Line Integrals

The line integrals can be evaluated in two ways, depending on whether the curve C is defined parametrically or by an explicit function. In either case the basic idea is to convert the line integral to a definite integral in a single variable.

Method of Evaluation – Curve Defined Parametrically

If C is a smooth curve parameterized by x=f(t),~ y=g(t),~ a \leq t \leq b, then we simply replace x and y in the integral by the functions f(t) and g(t), and the appropriate differential dx,~dy, or ds by f^\prime (t) dt ,~ g^\prime (t) dt, or \sqrt{[f^\prime (t)]^2 + [g^\prime (t)]^2} dt. The expression ds = \sqrt{[f^\prime (t)]^2 + [g^\prime (t)]^2} dt is called the differential of arc length. The integration is carried out with respect to the variable t in the usual manner:

(1)   \begin{equation*}\int_C G(x,y) dx = \int_a^b G(f(t),g(t)) ~ f^\prime (t) dt,\end{equation*}


(2)   \begin{equation*}\int_C G(x,y) dy = \int_a^b G(f(t),g(t)) ~ g^\prime (t) dt,\end{equation*}


(3)   \begin{equation*}\int_C G(x,y) ds = \int_a^b G(f(t),g(t)) ~ \sqrt{[f^\prime (t)]^2 + [g^\prime (t)]^2} dt .\end{equation*}

Method of Evaluation – Curve Defined by an Explicit Function

If the curve C is defined by an explicit function y=f(x), ~ a \leq x \leq b, we can use x as a parameter. With dy = f^\prime (x) dx and ds = \sqrt{1+[f^\prime (x)]^2} dx, the foregoing line integrals become, in turn,

(4)   \begin{equation*}\int_C G(x,y) dx = \int_a^b G(x,f(x)) dx,\end{equation*}


(5)   \begin{equation*}\int_C G(x,y) dy = \int_a^b G(x,f(x)) f^\prime (x) dx,\end{equation*}


(6)   \begin{equation*}\int_C G(x,y) ds = \int_a^b G(x,f(x)) \sqrt{1+[f^\prime (x)]^2} dx.\end{equation*}

YouTube Videos

Watch these two awesome videos on line integral and its physical interpretation.

Reference

Dennis G. Zill. Advanced Engineering Mathematics, 6^{th} edition. Jones & Bartlett Learning. 2016.