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Compare the relative severity of a magnitude 8.4 earthquake with a magnitude 7.4 earthquake.

The magnitude 8.4 earthquake is roughly 10 times as severe as the magnitude 7.4 earthquake.

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Hyperbolic functions

The hyperbolic functions are defined in terms of certain combinations of e x and e x . These functions arise naturally in various engineering and physics applications, including the study of water waves and vibrations of elastic membranes. Another common use for a hyperbolic function is the representation of a hanging chain or cable, also known as a catenary ( [link] ). If we introduce a coordinate system so that the low point of the chain lies along the y -axis, we can describe the height of the chain in terms of a hyperbolic function. First, we define the hyperbolic functions    .

A photograph of a spider web collecting dew drops.
The shape of a strand of silk in a spider’s web can be described in terms of a hyperbolic function. The same shape applies to a chain or cable hanging from two supports with only its own weight. (credit: “Mtpaley”, Wikimedia Commons)

Definition

Hyperbolic cosine

cosh x = e x + e x 2

Hyperbolic sine

sinh x = e x e x 2

Hyperbolic tangent

tanh x = sinh x cosh x = e x e x e x + e x

Hyperbolic cosecant

csch x = 1 sinh x = 2 e x e x

Hyperbolic secant

sech x = 1 cosh x = 2 e x + e x

Hyperbolic cotangent

coth x = cosh x sinh x = e x + e x e x e x

The name cosh rhymes with “gosh,” whereas the name sinh is pronounced “cinch.” Tanh , sech , csch , and coth are pronounced “tanch,” “seech,” “coseech,” and “cotanch,” respectively.

Using the definition of cosh ( x ) and principles of physics, it can be shown that the height of a hanging chain, such as the one in [link] , can be described by the function h ( x ) = a cosh ( x / a ) + c for certain constants a and c .

But why are these functions called hyperbolic functions ? To answer this question, consider the quantity cosh 2 t sinh 2 t . Using the definition of cosh and sinh , we see that

cosh 2 t sinh 2 t = e 2 t + 2 + e −2 t 4 e 2 t 2 + e −2 t 4 = 1 .

This identity is the analog of the trigonometric identity cos 2 t + sin 2 t = 1 . Here, given a value t , the point ( x , y ) = ( cosh t , sinh t ) lies on the unit hyperbola x 2 y 2 = 1 ( [link] ).

An image of a graph. The x axis runs from -1 to 3 and the y axis runs from -3 to 3. The graph is of the relation “(x squared) - (y squared) -1”. The left most point of the relation is at the x intercept, which is at the point (1, 0). From this point the relation both increases and decreases in curves as x increases. This relation is known as a hyperbola and it resembles a sideways “U” shape. There is a point plotted on the graph of the relation labeled “(cosh(1), sinh(1))”, which is at the approximate point (1.5, 1.2).
The unit hyperbola cosh 2 t sinh 2 t = 1 .

Graphs of hyperbolic functions

To graph cosh x and sinh x , we make use of the fact that both functions approach ( 1 / 2 ) e x as x , since e x 0 as x . As x , cosh x approaches 1 / 2 e x , whereas sinh x approaches −1 / 2 e x . Therefore, using the graphs of 1 / 2 e x , 1 / 2 e x , and 1 / 2 e x as guides, we graph cosh x and sinh x . To graph tanh x , we use the fact that tanh ( 0 ) = 1 , −1 < tanh ( x ) < 1 for all x , tanh x 1 as x , and tanh x 1 as x . The graphs of the other three hyperbolic functions can be sketched using the graphs of cosh x , sinh x , and tanh x ( [link] ).

An image of six graphs. Each graph has an x axis that runs from -3 to 3 and a y axis that runs from -4 to 4. The first graph is of the function “y = cosh(x)”, which is a hyperbola. The function decreases until it hits the point (0, 1), where it begins to increase. There are also two functions that serve as a boundary for this function. The first of these functions is “y = (1/2)(e to power of -x)”, a decreasing curved function and the second of these functions is “y = (1/2)(e to power of x)”, an increasing curved function. The function “y = cosh(x)” is always above these two functions without ever touching them. The second graph is of the function “y = sinh(x)”, which is an increasing curved function. There are also two functions that serve as a boundary for this function. The first of these functions is “y = (1/2)(e to power of x)”, an increasing curved function and the second of these functions is “y = -(1/2)(e to power of -x)”, an increasing curved function that approaches the x axis without touching it. The function “y = sinh(x)” is always between these two functions without ever touching them. The third graph is of the function “y = sech(x)”, which increases until the point (0, 1), where it begins to decrease. The graph of the function has a hump. The fourth graph is of the function “y = csch(x)”. On the left side of the y axis, the function starts slightly below the x axis and decreases until it approaches the y axis, which it never touches. On the right side of the y axis, the function starts slightly to the right of the y axis and decreases until it approaches the x axis, which it never touches. The fifth graph is of the function “y = tanh(x)”, an increasing curved function. There are also two functions that serve as a boundary for this function. The first of these functions is “y = 1”, a horizontal line function and the second of these functions is “y = -1”, another horizontal line function. The function “y = tanh(x)” is always between these two functions without ever touching them. The sixth graph is of the function “y = coth(x)”. On the left side of the y axis, the function starts slightly below the boundary line “y = 1” and decreases until it approaches the y axis, which it never touches. On the right side of the y axis, the function starts slightly to the right of the y axis and decreases until it approaches the boundary line “y = -1”, which it never touches.
The hyperbolic functions involve combinations of e x and e x .

Identities involving hyperbolic functions

The identity cosh 2 t sinh 2 t , shown in [link] , is one of several identities involving the hyperbolic functions, some of which are listed next. The first four properties follow easily from the definitions of hyperbolic sine and hyperbolic cosine. Except for some differences in signs, most of these properties are analogous to identities for trigonometric functions.

Rule: identities involving hyperbolic functions

  1. cosh ( x ) = cosh x
  2. sinh ( x ) = sinh x
  3. cosh x + sinh x = e x
  4. cosh x sinh x = e x
  5. cosh 2 x sinh 2 x = 1
  6. 1 tanh 2 x = sech 2 x
  7. coth 2 x 1 = csch 2 x
  8. sinh ( x ± y ) = sinh x cosh y ± cosh x sinh y
  9. cosh ( x ± y ) = cosh x cosh y ± sinh x sinh y
Practice Key Terms 7

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Source:  OpenStax, Calculus volume 1. OpenStax CNX. Feb 05, 2016 Download for free at http://cnx.org/content/col11964/1.2
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