# Introduction o satisfy rapidly changing global market and requirements of customer demand, systems needs to be designed to increase flexibility. Flexible manufacturing is the answer to the problem. FMS are as flexible as job shop and as efficient as production lines. Thus FMS are complex and combinational problem, where arises a wide range of problems with its exploration. Prior to start of manufacturing, production planning problems is one among them. FMS planning problems is to decide which cutting tools are to be placed in which tool magazine, to decide when and which part to be produced and in what quantity, how pooling of the machines and tools has to be done, number and types of fixtures and pallets required and available, number and type of cutting tools available and required, type of operations that can be performed etc. These decisions are to be made before the start of manufacturing. The scheduling problem needs next to be addressed. The five production planning problems mentioned by Kathryn E. Stecke (Stecke, 1983a(Stecke, , 1983b) ) needs to be solved before solving scheduling problem. Solution of production planning problem is the prerequisite to solve the scheduling problem. Scheduling is the time table for the machines set up for prescribed production target. Production planning problem needs to be solved to reach the shop floor and scheduling need to be done for actual production to begun. Depending on the type of the manufacturing problem objectives are defined for problem formulation and optimal solution. The type and number of objective function depends on the type and nature of a particular manufacturing system. One or more objective may be desirable at one or more stage of FMS life cycle, i.e. from FMS conception, design, to scheduling. For handling large number of objectives the weightage factor for each objective needs to be defined to solve the problem. Various modelling techniques for different objectives have been identified and different solution techniques were targeted in the literature. # II. Literature Review of Modelling for fms Loading Problem A model is a representation of the construction and working of some system of interest. A model is similar to but simpler than the system it represents. A model enables the analyst to predict the effect of changes to the system. A model should be a close approximation to the real system and should incorporate most of its salient features and, it should not be so complex to understand and experiment with. A good model is a judicious trade-off between realism and simplicity. Simulation practitioners recommends for increasing the complexity of a model iteratively. An important issue in modelling is model validity. According to Maria model validation techniques include simulating the model under known input conditions and comparing model output with system output (Maria, 1997). Mathematical programming models, Heuristic approaches, Queuing network models, Simulation models etc. have been utilized for modelling various types of complex problems of FMS's. Different modelling methods and approaches used for modelling FMS's, particularly the loading problem of FMS's have been identified and classified pearly reviewed as under. a) Artificial Intelligence (AI) AI covers techniques like fuzzy logic, neural networks, and immune algorithms. AI is potentially suitable for complex and ill-defined problem (Kempf, 1985) (Lu, 1986). Loading problems in FMS has been modelled with fuzzy logic by Vidyarthi and Tiwari in 2001 (Vidyarthi & Tiwari, 2001) # b) Branch and Backtrack Approach Branch and backtrack and Heuristic procedure for modelling the loading problem has been used by Shankar and Srinivasulu in 1989 (Shankar & Srinivasulu, 1989). # c) Branch and Bound Approach The method was first described by Land and Doig in 1960 (Land & Doig, 1960). Branch and bound algorithm works by enumerating possible combinations of the variables in a branch and bound tree. A few integer variables are fixed to have zero or one value and others are allowed to have any value in the range between zero and one. The root of the tree is the original problem. A leaf node is selected from the tree and the algorithm is solved. In each