Given that $u=x+1$, which integral is equivalent to $\int \frac{x^2}{\sqrt{x+1}} d x$ ?
a $\int(\sqrt{u^3}+\frac{1}{\sqrt{u}}) d u$
b $\int(\sqrt{u^3}-2 \sqrt{u}+\frac{1}{\sqrt{u}}) d u$
c $\int(\sqrt{u^3}-2 \sqrt{u}) d u$
d $\int(\sqrt{u^3}-2 \sqrt{u^2}+\frac{1}{u}) d u$
e $\int(\frac{1}{\sqrt{u}}-2 \sqrt{u}) d u$

Question

Given that $u=x+1$, which integral is equivalent to $\int \frac{x^2}{\sqrt{x+1}} d x$ ? 
a $\int(\sqrt{u^3}+\frac{1}{\sqrt{u}}) d u$ 
b $\int(\sqrt{u^3}-2 \sqrt{u}+\frac{1}{\sqrt{u}}) d u$ 
c $\int(\sqrt{u^3}-2 \sqrt{u}) d u$ 
d $\int(\sqrt{u^3}-2 \sqrt{u^2}+\frac{1}{u}) d u$ 
e $\int(\frac{1}{\sqrt{u}}-2 \sqrt{u}) d u$

GinnyAnswer · Answer

Express x in terms of u : x = u − 1 . 
 Substitute x = u − 1 into the integral: ∫ u ​ ( u − 1 ) 2 ​ d u . 
 Expand and simplify the integral: ∫ ( u ​ u 2 − 2 u + 1 ​ ) d u = ∫ ( u 3/2 − 2 u 1/2 + u − 1/2 ) d u . 
 Rewrite in radical form: ∫ ( u 3 ​ − 2 u ​ + u ​ 1 ​ ) d u . The answer is ∫ ( u 3 ​ − 2 u ​ + u ​ 1 ​ ) d u ​ . 
 
 Explanation 
 
 Problem Analysis We are given the integral ∫ x + 1 ​ x 2 ​ d x and the substitution u = x + 1 . Our goal is to rewrite the integral in terms of u . 
 
 Express x in terms of u and substitute First, we need to express x in terms of u . Since u = x + 1 , we have x = u − 1 . Now we substitute this into the integral: ∫ u ​ ( u − 1 ) 2 ​ d u 
 
 Expand the numerator Next, we expand the numerator: ∫ u ​ u 2 − 2 u + 1 ​ d u 
 
 Divide by sqrt(u) Now, we divide each term in the numerator by u ​ : ∫ ( u ​ u 2 ​ − u ​ 2 u ​ + u ​ 1 ​ ) d u 
 
 Simplify the expression We simplify the expression by using exponent rules. Recall that u ​ = u 1/2 . Thus, we have: ∫ ( u 2 − 1/2 − 2 u 1 − 1/2 + u − 1/2 ) d u = ∫ ( u 3/2 − 2 u 1/2 + u − 1/2 ) d u 
 
 Rewrite using radical notation Finally, we rewrite the expression using radical notation: ∫ ( u 3 ​ − 2 u ​ + u ​ 1 ​ ) d u 
 
 Final Answer Comparing this result with the given options, we see that it matches option b. Therefore, the equivalent integral is ∫ ( u 3 ​ − 2 u ​ + u ​ 1 ​ ) d u .

Examples 
 Imagine you are calculating the flow rate of a fluid through a pipe where the velocity profile depends on the position within the pipe. If the velocity is given by a function involving a square root, such as v ( x ) = x + 1 ​ x 2 ​ , and you need to find the total flow, you would integrate this function over the cross-sectional area. Using a substitution like u = x + 1 can simplify the integral, making it easier to compute the total flow rate. This technique is also applicable in various physics and engineering problems involving complex functions under square roots.

Answer (1)

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