/// <summary> /// Evaluate the spline coefficients as used /// internally by this interpolation algorithm. /// </summary> /// <param name="samplePoints">Sample Points t, sorted ascending.</param> /// <param name="sampleValues">Sample Values x(t)</param> /// <returns>Spline Coefficient Vector</returns> public static double[] EvaluateSplineCoefficients( IList <double> samplePoints, IList <double> sampleValues) { double[] derivatives = EvaluateSplineDerivatives( samplePoints, sampleValues); return(CubicHermiteSplineInterpolation.EvaluateSplineCoefficients( samplePoints, sampleValues, derivatives)); }
/// <summary> /// Evaluate the spline coefficients as used /// internally by this interpolation algorithm. /// </summary> /// <param name="samplePoints">Sample Points t, sorted ascending.</param> /// <param name="sampleValues">Sample Values x(t)</param> /// <param name="leftBoundaryCondition">Condition of the left boundary.</param> /// <param name="leftBoundary">Left boundary value. Ignored in the parabolic case.</param> /// <param name="rightBoundaryCondition">Condition of the right boundary.</param> /// <param name="rightBoundary">Right boundary value. Ignored in the parabolic case.</param> /// <returns>Spline Coefficient Vector</returns> public static double[] EvaluateSplineCoefficients( IList <double> samplePoints, IList <double> sampleValues, SplineBoundaryCondition leftBoundaryCondition, double leftBoundary, SplineBoundaryCondition rightBoundaryCondition, double rightBoundary) { double[] derivatives = EvaluateSplineDerivatives( samplePoints, sampleValues, leftBoundaryCondition, leftBoundary, rightBoundaryCondition, rightBoundary); return(CubicHermiteSplineInterpolation.EvaluateSplineCoefficients( samplePoints, sampleValues, derivatives)); }