Neutrosophic EOQ Model With Price Break - University Of New Mexico
Neutrosophic Sets and Systems, Vol. 19, 2018 24 University of New Mexico Neutrosophic EOQ Model with Price Break M. Mullai1 Assistant Professor of Mathematics, Alagappa University, Karaikudi, Tamilnadu, India. E-mail: mullaimalagappauniversity.ac.in R. Surya2 Department of Mathematics, Alagappa University, Karaikudi, Tamilnadu, India. E-mail: suryarrrm@gmail.com Abstract—Inventory control of an ideal resource is the most important one which fulfils various activities (functions) of an organisation. The supplier gives the discount for an item in the cost of units inorder to motivate the buyers (or) customers to purchase the large quantity of that item. These discounts take the form of price breaks where purchase cost is assumed to be constant. In this paper an EOQ model with price break in inventory model is developed to obtain its optimum solution by assuming neutrosophic demand and neutrosophic purchasing cost as triangular neutrosophic numbers. A numerical example is provided to illustrate the proposed model. Keywords: Price break, neutrosophic demand, neutrosophic purchase cost, neutrosophic sets, triangular neutrosophic number. 1 I NTRODUCTION by M. Mullai and S. Broumi[3]. In this paper, we introduce the neutroBai and Li[1] have discussed triangular and sophic inventory models with neutrosophic trapezoidal fuzzy numbers in inventory model price break to find the optimal solution of the for determining the optimal order quantity and model for the optimal order quantity. Also the the optimal cost. The quantity discount prob- neutrosophic inventory model under neutrolem has been analyzed from a buyers perspec- sophic demand and neutrosophic purchasing tive. Hadley and Whintin[2], Peterson and Sil- cost at which the quantity discount are offered ver[3], and Starr and Miller[6] considered vari- to be triangular neutrosophic number. Also the ous discount polices and demand assumptions. optimal order quantity for the neutrosophic toYang and Wee[7] developed an economic tal cost is determined by defining the accuracy ordering policy in the view of both the sup- function of triangular neutrosophic numbers. plier and the buyer. Prabjot Kaur and Mahuya Deb[5] developed an intuitionistic approach for price breaks in EOQ from buyer’s perspec- 2 N OTATIONS : tive. Smarandache[5] introduced neutrosophic QN Number of pieces per order set and neutrosophic logic by considering the non-standard analysis. Also, neutrosophic in- CN 0 Neutrosophic Ordering cost for each ventory model without shortages is introduced order M. Mullai, R. Surya: Neutrosophic EOQ Model with Price Break
25 Neutrosophic Sets and Systems, Vol. 19, 2018 QN P3N I N 2 CN h Neutrosophic Holding cost per unit per year N D units Neutrosophic Annual demand in )(D10N P QN P10N I N 2 , D2N P2N D30N C0N , D3 P30N 2 QN 00N N N 00N N D C Q P1 I )(D100N P100N 1QN 0 , D2N P2N 2 D00N C N QN P2N I N QN P300N I N , D300N P300N 3QN 0 ) 2 2 D2N C0N QN QN P30N I N 2 D2N C0N QN D10N C0N 0N 1 QN QN P2N I N 0N The defuzzified total neutrosophic cost using accuracy function is given by 3 N EUTROSOPHIC EOQ M ODEL W ITH D(TC)N P RICE B REAK : DN C N QN P1N I N 1 [(D1N P1N 1QN 0 ) 8 2 N CN N CN N P N IN D D Q 2 ) (D3N P3N 3QN 0 2(D2N P2N 2QN 0 2 N N N D00N C N Q P3 I QN P100N I N ) (D100N P100N 1QN 0 ) 2 2 N CN N P N IN D Q 2 2(D2N P2N 2QN 0 ) (D300N P300N 2 00N N N 00N N D3 C0 Q P3 I )] QN 2 The Neutrosophic inventory model with neutrosophic price break is introduced to find the optimal solutions for the optimal neutrosophic order quantity. Here we assume that there is no stock outs, no backlogs, replenishment is instantaneous, To find the minimum of D(TC)N by taking the neutrosophic ordering cost involved to N receive an order are known and constant and the derivative D(TC) and equating it to zero, purchasing values at which discounts are (i.e) 8Q12N [(D1N C0N 2D2N C0N D3N C0N ) offered as triangular neutrosophic numbers. 