iteration the descendents of feasible solutions are selected for further branching, and descendents of infeasible solutions are ignored. Branch and bound approach for formulation of loading problem of FMS has been discussed by # d) Heuristic Approaches Heuristics was the name of a certain branch of study, not very clearly circumscribed, belonging to logic, or to philosophy or to psychology often outlined, seldom presented in detail. The aim of heuristic is to study the methods and rules of discovery and invention. A few traces of such study may be found in the commentators of Euclid; a passage of Pappus is particularly interesting in this respect. The most famous attempts to build up a system of heuristic are due to Descartes and to Leibnitz, both great mathematicians and philosophers. Bernard Bolzano presented a notable detailed account of heuristic. The present booklet is an attempt to revive heuristic in a modern and modest form. Heuristic reasoning is reasoning not regarded as final and strict but as provisional and plausible only, whose purpose is to discover the solution of the present problem. We shall attain complete certainty when we shall have obtained the complete solution, but before obtaining certainty we must often be satisfied with a more or less plausible guess. We may need the provisional before we attain the final. We need heuristic reasoning when we construct a strict proof as we need scaffolding when we erect a building. Heuristic reasoning is often based on induction, or on analogy. Provisional, merely plausible heuristic reasoning is important in discovering the solution, but you should not take it for a proof; you must guess, but also examine your guess (Polya, 1945). Heuristic is a program, rule, piece of knowledge, etc., which one is not entirely confident to be useful in providing a practical solution, but has reason to believe to be useful, and which is added to a problem-solving system in expectation that an average the performance will improve (Romanycia & Pelletier, 1985). Heuristics are defined as the set of rules that provides optimal or non-optimal solution to the problem with less computational work (Greene & Sadowski, 1986). For different manufacturing enterprises a wide range of heuristics procedures have been developed. Heuristics for FMS in 1987 ( (Werra, 1987), and Petri net modelling combined with heuristic for FMS in 1994 (D. Y. Lee & DiCesare, 1994) has been developed. Heuristic model for the FMS capacity planning problem was presented in 1989 (Mazzola, 1989). The loading problems of FMS has been modelled with simple heuristics by Stecke and Talbot in 1983 (Stecke & Talbot, 1983) # e) Hierarchical Model Hierarchy modelling method is amongst the oldest modelling methods, dating from 1960's. This method processes data efficiently at faster rate but it is less flexible for optimization. The system is classified according to its hierarchy and its network tree is formulated. All links from one to many networks, from parent to child are specified. The system at higher level is parent to its lower level hierarchy. Modelling (Mazzola, 1989). # f) Markov Chains A Markov chain is a model consisting of a group of states and specified transitions between the states. A Markov chain can have a finite or infinite number of states. In a discrete time Markov chain (DTMC) each state change takes place at a fixed decision point and the time between changes is constant. In a continuous time Markov chain (CTMC), changes can happen at any instant. Transitions in a Markov chain depend on only the current state, and not on any history of previous states. Markov chains have been used to model FMS by Vishwanadham et al. in 1992 (Vishwanadham, Narahari, & Johnson, 1992) and loading problems of FMS by Aldaihani and Savsar in 2005 (Aldaihani & Savsar, 2005). # g) Mathematical Modelling Mathematics has been the language of science. Mathematics is used to solve many real-world problems of industry, physical sciences, economics, social and human sciences, engineering and technology (Stecke, 2005a). A mathematical model can be deterministic (input and output variables are fixed values) or stochastic (at least one of the input or output variables is