Geometrical Interpertation of Cauchy's Mean Value Theorem
Here's an explanation of the parametric curve drawing: Consider two functions $f(x)$ and $g(x)$ continuous on the interval $[a,b]$ and differentiable on $(a,b)$.
For every $x \in [a,b]$, we consider the point $(f(x),g(x))$. If we trace out the points $(f(x),g(x))$ over every $x \in [a,b]$, we get a curve in two dimensions, as shown in the graph.
In the drawing, the slope of the red line is $\frac{g(b)-g(a)}{f(b)-f(a)}$. (This is because $\frac{\Delta y}{\Delta x}=\frac{g(b)-g(a)}{f(b)-f(a)}$, assuming that the vertical axis, which contains the value of $g(x)$, is the $y$-axis.)
The slope of the green line is $\frac{g'(c)}{f'(c)}$. (Why? Because $\frac{\text{d}g}{\text{d}f}\Big|_{x=c} = \frac{\text dg / \text dx}{\text df / \text dx}\Big|_{x=c} = \frac{g'(c)}{f'(c)}$.) The drawing illustrates that for the value of $c$ chosen in the pictures, the slopes of the red line and green line are the same, i.e. $\frac{g(b)-g(a)}{f(b)-f(a)} = \frac{g'(c)}{f'(c)}$.