Coherent space

In proof theory, a coherent space (also coherence space) is a concept introduced in the semantic study of linear logic.

Let a set C be given. Two subsets S,T ⊆ C are said to be orthogonal, written S ⊥ T, if S ∩ T is ∅ or a singleton. The dual of a family F ⊆ ℘(C) is the family F ^⊥ of all subsets S ⊆ C orthogonal to every member of F, i.e., such that S ⊥ T for all T ∈ F. A coherent space F over C is a family of C-subsets for which F = (F ^⊥) ^⊥.

In Proofs and Types coherent spaces are called coherence spaces. A footnote explains that although in the French original they were espaces cohérents, the coherence space translation was used because spectral spaces are sometimes called coherent spaces.

Definitions[edit]

As defined by Jean-Yves Girard, a coherence space ${\mathcal {A}}$ is a collection of sets satisfying down-closure and binary completeness in the following sense:

Down-closure: all subsets of a set in ${\mathcal {A}}$ remain in ${\mathcal {A}}$ : $a'\subset a\in {\mathcal {A}}\implies a'\in {\mathcal {A}}$
Binary completeness: for any subset $M$ of ${\mathcal {A}}$ , if the pairwise union of any of its elements is in ${\mathcal {A}}$ , then so is the union of all the elements of $M$ : $\forall M\subset {\mathcal {A}},\left((\forall a_{1},a_{2}\in M,\ a_{1}\cup a_{2}\in {\mathcal {A}})\implies \bigcup M\in {\mathcal {A}}\right)$

The elements of the sets in ${\mathcal {A}}$ are known as tokens, and they are the elements of the set $|{\mathcal {A}}|=\bigcup {\mathcal {A}}=\{\alpha |\{\alpha \}\in {\mathcal {A}}\}$ .

Coherence spaces correspond one-to-one with (undirected) graphs (in the sense of a bijection from the set of coherence spaces to that of undirected graphs). The graph corresponding to ${\mathcal {A}}$ is called the web of ${\mathcal {A}}$ and is the graph induced a reflexive, symmetric relation $\sim$ over the token space $|{\mathcal {A}}|$ of ${\mathcal {A}}$ known as coherence modulo ${\mathcal {A}}$ defined as:

a\sim b\iff \{a,b\}\in {\mathcal {A}}

In the web of

{\mathcal {A}}

, nodes are tokens from

|{\mathcal {A}}|

and an edge is shared between nodes

a

and

b

when

a\sim b

(i.e.

\{a,b\}\in {\mathcal {A}}

.) This graph is unique for each coherence space, and in particular, elements of

{\mathcal {A}}

are exactly the cliques of the web of

{\mathcal {A}}

i.e. the sets of nodes whose elements are pairwise adjacent (share an edge.)

Coherence spaces as types[edit]

Coherence spaces can act as an interpretation for types in type theory where points of a type ${\mathcal {A}}$ are points of the coherence space ${\mathcal {A}}$ . This allows for some structure to be discussed on types. For instance, each term $a$ of a type ${\mathcal {A}}$ can be given a set of finite approximations $I$ which is in fact, a directed set with the subset relation. With $a$ being a coherent subset of the token space $|{\mathcal {A}}|$ (i.e. an element of ${\mathcal {A}}$ ), any element of $I$ is a finite subset of $a$ and therefore also coherent, and we have $a=\bigcup a_{i},a_{i}\in I.$

Stable functions[edit]

Functions between types ${\mathcal {A}}\to {\mathcal {B}}$ are seen as stable functions between coherence spaces. A stable function is defined to be one which respects approximants and satisfies a certain stability axiom. Formally, $F:{\mathcal {A}}\to {\mathcal {B}}$ is a stable function when

It is monotone with respect to the subset order (respects approximation, categorically, is a functor over the poset ${\mathcal {A}}$ ): $a'\subset a\in {\mathcal {A}}\implies F(a')\subset F(a).$
It is continuous (categorically, preserves filtered colimits): ${\textstyle F(\bigcup _{i\in I}^{\uparrow }a_{i})=\bigcup _{i\in I}^{\uparrow }F(a_{i})}$ where ${\textstyle \bigcup _{i\in I}^{\uparrow }}$ is the directed union over $I$ , the set of finite approximants of $a$ .
It is stable: $a_{1}\cup a_{2}\in {\mathcal {A}}\implies F(a_{1}\cap a_{2})=F(a_{1})\cap F(a_{2}).$ Categorically, this means that it preserves the pullback:

Product space[edit]

In order to be considered stable, functions of two arguments must satisfy the criterion 3 above in this form:

a_{1}\cup a_{2}\in {\mathcal {A}}\land b_{1}\cup b_{2}\in {\mathcal {B}}\implies F(a_{1}\cap a_{2},b_{1}\cap b_{2})=F(a_{1},b_{1})\cap F(a_{2},b_{2})

which would mean that in addition to stability in each argument alone, the pullback

is preserved with stable functions of two arguments. This leads to the definition of a product space ${\mathcal {A}}\ \&\ {\mathcal {B}}$ which makes a bijection between stable binary functions (functions of two arguments) and stable unary functions (one argument) over the product space. The product coherence space is a product in the categorical sense i.e. it satisfies the universal property for products. It is defined by the equations:

$|{\mathcal {A}}\ \&\ {\mathcal {B}}|=|{\mathcal {A}}|+|{\mathcal {B}}|=(\{1\}\times |{\mathcal {A}}|)\cup (\{2\}\times |{\mathcal {B}}|)$ (i.e. the set of tokens of ${\mathcal {A}}\ \&\ {\mathcal {B}}$ is the coproduct (or disjoint union) of the token sets of ${\mathcal {A}}$ and ${\mathcal {B}}$ .
Tokens from differents sets are always coherent and tokens from the same set are coherent exactly when they are coherent in that set.
- $(1,\alpha )\sim _{{\mathcal {A}}\ \&\ {\mathcal {B}}}(1,\alpha ')\iff \alpha \sim _{\mathcal {A}}\alpha '$
- $(2,\beta )\sim _{{\mathcal {A}}\ \&\ {\mathcal {B}}}(2,\beta ')\iff \beta \sim _{\mathcal {B}}\beta '$
- $(1,\alpha )\sim _{{\mathcal {A}}\ \&\ {\mathcal {B}}}(2,\beta ),\forall \alpha \in |{\mathcal {A}}|,\beta \in |{\mathcal {B}}|$

References[edit]

Girard, J.-Y.; Lafont, Y.; Taylor, P. (1989), Proofs and types (PDF), Cambridge University Press.
Girard, J.-Y. (2004), "Between logic and quantic: a tract", in Ehrhard; Girard; Ruet; et al. (eds.), Linear logic in computer science (PDF), Cambridge University Press.

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