Question

How many prime factors are obtained? `x^7 + c^3x^4 - c^4x^3-c^7`

`x^7 + c^3x^4 - c^4x^3-c^7`

Answer 1

`x^7+c^3x^4-c^4x^3-c^7=(x^2-cx+c^2)(x^2+c^2)(x+c)^2(x-c)`

Explanation:

We are asked to factor

`x^7+c^3x^4-c^4x^3-c^7`

Not so easy this one.

First note that if `x=c` then the expression yields zero.

`c^7+c^3c^4-c^4c^3-c^7=c^7+c^7-c^7-c^7=0`

This means that `(x-c)` is a factor of `x^7+c^3x^4-c^4x^3-c^7`.

Let's do the long division and see what remains.

`x^7+c^3x^4-c^4x^3-c^7`

`=x^7-cx^6+cx^6-c^2x^5+c^2x^5-c^3x^4+2c^3x^4-2c^4x^3+c^4x^3-c^5x^2+c^5x^2-c^6x+c^6x-c^7`

`=x^6(x-c)+cx^5(x-c)+c^2x^4(x-c)+2c^3x^3(x-c)+c^4x^2(x-c)+c^5x(x-c)+c^6(x-c)`

`=(x^6+cx^5+c^2x^4+2c^3x^3+c^4x^2+c^5x+c^6)(x-c)`

Now we notice that when `x=-c`,

`x^6+cx^5+c^2x^4+2c^3x^3+c^4x^2+c^5x+c^6=c^6-c^6+c^6-2c^6+c^6-c^6+c^6=0`

Let's divide `x^6+cx^5+c^2x^4+2c^3x^3+c^4x^2+c^5x+c^6` by `(x+c)`.

`x^6+cx^5+c^2x^4+2c^3x^3+c^4x^2+c^5x+c^6`

`=x^6+cx^5+c^2x^4+c^3x^3+c^3x^3+c^4x^2+c^5x+c^6`

`=x^5(x+c)+c^2x^3(x+c)+c^3x^2(x+c)+c^5(x+c)`

`=(x^5+c^2x^3+c^3x^2+c^5)(x+c)`

Next notice that when `x=-c`

`x^5+c^2x^3+c^3x^2+c^5=-c^5-c^5+c^5+c^5=0`

So lets divide `x^5+c^2x^3+c^3x^2+c^5` by `(x+c)`.

`x^5+c^2x^3+c^3x^2+c^5`

`=x^5+cx^4-cx^4-c^2x^3+2c^2x^3+2c^3x^2-c^3x^2-c^4x+c^4x+c^5`

`=x^4(x+c)-cx^3(x+c)+2c^2x^2(x+c)-c^3x(x+c)+c^4(x+c)`

`=(x^4-cx^3+2c^2x^2-c^3x+c^4)(x+c)`

Now we are forced to factor `x^4-cx^3+2c^2x^2-c^3x+c^4`.

A little "inspired grouping" gets us over this hurdle.

Start with

`x^4-cx^3+2c^2x^2-c^3x+c^4`.

Split the third term.

`x^4-cx^3+c^2x^2+c^2x^2-c^3x+c^4`

Commute the 3rd term.

`x^4+c^2x^2-cx^3-c^3x+c^2x^2+c^4`

Group and factor.

`x^2(x^2+c^2)-cx(x^2+c^2)+c^2(x^2+c^2)`

`(x^2-cx+c^2)(x^2+c^2)`

If `c` and `x` are both real numbers, then we cannot factor any further. Note that the only way for `x^2+c^2=0` is if they are both zero or if either `x^2` or `c^2` are less than zero. The only way for to have a squared number be less than zero is if it is imaginary. Also note that by using the quadratic formula, we can find `x`'s that satisfy `x^2-cx+c^2=0`.

`x=(cpmsqrt(c^2-4c^2))/2=(cpmcsqrt(-3))/2`

So both roots for this expression MUST be imaginary regardless of whether `c` is imaginary or not.

So we have the factored form with the following logic:

`x^7+c^3x^4-c^4x^3-c^7`

`=(x^6+cx^5+c^2x^4+2c^3x^3+c^4x^2+c^5x+c^6)(x-c)`

`=(x^5+c^2x^3+c^3x^2+c^5)(x+c)(x-c)`

`=(x^4-cx^3+2c^2x^2-c^3x+c^4)(x+c)(x+c)(x-c)`

`=(x^2-cx+c^2)(x^2+c^2)(x+c)(x+c)(x-c)`

`=(x^2-cx+c^2)(x^2+c^2)(x+c)^2(x-c)`

Yikes! Your teacher sure is mean!