(Maybe because taking powers of angles isn’t the most intuitive process?)<\/p>\n
As it turns out, mathematician (and teacher) Y. S. Chaikovsky elegantly illustrated the power series for sine and cosine as a kind of pinwheel of involutes<\/a> (first the involute of the circular arc, then the involute of that involute, then the involute of that involute, and so on).<\/p>\n In the diagram, the thick curves, \\(I_i\\), are the successive involutes. (We include the radius segment as \\(I_0\\) and the circular arc as \\(I_1\\) for symbolic completeness.) The nature of involutes is that they trace the path of “unrolling” a curve, which effectively transfers the lengths of the curves in the involute pinwheel onto the sides of the polygonal spiral. As the corners of that spiral —\\(P_0, P_1, P_2, P_3, \\dots\\)— close in on the tip of the inclined radius segment, alternately over- and under-shooting the mark both horizontally and vertically, we see<\/p>\n A little combinatorics, and an appeal to a basic Calculus result —namely, \\(\\lim_{x\\to 0} \\frac{\\sin x}{x} = 1\\)— help Chaikovsky show that the lengths of successive involutes depict powers of the angle<\/em> (that is, powers of the length of the circular arc) —\\(|I_i| = \\frac{1}{i!}\\theta^i\\)— so that we have our power series<\/p>\n A nifty geometric interpretation, indeed!<\/p>\n With a very-minor conceptual tweak (along with some more-intense combinatorial analysis), I was able to adapt Chaikovsky’s involute pinwheel into an involute zig-zag illustrating the series for secant and tangent (in their natural habitat as segments of the Complete Triangle!):<\/p>\n![\"The](\"http:\/\/daylateanddollarshort.com\/bloog\/wp-content\/uploads\/2012\/07\/sincosinvolutes-228x300.jpg\" "\\"sincosinvolutes\\"")
<\/a><\/div>\n
\n\\cos\\theta &= |I_0| – |I_2| + |I_4| – \\cdots = \\sum (-1)^i |I_{2i}| \\\\
\n\\sin\\theta &= |I_1| – |I_3| + |I_5| – \\cdots = \\sum (-1)^i |I_{2i+1}|
\n\\end{align}}\\)<\/div>\n
\n\\cos\\theta = \\sum (-1)^i \\frac{\\theta^{2i}}{(2i)!} \\qquad\u00a0\\sin\\theta = \\sum (-1)^i \\frac{\\theta^{2i+1}}{(2i+1)!}}\\)<\/div>\n
![\"The](\"http:\/\/daylateanddollarshort.com\/bloog\/wp-content\/uploads\/2012\/07\/sectaninvolutes-300x184.jpg\" "\\"sectaninvolutes\\"")
<\/a><\/div>\n