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

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which readily leads to Eq. (2.431) after dropping of 2ab between sides.

Image described by caption and surrounding text.

Figure 3.3 Graphical representation of (a) vectors u and v, (b) u and symmetrical of v, denoted as vector −v, (c, d) sum of u and – v, denoted as (d) vector w, (d,e,g) with lengths ‖ u ‖, ‖ v ‖, and ‖ w ‖, respectively, and (e) following rotation, and horizontal and vertical flipping of u, −v, and w; of (f) normal vectors u and v and (g) triangle with sides defined by u and v, and hypotenuse defined by w; and of (h) concentric squares, the larger with side a + b and the smaller with side c after rotation so as to touch the former at four points – with concomitant definition of lengths a and b.

3.4 Vector Multiplication of Vectors

The vector (or outer) product of two vectors is a third vector – denoted as u × v, and abiding to

(3.111) equation

here sin{∠ u , v } denotes sine of (the smaller) angle formed by vectors u and v – and n denotes unit vector normal to the plane containing u and v, and oriented such that u, v, and n form a right‐handed system. As will be proven in due time, the area, S, of a parallelogram with sides accounted for by u and v is given by the product of its base, ‖ u ‖, by its heigth – which is, in turn, obtained as the projection of v onto u^⊥, i.e. ‖ v ‖ sin {∠ u , v }, as given by

(3.112) equation

hence, Eq. (3.111) can be rewritten as

(3.113) equation

meaning that the vector product defines the vector area, Sn, of the portion of plane bounded by vectors u and v . The definition conveyed by Eq. (3.111) implies that the vector product is nil for two collinear vectors, because the sine of the angle formed thereby is nil; hence, the vector product being nil does not necessarily imply that at least one of the factors is a nil vector itself.

The vector product is not commutative; in fact,

(3.114) equation

stemming from Eq. (3.111), where −n appears because the vector system is now left handed; Eq. (3.114) may thus be rewritten as

(3.115) equation

due to commutativity of the product of scalars, so one eventually finds

(3.116) equation

– which means that the vector product is actually anticommutative.

Consider now vectors u, v, and w as depicted in Fig. 3.4a. Equation (3.59) still holds, relating ‖ u ‖ to L_[0A], as well as Eq. (3.111) pertaining to u × v, while one has that

(3.117) equation

as per Fig. 3.4b – where [BD], with length L_[BD], denotes a straight segment opposed to ∠ u, v and obtained after projection of v onto u^⊥. Consequently,

(3.118) equation

based on Eqs. (3.59), (3.112), and (3.117) – and illustrated in Fig. 3.4f. By the same token,

(3.119) equation

as per Fig. 3.4c, where [EF] denotes a straight segment opposed to ∠ u, w and obtained via projection of w onto u^⊥; therefore,

(3.120) equation

stemming from Eqs. (3.59), (3.112), and (3.119) – and apparent in Fig. 3.4g. Finally,

(3.121) equation

as per Fig. 3.4d, where [CG] denotes a straight segment opposed to ∠ u, v + w and generated through projection of v + w onto u^⊥; hence,

(3.122)Скачать книгу