DOCSLIB.ORG

Duality of Bochner Spaces by Seppo I

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text

Load more

Duality of Bochner spaces by Seppo I: Hiltunen Abstract. We construct the generalized Lebesgue { Bochner spaces mvL p ( µ ; Π ) for pos- itive measures µ and for suitable real or complex topological vector spaces Π so that for 1 < p < +1 and Banachable Π with separable topology the strong dual of the classical mv p mv p∗ 0 Bochner space L ( µ ; Π ) becomes canonically represented by L ( µ ; Πσ ) . Hence we 0 need no separability assumption of the norm topology of the strong dual Π of Π . For p = 1 and for suitably restricted positive measures µ we even get a similar result without any separability of the norm topology of the target space Π . For positive Radon mea- sures on locally compact topological spaces these results are essentially contained on pages 588 { 606 in R. E. Edwards' classical Functional Analysis. Introduction and some preliminaries Our main objective in this article is the following A1 Theorem. Let 1 ≤ p < +1 , and let q = (1 − p −1 −1 if p 6= 1, and q = +1 if p = 1. Further, let µ be a positive measure on Ω, and with K 2 ftf R ; tfC g let Π 2 BaS (K ) be such that (1) or (2) or (3) or (4) or (5) or (6) below holds when mv p (D) means that µ is almost decomposable. Also let F = L (µ ; Π ), and F1 = mv q 0 L (µ ; Πσ ) if (1) or (2) or (5) or (6) below holds, otherwise letting F1 = mv q 0 Ls (µ ; Πσ ) . For R ι = h υs F × C \ f ( X ; t): 8 x 2 X ; y 2 Y ; t = Ω y : x d µ g : Y 2 υs F1 i 0 mv q 0 then ι 2 Liis (F1 ;F ) holds. In addition F1 = L (µ ; Π ) if (1) or (5) holds. (1) p = 1 and (D) and Π is reflexive, (2) p = 1 and (D) and τrd Π is a separable topology, m 1 (3) p = 1 and (D) and τrd L (µ) is a separable topology, m (4) p = 1 and (D) and a choice function c 2 L ( L +1 (µ) ; ` +1 (Ω)) exists, (5) p 6= 1 and Π is reflexive, (6) p 6= 1 and τrd Π is a separable topology. The proof is given on pages 44 { 48 below. Here we first explain the notation arXiv:1801.09059v2 [math.FA] 1 Feb 2018 appearing above, mentioning that we generally utilize the notational convention explained in [ H05 ; pp. 4 { 8 ] , [ H07 ; pp. 4 { 9 ] and [ H08 ; p. 1 ] , and further to be \polished" in [ Hfs ]. Having K 2 ftf R ; tfC g means that K is either the topological field of real num- bers or that of the complex ones. The underlying sets of these fields are R and C , respectively. Then Π 2 BaS (K ) means that Π is a Banachable, i.e. a complete 2010 Mathematics Subject Classification. Primary 46E40 , 46A20 , 46G10 , 46E30 ; Secondary 28A20 , 28B05 , 46A16 , 28C20. Key words and phrases. Bochner space, Banach space, duality, positive measure, positive Radonian, vector measure, Lebesgue space, topological vector space, suitable space, measurability, bounded variation, Dunford { Pettis. 1 2 S. HILTUNEN normable real or complex topological vector space. Thus there is a compatible norm ν on the underlying vector space σrd Π such that (σrd Π; ν ) is a normed --i −1 + Banach space. Being compatible here means that f ν ``[ 0 ; n : n 2 Z is a --i −1 filter base for the filter No Π of zero neighbourhoods. Above ν ``[ 0 ; n is the image of the closed interval [ 0 ; n −1 under the relational inverse ν --i of ν . Here ν is a function υs Π ! R+ where υs Π is the underlying set of vectors of Π . For ξ 2 υs Π one may sometimes write k ξ k for the value ν `ξ of ν at ξ . For Π1 2 t.v.s (K ) , i.e. having Π1 a real or complex topological vector space with possibly non-Hausdorff topology τrd Π1 , the exact construction of the space mv p E = L (µ ; Π1) is given in Constructions 42 (3) on page 23 below. Here we infor- mally explain the basic ideas under the additional assumption that Π1 is suitable in the sense of Definitions 15 on page 10 below. Then it suffices to consider one fixed dominating norm ν for Π1 . We consider functions x :Ω ! υs Π such that