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Mathematics-Online lexicon:

Potential Functions, Gradient Fields and Line Integrals


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Let $ \Phi $ be a vector field and let $ u$ be a differentiable scalar function defined on a region $ D .$ Suppose that

$\displaystyle \Phi = \operatorname{grad} u
\, .
$

Then $ \Phi $ is called a gradient field and $ u$ is called a potential function of $ \Phi .$ The vector field $ \Phi $ is conservative, i.e. each line integral of $ \Phi $ in $ D$ is independent of the path.

More precisely let $ A$ and $ B$ be points in $ D .$ Let $ \sigma: [a,b] \longrightarrow D $ be a parametrization of a curve $ C$ in $ D$ beginning in $ \sigma (a) = A $ and ending with $ \sigma (b) = B .$ Then

$\displaystyle \int\limits_{C} \Phi dx \ = \ u(B)-u(A) \ \,,
$

i.e. the line integral is just the difference between the potentials at $ B$ and $ A .$

In particular for any closed path $ C$ in $ D$

$\displaystyle \int\limits_{C}\Phi \cdot dx \ = \ 0 .$

()

Examples:


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  automatically generated 6/15/2005