probabilistic); static (time is not taken into account) or dynamic (time-varying interactions among variables are taken into account). In a mathematical model usually, some of the decision variables are restricted to integer values and some are continuous. Usually the optimization problems are formulated with zero-ones to encode choices from a small set of available options to a decision, usually in binary form of zero and one. Use of mathematics and simple mathematical models to solve problems in industry were discussed in detail by Stecke in 2005 (Stecke, 2005b). Mathematical programming models have been applied widely to solve the production planning problems. Mathematical programming requires high degree of accuracy and the solution approach requires efficient computational help. Integer programming (IP), mixed integer programming (MIP) and linear integer programming (LIP) has been widely utilized for mathematical modelling. Stecke applied 0-1 nonlinear MIP for formulation of mathematical model of grouping and loading problems during 1981-83 (Stecke, 1981) (Stecke, 1982) (Stecke, 1983b) and mathematical program for FMS in 1983 (Stecke, 1983b (Hwang, 1986). Equivalent IP formulation for the process planning problem of FMS was carried out by Kusiak and Finke in 1988 (Kusiak & Finke, 1988). Kimemia in 1982 (Kimemia, 1982) and Kimemia and Gershwin in 1983 (Kimemia & Gershwin, 1983) used dynamic programming; Kimemia in 1982 (Kimemia, 1982), Kusiak in 1983(Kusiak, 1983) # h) Multi-Criterion Programming The loading problem of FMS has been formulated with multi-criterion programming model by Kumar et al. in 1987 (Kumar P. et al., 1987). # i) Network Modelling Network modelling has a wide range of applications. The manufacturing processes have also been be modelled as queueing networks, both as open or close networks. QN models are built in an aggregate way thus the models work well at the higher and more aggregate levels of a hierarchy of planning (Buzacott & Shanthikumar, 1980). Because of dynamic operations at lower levels, QN models are quite impractical at lower level of hierarchy. Also the specific distributions may not accurately reflect the true operating characteristics of the particular FMS. The queueing network modelling can be closed (CQN) and open (OQN) type. The difference between CQN and OQN is that CQN contains fixed number of parts with no external arrivals or departures. For analysis of the queueing network model Buzen's algorithm and mean value analysis were widely used. FMS has been modelled with CQN by Solberg in 1977 (Solberg, 1977), 1979 (Solberg, 1979) and 1980 (Solberg, 1980) # k) Petri Nets A Petri net has its origin from the dissertation of Carl Adam Petri, submitted in 1962 (Petri, 1962), to the faculty of Mathematics and Physics at the Technical University of Darmastadt, West Germany. The English translation of the report is also available in 1966 (Petri, 1966) # l) Sequential Approach The loading problem of FMS has been modelled with two-stage sequential approach by Liang in 1994 (Liang, 1993) and Ming in 1994 (Ming, 1994), and sequential approach by Liang and Dutta in 2009 (Liang & Dutta, 2009). The sequential modelled FMS problems have been solved with application of Lagrangian relaxation approach by Liang and Dutta in 2009 (Liang & Dutta, 2009). # m) Simulation Models Simulation is a descriptive modelling technique through computer based programmes for analysis of the problems and solutions. FMS problems are very complex in nature, so simulation models are widely used to solve FMS problems because of its descriptive nature. Cost and computational time increases with increase in complexity of the problems. A virtual manufacturing system mode has been developed for flexible manufacturing cells using objectoriented paradigm, and implemented with QUEST/IGRIP software by Kim and Choi in 2000 (S. Kim & Choi, 2000). Computer simulation package Simfactory II.5 has been used for modelling loading problem of FMS by Gupta in 1999 (Gupta, 1999). # n) Unit Operation Approach Unit operation has been used to model Block Angular Structures of loading problems by Kouvelis and Lee in 1991 (Kouvelis & Lee, 1991). Accuracy, results acceptability and adaptability, computational