Lie algebroid

In mathematics, a quotient algebra, (where algebra is used in the sense of universal algebra), also called a factor algebra, is obtained by partitioning the elements of an algebra into equivalence classes given by a congruence relation, that is an equivalence relation that is additionally compatible with all the operations of the algebra, in the formal sense described below.

Compatible relation

Let A be a set (of the elements of an algebra ${\displaystyle \mathcal{𝒜}}$), and let E be an equivalence relation on the set A. The relation E is said to be compatible with (or have the substitution property with respect to) an n-ary operation f if for all ${\displaystyle a_1,a_2,\dots ,a_n,b_1,b_2,\dots ,b_n\in A}$ whenever ${\displaystyle (a_1,b_1)\in E,(a_2,b_2)\in E,\dots ,(a_n,b_n)\in E}$ implies ${\displaystyle (f(a_1,a_2,\dots ,a_n),f(b_1,b_2,\dots ,b_n))\in E}$. An equivalence relation compatible with all the operations of an algebra is called a congruence.

Congruence lattice

For every algebra ${\displaystyle \mathcal{𝒜}}$ on the set A, the identity relation on A, and ${\displaystyle A\times A}$ are trivial congruences. An algebra with no other congruences is called simple.

Let ${\displaystyle \mathrm{C}\mathrm{o}\mathrm{n}(\mathcal{𝒜})}$ be the set of congruences on the algebra ${\displaystyle \mathcal{𝒜}}$. Because congruences are closed under intersection, we can define a meet operation: ${\displaystyle \wedge :\mathrm{C}\mathrm{o}\mathrm{n}(\mathcal{𝒜})\times \mathrm{C}\mathrm{o}\mathrm{n}(\mathcal{𝒜})\to \mathrm{C}\mathrm{o}\mathrm{n}(\mathcal{𝒜})}$ by simply taking the intersection of the congruences ${\displaystyle E_1\wedge E_2=E_1\cap E_2}$.

On the other hand, congruences are not closed under union. However, we can define the closure of any binary relation E, with respect to a fixed algebra ${\displaystyle \mathcal{𝒜}}$, such that it is a congruence, in the following way: ${\displaystyle ⟨E{⟩}_{\mathcal{𝒜}}=\bigcap \{F\in \mathrm{C}\mathrm{o}\mathrm{n}(\mathcal{𝒜})|E\subseteq F\}}$. Note that the (congruence) closure of a binary relation depends on the operations in ${\displaystyle \mathcal{𝒜}}$, not just on the carrier set. Now define ${\displaystyle \vee :\mathrm{C}\mathrm{o}\mathrm{n}(\mathcal{𝒜})\times \mathrm{C}\mathrm{o}\mathrm{n}(\mathcal{𝒜})\to \mathrm{C}\mathrm{o}\mathrm{n}(\mathcal{𝒜})}$ as ${\displaystyle E_1\vee E_2=⟨E_1\cup E_2{⟩}_{\mathcal{𝒜}}}$.

For every algebra ${\displaystyle \mathcal{𝒜}}$, ${\displaystyle (\mathcal{𝒜},\wedge ,\vee )}$ with the two operations defined above forms a lattice, called the congruence lattice of ${\displaystyle \mathcal{𝒜}}$.

Quotient algebras and homomorphisms

A set A can be partitioned in equivalence classes given by an equivalence relation E, and usually called a quotient set, and denoted A/E. For an algebra ${\displaystyle \mathcal{𝒜}}$, it is straightforward to define the operations induced on A/E if E is a congruence. Specifically, for any operation ${\displaystyle f_i^{\mathcal{𝒜}}}$ of arity ${\displaystyle n_i}$ in ${\displaystyle \mathcal{𝒜}}$ (where the superscript simply denotes that it's an operation in ${\displaystyle \mathcal{𝒜}}$) define ${\displaystyle f_i^{\mathcal{𝒜}/E}:(A/E{)}^{n_i}\to A/E}$ as ${\displaystyle f_i^{\mathcal{𝒜}/E}([a_1{]}_E,\dots ,[a_{n_i}{]}_E)=[f_i^{\mathcal{𝒜}}(a_1,\dots ,a_{n_i}){]}_E}$, where ${\displaystyle [a{]}_E}$ denotes the equivalence class of a modulo E.

For an algebra ${\displaystyle \mathcal{𝒜}=(A,(f_i^{\mathcal{𝒜}}{)}_{i\in I})}$, given a congruence E on ${\displaystyle \mathcal{𝒜}}$, the algebra ${\displaystyle \mathcal{𝒜}/E=(A/E,(f_i^{\mathcal{𝒜}/E}{)}_{i\in I})}$ is called the quotient algebra (or factor algebra) of ${\displaystyle \mathcal{𝒜}}$ modulo E. There is a natural homomorphism from ${\displaystyle \mathcal{𝒜}}$ to ${\displaystyle \mathcal{𝒜}/E}$ mapping every element to its equivalence class. In fact, every homomorphism h determines a congruence relation; the kernel of the homomorphism, ${\displaystyle \mathrm{k}\mathrm{e}\mathrm{r}h=\{(a,a^{\prime })\in A\times A|h(a)=h(a^{\prime })\}}$.

Given an algebra ${\displaystyle \mathcal{𝒜}}$, a homomorphism h thus defines two algebras homomorphic to ${\displaystyle \mathcal{𝒜}}$, the image h(${\displaystyle \mathcal{𝒜}}$) and ${\displaystyle \mathcal{𝒜}/\mathrm{k}\mathrm{e}\mathrm{r}h}$ The two are isomorphic, a result known as the homomorphic image theorem. Formally, let ${\displaystyle h:\mathcal{𝒜}\to \mathcal{ℬ}}$ be a surjective homomorphism. Then, there exists a unique isomorphism g from ${\displaystyle \mathcal{𝒜}/\mathrm{k}\mathrm{e}\mathrm{r}h}$ onto ${\displaystyle \mathcal{ℬ}}$ such that g composed with the natural homomorphism induced by ${\displaystyle \mathrm{k}\mathrm{e}\mathrm{r}h}$ equals h.

See also

• quotient ring

References

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• 20 year-old Real Estate Agent Rusty from Saint-Paul, has hobbies and interests which includes monopoly, property developers in singapore and poker. Will soon undertake a contiki trip that may include going to the Lower Valley of the Omo.
  
  My blog: http://www.primaboinca.com/view_profile.php?userid=5889534