1.3 Adjoint functors as solving optimization problems

One good way to motivate adjoint functors is to explain what problem they solve, and how they solve it.

That can only be done, in some sense, by what mathematicians call ' hand-waving'. It can be said, however, that adjoint functors pin down the concept of the best structure of a type one is interested in constructing. For example, an elementary question in ring theoryIn mathematics, ring theory is the study of rings, algebraic structures in which addition and multiplication are defined and have similar properties to those familiar from the integers. Please refer to the glossary of ring theory for the definitions of te is how to add a multiplicative identity to a ring that doesn't have one (the definition in this encyclopedia actually assumes one: see ring (mathematics)In ring theory, a branch of abstract algebra, a ring is an algebraic structure in which addition and multiplication are defined and have similar properties to those familiar from the integers. History See Ring theory Definition and notation A ring is an a and glossary of ring theory). The best way is to add an element '1' to the ring, add nothing extra you don't need (you will need to have r+1 for r in the ring, clearly), and add no relations in the new ring that aren't forced by axioms. This is rather vague, though suggestive.

There are several ways to make precise this concept of best structure. Adjoint functors are one method; the notion of universal properties provides another, essentially equivalent but arguably more concrete approach.

Universal properties are also based on category theory. The idea is to set up the problem in terms of some auxiliary category C; and then identify what we want to do as showing that C has an initial object. This has an advantage that the optimisation — the sense that we are finding the best solution — is singled out and recognisable rather like the attainment of a supremum. To do it is something of a knack: for example, take the given ring R, and make a category C whose objects are ring homomorphisms R → S, with S a ring having a multiplicative identity. The morphisms in C must fill in triangles that are commutative diagrams, and preserve multiplicative identity. The assertion is that C has an initial object R → R*, and R* is then the sought-after ring.

The adjoint functor method for defining an multiplicative identity for rings is to look at two categories, C₀ and C₁, of rings, respectively without and with assumption of multiplicative identity. There is a functor from C₁ to C₀ that forgets about the 1. We are seeking a left adjoint to it. This is a clear, if dry, formulation.

One way to see what is achieved by using either formulation is to try a direct method. (This is favoured, for example, by John Conway.) One simply adds to R a new element 1, and calculates on the basis that any equation resulting is valid if and only if it holds for all rings that we can create from R and 1. This is the impredicative method: meaning that the ring we are trying to construct is one of the rings quantified over in 'all rings'. This overt use of impredicativity is honest, in a way that category theory has no intention of being.

The answer regarding the way to get a ( unital) ring from one that is not unital is simple enough (see examples below); this section has been discussion how to formulate the question.

The major argument in favour of adjoint functors is probably this: if one goes through the universal property or impredicative reasoning often enough, it seems like repeating the same kind of steps.

1.4 The case of partial orders

Every partially ordered set can be viewed as a category (with a single morphism between x and y if and only if x ≤ y). A pair of adjoint functors between two partially ordered sets is called a Galois connection (or, if it contravariant, an antitone Galois connection). See that article for a number of examples: the case of Galois theory of course is a leading one. Any Galois connection gives rise to closure operators and to inverse order-preserving bijections between the corresponding closed elements.

As is the case for Galois groups, the real interest lies often in refining a correspondence to a duality (i.e. antitone order isomorphism). A treatment of Galois theory along these lines by Kaplansky was influential in the recognition of the general structure here.

The partial order case collapses the adjunction definitions quite noticeably, but can provide several themes:

• adjunctions may not be dualities or isomorphisms, but are candidates for upgrading to that status
• closure operators may indicate the presence of adjunctions, as corresponding monads (cf. the Kuratowski closure axioms)
• a very general comment of Martin Hyland is that syntax and semantics are adjoint: take C to be the set of all logical theories (axiomatizations), and D the power set of the set of all mathematical structures. For a theory T in C, let F(T) be the set of all structures that satisfy the axioms T; for a set of mathematical structures S, let G(S) be the minimal axiomatization of S. We can then say that F(T) is a subset of S if and only if T logically implies G(S): the "semantics functor" F is left adjoint to the "syntax functor" G.
• division is (in general) the attempt to invert multiplication, but many examples, such as the introduction of implication in propositional logic, or the ideal quotient for division by ring ideals, can be recognised as the attempt to provide an adjoint.

Together these observations provide explanatory value all over mathematics.

2 Formal definitions

A pair of adjoint functors between two categories C and D consists of two functors F : C → D and G : D → C and a natural isomorphism

φ : Mor_D(F—, —) → Mor_C(—, G—)

consisting of bijections:

φ_X,Y : Mor_D(F(X), Y) → Mor_C(X, G(Y))

for all objects X in C and Y in D. Here the naturality of φ means that for all morphisms f : X′ → X in C and all morphisms g : Y → Y′ in D the following diagram commutes:

The horizontal arrows in this diagram are those induced by f and g. We then say that F is a left-adjoint of G and G is a right-adjoint of F.

Every adjoint pair of functors defines a unit η, a natural transformation from the functor 1_C to GF consisting of morphisms

η_X : X → GF(X)

for every X in C. η_X is defined as φ_X,F(X) (id_F(X)).

