Linear algebra (Osnabrück 2024-2025)/Part I/List of definitions

The set which does not contain any element is called the empty set, denoted by

${\displaystyle \emptyset .}$

Let ${\displaystyle {}T}$ and ${\displaystyle {}M}$ denote sets. ${\displaystyle {}T}$ is called a subset

of ${\displaystyle {}M}$ if every element of ${\displaystyle {}T}$ is also an element of ${\displaystyle {}M}$.

For sets ${\displaystyle {}L}$ und ${\displaystyle {}M}$, we call

${\displaystyle {}L\cap M={\left\{x\mid x\in L{\text{ and }}x\in M\right\}}\,}$

the intersection

of the two sets.

For sets ${\displaystyle {}L}$ und ${\displaystyle {}M}$, we call

${\displaystyle {}L\cup M={\left\{x\mid x\in L{\text{ or }}x\in M\right\}}\,}$

the union

of the sets.

Suppose that two sets ${\displaystyle {}L}$ and ${\displaystyle {}M}$ are given. Then the set

${\displaystyle {}L\times M={\left\{(x,y)\mid x\in L,\,y\in M\right\}}\,}$

is called the product set

(or Cartesian product) of the sets.

Let ${\displaystyle {}L}$ and ${\displaystyle {}M}$ denote sets. A mapping ${\displaystyle {}F}$ from ${\displaystyle {}L}$ to ${\displaystyle {}M}$ is given by assigning to every element of the set ${\displaystyle {}L}$ exactly one element of the set ${\displaystyle {}M}$. The unique element that is assigned to ${\displaystyle {}x\in L}$ is denoted by ${\displaystyle {}F(x)}$. For the mapping as a whole, we write

${\displaystyle F\colon L\longrightarrow M,x\longmapsto F(x).}$

Let ${\displaystyle {}L}$ and ${\displaystyle {}M}$ denote sets, and let

${\displaystyle F\colon L\longrightarrow M,x\longmapsto F(x),}$

be a mapping. Then ${\displaystyle {}F}$ is called injective if for two different elements ${\displaystyle {}x,x'\in L}$, also ${\displaystyle {}F(x)}$ and ${\displaystyle {}F(x')}$

are different.

Let ${\displaystyle {}L}$ and ${\displaystyle {}M}$ denote sets, and let

${\displaystyle F\colon L\longrightarrow M,x\longmapsto F(x),}$

be a mapping. Then ${\displaystyle {}F}$ is called surjective if, for every ${\displaystyle {}y\in M}$, there exists at least one element ${\displaystyle {}x\in L}$, such that

${\displaystyle {}F(x)=y\,.}$

Let ${\displaystyle {}M}$ and ${\displaystyle {}L}$ denote sets, and suppose that

${\displaystyle F\colon M\longrightarrow L,x\longmapsto F(x),}$

is a mapping. Then ${\displaystyle {}F}$ is called bijective if ${\displaystyle {}F}$ is injective as well as

surjective.

Let ${\displaystyle {}F\colon L\rightarrow M}$ denote a bijective mapping. Then the mapping

${\displaystyle G\colon M\longrightarrow L}$

that sends every element ${\displaystyle {}y\in M}$ to the uniquely determined element ${\displaystyle {}x\in L}$ with ${\displaystyle {}F(x)=y}$,

is called the inverse mapping of ${\displaystyle {}F}$.

Let ${\displaystyle {}L,\,M}$ and ${\displaystyle {}N}$ denote sets, let

${\displaystyle F\colon L\longrightarrow M,x\longmapsto F(x),}$

and

${\displaystyle G\colon M\longrightarrow N,y\longmapsto G(y),}$

be mappings. Then the mapping

${\displaystyle G\circ F\colon L\longrightarrow N,x\longmapsto G(F(x)),}$

is called the composition of the mappings

${\displaystyle {}F}$ and ${\displaystyle {}G}$.

An operation (or binary operation) ${\displaystyle {}\circ }$ on a set ${\displaystyle {}M}$ is a mapping

${\displaystyle \circ \colon M\times M\longrightarrow M,(x,y)\longmapsto \circ (x,y)=x\circ y.}$

A set ${\displaystyle {}K}$ is called a field if there are two binary operations (called addition and multiplication)

${\displaystyle +:K\times K\longrightarrow K{\text{ and }}\cdot :K\times K\longrightarrow K}$

and two different elements ${\displaystyle {}0,1\in K}$ that fulfill the following properties.

1. Axioms for the addition:
   1. Associative law: ${\displaystyle {}(a+b)+c=a+(b+c)}$ holds for all ${\displaystyle {}a,b,c\in K}$.
   2. Commutative law: ${\displaystyle {}a+b=b+a}$ holds for all ${\displaystyle {}a,b\in K}$.
   3. ${\displaystyle {}0}$ is the neutral element of the addition, i.e., ${\displaystyle {}a+0=a}$ holds for all ${\displaystyle {}a\in K}$.
   4. Existence of the negative: For every ${\displaystyle {}a\in K}$, there exists an element ${\displaystyle {}b\in K}$ with ${\displaystyle {}a+b=0}$.
2. Axioms of the multiplication:
   1. Associative law: ${\displaystyle {}(a\cdot b)\cdot c=a\cdot (b\cdot c)}$ holds for all ${\displaystyle {}a,b,c\in K}$.
   2. Commutative law: ${\displaystyle {}a\cdot b=b\cdot a}$ holds for all ${\displaystyle {}a,b\in K}$.
   3. ${\displaystyle {}1}$ is the neutral element for the multiplication, i.e., ${\displaystyle {}a\cdot 1=a}$ holds for all ${\displaystyle {}a\in K}$.
   4. Existence of the inverse: For every ${\displaystyle {}a\in K}$ with ${\displaystyle {}a\neq 0}$, there exists an element ${\displaystyle {}c\in K}$ such that ${\displaystyle {}a\cdot c=1}$.
3. Distributive law: ${\displaystyle {}a\cdot (b+c)=(a\cdot b)+(a\cdot c)}$ holds for all ${\displaystyle {}a,b,c\in K}$.

For a natural number ${\displaystyle {}n}$, one puts

${\displaystyle {}n!:=n(n-1)(n-2)\cdots 3\cdot 2\cdot 1\,,}$

and calls this ${\displaystyle {}n}$ factorial.

Let ${\displaystyle {}k}$ and ${\displaystyle {}n}$ denote natural numbers with ${\displaystyle {}k\leq n}$. Then

${\displaystyle {}{\binom {n}{k}}:={\frac {n!}{k!(n-k)!}}\,}$

is called the binomial coefficient ${\displaystyle {}n}$ choose ${\displaystyle {}k}$

Let ${\displaystyle {}K}$ be a field. An expression of the form

${\displaystyle {}P=a_{0}+a_{1}X+a_{2}X^{2}+\cdots +a_{n}X^{n}\,,}$

with ${\displaystyle {}a_{i}\in K}$ and ${\displaystyle {}n\in \mathbb {N} }$,

is called a polynomial in one variable over ${\displaystyle {}K}$.

The degree of a nonzero polynomial

${\displaystyle {}P=a_{0}+a_{1}X+a_{2}X^{2}+\cdots +a_{n}X^{n}\,}$

with ${\displaystyle {}a_{n}\neq 0}$

is ${\displaystyle {}n}$.