User:Lethe/list of categories

In category theory, categories are the main object of study. The following is a list of important categories, and a glossary of named categories.

Table of categories[edit]

**Legend**
symbol	meaning	keys and comments
c	concrete category	objects and morphisms can be constructed as sets and functions
/	quotient objects
⊂	subobjects
∏	products	n: no objects have; c: some objects have; f: any finite number have; y: all objects; fbi:finite number have a biproduct; bi: all have biproduct
∐	coproducts	n: no objects have; c: some objects have; f: any finite number have; y: all objects
=	equalizers
cq	coequalizers
i	initial object
t	terminal object
z	zero object
+	additivity
→	complete
←	cocomplete
⊗	monoidal
ccc	Cartesian closed
y	yes. a category has a given property
a	all. For products or coproducts, all (small) collections of objects have the product or coproduct
f	finite. For products or coproducts, all finite collections of objects have product or coproduct.
bi	finite biproducts. All finite collections of objects in a pre-additive category have biproduct.

Categories[edit]

Category	Objects	morphisms	c	//⊂	∏/∐	=/cq	i/t/z	+	→/←	⊗	ccc	comments
Ab	abelian groups	group homomorphisms	y	y/y	y/y	y/y	0	Ab	y/y	y		a full reflective subcategory of Grp. Isomorphic to Z-Mod. Abelianization a functor from Grp.
AbF	filtered abelian groups		y	y/y			0	pAb
AbT	topological abelian groups	homomorphisms	y	y/y	y/y	y/y	0	pAb
Act-S	semiautomata	S-homomorphisms	n
Adj	small categories	adjunctions	n
Aff or AffSch	affine schemes
K-Alg or Alg_K	associative unital algebras over field K	homomorphisms	y	y	y y		0	Ab	y	y	n
AlgSet/K	algebraic sets	regular maps	y	y/y				n	n		n
Bool	Boolean algebras	homomorphisms	y					n	y			dually equivalent to Stone by Stone's representation theorem
CAb	compact abelian groups	group homomorphisms	y					Ab	y		n
Cat	small categories	functors	n		y/n		t: 1	n	y	y	y	with natural transformations, forms a 2-category
CGHaus	compactly generated Hausdorff spaces		y		y/y		n	n	y		y	used as a replacement for Top which has the benefit of being Cartesian closed
Cls	classes	functions	n¹
nCob	(n−1)-dimensional manifolds	n-dimensional cobordisms	n				n	n	n
CohLoc	coherent locales											equivalent to CohSp by Stone duality
CohSp	coherent sober spaces											equivalent to CohLoc by Stone duality
Comp	chain complexes		y				0	Ab
CompBool	complete Boolean algebras	homomorphisms	y					n	y
CompHaus or HComp	compact Hausdorff spaces	continuous maps	y				n	n	y			dually equivalent to *comUnCAlg** by Gelfand representation. A full reflective subcategory of completely regular Hausdorff spaces by Stone-Čech compactification.
Compmet	complete metric spaces		y				n	n	y
*comUnCAlg**	commutative unital C* algebras	*-homomorphisms	y
CRng	commutative rings	ring homomorphisms	y	y/y	y/y	y/y	0	Ab	y			dually equivalent to AffSch
DGA	differential graded algebras
${\mathfrak {Dif}}$ or DSP	diffeological or differential spaces		y	y/y	y/y	y/y	t:z	n	y/y		n	a replacement for Diff which has the benefit of being complete and cocomplete (but is not Cartesian closed)
Diff or Smooth or Sm	smooth manifolds	smooth maps	y		y/y	n/n		n	n/n		n
Div	divisible abelian groups		y					pAb
DLat	distributive lattices
Dom	integral domains	ring homomorphisms	y					Ab
Dom_m	integral domains	ring monomorphisms	y					Ab
Ens_V	subsets of universal set V	functions	y	y/y	y/y		t	n	y		y
Euclid	Euclidean vector spaces	orthogonal transformations	y				0	Ab
Fin	equivalence class of finite sets	functions	y	y	y	y	t	n			y	the skeletal category of FinSet. Isomorphic to ω.
FinOrd	finite ordinals	monotonic functions	y					n	n		y
FinSet	finite sets	functions	y					n	n		y
Fld	fields	field homomorphisms	y	y/n	n/n	n/n	n	n	n	n	n	all morphisms are monic
Frm	frames											defined to be the opposite category of Loc
Grp	groups	group homomorphisms	y	y/y	y/y	n/y	z	n	y	y	n
Grph	directed graphs						n	n	y/y		y	comma category (Set↓Δ)
Ha	Heyting algebras
Haus	Hausdorff spaces	continuous maps	y		y/y		n	n	y		n
Hilb	Hilbert spaces	linear maps	y	y		y	z	Ab	y	y	n
