DOI: 10.2478/orga-2014-0010 Fuzzy optimization for portfolio selection based on Embedding Theorem in Fuzzy Normed Linear Spaces Farnaz Solatikia1, Erdem Kilig2, Gerhard Wilhelm Weber3 1Department of Engineering Science, Middle East Technical University, Ankara, Turkey, solatikia.farnaz@metu.edu.tr (corresponding author) 2Erdem Kilig, Department of Economics, MEF University, Istanbul, Turkey, kilice@mef.edu.tr 3Gerhard Wilhelm Weber, Institute of Applied Mathematics, Middle East Technical University, Ankara, Turkey, gweber@metu.edu.tr Background: This paper generalizes the results of Embedding problem of Fuzzy Number Space and its extension into a Fuzzy Banach Space C(Q) x C(Q), where C(Q) is the set of all real-valued continuous functions on an open set Q. Objectives: The main idea behind our approach consists of taking advantage of interplays between fuzzy normed spaces and normed spaces in a way to get an equivalent stochastic program. This helps avoiding pitfalls due to severe oversimplification of the reality. Method: The embedding theorem shows that the set of all fuzzy numbers can be embedded into a Fuzzy Banach space. Inspired by this embedding theorem, we propose a solution concept of fuzzy optimization problem which is obtained by applying the embedding function to the original fuzzy optimization problem. Results: The proposed method is used to extend the classical Mean-Variance portfolio selection model into Mean Variance-Skewness model in fuzzy environment under the criteria on short and long term returns, liquidity and dividends. Conclusion: A fuzzy optimization problem can be transformed into a multiobjective optimization problem which can be solved by using interactive fuzzy decision making procedure. Investor preferences determine the optimal multiobjective solution according to alternative scenarios. Keywords: Embedding problem, Fuzzy optimization, Fuzzy Banach Space, Portfolio selection. 1 Introduction Based on the fact that in many situations the distance between two points is in exact rather than a single real number, Kaleva and Seikkala initiated the concept of a fuzzy metric space by describing the distance of points as s fuzzy real number. Since each usual metric space and each Menger probabilistic metric space can be considered as s special case of fuzzy metric space, the study for the fuzzy metric space has been attracted many authors, and several results for nonlinear mappings have been given in some literatures. The concept of a fuzzy norm on a linear space is of comparatively recent origin. It was Katsaras, who while studying fuzzy topological vector spaces, was the first to introduce in 1984 the idea of fuzzy norm on a linear space. Following his pioneering work, Felbin offered in 1992 an alternative definition of a fuzzy norm on a linear space with an associated metric of the Kaleva and Seikkala type. A further development along this line of inquiry took place when in 1994; Cheng and Mordeson evolved the definition Received: 15th January 2014; revised: 14th February 2014; accepted 24'h March 2014 90 of a further type of fuzzy norm having a corresponding metric of the Kramosil and Michalek type. Since these results apparently also constitute various types of fuzzy norms, the further line of inquiry that obviously suggests itself pertains to the determination of relations, if any, among these fuzzy norms. In 2007, an attempt was made to find such relation by making a comparative study of the fuzzy norms defined by Katsaras, Felbin and Bag and Samanta. It has been observed that the fuzzy norm defined by Bag and Samanta is similar to that of Katsaras who defined it in a different way. On the other hand, Felbin's type fuzzy norm corresponds to a pair of which one is a fuzzy norm in our sense and the other is a fuzzy anti-norm. It is as important the concept of Menger probabilistic normed linear space introduced by Serstnev and moreover, each usual classical normed space and Menger probabilistic normed spaces is special cases of fuzzy normed linear spaces. The authors (Sadeqi I, Solatikia F. 2010; Weber G.