The one-dimensional cutting stock problem with usable leftover – A heuristic approach (original) (raw)
Related papers
The one-dimensional cutting stock problem with usable leftovers – A survey
European Journal of Operational Research, 2014
In this work we consider a one-dimensional cutting stock problem in which the non-used material in the cutting patterns may be used in the future, if large enough. This feature introduces difficulties in comparing solutions of the cutting problem, for example, up to what extent a minimum leftover solution is the most interesting one when the leftover may be used. Some desirable characteristics of good solutions are defined and classical heuristic methods are modified, so that cutting patterns with undesirable leftover (not large enough to be used, nor too small to be acceptable waste) are redesigned. The performance of the modified heuristics is observed by solving instances from the literature, practical instances and randomly generated instances.
Resolution of the unidimensional cutting stock problem with usable leftover
2007
In this work we consider a one-dimentional cutting stock problem in which the non-used material in the cutting patterns may be used in the future, if large enough. This feature introduces difficulties in comparing solutions of the cutting problem, for example, up to what extent a minimum leftover solution is the most interesting one when the leftover may be used? Some desirable characteristics of good solutions are defined and classical heuristic methods are modified, so that cutting patterns with undesirable leftover (not large enough to be used, nor too small to be acceptable waste) are redesigned. The performance of the modified heuristics are observed by solving instances from the literature and practical instances.
The usable leftover one-dimensional cutting stock problem-a priority-in-use heuristic
International Transactions in Operational Research, 2013
We consider a one-dimensional cutting stock problem in which the material not used in the cutting patterns, if large enough, is kept for use in the future. Moreover, it is assumed that leftovers should not remain in stock for a long time, hence, such leftovers have priority-in-use compared to standard objects (objects bought by the industry) in stock. A heuristic procedure is proposed for this problem, and its performance is analyzed by solving randomly generated dynamic instances where successive problems are solved in a time horizon. For each period, new demands arise and a new problem is solved on the basis of the information about the stock of the previous periods (remaining standard objects in the stock) and usable leftovers generated during those previous periods. The computational experiments show that the solutions presented by the proposed heuristic are better than the solutions obtained by other heuristics from the literature.
A Tree-Based Heuristic for the One-Dimensional Cutting Stock Problem Optimization Using Leftovers
Materials
Cutting problems consist of cutting a set of objects available in stock in order to produce the desired items in specified quantities and sizes. The cutting process can generate leftovers (which can be reused in the case of new demand) or losses (which are discarded). This paper presents a tree-based heuristic method for minimizing the number of cut bars in the one-dimensional cutting process, satisfying the item demand in an unlimited bar quantity of just one type. The results of simulations are compared with the RGRL1 algorithm and with the limiting values for this considered type of problem. The results show that the proposed heuristic reduces processing time and the number of bars needed in the cutting process, while it provides a larger leftover (by grouping losses) for the one-dimensional cutting stock problem. The heuristic contributes to reduction in raw materials or manufacturing costs in industrial processes.
A New Heuristic Algorithm for the One-Dimensional Cutting Stock Problem
Applied and Computational Mathematics, 2010
This paper describes an attempt to solve the one-dimensional cutting stock problem heuristically by using dynamic programming used to solve subset-sum problem which is considered as a sub-problem. Thisway an optimal solution is found for the sub-problem, which yields solution for the original problem. Thus an economical gain is achieved by decreasing the rate of trim loss. Moreover the cutting-cost can be reduced by minimizing the number of different cutting-patterns by this algorithm. Toward this goal, a new mathematical model is proposed and a novel algorithm is developed. The proposed algorithm is coded with Delphi and then through computational experiments on real-life constrainted optimization problems, the results are compared with the others in the literature. The computational experiments show the efficiency of the algorithm.
One-dimensional cutting stock optimization with usable leftover: A case of low stock-to-order ratio
International Journal of Decision …, 2011
This paper describes a method for solving one-dimensional cutting stock problem with usable leftover (CSPUL) in cases where the ratio between the average stock and average order length is less than 3. The proposed method can solve general CSPUL where standard stock lengths, non-standard stock lengths, or a combination of both are cut in the exact required number of pieces. The solutions of sample problems are compared with other methods.
One Dimensional Cutting Stock Problem with Redevelopment of the Surplus Material
engopt.org
This work deals with the One Dimensional Cutting Stock Problem, in which a demand of a set of small pieces named items, gotten from large pieces named objects, has to be produced. It is desirable that the cutting layouts have a small waste or the remaining piece must be big enough to be reused in the future. This is an important problem, since even small improvements in the cutting layouts result in large savings of raw material and energy when the amount of produced material is huge. The Cutting Stock Problem is NPhard, so a heuristic combining the Modified First Fit Decreasing (FFD) method, an Integer Programming (IP) model and a Data Mining (DM) module is proposed to solve it. The FFD heuristic is used to produce an upper bound. With this upper bound the IP model becomes able to be solved more quickly. Then, the DM module is proposed to extract common parts from the best current solutions obtained from several iterations of the IP model. Finally the extracted common parts are used to guide the search for better solutions in less computational time. Computational results have shown that the proposed method is able to generate good quality and competitive solutions when compared to the ones presented in the related literature.
A New Mathematical Model for the Cutting Stock/Leftover Problem
Pesquisa Operacional, 2015
This paper addresses the cutting stock/leftover problem (CSLP), which differs from the ordinary cutting stock problem (CSP) by retaining stock leftovers that can be cut in the future to meet new demands. Therefore, leftovers are not considered waste in the current period. A new mathematical model for the CSLP is presented to capture a well-used strategy in the practice of cutting, which consists of partially cutting the objects in stock, and keeping the leftovers to be cut in the next periods. Computational experiments were made for the one-dimensional case, although other dimensions can be considered straightforward.
Combinatorial optimization modeling approach for one-dimensional cutting stock problems
modeling approach to one-dimensional cutting stock problem. The investigated problem seeks to determine the optimal length of the blanks and the optimum cutting pattern of each blank to meet the requirement for a given number of elements with different lengths. Blanks of particular type are offered with equal size in large quantities and the goal is to find such optimal length of blanks that leads to minimal overall trim waste. To achieve that goal a combinatorial optimization approach is used for modeling of one-dimensional cutting stock problem. Numerical example of real-life problem is presented to illustrate the applicability of the proposed approach. It is shown that numerical example can be solved for reasonable time by Lingo Solver and MS Excel Solver.
An iterative sequential heuristic procedure to a real-life 1.5-dimensional cutting stock problem
European Journal of Operational Research, 2006
This paper addresses a real-life 1.5D cutting stock problem, which arises in a make-to-order plastic company. The problem is to choose a subset from the set of stock rectangles to be used for cutting into a number of smaller rectangular pieces so as to minimize total production cost and meet orders. The total production cost includes not only material wastage, as in traditional cutting stock problems, but also production time. A variety of factors are taken into account, like cutter knife changes, machine restrictions, due dates and other work in progress limitations. These restrictions make the combinatorial structure of the problem more complex. As a result, existing algorithms and mathematical models are no longer appropriate. Thus we developed a new 1.5D cutting stock model with multiple objectives and multi-constraints and solve this problem in an incomplete enumerative way. The computational results show that the solution procedure is easy to implement and works very well. Ó 2005 Published by Elsevier B.V.