Line integral: Difference between revisions

The Curve, Line, Path or Contour integral expands the standard integral term for the Integration in the complex plane (Complex Analysis) or in the multidimensional space ${\displaystyle {ℝ}^n}$ or ${\displaystyle {ℂ}^n}$. The path, the line or the curve, via which is integrated, is called the integration path^[1]. The line integral over a closed path are written with the symbol ${\displaystyle \oint }$.

A path $\gamma :[a,b]\to {ℝ}^n$ is given which is imaged from an interval (e.g. interpreted as a time interval) into the vector space ${ℝ}^n$. $\gamma (t)\in {ℝ}^n$ indicates the place where the value is $t\in [a,b]$. The difference is

• Line integral first type and
• Line integral second type.

The path integral of a continuous Function

$f:{ℝ}^n\to ℝ$

along a continuously differentiable piece path $\gamma :[a,b]\to {ℝ}^n$ is defined as

$${\displaystyle \underset{\gamma }{\int }f\mathrm{d}s:=\underset{a}{\overset{b}{\int }}f(\gamma (t))\Vert {\gamma }^{\prime }(t){\Vert }_2\mathrm{d}t.}$$

$\gamma \text{'}$ refers to the derivation from $\gamma$ to $t$. $\gamma (t)\in {ℝ}^n$ and $\gamma \text{'}(t)\in {ℝ}^n$ are a vectors. The derivation vector $\gamma \text{'}(t)\in {ℝ}^n$ indicates the change behavior in each component function of $\gamma =({\gamma }_1,\dots ,{\gamma }_n)$.

The component functions ${\gamma }_i:[a,b]\to ℝ$ are illustrations for which the derivation with the knowledge from the real analysis can be calculated.

A differentiable path is defined first $\gamma$ with

$${\displaystyle \begin{array}{cccc}\gamma :& [0,2\pi ]& \to & {ℝ}^2\\ & t& \mapsto & \gamma \left(t\right)=\left(\begin{array}{c}5\cdot \cos (t)\\ 3\cdot \sin (t)\end{array}\right)\end{array}}$$

The track of the path forms an ellipse with the half axes 5 and 3.

The derivation $\gamma \text{'}$ of the path $\gamma$ results directly from the derivation of the component functions

$${\displaystyle \begin{array}{cccc}{\gamma }^{\prime }:& [0,2\pi ]& \to & {ℝ}^2\\ & t& \mapsto & {\gamma }^{\prime }\left(t\right)=\left(\begin{array}{c}-5\cdot \sin (t)\\ 3\cdot \cos (t)\end{array}\right)\end{array}}$$

Now a vector is $\gamma (t)=(\cos (t),\sin (t),t)\in {ℝ}^3$ and $\gamma \text{'}(t)=(-\sin (t),\cos (t),1)\in {ℝ}^3$. The derivation vector $\gamma \text{'}(t)\in {ℝ}^3$ indicates the change behavior in each component function of $\gamma =({\gamma }_1,{\gamma }_2,{\gamma }_3)$.

Draw the trail of the path in ${ℝ}^2$ (Ellipse) and plotted the trail of the path in ${ℝ}^3$ with CAS4Wiki plots.

$\Vert {\gamma }^{\prime }(t){\Vert }_2$ indicates the Euclidian norm of the vector $\gamma \text{'}(t)\in {ℝ}^n$.

The image set $\text{trace}(\gamma ):=𝒞:=\gamma ([a,b])$ of one piece differentiable curve in ${ℝ}^n$ should not be confused with the graph of a curve which is a part of the $[a,b]\times {ℝ}^n$.

• An example of such a function $f$ is a scalar field with cartesischen coordinaten.
• A path $\gamma$ can pass through a curve $𝒞$ either as a whole or only in sections several times.
• For $f\equiv 1$, the path integral of the first type gives the length of the path $\gamma$.
• The path $\gamma$ forms, inter alia $a\in ℝ$ on the starting point of the curve and $b\in ℝ$ on its end point.
• $t\in [a,b]$ is an element of the definition set of $\gamma$ and is generally not' for time. $\mathrm{d}t$ is the corresponding Differential.

