Kernel (set theory)

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In set theory, the kernel of a function ${\displaystyle f}$ (or equivalence kernel^[1]) may be taken to be either

• the equivalence relation on the function's domain that roughly expresses the idea of "equivalent as far as the function ${\displaystyle f}$ can tell",^[2] or
• the corresponding partition of the domain.

An unrelated notion is that of the kernel of a non-empty family of sets ${\displaystyle ℬ,}$ which by definition is the intersection of all its elements: $${\displaystyle \ker ℬ=\bigcap _{B\in ℬ}B.}$$ This definition is used in the theory of filters to classify them as being free or principal.

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For the formal definition, let ${\displaystyle f:X\to Y}$ be a function between two sets. Elements ${\displaystyle x_1,x_2\in X}$ are equivalent if ${\displaystyle f\left(x_1\right)}$ and ${\displaystyle f\left(x_2\right)}$ are equal, that is, are the same element of ${\displaystyle Y.}$ The kernel of ${\displaystyle f}$ is the equivalence relation thus defined.^[2]

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The Template:Visible anchor isTemplate:Sfn $${\displaystyle \ker ℬ:=\bigcap _{B\in ℬ}B.}$$ The kernel of ${\displaystyle ℬ}$ is also sometimes denoted by ${\displaystyle \cap ℬ.}$ The kernel of the empty set, ${\displaystyle \ker \varnothing ,}$ is typically left undefined. A family is called Template:Em and is said to have Template:Em if its Template:Em is not empty.Template:Sfn A family is said to be Template:Em if it is not fixed; that is, if its kernel is the empty set.Template:Sfn

Like any equivalence relation, the kernel can be modded out to form a quotient set, and the quotient set is the partition: $${\displaystyle \{\{w\in X:f(x)=f(w)\}:x\in X\}=\{f^{-1}(y):y\in f(X)\}.}$$

This quotient set ${\displaystyle X/{=}_f}$ is called the coimage of the function ${\displaystyle f,}$ and denoted ${\displaystyle \mathrm{coim}f}$ (or a variation). The coimage is naturally isomorphic (in the set-theoretic sense of a bijection) to the image, ${\displaystyle \mathrm{im}f;}$ specifically, the equivalence class of ${\displaystyle x}$ in ${\displaystyle X}$ (which is an element of ${\displaystyle \mathrm{coim}f}$) corresponds to ${\displaystyle f(x)}$ in ${\displaystyle Y}$ (which is an element of ${\displaystyle \mathrm{im}f}$).

Like any binary relation, the kernel of a function may be thought of as a subset of the Cartesian product ${\displaystyle X\times X.}$ In this guise, the kernel may be denoted ${\displaystyle \ker f}$ (or a variation) and may be defined symbolically as^[2] $${\displaystyle \ker f:=\{(x,x^{\prime }):f(x)=f(x^{\prime })\}.}$$

The study of the properties of this subset can shed light on ${\displaystyle f.}$

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If ${\displaystyle X}$ and ${\displaystyle Y}$ are algebraic structures of some fixed type (such as groups, rings, or vector spaces), and if the function ${\displaystyle f:X\to Y}$ is a homomorphism, then ${\displaystyle \ker f}$ is a congruence relation (that is an equivalence relation that is compatible with the algebraic structure), and the coimage of ${\displaystyle f}$ is a quotient of ${\displaystyle X.}$^[2] The bijection between the coimage and the image of ${\displaystyle f}$ is an isomorphism in the algebraic sense; this is the most general form of the first isomorphism theorem.

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If ${\displaystyle f:X\to Y}$ is a continuous function between two topological spaces then the topological properties of ${\displaystyle \ker f}$ can shed light on the spaces ${\displaystyle X}$ and ${\displaystyle Y.}$ For example, if ${\displaystyle Y}$ is a Hausdorff space then ${\displaystyle \ker f}$ must be a closed set. Conversely, if ${\displaystyle X}$ is a Hausdorff space and ${\displaystyle \ker f}$ is a closed set, then the coimage of ${\displaystyle f,}$ if given the quotient space topology, must also be a Hausdorff space.

A space is compact if and only if the kernel of every family of closed subsets having the finite intersection property (FIP) is non-empty;^[3][4] said differently, a space is compact if and only if every family of closed subsets with F.I.P. is fixed.

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