Abstract Algebra

Descripción

Senior Freshman Mathematics Mapa Mental sobre Abstract Algebra, creado por Luke Byrne el 22/04/2018.
Luke Byrne
Mapa Mental por Luke Byrne, actualizado hace más de 1 año
Luke Byrne
Creado por Luke Byrne hace más de 6 años
820
2

Resumen del Recurso

Abstract Algebra
  1. Binary Operations
    1. Let A be a set. A binary operation, ∗, on A is an operation applied to any two elements x, y ∈ A that yields an element x ∗ y in A. In other words, ∗ is a binary operation on A if ∀x, y ∈ A, x ∗ y ∈ A.
      1. Examples
        1. R, +
          1. Addition on R : ∀x, y ∈ R, x + y ∈ R
            1. Commutative
              1. Associative
              2. R, —
                1. Not Commutative
                  1. Not Associative
                  2. R, x
                    1. Commutative and Associative
                    2. R, /
                      1. Division on R is NOT a binary operation because ∀x ∈ R ∃ 0 ∈ R s.t. x/0 is undefined (not an element of R)
                  3. Semigroups
                    1. A semigroup is a set endowed with an associative binary operation. We denote the semigroup (A, *).

                      Adjunto:

                      1. (x + y) + z = x + (y + z)
                      2. Examples
                        1. Let A be a set and let P(A) be its power set. (P(A), ∩) and (P(A), ∪) are both semigroups.
                          1. (Mn, ∗), the set of n*n matrices with entries in R with the operation of matrix multiplication (which is associative) forms a semigroup.
                            1. Let (A, ∗) be a semigroup
                            2. General Associative Law
                              1. Let (A, ∗) be a semigroup. ∀a1, ..., an ∈ A, a1 ∗ a2 ∗ ... ∗ an has the same value regardless of how the product is bracketed.
                            3. Identity Elements
                              1. Let (A, ∗) be a semigroup
                                1. An element, e, e ∈ A, is called an identity element for the binary operation ∗, if e ∗ x = x ∗ e = x, ∀x ∈ A.
                                  1. (R, +): e = 0
                                    1. (R, x): e = 1
                                      1. (P(A), ∪): e = ∅
                                        1. (P(A), ∩): e = A
                                          1. (Mn, ∗) has In, the identity matrix, as its identity element
                                      2. Monoids
                                        1. A monoid is a semigroup (A, ∗), where ∗ has an identity element, e.
                                          1. Commutative (Abelian)
                                            1. (R, +): commutative monoid, e = 0
                                              1. (R, x): commutative monoid, e = 1
                                                1. (P(A), ∪): commutative monoid, e = ∅
                                                  1. (N, +): commutative monoid, e = 0
                                                  2. Non-Commutative
                                                    1. (Mn, ∗): monoid, e = In, but matrix multiplication is not commutative
                                                      1. (N*, +): semigroup, as N* = N\{0}
                                                    2. Inverses
                                                      1. Let (A, ∗) be a monoid with identity element, e, and let a ∈ A. An element y of A is called the inverse of x, if x ∗ y = y ∗ x = e. If an element a ∈ A has an inverse, then a is called invertible.
                                                        1. Invertible Monoids
                                                          1. (R, +): invertible, e = 0, ∀x ∈ R,(−x) is the inverse of xas x + (-x) = (-x) + x = 0.
                                                          2. Invertible Monoids (with exception)
                                                            1. (R, x): invertible, e = 1, ONLY if x != 0. If x != 0, inverse of x is 1/x, since x * 1/x = 1/x * x = 1
                                                              1. (Mn, ∗): invertible, e = In, ONLY if det(A) != 0
                                                              2. Not Invertible
                                                                1. (P(A), ∪): non-invertible, e = ∅
                                                                  1. However, the element ∅ of P(A) is invertible and has itself as its inverse: ∅ ∪ ∅ = ∅ ∪ ∅ = ∅
                                                                2. Groups
                                                                  1. A group is a monoid in which every element is invertible. In other words, a grouop is a set A endowed with a binary operation ∗, where ∗ is associative, there exists an identity element, and every element of A is invertible.
                                                                    1. (A, ∗, e)
                                                                      1. Closure
                                                                        1. IMPLICIT as ∀a, b ∈ A, a ∗ b ∈ A
                                                                        2. Commutative
                                                                          1. (R, +, 0): -x (inverse)
                                                                            1. (Q*, x, 1), 1/q (inverse)
                                                                              1. (R^3, +, 0) vectors, -x, -y, -z inverse
                                                                                1. (x, y, z) + (x', y', z') = (x + x', y + y', z + z')
                                                                          2. Morphs
                                                                            1. Homomorphism
                                                                              1. f(x∗y) = f(x) ∗ f(y) ∀x, y ∈ A
                                                                              2. Isomorphism

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