Difference between revisions of "1992 USAMO Problems/Problem 2"

Latest revision as of 06:41, 19 July 2016

Problem

Prove $\frac{1}{\cos 0^\circ \cos 1^\circ} + \frac{1}{\cos 1^\circ \cos 2^\circ} + \cdots + \frac{1}{\cos 88^\circ \cos 89^\circ} = \frac{\cos 1^\circ}{\sin^2 1^\circ}.$

Solution

Solution 1

Consider the points $M_k = (1, \tan k^\circ)$ in the coordinate plane with origin $O=(0,0)$ , for integers $0 \le k \le 89$ .

$[asy] size(200); defaultpen(1); pair O=(0,0), a=expi(0), b=expi(1/6), c=expi(2/6), d=expi(3/6), y=expi(32/30), z= expi(34/30); pair A=a, B=b/b.x, C= c/c.x, D=d/d.x, Y=y/y.x, Z=z/z.x, E=(D+Y)/2; pair X=(O+E)/2; draw(O--A--Z); draw(B--O--C--D--O--Y--Z--O); label("$O$",O,SW); label("$M_0$",A,ESE); label("$M_1$",B,ESE); label("$M_2$",C,ESE); label("$M_3$",D,ESE); label("$\vdots$",E,ESE); label("$M_{88}$",Y,ESE); label("$M_{89}$",Z,ESE); label("$\ddots$",X); [/asy]$

Evidently, the angle between segments $OM_a$ and $OM_b$ is $(b-a)^\circ$ , and the length of segment $OM_a$ is $1/\cos a^\circ$ . It then follows that the area of triangle $M_aOM_b$ is $\tfrac{1}{2} \sin(b-a)^\circ \cdot OM_a \cdot OM_b = \tfrac{1}{2} \sin(b-a)^\circ / (\cos a^\circ \cdot \cos b^\circ)$ . Therefore $\begin{align*} \sum_{k=0}^{88} \frac{\tfrac{1}{2} \sin 1^\circ}{ \cos k^\circ \cos k+1^\circ} &= \sum_{k=0}^{88} [ M_k O M_{k+1} ] \\ &= [ M_0 O M_{89} ] \\ &= \frac{ \tfrac{1}{2} \sin 89^\circ}{\cos 89^\circ} = \frac{\tfrac{1}{2} \cos 1^\circ}{\sin 1^\circ} , \end{align*}$ so $\sum_{k=0}^{88} \frac{1}{\cos k^\circ \cos (k+1)^\circ} = \frac{\cos 1^\circ}{ \sin^2 1^\circ},$ as desired. $\blacksquare$

Solution 2

First multiply both sides of the equation by $\sin 1$ , so the right hand side is $\frac{\cos 1}{\sin 1}$ . Now by rewriting $\sin 1=\sin((k+1)-k)=\sin(k+1)\cos(k)+\sin(k)\cos(k+1)$ , we can derive the identity $\tan(n+1)-\tan(n)=\frac{\sin 1}{\cos(n)\cos(n+1)}$ . Then the left hand side of the equation simplifies to $\tan 89-\tan 0=\tan 89=\frac{\sin 89}{\cos 89}=\frac{\cos 1}{\sin 1}$ as desired.

Solution 3

Multiply by $\sin{1}$ . We get:

$\frac {\sin{1}}{\cos{0}\cos{1}} + \frac {\sin{1}}{\cos{1}\cos{2}} + ... + \frac {\sin{1}}{\cos{88}\cos{89}} = \frac {\cos{1}}{\sin{1}}$

we can write this as:

$\frac {\sin{1 - 0}}{\cos{0}\cos{1}} + \frac {\sin{2 - 1}}{\cos{1}\cos{2}} + ... + \frac {\sin{89 - 88}}{\cos{88}\cos{89}} = \frac {\cos{1}}{\sin{1}}$

This is an identity $\tan{a} - \tan{b} = \frac {\sin{(a - b)}}{\cos{a}\cos{b}}$

Therefore;

$\sum_{i = 1}^{89}[\tan{k} - \tan{(k - 1)}] = \tan{89} - \tan{0} = \cot{1}$ , because of telescoping.

but since we multiplied $\sin{1}$ in the beginning, we need to divide by $\sin{1}$ . So we get that:

$\frac {1}{\cos{0}\cos{1}} + \frac {1}{\cos{1}\cos{2}} + \frac {1}{\cos{2}\cos{3}} + .... + \frac {1}{\cos{88}\cos{89}} = \frac {\cos{1}}{\sin^2{1}}$ as desired. QED

Solution 4

Let $S = \frac{1}{\cos 0^\circ\cos 1^\circ} + \frac{1}{\cos 1^\circ\cos 2^\circ} + ... + \frac{1}{\cos 88^\circ\cos 89^\circ}$ .

