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Algebra of Linear Transformations - Vector Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET PDF Download

linear transformation is a function from one vector space to another that respects the underlying (linear) structure of each vector space. A linear transformation is also known as a linear operator or map. The range of the transformation may be the same as the domain, and when that happens, the transformation is known as an endomorphism or, if invertible, an automorphism. The two vector spaces must have the same underlying field.

he defining characteristic of a linear transformation  Algebra of Linear Transformations - Vector Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET  is that, for any vectors v1 and v2 in V and scalars a and b of the underlying field,

Algebra of Linear Transformations - Vector Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

Linear transformations are useful because they preserve the structure of a vector space. So, many qualitative assessments of a vector space that is the domain of a linear transformation may, under certain conditions, automatically hold in the image of the linear transformation. For instance, the structure immediately gives that the kernel and image are both subspaces (not just subsets) of the range of the linear transformation.

Most linear functions can probably be seen as linear transformations in the proper setting. Transformations in the change of basis formulas are linear, and most geometric operations, including rotations, reflections, and contractions/dilations, are linear transformations. Even more powerfully, linear algebra techniques could apply to certain very non-linear functions through either approximation by linear functions or reinterpretation as linear functions in unusual vector spaces. A comprehensive, grounded understanding of linear transformations reveals many connections between areas and objects of mathematics.

Example

A common transformation in Euclidean geometry is rotation in a plane, about the origin. By considering Euclidean points as vectors in the vector space R2, rotations can be viewed in a linear algebraic sense. A rotation of v counterclockwise by angle θ is given by

Algebra of Linear Transformations - Vector Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

The linear transformation Rotate goes from R2 and R3 and is given by the matrix shown above. Because this matrix is invertible for any value θ, it follows that this linear transformation is in fact an automorphism. Since rotations can be "undone" by rotating in the opposite direction, this makes sense.

Types of Linear Transformations

Linear transformations are most commonly written in terms of matrix multiplication. A transformation Algebra of Linear Transformations - Vector Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET from m-dimensional vector space V to n--dimensional vector space W is given by an n x m matrix M. Note, however, that this requires choosing a basis for V and a basis for W, while the linear transformation exists independent of basis. (That is, it could be expressed as a matrix for any selection of bases.)

Example

The linear transformation from R3 to R2 defined byT (x,y,z) = (x - y, y - z) is given by the matrix

Algebra of Linear Transformations - Vector Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

So,  T can also be defined for vectors v =(v1 , v2, v3) by the matrix product

Algebra of Linear Transformations - Vector Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

Note that the dimension of the initial vector space is the number of columns in the matrix, while the dimension of the target vector space is the number of rows in the matrix.

Linear transformations also exist in infinite-dimensional vector spaces, and some of them can also be written as matrices, using the slight abuse of notation known as infinite matrices. However, the concept of linear transformations exists independent of matrices; matrices simply provide a nice framework for finite computations.

A linear transformation is surjective if every vector in its range is in its image. Equivalently, at least one n x n minor of the n x m matrix is invertible. It is injective if if every vector in its image is the image of only one vector in its domain. Equivalently, at least one m x m minor of the n x m matrix is invertible.

Example 

Is the linear transformation T(x,y,z) = (x - y, y - z) from R3 to R2,  injective? Is it surjective?

For a vector v = (v1,v2,v3), this can be written as

Algebra of Linear Transformations - Vector Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

M is a 2 x 3 matrix, so it is surjective because the minor Algebra of Linear Transformations - Vector Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET has determinant 1 and therefore is invertible (since the determinant is nonzero). However, there are no  3 x 3 minors, so it is not injective.

 

A linear transformation  Algebra of Linear Transformations - Vector Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET  between two vector spaces of equal dimension (finite or infinite) is invertible if there exists a linear transformation T-1 such thatAlgebra of Linear Transformations - Vector Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET for any vector Algebra of Linear Transformations - Vector Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET  For finite dimensional vector spaces, a linear transformation is invertible if and only if its matrix is invertible.

