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

having relabeled θ₁ and θ₂ to y and x, respectively. Equation (2.321), known as the basic angle transformation formula, permits calculation of the cosine of a difference of angles based on knowledge of sine and cosine of the individual angles – and is actually valid, irrespective of the relative amplitude of angles θ₁ and θ₂. If θ₂ is set equal to π/2 in particular, then Eq. (2.320) becomes

(2.322) equation

which reduces to

(2.323) equation

because cos π/2 is nil and sin π/2 is unity; Eq. (2.323) confirms that sine and cosine are complementary functions – so a change of variable to x ≡ π/2 − θ₁ (implying θ₁ = π/2 − x) allows retrieval of Eq. (2.294), as expected.

After rewriting Eq. (2.321) as

(2.324) equation

at the expense of Eqs. (2.295) and (2.296), and changing notation of −y to y (in view of its being a dummy variable), one obtains

(2.325) equation

Eq. (2.325) permits rapid calculation of the cosine of a sum of two arguments, again based on the sine and cosine of the individual arguments. On the other hand, Eqs. (2.294) and (2.323) allow reformulation of Eq. (2.321) to

(2.326) equation

where the argument of the left‐hand side may be rearranged to read

(2.327) equation

since dummy variable π/2 − x may as well be rewritten as just x, Eq. (2.327) transforms to

(2.328) equation

– thus unfolding an expression for the sine of a sum of two arguments based on sine and cosine of either argument. Finally, one may rewrite Eq. (2.328) as

(2.329) equation

again with the aid of Eqs. (2.295) and (2.296); since −y may be exchanged with y in both sides for being a dummy variable, Eq. (2.329) eventually yields

(2.330) equation

– so the difference between the two cross products of sine and cosine of arguments x and y allows generation of sine of the corresponding difference.

In view of the definition of tangent conveyed by Eq. (2.299), one may write

(2.331) equation

following insertion of Eqs. (2.321) and (2.330); division of both numerator and denominator by cos x and cos y gives rise to

(2.332) equation

where insertion of Eq. (2.299) allows simplification to

(2.333) equation

By the same token, ordered division of Eq. (2.328) by Eq. (2.325) generates

(2.334) equation

where division of both numerator and denominator of the right‐hand side simultaneously by cos x and cos y unfolds

(2.335) equation

Eq. (2.335) becomes

(2.336) equation

after taking Eq. (2.299) into account. Equations (2.333) and (2.336) permit calculation of the tangent of an algebraic sum of arguments, knowing the tangents of the individual arguments.

On the other hand, one may take reciprocals of both sides of Eq. (2.333) to get

(2.337) equation

with division of both numerator and denominator of the right‐hand side by tan x and tan y yielding

(2.338)Скачать книгу