on every set A of finite measure, --i i.e. for A 2 µ ``R+ it holds that outside some set N of measure zero, i.e. with N 2 µ --i ``f0g we have x a pointwise limit of a sequence of simple functions, with convergence in the sense of the topology τrd Π. In the case p < +1 we then take the subset of those x such that the generally nonmeasurable function p p abs ◦ ν ◦ x :Ω 3 η 7! (ν ◦ x`η ) 2 R+ is dominated by some integrable function α :Ω ! [ 0 ; +1 ] . With the pointwise vector operations from σrd Π the set of these x becomes a vector substructure X Ω]vs of σrd Π . Then we take E = (X=vs N0 ; T ) when N0 is the set of all x 2 vs X --i R such that for all u 2 L (Π; K ) and A 2 µ ``R+ we have A u ◦ x d µ = 0 . Here L (Π; K ) is the set of all continuous linear maps Π ! K . Furthermore, we take the topology T so that a filter of zero neighbourhoods is formed by the sets R p vs (X=vs N0 ) \ f X : 9 x 2 X ; abs ◦ ν ◦ x d µ < " g + for " 2 R . Here we have the upper integral of the not-necessarily measurable p R function abs ◦ ν ◦ x that is defined as the infimum of the set of all Ω α d µ with α as above. For p = +1 we take the \obvious" modification. mv p The space E 1 = Ls (µ ; Π1) is constructed otherwise similarly except that we instead require the functions x to be such that u◦x j (A nN ) is measurable, that is, --i --i for every A 2 µ ``R+ we require existence of some N 2 µ ``f0g such that for all u 2 L (Π; K ) it holds that u ◦ x j (A n N ) is a measurable real or complex valued function on A n N. Then every vector of E is contained in some vector of E 1 , but we need not have υs E ⊆ υs E 1 . Note above that υs E = vs (X=vs N0) , and that X=vs N0 is the quotient vector space structure of X by the linear subspace N0 . Having now informally explained the general construction of our generalized 0 Bochner spaces, we note that if Π is Banachable, then Πσ is its weak dual space, and that (σrd Π; ν ) is a Banach space for any compatible norm ν for Π . At least σ mv p for finite positive measures µ then (σrd L (µ ; Π ) ; ν2 ) is a classical Bochner R p p−1 space when ν 2 is defined by X 7! Ω abs ◦ ν ◦ x d µ) for any x 2 X . The appearing ι is the function υs F1 3 Y 7! ι `Y with ι `Y given by R υs F 3 X 7! Ω y : x d µ for any x 2 X and y 2 Y . Here y : x is the function Ω 3 η 7! y`η`(x`η ) = (y`η )`(x`η ) 2 υs K 2 f R ; C g . 0 The message of Theorem A 1 is then that ι 2 Liis (F1 ;F ) holds, i.e. that ι is 0 0 a linear homeomorphism F1 ! F where F is the normable, hence Banachable 0 strong dual of F with υs (F ) = L (F; K ) . For the spaces appearing in (3) and Duality of Bochner spaces 3 m p mv p (4) note that we define L (µ) = L (µ ; tf R) . Below note that in the usual man- ner we have p ∗ = (1 − p −1 −1 for 1 < p < +1 and p ∗ = +1 for p = 1 , and also p ∗ = 1 in the case where p = +1 holds. The last part in condition (4) means that there is a continuous linear map c : m +1 +1 m +1 L (µ) ! ` (Ω) such that c`X 2 X holds for all X 2 υs L (µ) . Continuity here being equivalent to the property that for some M 2 R+ it holds that for m +1 --i --i x 2 X 2 υs L (µ) and for all A 2 µ ``R+ there is N 2 µ ``f0g such that j c`X `η j ≤ M j x`η j holds for all η 2 A n N, our condition is weaker than the requirement (b) in [ E ; Theorem 8.18.2, p. 588 ] that mL +1 (µ) can be \lifted". 1 Remarks. At first sight, it may seem that Theorem A 1 is less general than the results contained in [ E ; Theorems 8.18.2, 8.18.3, pp. 588, 590 ] when p = 1 since in Edwards' presentation there is stated no assumption on any kind of \decompos- ability". However, one should note that in [ E ] one considers only positive measures that are positive Radonian in the sense of Definitions 28 (4) on page 15 below, and that by Proposition 29 these are \automatically" almost decomposable.
Recommended publications
  • Convenient Vector Spaces, Convenient Manifolds and Differential Linear Logic

