Question

How do you factor `4y^2 + 4yz + z^2 - 1`?

Answer 1

`4y^2+4yz+z^2-1 = (2y+z-1)(2y+z+1)`

Explanation:

Focusing our attention on just the terms of degree `2`, notice that both `4y^2 = (2y)^2` and `z^2` are perfect squares, and we find:

`(2y+z)^2 = (2y)^2+2(2y)z+z^2 = 4y^2+4yz+z^2`

So we have:

`4y^2+4yz+z^2-1 = (2y+z)^2 - 1`

Then since `(2y+z)^2` and `1=1^2` are both perfect squares, we can use the difference of squares identity:

`a^2-b^2 = (a-b)(a+b)`

with `a=(2y+z)` and `b=1` as follows:

`(2y+z)^2 - 1`

`= (2y+z)^2-1^2`

`= ((2y+z)-1)((2y+z)+1)`

`= (2y+z-1)(2y+z+1)`

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Bonus

One way of spotting that:

`4y^2+4yz+z^2 = (2y+z)^2`

is to notice the pattern `4, 4, 1` of coefficients on the left hand side.

You may know that `441=21^2` so notice that the pattern of coefficients on the right hand side is `2, 1`.

When the number `21` is squared to give `441` there are no carries from one column to another, so we have:

`21xx21 = (20+1)xx(20+1) = (20xx20)+2(20xx1)+(1xx1)`

`= 400+40+1 = 441`

This is like putting `y=10` and `z=1` in `4y^2+4yz+z^2` and `(2y+z)`.

This works for some other quadratics with small coefficients. For example:

`(x+3)^2 = x^2+6x+9` like `13^2 = 169`

`(2x+1)(x+3) = 2x^2+7x+3` like `21 xx 13 = 273`