HopfAlg_K	Hopf algebras		y
LCA	locally compact abelian groups	homomorphisms	y				z	pAb	y		n	dually isomorphic to itself by Pontryagin duality
Lconn	locally connected spaces	continuous maps	y		y/y			n			n
LieAlg	Lie algebras	Lie algebra homomorphisms	y	y/y	bi		0	Ab				functor from LieGrp
LieGrp	Lie groups	smooth homomorphisms	y					n			n
Loc	locales											the object of study in pointless topology. See Stone duality
Mag	magmas	homomorphisms	y					n			n
Mod	modules	morphisms of modules and underlying rings	y									a fibered category over Rng
R-Mod or ${}_{R}{\mathfrak {M}}$	left R-modules	R-linear homomorphisms	y					Ab	y		n
Mod-S or ${\mathfrak {M}}_{S}$	right S-modules	S-linear homomophisms	y					Ab	y		n
R-Mod-S or ${}_{R}{\mathfrak {M}}_{S}$	bimodules	bilinear homomorphisms	y					Ab	y		n
Matr_K	matrices over field (or sometimes ring) K		y					Ab	y		n
Med	medial magmas	homomorphisms	y					n	y		n
Met	metric spaces	short maps	y					n	y		n
Mon	monoids	monoid homomorphisms	y					n	y		n
MonCat	monoidal categories	strict morphisms	y					n	y		n
Ord	preordered sets	monotonic functions	y		c/c			n	y		n
P(R)	finitely generated projective modules over R
Rel	sets	binary relations	n
Rep(G)	K-linear representations of G											functor category from G to Vect_K. Isomorphic to KG-Mod.
Rng	rings	ring homomorphisms	y				i:Z	Ab	y		n
Sch	schemes	rational maps	y				t:Spec(Z)	n	y		n
Ses-A	short exact sequences of A-modules		y					Ab	y		n
Set or Sets	sets	functions	y		y/y	y/y	t:*	n	y		y
Set_*	pointed sets	basepoint preserving functions	y					n	y		n	comma category (↓Set*)
SFrm	frames											dually equivalent to Sob by Stone duality
SLoc	spatial locales											opposite category of SFrm, thus equivalent to Sob by Stone duality
Smgrp	semigroups	homomorphisms	y					n	y		n
Sob	sober spaces											dually equivalent to SFrm by Stone duality
Stone	Stone spaces											dually equivalent to Bool by Stone's representation theorem
StrAlgSet/K	structured algebraic sets		y					n	y		n
Top	topological spaces	continuous maps	y	y/y	y/y	y/y	t:*	n	y/y		n
Top_* or Top_•	pointed topological spaces	basepoint preserving continuous maps	y	y/y	y/y		z:*	n		y	n	comma category (↓Top). fundamental group is a functor to Grp*.
Toph or hTop	topological spaces	homotopy classes of maps	y					n	y		n
TOP(X) or O(X) or Open(X)	open sets in the topological space X	inclusions	n		y/y		i:∅ t:X	n	y		y
Uni	uniform spaces	uniformly continuous functions	y				n	n			n
US	unary systems											[1]
US₁	pointed unary systems						i:N					the natural numbers are initial. More generally, a natural number object is initial in pointed unary systems over some category
varieties	affine,quasi,projective,quasi-projective varieties	regular maps	y		f/f							dually equivalent to fgDom by an elementary result of algebraic geometry
VB_K	vector bundles with fibres over field K	bundle morphisms	y	y/y		n/n		add		y	n	Tangent bundle a functor from Smooth.
VB_K(X) or Vect_K(X)	vector bundles over X with fibres over field K	bundle morphisms	y	y/y	bi	n/n	0	add		y	n	equivalent to the category of locally free f.g. sheaves of O_X-modules. Smooth vector bundles equivalent to P(C^∞(X)) for X compact by Swan's theorem.
Vect_K or K-Vect	vector spaces over the field K	K-linear maps	y					Ab	y		n
Vect(K,Z/2Z)	Z2-graded vector spaces	Z2-graded K-linear maps	y					Ab	y		n
0	the empty category		y					n	n
1	one object	identity morphism					z:0	n	n		n
2							i:0;t:1	n	n		n	the ordinal 2
3							i:0;t:2	n	n		n	the ordinal 3
ω			y		y/y		i:0	n				the ordinal ω
↓↓			n					n	n		n

what are the abbreviated names for these categories? I could take a guess[edit]

category of presheaves ( a functor category) and the category of sheaves Sh(X) and Psc(X)
category of CW complexes
category of complex manifolds
measure spaces
Cauchy spaces
Riemannian manifolds
projective spaces over K
Affine spaces over K
stein manifolds
category of structures for a given language
varieties (affine, quasi-affine, projective, quasi-projective). dually equivalent to fgDom

to be inserted[edit]