Analogously, one may define a co-unit ε, a natural transformation from FG to 1_D consisting of morphisms

ε_Y : FG(Y) → Y.

for every Y in D. ε_Y is defined as as φ_G(Y),Y⁻¹(id_G(Y))

3 Examples

Free objects and forgetful functors. If F : Set → Grp is the functor assigning to each set X the free group over X, and if G : Grp → Set is the forgetful functor assigning to each group its underlying set, then the universal property of the free group shows that F is left adjoint to G. The unit of this adjoint pair is the embedding of a set X into the free group over X.

In general, free constructions in mathematics tend to be left adjoints of forgetful functors. Free rings, free abelian groups, and free modules follow this general pattern.

Products. Let F : Grp → Grp² be the functor which assigns to every group X the pair (X, X) in the product category Grp², and G : Grp² → Grp the functor which assigs to each pair (Y₁, Y₂) the product group Y₁×Y₂. The universal property of the product group shows that G is right-adjoint to F. The co-unit gives the natural projections from the product to the factors.

The cartesian product of sets, the product of rings, the product of topological spaces etc. follow the same pattern; it can also be extended in a straightforward manner to more than just two factors.

Coproducts. If F : Ab² → Ab assigns to every pair (X₁, X₂) of abelian groups their direct sum and if G : Ab → Ab² is the functor which assigns to every abelian group Y the pair (Y, Y), then F is left adjoint to G, again a consequence of the universal property of direct sums. The unit of the adjoint pair provides the natural embeddings from the factors into the direct sum.

Analogous examples are given by the direct sum of vector spaces and modules, by the free product of groups and by the disjoint union of sets.

Kernels. Consider the category D of homomorphisms of abelian groups. If f₁ : A₁ → B₁ and f₂ : A₂ → B₂ are two objects of D, then a morphism from f₁ to f₂ is a pair (g_A, g_B) of morphisms such that g_Bf₁ = f₂g_A. Let G : D → Ab be the functor which assigns to each homomorphism its kernel and let F : Ab → D be the morphism which maps the group A to the homomorphism A → 0. Then G is right adjoint to F, which expresses the universal property of kernels, and the co-unit of this adjunction yields the natural embedding of a homomorphism's kernel into the homomorphism's domain.

A suitable variation of this example also shows that the kernel functors for vector spaces and for modules are right adjoints. Analogously, one can show that the cokernel functors for abelian groups, vector spaces and modules are left adjoints.

Making a ring unital This example was discussed in section 1.3 above. Given a non-unital ring R, a multiplicative identity element can be added by taking RxZ and defining a Z-bilinear product with (r,0)(0,1) = (0,1)(r,0) = (r,0), (r,0)(s,0) = (rs,0), (0,1)(0,1) = (0,1). This constructs a left adjoint to the functor taking a ring to the underlying non-unital ring.

Ring extensions. Suppose R and S are rings, and ρ : R → S is a ring homomorphism. Then S can be seen as a (left) R-module, and the tensor product with S yields a functor F : R-Mod → S-Mod. Then F is left adjoint to the forgetful functor G : S-Mod → R-Mod.

Tensor products. If R is a ring and M is a right R module, then the tensor product with M yields a functor F : R-Mod → Ab. The functor G : Ab → R-Mod, defined by G(A) = Hom_Z(A, M) for every abelian group A, is a right adjoint to F.

From monoids and groups to rings The monoid ring construction gives a functor from monoids to rings. This functor is left adjoint to the functor that associates to a given ring its underlying multiplicative monoid. Similarly, the group ring construction yields a functor from groups to rings, left adjoint to the functor that assigns to a given ring its group of units. One can also start with a field K and consider the category of K- algebras instead of the category of rings, to get the monoid and group rings over K.

Direct and inverse images of sheaves Every continuous map f : X → Y between topological spaces induces a functor f_* from the category of sheaves (of sets, or abelian groups, or rings...) on X to the corresponding category of sheaves on Y, the direct image functor. It also induces a functor f^* from the category of sheaves on Y to the category of sheaves on X, the inverse image functor. f^* is left adjoint to f_*. Here a more subtle point is that the left adjoint for coherent sheaves will differ from that for sheaves (of sets).

The Grothendieck construction. In K-theory, the point of departure is to observe that the category of vector bundles on a topological space has a commutative monoid structure under direct sum. To make an abelian group out of this monoid, one can follow the method of making a presentation of a group, adding formally an additive inverse for each bundle (or equivalence class). Alternatively one can observe that the functor that for each group takes the underlying monoid (ignoring inverses) has a left adjoint. This is a once-for-all construction, in line with the third section discussion above. That is, one can imitate the construction of negative numbers; but there is the other option of an existence theorem. For the case of finitary algebraic structures, the existence by itself can be referred to universal algebra, or model theory; naturally there is also a proof adapted to category theory, too.

Frobenius reciprocity in the representation theory of groups: see induced representation. This example foreshadowed the general theory by about half a century.