time and cost are the major factors for selection of the type of particularly loading problems of FMS. III. # Conclusion Hierarchical modelling, mathematical modelling, heuristic approaches, network modelling, simulation techniques, artificial intelligence (fuzzy logic, artificial immune algorithms and artificial neural network), Petri nets, Markov chains, branch and bound approach, multi-criterion programming model, branch and backtrack approach, sequential approach, unit operation approach and perturbation approach have been discussed in the literature for modelling loading problems of FMS's. Mathematical, heuristics, hierarchical approaches and network modelling are the widely used and accepted ones. Moreover the global optimization techniques have been widely used for solving the formulated problems. Solution of the mathematical models have been approached by branch and backtrack method, branch and bound algorithm, ant colony optimization (ACO), genetic algorithm (GA), harmony search algorithm (HS), simulated annealing (SA), particle swarm optimization (PSO), approximation technique, artificial immune algorithm, artificial neural network (ANN), box complex method, computer simulation package simfactory II.5, fuzzy-based solution methodology, GA-HS hybrid algorithm, GA-PSO hybrid heuristic technique, GA-SA hybrid algorithm, heuristic algorithms, meta hybrid PSO, min-max approach, sequential and simultaneous approaches, simulation, surrogate and lagrangian approaches, TS-SA hybrid algorithm and -constraint method. Heuristics solutions do not assure optimal solution (Manoj Kumar Tiwari, Kumar, Kumar, Prakash, & , GA-based heuristics for the loading problem lead to constraint violations and large number of generations (A. Kumar et al., 2006) and PSO avoids premature convergence (Biswas & Mahapatra, 2007). Because of less computational requirements, easy and fast convergence, better ease of apply, less time requirements are some of the factors attracting the researchers to use global optimization techniques for solving the mathematical or other model of the loading problems and other problems and FMS's. The authors after spending a lot of time on analysing and studying the research papers, books, Ph.D. thesis and other relevant materials suggests integer programming for modelling the loading problems and PSO for solution of the model. To analyse the system performance and to provide insight of how the system behaves, and how system component behaves, and to identify the key factors and parameters affecting the system, modelling and simulation of the physical system is the only best solution. Various types of results, graphs, plots etc can be generated for useful analysis of the system. The key to be remembered is that the validity and accuracy of the result will depend on the model developed, and the information induced in the model (value of parameters and key variables). It is the human who developed the model and it is him only to validate and validate the results. The software or model will give the results in the type the user wants. Validation, accuracy and acceptance of the results depend on the user. The modelling simulation and analysis can be expensive and time consuming to develop and run for desired accurate and acceptable results and outputs. An ideal model should be least expensive which should require least computational time. A research work is required to compare the various modelling techniques on basis of certain parameters, which will help the industry and academicians in selection of the type of modelling techniques under certain parameters and constraints. The authors are working on this research. ![, Stecke and Talbot (Stecke & Talbot, 1985), Ammons et al. (Ammons, Lofgren, & A e XV Issue I Version I A Review of Modelling Techniques for Loading Problems in Flexible Manufacturing SystemMcGinnis, 1985) and, Shankar and Tzen(Shankar & Tzen, 1985) in 1985, Rajagopalan in 1986(Rajagopalan, ](image-2.png "") Abazari et al. in 2012 (Abazari, Solimanpur, &Sattari,2012)discussedlinearmathematicalprogramming for the loading problems.MIP is utilized by Greene and Sadowski in 1986(Greene & Sadowski, 1986), Liang and Dutt in 1990(Liang & Dutt, 1990), Henery et al. in 1990 (Henery C.Co, Biermann, & Chen, 1990), Guerrero in 1999(Guerrero, 1999), Lee and Kim in 2000 (D.