display all the ideas for this combination of philosophers
11 ideas
10859 | A set is 'well-ordered' if every subset has a first element [Clegg] |
Full Idea: For a set to be 'well-ordered' it is required that every subset of the set has a first element. | |
From: Brian Clegg (Infinity: Quest to Think the Unthinkable [2003], Ch.13) |
10857 | Set theory made a closer study of infinity possible [Clegg] |
Full Idea: Set theory made a closer study of infinity possible. | |
From: Brian Clegg (Infinity: Quest to Think the Unthinkable [2003], Ch.13) |
10864 | Any set can always generate a larger set - its powerset, of subsets [Clegg] |
Full Idea: The idea of the 'power set' means that it is always possible to generate a bigger one using only the elements of that set, namely the set of all its subsets. | |
From: Brian Clegg (Infinity: Quest to Think the Unthinkable [2003], Ch.14) |
10872 | Extensionality: Two sets are equal if and only if they have the same elements [Clegg] |
Full Idea: Axiom of Extension: Two sets are equal if and only if they have the same elements. | |
From: Brian Clegg (Infinity: Quest to Think the Unthinkable [2003], Ch.15) |
10875 | Pairing: For any two sets there exists a set to which they both belong [Clegg] |
Full Idea: Axiom of Pairing: For any two sets there exists a set to which they both belong. So you can make a set out of two other sets. | |
From: Brian Clegg (Infinity: Quest to Think the Unthinkable [2003], Ch.15) |
10876 | Unions: There is a set of all the elements which belong to at least one set in a collection [Clegg] |
Full Idea: Axiom of Unions: For every collection of sets there exists a set that contains all the elements that belong to at least one of the sets in the collection. | |
From: Brian Clegg (Infinity: Quest to Think the Unthinkable [2003], Ch.15) |
10878 | Infinity: There exists a set of the empty set and the successor of each element [Clegg] |
Full Idea: Axiom of Infinity: There exists a set containing the empty set and the successor of each of its elements. | |
From: Brian Clegg (Infinity: Quest to Think the Unthinkable [2003], Ch.15) | |
A reaction: This is rather different from the other axioms because it contains the notion of 'successor', though that can be generated by an ordering procedure. |
10877 | Powers: All the subsets of a given set form their own new powerset [Clegg] |
Full Idea: Axiom of Powers: For each set there exists a collection of sets that contains amongst its elements all the subsets of the given set. | |
From: Brian Clegg (Infinity: Quest to Think the Unthinkable [2003], Ch.15) | |
A reaction: Obviously this must include the whole of the base set (i.e. not just 'proper' subsets), otherwise the new set would just be a duplicate of the base set. |
10879 | Choice: For every set a mechanism will choose one member of any non-empty subset [Clegg] |
Full Idea: Axiom of Choice: For every set we can provide a mechanism for choosing one member of any non-empty subset of the set. | |
From: Brian Clegg (Infinity: Quest to Think the Unthinkable [2003], Ch.15) | |
A reaction: This axiom is unusual because it makes the bold claim that such a 'mechanism' can always be found. Cohen showed that this axiom is separate. The tricky bit is choosing from an infinite subset. |
10871 | Axiom of Existence: there exists at least one set [Clegg] |
Full Idea: Axiom of Existence: there exists at least one set. This may be the empty set, but you need to start with something. | |
From: Brian Clegg (Infinity: Quest to Think the Unthinkable [2003], Ch.15) |
10874 | Specification: a condition applied to a set will always produce a new set [Clegg] |
Full Idea: Axiom of Specification: For every set and every condition, there corresponds a set whose elements are exactly the same as those elements of the original set for which the condition is true. So the concept 'number is even' produces a set from the integers. | |
From: Brian Clegg (Infinity: Quest to Think the Unthinkable [2003], Ch.15) | |
A reaction: What if the condition won't apply to the set? 'Number is even' presumably won't produce a set if it is applied to a set of non-numbers. |