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- Bu səhifədəki naviqasiya:
- Foydalanilgan adabiyo tlar ro‘yxati
- Nilufarxon Raxmonova Vaxobjon qizi Kokand University teacher at Department of Digital technologies and mathematics Abstract
- Keywords : C*-algebra; Rickart complex and real C*-algebras; complex and real AW*- algebras. Introduction
- Preliminaries: Definition 2.1.
- Definition 2.2.
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kokanduni.uz yig‘indisi ( ) 2 1 2 1 1 2 , : l l x y y k x b b + = + + ko‘rinishdagi yarim tekislikdan iborat ekanligi kelib chiqadi. Agar 1 2 k k bo‘lsa, u holda 1 1 1 : l y k x b = + va 2 2 2 : l y k x b = + tog‘ri chizqlar o‘zaro parallel bo‘lma ydi. [1, Pr oposition 3.2.] ga ko‘ra bu to‘g‘ri chiziqlarning Minkovskiy yig‘indisi bu to‘g‘ri chiziqlar yotuvchi tekislik bo‘ladi, ya’ni 2 . Faraz qilaylik, 2 1 2 l l + bo‘lsin. U holda shunday ( ) 2 0 0 ; x y nuqta topilib, ( ) 0 0 1 2 ; x y l l + bo‘ladi. ( ) 0 0 1 2 ; x y l l + munosabatning ma’nosi 0 1 2 x x x = + va 0 1 2 y y y = + tengliklarni qanoatlantiradigan ( ) 1 1 1 ; x y l , ( ) 2 2 2 ; x y l nuqtalar topilmasligini bildiradi. Lekin 1 x va 2 x ekanligidan doimo 0 1 2 x x x = + tenglikni qanoatlantiradigan 1 2 , x x lar topiladi. Bundan 1 0 2 x x x = − yoza olamiz. 1 1 1 1 y k x b + va 2 2 2 2 y k x b + bo‘lgani uchun 1 2 1 1 2 2 1 2 y y k x k x b b + + + + ifoda kelib chiqadi. Bu ifodaga 1 0 2 x x x = − ni qo‘ysak ( ) 1 2 1 0 2 1 2 1 2 y y k x k k x b b + + − + + tengsizlikk a ega bo‘lamiz. 1 2 k k bo‘lgani uchun har qanday ( ) 2 0 0 ; x y nuqta olinmasin doim ( ) 0 1 0 2 1 2 1 2 y k x k k x b b + − + + munosabat o‘rinli bo‘luvchi 2 x topiladi. Demak, ( ) 0 0 1 2 ; x y l l + va 2 1 2 l l + = . Demak, bu to‘g‘ri chiziqlar hosil qilgan yarim tekisliklar Minkovskiy yig‘indisi ham butun tekislikdan iborat bo‘lar ekan. 2-teorema . Aytaylik ( ) 2 1 1 1 , : l x y y k x b = + va ( ) 2 2 2 2 , : l x y y k x b = + to‘plamlar 2 da aniqlangan yarim tekisliklar bo‘lsin. Agar 1 2 k k = tenglik bajarilsa, u holda ularning Minkowskiy ayirmasi ( ) 2 1 2 1 1 2 , : l l x y y k x b b = + − yarim tekislik bo‘ladi. Agar 1 2 k k munosabat bajarilsa 1 2 l l Minkovskiy ayirmasi bo‘sh to‘plamdan iborat bo‘ladi. Isbot. Agar 1 2 k k = bo‘lsa 1 l va 2 l to‘plamlarning mos ravishda yasovchilari bo‘lgan, 1 1 1 : l y k x b = + va 2 2 2 : l y k x b = + to‘g‘ri chiziqlar o‘zaro parallel bo‘lib qoladi. [2, 1 -teorema] ga ko‘ra bu chiziqlarning Minkowskiy ayirmasi shu to‘g‘ri chiziqlarga parallel to‘g‘ri chiziq bo‘ladi. Aytaylik, ( ) 0 0 1 2 ; x y l l bo‘lsin. Minkovskiy ayirmasining ta’rifiga ko‘ra ( ) 0 0 2 1 ; x y l l + munosabat o‘rinli bo‘ladi. ( ) 0 0 2 ; x y l + to‘plam 2 l to‘plamni ( ) 0 0 ; x y nuqtaga parallel ko‘chirishdan hosil bo‘lgan to‘plam bo‘lib, uni 2 l orqali belgilaymiz va ( ) ( ) 2 2 2 0 2 0 , : l x y y k x x b y = − + + (3) 40 www. kokanduni.uz ko‘ri nishda ifodalaymiz. 2 1 l l bo‘lgani uchun ( ) 2 1 1 1 , : l x y y k x b = + ekanligini bilgan holda ( ) 2 0 2 0 1 1 k x x b y k x b − + + + (4) tengsizlikni yoza olamiz. 1 2 k k = bo‘lgani uchun (4) munosabatni 0 1 0 1 2 y k x b b + − (5) ko‘rinishda yoza olamiz. Demak, ( ) 0 0 1 2 ; x y l l nuqtalar uchun (5) shart o‘rinli ekan. Bundan esa 1 l va 2 l yarim tekisliklarning Minkovskiy ayirmasi ( ) 2 1 2 1 1 2 , : l l x y y k x b b = + − ko‘rinishda gi yarim tekislikdan iborat ekanligi kelib chiqadi. 