Directional derivative

From Wikipedia, the free encyclopedia

In mathematics, the directional derivative of a multivariate differentiable function along a given vector V at a given point P intuitively represents the instantaneous rate of change of the function, moving through P, in the direction of V. It therefore generalizes the notion of a partial derivative, in which the direction is always taken parallel to one of the coordinate axes.

The directional derivative is a special case of the Gâteaux derivative.

1 Definition
- 1.1 Properties
2 In differential geometry
3 Normal derivative
4 References
5 See also

[edit] Definition

The directional derivative of a scalar function $f(\vec{x}) = f(x_1, x_2, \ldots, x_n)$ along a vector $\vec{v} = (v_1, \ldots, v_n)$ is the function defined by the limit

$\nabla_{\vec{v}}{f}(\vec{x}) = \lim_{h \rightarrow 0}{\frac{f(\vec{x} + h\vec{v}) - f(\vec{x})}{h}}.$

Sometimes authors write D_v instead of $\nabla_v$ . If the function $f$ is differentiable at $\vec{x}$ , then the directional derivative exists along any vector $\vec{v},$ and one has

$\nabla_{\vec{v}}{f}(\vec{x}) = \nabla f(\vec{x}) \cdot \vec{v}$

where the $\nabla$ on the right denotes the gradient and $\cdot$ is the Euclidean inner product. At any point $\vec{x}$ , the directional derivative of $f$ intuitively represents the rate of change in $f$ along $\vec{v}$ at the point $\vec{x}$ . Usually directions are taken to be normalized, so $\vec{v}$ is a unit vector, although the definition above works for arbitrary (even zero) vectors.^[1]

[edit] Properties

Many of the familiar properties of the ordinary derivative hold for the directional derivative. These include, for any functions f and g defined in a neighborhood of, and differentiable at, p:

The sum rule: $\nabla_v (f + g) = \nabla_v f + \nabla_v g$
The constant factor rule: For any constant c, $\nabla_v (cf) = c\nabla_v f$
The product rule (or Leibniz rule): $\nabla_v (fg) = g\nabla_v f + f\nabla_v g$
The chain rule: If g is differentiable at p and h is differentiable at g(p), then

$\nabla_v h\circ g (p) = h'(g(p)) \nabla_v g (p)$

[edit] In differential geometry

Let M be a differentiable manifold and p a point of M. Suppose that f is function defined in a neighborhood of p, and differentiable at p. If v is a tangent vector to M at p, then the directional derivative of f along v, denoted variously as $\nabla_v f(p)$ (see covariant derivative), $L v f (p)$ (see Lie derivative), or $v p (f)$ (see Tangent space#Definition via derivations), can be defined as follows. Let γ : [-1,1] → M be a differentiable curve with γ(0) = p and γ^′(0) = v. Then the directional derivative is defined by

$\nabla_v f(p) = \left.\frac{d}{d\tau} f\circ\gamma(\tau)\right|_{\tau=0}$

This definition can be proven independent of the choice of γ, provided γ is selected in the prescribed manner so that γ'(0) = v.

[edit] Normal derivative

A normal derivative is a directional derivative taken in the direction normal (that is, orthogonal) to some surface in space, or more generally along a normal vector field orthogonal to some hypersurface. See for example Neumann boundary condition. If the normal direction is denoted by $\vec{n}$ , then the directional derivative of a function ƒ is sometimes denoted as $\frac{ \partial f}{\partial n}$ .

[edit] References

^ See Tom Apostol (1974). Mathematical Analysis. Addison-Wesley, 344-345. ISBN 0-201-00288-4.

Directional derivative

From Wikipedia, the free encyclopedia

Contents

[edit] Definition

[edit] Properties

[edit] In differential geometry

[edit] Normal derivative

[edit] References

[edit] See also

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