    Convenient Vector Spaces, Convenient Manifolds and Differential Linear Logic

    Convenient Vector Spaces, Convenient Manifolds and Differential Linear Logic Richard Blute University of Ottawa ongoing discussions with Geoff Crutwell, Thomas Ehrhard, Alex Hoffnung, Christine Tasson June 20, 2011 Richard Blute Convenient Vector Spaces, Convenient Manifolds and Differential Linear Logic Goals Develop a theory of (smooth) manifolds based on differential linear logic. Or perhaps develop a differential linear logic based on manifolds. Convenient vector spaces were recently shown to be a model. There is a well-developed theory of convenient manifolds, including infinite-dimensional manifolds. Convenient manifolds reveal additional structure not seen in finite dimensions. In particular, the notion of tangent space is much more complex. Synthetic differential geometry should also provide information. Convenient vector spaces embed into an extremely good model. Richard Blute Convenient Vector Spaces, Convenient Manifolds and Differential Linear Logic Convenient vector spaces (Fr¨olicher,Kriegl) Definition A vector space is locally convex if it is equipped with a topology such that each point has a neighborhood basis of convex sets, and addition and scalar multiplication are continuous. Locally convex spaces are the most well-behaved topological vector spaces, and most studied in functional analysis. Note that in any topological vector space, one can take limits and hence talk about derivatives of curves. A curve is smooth if it has derivatives of all orders. The analogue of Cauchy sequences in locally convex spaces are called Mackey-Cauchy sequences. The convergence of Mackey-Cauchy sequences implies the convergence of all Mackey-Cauchy nets. The following is taken from a long list of equivalences. Richard Blute Convenient Vector Spaces, Convenient Manifolds and Differential Linear Logic Convenient vector spaces II: Definition Theorem Let E be a locally convex vector space.
  • Uniqueness of Von Neumann Bornology in Locally C∗-Algebras

    Uniqueness of Von Neumann Bornology in Locally C∗-Algebras

    Scientiae Mathematicae Japonicae Online, e-2009 91 UNIQUENESS OF VON NEUMANN BORNOLOGY IN LOCALLY C∗-ALGEBRAS. A BORNOLOGICAL ANALOGUE OF JOHNSON’S THEOREM M. Oudadess Received May 31, 2008; revised March 20, 2009 Abstract. All locally C∗- structures on a commutative complex algebra have the same bound structure. It is also shown that a Mackey complete C∗-convex algebra is semisimple. By the well-known Johnson’s theorem [4], there is on a given complex semi-simple algebra a unique (up to an isomorphism) Banach algebra norm. R. C. Carpenter extended this result to commutative Fr´echet locally m-convex algebras [3]. Without metrizability, it is not any more valid even in the rich context of locally C∗-convex algebras. Below there are given telling examples where even a C∗-algebra structure is involved. We follow the terminology of [5], pp. 101-102. Let E be an involutive algebra and p a vector space seminorm on E. We say that p is a C∗-seminorm if p(x∗x)=[p(x)]2, for every x. An involutive topological algebra whose topology is defined by a (saturated) family of C∗-seminorms is called a C∗-convex algebra. A complete C∗-convex algebra is called a locally C∗-algebra (by Inoue). A Fr´echet C∗-convex algebra is a metrizable C∗- convex algebra, that is equivalently a metrizable locally C∗-algebra, or also a Fr´echet locally C∗-algebra. All the bornological notions can be found in [6]. The references for m-convexity are [5], [8] and [9]. Let us recall for convenience that the bounded structure (bornology) of a locally convex algebra (l.c.a.)(E,τ) is the collection Bτ of all the subsets B of E which are bounded in the sense of Kolmogorov and von Neumann, that is B is absorbed by every neighborhood of the origin (see e.g.
  • Order-Quasiultrabarrelled Vector Lattices and Spaces

