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$\cos x = 0.3x$ has three solutions. $\cos x = 0.4x$ has one solution. How to find $k$ so that $\cos x = kx$ has two solutions?

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    I suggest you draw the graphs of the functions $kx$ and $\cos(x)$. I think it gives a good intuition.2011-11-04

2 Answers 2

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For a certain value of $k$ (I am assuming $k$ here is nonnegative), the line $kx$ will be tangent to the cosine curve. If you find that critical value of $k$ (call it $k^\ast$), any value of $k$ within the interval $[0,k^\ast)$ will yield a line that intersects the cosine more than twice.

Assembling the equation of the tangent line at $x=u$ gives

$y=-(\sin\,u)(x-u)+\cos\,u$

We thus need the value of $u$ that zeroes the $y$-intercept; i.e., the value of $u$ that satisfies the equation

$u=-\cot\,u$

Unfortunately, there is no closed form expression for $u$. Numerical computations indicate that $u\approx -2.79838604578388713672024890314$, corresponding to the critical slope $k^\ast=-\sin\,u\approx 0.33650841691839529161631981441$.

tangent to the cosine

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By symmetry we can assume $a>0$.

By IVT there is a solution between $0$ and $\frac{\pi}{2}$. You want a second solution $x_0$.

This means that $ax$ will be tangent to $\cos(x)$ at $x_0$, otherwise you can prove there is another solution.

Thus $\cos(x_0)=ax_0$ and $-\sin(x_0)=a$. Hence $a^2(x_0^2+1)=1$. Which means that

x_0$ must be the solution to

\cos(x_0)= \frac{x_0}{\sqrt{x_0^2+1}}$, between \frac{3\pi}{2}$ and $2\pi.

Then a=\frac{1}{\sqrt{x_0^2+1}}.

Geometrically, this is the point so that ax$ is tangent to the second "mountain" of $\cos(x).

The equation unfortunately seems to be impossible to solve exactly, but you can approximate the solution.

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    Since $k$ is bracketed between $0.3$ and $0.4$, it will be easy to solve numerically.2011-11-04