            Y   -   function values, array[0..N-1]
            N   -   points count, N>=2
            
        OUTPUT PARAMETERS:
            C   -   spline interpolant


        ORDER OF POINTS

        Subroutine automatically sorts points, so caller may pass unsorted array.

          -- ALGLIB PROJECT --
             Copyright 24.06.2007 by Bochkanov Sergey
        *************************************************************************/
        public static void spline1dbuildlinear(double[] x,
            double[] y,
            int n,
            ref spline1dinterpolant c)
        {
            int i = 0;

            x = (double[])x.Clone();
            y = (double[])y.Clone();

            System.Diagnostics.Debug.Assert(n>1, "Spline1DBuildLinear: N<2!");
            
            //
            // Sort points
            //
            heapsortpoints(ref x, ref y, n);
            
            //
            // Build
            //
            c.periodic = false;
            c.n = n;
            c.k = 3;
            c.x = new double[n];
            c.c = new double[4*(n-1)];
            for(i=0; i<=n-1; i++)
            {
                c.x[i] = x[i];
            }
            for(i=0; i<=n-2; i++)
            {
                c.c[4*i+0] = y[i];
                c.c[4*i+1] = (y[i+1]-y[i])/(x[i+1]-x[i]);
                c.c[4*i+2] = 0;
                c.c[4*i+3] = 0;
            }
        }
开发者ID:palefacer,项目名称:TelescopeOrientation,代码行数:56,代码来源:spline1d.cs


示例2: spline1dbuildhermite

        /*************************************************************************
        This subroutine builds Hermite spline interpolant.

        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           -   spline interpolant.


        ORDER OF POINTS

        Subroutine automatically sorts points, so caller may pass unsorted array.

          -- ALGLIB PROJECT --
             Copyright 23.06.2007 by Bochkanov Sergey
        *************************************************************************/
        public static void spline1dbuildhermite(double[] x,
            double[] y,
            double[] d,
            int n,
            ref spline1dinterpolant c)
        {
            int i = 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);
            
            //
            // Build
            //
            c.x = new double[n];
            c.c = new double[4*(n-1)];
            c.periodic = false;
            c.k = 3;
            c.n = n;
            for(i=0; i<=n-1; i++)
            {
                c.x[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.c[4*i+0] = y[i];
                c.c[4*i+1] = d[i];
                c.c[4*i+2] = (3*(y[i+1]-y[i])-2*d[i]*delta-d[i+1]*delta)/delta2;
                c.c[4*i+3] = (2*(y[i]-y[i+1])+d[i]*delta+d[i+1]*delta)/delta3;
            }
        }
开发者ID:palefacer,项目名称:TelescopeOrientation,代码行数:65,代码来源:spline1d.cs


示例3: count

        /*************************************************************************
        This subroutine builds linear spline interpolant

        INPUT PARAMETERS:
            X   -   spline nodes, array[0..N-1]
            Y   -   function values, array[0..N-1]
            N   -   points count (optional):
                    * N>=2
                    * if given, only first N points are used to build spline
                    * if not given, automatically detected from X/Y sizes
                      (len(X) must be equal to len(Y))
            
        OUTPUT PARAMETERS:
            C   -   spline interpolant


        ORDER OF POINTS

        Subroutine automatically sorts points, so caller may pass unsorted array.

          -- ALGLIB PROJECT --
             Copyright 24.06.2007 by Bochkanov Sergey
        *************************************************************************/
        public static void spline1dbuildlinear(double[] x,
            double[] y,
            int n,
            spline1dinterpolant c)
        {
            int i = 0;

            x = (double[])x.Clone();
            y = (double[])y.Clone();

            alglib.ap.assert(n>1, "Spline1DBuildLinear: N<2!");
            alglib.ap.assert(alglib.ap.len(x)>=n, "Spline1DBuildLinear: Length(X)<N!");
            alglib.ap.assert(alglib.ap.len(y)>=n, "Spline1DBuildLinear: Length(Y)<N!");
            
            //
            // check and sort points
            //
            alglib.ap.assert(apserv.isfinitevector(x, n), "Spline1DBuildLinear: X contains infinite or NAN values!");
            alglib.ap.assert(apserv.isfinitevector(y, n), "Spline1DBuildLinear: Y contains infinite or NAN values!");
            heapsortpoints(ref x, ref y, n);
            alglib.ap.assert(apserv.aredistinct(x, n), "Spline1DBuildLinear: at least two consequent points are too close!");
            
