Lecture notes
... There is a special kind of matrix that is similar to the arithmetic multiplication by one. 51=5 This matrix is called: Identity, denoted by I, where all its diagonal elements are set to one and the remaining elements to 0. Since this matrix has the same number of columns and rows: AI=A or IA=A ...
... There is a special kind of matrix that is similar to the arithmetic multiplication by one. 51=5 This matrix is called: Identity, denoted by I, where all its diagonal elements are set to one and the remaining elements to 0. Since this matrix has the same number of columns and rows: AI=A or IA=A ...
Matrix multiplication and composition of linear
... (2) implies (1). First note that if (2) is true and if X1 , . . . , Xr are vectors and c1 , . . . cr are numbers, then T (c1 X1 + · · · + cr Xr ) = c1 T (X1 ) + · · · + cr T (xr ). Now if T satisfies (2), we let B the n×p matrix whose jth column is the vector T (ej ), for j = 1, . . . p. We must pro ...
... (2) implies (1). First note that if (2) is true and if X1 , . . . , Xr are vectors and c1 , . . . cr are numbers, then T (c1 X1 + · · · + cr Xr ) = c1 T (X1 ) + · · · + cr T (xr ). Now if T satisfies (2), we let B the n×p matrix whose jth column is the vector T (ej ), for j = 1, . . . p. We must pro ...
Cartesian tensor
In geometry and linear algebra, a Cartesian tensor uses an orthonormal basis to represent a tensor in a Euclidean space in the form of components. Converting a tensor's components from one such basis to another is through an orthogonal transformation.The most familiar coordinate systems are the two-dimensional and three-dimensional Cartesian coordinate systems. Cartesian tensors may be used with any Euclidean space, or more technically, any finite-dimensional vector space over the field of real numbers that has an inner product.Use of Cartesian tensors occurs in physics and engineering, such as with the Cauchy stress tensor and the moment of inertia tensor in rigid body dynamics. Sometimes general curvilinear coordinates are convenient, as in high-deformation continuum mechanics, or even necessary, as in general relativity. While orthonormal bases may be found for some such coordinate systems (e.g. tangent to spherical coordinates), Cartesian tensors may provide considerable simplification for applications in which rotations of rectilinear coordinate axes suffice. The transformation is a passive transformation, since the coordinates are changed and not the physical system.