Forcing (computability): Difference between revisions

Browse history interactively

← Previous edit

Content deleted Content added

VisualWikitext

Revision as of 04:06, 7 January 2024 edit JohnAdams1800 (talk \| contribs) Extended confirmed users 15,601 edits →Terminology: Fixed the compatibility definition. ← Previous edit		Latest revision as of 03:06, 4 June 2025 edit undo Psychastes (talk \| contribs) Extended confirmed users 18,540 edits Removed {{Expert needed}} tag: not a valid reason to request an expert Tag: Twinkle
(4 intermediate revisions by 2 users not shown)
Line 1: ~~{{Expert needed\|mathematics \|ex2= logic \|reason= Article incomplete \|date = April 2021}}~~ ~~{{Missing information\|article\|the forcing relation <math>\Vdash</math>\|date=April 2021}}~~ '''Forcing''' in [[computability theory]] is a modification of [[Paul Cohen (mathematician)\|Paul Cohen's]] original [[set theory\|set-theoretic]] technique of [[forcing (set theory)\|forcing]] to deal with computability concerns. Conceptually the two techniques are quite similar: in both one attempts to build [[generic set\|generic]] objects (intuitively objects that are somehow 'typical') by meeting [[dense ~~sets~~set]]s. Both techniques are described as a relation (customarily denoted <math>\Vdash</math>) between 'conditions' and sentences. However, where set-theoretic forcing is usually interested in creating objects that meet every dense set of conditions in the ground model, computability-theoretic forcing only aims to meet dense sets that are arithmetically or hyperarithmetically definable. Therefore, some of the more difficult machinery used in set-theoretic forcing can be eliminated or substantially simplified when defining forcing in computability. But while the machinery may be somewhat different, computability-theoretic and set-theoretic forcing are properly regarded as an application of the same technique to different classes of formulas. ==Terminology== Line 37 ⟶ 35: The idea is that our language should express facts about the object we wish to build with our forcing construction. == Forcing relation == The forcing relation <math>\Vdash</math> was developed by [[Paul Cohen]], who introduced forcing as a technique for proving the independence of certain statements from the standard axioms of set theory, particularly the [[continuum hypothesis]] (CH). The notation <math>V \Vdash \phi</math> is used to express that a particular condition or generic set forces a certain proposition or formula <math>\phi</math> to be true in the resulting forcing extension. Here's <math>V</math> represents the original universe of sets (the ground model), <math>\Vdash</math> denotes the forcing relation, and <math>\phi</math> is a statement in set theory. When <math>V \Vdash \phi</math>, it means that in a suitable forcing extension, the statement <math>\phi</math> will be true. == References == Line 48 ⟶ 52: \|___location=Amsterdam, New York, and Oxford \|series=Studies in Logic and the Foundations of Mathematics \|pages=1078–1079 ~~\|pp=1078-1079~~ \|doi=10.2307/2273928 \|volume=105 \|jstor=2273928 \|s2cid=118376273 }} *{{Cite book