Find the derivative of 
| Foundations:
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| This problem requires several advanced rules of differentiation. In particular, you need
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The Chain Rule: If  and  are differentiable functions, then
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The Product Rule: If and are differentiable functions, then
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The Quotient Rule: If and are differentiable functions and  , then
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| Additionally, we will need our power rule for differentiation:
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 for  ,
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| as well as the derivative of natural log:
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Solution:
| Step 1:
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We need to identify the composed functions in order to apply the chain rule. Note that if we set  , and
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we then have 
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| Step 2:
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We can now apply all three advanced techniques. For  , we can use both the quotient and product rule to find
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| Step 3:
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We can now use the chain rule to find
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![{\displaystyle {\begin{array}{rcl}y'&=&\left(g\circ f\right)'(x)\\\\&=&g'\left(f(x)\right)\cdot f'(x)\\\\&=&\displaystyle {\left[{\frac {(2x-5)(x+4)}{(x+1)^{4}}}\right]{\frac {((x+1)^{4})'(2x-5)(x+4)-((2x-5)(x+4))'(x+1)^{4}}{(2x-5)^{2}(x+4)^{2}}}}\\\\&=&\displaystyle {\left[{\frac {(2x-5)(x+4)}{(x+1)^{4}}}\right]{\frac {(4(x+1)^{3})(2x-5)(x+4)-(2(x+4)+(2x-5))(x+1)^{4}}{(2x-5)^{2}(x+4)^{2}}}.}\end{array}}}](https://wikimedia.org/api/rest_v1/media/math/render/svg/1578dd8dcf067853351e1e9bb029f4dc787c9d9d)
Note that many teachers do not prefer a cleaned up answer, and may request that you do not simplify. In this case, we could write the answer as
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![{\displaystyle y'=\left[{\frac {(2x-5)(x+4)}{(x+1)^{4}}}\right]{\frac {(4(x+1)^{3})(2x-5)(x+4)-(2(x+4)+(2x-5))(x+1)^{4}}{(2x-5)^{2}(x+4)^{2}}}.}](https://wikimedia.org/api/rest_v1/media/math/render/svg/f8a430a011f6cdcb9f6368aa52071291f2e2d2b0)
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| Final Answer:
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