-W., Solatikia F. 2013) showed that each of the category of fuzzy normed space and Menger probabilistic normed space is isomorphically a subcategory of the category of topological vector spaces and all results and theorems of topological vector spaces apply to fuzzy normed space and Menger probabilistic normed space in general, also as a new result they showed that C(ü), is a fuzzy nor-med space then Menger probabilistic normed space, while it is not classically norm able. So, if we replace the normed space C[0,1] by the fuzzy normed linear space C(ü), then we get an important result in fuzzy normed linear space, while the same statement does not hold true in classical analysis. Portfolio optimization is the process of allocating budget between assets and managing the assets within it. The modern portfolio theory has been proposed by Markowitz (1952) that considers expected return and risk for a portfolio selection problem where variance is used as risk measure. Markowitz's mean-variance model is the central source for a single period portfolio selection problem, from where the efficient frontier model with beta market risk and risk free return can be exploited. As a common standard portfolio model it is used the determine the performance of financial investments and serves as a hedge instrument with encompassing specifications. A wide range of fuzzy model applications are derived from the initially proposed Markowitz model. Genetic algorithms with applications of portfolio selection models in a fuzzy framework are analyzed by Gupta et al. (2012), Bermudeza et al. (2012), Li and Xu (2013), Khalili-Damghani et al. (2013). Gupta analyze a multiobjective credibilistic model with fuzzy constraints of the portfolio selection problem. A hybrid intelligent algorithm that integrates fuzzy simulation with a real-coded genetic algorithm is contructed. They claim for more efficiency where fuzzy parameters are characterized by general functional forms. Bermudeza proposed genetic algorithms transfering applications from their traditional domain of optimization to fuzzy ranking strategy for selecting efficient portfolios of restricted cardinality. A special focus is put on the ambiguity of the trapezoidal fuzzy number which represents the uncertainty on the return. A hybrid multiobjective framework integrates and synthesizes a genetic based machine learning method to design an alternative fuzzy ranking system for comparison purposes based on the results from a data mining model with the results from a data envelope analysis model. Metaxiotis and Liagkouras (2012), and Khalili-Damghani et al. (2013) use evolutionary algorithms to evaluate fuzzy portfolio models. Metaxiotis and Liagkouras present a portfolio management model with the support of multiobjective evolutionary algorithms. They utilize this framework to gain an understanding of the current state of areas related to applications in the portfolio management research field. Khalili-Damghani develop an evolutionary algorithm to design the structure of fuzzy rule based multiobjective system. Tsaur (2013), Li and Xu (2013), Huang and Qiao (2012) put their focus on a behavioral aspect of portfolio selection. Investor behaviors can be classified as risk averse, risk neutral or risk affine. Tsaur conducts a behavioral analysis of the investor in the fuzzy portfolio model. They examine different investor risk preferences to discover an efficient method for fuzzy portfolio selection. In this relation, a probabilistic mean-standard deviation model is applied to fit the risk attitudes of investors. In an application of a multiobjective portfolio selection model with fuzzy random returns Li and Xu use experts' opinions and judgments and investors' different attitudes in the portfolio selection process, such that the investor's individual preference on return, risk and liquidity are considered by the help of a genetic algorithm. A similar model is proposed by Huang and Qiao to enable the users to solve a problem with currently available programming tools. In addition, a method of obtaining the uncertainty distributions of the security returns is described based on experts' evaluations and presented illustratively. A TOPSIS compromised programming approach is designed by Liu et al. (2012) to transform a portfolio selection problems in fuzzy environment into single objective models. The model includes return, transaction cost, risk and skewness of the portfolio as decision parameters. Wu (2004) develops models with fuzzy space and special spaces such as Banach spaces. In particular, Wu and Ma (1991) provide a specific Banach space that the set of all fuzzy real