Schröder–Bernstein theorem

In set theory, the Schröder–Bernstein theorem, named after Felix Bernstein and Ernst Schröder, states that, if there exist injective functions f : AB and g : BA between the sets A and B, then there exists a bijective function h : AB. In terms of the cardinality of the two sets, this means that if |A|  |B| and |B|  |A|, then |A| = |B|; that is, A and B are equipollent. This is a useful feature in the ordering of cardinal numbers.

The theorem is also known as the Cantor–Bernstein theorem, or the Cantor–Schroeder–Bernstein theorem (named after Georg Cantor).

This theorem does not rely on the axiom of choice. However, its various proofs are non-constructive, as they depend on the law of excluded middle, and are therefore rejected by intuitionists.[1]

Proof

König's definition of a bijection h:AB from given example injections f:AB and g:BA. An element in A and B is denoted by a number and a letter, respectively. The sequence 3→e→6→... is an A-stopper, leading to the defintitions h(3)=f(3)=e, h(6)=f(6), .... The sequence d→5→f→... is a B-stopper, leading to h(5)=g−1(5)=d, .... The sequence ...→a→1→c→4→... is doubly infinite, leading to h(1)=g−1(1)=a, h(4)=g−1(4)=c, .... The sequence b→2→b is cyclic, leading to h(2)=g−1(2)=b.

The following proof is attributed to Julius König.[2]

Assume without loss of generality that A and B are disjoint. For any a in A or b in B we can form a unique two-sided sequence of elements that are alternately in A and B, by repeatedly applying f and g to go right and g^{-1} and f^{-1} to go left (where defined).

 \cdots \rightarrow  f^{-1}(g^{-1}(a)) \rightarrow g^{-1}(a) \rightarrow   a  \rightarrow  f(a) \rightarrow  g(f(a)) \rightarrow \cdots

For any particular a, this sequence may terminate to the left or not, at a point where f^{-1} or g^{-1} is not defined.

By the fact that f and g are injective functions, each a in A and b in B is in exactly one such sequence to within identity: if an element occurs in two sequences, all elements to the left and to the right must be the same in both, by the definition of the sequences. Therefore, the sequences form a partition of the (disjoint) union of A and B. Hence it suffices to produce a bijection between the elements of A and B in each of the sequences separately, as follows:

Call a sequence an A-stopper if it stops at an element of A, or a B-stopper if it stops at an element of B. Otherwise, call it doubly infinite if all the elements are distinct or cyclic if it repeats. See the picture for examples.

Original proof

An earlier proof by Cantor relied, in effect, on the axiom of choice by inferring the result as a corollary of the well-ordering theorem.[3] The argument given above shows that the result can be proved without using the axiom of choice.

Furthermore, there is a proof which uses Tarski's fixed point theorem.[4]

History

The traditional name "Schröder-Bernstein" is based on two proofs published independently in 1898. Cantor is often added because he first stated the theorem in 1895, while Schröder's name is often omitted because his proof turned out to be flawed while the name of Richard Dedekind, who first proved it, is not connected with the theorem. According to Bernstein, Cantor had suggested the name equivalence theorem (Äquivalenzsatz).[5]

Cantor's first statement of the theorem (1887)[6]

Both proofs of Dedekind are based on his famous memoir Was sind und was sollen die Zahlen? and derive it as a corollary of a proposition equivalent to statement C in Cantor's paper,[10] which reads ABC and |A|=|C| implies |A|=|B|=|C|. Cantor observed this property as early as 1882/83 during his studies in set theory and transfinite numbers and therefore (implicitly) relying on the Axiom of Choice.