            //
            // Build
            //
            c.periodic = false;
            c.n = n;
            c.k = 3;
            c.continuity = 0;
            c.x = new double[n];
            c.c = new double[4*(n-1)+2];
            for(i=0; i<=n-1; i++)
            {
                c.x[i] = x[i];
            }
            for(i=0; i<=n-2; i++)
            {
                c.c[4*i+0] = y[i];
                c.c[4*i+1] = (y[i+1]-y[i])/(x[i+1]-x[i]);
                c.c[4*i+2] = 0;
                c.c[4*i+3] = 0;
            }
            c.c[4*(n-1)+0] = y[n-1];
            c.c[4*(n-1)+1] = c.c[4*(n-2)+1];
        }
开发者ID:KBrus,项目名称:nton-rbm,代码行数:68,代码来源:interpolation.cs


示例4: points

        /*************************************************************************
        This function builds monotone cubic Hermite interpolant. This interpolant
        is monotonic in [x(0),x(n-1)] and is constant outside of this interval.

        In  case  y[]  form  non-monotonic  sequence,  interpolant  is  piecewise
        monotonic.  Say, for x=(0,1,2,3,4)  and  y=(0,1,2,1,0)  interpolant  will
        monotonically grow at [0..2] and monotonically decrease at [2..4].

        INPUT PARAMETERS:
            X           -   spline nodes, array[0..N-1]. Subroutine automatically
                            sorts points, so caller may pass unsorted array.
            Y           -   function values, array[0..N-1]
            N           -   the number of points(N>=2).

        OUTPUT PARAMETERS:
            C           -   spline interpolant.

         -- ALGLIB PROJECT --
             Copyright 21.06.2012 by Bochkanov Sergey
        *************************************************************************/
        public static void spline1dbuildmonotone(double[] x,
            double[] y,
            int n,
            spline1dinterpolant c)
        {
            double[] d = new double[0];
            double[] ex = new double[0];
            double[] ey = new double[0];
            int[] p = new int[0];
            double delta = 0;
            double alpha = 0;
            double beta = 0;
            int tmpn = 0;
            int sn = 0;
            double ca = 0;
            double cb = 0;
            double epsilon = 0;
            int i = 0;
            int j = 0;

            x = (double[])x.Clone();
            y = (double[])y.Clone();

            
            //
            // Check lengths of arguments
            //
            alglib.ap.assert(n>=2, "Spline1DBuildMonotone: N<2");
            alglib.ap.assert(alglib.ap.len(x)>=n, "Spline1DBuildMonotone: Length(X)<N");
            alglib.ap.assert(alglib.ap.len(y)>=n, "Spline1DBuildMonotone: Length(Y)<N");
            
            //
            // Check and sort points
            //
            alglib.ap.assert(apserv.isfinitevector(x, n), "Spline1DBuildMonotone: X contains infinite or NAN values");
            alglib.ap.assert(apserv.isfinitevector(y, n), "Spline1DBuildMonotone: Y contains infinite or NAN values");
            heapsortppoints(ref x, ref y, ref p, n);
            alglib.ap.assert(apserv.aredistinct(x, n), "Spline1DBuildMonotone: at least two consequent points are too close");
            epsilon = math.machineepsilon;
            n = n+2;
            d = new double[n];
            ex = new double[n];
            ey = new double[n];
            ex[0] = x[0]-Math.Abs(x[1]-x[0]);
            ex[n-1] = x[n-3]+Math.Abs(x[n-3]-x[n-4]);
            ey[0] = y[0];
            ey[n-1] = y[n-3];
            for(i=1; i<=n-2; i++)
            {
                ex[i] = x[i-1];
                ey[i] = y[i-1];
            }
            
            //
            // Init sign of the function for first segment
            //
            i = 0;
            ca = 0;
            do
            {
                ca = ey[i+1]-ey[i];
                i = i+1;
            }
            while( !((double)(ca)!=(double)(0) || i>n-2) );
            if( (double)(ca)!=(double)(0) )
            {
                ca = ca/Math.Abs(ca);
            }
            i = 0;
            while( i<n-1 )
            {
                
                //
                // Partition of the segment [X0;Xn]
                //
                tmpn = 1;
                for(j=i; j<=n-2; j++)
                {
                    cb = ey[j+1]-ey[j];
                    if( (double)(ca*cb)>=(double)(0) )
//.........这里部分代码省略.........
开发者ID:KBrus,项目名称:nton-rbm,代码行数:101,代码来源:interpolation.cs


示例5: min

        /*************************************************************************
        This subroutine integrates the spline.

