nLab top

Redirected from "top element".
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Idea

In a poset PP, a top of PP is a greatest element: an element \top of PP such that aa \leq \top for every element aa. Such a top may not exist; if it does, then it is unique.

In a proset, a top may be defined similarly, but it need not be unique. (However, it is still unique up the natural equivalence in the proset.)

A top of PP can also be understood as a meet of zero elements in PP.

A poset that has both top and bottom is called bounded.

As a poset is a special kind of category, a top is simply a terminal object in that category.

The top of the poset of subsets or subobjects of a given set or object AA is always AA itself.

\phantom{-}symbol\phantom{-}\phantom{-}in logic\phantom{-}
A\phantom{A}\inA\phantom{A}element relation
A\phantom{A}:\,:A\phantom{A}typing relation
A\phantom{A}==A\phantom{A}equality
A\phantom{A}\vdashA\phantom{A}A\phantom{A}entailment / sequentA\phantom{A}
A\phantom{A}\topA\phantom{A}A\phantom{A}true / topA\phantom{A}
A\phantom{A}\botA\phantom{A}A\phantom{A}false / bottomA\phantom{A}
A\phantom{A}\RightarrowA\phantom{A}implication
A\phantom{A}\LeftrightarrowA\phantom{A}logical equivalence
A\phantom{A}¬\notA\phantom{A}negation
A\phantom{A}\neqA\phantom{A}negation of equality / apartnessA\phantom{A}
A\phantom{A}\notinA\phantom{A}negation of element relation A\phantom{A}
A\phantom{A}¬¬\not \notA\phantom{A}negation of negationA\phantom{A}
A\phantom{A}\existsA\phantom{A}existential quantificationA\phantom{A}
A\phantom{A}\forallA\phantom{A}universal quantificationA\phantom{A}
A\phantom{A}\wedgeA\phantom{A}logical conjunction
A\phantom{A}\veeA\phantom{A}logical disjunction
symbolin type theory (propositions as types)
A\phantom{A}\toA\phantom{A}function type (implication)
A\phantom{A}×\timesA\phantom{A}product type (conjunction)
A\phantom{A}++A\phantom{A}sum type (disjunction)
A\phantom{A}00A\phantom{A}empty type (false)
A\phantom{A}11A\phantom{A}unit type (true)
A\phantom{A}==A\phantom{A}identity type (equality)
A\phantom{A}\simeqA\phantom{A}equivalence of types (logical equivalence)
A\phantom{A}\sumA\phantom{A}dependent sum type (existential quantifier)
A\phantom{A}\prodA\phantom{A}dependent product type (universal quantifier)
symbolin linear logic
A\phantom{A}\multimapA\phantom{A}A\phantom{A}linear implicationA\phantom{A}
A\phantom{A}\otimesA\phantom{A}A\phantom{A}multiplicative conjunctionA\phantom{A}
A\phantom{A}\oplusA\phantom{A}A\phantom{A}additive disjunctionA\phantom{A}
A\phantom{A}&\&A\phantom{A}A\phantom{A}additive conjunctionA\phantom{A}
A\phantom{A}\invampA\phantom{A}A\phantom{A}multiplicative disjunctionA\phantom{A}
A\phantom{A}!\;!A\phantom{A}A\phantom{A}exponential conjunctionA\phantom{A}
A\phantom{A}?\;?A\phantom{A}A\phantom{A}exponential disjunctionA\phantom{A}

Last revised on July 3, 2018 at 07:04:45. See the history of this page for a list of all contributions to it.