Stone-Cech compactification. Let D be the category of compact Hausdorff spaces and G : D → Top be the forgetful functor which treats every compact Hausdorff space as a topological space. Then G has a left adjoint F : Top → D, the Stone-Cech compactification. The unit of this adjoint pair yields a continuous map from every topological space X into its Stone-Cech compactification. This map is an embedding (i.e. injective, continuous and open) if and only if X is a Tychonoff space.

Soberification. The article on Stone duality describes an adjunction between the category of topological spaces and the category of sober spaces that is known as soberification. Notably, the article also contains a detailed description of another adjunction that prepares the way for the famous duality of sober spaces and spatial locales, exploited in pointless topology.

A functor with a left and a right adjoint. Let G be the functor from topological spaces to sets that associates to every topological space its underlying set (forgetting the topology, that is). G has a left adjoint F, creating the discrete space on a set Y, and a right adjoint H creating the trivial topology on Y.

4 Properties

4.1 Uniqueness of adjoints

If the functor F : C → D had two right-adjoints G₁ and G₂, then G₁ and G₂ are naturally isomorphic. The same is true for left-adjoints.

4.2 Relation to universal constructions

All pairs of adjoint functors arise from universal constructions. Let F and G be a pair of adjoint functors with unit η and co-unit ε. Then we have a universal morphism for each object in C and D:

• For each object X in C, (F(X), η_X) is a universal morphism from X to G. That is, for all f : X → G(Y) there exists a unique g : F(X) → Y for which the following diagrams commute.
• For each object Y in D, (G(Y), ε_Y) is a universal morphism from F to Y. That is, for all g : F(X) → Y there exists a unique f : X → G(Y) for which the following diagrams commute.

Conversly, given any two functors F and G and natural transformations η : 1_C → GF and ε : FG → 1_D which are universal in the above sense, then F and G form an adjoint pair. (Actually it is sufficient to specify only one of η or ε). The isomorphism φ is then determined by the equations

f = φ_X,Y(g) = G(g) O η_X

g = φ_X,Y⁻¹(f) = ε_Y O F(f)

Universal constructions are more general than adjoint functor pairs: as mentioned earlier, a universal construction is like an optimization problem; it gives rise to an adjoint pair if and only if this problem has a solution for every object of C (equivalently, every object of D).

4.3 Characterization via unit and co-unit

There exists yet another characterization of adjoint functors via the unit η : 1_C → GF and co-unit ε : FG → 1_D. These natural transformations have the following properties: the composition (εF)O(Fη), a natural transformation F → FGF → F, is equal to 1_F, and the composition (Gε)o(ηG) : G → GFG → G is equal to 1_G.

Conversely, given two natural transformations η and ε with these properties, then the functors F and G form an adjoint pair.

4.4 Adjoints preserve certain limits

The most important property of adjoints is their continuity: every functor that has a left adjoint (and therefore is a right adjoint) is continuous (i.e. commutes with limits in the category theoretical sense); every functor that has a right adjoint (and therefore is a left adjoint) is cocontinuous (i.e. commutes with colimits).

Since many common constructions in mathematics are limits or colimits, this provides a wealth of information. For example:

• applying a right adjoint functor to a product of objects yields the product of the images;
• applying a left adjoint functor to a coproduct of objects yields the coproduct of the images;
• every right adjoint functor is left exact;
• every left adjoint functor is right exact.

4.5 Additivity

If the functor F : C → D is left adjoint to G : D → C and both C and D are additive categories, then both F and G are additive functors.

4.6 Composition

If the functor F₁ : C → D has G₁ : D → C as right adjoint and the functor F₂ : D → E has G₂ : E → D as right adjoint, then the composition F₂oF₁ : C → E has G₁oG₂ : E → C as right adjoint.

4.7 Adjoint pairs extend equivalences

Every adjoint pair extends an equivalence of certain subcategories. Specifically, if F : C → D is left adjoint to G : D → C with unit η and co-unit ε, define C₁ as the full subcategory of C consisiting of those objects X of C for which η_X is an isomorphism, and define D₁ as the full subcategory of D consisting of those objects Y of D for which ε_Y is an isomorphism. Then F and G can be restricted to C₁ and D₁ and yield inverse equivalences of these subcategories.

In a sense, then, adjoints are "generalized" inverses. Note however that a right inverse of F (i.e. a functor G such that FG is naturally isomorphic to 1_D) need not be a right (or left) adjoint of F. Adjoints generalize two-sided inverses.

4.8 General existence theorem

Not every functor G : D → C admits a left adjoint. If D is complete, then the functors with left adjoints can be characterized by the Freyd Adjoint Functor Theorem: G has a left adjoint if and only if it is continuous and a certain smallness condition is satisfied: for every object X of C there exists a family of morphisms

f_i : X → G(Y_i)

(where, to make the point explicitly, the indices i come from a set I, not a proper class—this is the whole idea), such that every morphism

h : X → G(Y)

can be written as

h = G(t) o f_i

for some i in I and some morphism

t : Y_i → Y in D.

An analogous statement characterizes those functors with a right adjoint.

Category theory

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