        INPUT PARAMETERS:
            C   -   spline interpolant.
            X   -   right bound of the integration interval [a, x],
                    here 'a' denotes min(x[])
        Result:
            integral(S(t)dt,a,x)

          -- ALGLIB PROJECT --
             Copyright 23.06.2007 by Bochkanov Sergey
        *************************************************************************/
        public static double spline1dintegrate(spline1dinterpolant c,
            double x)
        {
            double result = 0;
            int n = 0;
            int i = 0;
            int j = 0;
            int l = 0;
            int r = 0;
            int m = 0;
            double w = 0;
            double v = 0;
            double t = 0;
            double intab = 0;
            double additionalterm = 0;

            n = c.n;
            
            //
            // Periodic splines require special treatment. We make
            // following transformation:
            //
            //     integral(S(t)dt,A,X) = integral(S(t)dt,A,Z)+AdditionalTerm
            //
            // here X may lie outside of [A,B], Z lies strictly in [A,B],
            // AdditionalTerm is equals to integral(S(t)dt,A,B) times some
            // integer number (may be zero).
            //
            if( c.periodic && ((double)(x)<(double)(c.x[0]) || (double)(x)>(double)(c.x[c.n-1])) )
            {
                
                //
                // compute integral(S(x)dx,A,B)
                //
                intab = 0;
                for(i=0; i<=c.n-2; i++)
                {
                    w = c.x[i+1]-c.x[i];
                    m = (c.k+1)*i;
                    intab = intab+c.c[m]*w;
                    v = w;
                    for(j=1; j<=c.k; j++)
                    {
                        v = v*w;
                        intab = intab+c.c[m+j]*v/(j+1);
                    }
                }
                
                //
                // map X into [A,B]
                //
                apserv.apperiodicmap(ref x, c.x[0], c.x[c.n-1], ref t);
                additionalterm = t*intab;
            }
            else
            {
                additionalterm = 0;
            }
            
            //
            // Binary search in the [ x[0], ..., x[n-2] ] (x[n-1] is not included)
            //
            l = 0;
            r = n-2+1;
            while( l!=r-1 )
            {
                m = (l+r)/2;
                if( (double)(c.x[m])>=(double)(x) )
                {
                    r = m;
                }
                else
                {
                    l = m;
                }
            }
            
            //
            // Integration
            //
            result = 0;
            for(i=0; i<=l-1; i++)
            {
                w = c.x[i+1]-c.x[i];
                m = (c.k+1)*i;
                result = result+c.c[m]*w;
                v = w;
//.........这里部分代码省略.........
开发者ID:KBrus,项目名称:nton-rbm,代码行数:101,代码来源:interpolation.cs


示例6: spline1dlintransx

        /*************************************************************************
        This subroutine performs linear transformation of the spline argument.

        INPUT PARAMETERS:
            C   -   spline interpolant.
            A, B-   transformation coefficients: x = A*t + B
        Result:
            C   -   transformed spline

          -- ALGLIB PROJECT --
             Copyright 30.06.2007 by Bochkanov Sergey
        *************************************************************************/
        public static void spline1dlintransx(spline1dinterpolant 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];
            bool isperiodic = new bool();
            int contval = 0;

            alglib.ap.assert(c.k==3, "Spline1DLinTransX: internal error");
            n = c.n;
            x = new double[n];
            y = new double[n];
            d = new double[n];
            
            //
            // Unpack, X, Y, dY/dX.
            // Scale and pack with Spline1DBuildHermite again.
            //
            if( (double)(a)==(double)(0) )
            {
                
                //
                // Special case: A=0
                //
                v = spline1dcalc(c, b);
                for(i=0; i<=n-1; i++)
                {
                    x[i] = c.x[i];
                    y[i] = v;
                    d[i] = 0.0;
                }
            }
            else
            {
                
                //
                // General case, A<>0
                //
                for(i=0; i<=n-1; i++)
                {
                    x[i] = c.x[i];
                    spline1ddiff(c, x[i], ref v, ref dv, ref d2v);
                    x[i] = (x[i]-b)/a;
                    y[i] = v;
                    d[i] = a*dv;
                }
            }
            isperiodic = c.periodic;
            contval = c.continuity;
            if( contval>0 )
            {
                spline1dbuildhermite(x, y, d, n, c);
            }
            else
            {
                spline1dbuildlinear(x, y, n, c);
            }
            c.periodic = isperiodic;
            c.continuity = contval;
        }
开发者ID:KBrus,项目名称:nton-rbm,代码行数:79,代码来源:interpolation.cs


示例7: spline1dcopy

        /*************************************************************************
        This subroutine makes the copy of the spline.

