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Chapter 7: Problem 4

Gives a value of \(\sinh x\) or \(\cosh x .\) Use the definitions and the identity \(\cosh ^{2} x-\sinh ^{2} x=1\) to find the values of the remaining five hyperbolic functions. $$\cosh x=\frac{13}{5}, \quad x>0$$

Short Answer

Expert verified
\(\sinh x = \frac{12}{5}\); other functions are \(\tanh x = \frac{12}{13}\), \(\coth x = \frac{13}{12}\), \(\text{sech} x = \frac{5}{13}\), \(\text{csch} x = \frac{5}{12}\).

Step by step solution

01

Recall Hyperbolic Identities

The hyperbolic identity that we can use here is \( \cosh^2 x - \sinh^2 x = 1 \). This is analogous to the Pythagorean identity in trigonometry but for hyperbolic functions.
02

Substitute Given Value

Substitute the given value of \( \cosh x = \frac{13}{5} \) into the identity: \( \left(\frac{13}{5}\right)^2 - \sinh^2 x = 1 \).
03

Simplify Expression

Calculate \( \cosh^2 x \): \( \left(\frac{13}{5}\right)^2 = \frac{169}{25} \). The equation becomes \( \frac{169}{25} - \sinh^2 x = 1 \).
04

Solve for \(\sinh^2 x\)

Rearrange to solve for \(\sinh^2 x\): \( \sinh^2 x = \frac{169}{25} - 1 \). This simplifies to \( \sinh^2 x = \frac{144}{25} \).
05

Solve for \(\sinh x\)

Since \( x>0 \), \( \sinh x = \sqrt{\frac{144}{25}} = \frac{12}{5} \).
06

Calculate Remaining Hyperbolic Functions

Using the definitions: 1. \( \tanh x = \frac{\sinh x}{\cosh x} = \frac{\frac{12}{5}}{\frac{13}{5}} = \frac{12}{13} \).2. \( \coth x = \frac{1}{\tanh x} = \frac{13}{12} \).3. \( \text{sech} x = \frac{1}{\cosh x} = \frac{5}{13} \).4. \( \text{csch} x = \frac{1}{\sinh x} = \frac{5}{12} \).

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Key Concepts

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

Understanding \( \sinh \)
The hyperbolic sine function, denoted as \( \sinh x \), is a hyperbolic function closely related to the exponential function. It is defined as \( \sinh x = \frac{e^x - e^{-x}}{2} \). This definition shows that \( \sinh x \) is a measure of the vertical distance from the origin using hyperbolic geometry.
Unlike regular sine and cosine functions, which relate to circles, \( \sinh x \) operates over a hyperbola. Here are some key characteristics:
  • \( \sinh x \) is an odd function, meaning \( \sinh(-x) = -\sinh(x) \).
  • The graph of \( \sinh x \) is symmetric over the origin.
  • As \( x \) becomes very large, \( \sinh x \) approaches \( \frac{e^x}{2} \), indicating rapid growth.
Understanding \( \sinh x \) provides insight into solving problems like the one in the exercise, where it is calculated based on \( \cosh x \) using hyperbolic identities.
The Anatomy of \( \cosh \)
Hyperbolic cosine, represented as \( \cosh x \), is another fundamental hyperbolic function. It is defined by the equation \( \cosh x = \frac{e^x + e^{-x}}{2} \). This function describes the distance along the axis of a hyperbola.
Unlike \( \sinh x \), \( \cosh x \) is an even function, with several unique properties:
  • \( \cosh(-x) = \cosh(x) \), showcasing its even symmetry.
  • The minimum value of \( \cosh x \) is 1, occurring when \( x = 0 \).
  • As \( x \) increases, \( \cosh x \) follows an exponential growth, similar to \( \sinh x \), but never goes below 1.
In the exercise, the given value of \( \cosh x = \frac{13}{5} \) sets the stage for finding other hyperbolic functions, including \( \sinh x \), by utilizing the hyperbolic identity.
Hyperbolic Identities Unveiled
Hyperbolic identities are key tools in solving problems involving hyperbolic functions. The main identity used in the exercise is \( \cosh^2 x - \sinh^2 x = 1 \). It's akin to the Pythagorean identity in trigonometry, \( \cos^2 x + \sin^2 x = 1 \), but adjusted for hyperbolic contexts.
These identities help in:
  • Bridging \( \sinh x \) and \( \cosh x \) through their squared values.
  • Calculating unknown hyperbolic functions when one is known, like in the solution's steps.
With this identity, determining remaining hyperbolic functions becomes straightforward when one function like \( \cosh x \) is given. Besides the main identity, others include:
  • \( 1 - \tanh^2 x = \text{sech}^2 x \)
  • \( \, \text{coth}^2 x - 1 = \text{csch}^2 x \)
These identities create a framework for understanding and computing all related hyperbolic functions.

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Most popular questions from this chapter

Show that the value of $$\lim _{x \rightarrow \infty} \frac{\ln (x+a)}{\ln x}$$ is the same no matter what value you assign to the constant \(a\) What does this say about the relative rates at which the functions \(f(x)=\ln (x+a)\) and \(g(x)=\ln x\) grow?

Evaluate the integrals in Exercises \(107-110.\) $$\int_{1}^{\ln x} \frac{1}{t} d t, \quad x>1$$

Evaluate the integrals in Exercises \(67-74\) in terms of a. inverse hyperbolic functions. b. natural logarithms. $$\int_{0}^{1 / 2} \frac{d x}{1-x^{2}}$$

Find the domain and range of each composite function. Then graph the composites on separate screens. Do the graphs make sense in each case? Give reasons for your answers. Comment on any differences you see. a. \(y=\sin ^{-1}(\sin x)\) b. \(y=\sin \left(\sin ^{-1} x\right)\)

Use logarithmic differentiation to find the derivative of \(y\) with respect to the given independent variable. $$y=\sin x^{x}$$
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