Ch. 4 - Applications of Derivatives

Hass15th EditionThomas' CalculusISBN: 9780137616077Not the one you use?Change textbook

Hass 15th Edition

Ch. 4 - Applications of Derivatives

Problem 4.1.54

Chapter 4, Problem 4.1.54

Theory and Examples

In Exercises 53 and 54, show that the function has neither an absolute minimum nor an absolute maximum on its natural domain.

y = 3x + tan x

Verified step by step guidance

Identify the natural domain of the function y = 3x + tan(x). The function tan(x) is undefined at odd multiples of π/2, so the natural domain is all real numbers except x = (2n+1)π/2, where n is an integer.

Consider the behavior of the function as x approaches the points where tan(x) is undefined. As x approaches (2n+1)π/2 from the left, tan(x) approaches negative infinity, and from the right, tan(x) approaches positive infinity. This indicates that the function y = 3x + tan(x) has vertical asymptotes at these points.

Analyze the behavior of the function as x approaches positive and negative infinity. As x approaches positive or negative infinity, the linear term 3x dominates, causing the function to increase or decrease without bound.

Since the function has vertical asymptotes and increases or decreases without bound as x approaches infinity or negative infinity, it does not attain a highest or lowest value on its natural domain.

Conclude that the function y = 3x + tan(x) has neither an absolute minimum nor an absolute maximum on its natural domain due to the presence of vertical asymptotes and unbounded behavior at infinity.

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Key Concepts

Here are the essential concepts you must grasp in order to answer the question correctly.

Natural Domain

The natural domain of a function is the set of all possible input values (x-values) for which the function is defined. For the function y = 3x + tan x, the natural domain excludes values where tan x is undefined, such as x = π/2 + kπ, where k is an integer. Understanding the domain is crucial for analyzing the behavior of the function across its entire range.

Absolute Minimum and Maximum

An absolute minimum or maximum refers to the lowest or highest value a function can attain on a given interval or domain. For y = 3x + tan x, determining the existence of absolute extrema involves analyzing the function's behavior and limits, especially considering the periodic nature and asymptotes of the tangent function, which can lead to unbounded behavior.

Behavior of Trigonometric Functions

Trigonometric functions like tan x have unique properties, such as periodicity and asymptotes, which affect their graphs and values. The tangent function has vertical asymptotes at odd multiples of π/2, causing it to approach infinity. This behavior is key to understanding why y = 3x + tan x may not have absolute extrema, as the function can increase or decrease without bound near these asymptotes.

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Related Practice

Textbook Question

Identify the inflection points and local maxima and minima of the functions graphed in Exercises 1–8. Identify the open intervals on which the functions are differentiable and the graphs are concave up and concave down.

5. y=x+sin(2x), -2π/3≤x≤2π/3

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Textbook Question

Roots (Zeros)

Show that the functions in Exercises 19–26 have exactly one zero in the given interval.

g(t) = 1/(1 − t) + √(1 + t) − 3.1, (−1, 1)

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Textbook Question

Root Finding

5. Use Newton's method to find the positive fourth root of 2 by solving the equation x^4 -2 = 0. Start with x_0 = 1 and find x_2.

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Textbook Question

Each of Exercises 67–88 gives the first derivative of a continuous function y=f(x). Find y'' and then use Steps 2–4 of the graphing procedure described in this section to sketch the general shape of the graph of f.

71. y' = x(x² - 12)

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Textbook Question

Sketch the graphs of the rational functions in Exercises 53–60.

𝓍⁴ ― 1

y = ------------------

𝓍²

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Textbook Question

Initial Value Problems