1 [(P1N I N (D100N C0N 2D2N C0N D300N C0N )] 16 Consider the following variables: 2P2N I N P3N I N ) (P100N I N 2P2N I N P300N I N )] DN : Neutrosophic yearly demand, 0, we r get 2[(D1N C0N 2D2N C0N D3N C0N ) (D100N C0N 2D2N C0N D300N C0N )] PN : Neutrosophic purchasing cost QN [(P N I N 2P N I N P N I N ) (P 00N I N 2P N I N P 00N I N )] 1 Let DN (D1N , D2N , D3N ) (D10N , D2N , D30N ) (D100N , D2N , D300N ) N P (P1N , P2N , P3N ) (P10N , P2N , P30N ) 2 3 1 2 3 Neutrosophic Price Break: (P100N , P2N , P300N ) S.No. Quantity Price Per Unit (Rs) 1 0 QN P1N 1 b 2 b QN P2N ( P1N ) 2 00N N 00N 0N N 0N N N N PN 1 (P11 , P12 , P13 ) (P11 , P12 , P13 ) (P11 , P12 , P13 ) 4 A LGORITHM F OR F INDING N EUTRO SOPHIC O PTIMAL Q UANTITY AND N EU are non negative triangular neutrosophic TROSOPHIC O PTIMAL C OST: 00N N 00N 0N N 0N N N N PN 2 (P21 , P22 , P23 ) (P21 , P22 , P23 ) (P21 , P22 , P23 ) numbers. Now, we introduce the neutrosophic inventory model under neutrosophic demand and neutrosophic purchasing cost at which the quantity discounts are offered. Total neutrosophic inventory cost is given by (TC)N DN P N DN C0N QN Step I: Consider the lowest price P2N and determine QN by using the economic order quantity 2 (EOQ)rformula: QN 2[(D1N C0N 2D2N C0N D3N C0N ) (D100N C0N 2D2N C0N D300N C0N )] [(P1N I N 2P2N I N P3N I N ) (P100N I N 2P2N I N P300N I N )] N If QN 2 lies in the range specified, b Q2 then is the EOQ .The defuzzified optimal total cost (T C)N associated with QN is calculated as follows: QN 2 QN P N I N 2 Then the total neutrosophic inventory cost is DN C N DN C N QN P1N I N , D2N P2N (TC)N (D1N P1N 1QN 0 2 N N N N N D2 C0 Q P2 I D3N C0N N N P , D N 3 3 Q 2 QN bP N I N (TC)N DN P2N b 0 2 2 by using the accuracy 00 (a1 2a2 a3 ) (a00 N 1 2a2 a3 ) A 8 M. Mullai, R. Surya: Neutrosophic EOQ Model with Price Break , function
26 Neutrosophic Sets and Systems, Vol. 19, 2018 TC(P1 800) Rs.296039 Step 2: (i) If QN 2 b, we cannot place an order at the lowest price P2N . N (ii) We calculate QN 1 with price P1 and the N corresponding total cost TC at Q . (iii) If (T C)N b (T C)N QN 1 , then EOQ is N N N Q Q1 , Otherwise Q b is the required EOQ. The EOQ in crisp, fuzzy and intuitionistic fuzzy sets are discussed detail in [5]. They are (i) Crisp: q 0 Q 2 2DC P2 I TC(b 100) Rs.224250, which is than the total cost corresponding to Q2 (ii) Fuzzy Case: e (300, 350, 400), Pe1 (750, 800, Given D 850) Pe2 (550, 600, 650),C0 Rs.1500,I 0.3 e 2 88.192 Q g T C(P1 800) Rs.297785.95 g T C (b 100) Rs.225500, which is lower than the total cost corresponding to Q2 . (ii) Fuzzy: q e Q2 2(D1 C0 2D2 C0 D3 C0 ) (iii) Intuitionistic Fuzzy Case: (iii) Intuitionistic fuzzy: q 2(D1 C0 4D2 C0 D3 C0 D10 C0 D30 C0 ) Q2 P1 I 4P2 I P3 I P 0 I P 0 I P 1 (750, 800, 850) (700, 800, 900) P1 I 2P2 I P3 I lower Given D (300, 350, 400) (250, 350, 450) 1 3 Using these formula, the numerical example for neutrosophic set is illustrated as follows. P 2 (550, 600, 650) (500, 600, 700), C0 Rs.1500, I 0.3 Q2 88.19 T C(P1 800) Rs.299660.85 5 N UMERICAL E XAMPLE : T C(b 100) Rs.227375, which is lower A manufacturing company issues the supply of than the total cost corresponding to Q2 . a special component which has the following (iv) Neutrosophic Case: price schedule: Given DN (300, 350, 400) (250, 350, 450) (150, 350, 550) 0 to 99 items: Rs.800 per unit 100 items and above: Rs.600 per unit The inventory holding costs are estimated to be Rs.30/- of the value of the inventory. The procurement ordering costs are estimated to be Rs.1500 per order. If the annual requirement of the special component is 350, then compute the economic order quantity for the procurement of these items. Solution: P1N (750, 800, 850) (700, 800, 900)(600, 800, 1000) P2N (550, 600, 650) (500, 600, 700)(400, 600, 800) N CN 0 Rs.1500, I 0.3 We calculate Q 2 price 600, r N Q 2 (i) Crisp Case: corresponding to the lowest 2[(D1N C0N 2D2N C0N D3N C0N ) (D100N C0N 2D2N C0N D300N C0N )] [(P1N I N 2P2N I N P3N I N ) (P100N I N 2P2N I N P300N I N )] 76.376, which is less than the price break point. Given D 350, P1 Rs.800, P2 Rs.600, C0 Rs.1500, I 0.3 Q 2 76 N Therefore, we have to determine the optimal total cost for the first price and the total cost at the price- break corresponding to the second price and compare the two. M. Mullai, R. Surya: Neutrosophic EOQ Model with Price Break
