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Chapter 3: Problem 6

Find the general antiderivative \(F(x)+C\) for each of the following. $$ f(x)=3 x^{2 / 3} $$

Short Answer

Expert verified
The general antiderivative is \( F(x) + C = \frac{9}{5}x^{5/3} + C \).

Step by step solution

01

Identify the function

The function given is \( f(x) = 3x^{2/3} \). We need to find its antiderivative, which involves integrating the function.
02

Recall the Power Rule for Integration

The power rule for integration tells us that the antiderivative of \( x^n \) is \( \frac{x^{n+1}}{n+1} \) if \( n eq -1 \). We can apply this rule to integrate \( 3x^{2/3} \).
03

Apply the Power Rule

Apply the power rule to the function: \[ \int 3x^{2/3} \, dx = 3 \cdot \frac{x^{2/3 + 1}}{2/3 + 1} \] Calculate \( 2/3 + 1 = 5/3 \).
04

Simplify the Expression

Simplify the expression:\[ 3 \cdot \frac{x^{5/3}}{5/3} = 3 \cdot \frac{3}{5} \cdot x^{5/3} = \frac{9}{5}x^{5/3} \].
05

Add the Constant of Integration

Since we are finding the general antiderivative, we need to add the constant of integration \( C \). Thus, the antiderivative of \( f(x) = 3x^{2/3} \) is \[ F(x) + C = \frac{9}{5}x^{5/3} + C \].

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Power Rule for Integration
The Power Rule for Integration is a fundamental technique used for finding antiderivatives of polynomial expressions. This rule is particularly useful because it simplifies the integration process by directly applying a formula. The basic idea is straightforward: if you have a function in the form of \( x^n \), where \( n \) is not equal to \(-1\), the antiderivative is given by:
  • \( \frac{x^{n+1}}{n+1} \)
This formula helps us "undo" the differentiation of power functions.

In the given exercise, the function is \( f(x) = 3x^{2/3} \). By applying the power rule, we calculate \( n + 1 \) where \( n = \frac{2}{3} \), yielding \( \frac{5}{3} \). The antiderivative becomes \( \frac{x^{5/3}}{5/3} \). This step transforms the complex-looking power into a manageable expression, allowing further simplification.
Constant of Integration
When finding antiderivatives, always remember to add the Constant of Integration, denoted as \( C \). This constant represents an infinite number of possible vertical shifts of the antiderivative.

The reason behind this is simple: differentiation eliminates constants. So when you differentiate any constant, its derivative is zero. When we integrate and recover the original function, we can miss any constant that was there initially. Therefore, the general solution to an indefinite integral should always include \( C \).
  • Example: \( \,F(x) + C = \frac{9}{5}x^{5/3} + C\)
Incorporating the constant of integration is crucial in expressing the full range of solutions an antiderivative can provide.
Integration Technique
Solving the given function \( f(x) = 3x^{2/3} \) involves selecting the correct integration technique. For polynomial-like expressions or functions that can be decomposed into powers of x, applying the Power Rule is efficient.

Here's a detailed step-by-step approach:
  • Identify if the function is suitable for the Power Rule by recognizing its polynomial features.
  • Adjust the power by incrementing it by 1, which is necessary for integration.
  • Divide by this new power to complete the antiderivative formula \( \frac{x^{n+1}}{n+1} \).
  • Simplify the expression as needed for easier understanding and applications, transforming fractions and constants if required.
In this exercise, we took \( 3x^{2/3} \) and used the Power Rule to find the antiderivative. Practice with various functions will show how powerful and versatile this integration technique really is.

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Most popular questions from this chapter

In installment buying, one would like to figure out the real interest rate (effective rate), but unfortunately this involves solving a complicated equation. If one buys an item worth \(\$ P\) today and agrees to pay for it with payments of \(\$ R\) at the end of each month for \(k\) months, then $$ P=\frac{R}{i}\left[1-\frac{1}{(1+i)^{k}}\right] $$ where \(i\) is the interest rate per month. Tom bought a used car for \(\$ 2000\) and agreed to pay for it with \(\$ 100\) payments at the end of each of the next 24 months. (a) Show that \(i\) satisfies the equation $$ 20 i(1+i)^{24}-(1+i)^{24}+1=0 $$ (b) Show that Newton's Method for this equation reduces to $$ i_{n+1}=i_{n}-\left[\frac{20 i_{n}^{2}+19 i_{n}-1+\left(1+i_{n}\right)^{-23}}{500 i_{n}-4}\right] $$ (c) Find \(i\) accurate to five decimal places starting with \(i=0.012,\) and then give the annual rate \(r\) as a percent \((r=1200 i)\)

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