Goursat's integral lemma for complex-differentiable functions: Difference between revisions

Latest revision as of 19:13, 18 May 2008

This article gives the statement, and possibly proof, of a basic fact in complex analysis.
View a complete list of basic facts in complex analysis

Statement

Suppose $U \subset C$ is an open subset, and $f : U \to C$ is complex-differentiable at every point. Suppose $△$ is a triangle lying completely inside $U$ . Then, we have:

$\int_{\partial △} f (z) d z = 0$

Proof

Define:

$α (△) = \int_{\partial △} f (z) d z$

Note that $△$ can be split into four congruent triangles by joining the midpoints of the sides. Since $α (△)$ is the sum of $α$ evaluated for each of the pieces, at least one of the pieces $△^{1}$ must satisfy:

$| α (△^{1}) | \leq | α (△) |$

Pick this triangle, and again divide it into four triangles. Repeating this process we get a descending sequence of triangles, each having side-lengths half of its predecessor:

$△ \supset △^{1} \supset △^{2} \supset \dots$

and with the further property that:

$| α (△) | \leq 4^{n} | α (△^{n}) |$

On the other hand, we have that:

$L (\partial △^{n}) = \frac{1}{2^{n}} L (\partial △)$

Now let $c \in △$ be the unique point in the intersection of all the $△^{n}$ s. Since $f$ is differentiable at the point $c$ , we have:

$lim_{z \to c} \frac{f (z) - f (c)}{z - c} = 0$

Define now:

$g (z) : = \frac{f (z) - f (c)}{z - c} - f^{'} (c)$

Then $g (c) = 0$ . Observe that:

$\int_{\partial △^{n}} f (c) d z = \int_{\partial △^{n}} f^{'} (c) (z - c) = 0$

Thus, we get:

$α (△^{n}) = \int_{\partial △^{n}} g (z) (z - c) d z$

Applying the length estimates and size estimates now gives the result. Fill this in later