Line integral
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In mathematics, a line integral (in rare cases called a path integral) is an integral where the function to be integrated is evaluated along a curve. Various different line integrals are in use. In the case of a closed curve it is also called a contour integral.
Complex analysis
The line integral is a fundamental tool in complex analysis. Suppose U is an open subset of C, γ : [a, b] → U is a rectifiable curve and f : U → C is a function. Then the line integral
- [\int_\gamma f(z)\,dz]
- [\sum_ f(\gamma(t_k)) ( \gamma(t_k) - \gamma(t_) ).]
If γ is a continuously differentiable curve, the line integral can be evaluated as an integral of a function of a real variable:
- [\int_\gamma f(z)\,dz=\int_a^b f(\gamma(t))\,\gamma\,'(t)\,dt.]
- [\oint_\gamma f(z)\,dz]
Important statements about contour integrals are the Cauchy integral theorem and Cauchy's integral formula.
Because of the residue theorem, one can often use contour integrals in the complex plane to find integrals of real-valued functions of a real variable (see residue theorem for an example).
Example
Consider the function f(z)=1/z, and let the contour C be the unit circle about 0, which can be parametrized by eit, with t in [0, 2π]. Substituting, we find
- [\oint_C f(z)\,dz = \int_0^ } ie^\,dt = i\int_0^ e^e^\,dt]
- [=i\int_0^\,dt = i(2\pi-0)=2\pi i]
Vector calculus
In qualitative terms, a line integral in vector calculus can be thought of as a measure of the effect of a given vector field along a given curve.Definition
For some scalar field f : Rn → R, the line integral on a curve C, parametrized as r(t) with t ∈ [a, b], is defined by
- [\int_C f\ ds = \int_a^b f(\mathbf(t)) |\mathbf'(t)|\, dt.]
For a vector field F : Rn → Rn, the line integral on a curve C, parametrized as r(t) with t ∈ [a, b], is defined by
- [\int_C \mathbf(\mathbf)\cdot\,d\mathbf = \int_a^b \mathbf(\mathbf(t))\cdot\mathbf'(t)\,dt.]
Path independence
If a vector field F is the gradient of a scalar field G, that is,
- [\nabla G = \mathbf,]
- [\frac(t))} = \nabla G(\mathbf(t)) \cdot \mathbf'(t) = \mathbf(\mathbf(t)) \cdot \mathbf'(t)]
- [\int_C \mathbf(\mathbf)\cdot\,d\mathbf = \int_a^b \mathbf(\mathbf(t))\cdot\mathbf'(t)\,dt = \int_a^b \frac(t))}\,dt = G(\mathbf(b)) - G(\mathbf(a)).]
For this reason, a vector field which is the gradient of a scalar field is called path independent.
Applications
The line integral has many uses in physics. For example, the work done on a particle traveling on a curve C inside a force field represented as a vector field F is the line integral of F on C.Relationship with the line integral in complex analysis
Viewing complex numbers as 2D vectors, the line integral in 2D of a vector field corresponds to the real part of the line integral of the conjugate of the corresponding complex function of a complex variable.Due to the Cauchy-Riemann equations the curl of the vector field corresponding to the conjugate of a holomorphic function is zero. This relates through Stokes theorem both types of line integral being zero.
Quantum mechanics
The "path integral formulation" of quantum mechanics actually refers not to path integrals in this sense but to functional integrals, that is, integrals over a space of paths, of a function of a possible path. However, path integrals in the sense of this article are important in quantum mechanics; for example, complex contour integration is often used in evaluating probability amplitudes in quantum scattering theory.
See also
- Methods of contour integration
- Nachbin's theorem
- Surface integral
- Volume integral
- Stokes' theorem
- Functional integration
External links
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