From bd1f6b5eefe15c8f5fa73da2d1fc4b36705bfe0e Mon Sep 17 00:00:00 2001 From: JJ Date: Sun, 29 Sep 2024 15:20:09 -0700 Subject: meow --- mathematics/algebra.md | 69 -------------------------------------------------- 1 file changed, 69 deletions(-) delete mode 100644 mathematics/algebra.md (limited to 'mathematics/algebra.md') diff --git a/mathematics/algebra.md b/mathematics/algebra.md deleted file mode 100644 index 3717445..0000000 --- a/mathematics/algebra.md +++ /dev/null @@ -1,69 +0,0 @@ ---- -layout: algebra -title: mathematics/algebra ---- - -# algebra - -Modern algebra is the study of **algebraic structures**: groups, rings, fields, modules, and the like. These structures are very abstract: and so results can be applied to a wide variety of situations. - -## structures - -An **algebraic structure** is a set with a collection of *operations* and a finite set of *axioms* those operations must satisfy. - -A [**group**](group-theory) $G$ is a set with a single binary operation $⋆$ satisfying the following axioms: -- associativity: $∀a,b,c : (a⋆b)⋆c = a⋆(b⋆c)$ -- identity: $∃e, ∀a : e⋆a = a⋆e = a$ -- inverse: $∀a, ∃a^{-1} : a⋆a^{-1} = e$ -- An Abelian or **commutative group** satisfies an additional axiom: - - commutativity: $∀a,b : a⋆b=b⋆a$ - -A **monoid** is a group without an inverse operation. - -A [**ring**](ring-theory) $R$ is a set with two binary operations $+$ and $×$ satisfying the following axioms: -- $(R, +)$ is a *commutative group*: - - associativity: $∀a,b,c : (a+b)+c = a+(b+c)$ - - additive identity: $∃0, ∀a : 0+a = a+0 = a$ - - additive inverse: $∀a, ∃-a : a+(-a) = 0$ - - commutativity: $∀a,b : a+b=b+a$ -- $(R, ×)$ is a *monoid* - - associativity: $∀a,b,c : (a×b)×c = a×(b×c)$ - - multiplicative identity: $∃1, ∀a : 1×a = a×1 = a$ -- The *distributive laws* hold for + and ×: - - $∀a,b,c : (a+b) × c = (a×c)+(b×c)$ - - $∀a,b,c : a × (b+c) = (a×b) + (a×c)$ -- An Abelian or **commutative ring** satisfies an additional axiom: - - commutativity (of $×$): $∀a,b : a×b=b×a$ - -A **field** is a *commutative ring* where all elements sans $0$ have an inverse $a^{-1}$ under multiplication. Subsequently, $0 ≠ 1$. A field may be also thought of as a set on which addition, subtraction, multiplication, and division are defined and behave as they do on $ℝ$. - -A [**vector space**](linear-algebra) $V$ over a field $F$ of scalars is a set with a binary operation $+$ and a binary function satisfying the following axioms: -- $(V, +)$ is a *commutative group*: - - associativity: $∀u,v,w : (u+v)+w = u+(v+w)$ - - additive identity: $∃0, ∀v: 0+v = v+0 = v$ - - additive inverse: $∀v, ∃-v: v+(-v) = 0$ - - commutativity: $∀u,v : u+v=v+u$ -- $(V, )$ is a *scalar operation*: - - scalar identity: $∃1 ∈ F, ∀v ∈ V : 1v = v1 = v$ - - commutativity: $∀a,b ∈ F, ∀v ∈ V : (ab)v = a(bv)$ -- The *distributive laws* hold: - - $∀a ∈ F, ∀u,v ∈ V : a(u+v) = au+av$ - - $∀a,b ∈ F, ∀v ∈ V : (a+b)v = av + bv$ - -A **module** $M$ is a generalization of a *vector space* to function over a ring $R$ instead of a field. - -A [**lattice**](order-theory) $L$ is a set with two binary operations $∧$ and $∨$ satisfying the following axioms: -- commutativity: - - $∀a,b : a ∧ b = b ∧ a$ - - $∀a,b : a ∨ b = b ∨ a$ -- associativity: - - $∀a,b,c : a ∧ (b ∧ c) = (a ∧ b) ∧ c$ - - $∀a,b,c : a ∨ (b ∨ c) = (a ∨ b) ∨ c$ -- absorption: - - $∀a,b : a ∧ (a ∨ b) = a$ - - $∀a,b : a ∨ (a ∧ b) = a$ -- idempotence: - - $∀a : a ∧ a = a$ - - $∀a : a ∨ a = a$ - -An **algebra** $A$ over a field $F$ is a *vector space* equipped with an additional *bilinear product*. It is also common to consider algebras over a *ring* (and thus $A$ as a *module* with an additional product). -- cgit v1.2.3-70-g09d2