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

rel="nofollow" href="#ulink_534d2138-ace4-5f23-8c76-cd6ca840ba47">Eq. (2.84).

Graph of Sn/u0 vs. n displaying 4 ascending curves labeled 2, 1, 0.5, and 0 = k/u0.

Figure 2.4 Variation of value of n‐term arithmetic series, S_n, normalized by first term, u₀, as a function of n – for selected values of increment, k, normalized also by u₀.

2.1.2 Geometric Series

A geometric series is said to exist when each term is obtained from the previous one via multiplication by a constant parameter, k, viz.

(2.86) equation

– and is said to possess ratio k and first term u₀; after factoring u₀ out, Eq. (2.86) becomes

(2.87) equation

An alternative form of calculating images ensues after first rewriting Eq. (2.87) as

(2.88) equation

where the first term of the summation was made apparent; multiplication of both sides by k unfolds

(2.89) equation

where straightforward algebraic rearrangement leads to

(2.90) equation

Ordered subtraction of Eq. (2.90) from Eq. (2.88) generates

(2.91) equation

where images may be factored out in the left‐hand side and u₀ in its right counterpart to obtain

(2.92) equation

upon canceling out symmetrical terms in the right‐hand side, and dividing both sides by 1 − k afterward, Eq. (2.92) becomes

(2.93) equation

Note that k = 1 turns nil both numerator and denominator of Eq. (2.93), so it is a (common) root thereof; Ruffini’s rule (see below) then permits reformulation of Eq. (2.93) to

(2.94) equation

that mimics Eq. (2.87), as expected. Revisiting Eq. (2.72) with division of both sides by u₀, one may insert Eq. (2.93) to get

(2.95) equation

Eq. (2.95) is illustrated in Fig. 2.5. Upon inspection of this plot, one anticipates a horizontal asymptote for k = 0.5 (besides k = 0); in general, one indeed finds that

(2.96) equation

at the expense of Eqs. (2.72), (2.73), and (2.95), which is equivalent to

(2.97) equation

– and reduces to merely

(2.98) equation

should k lie between −1 and 1, as it would give rise to a convergent series (i.e. k^{n + 1} → 0 when n → ∞, in this case). All remaining values, i.e. k ≤ −1 or k ≥ 1, produce divergent series – as apparent in Fig. 2.5; when k is nil, Eq. (2.93) turns to just

(2.99) equation

which corresponds to the trivial case of only the first term of said series being significant – and fully consistent with Eqs. (2.97) and (2.98).

Graph of Sn/u0 vs. n displaying 2 ascending curves labeled k = 2 and 1 and an almost flat curve labeled 0.5.

Figure 2.5 Variation of value of n‐term geometric series, S_n, normalized by first term, u₀, as a function of n – for selected values of ratio, k.

An alternative proof of Eq. (2.93) comes from finite induction; one should first confirm that it applies to n = 0, i.e.

(2.100)Скачать книгу