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Chapter 2: Problem 30

Find (a) \(f \circ g\) and (b) \(g \circ f\). . \(f(x)=\sqrt[3]{x-1}, \quad g(x)=x^{3}+1\)

Short Answer

Expert verified
(a) \(f \circ g = x\), (b) \(g \circ f = x\).

Step by step solution

01

Find \(f \circ g\)

Replace \(x\) in \(f(x)\) with \(g(x)\). Therefore, \(f \circ g = f(g(x))= \sqrt[3]{g(x)-1}= \sqrt[3]{(x^{3}+1)-1}\)}, which simplifies to \(\sqrt[3]{x^{3}} = x\).
02

Find \(g \circ f\)

Replace \(x\) in \(g(x)\) with \(f(x)\). Therefore, \(g \circ f = g(f(x))= (f(x))^{3}+1)= (\sqrt[3]{x-1})^{3}+1\), which simplifies to \(x-1+1=x\).

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Key Concepts

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

Inverse Functions
Inverse functions essentially go in reverse. They "undo" what the original function does. For a pair of functions, like the ones given:
  • \(f(x) = \sqrt[3]{x-1}\)
  • \(g(x) = x^{3} + 1\)
To find if they are inverses, we evaluate the compositions \(f \circ g\) and \(g \circ f\). If both expressions simplify back to \(x\), the functions are true inverses of each other.

In the example, both compositions simplify correctly:
  • \(f(g(x)) = x\)
  • \(g(f(x)) = x\)
Thus, confirming \(f(x)\) and \(g(x)\) are inverses. In inverse functions, any element that goes through one function and its inverse gets returned to its original state.
Cubic Functions
Cubic functions are a type of polynomial function characterized by the highest degree term being cubed (to the power of 3). An example of a cubic function is
  • \(g(x) = x^{3} + 1\)
This function shapes like a stretched-out "S" when graphed. It has curves due to the cubic term dominating behavior at extreme values of \(x\).

Critical points of cubic functions reveal interesting behavior like turning points or inflections. They don't necessarily imply min or max points which is distinctive of their curve.

Cubic functions can be reversed when a corresponding radical function partners up with them. This is because the cubic can be effectively neutralized through root extraction, demonstrated in their inverse relationship.
Radical Functions
Radical functions include roots—square roots, cube roots, and higher ones—which determines their nature. One such function, used in the exercise, is the cube root function:
  • \(f(x) = \sqrt[3]{x-1}\)
The cube root operation takes a number times itself three times to retrieve the original number from its cube. They’re unique since odd roots (like cube roots) can take negatives and yield negative results, as opposed to even roots.

In operations, combining cube roots with cubic terms often leads to simplifications. This is because they counteract each other thanks to their mathematical relationship. For instance, \(\sqrt[3]{x^3} = x\).

Radical functions, like \(f(x)\), in this problem particularly show how radical functions work with polynomials to return linear relationships, when paired just right.

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Most popular questions from this chapter

While driving at \(x\) miles per hour, you are required to stop quickly to avoid an accident. The distance the car travels (in feet) during your reaction time is given by \(R(x)=\frac{3}{4} x\). The distance the car travels (in feet) while you are braking is given by \(B(x)=\frac{1}{15} x^{2}\) Find the function that represents the total stopping distance \(T\). (Hint: \(T=R+B\).) Graph the functions \(R, B\), and \(T\) on the same set of coordinate axes for \(0 \leq x \leq 60\).

Consider the graph of \(g(x)=\sqrt{x}\) Use your knowledge of rigid and nonrigid transformations to write an equation for each of the following descriptions. Verify with a graphing utility. The graph of \(g\) is shifted four units to the right and three units downward.

Describe the sequence of transformations from \(f(x)=\sqrt[3]{x}\) to \(y\). Then sketch the graph of \(y\) by hand. Verify with a graphing utility. \(y=\sqrt[3]{x+1}\)

Determine whether the statement is true or false. Justify your answer. If you are given two functions \(f(x)\) and \(g(x)\), you can calculate \((f \circ g)(x)\) if and only if the range of \(g\) is a subset of the domain of \(f\).

Show that \(f\) and \(g\) are inverse functions by (a) using the definition of inverse functions and (b) graphing the functions. Make sure you test a few points, as shown in Examples 6 and 7 . \(f(x)=9-x^{2}, \quad x \geq 0\) \(g(x)=\sqrt{9-x}, \quad x \leq 9\)
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