    Order-Quasiultrabarrelled Vector Lattices and Spaces

    Periodica Mathematica Hungarica YoL 6 (4), (1975), pp. 363--371. ~ ORDER-QUASIULTRABARRELLED VECTOR LATTICES AND SPACES by T. HUSAIN and S. M. KHALEELULLA (Hamilton) 1. Introduetion In this paper, we introduce and study a class of topological vector lattices (more generally, ordered topological vector spaces) which we call the class of order-quasiultrabarreUed vector lattices abbreviated to O. Q. U. vector lattices (respectively, O. Q. U. spaces). This class replaces that of order-infrabarrened Riesz spaces (respectively, order-infrabarrelled spaces) [8] in situations where local convexity is not assumed. We obtain an analogue of the Banach--Stein- haus theorem for lattice homom0rphisms on O. Q. U. vector lattices (respec- tively positive linear maps on O. Q. U. spaces) and the one for O. Q. U. spaces is s used successfully to obtain an analogue of the isomorphism theorem concerning O. Q.U. spaces and similar Schauder bases. Finally, we prove a closed graph theorem for O. Q. U, spaces, analogous to that for ultrabarrelled spa~s [6]. 2. Notations and preliminaries We abbreviate locally convex space, locally convex vector lattice, tope- logical vector space, and topological vector lattice to 1.c.s., 1.c.v.l., t.v.s., and t.v.l., respectively. We write (E, C) to denote a vector lattice (or ordered vector space) over the field of reals, with positive cone (or simply, cone) C. A subset B of a vector lattice (E, G) is solid if Ixl ~ ]y], yEB implies xEB; a vector subspace M of (~, C) which is also solid is called a lattice ideal.
  • On Bornivorous Set

    On Bornivorous Set

    On Bornivorous Set By Fatima Kamil Majeed Al-Basri University of Al-Qadisiyah College Of Education Department of Mathematics E-mail:[email protected] Abstract :In this paper, we introduce the concept of the bornivorous set and its properties to construct bornological topological space .Also, we introduce and study the properties related to this concepts like bornological base, bornological subbase , bornological closure set, bornological interior set, bornological frontier set and bornological subspace . Key words : bornivorous set , bornological topological space,b-open set 1.Introduction- The space of entire functions over the complex field C was introduced by Patwardhan who defined a metric on this space by introducing a real-valued map on it[6]. In(1971), H.Hogbe- Nlend introduced the concepts of bornology on a set [3].Many workers such as Dierolf and Domanski, Jan Haluska and others had studied various bornological properties[2]. In this paper at the second section ,bornivorous set has been introduced with some related concepts. While in the third section a new space “Bornological topological space“ has been defined and created in the base of bornivorous set . The bornological topological space also has been explored and its properties .The study also extended to the concepts of the bornological base and bornological subbase of bornological topological space .In the last section a new concepts like bornological closure set, bornological drived set, bornological dense set, bornological interior set, bornological exterior set, bornological frontier set and bornological topological subspace, have been studied with supplementary properties and results which related to them. 1 Definition1.1[3] Let A and B be two subsets of a vector space E.
  • Locally Convex Spaces Manv 250067-1, 5 Ects, Summer Term 2017 Sr 10, Fr

    Locally Convex Spaces Manv 250067-1, 5 Ects, Summer Term 2017 Sr 10, Fr

    LOCALLY CONVEX SPACES MANV 250067-1, 5 ECTS, SUMMER TERM 2017 SR 10, FR. 13:15{15:30 EDUARD A. NIGSCH These lecture notes were developed for the topics course locally convex spaces held at the University of Vienna in summer term 2017. Prerequisites consist of general topology and linear algebra. Some background in functional analysis will be helpful but not strictly mandatory. This course aims at an early and thorough development of duality theory for locally convex spaces, which allows for the systematic treatment of the most important classes of locally convex spaces. Further topics will be treated according to available time as well as the interests of the students. Thanks for corrections of some typos go out to Benedict Schinnerl. 1 [git] • 14c91a2 (2017-10-30) LOCALLY CONVEX SPACES 2 Contents 1. Introduction3 2. Topological vector spaces4 3. Locally convex spaces7 4. Completeness 11 5. Bounded sets, normability, metrizability 16 6. Products, subspaces, direct sums and quotients 18 7. Projective and inductive limits 24 8. Finite-dimensional and locally compact TVS 28 9. The theorem of Hahn-Banach 29 10. Dual Pairings 34 11. Polarity 36 12. S-topologies 38 13. The Mackey Topology 41 14. Barrelled spaces 45 15. Bornological Spaces 47 16. Reflexivity 48 17. Montel spaces 50 18. The transpose of a linear map 52 19. Topological tensor products 53 References 66 [git] • 14c91a2 (2017-10-30) LOCALLY CONVEX SPACES 3 1. Introduction These lecture notes are roughly based on the following texts that contain the standard material on locally convex spaces as well as more advanced topics.
  • Functional Properties of Hörmander's Space of Distributions Having A