Example

Note that a linear transformation must be between vector spaces of equal dimension in order to be invertible. To see why, consider the linear transformation 

T(x,y,z) = (x - y, y - z) from R3 to R2, his linear transformation has a right inverse S (x,y) = (x + y, y, 0). That is, 

T(S (x,y)) = T(x + y, y, 0) = (x,y) for all (x,y) ∈R2.  However, it has no left inverse, since there is no map R : R2 → R3  such that 

R(T (x,yz)) = T(x, y, z) = (x,y) for all (x,y,z) ∈R3. This follows from facts about the rank of T.

Examples of Linear Transformations

A linear transformation can take many forms, depending on the vector space in question.

Consider the vector space  Algebra of Linear Transformations - Vector Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET of polynomials of degree at most n. By noting there are n + 1 coefficients in any such polynomial, in some sense the equality  Algebra of Linear Transformations - Vector Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET holds. However, there is a natural linear transformation d/dx on the vector space  Algebra of Linear Transformations - Vector Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET  that satisfies

Algebra of Linear Transformations - Vector Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NETAlgebra of Linear Transformations - Vector Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

Effects on the Basis

A linear transformation from vector space V to vector space w is determined entirely by the image of basis vectors of V. This allows for more concise representations of linear transformations, and it provides a linear algebraic explanation for the relation between linear transformations and matrices (the matrix's columns and rows represent bases).

Theorem

Let V and W be vector spaces over the same field, and let B ⊂ V be a set of basis vectors of V. Then, for any function  f : B → W, there is a unique linear transformation T : V → W such that T(u) = f(u) for each u ∈ B. Furthermore, the span of f(B) is equal to the image of T.

In other words, a linear transformation can be created from any function (no matter how "non-linear" in appearance) on the basis vectors. The behavior of basis vectors entirely determines the linear transformation.

Proof

The proof follows from the fact that any element of V is expressible as a linear combination of basis elements and that there is only one possible such linear combination.

With this mentality, change of basis can be used to rewrite the matrix for a linear transformation in terms of any basis. This is particularly helpful for endomorphisms (linear transformations from a vector space to itself).

However, the linear transformation itself remains unchanged, independent of basis choice. That is, no matter what the choice of basis, all the qualities of a linear transformation remain unchanged: injectivity, surjectivity, invertibility, diagonalizability, etc.

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FAQs on Algebra of Linear Transformations - Vector Algebra, CSIR-NET Mathematical Sciences - Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

1. What is a linear transformation in vector algebra?
Ans. A linear transformation in vector algebra is a function that maps vectors from one vector space to another, while preserving the linear structure of the vectors. It satisfies two properties: additivity and homogeneity. Additivity means that the transformation of the sum of two vectors is equal to the sum of the transformations of the individual vectors. Homogeneity means that the transformation of a scalar multiple of a vector is equal to the scalar multiple of the transformation of the vector.
2. How is the composition of linear transformations defined?
Ans. The composition of two linear transformations, say T and U, is defined as the transformation obtained by applying U first and then T. In other words, if T maps vectors from vector space V to vector space W, and U maps vectors from vector space W to vector space X, then the composition of T and U, denoted as TU, maps vectors from V to X. The composition of linear transformations is also a linear transformation.
3. What is the kernel of a linear transformation?
Ans. The kernel of a linear transformation, also known as the null space, is the set of all vectors in the domain that are mapped to the zero vector in the codomain by the transformation. In other words, it is the set of all vectors that are "annihilated" or "collapsed" to zero under the linear transformation. The kernel of a linear transformation is always a subspace of the domain vector space.
4. How can the range of a linear transformation be determined?
Ans. The range of a linear transformation is the set of all possible vectors in the codomain that can be obtained by applying the transformation to vectors in the domain. To determine the range, we can consider the image of the standard basis vectors of the domain. The set of all these images forms a spanning set for the range. By determining the linear independence of this spanning set, we can find a basis for the range and hence determine the range of the linear transformation.
5. Can a linear transformation have an inverse?
Ans. A linear transformation can have an inverse if and only if it is a one-to-one (injective) and onto (surjective) mapping. In other words, the linear transformation must preserve both the linear structure and the bijective property. If a linear transformation has an inverse, it is called an invertible or bijective linear transformation. The inverse of a linear transformation, if it exists, is also a linear transformation.
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