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Chapter 2: Problem 63

a. Use the Intermediate Value Theorem to show that the following equations have a solution on the given interval. b. Use a graphing utility to find all the solutions to the equation on the given interval. c. Illustrate your answers with an appropriate graph. $$x+e^{x}=0 ;(-1,0)$$

Short Answer

Expert verified
Question: Use the Intermediate Value Theorem to show that the equation x + e^x = 0 has a solution on the interval (-1,0), and then use a graphing utility to find the solution and illustrate the answer with a graph. Answer: We applied the Intermediate Value Theorem on the continuous function f(x) = x + e^x for the interval (-1,0) and found that f(-1) ≈ -0.632 and f(0) = 1 have different signs. This implies that there is at least one solution in the given interval. Using a graphing utility, we found an intersection point between the function and the x-axis in the given interval. By illustrating the graph with the function and highlighting the intersection point, we confirmed that the function x + e^x = 0 has a solution in the interval (-1,0).

Step by step solution

01

Find the function values at the endpoints of the interval

First, let's rewrite the equation as $$f(x) = x + e^x$$. Now, we need to find the function values at the given interval endpoints, \(-1\) and \(0\). For \(x=-1\), we have: $$f(-1) = -1 + e^{-1}$$ For \(x=0\), we have: $$f(0) = 0 + e^0$$ (Note that \(e^0 = 1\)) Now, calculate these values.
02

Check the signs of function values

We obtained the following values for \(f(-1)\) and \(f(0)\): $$f(-1) = -1 + e^{-1} = -1 + \frac{1}{e} \approx -0.632$$ $$f(0) = 1$$ Now we check the signs. We can see that \(f(-1)\) and \(f(0)\) have different signs, as \(f(-1) < 0\) and \(f(0) > 0\).
03

Apply the Intermediate Value Theorem

Since the function \(f(x) = x + e^x\) is continuous on \((-1,0)\) and has different signs at the endpoints, according to the Intermediate Value Theorem, we can conclude that there must be at least one solution to the equation in the given interval \((-1,0)\).
04

Use a graphing utility to find the solution(s)

We can use a graphing tool like Desmos or GeoGebra to find the solution(s) on the given interval. Once you've found the graph, find the intersection point(s) between the function \(f(x)\) and the x-axis. This intersection point(s) will be the solution(s) to the equation.
05

Illustrate the answer with a graph

After plotting the graph of \(f(x) = x + e^x\), we can see that there is indeed an intersection point in the interval \((-1,0)\). To better visualize the solution we found, include both the function graph and the x-axis, highlighting the intersection point(s). This will serve as an appropriate illustration of the answer.

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Most popular questions from this chapter

Suppose \(g(x)=\left\\{\begin{array}{ll}x^{2}-5 x & \text { if } x \leq-1 \\ a x^{3}-7 & \text { if } x>-1.\end{array}\right.\) Determine a value of the constant \(a\) for which \(\lim _{x \rightarrow-1} g(x)\) exists and state the value of the limit, if possible.

Evaluate the following limits. \(\lim _{x \rightarrow 1} \frac{x-1}{\sqrt{4 x+5}-3}\)

Use a graphing utility to plot \(y=\frac{\sin p x}{\sin q x}\) for at least three different pairs of nonzero constants \(p\) and \(q\) of your choice. Estimate \(\lim _{x \rightarrow 0} \frac{\sin p x}{\sin q x}\) in each case. Then use your work to make a conjecture about the value of \(\lim _{x \rightarrow 0} \frac{\sin p x}{\sin q x}\) for any nonzero values of \(p\) and \(q\)

Use analytical methods and/or a graphing utility en identify the vertical asymptotes (if any) of the following functions. $$g(\theta)=\tan \frac{\pi \theta}{10}$$

Use the following definitions. Assume fexists for all \(x\) near a with \(x>\) a. We say the limit of \(f(x)\) as \(x\) approaches a from the right of a is \(L\) and write \(\lim _{x \rightarrow a^{+}} f(x)=L,\) if for any \(\varepsilon>0\) there exists \(\delta>0\) such that $$|f(x)-L|<\varepsilon \quad \text { whenever } \quad 0< x-a<\delta$$ Assume fexists for all \(x\) near a with \(x < \) a. We say the limit of \(f(x)\) as \(x\) approaches a from the left of a is \(L\) and write \(\lim _{x \rightarrow a^{-}} f(x)=L,\) if for any \(\varepsilon > 0 \) there exists \(\delta > 0\) such that $$|f(x)-L| < \varepsilon \quad \text { whenever } \quad 0< a-x <\delta$$ Why is the last inequality in the definition of \(\lim _{x \rightarrow a} f(x)=L,\) namely, \(0<|x-a|<\delta,\) replaced with \(0
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