Intuitionistic Fuzzy 2-norm

Similar documents
On fuzzy normed algebras

STABILITY OF PEXIDERIZED QUADRATIC FUNCTIONAL EQUATION IN NON-ARCHIMEDEAN FUZZY NORMED SPASES

Product of Fuzzy Metric Spaces and Fixed Point Theorems

ON COMPATIBLE MAPPINGS OF TYPE (I) AND (II) IN INTUITIONISTIC FUZZY METRIC SPACES

FUZZY n-inner PRODUCT SPACE

On the stability of a Pexiderized functional equation in intuitionistic fuzzy Banach spaces

Stability of General Cubic Mapping in Fuzzy Normed Spaces

VOL. 1, NO. 8, November 2011 ISSN ARPN Journal of Systems and Software AJSS Journal. All rights reserved

ON I-CONVERGENCE OF DOUBLE SEQUENCES IN THE TOPOLOGY INDUCED BY RANDOM 2-NORMS. Mehmet Gürdal and Mualla Birgül Huban. 1.

Nonlinear Fuzzy Stability of a Functional Equation Related to a Characterization of Inner Product Spaces via Fixed Point Technique

On Fixed Point Theorem in Fuzzy2- Metric Spaces for Integral type Inequality

On the Stability of the n-dimensional Quadratic and Additive Functional Equation in Random Normed Spaces via Fixed Point Method

Introduction. Common Fixed Point Theorems For Six Self Mappings Complying Common (E.A.) Property in Fuzzy Metric Space

On the probabilistic stability of the monomial functional equation

A natural selection of a graphic contraction transformation in fuzzy metric spaces

The Asymptotic Behavior of Nonoscillatory Solutions of Some Nonlinear Dynamic Equations on Time Scales

Oscillation of an Euler Cauchy Dynamic Equation S. Huff, G. Olumolode, N. Pennington, and A. Peterson

Essential Maps and Coincidence Principles for General Classes of Maps

Stability Results in Intuitionistic Fuzzy Normed Spaces for a Cubic Functional Equation

CHARACTERIZATION OF REARRANGEMENT INVARIANT SPACES WITH FIXED POINTS FOR THE HARDY LITTLEWOOD MAXIMAL OPERATOR

A New Kind of Fuzzy Sublattice (Ideal, Filter) of A Lattice

NEW EXAMPLES OF CONVOLUTIONS AND NON-COMMUTATIVE CENTRAL LIMIT THEOREMS

THE GENERALIZED PASCAL MATRIX VIA THE GENERALIZED FIBONACCI MATRIX AND THE GENERALIZED PELL MATRIX

Faα-Irresolute Mappings

Roughness in ordered Semigroups. Muhammad Shabir and Shumaila Irshad

Olaru Ion Marian. In 1968, Vasilios A. Staikos [6] studied the equation:

FIXED FUZZY POINT THEOREMS IN FUZZY METRIC SPACE

Generalized Chebyshev polynomials

Variational Iteration Method for Solving System of Fractional Order Ordinary Differential Equations

Monotonic Solutions of a Class of Quadratic Singular Integral Equations of Volterra type

@FMI c Kyung Moon Sa Co.

International Journal of Scientific & Engineering Research, Volume 4, Issue 10, October ISSN

CERTAIN CLASSES OF SOLUTIONS OF LAGERSTROM EQUATIONS

L-fuzzy valued measure and integral

Nonlinear L -Fuzzy stability of cubic functional equations

International Journal of Pure and Applied Mathematics Volume 56 No ,

A Sharp Existence and Uniqueness Theorem for Linear Fuchsian Partial Differential Equations

EXISTENCE OF NON-OSCILLATORY SOLUTIONS TO FIRST-ORDER NEUTRAL DIFFERENTIAL EQUATIONS

STABILITY OF NONLINEAR NEUTRAL DELAY DIFFERENTIAL EQUATIONS WITH VARIABLE DELAYS

Mapping Properties Of The General Integral Operator On The Classes R k (ρ, b) And V k (ρ, b)