        INPUT PARAMETERS:
            C   -   spline interpolant.

        Result:
            CC  -   spline copy

          -- ALGLIB PROJECT --
             Copyright 29.06.2007 by Bochkanov Sergey
        *************************************************************************/
        public static void spline1dcopy(spline1dinterpolant c,
            spline1dinterpolant cc)
        {
            int s = 0;
            int i_ = 0;

            cc.periodic = c.periodic;
            cc.n = c.n;
            cc.k = c.k;
            cc.continuity = c.continuity;
            cc.x = new double[cc.n];
            for(i_=0; i_<=cc.n-1;i_++)
            {
                cc.x[i_] = c.x[i_];
            }
            s = alglib.ap.len(c.c);
            cc.c = new double[s];
            for(i_=0; i_<=s-1;i_++)
            {
                cc.c[i_] = c.c[i_];
            }
        }
开发者ID:KBrus,项目名称:nton-rbm,代码行数:34,代码来源:interpolation.cs


示例8: S

        /*************************************************************************
        This subroutine calculates the value of the spline at the given point X.

        INPUT PARAMETERS:
            C   -   spline interpolant
            X   -   point

        Result:
            S(x)

          -- ALGLIB PROJECT --
             Copyright 23.06.2007 by Bochkanov Sergey
        *************************************************************************/
        public static double spline1dcalc(spline1dinterpolant c,
            double x)
        {
            double result = 0;
            int l = 0;
            int r = 0;
            int m = 0;
            double t = 0;

            alglib.ap.assert(c.k==3, "Spline1DCalc: internal error");
            alglib.ap.assert(!Double.IsInfinity(x), "Spline1DCalc: infinite X!");
            
            //
            // special case: NaN
            //
            if( Double.IsNaN(x) )
            {
                result = Double.NaN;
                return result;
            }
            
            //
            // correct if periodic
            //
            if( c.periodic )
            {
                apserv.apperiodicmap(ref x, c.x[0], c.x[c.n-1], ref t);
            }
            
            //
            // Binary search in the [ x[0], ..., x[n-2] ] (x[n-1] is not included)
            //
            l = 0;
            r = c.n-2+1;
            while( l!=r-1 )
            {
                m = (l+r)/2;
                if( c.x[m]>=x )
                {
                    r = m;
                }
                else
                {
                    l = m;
                }
            }
            
            //
            // Interpolation
            //
            x = x-c.x[l];
            m = 4*l;
            result = c.c[m]+x*(c.c[m+1]+x*(c.c[m+2]+x*c.c[m+3]));
            return result;
        }
开发者ID:KBrus,项目名称:nton-rbm,代码行数:68,代码来源:interpolation.cs


示例9: tasks


//.........这里部分代码省略.........
        Spline1DFitCubicWC()    -   fitting by Cubic splines (less flexible,
                                    more smooth)
        Spline1DFitHermite()    -   "lightweight" Hermite fitting, without
                                    invididual weights and constraints

    INPUT PARAMETERS:
        X   -   points, array[0..N-1].
        Y   -   function values, array[0..N-1].
        W   -   weights, array[0..N-1]
                Each summand in square  sum  of  approximation deviations from
                given  values  is  multiplied  by  the square of corresponding
                weight. Fill it by 1's if you don't  want  to  solve  weighted
                task.
        N   -   number of points (optional):
                * N>0
                * if given, only first N elements of X/Y/W are processed
                * if not given, automatically determined from X/Y/W sizes
        XC  -   points where spline values/derivatives are constrained,
                array[0..K-1].
        YC  -   values of constraints, array[0..K-1]
        DC  -   array[0..K-1], types of constraints:
                * DC[i]=0   means that S(XC[i])=YC[i]
                * DC[i]=1   means that S'(XC[i])=YC[i]
                SEE BELOW FOR IMPORTANT INFORMATION ON CONSTRAINTS
        K   -   number of constraints (optional):
                * 0<=K<M.
                * K=0 means no constraints (XC/YC/DC are not used)
                * if given, only first K elements of XC/YC/DC are used
                * if not given, automatically determined from XC/YC/DC
        M   -   number of basis functions (= 2 * number of nodes),
                M>=4,
                M IS EVEN!