numbers, which was introduced by Zadeh (1965) and plays the most fundamental role in the theory of fuzzy analysis, can be embedded into a Banach space C[0,1] X C[0,1], where C[0,1] is the set of all real-valued bounded functions on [0,1] such that it is left-continuous for any t e (0,1] and right-continuous at 0, and has a right limit for any t e (0,1]. In 2011, Bhattacharyya and Kar extend the classical Mean-Variance portfolio selection model into Mean Variance Skewness model in fuzzy environment under the criteria on short and long term returns, liquidity and dividends. The embedding theorem is used to convert the fuzzy MVS model into crisp multi-objective constrained optimization problem. They proposed a convenient tool for deep research of fuzzy analysis. It seems therefore reasonable to think if the concept of Fuzzy optimization problems based on the embedding theorem and also Multiobjective fuzzy optimization for portfolio selection can be extended to probabilistic normed spaces and in that case enquire how the basic properties are affected. In this paper, the embedding theorem from the set of all fuzzy numbers into a Banach space C[0,1] x C[0,1], is extended to more general case, i.e., from fuzzy number space into a Fuzzy Banach space C(ü), where C(ü) is the set of all real-valued continuous functions on an open set fi, to propose a solution concept of fuzzy optimization problem which is obtained by applying the embedding function to the original fuzzy optimization problem. 2 Preliminaries For readers convenience, in this section we briefly recall some concepts and results from Menger probabilistic nor-med spaces theory used in the paper. Definition: A mapping 77 :91 [0,1] is called a fuzzy real number, whose a - level set is denoted by Vv^a, i.e., in^a = {t '■ ^7(0 ^ «}, if it satisfies two axioms: (^1) There exists t^ such that ri{Q = 1. (NT) For each a e(0,1]:[??]„ = 9? (/) satisfies the following axioms, where [||:«:||]„ = H;,!! Jc H;^] for xeX and a G (0,1]: _ {A)1 II X 11=0 if and only if x = 0, (A)2 II rx 11=1 r III jc II for all x|| x ||i, t >|| y ||i and s + t^\x + y H" then llx + jvlK^ + O^i^dUIK^XiblKO). Definition: Let X be a vector space. A fuzzy subset N of XxSR is called a fuzzy norm on X if the following conditions: N1) N (x, t) = 0; V^ G 91 with t < 0, N2) N (x, t) = 1; V^ G 9?, ^ > 0 iff x = 0, N3) N{cx,t) = N{x, —); Vt(=m,t>0 and c 4 0, N4) iV(x + ;;,^ + .s)>mm{Ar(x,j),A^(;;,0}; for all x,y G X for all ^ g 91, N5) N (x,.) is a non -decreasing function on 91, and lim^-^oo A''(x,0 = 1. The pair (X, N) is said to be a fuzzy normed space. Definition: Let X and Y be topological spaces. An embedding function of X into Y is a function e : X ^ Y which is a homeomorphism when considered as a function from X onto e(X). A function e : X ^ Y is an embedding function if and only if it is continuous and one-to-one and for every open set V in X there exists an open subset W of Y such that e(V) is the intersection of W and Y. 3 Main results Theorem: Let (X N1, *) and (Y, N2, *) be two fuzzy normed spaces. Let (x,y)eXxY,t <= 9?, and N{{x,y),t) = mm{N,{x,t),N^{y,t)}. Then (X xY, N, *) is a fuzzy normed space on X xY. Let (X ,||.|| and {Y,\\.\\ be two fuzzy normed spaces by the above definition, where R^ (x, y) < max(x, y), and R2 (x, y) < max(x, >'). Then (Xx 7,11.11,!,,./?) is a fuzzy normed space where R = max and L = 0, 1, max{||x II (0,11;^ 11(0}, t e [min{|| x |f, || lr},max{|| x || ||-}], otherwise. By applying the induction method, we conclude that the Cartesian product of fuzzy normed spaces, Xj xXj x....xX^ is also fuzzy normed space. We have also same result in Menger probabilistic spaces. Let (X,||. II) be a classical real normed space. Felbin and Samanta have been shown that classical real normed space can be considered as fuzzy normed linear spaces (Felbin's type and Samanta's type). In the following we bring an example of a fuzzy normed space which is not a real normed space in the classical sense. Therefore the spectrum of the category of fuzzy normed linear spaces is broader than the category of normed spaces. This is why the study of fuzzy normed linear spaces (Felbin's type and Samanta's type) is of great importance. Let fi be a nonempty open set in some euclidean space. It is well known that fi is the union of countably sets Kn 4 0, which can be chosen so that Kn lies in the interior of