Undetermined coefficients for local fractional differential equations

COMMON FIXED POINT THEOREMS IN MENGER SPACE FOR SIX SELF MAPS USING AN IMPLICIT RELATION

arxiv: v1 [math.fa] 9 Dec 2018

On Gronwall s Type Integral Inequalities with Singular Kernels

Ordinary Differential Equations

Positive continuous solution of a quadratic integral equation of fractional orders

LIMIT AND INTEGRAL PROPERTIES OF PRINCIPAL SOLUTIONS FOR HALF-LINEAR DIFFERENTIAL EQUATIONS. 1. Introduction

Fréchet derivatives and Gâteaux derivatives

t 2 B F x,t n dsdt t u x,t dxdt

Application of a Stochastic-Fuzzy Approach to Modeling Optimal Discrete Time Dynamical Systems by Using Large Scale Data Processing

Ann. Funct. Anal. 2 (2011), no. 2, A nnals of F unctional A nalysis ISSN: (electronic) URL:

An Introduction to Malliavin calculus and its applications

Some New Uniqueness Results of Solutions to Nonlinear Fractional Integro-Differential Equations

MODULE 3 FUNCTION OF A RANDOM VARIABLE AND ITS DISTRIBUTION LECTURES PROBABILITY DISTRIBUTION OF A FUNCTION OF A RANDOM VARIABLE

Weyl sequences: Asymptotic distributions of the partition lengths

GCD AND LCM-LIKE IDENTITIES FOR IDEALS IN COMMUTATIVE RINGS

Transformations of measure on infinite-dimensional vector spaces

On Two Integrability Methods of Improper Integrals

A NEW APPROACH FOR STUDYING FUZZY FUNCTIONAL EQUATIONS

Matrix Versions of Some Refinements of the Arithmetic-Geometric Mean Inequality

Asymptotic instability of nonlinear differential equations

An Excursion into Set Theory using a Constructivist Approach

Characterization of Gamma Hemirings by Generalized Fuzzy Gamma Ideals

Sobolev-type Inequality for Spaces L p(x) (R N )

Existence Theory of Second Order Random Differential Equations

Cash Flow Valuation Mode Lin Discrete Time

Fixed Point Theorem in Intuitionistic Fuzzy Metric Spaces Using Compatible Mappings of Type (A)

SPECTRAL EVOLUTION OF A ONE PARAMETER EXTENSION OF A REAL SYMMETRIC TOEPLITZ MATRIX* William F. Trench. SIAM J. Matrix Anal. Appl. 11 (1990),

Atomic Decompositions of Fuzzy Normed Linear Spaces for Wavelet Applications

CONTRIBUTION TO IMPULSIVE EQUATIONS

A New Perturbative Approach in Nonlinear Singularity Analysis

Method For Solving Fuzzy Integro-Differential Equation By Using Fuzzy Laplace Transformation

The Stacked Semi-Groups and Fuzzy Stacked Systems on Transportation Models

On Carlsson type orthogonality and characterization of inner product spaces

L p -L q -Time decay estimate for solution of the Cauchy problem for hyperbolic partial differential equations of linear thermoelasticity

Inequality measures for intersecting Lorenz curves: an alternative weak ordering

Existence of non-oscillatory solutions of a kind of first-order neutral differential equation

