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CGAL 5.3.2 - 2D and 3D Linear Geometry Kernel
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CGAL 5.3.2 - 2D and 3D Linear Geometry Kernel
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AdaptableFunctor (with two arguments)Operations | |
| Kernel::FT | operator() (const Kernel::Weighted_point_2 &pw, const Kernel::Weighted_point_2 &qw) const |
returns the power product of pw and qw. More... | |
| Kernel::FT Kernel::ComputePowerProduct_2::operator() | ( | const Kernel::Weighted_point_2 & | pw, |
| const Kernel::Weighted_point_2 & | qw | ||
| ) | const |
returns the power product of pw and qw.
Let \( {p}^{(w)} = (p,w_p), p\in\mathbb{R}^2, w_p\in\mathbb{R}\) and \( {q}^{(w)}=(q,w_q), q\in\mathbb{R}^2, w_q\in\mathbb{R}\) be two weighted points.
The power product, also called power distance between \( {p}^{(w)}\) and \( {q}^{(w)}\) is defined as
\[ \Pi({p}^{(w)},{q}^{(w)}) = {\|{p-q}\|^2-w_p-w_q} \]
where \( \|{p-q}\|\) is the Euclidean distance between \( p\) and \( q\).
The weighted points \( {p}^{(w)}\) and \( {q}^{(w)}\) are said to be orthogonal iff \( \Pi{({p}^{(w)},{q}^{(w)})} = 0\).
Three weighted points have, in 2D, a unique common orthogonal weighted point called the power circle. The power segment will denote the weighted point orthogonal to two weighted points on the line defined by these two points.
1.8.13