1 2 k k bo‘lsin. 2 2 l l to‘g‘ri chiziqni olaylik. Minkovskiy ayirmasi aniqlanishiga ko‘ra 1 2 l l to‘plam shunday nuqtalardan iborat bo‘lishi kerakki, 2 l to‘g‘ri chiziqning bu nuqtalarga parallel ko‘chirganimizdagi obrazi 2 l yarim tekis likda to‘la yotib qolishi lozim. 1 1 1 : l y k x b = + va 2 2 2 : l y k x b = + to‘g‘ri chiziqlar o‘zaro parallel bo‘lmagani uchun bunday nuqtalar topilmaydi. Bu esa 1 2 l l = ekanini anglatadi. 2 2 l l bo‘lgani uchun 1 2 l l = munosabat ham o‘rinli bo‘ladi. Foydalanilgan adabiyo tlar ro‘yxati: 1. D. Velichova. Notes on properties and applications of Minkowski point set operations// South Bohemia Mathematical Letters. 2016. Volume 24. 1. pp.57-71. 2. J.T. Nuritdinov. To‘g‘ri chiziq va tekisliklar Minkovskiy ayirmasi haqida .// Differential equations and related problems of analysis. Republican Scientific Conference with the participation of foreign scientists Bukhara, Uzbekistan, November 04 – 05, 2021 41 www. kokanduni.uz THE CONNECTION OF A RICKART REAL C*-ALGEBRA WITH ITS ENVELOPING RICKART (COMPLEX) C*-ALGEBRA Abduxamidova Dilshoda Bayram qizi Kokand University Student of MLS – 1 – 22, Nilufarxon Raxmonova Vaxobjon qizi Kokand University teacher at Department of Digital technologies and mathematics Abstract: In the paper Rickart complex and real C*-algebra are consider. For Rickart real C*-algebra, its connection with the enveloping (complex) C*-algebra is studied. It is shown that the fact that A is a Rickart real C*-algebra does not imply that a complexification A +i A of A is a Rickart (complex) C*-algebra. Proved that if A is a real C*-algebra and A +i A is a Rickart C*-algebra, then A is a Rickart real C*-algebra. It is shown that there exists a Rickart real C*- algebra whose projection lattice is not complete. Keywords : C*-algebra; Rickart complex and real C*-algebras; complex and real AW*- algebras. Introduction: The theory of operator algebras was initiated in a series of papers by Murray and von Neumann in thirties. Later such algebras were called von Neumann algebras or W*-algebras. These algebras are self-adjoint unital subalgebras M of the algebra B(H) of bounded linear operators on a complex Hilbert space H, which are closed in the weak operator topology. Equivalently M is a von Neumann algebra in B(H) if it is equal to the commutant of its commutant (von Neumann's bicommutant theorem). A factor (or W*-factor) is a von Neumann algebra with trivial centre and investigation of general W*-algebras can be reduced to the case of W*-factors, which are classified into types I, II and III. Rings and algebras, which will be discussed below, first studied by C.E. Rickart [1]. These algebras were further developed in the works of I. Kaplansky [2-4]. Exactly, AW*-algebras were proposed by I. Kaplansky as an appropriate setting for certain parts of the algebraic theory of von Neumann algebras. In this article, we consider the real analogue of these algebras. Preliminaries: Definition 2.1. A C*-algebra is a (complex) Banach *-algebra whose norm satisfies the identity 2 || * || || || x x x = . Now let A be a real Banach *-algebra. A is called a real C*-algebra, if c A A iA = + can be normed to become a (complex) C*-algebra by extending the original norm on A. Note that a C*-norm on c A is unique, if it exists. It is known that [5, Corollary 5.2.11] A is real C*-algebra if and only if 2 || * || || || x x x = and 1 * x x + is invertible, for any x A . Definition 2.2. If A is a ring and S is a nonempty subset of A, we write ( ) { : 0, } R S x A sx s S = = and call R(S) the right-annihilator of S. Similarly, ( ) { : 0, } L S x A xs s S = = |