How Do You Simplify Complex Algebraic Expressions?

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The discussion revolves around simplifying the algebraic expression [(x^2 -1)^2 * √(x+1)]/ (x-1)^3/2. The initial attempt incorrectly squared the expression and mismanaged the indices, leading to an incorrect result. The correct approach involves recognizing that "without fractional indices" means using square roots appropriately. The final simplified form should be (x + 1)^2 √(x^2 - 1). Participants emphasize the importance of correctly handling square roots and fractional indices in algebraic simplification.
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Homework Statement



Simplify the following, giving the result without fractional indices:

[(x^2 -1)^2 * √(x+1)]/ (x-1)^3/2

Homework Equations


The Attempt at a Solution



There are no common bases to add the indices and no common indices to multiply out the bases so I tried this and got it wrong, please show me where though:

[(x-1) (x+1)]^2 * (x+1)^(1/2)] / (x-1)^(3/2)

=[(x-1)^2 * (x+1)^2 * (x+1)^(1/2)] / (x-1)^(3/2)

multiplied the indices by 2 and got rid of the fractions

=[(x-1)^4 * (x+1)^4 * (x+1)] / (x-1)^3

= (x-1) *(x+1)^5

But my textbook says it is :( x + 1 )^2 √( x^2 - 1 )

Thank You.
 
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multiplied the indices by 2 and got rid of the fractions

=[(x-1)^4 * (x+1)^4 * (x+1)] / (x-1)^3

= (x-1) *(x+1)^5

You effectively squared the original problem. Now you need to un-square your result.
 
"Without fractional indices" just mean you need to use the square root:
(x- 1)^{3/2}= \sqrt{(x-1)^3}
 
Thank You, Everyone.
 

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