nLab first-order hyperdoctrine

Contents

Context

Type theory

natural deduction metalanguage, practical foundations

judgement
hypothetical judgement, sequent
- antecedents $\vdash$ consequent, succedents

type theory (dependent, intensional, observational type theory, homotopy type theory)

calculus of constructions

syntax object language

theory, axiom
proposition/type (propositions as types)
definition/proof/program (proofs as programs)
theorem

computational trinitarianism =
propositions as types +programs as proofs +relation type theory/category theory

logic	set theory (internal logic of)	category theory	type theory
proposition	set	object	type
predicate	family of sets	display morphism	dependent type
proof	element	generalized element	term/program
cut rule		composition of classifying morphisms / pullback of display maps	substitution
introduction rule for implication		counit for hom-tensor adjunction	lambda
elimination rule for implication		unit for hom-tensor adjunction	application
cut elimination for implication		one of the zigzag identities for hom-tensor adjunction	beta reduction
identity elimination for implication		the other zigzag identity for hom-tensor adjunction	eta conversion
true	singleton	terminal object/(-2)-truncated object	h-level 0-type/unit type
false	empty set	initial object	empty type
proposition, truth value	subsingleton	subterminal object/(-1)-truncated object	h-proposition, mere proposition
logical conjunction	cartesian product	product	product type
disjunction	disjoint union (support of)	coproduct ((-1)-truncation of)	sum type (bracket type of)
implication	function set (into subsingleton)	internal hom (into subterminal object)	function type (into h-proposition)
negation	function set into empty set	internal hom into initial object	function type into empty type
universal quantification	indexed cartesian product (of family of subsingletons)	dependent product (of family of subterminal objects)	dependent product type (of family of h-propositions)
existential quantification	indexed disjoint union (support of)	dependent sum ((-1)-truncation of)	dependent sum type (bracket type of)
logical equivalence	bijection set	object of isomorphisms	equivalence type
	support set	support object/(-1)-truncation	propositional truncation/bracket type
		n-image of morphism into terminal object/n-truncation	n-truncation modality
equality	diagonal function/diagonal subset/diagonal relation	path space object	identity type/path type
completely presented set	set	discrete object/0-truncated object	h-level 2-type/set/h-set
set	set with equivalence relation	internal 0-groupoid	Bishop set/setoid with its pseudo-equivalence relation an actual equivalence relation
	equivalence class/quotient set	quotient	quotient type
induction		colimit	inductive type, W-type, M-type
higher induction		higher colimit	higher inductive type
-		0-truncated higher colimit	quotient inductive type
coinduction		limit	coinductive type
	preset		type without identity types
	set of truth values	subobject classifier	type of propositions
domain of discourse	universe	object classifier	type universe
modality		closure operator, (idempotent) monad	modal type theory, monad (in computer science)
linear logic		(symmetric, closed) monoidal category	linear type theory/quantum computation
proof net		string diagram	quantum circuit
(absence of) contraction rule		(absence of) diagonal	no-cloning theorem
		synthetic mathematics	domain specific embedded programming language

homotopy levels

semantics

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As an Internal Heyting Algebra
Interpretation
Variants

Related concepts

Idea

A first-order hyperdoctrine is a hyperdoctrine with respect to lattices that are Heyting algebras.

Definition

We denote by $HeytAlg_{AdjCyl}$ the category whose objects are Heyting algebras, and whose morphisms are Heyting algebra morphisms having both left and right adjoints. (The adjoints are not required to be Heyting algebra morphisms, but can be arbitrary monotone maps.)

A first-order hyperdoctrine consists of a category with finite products $C_T$ , along with a functor

P \colon C_T^{op} \to HeytAlg_{AdjCyl}

such that the following Beck-Chevalley condition is satisfied: for every object $A$ , the left adjoints to $P(\pi)$ for the projections $\pi : A \times - \to -$ comprise a natural transformation from $P(A \times -)$ to $P(-)$ , and so do the right adjoints. This expresses the Beck-Chevalley condition for pullback squares of the form

\array{ A \times B & \stackrel{\pi_B}{\to} & B \\ ^\mathllap{1_A \times f} \downarrow & & \downarrow^\mathrlap{f} \\ A \times C & \underset{\pi_C}{\to} & C }

An element of $P(A)$ is often called a predicate over $A$ (with respect to the hyperdoctrine).

For any first-order hyperdoctrine, an equality predicate can be defined for each type $A \in Ob(C_T)$ as

\exists(\delta_A)(\top_{P(A)}) \in P(A \times A)

where for any morphism $f$ in $C_T$ , we use $\exists (f)$ to denote the left adjoint of $P(f)$ , and $\top_H$ denotes the top element in a Heyting algebra $H$ .

However, to get good properties for equality, we need to assume a little more. A first-order hyperdoctrine with equality is a first-order hyperdoctrine such that the Beck-Chevalley condition is satisfied for pullback diagrams of the form

\array{ A\times B & \stackrel{A\times f}{\to} & A \times C \\ ^\mathllap{\delta_A\times B} \downarrow & & \downarrow^\mathrlap{\delta_A \times C} \\ A \times A \times B& \underset{A\times A\times f}{\to} & A \times A \times C },

i.e. that $P(A\times A \times f) \circ \exists (\delta_A \times B) = \exists (\delta_A \times C) \circ P(A\times f)$ .