    OUTPUT PARAMETERS:
        Info-   same format as in LSFitLinearW() subroutine:
                * Info>0    task is solved
                * Info<=0   an error occured:
                            -4 means inconvergence of internal SVD
                            -3 means inconsistent constraints
                            -2 means odd M was passed (which is not supported)
                            -1 means another errors in parameters passed
                               (N<=0, for example)
        S   -   spline interpolant.
        Rep -   report, same format as in LSFitLinearW() subroutine.
                Following fields are set:
                * RMSError      rms error on the (X,Y).
                * AvgError      average error on the (X,Y).
                * AvgRelError   average relative error on the non-zero Y
                * MaxError      maximum error
                                NON-WEIGHTED ERRORS ARE CALCULATED

    IMPORTANT:
        this subroitine doesn't calculate task's condition number for K<>0.

    IMPORTANT:
        this subroitine supports only even M's


    ORDER OF POINTS

    Subroutine automatically sorts points, so caller may pass unsorted array.

    SETTING CONSTRAINTS - DANGERS AND OPPORTUNITIES:

    Setting constraints can lead  to undesired  results,  like ill-conditioned
    behavior, or inconsistency being detected. From the other side,  it allows
    us to improve quality of the fit. Here we summarize  our  experience  with
    constrained regression splines:
    * excessive constraints can be inconsistent. Splines are  piecewise  cubic
      functions, and it is easy to create an example, where  large  number  of
      constraints  concentrated  in  small  area will result in inconsistency.
      Just because spline is not flexible enough to satisfy all of  them.  And
      same constraints spread across the  [min(x),max(x)]  will  be  perfectly
      consistent.
    * the more evenly constraints are spread across [min(x),max(x)],  the more
      chances that they will be consistent
    * the  greater  is  M (given  fixed  constraints),  the  more chances that
      constraints will be consistent
    * in the general case, consistency of constraints is NOT GUARANTEED.
    * in the several special cases, however, we can guarantee consistency.
    * one of this cases is  M>=4  and   constraints  on   the  function  value
      (AND/OR its derivative) at the interval boundaries.
    * another special case is M>=4  and  ONE  constraint on the function value
      (OR, BUT NOT AND, derivative) anywhere in [min(x),max(x)]

    Our final recommendation is to use constraints  WHEN  AND  ONLY  when  you
    can't solve your task without them. Anything beyond  special  cases  given
    above is not guaranteed and may result in inconsistency.

      -- ALGLIB PROJECT --
         Copyright 18.08.2009 by Bochkanov Sergey
    *************************************************************************/
    public static void spline1dfithermitewc(double[] x, double[] y, double[] w, int n, double[] xc, double[] yc, int[] dc, int k, int m, out int info, out spline1dinterpolant s, out spline1dfitreport rep)
    {
        info = 0;
        s = new spline1dinterpolant();
        rep = new spline1dfitreport();
        lsfit.spline1dfithermitewc(x, y, w, n, xc, yc, dc, k, m, ref info, s.innerobj, rep.innerobj);
        return;
    }
开发者ID:Ring-r,项目名称:opt,代码行数:101,代码来源:interpolation.cs


示例10: S

    /*************************************************************************
    Weighted fitting by penalized cubic spline.

    Equidistant grid with M nodes on [min(x,xc),max(x,xc)] is  used  to  build
    basis functions. Basis functions are cubic splines with  natural  boundary
    conditions. Problem is regularized by  adding non-linearity penalty to the
    usual least squares penalty function:

        S(x) = arg min { LS + P }, where
        LS   = SUM { w[i]^2*(y[i] - S(x[i]))^2 } - least squares penalty
        P    = C*10^rho*integral{ S''(x)^2*dx } - non-linearity penalty
        rho  - tunable constant given by user
        C    - automatically determined scale parameter,
               makes penalty invariant with respect to scaling of X, Y, W.

