kaliprasad
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Show that $\sin\,10^\circ$ is irrational
[sp]Let $x = \sin10^\circ$. The formula for $\sin3\theta$ shows that $3x - 4x^3 = \sin30^\circ = \frac12.$ So $8x^3 - 6x + 1 = 0.$ If $y=2x$ then $y^3 - 3y + 1 = 0.$ That cubic equation has no integer solutions, so by Gauss's lemma it has no rational solutions. Hence $y$, and therefore $x$, is irrational.kaliprasad said:Show that $\sin\,10^\circ$ is irrational
kaliprasad said:Show that $\sin\,10^\circ$ is irrational
[sp]Not quite that simple! What that argument shows is that $\sin10^\circ$ and $\cos10^\circ$ cannot both be rational. In that case, there would indeed have to be a Pythagorean triple with $1$ as a member.greg1313 said:Could it be this simple?
Consider right triangle $ABC$ with $\angle{A}=80^\circ$, $\angle{B}=10^\circ$ and $\overline{AC}=1$. Then $c\sin10^\circ=1\Rightarrow\sin10^\circ=\frac1c$. As there is no Pythagorean triple with $1$ as a member, $c$ must be irrational, hence $\sin10^\circ$ is irrational.
Opalg said:[sp]Not quite that simple! What that argument shows is that $\sin10^\circ$ and $\cos10^\circ$ cannot both be rational. In that case, there would indeed have to be a Pythagorean triple with $1$ as a member.
The case of $\sin30^\circ$ shows that $\sin x$ can be of the form $\frac1n$ where $n$ is an integer. But of course $\cos30^\circ = \frac{\sqrt3}2$ which is not rational.
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[sp]It holds for $\alpha=\arctan(3/4)$ because $(3,4,5)$ is a Pythagorean triple. The point is that there is no such triple having $1$ as one of its elements.I like Serena said:By that logic that would hold for any angle, wouldn't it?
But it doesn't, since with $\alpha=\arctan(3/4)$ both $\cos\alpha$ and $\sin\alpha$ are rational.
Opalg said:[sp]It holds for $\alpha=\arctan(3/4)$ because $(3,4,5)$ is a Pythagorean triple. The point is that there is no such triple having $1$ as one of its elements.
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greg1313 said:I still don't see why what I wrote is incorrect. $c$ is irrational, so must be $\sin10^\circ$.