On a Fractional Stochastic Landau-Ginzburg Equation

Integral representations and new generating functions of Chebyshev polynomials

LINEAR INVARIANCE AND INTEGRAL OPERATORS OF UNIVALENT FUNCTIONS

Some Fixed Point Results in Dislocated Probability Menger Metric Spaces

POSITIVE SOLUTIONS OF NEUTRAL DELAY DIFFERENTIAL EQUATION

arxiv:math/ v1 [math.nt] 3 Nov 2005

EXISTENCE AND UNIQUENESS THEOREMS ON CERTAIN DIFFERENCE-DIFFERENTIAL EQUATIONS

arxiv: v1 [math.pr] 19 Feb 2011

Generalized Snell envelope and BSDE With Two general Reflecting Barriers

A Specification Test for Linear Dynamic Stochastic General Equilibrium Models

Some operator monotone functions related to Petz-Hasegawa s functions

Lower and Upper Approximation of Fuzzy Ideals in a Semiring

Endpoint Strichartz estimates

Omega-limit sets and bounded solutions

BOUNDEDNESS OF MAXIMAL FUNCTIONS ON NON-DOUBLING MANIFOLDS WITH ENDS

Exponential Weighted Moving Average (EWMA) Chart Under The Assumption of Moderateness And Its 3 Control Limits

Convergence of the Neumann series in higher norms

Sumudu Decomposition Method for Solving Fractional Delay Differential Equations

OSCILLATION OF SECOND-ORDER DELAY AND NEUTRAL DELAY DYNAMIC EQUATIONS ON TIME SCALES

On the Fourier Transform for Heat Equation

I λ -convergence in intuitionistic fuzzy n-normed linear space. Nabanita Konwar, Pradip Debnath

INDEPENDENT SETS IN GRAPHS WITH GIVEN MINIMUM DEGREE

GENERALIZATION OF THE FORMULA OF FAA DI BRUNO FOR A COMPOSITE FUNCTION WITH A VECTOR ARGUMENT

Transcription:

In. Journal of Mah. Analysis, Vol. 5, 2011, no. 14, 651-659 Inuiionisic Fuzzy 2-norm B. Surender Reddy Deparmen of Mahemaics, PGCS, Saifabad, Osmania Universiy Hyderabad - 500004, A.P., India bsrmahou@yahoo.com Absrac In his paper, we redefine he noion of fuzzy 2-normed linear space using -norm and fuzzy ani-2-normed linear space using -conorm and inroduced he definiion of inuiionisic fuzzy 2-norm on a linear space. Mahemaics Subjec Classificaion: 46S40, 03E72 Keywords: -norm, -conorm, fuzzy -2-norm, fuzzy -ani-2-norm 1 Inroducion Fuzzy se heory is a useful ool o describe siuaions in which he daa are imprecise or vague. Fuzzy ses handle such siuaion by aribuing a degree o which a cerain objec belongs o a se. The idea of fuzzy norm was iniiaed by Kasaras in [8]. Felbin [5] defined a fuzzy norm on a linear space whose associaed fuzzy meric is of Kaleva and Seikkala ype [7]. Cheng and Mordeson [4] inroduced an idea of a fuzzy norm on a linear space whose associaed meric is Kramosil and Michalek ype [9]. Bag and Samana in [1] gave a definiion of a fuzzy norm in such a manner ha he corresponding fuzzy meric is of Kramosil and Michalek ype [9]. They also sudied some properies of he fuzzy norm in [2] and [3]. Bag and Samana discussed he noions of convergen sequence and Cauchy sequence in fuzzy normed linear space in [1]. They also made in [3] a comparaive sudy of he fuzzy norms defined by Kasaras [8], Felbin [5], and Bag and Samana [1]. In [6] Iqbal H. Jebril and Samana redefined he noion of fuzzy normed linear space using -norm and fuzzy ani-normed linear space using -conorm and inroduced he definiion of inuiionisic fuzzy norm on a linear space. In [12] Surender Reddy inroduced he noion fuzzy ani-2-norm on a linear space and some resuls are inroduced in fuzzy ani-2-norms on a linear space.

