Structural aspects of truncated archimedean vector lattices: good sequences, simple elements

Richard N. Ball

Commentationes Mathematicae Universitatis Carolinae (2021)

  • Issue: 1, page 95-134
  • ISSN: 0010-2628

Abstract

top
The truncation operation facilitates the articulation and analysis of several aspects of the structure of archimedean vector lattices; we investigate two such aspects in this article. We refer to archimedean vector lattices equipped with a truncation as truncs. In the first part of the article we review the basic definitions, state the (pointed) Yosida representation theorem for truncs, and then prove a representation theorem which subsumes and extends the (pointfree) Madden representation theorem. The proof has the virtue of being much shorter than the one in the literature, but the real novelty of the theorem lies in the fact that the topological data dual to a given trunc G is a (localic) compactification, i.e., a dense pointed frame surjection q : M L out of a compact regular pointed frame M . The representation is an amalgam of the Yosida and Madden representations; the compact frame M is sufficient to describe the behavior of the bounded part G * of G in the sense that G ˜ * separates the points of the compact Hausdorff pointed space X dual to M , while the frame L is just sufficient to capture the behavior of the unbounded part of G in 0 L . The truncation operation lends itself to identifying those elements of a trunc which behave like characteristic functions, and in the second part of the article we characterize in several ways those truncs composed of linear combinations of such elements. Along the way, we show that the category of such truncs is equivalent to the category of pointed Boolean spaces, and to the category of generalized Boolean algebras. The short third part contains a characterization of the kernels of truncation homomorphisms in terms of pointwise closure. In it we correct an error in the literature.

How to cite

top

Ball, Richard N.. "Structural aspects of truncated archimedean vector lattices: good sequences, simple elements." Commentationes Mathematicae Universitatis Carolinae (2021): 95-134. <http://eudml.org/doc/298208>.

@article{Ball2021,
abstract = {The truncation operation facilitates the articulation and analysis of several aspects of the structure of archimedean vector lattices; we investigate two such aspects in this article. We refer to archimedean vector lattices equipped with a truncation as truncs. In the first part of the article we review the basic definitions, state the (pointed) Yosida representation theorem for truncs, and then prove a representation theorem which subsumes and extends the (pointfree) Madden representation theorem. The proof has the virtue of being much shorter than the one in the literature, but the real novelty of the theorem lies in the fact that the topological data dual to a given trunc $G$ is a (localic) compactification, i.e., a dense pointed frame surjection $q\colon M \rightarrow L$ out of a compact regular pointed frame $M$. The representation is an amalgam of the Yosida and Madden representations; the compact frame $M$ is sufficient to describe the behavior of the bounded part $G^*$ of $G$ in the sense that $\widetilde\{G\}^*$ separates the points of the compact Hausdorff pointed space $X$ dual to $M$, while the frame $L$ is just sufficient to capture the behavior of the unbounded part of $G$ in $\mathcal \{R\}_0 L$. The truncation operation lends itself to identifying those elements of a trunc which behave like characteristic functions, and in the second part of the article we characterize in several ways those truncs composed of linear combinations of such elements. Along the way, we show that the category of such truncs is equivalent to the category of pointed Boolean spaces, and to the category of generalized Boolean algebras. The short third part contains a characterization of the kernels of truncation homomorphisms in terms of pointwise closure. In it we correct an error in the literature.},
author = {Ball, Richard N.},
journal = {Commentationes Mathematicae Universitatis Carolinae},
keywords = {truncated archimedean vector lattice; pointwise convergence; $l$-group; completely regular pointed frame},
language = {eng},
number = {1},
pages = {95-134},
publisher = {Charles University in Prague, Faculty of Mathematics and Physics},
title = {Structural aspects of truncated archimedean vector lattices: good sequences, simple elements},
url = {http://eudml.org/doc/298208},
year = {2021},
}

TY - JOUR
AU - Ball, Richard N.
TI - Structural aspects of truncated archimedean vector lattices: good sequences, simple elements
JO - Commentationes Mathematicae Universitatis Carolinae
PY - 2021
PB - Charles University in Prague, Faculty of Mathematics and Physics
IS - 1
SP - 95
EP - 134
AB - The truncation operation facilitates the articulation and analysis of several aspects of the structure of archimedean vector lattices; we investigate two such aspects in this article. We refer to archimedean vector lattices equipped with a truncation as truncs. In the first part of the article we review the basic definitions, state the (pointed) Yosida representation theorem for truncs, and then prove a representation theorem which subsumes and extends the (pointfree) Madden representation theorem. The proof has the virtue of being much shorter than the one in the literature, but the real novelty of the theorem lies in the fact that the topological data dual to a given trunc $G$ is a (localic) compactification, i.e., a dense pointed frame surjection $q\colon M \rightarrow L$ out of a compact regular pointed frame $M$. The representation is an amalgam of the Yosida and Madden representations; the compact frame $M$ is sufficient to describe the behavior of the bounded part $G^*$ of $G$ in the sense that $\widetilde{G}^*$ separates the points of the compact Hausdorff pointed space $X$ dual to $M$, while the frame $L$ is just sufficient to capture the behavior of the unbounded part of $G$ in $\mathcal {R}_0 L$. The truncation operation lends itself to identifying those elements of a trunc which behave like characteristic functions, and in the second part of the article we characterize in several ways those truncs composed of linear combinations of such elements. Along the way, we show that the category of such truncs is equivalent to the category of pointed Boolean spaces, and to the category of generalized Boolean algebras. The short third part contains a characterization of the kernels of truncation homomorphisms in terms of pointwise closure. In it we correct an error in the literature.
LA - eng
KW - truncated archimedean vector lattice; pointwise convergence; $l$-group; completely regular pointed frame
UR - http://eudml.org/doc/298208
ER -