-H. Lee & Kim,2000) Kumar and Shanker in 2000 (N. Kumar &Shanker, 2000), Kumar and Shanker in 2001 (N. Kumar& Shanker, 2001), Yang and Wu in 2002 (Yang & Wu,2002), Tadeusz in 2004 (Tadeusz, 2004), Bilgin andAzizoglu in 2006 (Bilgin & Azizoglu, 2006), Murat andErol in 2012 (Murat & Erol, 2012) and Yusof et al. in 2012(Yusof et al., 2012) for loading problems of FMS.Sawik in 2000 (Sawik, 2000) and Dobson and Nambimadom in 2001 (Dobson & Nambimadom, 2001) adopted IP0-1 Linear MIP is utilized by Chakravarty and Schtub in 1984 (Chakravarty & Schtub, 1984), Co in 1984 (H. C. Co, 1984),formulation; Taboun & Ulger in 1992 (Taboun & Ulger,1992), Swarnkar & Tiwari in 2004 (Swarnkar & Tiwari,2004) and Sujono & Lashkari in 2007 (Sujono &Lashkari, 2007) utilized 0-1 IP formulation; and Jahromi& Tavakkoli-Moghaddam in 2012 (Jahromi & Tavakkoli-Moghaddam, 2012) discussed 0-1 LIP formulation formodelling the loading problems of FMS.Sarin and Chen in 1987 (Sarin & Chen, 1987),Rajamani and Adil in 1996 (Rajamani & Adil, 1996),Ozdamarl and Barbarosoglu in 1999 (Ozdamarl &Barbarosoglu, 1999), Chen and Ho in 2005 (Chen & Ho,2005), Nagarjuna et al. in 2006 (Nagarjuna, Mahesh, &Rajagopal, 2006), Goswami and Tiwari in 2006(Goswami & Tiwari, 2006), Kumar et al. in 2006 (A.Kumar, Prakash, Tiwari, Shankar, & Baveja, 2006),Biswas and Mahapatra in 2007 (Biswas & Mahapatra,2007) and 2008(Biswas & Mahapatra, 2008),Ponnambalam and Kiat in 2008 (Ponnambalam & Kiat,2008), Yogeswaran et al. in 2009(Yogeswaran,Ponnambalam, & Tiwari, 2009), Yusof et al. in 2011(Yusof, Budiarto, & Deris, 2011), Mgwatu in 2011(Mgwatu, 2011), Yusof et al. in 2011 (Yusof, Budiarto, &Venkat, 2011), Kumar et al. 2012 (V. M. Kumar, Murthy,& Chandrashekara, 2012), Yaqoub and Abdulghafour in2012 (Yaqoub & Abdulghafour, 2012), Yusof et al. in2012 (Yusof, Budiarto, & Deris, 2012) and Mahmudy etal. in 2012 (Mahmudy, Marian, & Luong, 2012) utilizedmathematical modelling for loading problems of FMS.Mathematical programming for loadingproblems of FMS is discussed by Kiran and Tansel in1985 (A. S. Kiran & Tansel, 1985), Kiran in 1986 (S.Kiran, 1986), Nayak and Acharya in 1998 (Nayak &Acharya, 1998), Turkcan et al. in 2007 (Turkcan, Akturk,& Storer, 2007), Ozpeynirci and Azizoglu in 2010 Year 2015FMS has also been modelled with advanced CQN by Seidmann et al. in 1987 (Seidmann,27Schweitzer, & Shalev-oren, 1987), with discrete generalized network by Ram et al. in 1990 (Ram, Sarin, & Chen, 1990) and with queueing networks by Narahari et al. in 1990 (Narahari, Viswanadham, Meenakshisundaram, & Rao, 1990) and Vishwanadham et al. in 1992 (Vishwanadham et al., 1992). Queueing model has been developed for the performance prediction of FMS's by Jain et al. in 2008 (Jain, Maheshwari, & Baghel, 2008). Modelling of the loading problems of FMS with single server CQN model by Stecke and Morin in 1984 (Stecke & Morin, 1984), CQN model by Stecke and Kim in 1987 (Stecke & Kim, 1987) and constrained network model by Bretthauer and Venkataramanan in 1990 (Bretthauer & Venkataramanan, 1990) were developed. Solution of the network modelled FMS problems has been achieved by surrogate and Lagrangian relaxation by Bretthauer and Venkataramanan in 1990 (Bretthauer & Venkataramanan, 1990). Mean value analysis (MVA) has a wide suitability for solving the network models. MVA is an iterative technique that avoids numerical instabilities, developed by Reiser and Lavenberg in 1978-80 as an efficient solution technique numerical problems raised with the convolution algorithms (Reiser & Lavenberg, 1978)(Reiser & Lavenberg, 1980). MVA is based on applications of Little's theorem (Little, 1961). The application of Mean-value analysis of queues (MVAQ) for FMS modelling has for queueing network models, to overcome theXV Issue I Version I Global Journal of Researches in Engineering ( ) Volume Abeen discussed by Suri and Hildebrant in 1984 (Suri &Hildebrant, 1984).j) Perturbation ApproachPerturbation for modelling the loading problemsof FMS has been used by Mukhopadhyay et al. in 1998(Mukhopadhyay, Singh, & Srivastava, 1998).