    INPUT PARAMETERS:
        X   -   points, array[0..N-1].
        Y   -   function values, array[0..N-1].
        W   -   weights, array[0..N-1]
                Each summand in square  sum  of  approximation deviations from
                given  values  is  multiplied  by  the square of corresponding
                weight. Fill it by 1's if you don't  want  to  solve  weighted
                problem.
        N   -   number of points (optional):
                * N>0
                * if given, only first N elements of X/Y/W are processed
                * if not given, automatically determined from X/Y/W sizes
        M   -   number of basis functions ( = number_of_nodes), M>=4.
        Rho -   regularization  constant  passed   by   user.   It   penalizes
                nonlinearity in the regression spline. It  is  logarithmically
                scaled,  i.e.  actual  value  of  regularization  constant  is
                calculated as 10^Rho. It is automatically scaled so that:
                * Rho=2.0 corresponds to moderate amount of nonlinearity
                * generally, it should be somewhere in the [-8.0,+8.0]
                If you do not want to penalize nonlineary,
                pass small Rho. Values as low as -15 should work.

    OUTPUT PARAMETERS:
        Info-   same format as in LSFitLinearWC() subroutine.
                * Info>0    task is solved
                * Info<=0   an error occured:
                            -4 means inconvergence of internal SVD or
                               Cholesky decomposition; problem may be
                               too ill-conditioned (very rare)
        S   -   spline interpolant.
        Rep -   Following fields are set:
                * RMSError      rms error on the (X,Y).
                * AvgError      average error on the (X,Y).
                * AvgRelError   average relative error on the non-zero Y
                * MaxError      maximum error
                                NON-WEIGHTED ERRORS ARE CALCULATED

    IMPORTANT:
        this subroitine doesn't calculate task's condition number for K<>0.

    NOTE 1: additional nodes are added to the spline outside  of  the  fitting
    interval to force linearity when x<min(x,xc) or x>max(x,xc).  It  is  done
    for consistency - we penalize non-linearity  at [min(x,xc),max(x,xc)],  so
    it is natural to force linearity outside of this interval.

    NOTE 2: function automatically sorts points,  so  caller may pass unsorted
    array.

      -- ALGLIB PROJECT --
         Copyright 19.10.2010 by Bochkanov Sergey
    *************************************************************************/
    public static void spline1dfitpenalizedw(double[] x, double[] y, double[] w, int n, int m, double rho, out int info, out spline1dinterpolant s, out spline1dfitreport rep)
    {
        info = 0;
        s = new spline1dinterpolant();
        rep = new spline1dfitreport();
        lsfit.spline1dfitpenalizedw(x, y, w, n, m, rho, ref info, s.innerobj, rep.innerobj);
        return;
    }
开发者ID:Ring-r,项目名称:opt,代码行数:74,代码来源:interpolation.cs


示例11: S

        /*************************************************************************
        This subroutine calculates the value of the spline at the given point X.

        INPUT PARAMETERS:
            C   -   spline interpolant
            X   -   point

        Result:
            S(x)

          -- ALGLIB PROJECT --
             Copyright 23.06.2007 by Bochkanov Sergey
        *************************************************************************/
        public static double spline1dcalc(ref spline1dinterpolant c,
            double x)
        {
            double result = 0;
            int l = 0;
            int r = 0;
            int m = 0;
            double t = 0;

            System.Diagnostics.Debug.Assert(c.k==3, "Spline1DCalc: internal error");
            
            //
            // correct if periodic
            //
            if( c.periodic )
            {
                apserv.apperiodicmap(ref x, c.x[0], c.x[c.n-1], ref t);
            }
            
            //
            // Binary search in the [ x[0], ..., x[n-2] ] (x[n-1] is not included)
            //
            l = 0;
            r = c.n-2+1;
            while( l!=r-1 )
            {
                m = (l+r)/2;
                if( (double)(c.x[m])>=(double)(x) )
                {
                    r = m;
                }
                else
                {
                    l = m;
                }
            }
            
            //
            // Interpolation
            //
            x = x-c.x[l];
            m = 4*l;
            result = c.c[m]+x*(c.c[m+1]+x*(c.c[m+2]+x*c.c[m+3]));
            return result;
        }
开发者ID:palefacer,项目名称:TelescopeOrientation,代码行数:58,代码来源:spline1d.cs


示例12: Spline1DFitHermiteWC

        /*************************************************************************
        Least squares fitting by Hermite spline.

        This subroutine is "lightweight" alternative for more complex and feature-
        rich Spline1DFitHermiteWC().  See Spline1DFitHermiteWC()  description  for
        more information about subroutine parameters (we don't duplicate  it  here
        because of length).