27 Neutrosophic Sets and Systems, Vol. 19, 2018 The defuzzified optimal total cost (T C)N associated with P1N is calculated as follows: (T C)N (P1N 800) 5 3.5 x 10 3 N N DN C0N QN 2 P1 I 2 QN 2 Rs.306664.13 331337.2 DN P1N 324354.86 2.5 316127.02 2 323115.96 299660.85 306664.13 1.5 (T C)N (b 100) DN P2N D N C0N b bP2N I 2 N 283181.28 1 0 which is lower than corresponding to QN 2 . the total 290198.96 274936.56 0.5 Rs.173812.5 281961.24 N Neutrosophic (TC) (p1) Intuitionistic (TC)(p1) cost S.No. 1 S.No. 2 S.No. 3 S.No. 4 S.No. 5 Figure 2. Analysis of first price between intuitionistic fuzzy set and neutrosophic set 6 S ENSITIVITY A NALYSIS 5 2.5 In this section, the analysis between intuitionistic set and neutrosophic set is tabulated and the results are compared graphically. x 10 S.No. 1 S.No. 2 S.No. 3 S.No. 4 S.No. 5 2 245825 187650 1.5 239675 183037.5 227375 173812.5 1 S.No. 1 2 3 4 5 Intuitionistic Demand (270,320,370) (220,320,420) (280,330,380) (230,330,430) (300,350,400) (250,350,450) (320,370,420) (270,370,470) (330,380,430) (280,380,480) Neutrosophic Demand (270,320,370) (220,320,420) (120,320,520) (280,330,380) (230,330,430) (130,330,530) (300,350,400) (250,350,450) (150,350,550) (320,370,420) (270,370,470) (170,370,570) (330,380,430) (280,380,480) (180,380,580) 90 164587.5 0 Intuitionistic (TC)(b) 159975 N Neutrosophic (TC) (b) S.No. 1 S.No. 2 S.No. 3 S.No. 4 S.No. 5 80 70 79.58 91.89 60 78.53 90.68 50 40 88.19 76.38 30 74.16 85.63 20 0 208925 Figure 3. Analysis of price break corresponding to second price between intuitionistic fuzzy set and neutrosophic set 100 10 215075 0.5 84.33 73.03 Intuitionistic (Q) N Neutrosophic (Q) Figure 1. Analysis of economic order quantity (EOQ) between intuitionistic fuzzy set and neutrosophic set Conclusion In this paper, EOQ model with price break in neutrosophic environment is introduced. An inventory model is developed for price breaks and its optimum solution is obtained by using triangular neutrosophic number. An algorithm for solving neutrosophic optimal quantity and neutrosophic optimal cost is also developed. This will be an advantage for the buyer who can easily decrease the bad cases and increase the better ones. Hence, the neutrosophic set gives the better solutions to the real world problems than fuzzy and intuitionistic fuzzy sets. In future, the various neutrosophic inventory models will be developed with various limitations such as lead time, backlogging, back order and deteriorating items, etc. M. Mullai, R. Surya: Neutrosophic EOQ Model with Price Break
28 Neutrosophic Sets and Systems, Vol. 19, 2018 R EFERENCES [1] S. B AI AND Y. L I ,Study of inventory management based on tri- [2] [3] [4] [5] [6] [7] [8] angular fuzzy numbers theory, IEEE, 978-1-4244-2013-1/08/ 2008. G. H ADLEY AND T. M. W HITIN ,Analysis of Inventory Systems, Prentice Hall, Inc, Englewood Cliffs,N.J 1963. M. M ULLAI AND S. B ROUMI , Neutrosophic Inventory Model without Shortages, Asian Journal of Mathematics and Computer Research, 23(4): 214-219, 2018. R. P ETERSON AND E. A. S ILVER ,Decisions Systems for Inventory Management and Production Planning, John Wiley and Sons, New York 1979. P RABJOT K AUR AND M AHUYA D EB ,An Intuitionistic Approach for Price Breaks in EOQ from Buyer’s Perspective, Applied Mathematical Sciences, Vol. 9, 2015, no. 71, 3511 - 3523 F. S MARANDACHE , Neutrosophic set - a generalization of the intuitionistic fuzzy set, Granular Computing, 2006 IEEE International Conference, 2006, pp. 38 – 42. K. M. S TARR AND D. W. M ILLER ,Inventory Control: Theory and Practice, Prentice Hall, Inc, Englewood Cliffs, N.J 1962. YANG, P., AND WEE, H.,Economic ordering policy of deteriorated item for vendor and buyer: an integrated approach.Production Planning and Control, 11, 2000, 474–480 [9] Abdel-Basset, M., Mohamed, M., Smarandache, F., & Chang, V. (2018). Neutrosophic Association Rule Mining Algorithm for Big Data Analysis. Symmetry, 10(4), 106. [10] Abdel-Basset, M., & Mohamed, M. (2018). The Role of Single Valued Neutrosophic Sets and Rough Sets in Smart City: Imperfect and Incomplete Information Systems. Measurement. Volume 124, August 2018, Pages 47-55 [11] Abdel-Basset, M., Gunasekaran, M., Mohamed, M., & Smarandache, F. A novel method for solving the fully neutrosophic linear programming problems. Neural Computing and Applications, 1-11. [12] Abdel-Basset, M., Manogaran, G., Gamal, A., & Smarandache, F. (2018). A hybrid approach of neutrosophic sets and DEMATEL method for developing supplier selection criteria. Design Automation for Embedded Systems, 1-22. [13] Abdel-Basset, M., Mohamed, M., & Chang, V. (2018). NMCDA: A framework for evaluating cloud computing services. Future Generation Computer Systems, 86, 12-29. Received : January 17, 2018. Accepted : March 5, 2018. M. Mullai, R. Surya: Neutrosophic EOQ Model with Price Break
76.376, which is less than the price break point. Therefore, we have to determine the optimal total cost for the first price and the total cost at the price- break corresponding to the second price and compare the two. 26 NeutrosophicSets and Systems,Vol. 19;2018 M. Mullai, R. Surya: Neutrosophic EOQ Model with Price Break
Laws of Classical Logic That Do Not Hold in The Interval Neutrosophic Logic 184 Modal Contexts 186 Neutrosophic Score Function 186 Applications. 187 Neutrosophic Lattices 188 Conclusion 191 CHAPTER XII Neutrosophic Predicate Logic 196 Neutrosophic Quantifiers 199 Neutrosophic Existential Quantifier. 199 Neutrosophic Universal Quantifier. 199
Content THEORY Definition of Neutrosophy A Short Historyyg of the Logics Introduction to Non-Standard Analysis Operations with Classical Sets Neutrosophic Logic (NL) Refined Neutrosophic Logic and Set Classical Mass and Neutrosophic Mass Differences between Neutrosophic Logic and Intuitionistic Fuzzy Logic Neutrosophic Logic generalizes many Logics
Neutrosophic Modal Logic Florentin Smarandache University of New Mexico, Mathematics & Science Department, 705 Gurley Ave., Gallup, NM 87301, USA. . modalities. It is an extension of neutrosophic predicate logic and of neutrosophic propositional logic. Applications of neutrosophic modal logic are to neutrosophic modal metaphysics. Similarly .
integer neutrosophic complex numbers, rational neutrosophic complex numbers and real neutrosophic complex numbers and derive interesting properties related with them. Throughout this chapter Z denotes the set of integers, Q the rationals and R the reals. I denotes the indeterminacy and I 2 I. Further i is the complex number and i 2 -1 or .
The Economic Order Quantity (EOQ) models have been the central part of supply chain for many years. The EOQ model is the building block of deterministic inventory models. For a complete review of EOQ models, we refer the readers to Choi (2014); For the treatment of EOQ models with general
13-13 Inventory Management Economic order quantity model Economic production model Quantity discount model How Much to Order: EOQ Models Skip 13-14 Inventory Management Basic EOQ Model The basic EOQ model is used to find a fixed order quantity that will minimize total annual inventory costs
on the implementation of fuzzy set theory in inventory management. [Chang et al., 1998] extended classical EOQ model with backorder by assuming backorder quantity as fuzzy number. [Yao et al., 2000] extended the classical EOQ model in fuzzy environment with the assumption that demand rate is fuzzy number.
To better understand the events that led to the American Revolution, we will have to travel back in time to the years between 1754 and 1763, when the British fought against the French in a different war on North American soil. This war, known as the French and Indian War, was part of a larger struggle in other countries for power and wealth. In this conflict, the British fought the French for .
