PlanetPhysics/Axiomatic Theories of Metacategories and Supercategories

This is a topic on the axioms of [[../Cod/|categories]], metacategories and supercategories that are relevant, respectively, to mathematics and meta-mathematics. Lawvere's [[../Formula/|elementary theory of abstract categories]] ([[../ETACAxioms/|ETAC]]) provides an axiomatic construction of the theory of categories and [[../TrivialGroupoid/|functors]]. Intuitively, with this terminology and axioms, a category is meant to be any structure which is a direct interpretation of ETAC. A functor is then understood to be a triple consisting of two such categories and of a rule F (`the functor') which assigns to each arrow or [[../TrivialGroupoid/|morphism]] x of the first category, a unique morphism, written as `F(x)' of the second category, in such a way that the usual two conditions on both [[../TrivialGroupoid/|objects]] and arrows in the standard functor definition are fulfilled --the functor is well behaved, i.e., it carries object [[../Cod/|identities]] to image object identities, and [[../Commutativity/|commutative diagrams]] to image commmutative [[../TrivialGroupoid/|diagrams]] of the corresponding image objects and image morphisms. At the next level, one then defines [[../VariableCategory2/|natural transformations]] or functorial morphisms between functors as meta-level abbreviated [[../Formula/|formulas]] and equations pertaining to commutative diagrams of the distinct images of two functors acting on both objects and morphisms. As the name indicates natural transformations are also well--behaved in terms of the ETAC equations that are satisfied by natural transformations.

Categories were defined in refs. ^[1] as mathematical interpretations of the `elementary theory of abstract categories' (ETAC). One can generalize the theory of categories to higher dimensions-- as in [[../HigherDimensionalAlgebra2/|higher dimensional algebra]] ([[../2Groupoid2/|HDA]])-- by defining multiple [[../Identity2/|composition laws]] and allowing higher dimensional, functorial morphisms of several variables to be employed in such higher dimensional structures. Thus, one can introduce an elementary theory of supercategories ([[../ETACAxioms/|ETAS]];(^[2]) as a natural extension of Lawvere's ETAC theory to higher dimensions (^[3]). Then, supercategories can be defined as mathematical interpretations of the [[../ETACAxioms/|ETAS axioms]] as in ref.^[4].

A concrete metagraph ${\displaystyle {ℳ}_G}$ consists of objects, ${\displaystyle A,B,C,}$... and arrows ${\displaystyle f,g,h,}$... between objects, and two [[../Cod/|operations]] as follows:

• a \htmladdnormallink{domain {http://planetphysics.us/encyclopedia/Bijective.html} operation}, ${\displaystyle dom}$, which assigns to each arrow ${\displaystyle f}$ an object ${\displaystyle A=domf}$
• a \htmladdnormallink{codomain {http://planetphysics.us/encyclopedia/Bijective.html} operation}, ${\displaystyle cod}$, which assigns to each arrow ${\displaystyle f}$ an object ${\displaystyle B=codf,}$ represented as ${\displaystyle f:A\to B}$ or ${\displaystyle A\stackrel{f}{⟶}B}$

Related [[../PreciseIdea/|concepts]] to the general notion of a supercategory recalled above can also be rendered graphically on a [[../Program3/|computer]] as a multigraph or a [[../SimpleIncidenceStructure2/|hypergraph]]. More generally, the class of metagraphs can be also defined as a specific class of supercategories. On the other hand, a [[../SupercomputerArchitercture/|supercomputer]] architecture and operating [[../SimilarityAndAnalogousSystemsDynamicAdjointnessAndTopologicalEquivalence/|system]] software are examples of realizations of relatively simple, or lower dimensional supercategories, as explained in further detail in the next subsections.

1. (S1) . All symbols, formulas and the eight axioms defined in ETAC are, respectively, also ETAS symbols, formulas and axioms; thus, for any letters ${\displaystyle x,y,i,u,A,B}$, and unary [[../Bijective/|function]] symbols ${\displaystyle {\mathrm{\Delta }}_0}$ and ${\displaystyle {\mathrm{\Delta }}_1}$, and composition laws ${\displaystyle {\mathrm{\Gamma }}_i}$, the following are defined as formulas : ${\displaystyle {\mathrm{\Delta }}_0(x)=A}$,${\displaystyle {\mathrm{\Delta }}_1(x)=B}$, ${\displaystyle \mathrm{\Gamma }(x,y;u)}$, and ${\displaystyle x=y}$.

