示例#1
0
        static element ComputeMaxError(vector[] d, int first, int last, cubicbezier bezCurve, element[] u, out int splitPoint)
        {
            var     sp       = (last - first + 1) / 2;
            element maxDist2 = 0;

            for (var i = first + 1; i < last; i++)
            {
                var dist2 = (bezCurve.Interpolate(u[i - first]) - d[i]).LengthSquare;
                if (maxDist2 <= dist2)
                {
                    maxDist2 = dist2;
                    sp       = i;
                }
            }
            splitPoint = sp;
            return(maxDist2);
        }
示例#2
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        /// <summary>
        /// Use Newton-Raphson iteration to find better root.
        /// </summary>
        /// <param name="Q">Current fitted curve</param>
        /// <param name="P">Digitized point</param>
        /// <param name="u">Parameter value for <see cref="P"/></param>
        /// <returns>パラメータ</returns>
        static element NewtonRaphsonRootFind(cubicbezier Q, vector P, element u)
        {
            /* Compute Q(u)	*/
            var Q_u = Q.Interpolate(u);

            /* Generate control vertices for Q'	*/
            var Q1 = new vector[3];                /*  Q' and Q''			*/

            for (int i = 0; i <= 2; i++)
            {
                Q1[i] = (Q[i + 1] - Q[i]) * 3;
            }

            /* Generate control vertices for Q'' */
            var Q2 = new vector[2];

            for (int i = 0; i <= 1; i++)
            {
                Q2[i] = (Q1[i + 1] - Q1[i]) * 2;
            }

            /* Compute Q'(u) and Q''(u)	*/
            var Q1_u = Interpolate2(u, Q1[0], Q1[1], Q1[2]);
            var Q2_u = Interpolate1(u, Q2[0], Q2[1]);

            /* Compute f(u)/f'(u) */
            var Q_u_P       = Q_u - P;
            var numerator   = Q_u_P.Dot(Q1_u);
            var denominator = Q1_u.LengthSquare + Q_u_P.Dot(Q2_u);

            if (denominator == 0)
            {
                return(u);
            }

            /* u = u - f(u)/f'(u) */
            return(u - numerator / denominator);
        }
示例#3
0
        /// <summary>
        /// 最小二乗法を用いて指定範囲のベジェコントロールポイントを探す
        /// </summary>
        /// <param name="d">頂点列</param>
        /// <param name="first">範囲開始インデックス</param>
        /// <param name="last">範囲終了インデックス</param>
        /// <param name="uPrime">指定範囲内のパラメータ</param>
        /// <param name="tHat1">範囲開始部分のベクトル</param>
        /// <param name="tHat2">範囲終了部分のベクトル</param>
        /// <returns>3次ベジェ曲線</returns>
        static cubicbezier GenerateBezier(vector[] d, int first, int last, element[] uPrime, vector tHat1, vector tHat2)
        {
            var nPts        = last - first + 1;
            var tHat1LenDiv = tHat1.Length;
            var tHat2LenDiv = tHat2.Length;

            if (tHat1LenDiv != 0)
            {
                tHat1LenDiv = 1 / tHat1LenDiv;
            }
            if (tHat2LenDiv != 0)
            {
                tHat2LenDiv = 1 / tHat2LenDiv;
            }

            /* Compute the A's	*/
            var A = new vector[nPts, 2];              /* Precomputed rhs for eqn	*/

            for (int i = 0; i < nPts; i++)
            {
                var u  = uPrime[i];
                var ui = 1 - u;
                var b1 = 3 * u * ui * ui;
                var b2 = 3 * u * u * ui;
                A[i, 0] = tHat1 * (b1 * tHat1LenDiv);
                A[i, 1] = tHat2 * (b2 * tHat2LenDiv);
            }

            /* Create the C and X matrices	*/
            var    C = new element[2, 2]; /* Matrix C		*/
            var    X = new element[2];    /* Matrix X			*/
            vector tmp;                   /* Utility variable		*/

            for (int i = 0; i < nPts; i++)
            {
                C[0, 0] += A[i, 0].Dot(A[i, 0]);
                C[0, 1] += A[i, 0].Dot(A[i, 1]);
                C[1, 0]  = C[0, 1];
                C[1, 1] += A[i, 1].Dot(A[i, 1]);

                var df = d[first];
                var dl = d[last];
                tmp = d[first + i] - Interpolate3(uPrime[i], df, df, dl, dl);

                X[0] += A[i, 0].Dot(tmp);
                X[1] += A[i, 1].Dot(tmp);
            }

            /* Compute the determinants of C and X	*/
            var det_C0_C1 = C[0, 0] * C[1, 1] - C[1, 0] * C[0, 1];
            var det_C0_X  = C[0, 0] * X[1] - C[1, 0] * X[0];
            var det_X_C1  = X[0] * C[1, 1] - X[1] * C[0, 1];

            /* Finally, derive alpha values	*/
            var alpha_l = det_C0_C1 == 0 ? 0 : det_X_C1 / det_C0_C1;
            var alpha_r = det_C0_C1 == 0 ? 0 : det_C0_X / det_C0_C1;