© 2015 Global Journals Inc. (US) Perturbation modelled FMS loading problem has been solved with application of SA in by Mukhopadhyay et al. 1998 (Mukhopadhyay et al., 1998). .Petri nets are graphical and mathematicalmodelling tool used to model physical systems.Because of its graphic nature Petri nets are used asvisual communication tool similar to flow charts,networks and block diagrams. It is possible to set upstate equations, algebraic equations and othergoverning equations because of its mathematicalnature.FMS has been modelled with timed Petri nets by 1Year 201528I Version Ie XV Issue( ) Volum AGlobal Journal of Researches in Engineering13A Review of Modelling Techniques for Loading Problems in Flexible Manufacturing System A Review of Modelling Techniques for Loading Problems in Flexible Manufacturing System4. Al Titinchi, A. A., & Al Aubidy, K. M. (2004). Density of literature Modeling and analysis of an on-line FMS scheduler17. Chan, F. T. S., Swamkar, R., & Tiwari, M. K. (2004). A random search approach to the machine loadingcollected (over 1977-2013) International Journal ofproblem of an FMS. In Proceedings of the 2004& Information Sciences, 2(2), 74-83. 5. Ammons, J. C., Lofgren, C. B., & McGinnis, L. F. 12IEEE, Intemational Symposium on Intelligent Control (pp. 96-101). Taipei, Taiwan, September 2-4,2004.(1985). 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Selectingmanufacturing system. International Journal ofparts and loading FMS. In 1. Proceedings of the First ORSA/TIMS Conference on FMS. Ann Arbor.Production Engineering, 49, 600-610. doi:10.1016/j.cie. Research, 44(3), 569-588. 2005.09.002 doi:10.1080/00207540500266263A doiA © 2015 Global Journals Inc. (US) 1986), Kim and (Shankar & Tzen, 1985). ## Global Journals Inc. (US) Guidelines Handbook 2015 www.GlobalJournals.org * Kumar 2004, and Mandal et al. in 2010 (Mandal et al., 2010); with application of particle swarm optimization (PSO) by Biswas and Mahapatra in 2007 (Biswas & Mahapatra, 2007) and 2008 (Biswas & Mahapatra, 2008) and, Ponnambalam and Kiat Kumar Yusof, Budiarto, & Deris 1999. 1999. 2000. 2000. 2002. 2002. 2006. 2006. 2010. 2010. 2012. 2012. 2012. 1999. 2004. 2008. 2008. 2011. 1991. 1991. 1992 with application of Harmony Search algorithm (HS) by Yusof in 2011. with application of approximation technique by Wilson in 1992. and with application of iterative algorithms by Lee et al. in 1997 (D.-H. Lee et al., 1997) and Lee and Kim in 1998 (D.-H * TS-SA hybrid algorithm by Murat & Erol in 2012 (Murat & Erol, 2012), constraint method by Sujono and Lashkari &Lee Kim ; Yogeswaran The loading problem of FMS has also been solved by techniques like TS-SA hybrid algorithm by Swarnkar and Tiwari in 2004 (Swarnkar & Tiwari Kumar Sujono & Lashkari 1998. 2004. 2009. 2009. 2011. 2011. 2012. 2007. 2007. 2010 Sequential and simultaneous approaches by Turkcan et al. in 2007 (Turkcan et al., 2007) and artificial immune system (AIS) by Mandal. et al. in 2010 (Mandal et al. * A Review of Modelling Techniques for Loading Problems in Flexible Manufacturing System 1977 1978 1979 1980 1981 1982 1983 1984 1985 1986 1987 1988 1989 1990 1991 1992 1993 1994 1995 1996 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 * References Références Referencias * Optimum loading of machines in a flexible manufacturing system using a mixed-integer linear mathematical programming model and genetic algorithm AMAbazari MSolimanpur HSattari 10.1016/j.cie.2011.10.013 Computers & Industrial Engineering 62 2 2012 * A loop layout design problem for flexible manufacturing systems PAfentakis International Journal of Flexible Manufacturing Systems 1 1989 * A stochastic model for the analysis of a two-machine flexible manufacturing cell MMAldaihani MSavsar Computers & Industrial 2005 * Heuristic approaches for loading problems in flexible manufacturing systems Y.-DKim CAYano 87- 21 1987 Technical report * A new branch and bond algo for loading problems in flexible manufacting system Y.-DKim CAYano 1989 * A branch and bound approach for the loading problem in flexible manufacturing systems: an unbalancing case KimYeong -Dae YanoCandace A 87-18 1987 Technical Report * Hierarchical control of production in FMS. 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