"A handy book like this," noted The Mathematical Gazette, "will fill a great want." Devoted to fully worked out examples, this unique text constitutes a self-contained introductory course in vector analysis for undergraduate and graduate students of applied mathematics.
Opening chapters define vector addition and subtraction, show how to resolve and determine the direction of two or more vectors, and explain systems of coordinates, vector equations of a plane and straight line, relative velocity and acceleration, and infinitely small vectors. The following chapters deal with scalar and vector multiplication, axial and polar vectors, areas, differentiation of vector functions, gradient, curl, divergence, and analytical properties of the position vector. Applications of vector analysis to dynamics and physics are the focus of the final chapter, including such topics as moving rigid bodies, energy of a moving rigid system, central forces, equipotential surfaces, Gauss's theorem, and vector flow.

lgrsnf/Shorter L.R. Problems and worked solutions in vector analysis (Dover, 1961)(ASIN B0007DO4IE)(K)(T)(O)(372s)_MCta_.djvu

Cover
Title page
Date-line
Preface
CONTENTS
Title
CHAPTER I. ADDITION
[1]. Definition of a vector
[2]. Addition of vectors
[3]. Vectorial signs and subtraction of vectors
[4]. Resolution of a vector into parts, one scalar, the other vectorial
[5]. Resolution of a vector into its components
[6]. On the determination of the direction of a vector
[7]. Systems of coordinates
[8]. Vector equations of the plane and the straight line
[9]. Vector equation of a straight line passing through two given points
[10]. Vector equation of a plane passing through the extremities of three vectors $\vec{a}$, $\vec{b}$, $\vec{c}$, drawn from a common origin $O$
[11]. Centre of mass or centroid
[12]. Centroid of a system consisting of two point-masses
[13]. Relative velocity and acceleration
[14]. Varying vectors and vector point-functions
[15]. Infinitely small vectors
[16]. Differences of vectors
CHAPTER II. EXAMPLES ON CHAPTER I
[17]. Plan of the present Chapter
[18]. List of examples in illustration of the results of Chapter I
[19]. Examples 1 to 40
CHAPTER III. MULTIPLICATION
[20]. Multiplication of scalars and vectors
[21]. "Multiplication" of vectors by vectors
[22]. Scalar multiplication
[23]. Vector multiplication
[24]. Variation of the angle between two vectors
[25]. The commutative law of algebra in the multiplication of vectors
[26]. The distributive law of algebra in the multiplication of vectors
[27]. The distributive law in the multiplication of vectors (continued). Extension to the products of polynomials generally
[28]. Scalar and vector products of unit vectors. The reciprocal vector
[29]. Scalar products of vectors when resolved into their components
[30]. Vector products of vectors when resolved into their components
[31]. The areas of the projections on the coordinate planes of $YZ$, $ZX$, $ZY$ of the parallelogram whose adjacent sides are the vectors $\vec{a}$ and $\vec{b}$, are respectively equal to $c_1$, $c_2$, $c_3$ of the preceding section
[32]. Extension of the conception of the area represented by $\vec{a}\times\vec{b}$
[33]. "Axial" and "polar" vectors
[34]. Scalar multiplication of a polar and an axial vector
[35]. Extension of the results of the preceding to the case of the area $OABD$ of Fig. 78 having any contour whatever. Pseudo-scalars
[36]. Relation between the rectangular components of an axial vector and the areas of the projections on the coordinate planes of the area represented by the axial vector
[37]. Vector product of a polar vector and an axial vector
[38]. Geometrical verification of the vector equation $\vec{a}\times(\vec{b}\times\vec{c}) = \vec{b}( \vec{c}\cdot\vec{a} )—\vec{c}( \vec{a}\cdot\vec{b} )$
[39]. Scalar and vector products of two axial vectors
[40]. Division of vectors
CHAPTER IV. EXAMPLES ON CHAPTER III
[41]. List of examples in illustration of the results of Chapter III
[42]. Examples 41 to 104
CHAPTER V. DIFFERENTIATION
[43]. The independent variable is always a scalar quantity
[44]. Development of some results already obtained in scalar multiplication (Chapter III)
[45]. Differentiation of a scalar function
[46]. Differentiation of a vector function
[47]. Differentiation of the product of two scalars, of the product of a scalar and a vector, and of the scalar and vector products of two vectors
[48]. Differentiation of a unit vector
[49]. The "gradient" of a scalar function
[50]. Recapitulation of the results of the preceding section
[51]. Finite displacements
[52]. Expression of the partial differential coefficients $\partial a/\partial x$, $\partial a/\partial y$, $\partial a/\partial z$ in terms of $\nabla a$ or $\grad a$
[53]. Application of the operator $\nabla$ to a vector function of the space coordinates of a point
[54]. Application of the operator $\nabla$ to the sum or difference of two point-functions
[55]. Modification of the notation of expressions in which $\nabla$ is present
[56]. Application of the operator $\nabla$ to the products of two point-functions
[57]. Vector "Identities"
[58]. Successive operations with $\nabla$
[59]. Alternative expression for the total differential coefficient of a vector
[60]. Analytical properties of the position vector, i.e. the vector joining the origin to a given point in space
[61]. Application of $\nabla$ to the position vector $\vec{r}$, and to its scalar value $r$
[62]. Curvature and tortuosity of curves
CHAPTER VI. EXAMPLES ON CHAPTER V
[63]. List of examples in illustration of the results of Chapter V
[64]. Note referring to Examples 105-110
[65]. Examples 105 to 138
CHAPTER VII. APPLICATIONS
[66]. Kinematics of a rigid body treated by differential methods
[67]. The line integral
[68]. Application of $\nabla$ to $\vec{v}$ and $d\vec{v}/dt$ in a moving rigid body
[69]. Determination of the "Minimum Couple" of a system of forces acting on a rigid body
[70]. Energy of a moving rigid body. Momental ellipsoid
[71]. Euler's equations of motion of a rigid body deduced vectorially from D'Alembert's second equation
[72]. The equations of the linear and angular momentum of a rigid body obtained by vectorial methods
[73]. Impulses in a rigid system treated vectorially
[74]. Vectorial methods applied to central forces
[75]. Equipotential surfaces
[76]. Transformation of an integral of a vector function over a closed surface into an integral of an allied function over the volume enclosed by the surface
[77]. Equivalence of the line integral of a given point-function round a closed curve to the surface integral of an allied point-function over a surface bounded by the closed curve. Stokes's Theorem
[78]. Vector flow
[79]. Vector flow (continued). Time-rate of change of vector flow through a surface moving with velocity $\vec{v}$
List of Equations
Index

2024-08-04