652 B. Surender Reddy In his paper, we redefine he noion of fuzzy 2-normed linear space using -norm and fuzzy ani-2-normed linear space using -conorm and inroduced he definiion of inuiionisic fuzzy 2-norm on a linear space. In [5], Felbin inroduced he concep of a fuzzy norm based on a Kaleva and Seikkala ype [7] of fuzzy meric using he noion of fuzzy number. Le X be a vecor space over R(se of real numbers). Le : X R (I) be a mapping and le he mappings L, U :[0, 1] [0, 1] [0, 1], be symmeric, non-decreasing in boh argumens and saisfying L(0, 0) = 0 and U(1, 1) = 1. Wrie [ x ] α =[ x 1 α R x 2 α ] for x X, 0<α 1 and suppose for all x X, x 0here exiss α 0 (0, 1] independen of x such ha for all α α 0, (A) x 2 α < (B) inf x 1 α > 0 The quadruple (X,,L,U) is called a Felbin-fuzzy normed linear space and is a Felbin-fuzzy norm if (i) x = 0 if and only if x =0(he null vecor), (ii) rx = r x, x X, r R, (iii) For all x, y X, (a) Whenever s x 1 1, y 1 1 and s+ x + y 1 1, x + y (s + ) L( x (s), y ()). (b)whenever s x 1 1, y 1 1 and s + x + y 1 1, x + y (s + ) U( x (s), y ()). Definiion 1.1 Le X be a vecor space over R(se of real numbers). Le, : X X R (I) be a mapping and le he mappings L, U :[0, 1] [0, 1] [0, 1], be symmeric, non-decreasing in boh argumens and saisfying L(0, 0) = 0 and U(1, 1) = 1. Wrie [ x, z ] α =[ x, z 1 α R x, z 2 α ] for x, z X, 0 <α 1and suppose for all x, z X, x 0, z 0, here exiss α 0 (0, 1] independen of x, z such ha for all α α 0, (A) x, z 2 α < (B) inf x, z 1 α > 0 The quadruple (X,,, L,U) is called a Felbin-fuzzy 2-normed linear space and, is a Felbin-fuzzy 2-norm if (i) x, z =0if and only if x, z are linearly dependen, (ii) rx, z = r x, z, x, z X, r R (iii) x, z is invarian under any permuaion of x, z, (iv) For all x, y, z X, (a) Whenever s x, z 1 1, y, z 1 1 and s + x + y, z 1 1, x + y, z (s + ) L ( x, z (s), y, z ()). (b) Whenever s x, z 1 1, y, z 1 1 and s + x + y, z 1 1, x + y, z (s + ) U ( x, z (s), y, z ()). 2 Preliminaries This secion conains a few basic definiions and preliminary resuls which will be needed in he sequel.

Inuiionisic fuzzy 2-norm 653 Definiion 2.1 Le X be a real linear space of dimension greaer han one and le, be a real valued funcion on X X saisfying he following condiions 2N 1 : x, y =0if and only if x and y are linearly dependen, 2N 2 : x, y = y, x, 2N 3 : αx, y α x, y, for every α R 2N 4 : x, y + z x, y + x, z hen he funcion, is called a 2-norm on X and he pair (X,, ) is called a 2-normed linear space. Definiion 2.2 [10] Le X be a linear space over a field F. A fuzzy subse N of X X R is such ha for all x, y, z X, c F (2 N1): For all R wih 0, N(x, y, ) =0, (2 N2): For all R wih >0, N(x, y, ) =1if and only if x, y are linearly dependen (2 N3): N(x, y, ) is invarian under any permuaion of x, y (2 N4): For all R wih >0, N(x, cy, ) =N(x, y, ) if c 0, (2 N5): For all s, R, N(x, y + z, s + ) min{n(x, y, s),n(x, z, )} (2 N6): N(x, y, ) is a non-decreasing funcion of R and lim N(x, y, ) = 1. Then N is said o be a fuzzy 2-norm on a linear space X and he pair (X, N) is called a fuzzy 2-normed linear space (briefly F-2-NLS) Example 2.3 Le (X,, ) be a 2-normed linear space. Define N(x, y, ) =, + x, y when > 0, R, x, y X = 0, when 0, R, x, y X. Then (X, N) is an F-2-NLS. Example 2.4.Le(X,, ) be a 2-normed linear space. Define N(x, y, ) = 0, when x, y, R, x, y X = 1, when > x, y, R, x, y X. Then (X, N) is an F-2-NLS. Definiion 2.5 Le U be a linear space over a real field F. A fuzzy subse N of U U R such ha for all x, y, u U, c F (a 2 N1): For all R wih 0, N (x, y, ) =1, (a 2 N2): For all R wih >0, N (x, y, ) =0if and only if x, y are linearly dependen (a 2 N3): N (x, y, ) is invarian under any permuaion of x, y