This assures that the equality predicate is well behaved in the sense that it allows a sound interpretation of first order logic with equality in the hyperdoctrine.

Additionally one may require the condition for pullbacks of the form

\array{ A & \stackrel{\delta_A}{\to} & A \times A \\ ^\mathllap{\delta_A} \downarrow & & \downarrow^\mathrlap{1_A \times \delta_A} \\ A \times A & \underset{\delta_A \times 1_A}{\to} & A \times A \times A },

which is a kind of Frobenius law. By taking right adjoints, a similar equation holds for $\forall (f)$ in place of $\exists (f)$ , where $P(f) \dashv \forall (f)$ .

As an Internal Heyting Algebra

Similar to the natural models formulation of a category with families, a first-order hyperdoctrince can be defined concisely using the internal language of presheaf categories. That is, a first-order hyperdoctrine is equivalently defined as a category $C_T$ with finite products and $P$ an internal Heyting algebra in the category of presheaves on $C_T$ that additionally has

For every $A \in C_T$ internal $YA$ -meets and joins where $YA$ is the representable presheaf of $A$ .
For every $A \in C_T$ , $P$ internally has an $YA$ -equality predicate, i.e., a least reflexive binary relation on $YA$ valued in $P$ . In more detail, this is an internal function $=_A \in P^{YA \times YA}$ such that for every $f \in P^{YA\times YA}$ we have $\forall x,y. x =_A y \leq f(x,y)$ if and only if $\forall x\in A. \top \leq f(x,x)$ .

Here the Beck-Chevalley conditions on the quantifiers and equality arises from the fact that the operations are internal and therefore natural in $C$ . Unraveling the internal language, this definition is the same as the formulation given by Lawvere that requires only equality predicates and adjoints to substitution along projections.

Interpretation

With this, we have enough structure to interpret multi-sorted first-order intuitionistic logic with equality, taking the objects of $C_T$ to be sorts and its morphisms to be terms, $P$ to assign to each sort the Lindenbaum algebra of predicates upon that sort and to each term the operation of substitution of that term into predicates, and the left and right adjoints to $P$ upon projections to provide existential and universal quantification, respectively, with the existence of the further adjoints providing the ability to interpret equality, and the Beck-Chevalley condition ensuring that quantification commutes appropriately with substitution (just as the propositional connectives do).

Variants

There are, of course, many variants on this, corresponding straightforwardly to modifications of the kind of logic one wishes to represent. For instance, to represent specifically classical logic, one should use Boolean algebras instead of Heyting algebras. To represent first-order logic without equality, one should no longer require left and right adjoints to every morphism in the range of $P$ , but rather only those given by the natural transformations yielding the quantifiers (i.e., only requiring adjoints to substitution along projections). Various higher-order constructs can be added by adding new ways of forming objects in $C_T$ (e.g., adding cartesian closedness). Etc.

One can even extend this into the realm not just of provability, but furthermore of proof theory, by taking the objects in the codomain of $P$ to be categories rather than mere preorders (e.g., by using bicartesian closed categories rather than Heyting algebras); in this case, the objects in a category $P(\sigma)$ would still represent predicates on the sort $\sigma$ , but the morphisms in $P(\sigma)$ would represent proofs (rather than mere provability) of entailments between these predicates, with the possibility that not all such proofs would be equal.

Related concepts

tripos

category	functor	internal logic	theory	hyperdoctrine	subobject poset	coverage	classifying topos
finitely complete category	cartesian functor	cartesian logic	essentially algebraic theory
lextensive category		disjunctive logic
regular category	regular functor	regular logic	regular theory	regular hyperdoctrine	infimum-semilattice	regular coverage	regular topos
coherent category	coherent functor	coherent logic	coherent theory	coherent hyperdoctrine	distributive lattice	coherent coverage	coherent topos
geometric category	geometric functor	geometric logic	geometric theory	geometric hyperdoctrine	frame	geometric coverage	Grothendieck topos
Heyting category	Heyting functor	intuitionistic first-order logic	intuitionistic first-order theory	first-order hyperdoctrine	Heyting algebra
De Morgan Heyting category		intuitionistic first-order logic with weak excluded middle			De Morgan Heyting algebra
Boolean category		classical first-order logic	classical first-order theory	Boolean hyperdoctrine	Boolean algebra
star-autonomous category		multiplicative classical linear logic
symmetric monoidal closed category		multiplicative intuitionistic linear logic
cartesian monoidal category		fragment $\{\&, \top\}$ of linear logic
cocartesian monoidal category		fragment $\{\oplus, 0\}$ of linear logic
cartesian closed category		simply typed lambda calculus

Last revised on June 15, 2023 at 01:01:50. See the history of this page for a list of all contributions to it.