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2.14a (with the exact concept of limit coming soon); while there is a unit minimum value of cosh x at x = 0, viz.

(2.477) equation

based on Eq. (2.473) – with derivation rules to be introduced in due course.

Top: Graph with a U-shaped curve labeled cosh x and an ascending curve labeled sinh x. Bottom left: Graph with 2 hyperbolic curves labeled cotanh x and ascending curve labeled tanh x. Bottom right: Graph with 2 hyperbolic curves labeled cosech x and a curve labeled sech x.

Figure 2.14 Variation, with their argument x, of major hyperbolic functions, (a) hyperbolic sine (sinh) and cosine (cosh), (b) hyperbolic tangent (tanh) and cotangent (cotanh), and (c) hyperbolic secant (sech) and cosecant (cosech).

On the other hand, ordered addition of Eqs. (2.472) and (2.473), viz.

(2.478) equation

along with cancelation of symmetrical terms lead to

(2.479) equation

while ordered subtraction of Eq. (2.472) from Eq. (2.473) yields

(2.480) equation

since e^x /2 cancels out with its negative – or simply

(2.481) equation

Equations (2.479) and (2.481) are expected, in view of cosh x being an even function and sinh x being an odd function – as per Eqs. (2.474) and (2.475), respectively, coupled with Eq. (2.1).

The remaining functions of practical interest include the hyperbolic tangent, tanh x, defined as

(2.482) equation

– at the expense of Eqs. (2.472) and (2.473), after dropping 2 from both numerator and denominator; as well as its reciprocal, the hyperbolic cotangent, cotanh x, according to

(2.483) equation

with the aid of Eq. (2.482) – both of which are depicted in Fig. 2.14b. Note the monotonically increasing pattern of tanh x, with

(2.484) equation

serving as leftward horizontal asymptote based on Eq. (2.482), complemented by

(2.485) equation

serving as rightward horizontal asymptote; along with the decreasing behavior of cotanh x, despite the discontinuity at x = 0, i.e.

(2.486) equation

stemming from Eq. (2.483) – which accordingly justifies why the vertical axis plays the role of vertical asymptote.

By the same token, the hyperbolic secant, sech x, abides to

(2.487) equation

after resorting to Eq. (2.473); while the corresponding hyperbolic cosecant, cosech x, looks like

(2.488) equation

once Eq. (2.472) is retrieved – and as plotted in Fig. 2.14c. When x approaches zero, the hyperbolic cosecant is driven by

(2.489) equation

arising from Eq. (2.488), so x = 0 plays the role of vertical asymptote for this function; as for the remaining values, cosech x monotonically decreases within]−∞,0[ and also within]0,∞[, as can be grasped in Fig. 2.14c. Conversely,

(2.490) equation

based on Eq. (2.487) – so the horizontal axis serves as horizontal asymptote toward −∞, whereas

(2.491) equation

indicates that the very same straight line serves as (horizontal) asymptote toward ∞. In this case, there is a maximum at x = 0 – since d sech x/dx = −2(e^x − e^−x)/(e^x + e^−x)² (to be fully proven at a later stage) equals zero when e^x = e^−x, or else at x = 0; this critical point is easily perceived in Fig. 2.14c. Finally, note the resemblance between the functional form of Eqs. (2.482) and (2.483) with Eqs.

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