K^1 (n = 1, 2, 3, ...). The linear space C(fi), is the vector space of all complex valued continuous functions on Ü., topolo-gized by the family of non-decreasing classical seminorms Pnif) " sup{| fix) I ; X e K J. In the following results, we will prove that C(Q.) is fuzzy normable but it is not so in classical analysis, where Q e is an open subset. Theorem: The linear space C(fi) is fuzzy normable in general. For a e (0,1], there exists « g N such that ^^"-n. Let / e C(Q) define fä = sup{| /W I ; :«: e išTi} and /; = sup{| m I ; ^ 6 Then {[/;,/;] ; a e (0,1]} is a family of nested bounded closed intervals. We define the fuzzy norm map ||. || on C(fi) as: , ||/||(0 = sup{ae(0,l]; ^g[/;,/;]}. It is easy to see that for / e C(Q), || / || is a fuzzy real number. Now we show that (C(Q),||. ||, min, max) is a fuzzy normed space. Also by definition [0, tp„if). Pnif,t') = We have shown that that /?„(/, 0 is a fuzzy seminorm for all n&'M and P = is the separating family of seminorms on C(fi). According to the above theorem we can define a fuzzy norm on C(Ql) as Then, (C(fi), N) is a fuzzy normed space. But C(fi) is not normable in classical analysis, where fi is an open subset of 91" Furthermore, C(fi) x C(fi) is also a Fuzzy Banach space with the norm where (/, g) e C(n) x C{ü) and / e defined by Nüf, g), t) = rmn{N{f, t), N (g, 0}, and 1, max{||/||(0,||g||(0}, II 11(0 = ie[mm{||/||;,| otherwise. g|;},max{||/|i;,||g|i:}], Definition: [Wu and Ma (1991)] let n be a fuzzy number in 9?(/) and we write («) = fJä and rj^{a) = tj^ as the function of a e [0,1], then the function TT : 9?(/) C(n) X C(n) defined by ^ ('?"(«)> iß)) is injective. Now, we prove that each element in 9?(/) can be identified with an element {t]~{a),ri^{a)) in C(fi) x C(fi), where T]~{a) = rjl and {a) = T]^^ and this identification is isometric and isomorphic. An important problem in topology is embedding problem. Theorems asserting the embedding of a space into some other space which is more manageable than the original space are known as embedding theorems. Theorem: (Embedding Theorem). The function 71:9?(/) C(Q) X C(Q) be defined by 0.5, and (/"(«), /^(a)), if a < 0.5. Then, the following properties hold true: (Ž) 7C is injective. ill) (8)/0e(l„ ®f,)) = sn{f,) + tn{f,) for all e 91(7), 5 > 0 and t>0. m = NW,) - n{f,),t) = sup{a e (0,1], t e [/„",/;]}. That is to say, 9?(/) can be embedded into C(fi) x C(fi) isometrically and isomorphi-cally. Proof: (i): Let fj, f^ be two distinct fuzzy numbers such that ?r(/i) = ;r(/2 ). Then (/lä>/la) = (/2«'/2a), i.e. (/r(«), /,"(«)) = (/2"(«), flioc)). Then /i («) = fi («), and = /2" (a), because the two real open intervals are equal which contradicts our assumption and consequently the mapping n is injective. (ii): By the definition of fuzzy number and function of n we have: ;r((i,,j ®y;)e(i„ 0/2)) = ([(i^,, <8)/oe(i„ (8)/2)];,[(i,,j ®y;)e(i„ 0/2)]:) = ([(1« <8)/)]; ©[(i,j 00 (/ = 1,2,..,«). (1) A more approximative style to implement a numerical solution to a portfolio selection is described as an application such as in Eqn. (2) or in Eqn. (3). In the following section we present optimization models which illustrate the solution to multiobjective portfolio selection models in a fuzzy optimization environment. It maximize i=l and minimize i=l such that =1, jc, >0 (i = l,2,...,n); (2) i=l maximize Z^ = i=i and minimize Z^ + 2 ^ x,XjCov(r„rj) i=l J=1 ISlS/SB such tiiat jTx, =1, jc, > 0 (/ = (3) 1=1 4 FNLP technique for solution of Multiobjective Programming Problem (MONLP) Consider the following general Multiobjective Nonlinear Programming (MONLP) optimization problem: minimize (/i(x),/.(x),...,/^(x)f such that X e X = {xe R"; g/x) <0(J = 1,2,..., m)}, (4) Step 1: In order to solve the MONLP problem in (12) we solve the problem as only one objective while disregarding the other ones. The procedure is successively repeated to find the ideal solution. Step 2: Once all optimal solutions for each objective are solved, a pay-off matrix for each single objective can be obtained. The obtained pay-off matrix is described as follows: m AW f^ix') Mx) Mx') (5) Mx') f2(x') - fdx') Optimal solutions for each objective function f\{x),f2{x),...,f,^{x) are given as From this computation we derive the upper and lower bounds of each objective function f„{x) {n = 1,2,..., k). The upper and lower bounds are given in the following