Difference between revisions of "Normal"
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A straight line passing through the point and perpendicular to the [[Tangent|tangent]] (or [[Tangent plane|tangent plane]]) of the curve (or surface) at this point. A smooth plane curve has at every point a unique normal situated in the plane of the curve. If a curve in a plane is given in rectangular coordinates by an equation $y=f(x)$, then the equation of the normal to the curve at $(x_0,y_0)$ has the form | A straight line passing through the point and perpendicular to the [[Tangent|tangent]] (or [[Tangent plane|tangent plane]]) of the curve (or surface) at this point. A smooth plane curve has at every point a unique normal situated in the plane of the curve. If a curve in a plane is given in rectangular coordinates by an equation $y=f(x)$, then the equation of the normal to the curve at $(x_0,y_0)$ has the form | ||
− | $$(x-x_0)(y-y_0)f'(x_0)=0.$$ | + | $$(x-x_0)+(y-y_0)f'(x_0)=0.$$ |
A curve in space has infinitely many normals at every point of it. These fill a certain plane (the [[Normal plane|normal plane]]). The normal lying in the [[Osculating plane|osculating plane]] is called the [[Principal normal|principal normal]]; the one perpendicular to the osculating plane is called the [[Binormal|binormal]]. | A curve in space has infinitely many normals at every point of it. These fill a certain plane (the [[Normal plane|normal plane]]). The normal lying in the [[Osculating plane|osculating plane]] is called the [[Principal normal|principal normal]]; the one perpendicular to the osculating plane is called the [[Binormal|binormal]]. |
Latest revision as of 17:15, 30 July 2014
to a curve (or surface) at a point of it
A straight line passing through the point and perpendicular to the tangent (or tangent plane) of the curve (or surface) at this point. A smooth plane curve has at every point a unique normal situated in the plane of the curve. If a curve in a plane is given in rectangular coordinates by an equation $y=f(x)$, then the equation of the normal to the curve at $(x_0,y_0)$ has the form
$$(x-x_0)+(y-y_0)f'(x_0)=0.$$
A curve in space has infinitely many normals at every point of it. These fill a certain plane (the normal plane). The normal lying in the osculating plane is called the principal normal; the one perpendicular to the osculating plane is called the binormal.
The normal at $(x_0,y_0,z_0)$ to a surface given by an equation $z=f(x,y)$ is defined by
$$\begin{cases}(x-x_0)+(z-z_0)\frac{\partial z}{\partial x}=0,\\(y-y_0)+(z-z_0)\frac{\partial z}{\partial y}=0.\end{cases}$$
If the equation of the surface has the form $\mathbf r=\mathbf r(u,v)$, then the parametric representation of the normal is
$$\mathbf R=\mathbf r+\lambda[\mathbf r_u,\mathbf r_v].$$
Comments
The notion of a normal obviously extends to $m$-dimensional submanifolds of Euclidean $n$-space $E^n$, giving an $(n-m)$-dimensional affine subspace as the normal $(n-m)$-plane to the manifold at the corresponding point. For submanifolds of (pseudo-) Riemannian manifolds, the normal planes are considered as subspaces of the tangent space of the ambient space, where orthogonality is defined by means of the (ambient) (pseudo-) Riemannian metric. See also Normal bundle; Normal plane; Normal space (to a surface).
References
[a1] | M. Berger, B. Gostiaux, "Differential geometry: manifolds, curves, and surfaces" , Springer (1988) (Translated from French) |
[a2] | H.S.M. Coxeter, "Introduction to geometry" , Wiley (1963) |
[a3] | M.P. Do Carmo, "Differential geometry of curves and surfaces" , Prentice-Hall (1976) pp. 145 |
[a4] | M. Spivak, "A comprehensive introduction to differential geometry" , 1979 , Publish or Perish pp. 1–5 |
[a5] | W. Blaschke, K. Leichtweiss, "Elementare Differentialgeometrie" , Springer (1973) |
[a6] | B.-Y. Chen, "Geometry of submanifolds" , M. Dekker (1973) |
Normal. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Normal&oldid=32593