            /* If alpha negative, use the Wu/Barsky heuristic (see text) */

            /* (if alpha is 0, you get coincident control points that lead to
             * divide by zero in any subsequent NewtonRaphsonRootFind() call. */
            var bezCurve  = new cubicbezier();
            var segLength = (d[last] - d[first]).Length;
            var epsilon   = (element)1.0e-6 * segLength;

            if (alpha_l < epsilon || alpha_r < epsilon)
            {
                /* fall back on standard (probably inaccurate) formula, and subdivide further if needed. */
                element dist = segLength / 3;
                bezCurve.P0 = d[first];
                bezCurve.P3 = d[last];
                bezCurve.P1 = bezCurve.P0 + tHat1 * (dist * tHat1LenDiv);
                bezCurve.P2 = bezCurve.P3 + tHat2 * (dist * tHat2LenDiv);
                return(bezCurve);
            }

            /*  First and last control points of the Bezier curve are */
            /*  positioned exactly at the first and last data points */
            /*  Control points 1 and 2 are positioned an alpha distance out */
            /*  on the tangent vectors, left and right, respectively */
            bezCurve.P0 = d[first];
            bezCurve.P3 = d[last];
            bezCurve.P1 = bezCurve.P0 + tHat1 * (alpha_l * tHat1LenDiv);
            bezCurve.P2 = bezCurve.P3 + tHat2 * (alpha_r * tHat2LenDiv);
            return(bezCurve);
        }
示例#4
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        /// <summary>
        /// Given set of points and their parameterization, try to find a better parameterization.
        /// </summary>
        /// <param name="d">Array of digitized points</param>
        /// <param name="first">Indices defining region</param>
        /// <param name="last">Indices defining region</param>
        /// <param name="u">Current parameter values</param>
        /// <param name="bezCurve">Current fitted curve</param>
        /// <returns>パラメータ列</returns>
        static element[] Reparameterize(vector[] d, int first, int last, element[] u, cubicbezier bezCurve)
        {
            var uPrime = new element[last - first + 1];                 /*  New parameter values	*/

            for (int i = first; i <= last; i++)
            {
                var j = i - first;
                uPrime[j] = NewtonRaphsonRootFind(bezCurve, d[i], u[j]);
            }
            return(uPrime);
        }
示例#5
0
        /// <summary>
        /// 指定された頂点列の指定範囲にベジェ曲線をフィットさせる
        /// </summary>
        /// <param name="d">フィット元頂点列</param>
        /// <param name="first"><see cref="d"/>内の範囲開始インデックス</param>
        /// <param name="last"><see cref="d"/>内の範囲終了インデックス</param>
        /// <param name="tHat1">指定範囲開始点の長さ1の順方向ベクトル</param>
        /// <param name="tHat2">指定範囲終了点の長さ1の逆方向ベクトル</param>
        /// <param name="error">フィット時許容誤差の二乗</param>
        /// <param name="result">ここにベジェ曲線列が追加される</param>
        static void FitCubic(vector[] d, int first, int last, vector tHat1, vector tHat2, element error, List <cubicbezier> result)
        {
            cubicbezier bezCurve;                /*Control points of fitted Bezier curve*/
            var         nPts = last - first + 1; /*  Number of points in subset  */

            /*  Use heuristic if region only has two points in it */
            if (nPts == 2)
            {
                bezCurve    = new cubicbezier();
                bezCurve.P0 = d[first];
                bezCurve.P3 = d[last];

                var dist = (d[last] - d[first]).Length / 3;
                bezCurve.P1 = bezCurve.P0 + tHat1.Relength(dist);
                bezCurve.P2 = bezCurve.P3 + tHat2.Relength(dist);
                result.Add(bezCurve);
                return;
            }

            /*  Parameterize points, and attempt to fit curve */
            var u = ChordLengthParameterize(d, first, last);

            bezCurve = GenerateBezier(d, first, last, u, tHat1, tHat2);

            /*  Find max deviation of points to fitted curve */
            int splitPoint;             /*  Point to split point set at	 */
            var maxError = ComputeMaxError(d, first, last, bezCurve, u, out splitPoint);

            if (maxError < error)
            {
                result.Add(bezCurve);
                return;
            }


            /*  If error not too large, try some reparameterization  */
            /*  and iteration */
            var iterationError = error * error;             /*Error below which you try iterating  */

            if (maxError < iterationError)
            {
                var maxIterations = 4;                 /*  Max times to try iterating  */
                for (var i = 0; i < maxIterations; i++)
                {
                    var uPrime = Reparameterize(d, first, last, u, bezCurve);
                    bezCurve = GenerateBezier(d, first, last, uPrime, tHat1, tHat2);
                    maxError = ComputeMaxError(d, first, last, bezCurve, uPrime, out splitPoint);
                    if (maxError < error)
                    {
                        result.Add(bezCurve);
                        return;
                    }
                    u = uPrime;
                }
            }

            /* Fitting failed -- split at max error point and fit recursively */
            var tHatCenter = ((d[splitPoint - 1] - d[splitPoint + 1]) * (element)0.5).Normalize();

            FitCubic(d, first, splitPoint, tHat1, tHatCenter, error, result);

            tHatCenter = -tHatCenter;

            FitCubic(d, splitPoint, last, tHatCenter, tHat2, error, result);
        }