File:Line integral of vector field.gif

The line integral over a continuous gradient vector field

$𝐟:{ℝ}^n\to {ℝ}^n$

with a curve also parameterized in this way is defined as the integral over the scalar product of $𝐟\circ \gamma$ and $\gamma {}^{\prime }$:

$\underset{\gamma }{\int }𝐟(𝐱)\cdot \mathrm{d}𝐱:=\underset{a}{\overset{b}{\int }}⟨𝐟(\gamma (t)),{\gamma }^{\prime }(t)⟩\mathrm{d}t$

If $\gamma :[a,b]\to {ℝ}^n$ and $\eta :[c,d]\to {ℝ}^n$ 'simplified' (d. h, ${\gamma }_{|(a,b)}$ and ${\eta }_{|(c,d)}$ are identical This justifies the name curve integral; if the direction of integration is visible or irrelevant, the path in the notation can be suppressed.

Since a curve $𝒞$ is the image of a path $\gamma$, the definitions of the curve integrals essentially correspond to the path integrals.

$\underset{𝒞}{\int }f\mathrm{d}s:=\underset{a}{\overset{b}{\int }}f(\gamma (t))\cdot \Vert {\gamma }^{\prime }(t){\Vert }_2\mathrm{d}t$

$\underset{𝒞}{\int }𝐟(𝐱)\cdot \mathrm{d}𝐱:=\underset{a}{\overset{b}{\int }}⟨𝐟(\gamma (t)),{\gamma }^{\prime }(t)⟩\mathrm{d}t$

A special case is again the length of the curve $𝒞$ parameterized by $\gamma$ :

$ℒ(𝒞)=\underset{𝒞}{\int }1\mathrm{d}s=\underset{a}{\overset{b}{\int }}\Vert {\gamma }^{\prime }(t){\Vert }_2\mathrm{d}t$

The expression occurring in the first type of curves

$\mathrm{d}s=\Vert {\gamma }^{\prime }(t){\Vert }_2\mathrm{d}t$

is called scalar path element' or 'length element.The expression occurring in the second type of curve integrals

$${\displaystyle \mathrm{d}𝐱={\gamma }^{\prime }(t)\mathrm{d}t}$$

is called 'vectorial path element'.

Be $\underset{\gamma }{\int }𝐟(𝐱)$, $\underset{\gamma }{\int }𝐠(𝐱)$ Curve integrals of the same type (i.e. either both first or second type), be the original image of the two functions $𝐟$ and $𝐠$ of the same dimension and be (698104789). The following rules apply to $\alpha$, $\beta \in ℝ$ and $c\in \mathbb{[}a,b]$:

• $\alpha \underset{\gamma }{\int }𝐟(𝐱)+\beta \underset{\gamma }{\int }𝐠(𝐱)=\underset{\gamma }{\int }(\alpha 𝐟(𝐱)+\beta 𝐠(𝐱))$
• $\underset{\gamma }{\int }𝐟(𝐱)=\underset{\gamma {|}_{[a,c]}}{\int }𝐟(𝐱)+\underset{\gamma {|}_{[c,b]}}{\int }𝐟(𝐱)$

If $\gamma$ is a closed way, you write

instead of ${\displaystyle \underset{\gamma }{\int }}$ also ${\displaystyle \underset{\gamma }{{\displaystyle \oint }}}$

and similar for closed curves $𝒞$

instead of ${\displaystyle \underset{𝒞}{\int }}$ also ${\displaystyle \underset{𝒞}{{\displaystyle \oint }}}$.

With the circle in the Integral one would like to make clear that $\gamma$ is closed. The only difference is in the notation.

