# Interesting functional equations problem? $f(x) + 3 f\left( \frac {x-1}{x} \right) = 7x$

Find all functions $$f:\mathbb R \to \mathbb R$$ that satisfy $$f(x) + 3 f\left( \frac {x-1}{x} \right) = 7x$$.

How would we solve this? I noticed that if you plug in $$\frac{x-1}{x}$$ in for $$x$$, and then again, we can solve $$f(x)$$ after bashing it out with systems of equations. However, the resulting function has a few values for which it is undefined. I tried finding those values by going back to the original equation, but it doesn't seem like a "good" answer. Since I then wanted to verify that I had the correct function first, I plugged the actual function back into the original equation. However, the LHS and RHS didn't match up. Is there a better way to solve this other than just bashing?

I think this is essentially the solution you came up with, but it's helpful to write out all the details.

Let $y=\frac{x-1}{x}$, $z=\frac{1}{1-x}$. Then, if $g(x)=\frac{x-1}{x}$, we have $y=g(x)$, $z=g(y)$, and $x=g(z)$. So the functional equation implies that \begin{align} f(x) + 3f(y)&=7x\\ f(y) + 3f(z)&=7y\\ f(z) + 3f(x)&=7z \end{align}

Then $f(y)=7y-3f(z)$ and $f(z)=7z-3f(x)$, so $f(y)=7y-3(7z-3f(x))=7y-21z+9f(x)$.

So $f(x)+21y-63z+27f(x)=7x$, meaning that \begin{align} f(x)&=\frac{7x-21y+63z}{28} \\ &=\frac{x-3y+9z}{4}\\ &=\frac{1}{4}\left(x-3+\frac{3}{x}+\frac{9}{1-x}\right) \end{align}

It's not too hard to check that this satisfies the original functional equation for all $x \neq 0,1$. (Actually, it's easier if you leave everything in terms of $x$, $y$, and $z$.)

What about the value of $f$ at $0$ and $1$? By setting $x=1$ in the original equation, we can see that:

$$f(1)+3f(0)=7 \tag{1}$$

Because $\frac{x-1}{x}$ is never equal to $1$ and undefined at $x=0$, this is the only meaningful data the equation gives us about $f(0)$ and $f(1)$, so you can pick any values for them you wanted that satisfy $(1)$. There doesn't seem to be any choice that's much nicer than the others, since $f$ has simple poles at both $0$ and $1$ (e.g., we can never make $f$ continuous).

• @ Micah, I realized that I had a mistake in my original work after reviewing your solution, so thanks for that :) Just a quick question - how would one write $f(x)$, since there is no fixed value for $f(0)$ and $f(1)$? Oct 23 '14 at 21:32
• I would say something like: the solutions are of the form $$f_a(x)=\begin{cases} a & \text{for }x=0\\ 7-3a&\text{for }x=1\\ \frac{1}{28}\left(x-3-\frac{3}{x}+\frac{9}{1-x}\right) &\text{otherwise}\end{cases}$$ where $a$ is arbitrary. Oct 23 '14 at 21:43
• Oh, I see. Thank you so much! Oct 23 '14 at 21:44

Sorry, this wouldn't fit into a comment, so I had to post this in as an answer, but when I plugged $f$ back into the original equation, I got: \begin{align*} f(x) + 3 f\left(\frac{x-1}{x}\right) &= \frac{1}{28}\left(x - 3 - \frac{3}{x} - \frac{9}{x-1}\right) + 3\left(\frac{1}{28}\right)\left(\frac{x-1}{x} - 3 - \frac{3}{\frac{x-1}{x}} - \frac{9}{\frac{x-1}{x}-1}\right)\\ &= \left(\frac{1}{28}\right)\left(x - 3 - \frac{3}{x}-\frac{9}{x-1}+3\left(\frac{x-1}{x}-3-\frac{3x}{x-1}+9x\right)\right)\\ &= \left(\frac{1}{28}\right)\left(x - 3 - \frac{3}{x}-\frac{9}{x-1}+\frac{3x-3}{x} - 3 - \frac{9x}{x-1} + 27x\right)\\ &= \left(\frac{1}{28}\right)\left(28x - 6 + \frac{3x-6}{x}-\frac{9+9x}{x-1}\right)\\ &= \left(\frac{1}{28}\right)\left(28x^3-28x^2-6x^2+6x-3x^2+6x+3x+6-9x+9x^2\right)\\ &= \left(\frac{1}{28}\right)\left(28x^3-28x^2+6x+6\right)\\ &= x^3-x^2+\frac{3x}{14} + \frac{3}{14}, \end{align*} which doesn't match the given $7x$. If you could tell me where I made my mistake, it would be greatly appreciated. Thanks in advance!

• Well, one thing is that I had a brain-fart and solved the equation $f(x)+3f((x-1)/x)=x$ (instead of $7x$). I'm currently in the middle of fixing my answer to account for this. But you also have at least one algebra error -- on your third line you multiply $3$ by $3$ and come up with $3$. Oct 24 '14 at 3:47
• I also found another sign error in my final answer. I think it should all be good now, though... Oct 24 '14 at 4:00