See also

References

  1. Ettore Carruccio (2006). Mathematics and Logic in History and in Contemporary Thought. Transaction Publishers. p. 354. ISBN 978-0-202-30850-0.
  2. J. König (1906). "Sur la théorie des ensembles". Comptes rendus hebdomadaires des séances de l'Académie des sciences 143: 110–112.
  3. Georg Cantor (1895). "Beiträge zur Begründung der transfiniten Mengenlehre (1)". Mathematische Annalen 46: 481–512. doi:10.1007/bf02124929.
    Georg Cantor (1897). "Beiträge zur Begründung der transfiniten Mengenlehre (2)". Mathematische Annalen 49: 207–246. doi:10.1007/bf01444205.
  4. R. Uhl, "Tarski's Fixed Point Theorem", from MathWorld–a Wolfram Web Resource, created by Eric W. Weisstein. (Example 3)
  5. 1 2 3 4 5 6 Felix Hausdorff (2002), Egbert Brieskorn, Srishti D. Chatterji; et al., eds., Grundzüge der Mengenlehre (1. ed.), Berlin/Heidelberg: Springer, p. 587, ISBN 3-540-42224-2 - Original edition (1914)
  6. 1 2 Georg Cantor (1887), "Mitteilungen zur Lehre vom Transfiniten", Zeitschrift für Philosophie und philosophische Kritik 91: 81–125
    Reprinted in: Georg Cantor (1932), Adolf Fraenkel (Lebenslauf); Ernst Zermelo, ed., Gesammelte Abhandlungen mathematischen und philosophischen Inhalts, Berlin: Springer, pp. 378–439 Here: p.413 bottom
  7. Richard Dedekind (1932), Robert Fricke, Emmy Noether, Øystein Ore, ed., Gesammelte mathematische Werke 3, Braunschweig: Friedr. Vieweg & Sohn, pp. 447–449 (Ch.62)
  8. Ernst Zermelo (1908), Felix Klein, Walther von Dyck, David Hilbert, Otto Blumenthal, ed., "Untersuchungen über die Grundlagen der Mengenlehre I", Mathematische Annalen (Leipzig: B. G. Teubner) 65 (2): 261–281; here: p.271–272, doi:10.1007/bf01449999, ISSN 0025-5831
  9. Richard Dedekind (1888), Was sind und was sollen die Zahlen? (2., unchanged (1893) ed.), Braunschweig: Friedr. Vieweg & Sohn
  10. 1 2 Georg Cantor (1932), Adolf Fraenkel (Lebenslauf); Ernst Zermelo, ed., Gesammelte Abhandlungen mathematischen und philosophischen Inhalts, Berlin: Springer, pp. 285 ("Satz B")
  11. Georg Cantor (1895). "Beiträge zur Begründung der transfiniten Mengenlehre (1)". Mathematische Annalen 46: 481–512 (Theorem see "Satz B", p.484). doi:10.1007/bf02124929.
    (Georg Cantor (1897). "Beiträge zur Begründung der transfiniten Mengenlehre (2)". Mathematische Annalen 49: 207–246. doi:10.1007/bf01444205.)
  12. Friedrich M. Hartogs (1915), Felix Klein, Walther von Dyck, David Hilbert, Otto Blumenthal, ed., "Über das Problem der Wohlordnung", Mathematische Annalen (Leipzig: B. G. Teubner) 76 (4): 438–443, doi:10.1007/bf01458215, ISSN 0025-5831
  13. Ernst Schröder (1896). "Über G. Cantorsche Sätze" (PDF). Jahresbericht der Deutschen Mathematiker-Vereinigung 5: 81—82.
  14. Ernst Schröder (1898), Kaiserliche Leopoldino-Carolinische Deutsche Akademie der Naturforscher, ed., "Ueber zwei Definitionen der Endlichkeit und G. Cantor’sche Sätze", Nova Acta (Halle a. S.: Johann Ambrosius Barth Verlag) 71 (6): 303–376 (proof: p.336)
  15. Alwin R. Korselt (1911), Felix Klein, Walther von Dyck, David Hilbert, Otto Blumenthal, ed., "Über einen Beweis des Äquivalenzsatzes", Mathematische Annalen (Leipzig: B. G. Teubner) 70 (2): 294–296, doi:10.1007/bf01461161, ISSN 0025-5831
  16. Korselt (1911), p.295
  17. 1 2 Oliver Deiser (2010), Einführung in die Mengenlehre - Die Mengenlehre Georg Cantors und ihre Axiomatisierung durch Ernst Zermelo (3rd, corrected ed.), Berlin/Heidelberg: Springer, pp. 71, 501, doi:10.1007/978-3-642-01445-1, ISBN 3-540-20401-6Appendix (freely accessible, includes p.501)
  18. 1 2 Patrick Suppes (1972), Axiomatic Set Theory (1. ed.), New York: Dover Publications, pp. 95 f., ISBN 0-486-61630-4
  19. Émile Borel (1898), Leçons sur la théorie des fonctions, Paris: Gauthier-Villars et fils, pp. 103 ff.
  20. Felix Bernstein (1901), Untersuchungen aus der Mengenlehre, Halle a. S.: Buchdruckerei des Waisenhauses
    Reprinted in: Felix Bernstein (1905), Felix Klein, Walther von Dyck, David Hilbert, ed., "Untersuchungen aus der Mengenlehre", Mathematische Annalen (Leipzig: B. G. Teubner) 61 (1): 117–155, (Theorem see "Satz 1" on p.121), doi:10.1007/bf01457734, ISSN 0025-5831

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