    Functional Properties of Hörmander's Space of Distributions Having A

    Functional properties of Hörmander’s space of distributions having a specified wavefront set Yoann Dabrowski, Christian Brouder To cite this version: Yoann Dabrowski, Christian Brouder. Functional properties of Hörmander’s space of distributions having a specified wavefront set. 2014. hal-00850192v2 HAL Id: hal-00850192 https://hal.archives-ouvertes.fr/hal-00850192v2 Preprint submitted on 3 May 2014 HAL is a multi-disciplinary open access L’archive ouverte pluridisciplinaire HAL, est archive for the deposit and dissemination of sci- destinée au dépôt et à la diffusion de documents entific research documents, whether they are pub- scientifiques de niveau recherche, publiés ou non, lished or not. The documents may come from émanant des établissements d’enseignement et de teaching and research institutions in France or recherche français ou étrangers, des laboratoires abroad, or from public or private research centers. publics ou privés. Communications in Mathematical Physics manuscript No. (will be inserted by the editor) Functional properties of H¨ormander’s space of distributions having a specified wavefront set Yoann Dabrowski1, Christian Brouder2 1 Institut Camille Jordan UMR 5208, Universit´ede Lyon, Universit´eLyon 1, 43 bd. du 11 novembre 1918, F-69622 Villeurbanne cedex, France 2 Institut de Min´eralogie, de Physique des Mat´eriaux et de Cosmochimie, Sorbonne Univer- sit´es, UMR CNRS 7590, UPMC Univ. Paris 06, Mus´eum National d’Histoire Naturelle, IRD UMR 206, 4 place Jussieu, F-75005 Paris, France. Received: date / Accepted: date ′ Abstract: The space Γ of distributions having their wavefront sets in a closed cone Γ has become importantD in physics because of its role in the formulation of quantum field theory in curved spacetime.
  • Mackey +0-Barrelled Spaces Stephen A

    Mackey +0-Barrelled Spaces Stephen A

    Advances in Mathematics 145, 230238 (1999) Article ID aima.1998.1815, available online at http:ÂÂwww.idealibrary.com on Mackey +0-Barrelled Spaces Stephen A. Saxon* Department of Mathematics, University of Florida, P.O. Box 118105, Gainesville, Florida 32611-8105 E-mail: saxonÄmath.ufl.edu and Ian Tweddle* Department of Mathematics, University of Strathclyde, Glasgow G11XH, Scotland, United Kingdom E-mail: i.tweddleÄstrath.ac.uk CORE Metadata, citation and similar papers at core.ac.uk Provided by Elsevier - PublisherReceived Connector March 25, 1998; accepted December 14, 1998 In the context of ``Reinventing weak barrelledness,'' the best possible versions of the RobertsonSaxonRobertson Splitting Theorem and the SaxonTweddle Fit and Flat Components Theorem are obtained by weakening the hypothesis from ``barrelled'' to ``Mackey and +0-barreled.'' An example showing that the latter does not imply the former validates novelty, answers an old question, and completes a robust linear picture of ``Mackey weak barrelledness'' begun several decades ago. 1999 Academic Press Key Words: weak barrelledness; Mackey topology; splitting theorem. 1. INTRODUCTION Barrelled spaces have occupied an important place in the theory of locally convex spaces since its earliest days. This is probably due to the fact that they provide a vehicle for generalizing certain important properties of Banach spaces; for example, they form the class of domain spaces for a natural generalization of Banach's closed graph theorem and, in their dual characterization, they embody the conclusion of the BanachSteinhaus theorem for continuous linear functionals. Unlike Banach spaces, they are closed under the taking of inductive limits, countable-codimensional subspaces, products, etc. A barrel in a locally convex space is a closed * We are grateful for support and hospitality from EPSRC GRÂL67257 and Strathclyde University, and for helpful discussions with Professors J.
  • Closed Graph Theorems for Bornological Spaces

