Mathematics for Enzyme Reaction Kinetics and Reactor Performance. F. Xavier MalcataЧитать онлайн книгу.

and

(2.293) equation

and also their lower and upper bounds, i.e. −1 and 1. It becomes apparent from inspection of Fig. 2.10b that the plot of cos x may be obtained from the plot of sin x via a horizontal translation of π/2 rad leftward; in other words,

(2.294) equation

– and such a complementarity to a right angle, of amplitude π/2 rad, justifies the term cosine (with prefix ‐co standing for complementary, or adding up to a right angle). The sine is an odd function, i.e.

(2.295) equation

hence, its plot is symmetrical relative to the origin of coordinates. Conversely, the cosine is an even function, i.e.

(2.296) equation

– meaning that its plot is symmetrical relative to the vertical axis.

The tangent of angle θ may be defined as the ratio of the length of the opposite leg, [AB], to the length of the adjacent leg, [OA], in triangle [OAB] – or, alternatively, as the ratio of the length of the opposite leg, [BD], to the length of the adjacent leg, [OB], in triangle [OBD], according to

(2.297) equation

– once more with the aid of Eq. (2.287), and as emphasized in Fig. 2.10 a; note that Eq. (2.297) may also appear as

(2.298) equation

following division of both numerator and denominator by images , and with the extra aid of Eqs. (2.288) and (2.290). If θ is expressed in rad, then one has

(2.299) equation

in general – as plotted in Fig. 2.10c. Note that tangent is still a periodic function, but of smaller period, π rad, according to

(2.300) equation

whereas combination of Eqs. (2.295), (2.296), and (2.299) implies that

(2.301) equation

– so the (trigonometric) tangent is an odd function. The tangent is also a monotonically increasing function – yet it exhibits vertical asymptotes at x = kπ/2 (with relative integer k), see again Fig. 2.10c.

The cotangent of angle θ may, in turn, be defined as the ratio of the length of the adjacent leg, [OA], to the length of the opposite leg, [AB], in triangle [OAB] – or, instead, as the tangent of the complementary of angle θ, i.e. ∠BOE, via the ratio of the length of the opposite leg, [BE], to the length of the adjacent leg, [OB], in triangle [OBE], viz.

(2.302) equation

as outlined in Fig. 2.10a, where Eq. (2.287) was taken advantage of; Eq. (2.302) may be redone to

(2.303) equation

again after dividing numerator and denominator by images , and recalling Eqs. (2.288) and (2.290). For a general argument x (in rad), one may accordingly state

(2.304) equation

following comparative inspection of Eqs. (2.298) and (2.303) – which varies with argument x as depicted in Fig. 2.10d. Once again, a period of π rad is apparent, i.e.

(2.305) equation

while Eqs. (2.301) and (2.304) imply

(2.306) equation

– meaning that cotangent is also an odd function. The cotangent always decreases when x increases, and is driven by vertical asymptotes described by x = kπ (with relative integer k) as can be perceived in Fig. 2.10d.

With regard to secant of angle θ, it follows from the ratio of the length of the hypotenuse, [OB], to the length of the adjacent leg, [OA], in triangle [OAB] – or, alternatively, as the ratio of the length of the hypotenuse, [OD], to the length of the adjacent leg, [OB], in triangle [OBD], according to

(2.307)Скачать книгу