The above formulas are to be, respectively, interpreted as ``${\displaystyle A}$ is the domain of ${\displaystyle x}$", ``${\displaystyle B}$ is the codomain, or range, of ${\displaystyle x}$", ``${\displaystyle u}$ is the [[../Cod/|composition]] ${\displaystyle x}$ followed by ${\displaystyle y}$", and ``${\displaystyle x}$ equals ${\displaystyle y}$"; letters ${\displaystyle i,j,k,l,m,...}$ are to be interpreted as ``either element, set or class (${\displaystyle C}$ ) indices". An example of valid ETAC and ETAS formula is a couple or pair of two letters written as ``${\displaystyle (x,y)}$"; a more general related example is that of Cartesian or direct products ${\displaystyle {\mathrm{\Pi }}_{iinC}}$.

1. (S2) . There are several composition laws defined in ETAS (as distinct from ETAC where there is only one composition law for each interpretation in any specific [[../Bijective/|type]] of category ); such multiple composition laws ${\displaystyle {\mathrm{\Gamma }}_i}$, with ${\displaystyle iinC}$ are interpreted as ``definitions of multiple (specific) mathematical structures, within the same supercategory ${\displaystyle \mathrm{\S }}$" .

In the case of general algebras, the multiple composition laws are interpreted as "definitions of \htmladdnormallink{algebraic structures" {http://planetphysics.us/encyclopedia/TrivialGroupoid.html}"}, (whereas [[../CategoryOfLogicAlgebras/|categorical algebra]] is interpreted as being defined by a single composition law ${\displaystyle {\mathrm{\Gamma }}_1=\circ }$ (or ``*" for -involution or ${\displaystyle C^{*}}$ -algebras )". An ETAC structure is thus identified by the singleton ${\displaystyle \left\{1\right\}}$ index set.

Pseudographs, hypergraphs, 1-categories, categorical algebras, ${\displaystyle 2}$-categories, ${\displaystyle n}$-categories, [[../TrivialGroupoid/|functor categories]], [[../SuperCategory6/|super-categories]], super-diagrams, functor supercatgeories, [[../ThinEquivalence/|double groupoids]], [[../HorizontalIdentities/|double categories]], organismic supercategories, self-replicating [[../QuantumComputers/|quantum automata]], standard Heyting [[../GrothendieckTopos/|topos]], generalized ${\displaystyle L{M}_n}$-logic algebra topoi, [[../GeneralizedSuperalgebras/|double algebroids]], super-categories of double algebroids, and any higher dimensional algebra (HDA) are examples of supercategories of various orders.

A pictorial [[../CategoricalGroupRepresentation/|representation]] of a particular class of metagraphs --the class of multigraphs, ${\displaystyle M_g}$-- is also useful as a visual or `geometric' (or [[../CoIntersections/|topological]]) representation of a specific example of a supercategory defined over the topological space of the multigraph with the composition operations of the supercategory heteromorphisms defined, in this case of the multigraph, by the concatenations of the multigraph vertices in ${\displaystyle n}$ dimensions for a finite , ${\displaystyle n}$-dimensional multigraph that can be graphically rendered on a computer.

A more recent version of Lawvere's axioms was presented by MacLane (2000) in which a metagraph is first defined as a structure consisting of objects ${\displaystyle a,b,c,...x,y,z}$, arrows ${\displaystyle f,g,h,...}$, and two operations -- the Domain (which assigns to each arrow ${\displaystyle f}$ an object ${\displaystyle a=domf}$), and a Codomain (which assigns to each arrow ${\displaystyle f}$ an object ${\displaystyle b=codf}$. Such operations can be readily represented by displaying ${\displaystyle f}$ as an actual arrow ${\displaystyle .\to .}$ starting at the ${\displaystyle domf}$ and ending at ${\displaystyle codf}$, ${\displaystyle f:a\to b}$. With this pictorial, or `geometric' representation, a finite number of arrows is depicted as a finite [[../Cod/|graph]]. Then, one defines a metacategory as a metagraph with two additional operations, Identity and Composition (viz. ^[5]). Identity assigns to each object ${\displaystyle a}$ an arrow ${\displaystyle i{d}_a=1_a:a\to a<math>.A}$composition${\displaystyle operationassignstoeachpairofarrows}$(f,g)${\displaystyle with}$dom ~g = cod~ f</math> an arrow called their composite, ${\displaystyle g\circ f:domf\to codg}$.

^{[4] [6] [7] [8] [9] [10] [3] [11] [12] [13] [14] [5]}

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