    Closed Graph Theorems for Bornological Spaces

    Khayyam J. Math. 2 (2016), no. 1, 81{111 CLOSED GRAPH THEOREMS FOR BORNOLOGICAL SPACES FEDERICO BAMBOZZI1 Communicated by A. Peralta Abstract. The aim of this paper is that of discussing closed graph theorems for bornological vector spaces in a self-contained way, hoping to make the subject more accessible to non-experts. We will see how to easily adapt classical arguments of functional analysis over R and C to deduce closed graph theorems for bornological vector spaces over any complete, non-trivially valued field, hence encompassing the non-Archimedean case too. We will end this survey by discussing some applications. In particular, we will prove De Wilde's Theorem for non-Archimedean locally convex spaces and then deduce some results about the automatic boundedness of algebra morphisms for a class of bornological algebras of interest in analytic geometry, both Archimedean (complex analytic geometry) and non-Archimedean. Introduction This paper aims to discuss the closed graph theorems for bornological vector spaces in a self-contained exposition and to fill a gap in the literature about the non-Archimedean side of the theory at the same time. In functional analysis over R or C bornological vector spaces have been used since a long time ago, without becoming a mainstream tool. It is probably for this reason that bornological vector spaces over non-Archimedean valued fields were rarely considered. Over the last years, for several reasons, bornological vector spaces have drawn new attentions: see for example [1], [2], [3], [5], [15] and [22]. These new developments involve the non-Archimedean side of the theory too and that is why it needs adequate foundations.
  • Quasi-Barrelled Locally Convex Spaces 811

    Quasi-Barrelled Locally Convex Spaces 811

    i960] quasi-barrelled locally convex spaces 811 Bibliography 1. R. E. Lane, Absolute convergence of continued fractions, Proc. Amer. Math. Soc. vol. 3 (1952) pp. 904-913. 2. R. E. Lane and H. S. Wall, Continued fractions with absolutely convergent even and odd parts, Trans. Amer. Math. Soc. vol. 67 (1949) pp. 368-380. 3. W. T. Scott and H. S. Wall, A convergence theorem for continued fractions, Trans. Amer. Math. Soc. vol. 47 (1940) pp. 155-172. 4. H. S. Wall, Analytic theory of continued fractions, New York, D. Van Nostrand Company, Inc., 1948. The University of Texas and University of Houston QUASI-BARRELLED LOCALLY CONVEX SPACES MARK MAHOWALD AND GERALD GOULD 1. Introduction and preliminary definitions. The main object of this paper is to answer some problems posed by Dieudonné in his paper Denumerability conditions in locally convex vector spaces [l]. His two main results are as follows: Proposition 1. If Eis a barrelled space on which there is a countable fundamental system of convex compact subsets, [Definition 1.2] then it is the strong dual of a Fréchet-Montel Space. Proposition 2. If E is either bornological or barrelled, and if there is a countable fundamental system of compact subsets, then E is dense in the strong dual of a Fréchet-Montel Space. Two questions raised by Dieudonné in connection with these results are: (a) If E is either bornological or barrelled then it is certainly quasi- barrelled [l, Chapter 3, §2, Example 12]. Can one substitute this weaker condition on E in Proposition 2? (b) Is there is an example of a quasi-barrelled space which is neither barrelled nor bornological? We shall show that the answer to (a) is "Yes," and that the answer to (b) is also "Yes," so that the generalization is in fact a real one.
  • Canonical Metric on Moduli Spaces of Log Calabi-Yau Varieties Hassan Jolany

    Canonical Metric on Moduli Spaces of Log Calabi-Yau Varieties Hassan Jolany

    Canonical metric on moduli spaces of log Calabi-Yau varieties Hassan Jolany To cite this version: Hassan Jolany. Canonical metric on moduli spaces of log Calabi-Yau varieties . 2017. hal-01413746v3 HAL Id: hal-01413746 https://hal.archives-ouvertes.fr/hal-01413746v3 Preprint submitted on 14 Feb 2017 (v3), last revised 20 Jun 2017 (v4) HAL is a multi-disciplinary open access L’archive ouverte pluridisciplinaire HAL, est archive for the deposit and dissemination of sci- destinée au dépôt et à la diffusion de documents entific research documents, whether they are pub- scientifiques de niveau recherche, publiés ou non, lished or not. The documents may come from émanant des établissements d’enseignement et de teaching and research institutions in France or recherche français ou étrangers, des laboratoires abroad, or from public or private research centers. publics ou privés. Canonical metric on moduli spaces of log Calabi-Yau varieties Hassan Jolany February 14, 2017 Abstract In this paper, we give a short proof of closed formula [9],[18] of loga- rithmic Weil-Petersson metric on moduli space of log Calabi-Yau varieties (if exists!) of conic and Poincare singularities and its connection with Bismut-Vergne localization formula. Moreover we give a relation between logarithmic Weil-Petersson metric and the logarithmic version of semi Ricci flat metric on the family of log Calabi-Yau pairs with conical sin- gularities. In final we consider the semi-positivity of singular logarithmic Weil-Petersson metric on the moduli space of log-Calabi-Yau varieties. Moreover, we show that Song-Tian-Tsuji measure is bounded along Iitaka fibration if and only if central fiber has log terminal singularities and we consider the goodness of fiberwise Calabi-Yau metric in the sense of Mumford and goodness of singular Hermitian metric corresponding to Song-Tian-Tsuji measure.
  • Bornological Topology Space Separation Axioms a Research Submitted by Deyar