Tych
Kähler
Rel category of sets and relations between them (not concrete)
comUnC*Alg commutative unital C*-algebras with unital *-homomorphisms
compTopGrp compact topological groups
fdVect_K finite dimensional vector spaces
CoAlg_K coalgebras
BiAlg_K bialgebras
FRL Fröhlicher spaces (ccc) a full subcategory of DSP
Frm
G-Set of group actions. a topos
TVS
LCTVS
CPO complete partial orders
DCPO
CABA complete atomic boolean algebras. dually equivalent to Set by some version of Stone
Prof the category of categories, profunctors, and natural tranformations
GRPO G-relative pushouts and RPO relative pushouts
Bun bunch contexts
Alg_τ algebras (in the sense of universal algebra) with signature τ.
Chu(V,k) Chu spaces over V valued in k

specific categories[edit]

Ab: abelian groups
Adj: small categories and adjunctions between them
K-Alg: algebras over field K
AlgSet/K: algebraic sets with regular maps
Bool: Boolean algebras and their homomorphisms
CAb: compact topological abelian groups
Cat: all small categories with functors
CGHaus: compactly generated Hausdorff spaces
nCob: (n−1)-dimensional manifolds with n-dimensional cobordisms
Comp: chain complexes
CompBool: complete Boolean algebras
CompHaus: compact Hausdorff spaces
Compmet: complete metric spaces
CRng: commutative rings
${\mathfrak {Dif}}$ : diffeological spaces
Diff or Smooth: smooth manifolds with smooth maps
Div: divisible abelian groups
Dom: integral domains
Dom_m: integral domains with monomorphisms
Ens_V: sets and functions within a given universal set V
Euclid: Euclidean vector spaces with orthogonal transformations
Fin: The skeletal category of finite sets
Finord: finite ordinals
FinSet: finite sets with functions
Fld: fields with field homomorphisms
Grp: all groups with their group homomorphisms
Grph: directed graphs
Haus: Hausdorff spaces
Hilb: Hilbert spaces with linear maps
LCA: locally compact abelian groups with continuous homomorphisms
Lconn: locally connected spaces
LieGrp: Lie groups
Mag: The category consisting of all magmas with their homomorphisms
R-Mod: left R-modules
Mod-S: right S-modules
R-Mod-S: bimodules
Matr_K: matrices over field (or sometimes ring) K
Med: The category consisting of all medial magmas with their homomorphisms
Met: all metric spaces with short maps
Mon: monoids with monoid homomorphisms
Moncat: monoidal categories and strict morphisms
Ord: all preordered sets with monotonic functions
Rng: rings
Sch: schemes
Ses-A: short exact sequences of A-modules
Set: sets with functions
Set_*: pointed sets with base preserving functions
Smgrp: semigroups
StrAlgSet/K: structured algebraic sets
Top: all topological spaces with continuous functions
Toph: topological spaces with homotopy classes
TOP(X): open sets in the topological space X with inclusions
Uni: all uniform spaces with uniformly continuous functions
Vect_K or K-Vect: vector spaces over the field K (which is held fixed) with their K-linear maps
Vect(K,Z/2Z): Z2-graded vector spaces with graded maps
0: The empty category
1: The one object category with one morphism
2: The two object category with one morphism not an identity between the distinct objects (this is the ordinal number 2 viewed as a category)
3: The three object with one morphisms between each distinct pair of objects (this is the ordinal number 3 viewed as a category)
↓↓: The two object category with two morphisms from one object to the other

classes of categories[edit]

any preordered set is a category with elements for objects and "<" as the morphisms. It follows that any ordinal is a category.
any monoid is a category with one object and elements as morphisms
consequently any group is a category with one object with elements as morphisms and has the categorical property that all its morphisms are isomorphisms
a category is generated by any graph
given any set, the discrete category on that set has the elements as objects and only identity morphisms
given any category C, we may form the dual category C^op
given two categories C and D, we may form the product category CxD
given two categories C and D, we may form the functor category D^C
given a category C and an object b of C, the comma category (b ↓ C) of objects under b is arrows from b. The comma category (C ↓ b) of objects over b is arrows to b. More generally, given two functors F and G to C, one may form the comma category (F ↓ G)
assuming the axiom of choice, every category has a skeleton, whose objects are representatives of the isomorphism classes of the category.