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Chapter 2: Problem 41

Decide if each function is odd, even, or neither by using the definitions. $$f(x)=x^{5}-2 x$$

Short Answer

Expert verified
The given function \(f(x)=x^{5}-2x\) is an odd function.

Step by step solution

01

Compute f(-x)

To find whether the function is even or odd, we need to calculate \(f(-x)\) which involves replacing every \(x\) in \(f(x)\) with \(-x\). So, \(f(-x)=(-x)^{5}-2(-x)= -x^{5}+2x\).
02

Compare f(-x) with f(x) and -f(x)

Now, compare \(f(-x)\) with \(f(x)\) and \(-f(x)\). We have \(f(x) = x^{5}-2x\) and \(-f(x) = -x^{5}+2x\). Comparing, we can see that \(f(-x)= -f(x)\), hence the given function is an odd function. And it is clear that \(f(-x) \neq f(x)\), so it is not an even function.

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Key Concepts

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

Function Symmetry
Understanding function symmetry is essential in determining if a function is odd, even, or neither. The symmetry of a function reveals how it behaves when its input is transformed (like flipping across axes). A function is said to be **even** if it is symmetric with respect to the y-axis. Mathematically, this means that for every input \(x\), \(f(x) = f(-x)\). Think of it as looking into a mirror placed on the y-axis: the reflection of the graph on one side should perfectly overlap with the other side.

An **odd** function, on the other hand, is symmetric about the origin. This implies that for every \(x\), \(f(-x) = -f(x)\). A useful way to visualize this is by performing a 180-degree rotation around the origin. If the function maps onto itself in this way, it is odd.

If neither symmetry condition is satisfied, the function is neither even nor odd. Understanding these properties allows you to discern more information about the function's behavior and how it might look when graphed.
Polynomial Functions
Polynomial functions are expressions involving variables raised to whole-number exponents, such as \(f(x) = x^5 - 2x\). These functions are quite straightforward since they are composed of several terms added together, each term being a product of a constant and a variable raised to a power.

Polynomials can be classified based on their degree, which is the highest power of the variable in the expression. For example, in \(x^5 - 2x\), the degree is 5, indicating a quintic polynomial. The structure of polynomial functions usually provides visual symmetry clues. **Even-degree polynomials** tend to show even symmetry, while **odd-degree polynomials** often display odd symmetry.

One significant property of polynomials is how they behave with respect to function symmetry. For our original example, calculating \(f(-x)\) yields the expression \(-x^5 + 2x\), leading to a determination that \(f(x)\) is an odd function since \(f(-x)\) mirrors \(-f(x)\). Understanding these fundamental aspects is crucial for correctly identifying the symmetry properties of polynomial functions.
Function Transformation
Function transformation involves modifying a function's graph in a variety of ways. These transformations can include shifting, scaling, reflecting, or rotating. When analyzing a function like \(f(x) = x^5 - 2x\), transformations can provide insights into behavior changes without altering the function’s inherent properties.

Here are common types of transformations:
  • **Translation**: Shifting the graph horizontally or vertically depending on added constants outside the function.
  • **Scaling**: Expanding or contracting the graph in the vertical or horizontal direction, affecting the steepness or width of the graph shape.
  • **Reflection**: Flipping the graph over an axis. This forms the core of determining whether a function is even or odd.
Reflecting a function about the y-axis or the origin can help reveal its symmetry characteristics, aiding the determination of evenness or oddness. Through transformations, the essential nature of functions becomes more visually and conceptually clear, offering deeper insights into their mathematical properties.

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Most popular questions from this chapter

A rectangular garden plot is to be enclosed with a fence on three of its sides and an existing wall on the fourth side. There is 45 feet of fencing material available. (a) Write an equation relating the amount of available fencing material to the lengths of the three sides that are to be fenced. (b) Use the equation in part (a) to write an expression for the width of the enclosed region in terms of its length. (c) For each value of the length given in the following table of possible dimensions for the garden plot, fill in the value of the corresponding width. Use your expression from part (b) and compute the resulting area. What do you observe about the area of the enclosed region as the dimensions of the garden plot are varied? $$\begin{array}{ccc}\hline \begin{array}{c}\text { Length } \\\\\text { (feet) }\end{array} & \begin{array}{c}\text { Width } \\\\\text { (feet) }\end{array} & \begin{array}{c}\text { Total Amount of } \\\\\text { Fencing Material (feet) }\end{array} & \begin{array}{c}\text { Area } \\\\\text { (square feet) }\end{array} \\\\\hline 5 & & 45 \\\10 & & 45 \\\15 & & 45 \\\20 & & 45 \\\30 & & 45 \\\k & & 45 \\\& &\end{array}$$ (d) Write an expression for the area of the garden plot in terms of its length. (e) Find the dimensions that will yield a garden plot with an area of 145 square feet.

Graph each quadratic function by finding a suitable viewing window with the help of the TABLE feature of a graphing utility. Also find the vertex of the associated parabola using the graphing utility. $$h(x)=x^{2}+5 x-20$$

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Attendance at Broadway shows in New York can be modeled by the quadratic function \(p(t)=0.0489 t^{2}-0.7815 t+10.31,\) where \(t\) is the number of years since 1981 and \(p(t)\) is the attendance in millions. The model is based on data for the years \(1981-2000 .\) (Source: The League of American Theaters and Producers, Inc.) (a) Use this model to estimate the attendance in the year \(1995 .\) Compare it to the actual value of 9 million. (b) Use this model to predict the attendance for the year 2006 (c) What is the vertex of the parabola associated with the function \(p\), and what does it signify in relation to this problem? (d) Would this model be suitable for predicting the attendance at Broadway shows for the year \(2025 ?\) Why or why not? (e) \(\quad\) Use a graphing utility to graph the function \(p\) What is an appropriate range of values for \(t ?\)
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