says: C/„=max{/„(xO, /„(X2), - Z„ =max{/„(x,), f„(x2), ••• (6) Step 3: Fuzzy set: characteristic function of crisp set to each member in X with : X-> [0,1]. The assigned values is called a membership function and the set A = {(x, (x)) :xeX}, defined by Mn (x) for xeX is called afuzzy set. Membership function, crisp problem the membership function yU^ and Vj. are used respectively to solve the maximization of objective functionf1(x) and minimization of objective function f2(x). We note: 1, _ 0, ifZ,(X)>C/„ iiZ,(X)>U„ if L,a. W2 o Z"-z v v Z"-z! n ^JC; =1, Oa. V o >a (8) 1=1 5 Numerical Illustration This section gives an illustrative example to present optimal solutions to MONLP models. We selected six stock exchange shares which are traded in the Frankfurt DAX stock exchange market. The daily data ranges between January 2011 and January 2014. We selected each share from different sectors to account for alternative portfolio investments. Table 1 shows expected return and variance of the alternative shares. The companies are as follows: Deutsche Bank (DB), Daimler AG (DM), Henkel AG (HK), E.ON. (EON), BASF AG (BASF), Allianz AG (AL). The covariance matrix for the selected data sample is given in Table 2. In Table 3, the pay-off matrix indicates the optimal results of each single objective. Weighted Portfolio Selection: Table 4 shows the optimal solution values according the relative investor preferences. Finally, we derive the Fuzzy weighted model solution in Table 5. 6 Conclusion The optimal solution of the crisp optimization problem deduced from the fuzzy optimization problem by using embedding theorem is an optimal solution of the original fuzzy optimization problem under the set of core values of fuzzy real numbers. In a portfolio selection problem, the expected return, risk, liquidity cannot be predicted accurately. So the investor generally makes his portfolio choice according to his knowledge and his economic wisdom. Thus, deterministic portfolio selection is not a sensible option for the investor. Because of the existence of several non-stochastic factors in a stock market, fuzzy portfolio selection models have been proposed by model within fuzzy Table 1: Expectation and variance for selected stocks (in growth). DB DM HK EON BASF AL Expected Return 1.00 1.00 1.00 0.99 1.00 1.00 Variance 0.00061 0.000395683 0.000181948 0.000348582 0.000289541 0.000360242 Table 2: Covariance matrix. DB DM HK EON BASF AL DB 0.22349517 0.223058336 0.223346256 0.222815933 0.222994258 0.22296937 DM 0.223058336 0.223449288 0.223118822 0.222894143 0.223114491 0.223061775 HK 0.223346256 0.223118822 0.223689574 0.222889422 0.223063648 0.223015952 EON 0.222815933 0.222894143 0.222889422 0.222987418 0.222826304 0.222803293 BASF 0.222994258 0.223114491 0.223063648 0.222826304 0.223347778 0.222988255 AL 0.22296937 0.223061775 0.223015952 0.222803293 0.222988255 0.222985648 Organizacija, Volume 47 Research papers Number 2, May 2014 Table 3: Pay-off matrix signifying optima. Zr ZVar (DB,DM,HK,EON,BASF,AL)1 1.000994 0.1885714E-03 (DB,DM,HK,EON,BASF,AL)2 0.1885714E-03 1.000994 Note. The model is solved as in Step 2. The optimal values are obtained by iteratively solving and combining the single objective functions Zr and ZVar. Table 4: Relative preferences of the investors. Case W1 W2 SOLRETURN SOLVAR ALPHA 1 0.5 0.5 1.001174 0.000000 0.5000942 2 0.6 0.4 0.6675093 0.000000 0.4000754 3 0.4 0.6 1.501671 0.000000 0.6001131 Note.The abbreviations are as follows: w1, weight for return maximizing objective, w2, weight for variance minizing objective, SOLRETURN, solution value for return objective, SOLVAR, solution value for variance objective, alpha, solution value for final multiob-jective optimal solution. Table 5: Optimal solutions in the fuzzy weighted model. Case FW1 FW2 SOLRETURN SOLVAR ALPHA W1 W2 1 [0.4, 0.5] [0.6, 0.7] 1.667149 0.000000 0.7001319 0.5000000 0.7000000 2 [0.6, 0.7] [0.4, 0.5] 1.261565 0.000000 0.5000942 0.7000000 0.5000942 3 [0.5, 0.6] [0.7, 0.8] 1.470387 0.000000 0.8001507 0.6000000 0.8000000 4 [0.7, 0.8] [0.5, 0.6] 1.168285 0.000000 0.6001131 0.8000000 0.6000000 Note. See Table 4. FW1 and FW2 denote the fuzzy weights. norm. This paper extends the classical Banach spaces into fuzzy Banach and Menger probablistic Banach spaces model in fuzzy environment. This embedding theorem can be used for multiobjective decision making