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authorJJ2024-01-18 22:00:05 +0000
committerJJ2024-01-18 22:00:05 +0000
commit19ab14173c4242792cee0bd9b75d81c788e0fb70 (patch)
tree5cbf3c75d720bc7b0403000f14ed44b5c4103467 /mathematics
parentf0846498d1ffc320445feae07eed571522a460ba (diff)
meow
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-rw-r--r--mathematics/algebra.md17
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diff --git a/mathematics/algebra.md b/mathematics/algebra.md
index 5047970..4b9a097 100644
--- a/mathematics/algebra.md
+++ b/mathematics/algebra.md
@@ -6,14 +6,13 @@ title: mathematics/algebra
# algebra
modern algebra is the study of **algebraic structures**: groups, rings, fields, modules, vector spaces, lattices, and the like.
-
these structures are very general: and so results from abstract algebra 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** $G$ is a set with a single binary operation ⋆ satisfying the following axioms:
+A **group** $G$ 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: $∀a, ∃a^{-1} : a⋆a^{-1} = e$
@@ -22,7 +21,7 @@ A **group** $G$ is a set with a single binary operation ⋆ satisfying the follo
A **monoid** is a group without an inverse operation.
-A **ring** $R$ is a set with two binary operations + and × satisfying the following axioms:
+A **ring** $R$ 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: $∃0, ∀a : 0+a = a+0 = a$
@@ -39,7 +38,7 @@ A **ring** $R$ is a set with two binary operations + and × satisfying the follo
A **field** is a *commutative ring* where $0 ≠ 1$ and all elements sans $0$ have an inverse $a^{-1}$ under multiplication.
-A **vector space** $V$ over a field $F$ of scalars is a set with a binary operation + and a binary function satisfying the following axioms:
+A **vector space** $V$ 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: $∃0, ∀v: 0+v = v+0 = v$
@@ -55,7 +54,7 @@ A **vector space** $V$ over a field $F$ of scalars is a set with a binary operat
A **module** $M$ is a generalization of a *vector space* to function over a ring $R$ instead of a field.
A **lattice** $L$ is a set with two binary operations ∧ and ∨ satisfying the following axioms:
-- commutativity:
+- commutativity:
- $∀a,b : a ∧ b = b ∧ a$
- $∀a,b : a ∨ b = b ∨ a$
- associativity:
@@ -70,12 +69,20 @@ A **lattice** $L$ is a set with two binary operations ∧ and ∨ satisfying the
## group theory
+...
+
## ring theory
+...
+
## galois theory
+...
+
## linear algebra
+...
+
## order theory
a lattice may alternatively be defined as...