654 B. Surender Reddy (a 2 N4): For all R wih >0, N (x, cy, ) =N (x, y, ) if c 0, (a 2 N5): For all s, R, N (x, y+u, s+) max{n (x, y, s),n (x, u, )} (a 2 N6): N (x, y, ) is a non-increasing funcion of R and lim N (x, y, ) = 0. Then N is said o be a fuzzy ani-2-norm on a linear space U and he pair (U, N ) is called a fuzzy ani-2-normed linear space (briefly Fa-2-NLS). Example 2.6 Le (U,, ) be a 2-normed linear space. Define N x, y (x, y, ) =, when > 0, R, x, y U + x, y = 1, when 0, R, x, y U. Then (U, N ) is an Fa-2-NLS. Proof. Now we have o show ha N (x, y, ) is a fuzzy ani-2-norm in U. (a 2 N1): For all R wih 0, we have by definiion N (x, y, ) =1. (a 2 N2): For all R wih >0, N (x, y, ) =0 x,y =0 + x,y x, y =0 x, y are linearly dependen (a 2 N3): As x, y is invarian under any permuaion of x, y, i follows ha N (x, y, ) is invarian under any permuaion of x, y (a 2 N4): For all R wih >0 and c 0,c F, we ge N (x, cy, ) = x, cy + x, cy = x, y + x, y = x, y + x, y = N (x, y, ). (a 2 N5): For all s, R and x, y, u U. We have o show ha N (x, y +u, s+) max{n (x, y, s),n (x, u, )}. If (a) s+ <0 (b) s = =0 (c) s + >0; s>0, <0; s<0, >0, hen in hese cases he relaion is obvious. If (d) s>0, >0, s + >0. Then assume ha N (x, y, s) N (x, u, ) x, y s + x, y x, u + x, u x, y ( + x, u ) x, u (s + x, y ) x, y s x, u. Now x, y + u s + + x, y + u = x, u + x, u x, y s x, u (s + + x, y + x, u )( + x, u ) x, y + u s + + x, y + u x, y + x, u s + + x, y + x, u x, u + x, u 0. (Since x, y s x, u ) x, u + x, u. Similarly x, y + u s + + x, y + u x, y s + x, y.

Inuiionisic fuzzy 2-norm 655 Hence N (x, y + u, s + ) max{n (x, y, s),n (x, u, )}. (a 2 N6): If 1 < 2 0, hen we have N (x, y, 1 )=N (x, y, 2 ) = 1. If 0 < 1 < 2 hen x, y 1 + x, y x, y 2 + x, y = x, y ( 2 1 ) ( 1 + x, y )( 2 + x, y ) > 0 N (x, y, 1 ) N (x, y, 2 ). Thus N (x, y, ) is a non-increasing funcion of R. Again for all x, y U lim N x, y (x, y, ) = lim + x, y =0. Hence (U, N ) is an F a 2 NLS. Example 2.7 Le (U,, ) be a 2-normed linear space. Define N : U U R [0, 1] by N (x, y, ) = 0, when > x, y, R, x, y U = 1, when x, y, R, x, y U. Then (U, N ) is an Fa-2-NLS. 3 Inuiionisic Fuzzy 2-norm In his secion we redefine he noion of fuzzy 2-normed linear space using -norm and fuzzy ani 2-normed linear space using -conorm hen we inroduce he definiion of inuiionisic fuzzy 2-norm on a linear space. Definiion 3.1 [11] A binary operaion :[0, 1] [0, 1] [0, 1] is coninuous -norm if saisfies he following condiions (a) is commuaive and associaive (b) is coninuous (c) a 1=a for all a [0, 1] (d) a b c d, whenever a c and b d, and a, b, c, d [0, 1]. Example 3.2 (i) a b = ab (ii) a b = min{a, b} (iii) a b = max{a + b 10} are coninuous -norms. Definiion 3.3 Le X be a linear space over a real field F. A fuzzy subse N of X X R(se of real numbers) is such ha for all x, y, z X, c F (F 2 N1): For all R wih 0, N(x, y, ) =0, (F 2 N2): For all R wih >0, N(x, y, ) =1if and only if x, y are linearly dependen (F 2 N3): N(x, y, ) is invarian under any permuaion of x, y (F 2 N4): For all R wih >0, N(x, cy, ) =N(x, y, ) if c 0, (F 2 N5): For all s, R, N(x, y + z, s + ) N(x, y, s) N(x, z, ) (F 2 N6): N(x, y, ) is a non-decreasing funcion of R and lim N(x, y, ) = 1. Then N is said o be a fuzzy -2-norm on a linear space X and he pair (X, N) is called a fuzzy -2-normed linear space (briefly F- -2-NLS).