          -- ALGLIB PROJECT --
             Copyright 18.08.2009 by Bochkanov Sergey
        *************************************************************************/
        public static void spline1dfithermite(ref double[] x,
            ref double[] y,
            int n,
            int m,
            ref int info,
            ref spline1dinterpolant s,
            ref spline1dfitreport rep)
        {
            int i = 0;
            double[] w = new double[0];
            double[] xc = new double[0];
            double[] yc = new double[0];
            int[] dc = new int[0];

            if( n>0 )
            {
                w = new double[n];
                for(i=0; i<=n-1; i++)
                {
                    w[i] = 1;
                }
            }
            spline1dfithermitewc(ref x, ref y, ref w, n, ref xc, ref yc, ref dc, 0, m, ref info, ref s, ref rep);
        }
开发者ID:palefacer,项目名称:TelescopeOrientation,代码行数:35,代码来源:spline1d.cs


示例13: tasks


//.........这里部分代码省略.........
                                        more smooth)
            Spline1DFitHermite()    -   "lightweight" Hermite fitting, without
                                        invididual weights and constraints

        INPUT PARAMETERS:
            X   -   points, array[0..N-1].
            Y   -   function values, array[0..N-1].
            W   -   weights, array[0..N-1]
                    Each summand in square  sum  of  approximation deviations from
                    given  values  is  multiplied  by  the square of corresponding
                    weight. Fill it by 1's if you don't  want  to  solve  weighted
                    task.
            N   -   number of points, N>0.
            XC  -   points where spline values/derivatives are constrained,
                    array[0..K-1].
            YC  -   values of constraints, array[0..K-1]
            DC  -   array[0..K-1], types of constraints:
                    * DC[i]=0   means that S(XC[i])=YC[i]
                    * DC[i]=1   means that S'(XC[i])=YC[i]
                    SEE BELOW FOR IMPORTANT INFORMATION ON CONSTRAINTS
            K   -   number of constraints, 0<=K<M.
                    K=0 means no constraints (XC/YC/DC are not used in such cases)
            M   -   number of basis functions (= 2 * number of nodes),
                    M>=4,
                    M IS EVEN!

        OUTPUT PARAMETERS:
            Info-   same format as in LSFitLinearW() subroutine:
                    * Info>0    task is solved
                    * Info<=0   an error occured:
                                -4 means inconvergence of internal SVD
                                -3 means inconsistent constraints
                                -2 means odd M was passed (which is not supported)
                                -1 means another errors in parameters passed
                                   (N<=0, for example)
            S   -   spline interpolant.
            Rep -   report, same format as in LSFitLinearW() subroutine.
                    Following fields are set:
                    * RMSError      rms error on the (X,Y).
                    * AvgError      average error on the (X,Y).
                    * AvgRelError   average relative error on the non-zero Y
                    * MaxError      maximum error
                                    NON-WEIGHTED ERRORS ARE CALCULATED

        IMPORTANT:
            this subroitine doesn't calculate task's condition number for K<>0.

        IMPORTANT:
            this subroitine supports only even M's


        ORDER OF POINTS

        Subroutine automatically sorts points, so caller may pass unsorted array.

        SETTING CONSTRAINTS - DANGERS AND OPPORTUNITIES:

        Setting constraints can lead  to undesired  results,  like ill-conditioned
        behavior, or inconsistency being detected. From the other side,  it allows
        us to improve quality of the fit. Here we summarize  our  experience  with
        constrained regression splines:
        * excessive constraints can be inconsistent. Splines are  piecewise  cubic
          functions, and it is easy to create an example, where  large  number  of
          constraints  concentrated  in  small  area will result in inconsistency.
          Just because spline is not flexible enough to satisfy all of  them.  And
          same constraints spread across the  [min(x),max(x)]  will  be  perfectly
          consistent.
        * the more evenly constraints are spread across [min(x),max(x)],  the more
          chances that they will be consistent
        * the  greater  is  M (given  fixed  constraints),  the  more chances that
          constraints will be consistent
        * in the general case, consistency of constraints is NOT GUARANTEED.
        * in the several special cases, however, we can guarantee consistency.
        * one of this cases is  M>=4  and   constraints  on   the  function  value
          (AND/OR its derivative) at the interval boundaries.
        * another special case is M>=4  and  ONE  constraint on the function value
          (OR, BUT NOT AND, derivative) anywhere in [min(x),max(x)]

        Our final recommendation is to use constraints  WHEN  AND  ONLY  when  you
        can't solve your task without them. Anything beyond  special  cases  given
        above is not guaranteed and may result in inconsistency.

