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92 lines
3.9 KiB
C++
92 lines
3.9 KiB
C++
#include "FITKCircleAlg.h"
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#include "FITKVec3DAlg.h"
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#include <cmath>
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namespace Core
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{
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QPair<FITKPoint, FITKPoint> GetCircleCenter(const FITKPoint& p1, const FITKPoint& p2,
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const FITKPoint& another, const double r)
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{
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QPair<FITKPoint, FITKPoint> centers;
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//弦 P1 P2中点
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const FITKPoint mid((p1.x() + p2.x()) / 2, (p1.y() + p2.y()) / 2, (p1.z() + p2.z()) / 2);
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//弦长度的一半,与半径可形成直角三角形
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const double d = Distance(p1, mid);
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if (d > r) return centers;
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//直角三角形的另一边长度
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const double offset = sqrt(r*r - d * d);
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const FITKVec3D m2(p2, mid);
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const FITKVec3D mo(another, mid);
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const FITKVec3D mz = CrossProduct(m2, mo);
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//半径方向
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FITKVec3D dir = CrossProduct(m2, mz);
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dir.normalize();
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//弦中心点向两侧偏移分别得到两个圆心位置
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centers.first = FITKPoint(mid.x() + dir.x()* offset,
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mid.y() + dir.y()* offset,
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mid.z() + dir.z()* offset);
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centers.second = FITKPoint(mid.x() - dir.x()* offset,
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mid.y() - dir.y()* offset,
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mid.z() - dir.z()* offset);
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return centers;
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}
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FITKPoint GetMidPointOnArc(const FITKPoint& p1, const FITKPoint& p2, const FITKPoint& center, const double r)
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{
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//弦 P1 P2中点
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const FITKPoint mid((p1.x() + p2.x()) / 2, (p1.y() + p2.y()) / 2, (p1.z() + p2.z()) / 2);
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const double d = Distance(p1, mid);
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if (d >= r) return FITKPoint();
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//圆心到弦中点的方向
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FITKVec3D dir(mid,center);
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dir.normalize();
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//圆心偏移
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return Add(center, dir, 1, r);
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}
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void GetCircleBy3Points(const FITKPoint& p1, const FITKPoint& p2, const FITKPoint& p3,
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FITKPoint& center, FITKVec3D& normal, double& r)
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{
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//计算圆心
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double a1 = (p1.y()*p2.z() - p2.y() * p1.z() - p1.y() * p3.z() + p3.y() * p1.z() + p2.y() * p3.z() - p3.y() * p2.z()),
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b1 = -(p1.x()*p2.z() - p2.x() * p1.z() - p1.x() * p3.z() + p3.x() * p1.z() + p2.x() * p3.z() - p3.x() * p2.z()),
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c1 = (p1.x()*p2.y() - p2.x() * p1.y() - p1.x() * p3.y() + p3.x() * p1.y() + p2.x() * p3.y() - p3.x() * p2.y()),
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d1 = -(p1.x()*p2.y()*p3.z() - p1.x() * p3.y()*p2.z() - p2.x() * p1.y()*p3.z() + p2.x() * p3.y()*p1.z() + p3.x() * p1.y()*p2.z() - p3.x() * p2.y()*p1.z());
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double a2 = 2 * (p2.x() - p1.x()),
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b2 = 2 * (p2.y() - p1.y()),
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c2 = 2 * (p2.z() - p1.z()),
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d2 = p1.x() * p1.x() + p1.y() * p1.y() + p1.z() * p1.z() - p2.x() * p2.x() - p2.y() * p2.y() - p2.z() * p2.z();
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double a3 = 2 * (p3.x() - p1.x()),
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b3 = 2 * (p3.y() - p1.y()),
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c3 = 2 * (p3.z() - p1.z()),
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d3 = p1.x() * p1.x() + p1.y() * p1.y() + p1.z() * p1.z() - p3.x() * p3.x() - p3.y() * p3.y() - p3.z() * p3.z();
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double x = -(b1*c2*d3 - b1 * c3*d2 - b2 * c1*d3 + b2 * c3*d1 + b3 * c1*d2 - b3 * c2*d1)
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/ (a1*b2*c3 - a1 * b3*c2 - a2 * b1*c3 + a2 * b3*c1 + a3 * b1*c2 - a3 * b2*c1);
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double y = (a1*c2*d3 - a1 * c3*d2 - a2 * c1*d3 + a2 * c3*d1 + a3 * c1*d2 - a3 * c2*d1)
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/ (a1*b2*c3 - a1 * b3*c2 - a2 * b1*c3 + a2 * b3*c1 + a3 * b1*c2 - a3 * b2*c1);
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double z = -(a1*b2*d3 - a1 * b3*d2 - a2 * b1*d3 + a2 * b3*d1 + a3 * b1*d2 - a3 * b2*d1)
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/ (a1*b2*c3 - a1 * b3*c2 - a2 * b1*c3 + a2 * b3*c1 + a3 * b1*c2 - a3 * b2*c1);
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//计算半径
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r = sqrt((p1.x() - x)*(p1.x() - x) + (p1.y() - y)*(p1.y() - y) + (p1.z() - z)*(p1.z() - z));
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//返回圆心
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center = FITKPoint(x, y, z);
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//计算三个点法向
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const FITKVec3D v1(p1, p2);
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const FITKVec3D v2(p1, p3);
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normal = CrossProduct(v1, v2);
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normal.normalize();
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}
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}
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