Difference between revisions of "Shoelace Theorem"
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& \vdots \\ | & \vdots \\ | ||
(a_n &, b_n) \\ | (a_n &, b_n) \\ | ||
+ | (a_1 &, b_1) \\ | ||
\end{align*},</cmath> | \end{align*},</cmath> | ||
and marks the pairs of coordinates to be multiplied, the resulting image looks like laced-up shoes. | and marks the pairs of coordinates to be multiplied, the resulting image looks like laced-up shoes. |
Revision as of 00:50, 24 July 2014
The Shoelace Theorem is a nifty formula for finding the area of a polygon given the coordinates of its vertices.
Contents
Theorem
Suppose the polygon has vertices
,
, ... ,
, listed in clockwise order. Then the area of
is
The Shoelace Theorem gets its name because if one lists the coordinates in a column,
and marks the pairs of coordinates to be multiplied, the resulting image looks like laced-up shoes.
Proof
Let be the set of points belonging to the polygon.
We have that
where
.
The volume form
is an exact form since
, where
Using this substitution, we have
Next, we use the theorem of Green to obtain
We can write
, where
is the line
segment from
to
. With this notation,
we may write
If we substitute for
, we obtain
If we parameterize, we get
Performing the integration, we get
More algebra yields the result
Problems
Introductory
In right triangle , we have
,
, and
. Medians
and
are drawn to sides
and
, respectively.
and
intersect at point
. Find the area of
.