and has successfully been applied to optimization problems. We tried out various scenarios for portfolio selection which are pointing out different investor preferences. In Case 1 (See Table 4), the investor treats both objectives equally. In Case 2, the investor put more weight on portfolio return. In Case 3, the investor prefers to put more weight on the portfolio variance. We observe that different investor preferences determine the optimal solution to multiobjective fuzzy portfolio selection models according to alternative scenarios. Literature Bag, T., & Samanta, T. K. (2003). Finite dimensional fuzzy normed linear spaces. J. Fuzzy Math. 11(3), 687-705. Bag, T., & Samanta, T. K. (2008). A comparative study of fuzzy norms on a linear space. 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Math., 2(3), 1000e131, http://dx.doi.org/10.4172/2168-9679.1000e131 Wu C. X. & Ma M. (1991). Embedding Problem of Fuzzy Number Space: Part I, Fuzzy Sets and Systems, 44, 33-38. Wu, H.-C. (2004). Evaluate Fuzzy Optimization Problems Based on Biobjective Programming Problems, Computers and Mathematics with Applications 47, 893-902, http://dx.doi. org/10.1016/S0898-1221(04)90073-9 Zadeh L.A. (1965). Fuzzy sets. Information and Control, 8, 338353, http://dx.doi.org/10.1016/S0019-9958(65)90241-X Farnaz Solatikia is a Ph.D. student and Teaching Assistant in at the Department of Engineering Science and Research Assistant in Graduate School of Applied Mathematics in METU, Ankara. She has specialized on applied mathematics in fuzzy environment. Farnaz has received MSc. in Mathematics, on the Faculty of Basic Sciences. Her research interests include Fuzzy Mathematics, Functional Analysis, portfolio optimization, Applied Probability, and differential equation models. She has some publications in journals and conferences. Erdem Kilic has a Ph.D. in financial economics with emphasis on financial econometrics and financial modeling. He is an assistant professor at the Department of Economics, MEF University in Istanbul. His main research interests include financial economics and stochastic models in finance. Recently, he has been focusing on optimal contracts under asymmetric information, multiobjective portfolio selection models, and effects of consumer confidence dynamics on business activity. Gerhard-Wilhelm Weber is a professor at Institute of Applied Mathematics, METU, Ankara, Turkey. His research in on optimization and control, OR, financial mathematics, life and human sciences, data mining and inverse problems. G.-W. Weber received Diploma and Doctorate in Mathematics and Economics/BA, at RWTH Aachen, and Habilitation at TU Darmstadt. He held Professorships by proxy at University of Cologne, and TU Chemitz (Germany); he has several international affiliations, memberships and honorary positions, and is »Advisor to EURO Conferences«. Mehka optimizacija za izbiro portfelja na osnovi vstavljenega (vgrajenega) izreka v mehko normiran linearni prostor Ozadje: Članek posploši rezultate problema vgrajenega mehkega številskega prostora in njegovih razširitev v mehki Banachov prostor , kjer je množica vseh realnih kontinuirnih funkcij na odprti množici Q. Cilji: Poglavitna ideja v ozadju našega pristopa je izrabiti prednost medsebojnega vpliva mehkih normiranih prostorov in normiranih prostorov na način, da dobimo ekvivalenten stohastičen program. Tako se laže izognemo tveganju zaradi prevelikega poenostavljanja realnosti. Metoda: vgrajeni izrek pokaže, da množico vseh mehkih števil lahko vgradimo v mehki Banach-ov prostor. Izhajajoč iz tega izreka predlagamo rešitev koncepta mehkega optimizacijske problema, ki se pojavi, kadar uporabimo vgrajeno funkcijo na prvotnem mehkem optimizacijskem problemu. Rezultati: Predlagano metodo smo uporabili, da smo razširili klasičen model (srednja varianca) za izbiro portfeja na model v mehkem okolju (srednja varianca z nesimetrično porazdelitvijo) ob kriteriju dolgoročnih in kratkoročnih dobičkov na vlaganja, likvidnosti in dividend. Zaključek: Problem zabrisane optimizacije je mogoče pretvoriti v problem večkriterijske optimizacije, ki ga je mogoče rešiti z uporabo interaktivnega mehkega postopka odločanja. Investitorjeve preference določajo optimalno večkriterijsko rešitev glede na alternativne scenarije. Ključne besede: vgrajeni problem, Mehka optimizacija, Mehki Banach-ov prostor, izbira portfelja