656 B. Surender Reddy Definiion 3.4 [11] A binary operaion :[0, 1] [0, 1] [0, 1] is coninuous -conorm if saisfies he following condiions (a) is commuaive and associaive (b) is coninuous (c) a 0 =a for all a [0, 1] (d) a b c d, whenever a c and b d, and a, b, c, d [0, 1]. Example 3.5 (i) a b = min{a+b, 1} (ii) a b = max{a, b} (iii) a b = a + b ab are coninuous -conorms. Definiion 3.6 Le X be a linear space over a real field F. A fuzzy subse M of X X R(se of real numbers) is such ha for all x, y, z X, c F (Fa 2 N1): For all R wih 0, M(x, y, ) =1, (Fa 2 N2): For all R wih >0, M(x, y, ) =0if and only if x, y are linearly dependen (Fa 2 N3): M(x, y, ) is invarian under any permuaion of x, y (Fa 2 N4): For all R wih >0, M(x, cy, ) =M(x, y, ) if c 0, (Fa 2 N5): For all s, R, M(x, y + z, s + ) M(x, y, s) M(x, z, ) (Fa 2 N6): M(x, y, ) is a non-increasing funcion of R and lim M(x, y, ) = 0. Then M is said o be a fuzzy -ani-2-norm on a linear space X and he pair (X, M) is called a fuzzy -ani-2-normed linear space (briefly F- -a-2-nls). Definiion 3.7 [13] Le E be any se. An inuiionisic fuzzy se A of E is an objec of he form A = {(x, μ A (x),ν A (x)) : x E}, where μ A : E [0, 1] and ν A : E [0, 1] denoes he degree of membership and he nonmembership of he elemen x E respecively and for every x E, 0 μ A (x)+ν A (x) 1. Definiion 3.8 Le E be any se. An inuiionisic fuzzy 2-se A of E is an objec of he form A = {((x, y),μ A (x, y),ν A (x, y)) : (x, y) E E}, where μ A : E E [0, 1] and ν A : E E [0, 1] denoes he degree of membership and he non-membership of he elemen (x, y) E E respecively and for every (x, y) E E, 0 μ A (x, y)+ν A (x, y) 1. Definiion 3.9 Le be coninuous -norm, be a coninuous -conorm and X be a linear space over he field F, (where F = R or C). An inuiionisic fuzzy 2-norm on X is an objec of he form A = {((x, y, ),N(x, y, ),M(x, y, )) : (x, y, ) X X R + }, where N,M are fuzzy ses on X X R +, N denoes he degree of membership and M denoes he degree of non-membership of he elemen (x, y, ) X X R + saisfying he following condiions (i) N is a fuzzy -2-norm on a linear space X (ii) M is a fuzzy -ani-2-norm on a linear space X (iii) N(x, y, )+M(x, y, ) 1, for all (x, y, ) X X R +.

