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Suppose we have a path P in two dimensions from x0 y0 to (x f , y f) defined by an equation:
y - f(x) = 0
or more generally
g(x, y) = 0
Suppose further we seek to evaluate a circulation measure integral along
this path. We do this by reducing it to an ordinary integral with a modified
integrand, and then integrating it.
If we define the vector w by ,
the integral
becomes the ordinary integral
We have assumed here that the variable x changes monotonically along the path (it keeps increasing or decreasing). Otherwise you have to break the integral up into pieces on each of which x is monotone, if you want to use x as your variable of integration.
More generally, if you use a parameter t to describe your path, the relevant vector w is given by
w
and one integrates v
w
dt.
If you want to integrate using length measure, as you would to compute arc-length
along the path, then you integrate the magnitude of w, 
times the integrand f, instead of vw.
This gives exactly the expressions for arc length encountered in single variable
calculus.
In three dimensions, the only difference, given parameter t, is that w is given by
and
its magnitude is 