    Bornological Topology Space Separation Axioms a Research Submitted by Deyar

    Republic of Iraq Ministry of Higher Education & Scientific Research AL-Qadisiyah University College of Computer Science and Mathematics Department of Mathematics Bornological Topology Space Separation Axioms A Research Submitted by Deyar To the Council of the department of Mathematics ∕ College of Education, University of AL-Qadisiyah as a Partial Fulfilment of the Requirements for the Bachelor Degree in Mathematics Supervised by Fatma Kamel Majeed A. D. 2019 A.H. 1440 Abstract we study Bornological Topology Separation Axioms like bornological topology , bornological topology , bornological topology , bornological topology , bornological topology and the main propositions and theorems about this concept. introduction For the first time in (1977), H. Hogbe–NIend [1] introduced the Concept of Bornology on a set and study Bornological Construction. In chapter one study Bornology on a set , Bornological subspace, convex Bornological space, Bornological vector space and Bornivorous set. Bornological topology space were first introduced and investigated in [4], we introduce in chapter two Bornological topology space and we study Bornological topology continuous and bornological topology homeomorphism. Bornological topology open map, bornological topology separation axioms studied in chapter three like bornological topology , bornological topology , bornological topology And bornological topology Bornological topology and main properties have been studied. The Contents Subject Page Chapter One 1.1 Bornological Space 1 1. 2 Bornivorous Set 4 Chapter Two 2.1 Bornological Topological Space 6 2.2 Bornological Topology Continuous 8 Chapter three 3.1 Bornological topology And Bornological 9 topology 3.2 Bornological topology , Bornological topology 10 And Bornological topology Chapter One 1.1 Bornological space In this section, we introduce some definitions, bornological space, bornological vector space, convex bornological vector space, separated bornological vector space, bounded map and some examples .
  • Canonical Metric on a Mildly Singular Kähler Varieties with an Intermediate Log Kodaira Dimension Hassan Jolany

    Canonical Metric on a Mildly Singular Kähler Varieties with an Intermediate Log Kodaira Dimension Hassan Jolany

    Canonical metric on a mildly singular Kähler varieties with an intermediate log Kodaira dimension Hassan Jolany To cite this version: Hassan Jolany. Canonical metric on a mildly singular Kähler varieties with an intermediate log Kodaira dimension. 2017. hal-01413751v2 HAL Id: hal-01413751 https://hal.archives-ouvertes.fr/hal-01413751v2 Preprint submitted on 21 Jun 2017 HAL is a multi-disciplinary open access L’archive ouverte pluridisciplinaire HAL, est archive for the deposit and dissemination of sci- destinée au dépôt et à la diffusion de documents entific research documents, whether they are pub- scientifiques de niveau recherche, publiés ou non, lished or not. The documents may come from émanant des établissements d’enseignement et de teaching and research institutions in France or recherche français ou étrangers, des laboratoires abroad, or from public or private research centers. publics ou privés. Canonical metric on a mildly singular Kahler¨ varieties with an intermediate log Kodaira dimension HASSAN JOLANY Existence of canonical metric on a canonical model of projective singular variety was a long standing conjecture and the major part of this conjecture is about varieties which do not have definite first Chern class(most of the varieties do not have definite first Chern class). There is a program which is known as Song-Tian program for finding canonical metric on canonical model of a projective variety by using Minimal Model Program. In this paper, we apply Song-Tian program for mildly singular pair (X; D) via Log Minimal Model Program where D is a simple normal crossing divisor on X with conic singularities.