Find $a$, $b$ such that $x^2 - x -1$ is a factor of $ax^9 + bx^8 + 1$

Question

The second polynomial can be rewritten as
$$ax^9 + bx^8 + 1 = f(x)(x^2 - x - 1)$$
The roots of this polynomial are $frac{1 pm sqrt 5}{2}$. Substituting one of these roots in this equation gives us:
$$aleft( frac{1 + sqrt5}{2}right)^9 + bleft( frac{1 + sqrt 5}{2}right)^8 + 1 = 0$$
I was able to solve this far, but I gave up because the calculation past this point gets too tedious. The textbook has gone ahead and simplified this to
$$2^9 a + 2^8b(sqrt 5 - 1) + (sqrt5 - 1)^9 = 0$$
after which it simplifies to (divide by $2^8$ and solve the binomial expression)
$$2a + b(sqrt 5 -1) = 76 - 34sqrt5$$
Is there a more elegant way to solve this problem? Preferably one that does not include the magical use of a calculator or the evaluation of that ugly binomial expansion?

Jack D'Aurizio · Accepted Answer

A polynomial $f(x)$ is a multiple of $x^2-x-1$ (the characteristic polynomial of the Fibonacci sequence) iff $f(varphi)=f(bar{varphi})=0$, with $varphi=frac{1+sqrt{5}}{2}$, $bar{varphi}=frac{1-sqrt{5}}{2}$ being algebraic conjugates. Since $varphi^2=varphi+1$ we have by induction $varphi^k=F_{k}varphi+F_{k-1}$ and the same holds for $bar{varphi}$. It follows that $ax^9+bx^8+1$ is a multiple of $x^2-x-1$ iff
$$begin{eqnarray*} 0 &=& avarphi^9+bvarphi^8+1 = a(34varphi+21)+b(21varphi+13)+1\&=&(34a+21b)varphi+(21a+13b+1)end{eqnarray*}$$
and
$$ 0 = (34a+21b)bar{varphi}+(21a+13b+1). $$
It follows that we must have $21a+13b=-1$ and $34a+21b=0$, so $color{red}{a=21,b=-34}$ works.
You may also invoke the more general identity
$$ (x^2-x-1)sum_{k=0}^{n}(-1)^{k+1}F_k x^k = (-1)^{n+1}F_n x^{n+2}+(-1)^n F_{n+1} x^{n+1}-x.$$

Aqua · Answer

Say $c$ and $d$ are zeroes of $x^2-x-1$ then they are zeros of  $ax^9+bx^8+1$ too.
Since $c^2 = c+1$ we have $$c^4=c^2+2c+1=3c+2$$ and $$c^8 = 9c^2+12c+4 = 21c+13$$
and finnaly $c^9 = 34c+21$.
So we have $$a(34c+21)+b(21c+13)+1=0$$ or $$boxed{(34a+21b)c+ (21a+13b+1)=0}$$
Simmilay we have for $d$: $$boxed{(34a+21b)d+ (21a+13b+1)=0}$$
so if we substract equation and since $cne d$ we have $$(34a+21b)(c-d) = 0implies 34a+21b=0$$
and thus $$21a+13b+1=0$$
Now solve this system and you are done.

medicu · Answer

Consider
$P(x)= ax^9+bx^8+1$ and $alpha$ one of the numbers$frac{1 pm sqrt 5}{2}.$
We have equalities:
$alpha^2$ = $alpha$ + 1, $alpha^4$ = 3$alpha$ + 2,
$alpha^8$ = 21$alpha$ + 13, $alpha^9$ = 34$alpha$ + 21.
(The coefficients to the right of the equations are terms of the Fibonacci sequence)
From $P(alpha) = 0$ results $a(34alpha + 21) +b(21alpha + 13) + 1 =0$ and then
$(34a + 21b)alpha + 21a + 13b + 1 = 0$
If $a$ and $b$ are rational numbers then $$ a = 21, b = -34.$$

Claude Leibovici · Answer

Consider
$$frac{a x^9+bx^8+1}{x^2-x-1}$$ perform long division to get
$$-1+x-2 x^2+3 x^3-5 x^4+8 x^5-13 x^6+21 x^7-(b+34) x^8+x^9
   (-a+b+55)+Oleft(x^{10}right)$$
So $b=-34$ and $a=21$ and the result is
$$frac{a x^9+bx^8+1}{x^2-x-1}=-1+x-2 x^2+3 x^3-5 x^4+8 x^5-13 x^6+21 x^7$$

TheSimpliFire · Answer

Write $ax^9+bx^8+1=(x^2-x-1)sumlimits_{k=0}^7c_kx^{7-k}$ which gives the initial conditions $c_7=-1$ and $-c_7-c_6=0implies c_6=1$. Notice that $c_0=a$ and $c_1-c_0=b$ on equating coefficients.
Further, we have $c_i=c_{i-1}+c_{i-2}$ for $i>1$ which is the negative Fibonacci sequence shifted by one. In particular, $c_{7-i}=(-1)^{i+1}F_{i+1}$ so $c_0=F_8$ and $c_1=-F_7$. Hence $a=21$ and $b=-34$.

rain1 · Answer

Put $A = x^2 - x - 1$, $B = ax^9 + bx^8 + 1$ now we want $B/A$ to divide without remainder. We can subtract multiples of $A$ from $B$ to kill off high order terms and see what the remainder would be:
B
- a*x^7*A
= (a + b)*x^8 + a*x^7 + 1

- (a + b)*x^6*A
(2*a + b)*x^7 + (a + b)*x^6 + 1

- (2*a + b)*x^5*A
(3*a + 2*b)*x^6 + (2*a + b)*x^5 + 1

We find
Q = a*x^7 + (a + b)*x^6 + (2*a + b)*x^5
  + (3*a+2*b)*x^4 + (5*a + 3*b)*x^3 + (8*a + 5*b)*x^2
  + (13*a + 8*b)*x + (21*a + 13*b)

R = (34*a + 21*b)*x + 21*a + 13*b + 1

via B - Q A = R

So we need to solve the system

$34a + 21b = 0$
$21a + 13b + 1 = 0$

To get no remainder.

Find $a$, $b$ such that $x^2 - x -1$ is a factor of $ax^9 + bx^8 + 1$

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