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

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for a ≡ 10 and b ≡ e – thus making a tool available to convert a natural exponential to a decimal exponential; note ln 10 appearing again as conversion factor, in parallel to Eq. (2.32).

Complex functions do often exhibit simple linear behaviors near specific finite value(s), or when their independent variable grows unbounded toward either −∞ or ∞; such a driving line – originally described by Apollonius of Perga in the Greek Antiquity, is termed asymptote, and represents a straight line tangent to the germane curve at infinity. A vertical asymptote is accordingly defined by

(2.36) equation

(2.37) equation

typical examples of a are the zeros of the denominator (or poles) of rational functions, or the value(s) that turn nil the argument of a logarithmic function. Oblique asymptotes abide, in turn, to

(2.38) equation

– which will, in particular, be horizontal if b = 0; division of both sides by x transforms Eq. (2.38) to

(2.39) equation

because 0/x = 0 for x ≠ 0 (as is the case) – where a/x becoming, in turn, negligible when x → 0 permits simplification to

(2.40) equation

If the limit described by Eq. (2.40) does not exist, then there is no oblique asymptote in that direction; otherwise, one may proceed and compute a from Eq. (2.38) via

(2.41) equation

where b obviously abides to Eq. (2.40). Although the concept of asymptote may be extended to other polynomial forms (e.g. quadratic) using essentially the same rationale, their determination (and usefulness) is far less common and rather limited.

When in the presence of two (or more, say, n) real values, one may define the most likely value, or arithmetic mean (referred to via subscript_arm, with images denoting mean) as

(2.42) equation

by the same token, one can define a geometric mean (referred to via subscript_gem) as

(2.43) equation

The harmonic mean (referred to via subscript_ham) satisfies

(2.44) equation

or, after taking reciprocals of both sides,

(2.45) equation

the aforementioned three means are useful in a great many problems – depending on the underlying mathematical nature of the data, so their relative location deserves further exploitation (as done below).

Consider, for simplicity, only two values x₁ and x₂; after realizing that

(2.46) equation

for being a square – with validity assured irrespective of the relative magnitude of x₁ and x₂, one may apply Newton’s binomial (to be considered shortly) to write

(2.47) equation

Upon addition of 4x₁ x₂ to both sides, Eq. (2.47) becomes

(2.48) equation

– where Newton’s binomial may again be invoked to support condensation to

(2.49) equation

If square roots are taken of both sides, then Eq. (2.49) transforms to

(2.50) equation

on the common assumption that both x₁ and x₂ are positive – whereas division of both sides by 2 unfolds

(2.51) equation

based on Eqs. (2.42) and (2.43), one concludes that

(2.52) equation

– i.e. the arithmetic mean of two numbers never lies below their geometric mean (being equal only when x₁ = x₂).

On the other hand, inspection of Eq. (2.44) vis‐à‐vis with Eq. (2.42) indicates that images is the arithmetic mean of 1/x₁ and 1/x₂ (in the case of n = 2); hence, application of the result conveyed by Eq. (2.52) indicates that

(2.53)Скачать книгу