Inuiionisic fuzzy 2-norm 657 Example 3.10 Le (X = R,, ) be a 2-normed linear space. a b = min{a, b} and a b = max{a, b} for all a, b [0, 1] Also define Define N(x, y, ) =, when > 0, R, x, y X, k > 0 + k x, y = 0, when 0, R, x, y X. k x, y and M(x, y, ) =, when > 0, R, x, y X, k > 0 + k x, y = 1, when 0, R, x, y X. Now consider A = {((x, y, ),N(x, y, ),M(x, y, )) : (x, y, ) X X R + } hen A is an inuiionisic fuzzy 2-norm on X. Proof.(i) To prove ha N is a fuzzy -2-norm on a linear space X (F 2 N1): For all R wih 0, we have by definiion N(x, y, ) =0. (F 2 N2): For all R wih >0, N(x, y, ) =1 =1 +k x,y x, y =0 x, y are linearly dependen (F 2 N3): As x, y is invarian under any permuaion of x, y, i follows ha N(x, y, ) is invarian under any permuaion of x, y (F 2 N4): For all R wih >0 and c 0,c F, we ge N(x, cy, ) = + k x, cy = + k x, y = + k x, y = N(x, y, ). (F 2 N5): For all s, R and x, y, u X. We have o show ha N(x, y + u, s + ) min{n(x, y, s),n(x, u, )} = N(x, y, s) N(x, y, ). If (a) s + <0 (b) s = = 0 (c) s + >0; s>0, <0; s<0, >0, hen in hese cases he relaion is obvious. If (d) s>0, >0, s + >0. Then assume ha N(x, y, s) N(x, u, ) s s + k x, y + k x, u (+k x, u ) ( (s + k x, y ) s Now s++k x, y+u s + + k x, y + k x, u =(s+k x, y )+(+k x, u ) (s + k x, y )+ (s + k x, y ) ) s =( s+ s (s + k x, y ). s + + k x, y + u s + s + k x, y s s + s + + k x, y + u s s + k x, y. Hence N(x, y + u, s + ) min{n(x, y, s),n(x, u, )} = N(x, y, s) N(x, u, ). (F 2 N6): If 1 < 2 0, hen we have N(x, y, 1 )=N(x, y, 2 ) = 0. If 0 < 1 < 2 hen 1 1 + k x, y 2 2 + k x, y = k x, y ( 1 2 ) ( 1 + k x, y )( 2 + k x, y ) < 0