Multiplying by $\sin 1^\circ$ gives $S \sin 1^\circ = \frac{\sin(1^\circ-0^\circ)}{\cos 0^\circ\cos 1^\circ} + ... + \frac{\sin(89^\circ-88^\circ)}{\cos 88^\circ\cos 89^\circ}$

Notice that $\frac{\sin((x+1^\circ)-x)}{\cos 0^\circ\cos 1^\circ} = \tan (x+1^\circ) - \tan x$ after expanding the sine, and so $S \sin 1^\circ = \left(\tan 1^\circ - \tan 0^\circ\right) + \cdots + \left(\tan 89^\circ - \tan 88^\circ\right) = \tan 89^\circ - \tan 0^\circ = \cot 1^\circ = \frac{\cos 1^\circ}{\sin 1^\circ},$ so $S = \frac{\cos 1^\circ}{\sin^21^\circ}.$

@@ Line 4: / Line 4: @@
 <cmath> \frac{1}{\cos 0^\circ \cos 1^\circ} +  \frac{1}{\cos 1^\circ \cos 2^\circ} + \cdots + \frac{1}{\cos 88^\circ \cos 89^\circ} = \frac{\cos 1^\circ}{\sin^2 1^\circ}. </cmath>
-== Solution 1==
+== Solution==
+=== Solution 1 ===
 Consider the points <math>M_k = (1, \tan k^\circ)</math> in the coordinate plane with origin <math>O=(0,0)</math>, for integers <math>0 \le k \le 89</math>.
@@ Line 37: / Line 38: @@
 as desired.  <math>\blacksquare</math>
-== Solution 2==
+=== Solution 2 ===
 First multiply both sides of the equation by <math>\sin 1</math>, so the right hand side is <math>\frac{\cos 1}{\sin 1}</math>.  Now by rewriting <math>\sin 1=\sin((k+1)-k)=\sin(k+1)\cos(k)+\sin(k)\cos(k+1)</math>, we can derive the identity <math>\tan(n+1)-\tan(n)=\frac{\sin 1}{\cos(n)\cos(n+1)}</math>.  Then the left hand side of the equation simplifies to <math>\tan 89-\tan 0=\tan 89=\frac{\sin 89}{\cos 89}=\frac{\cos 1}{\sin 1}</math> as desired.
-== Solution 3==
+=== Solution 3 ===
 Multiply by <math>\sin{1}</math>. We get:
@@ Line 61: / Line 62: @@
 as desired. QED
-== Resources ==
+=== Solution 4 ===
+Let <math>S = \frac{1}{\cos 0^\circ\cos 1^\circ} + \frac{1}{\cos 1^\circ\cos 2^\circ} + ... + \frac{1}{\cos 88^\circ\cos 89^\circ}</math>.
+Multiplying by <math>\sin 1^\circ</math> gives
+<cmath>S \sin 1^\circ = \frac{\sin(1^\circ-0^\circ)}{\cos 0^\circ\cos 1^\circ} + ... + \frac{\sin(89^\circ-88^\circ)}{\cos 88^\circ\cos 89^\circ}</cmath>
+Notice that <math>\frac{\sin((x+1^\circ)-x)}{\cos 0^\circ\cos 1^\circ} = \tan (x+1^\circ) - \tan x</math> after expanding the sine, and so
+<cmath>S \sin 1^\circ = \left(\tan 1^\circ - \tan 0^\circ\right) + \cdots + \left(\tan 89^\circ - \tan 88^\circ\right) = \tan 89^\circ - \tan 0^\circ = \cot 1^\circ = \frac{\cos 1^\circ}{\sin 1^\circ},</cmath> so <cmath>S = \frac{\cos 1^\circ}{\sin^21^\circ}.</cmath>
+== See Also ==
 {{USAMO box|year=1992|num-b=1|num-a=3}}
 * [http://www.artofproblemsolving.com/Forum/viewtopic.php?p=356413#p356413 Discussion on AoPS/MathLinks]
+{{MAA Notice}}
 [[Category:Olympiad Algebra Problems]]

1992 USAMO (Problems • Resources)
Preceded by Problem 1	Followed by Problem 3
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All USAMO Problems and Solutions

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