References

top
  1. Adámek J., Herrlich H., Strecker G. E., Abstract and Concrete Categories, the Joy of Cats, Repr. Theory Appl. Categ., 17, Wiley, New York, 2004. MR2240597
  2. Ball R. N., 10.1016/j.topol.2013.11.007, Topology Appl. 162 (2014), 43–65. MR3144659DOI10.1016/j.topol.2013.11.007
  3. Ball R. N., 10.1016/j.topol.2014.08.031, Topology Appl. 178 (2014), 56–86. MR3276729DOI10.1016/j.topol.2014.08.031
  4. Ball R. N., 10.1016/j.topol.2017.12.027, Topology Appl. 235 (2018), 492–522. MR3760215DOI10.1016/j.topol.2017.12.027
  5. Ball R. N., Hager A. W., 10.1016/0022-4049(91)90004-L, Proc. of the Conf. on Locales and Topological Groups, Curaçao, 1989, J. Pure Appl. Algebra 70 (1991), no. 1–2, 17–43. MR1100503DOI10.1016/0022-4049(91)90004-L
  6. Ball R. N., Hager A. W., Walters-Wayland J., 10.1016/j.jpaa.2015.03.006, J. Pure Appl. Algebra 219 (2015), no. 11, 4793–4815. MR3351563DOI10.1016/j.jpaa.2015.03.006
  7. Ball R. N., Marra V., 10.1016/j.topol.2014.03.016, Topology Appl. 170 (2014), 10–24. MR3200386DOI10.1016/j.topol.2014.03.016
  8. Ball R. N., Walters-Wayland J., C - and C * - quotients in pointfree topology, Dissertationes Math. (Rozprawy Mat.) 412 (2002), 62 pages. MR1952051
  9. Ball R. N., Walters-Wayland J., κ -Lindelöf sublocales of completely regular locales, undergoing review. 
  10. Bezhanishvili G., Morandi P. J., Olberding B., Specker algebras: a survey, in Algebraic Techniques and Their Use in Describing and Processing Uncertainty, Studies in Computational Intelligence, 878, Springer Nature Switzerland AG, 2020, pages 1–19. 
  11. Darnel M. R., Theory of Lattice-Ordered Groups, Monographs and Textbooks in Pure and Applied Mathematics, 187, Marcel Dekker, New York, 1995. Zbl0810.06016MR1304052
  12. Dini U., Fondamenti per la teorica delle funzioni di variabili reali, Nistri, Pisa, 1878 (Italian). 
  13. Dudley R. M., Real Analysis and Probability, Cambridge Studies in Advanced Mathematics, 74, Cambridge University Press, Cambridge, 2003. MR1932358
  14. Fremlin D. H., Topological Riesz Spaces and Measure Theory, Cambridge University Press, London, 1974. Zbl0273.46035MR0454575
  15. Hager A. W., 10.1216/RMJ-2013-43-6-1901, Rocky Mountain J. Math. 43 (2013), no. 6, 1901–1930. MR3178449DOI10.1216/RMJ-2013-43-6-1901
  16. Hager A. W., van Mill J., Egoroff, σ , and convergence properties in some archimedean vector lattices, Studia Math. 231 (2015), no. 3, 269–285. MR3471054
  17. Henriksen M., Johnson D. G., 10.4064/fm-50-1-73-94, Fund. Math. 50 (1961/62), 73–94. MR0133698DOI10.4064/fm-50-1-73-94
  18. Madden J., Vermeer J., 10.1016/0022-4049(90)90147-A, Special issue in honor of B. Banaschewski, J. Pure Appl. Algebra 68 (1990), no. 1–2, 243–252. MR1082794DOI10.1016/0022-4049(90)90147-A
  19. Mundici D., 10.1016/0022-1236(86)90015-7, J. Funct. Anal. 65 (1986), no. 1, 15–63. MR0819173DOI10.1016/0022-1236(86)90015-7
  20. Picado J., Pultr A., Frames and Locales: Topology Without Points, Frontiers in Mathematics, 28, Birkhäuser, 2012. MR2868166
  21. Stone M. H., 10.1073/pnas.34.9.447, Proc. Nat. Acad. Sci. U.S.A. 34 (1948), 447–455. MR0026102DOI10.1073/pnas.34.9.447

NotesEmbed ?

top

You must be logged in to post comments.

To embed these notes on your page include the following JavaScript code on your page where you want the notes to appear.

Only the controls for the widget will be shown in your chosen language. Notes will be shown in their authored language.

Tells the widget how many notes to show per page. You can cycle through additional notes using the next and previous controls.

    
                

                
Note: Best practice suggests putting the JavaScript code just before the closing </body> tag.