• If $𝒞$ is the graph of a function $f:[a,b]\to ℝ$, this curve will be passed through the path

$\gamma :[a,b]\to {ℝ}^2,t\mapsto (t,f(t))$

parametrized with ${\displaystyle (t,f(t))\in {ℝ}^3}$. About

$\Vert \gamma {}^{\prime }(t){\Vert }_2=\sqrt{1+f^{\prime }(t{)}^2}$

the length of the curve is equal

$\underset{𝒞}{\int }\mathrm{d}s=\underset{a}{\overset{b}{\int }}\sqrt{1+f^{\prime }(t{)}^2}\mathrm{d}t.$

• A ellipse with large half-axis $a$ and small half-axis $b$ is parameterized by $(a\cos t,b\sin t)$ for $t\in [0,2\pi ]$. Your scope is therefore

$\underset{0}{\overset{2\pi }{\int }}\sqrt{a^2{\sin }^{2}t+b^2{\cos }^{2}t}\mathrm{d}t=4a\underset{0}{\overset{\frac{\pi }{2}}{\int }}\sqrt{1-{\epsilon }^2{\cos }^{2}t}\mathrm{d}t$.

In this case $\epsilon$ refers to the numerical eccenttricity $\sqrt{1-b^2/a^2}$ of the ellipse. The integral on the right is referred to as elliptic tntegral due to this connection.

If a vector field $𝐅$ is a Gradient field, i.e.

$\mathrm{\nabla }V=𝐅$,

This applies to derivation of function composition of $V$ and $𝐫(t)$

$\frac{\mathrm{d}}{\mathrm{d}t}V(𝐫(t))=\mathrm{\nabla }V(𝐫(t))\cdot \dot{𝐫}(t)=𝐅(𝐫(t))\cdot \dot{𝐫}(t)$,

which exactly corresponds to the integral of the path integral over $𝐅$ to $𝐫(t)$.

This follows for a given curve $𝒮$

$\underset{𝒮}{\int }𝐅(𝐱)\cdot \mathrm{d}𝐱=\underset{a}{\overset{b}{\int }}𝐅(𝐫(t))\cdot \dot{𝐫}(t)\mathrm{d}t=\underset{a}{\overset{b}{\int }}\frac{\mathrm{d}}{\mathrm{d}t}V(𝐫(t))\mathrm{d}t=V(𝐫(b))-V(𝐫(a)).$

The following image show two arbitrary curves ${\displaystyle S1}$ and ${\displaystyle S2}$ in a Gradient vector field connecting point ${\displaystyle 1}$ with point ${\displaystyle 2}$.

This means that the integral of $𝐅$ over $𝒮$ depends solely on points $𝐫(b)$ and $𝐫(a)$ and the path between them is irrelevant to the result. For this reason, the integral of a gradient field is referred to as “displaced”.

In particular, the ring integral applies to the closed curve $𝒮$ with two arbitrary paths ${𝒮}_1$ and ${𝒮}_2$:

$\underset{𝒮}{{\displaystyle \oint }}𝐅(𝐱)\mathrm{d}𝐱=\underset{1,{𝒮}_1}{\overset{2}{\int }}𝐅(𝐱)\mathrm{d}𝐱+\underset{2,{𝒮}_2}{\overset{1}{\int }}𝐅(𝐱)\mathrm{d}𝐱=0$

This is particularly important in Physics, since, for example, the Gravitation has these properties. Since the energy in these force fields is always a conservation variable, they are referred to in physics as conservative force.

The scalar field $V$ is the Potential or the potential Energy. Conservative force fields receive the mechanical energy, i.e. the sum of kinetic Energy and potential energy. According to the above integral, a work of 0 J is applied on a closed curve overall.

Path independence can also be shown with the application of the Integrability condition.

if the vector field is not possible as a gradient field only in a (small) environment $U$ of a point, the closed path integral of curves outside $U$ is proportional to the number of turns around this point and otherwise independent of the exact curve (see Algebraic Topology: Methodology).

If ${ℝ}^n$ is replaced by $ℂ$, complex path integrals are treated which are treated in the Complex Analysis.

• Harro Heuser: Lehrbuch der Analysis – Teil 2. 1981, 5. Auflage, Teubner 1990, ISBN 3-519-42222-0. p. 369, Theorem 180.1; p. 391, Theorem 184.1; p. 393, Theorem 185.1.

• Complex Analysis
• Topological vector space

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