          -- ALGLIB PROJECT --
             Copyright 18.08.2009 by Bochkanov Sergey
        *************************************************************************/
        public static void spline1dfithermitewc(ref double[] x,
            ref double[] y,
            ref double[] w,
            int n,
            ref double[] xc,
            ref double[] yc,
            ref int[] dc,
            int k,
            int m,
            ref int info,
            ref spline1dinterpolant s,
            ref spline1dfitreport rep)
        {
            spline1dfitinternal(1, x, y, ref w, n, xc, yc, ref dc, k, m, ref info, ref s, ref rep);
        }
开发者ID:palefacer,项目名称:TelescopeOrientation,代码行数:101,代码来源:spline1d.cs


示例14: spline1dbuildakima

        /*************************************************************************
        This subroutine builds Akima spline interpolant

        INPUT PARAMETERS:
            X           -   spline nodes, array[0..N-1]
            Y           -   function values, array[0..N-1]
            N           -   points count, N>=5

        OUTPUT PARAMETERS:
            C           -   spline interpolant


        ORDER OF POINTS

        Subroutine automatically sorts points, so caller may pass unsorted array.

          -- ALGLIB PROJECT --
             Copyright 24.06.2007 by Bochkanov Sergey
        *************************************************************************/
        public static void spline1dbuildakima(double[] x,
            double[] y,
            int n,
            ref spline1dinterpolant 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-1];
            diff = new double[n-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];
            for(i=2; i<=n-3; i++)
            {
                if( (double)(Math.Abs(w[i-1])+Math.Abs(w[i+1]))!=(double)(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
            //
            spline1dbuildhermite(x, y, d, n, ref c);
        }
开发者ID:palefacer,项目名称:TelescopeOrientation,代码行数:78,代码来源:spline1d.cs


示例15: spline1dfithermitewc

    public static void spline1dfithermitewc(double[] x, double[] y, double[] w, double[] xc, double[] yc, int[] dc, int m, out int info, out spline1dinterpolant s, out spline1dfitreport rep)
    {
        int n;
        int k;
        if( (ap.len(x)!=ap.len(y)) || (ap.len(x)!=ap.len(w)))
            throw new alglibexception("Error while calling 'spline1dfithermitewc': looks like one of arguments has wrong size");
        if( (ap.len(xc)!=ap.len(yc)) || (ap.len(xc)!=ap.len(dc)))
            throw new alglibexception("Error while calling 'spline1dfithermitewc': looks like one of arguments has wrong size");
        info = 0;
        s = new spline1dinterpolant();
        rep = new spline1dfitreport();
        n = ap.len(x);
        k = ap.len(xc);
        lsfit.spline1dfithermitewc(x, y, w, n, xc, yc, dc, k, m, ref info, s.innerobj, rep.innerobj);

        return;
    }
开发者ID:Ring-r,项目名称:opt,代码行数:17,代码来源:interpolation.cs


示例16: Spline1DFitHermiteWC

    /*************************************************************************
    Least squares fitting by Hermite spline.

    This subroutine is "lightweight" alternative for more complex and feature-
    rich Spline1DFitHermiteWC().  See Spline1DFitHermiteWC()  description  for
    more information about subroutine parameters (we don't duplicate  it  here
    because of length).

      -- ALGLIB PROJECT --
         Copyright 18.08.2009 by Bochkanov Sergey
    *************************************************************************/
    public static void spline1dfithermite(double[] x, double[] y, int n, int m, out int info, out spline1dinterpolant s, out spline1dfitreport rep)
    {
        info = 0;
        s = new spline1dinterpolant();
        rep = new spline1dfitreport();
        lsfit.spline1dfithermite(x, y, n, m, ref info, s.innerobj, rep.innerobj);
        return;
    }
开发者ID:Ring-r,项目名称:opt,代码行数:19,代码来源:interpolation.cs


示例17: spline1dfithermite

    public static void spline1dfithermite(double[] x, double[] y, int m, out int info, out spline1dinterpolant s, out spline1dfitreport rep)
    {
        int n;
        if( (ap.len(x)!=ap.len(y)))
            throw new alglibexception("Error while calling 'spline1 

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