Symmetry reduction of states II: A non-commutative Positivstellensatz for CP^n

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Authors

  • Philipp Lothar Schmitt
  • Matthias Schötz

Research Organisations

External Research Organisations

  • Free University of Brussels (ULB)
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Original languageEnglish
Pages (from-to)326-353
Number of pages28
JournalLinear Algebra and Its Applications
Volume649
Early online date24 May 2022
Publication statusPublished - 15 Sept 2022

Abstract

We give a non-commutative Positivstellensatz for CP^n: The (commutative) *-algebra of polynomials on the real algebraic set CP^n with the pointwise product can be realized by phase space reduction as the U(1)-invariant polynomials on C^{1+n}, restricted to the real (2n+1)-sphere inside C^{1+n}, and Schmüdgen's Positivstellensatz gives an algebraic description of the real-valued U(1)-invariant polynomials on C^{1+n} that are strictly pointwise positive on the sphere. In analogy to this commutative case, we consider a non-commutative *-algebra of polynomials on C^{1+n}, the Weyl algebra, and give an algebraic description of the real-valued U(1)-invariant polynomials that are positive in certain *-representations on Hilbert spaces of holomorphic sections of line bundles over CP^n. It is especially noteworthy that the non-commutative result applies not only to strictly positive, but to all positive (semidefinite) elements. As an application, all *-representations of the quantization of the polynomial *-algebra on CP^n, obtained e.g. through phase space reduction or Berezin–Toeplitz quantization, are determined.

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Symmetry reduction of states II: A non-commutative Positivstellensatz for CP^n. / Schmitt, Philipp Lothar; Schötz, Matthias.
In: Linear Algebra and Its Applications, Vol. 649, 15.09.2022, p. 326-353.

Research output: Contribution to journalArticleResearchpeer review

Schmitt PL, Schötz M. Symmetry reduction of states II: A non-commutative Positivstellensatz for CP^n. Linear Algebra and Its Applications. 2022 Sept 15;649:326-353. Epub 2022 May 24. doi: 10.48550/arXiv.2110.03437, 10.1016/j.laa.2022.05.011
Schmitt, Philipp Lothar ; Schötz, Matthias. / Symmetry reduction of states II: A non-commutative Positivstellensatz for CP^n. In: Linear Algebra and Its Applications. 2022 ; Vol. 649. pp. 326-353.
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AU - Schötz, Matthias

N1 - Acknowledgements: The first author was partly supported by the Danish National Research Foundation through the Centre of Symmetry and Deformation (DNRF92). The second author was supported by the Fonds de la Recherche Scientifique (FNRS) and the Fonds Wetenschappelijk Onderzoek - Vlaaderen (FWO) under EOS Project n∘30950721

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N2 - We give a non-commutative Positivstellensatz for CP^n: The (commutative) *-algebra of polynomials on the real algebraic set CP^n with the pointwise product can be realized by phase space reduction as the U(1)-invariant polynomials on C^{1+n}, restricted to the real (2n+1)-sphere inside C^{1+n}, and Schmüdgen's Positivstellensatz gives an algebraic description of the real-valued U(1)-invariant polynomials on C^{1+n} that are strictly pointwise positive on the sphere. In analogy to this commutative case, we consider a non-commutative *-algebra of polynomials on C^{1+n}, the Weyl algebra, and give an algebraic description of the real-valued U(1)-invariant polynomials that are positive in certain *-representations on Hilbert spaces of holomorphic sections of line bundles over CP^n. It is especially noteworthy that the non-commutative result applies not only to strictly positive, but to all positive (semidefinite) elements. As an application, all *-representations of the quantization of the polynomial *-algebra on CP^n, obtained e.g. through phase space reduction or Berezin–Toeplitz quantization, are determined.

AB - We give a non-commutative Positivstellensatz for CP^n: The (commutative) *-algebra of polynomials on the real algebraic set CP^n with the pointwise product can be realized by phase space reduction as the U(1)-invariant polynomials on C^{1+n}, restricted to the real (2n+1)-sphere inside C^{1+n}, and Schmüdgen's Positivstellensatz gives an algebraic description of the real-valued U(1)-invariant polynomials on C^{1+n} that are strictly pointwise positive on the sphere. In analogy to this commutative case, we consider a non-commutative *-algebra of polynomials on C^{1+n}, the Weyl algebra, and give an algebraic description of the real-valued U(1)-invariant polynomials that are positive in certain *-representations on Hilbert spaces of holomorphic sections of line bundles over CP^n. It is especially noteworthy that the non-commutative result applies not only to strictly positive, but to all positive (semidefinite) elements. As an application, all *-representations of the quantization of the polynomial *-algebra on CP^n, obtained e.g. through phase space reduction or Berezin–Toeplitz quantization, are determined.

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