Question 1038091: Hello, I am having a really hard time finding the factors of these. It would be much appreciated for you to answer :)
15x^3(x+y)^2 - 30x^2(x+y) - 45x(x+y)^4
Found 2 solutions by Alan3354, Edwin McCravy:
Answer by Alan3354(69443)   (Show Source):
You can put this solution on YOUR website!
15x^3(x+y)^2 - 30x^2(x+y) - 45x(x+y)^4
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Each term has a factor of 15.
Each term has a factor of x.
Each term has a factor of (x+y).
Answer by Edwin McCravy(20056)  (Show Source):
You can put this solution on YOUR website!
15x^3(x+y)^2 - 30x^2(x+y) - 45x(x+y)^4
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15 30 45
Look at the numbers: 15, 30, 45
What is the largest integer that will divide evenly
into all three of those numbers? It's 15. So 15 is
a common factor that can be factored out.
So we know the factoring starts like this:
15 [ ]
Next we look at the powers of x: x^3, x^2, x^4
15x^3(x+y)^2 - 30x^2(x+y) - 45x(x+y)^4
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x^3 x^2 x
What is the largest power of x that will divide evenly into
all three of those? x means x^1. The largest power of x
that will divide evenly into all three of those is x^1 or just
x, the smallest power of x. So we can factor out x. So the
factoring will look like this:
15x [ ]
Next we look at (x+y)^2, (x+y), and (x+y)^4
Next we look at the powers of x: x^3, x^2, x^4
15x^3(x+y)^2 - 30x^2(x+y) - 45x(x+y)^4
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(x+y)^2 (x+y) (x+y)^4
What is the largest power of (x+y) that will divide evenly into
all three of those? (x+y) means (x+y)^1. The largest power of
(x+y) that will divide evenly into all three of those is (x+y)^1
or just (x+y), the smallest power of (x+y). So we can factor out
(x+y). So the factoring will look like this:
15x(x+y)[ ]
The first term of the original expression is 15x^3(x+y)^2.
What factors does 15x^3(x+y)^2 have that 15x(x+y) does NOT
have? 15x^3(x+y)^2 has factors x^2 and (x+y) that 15x(x+y)
does not have, because x needs to be multiplied by x^2 to
get x^3 and (x+y) needs to be multiplied by itself (x+y) to
get (x+y)^2. So the first term to put inside the brackets
is x^2(x+y)
15x(x+y)[x^2(x+y) ]
The second term of the original expression is - 30x^2(x+y).
What factors does - 30x^2(x+y) have that 15x(x+y) does NOT
have? - 30x^2(x+y) has only factors -2 and x that 15x(x+y)
does not have, because 15 needs to be multiplied by -2 to
get -30 and x needs to be multiplied by itself x to
get x^2. So the second term to put inside the brackets
is - 2x. So now we have
15x(x+y)[x^2(x+y) - 2x ]
The third and final term of the original expression is - 45x(x+y)^4.
What factors does - 45x(x+y)^4 have that 15x(x+y) does NOT
have? - 45x(x+y)^4 has factors -3 and (x+y)^3
does not have, because 15 needs to be multiplied by -3 to
get -45 and (x+y) needs to be multiplied by (x+y)^2 to
get (x+y)^3. So the third term to put inside the brackets
is - 2(x+y)^2. So now we have
15x(x+y)[x^2(x+y) - 2x - 3(x+y)^3]
Now we have to remove the parentheses within the brackets:
15x(x+y)[x^3 + x^2y - 2x - 3(x+y)(x+y)(x+y)]
15x(x+y)[x^3 + x^2y - 2x - 3(x+y)(x^2+2xy+y^2)]
15x(x+y)[x^3 + x^2y - 2x - 3(x^3+2x^2y+xy^2+x^2y+2xy^2+y^3)]
15x(x+y)[x^3 + x^2y - 2x - 3(x^3+3x^2y+3xy^2+y^3)]
15x(x+y)[x^3 + x^2y - 2x - 3x^3 - 9x^2y - 9xy^2 - 3y^3]
15x(x+y)[-2x^3 - 8x^2y - 9x^2y - 2x - 3y^3]
Since all those terms are negative we can take a negative sign
out front:
-15x(x+y)[2x^3 + 8x^2y + 9xy^2 + 2x + 3y^3]
We can only change the brackets to parentheses
because they no longer hold parentheses:
-15x(x+y)(2x^3 + 8x^2y + 9xy^2 + 2x + 3y^3)
Edwin
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