658 B. Surender Reddy N(x, y, 1 ) N(x, y, 2 ). Thus N(x, y, ) is a non-decreasing funcion of R and for all x, y X lim N(x, y, ) = lim = 1. Hence N is a +k x,y fuzzy -2-norm on a linear space X. (ii)to prove M(x, y, ) is a fuzzy -ani-2-norm in X. (Fa 2 N1): For all R wih 0, we have by definiion M(x, y, ) =1. (Fa 2 N2): For all R wih >0, M(x, y, ) =0 k x,y =0 +k x,y x, y =0 x, y are linearly dependen (Fa 2 N3): As x, y is invarian under any permuaion of x, y, i follows ha M(x, y, ) is invarian under any permuaion of x, y (Fa 2 N4): For all R wih >0 and c 0,c F, we ge k x, cy M(x, cy, ) = + k x, cy = k x, y + k x, y = k x, y + k x, y = M(x, y, ). (Fa 2 N5): For all s, R and x, y, u X. We have o show ha M(x, y + u, s + ) max{m(x, y, s),m(x, u, )} = M(x, y, s) M(x, u, ). If (a) s + <0 (b) s = = 0 (c) s + >0; s>0, <0; s<0, >0, hen in hese cases he relaion is obvious. If (d) s>0, >0, s + >0. Then assume ha M(x, y, s) M(x, u, ) k x,y k x,u k x, y ( + k x, u ) s+k x,y +k x,u k x, u (s + k x, y ) x, y s x, u. Now = k x, y + u s + + k x, y + u k x, u + k x, u k x, y ks x, u (s + + k x, y + k x, u )( + k x, u ) Since x, y s x, u. Similarly k x, y + k x, u s + + k x, y + k x, u k x, y + u s + + k x, y + u k x, y + u s + + k x, y + u k x, y s + k x, y. k x, u + k x, u k x, u + k x, u. Hence M(x, y+u, s+) max{m(x, y, s),m(x, u, )} = M(x, y, s) M(x, u, ). (Fa 2 N6): If 1 < 2 0, hen we have M(x, y, 1 )=M(x, y, 2 ) = 1. If 0 < 1 < 2 hen k x, y 1 + k x, y k x, y 2 + k x, y = k x, y ( 2 1 ) ( 1 + k x, y )( 2 + k x, y ) > 0 M(x, y, 1 ) M(x, y, 2 ). Thus M(x, y, ) is a non-increasing funcion of k x,y R and for all x, y X lim M(x, y, ) = lim = 0. Hence M is a +k x,y fuzzy -ani-2-norm on a linear space X. (iii) Also N(x, y, )+M(x, y, ) 1, for all (x, y, ) X X R +. Hence A is an inuiionisic fuzzy 2-norm on X. Definiion 3.11 [10] If A is an inuiionisic fuzzy norm on X (where X is a linear space over he field F, where F = R or C) hen (X, A) is called an inuiionisic fuzzy normed linear space (briefly IF-NLS).

Inuiionisic fuzzy 2-norm 659 Definiion 3.12 If A is an inuiionisic fuzzy 2-norm on X (where X is a linear space over he field F, where F = R or C) hen (X, A) is called an inuiionisic fuzzy 2-normed linear space (briefly IF-2-NLS). References [1] T. Bag and T. K. Samana, Finie dimensional fuzzy normed linear spaces, The Journal of Fuzzy Mahemaics, 11(3) (2003), 687-705. [2] T. Bag and T. K. Samana, Fuzzy bounded linear operaors, Fuzzy Ses and Sysems, 151 (2005), 513-547. [3] T. Bag and T. K. Samana, A comparaive sudy of fuzzy norms on a linear space, Fuzzy Ses and Sysems, 159 (2008), 670-684. [4] S. C. Cheng and J. N. Mordesen, Fuzzy linear operaors and fuzzy normed linear spaces, Bull. Cal. Mah. Soc., 86 (1994), 429-436. [5] C. Felbin, Finie dimensional fuzzy normed linear spaces, Fuzzy Ses and Sysems, 48(1992) 239-248. [6] Iqbal H. Jebril and T.K. Samana, Fuzzy Ani-Normed space, Journal of Mahemaics and Technology, February (2010), 66-77. [7] O. Kaleva and S. Seikkala, On fuzzy meric spaces, Fuzzy Ses and Sysems, 12 (1984), 215-229. [8] A.K. Kasaras, Fuzzy opological vecor spaces, Fuzzy Ses and Sysems, 12 (1984), 143-154. [9] I. Kramosil and J. Michalek, Fuzzy meric and saisical meric space, Kyberneica, 11 (1975), 326-334. [10] T.K Samana and Iqbal H. Jebril, Finie dimensional Inuiionisic fuzzy n-normed linear space, In. J. Open Prolbems Comp. Mah., 2(4) (2009). [11] B. Schweizer and A. Sklar, Probabilisic meric space, New York, Amserdam, Oxford, Norh Holland, 1983. [12] B. Surender Reddy, Fuzzy ani-2-normed linear space, Journal of Mahemaics Research, 3(2) May (2011). [13] S. Vijayabalaji, N. Thillaigovindan and Y. Bae Jun, Inuiionisic fuzzy n-normed linear space, Korean Bull. Mah. Soc., 44 (2007), 291-308. Received: December, 2010

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback