Search Results - "Multi-level programming problem"

An algorithm for multi-level programming problem using goal programming

Authors: R.D. Gupta S. R. Arora

Source: OPSEARCH. 45:1-11

Subject Terms: 0209 industrial biotechnology, 0211 other engineering and technologies, 02 engineering and technology

Access URL: https://link.springer.com/article/10.1007/BF03398801

TOPSIS Based Algorithm for Solving Multi-objective Multi-level Programming Problem with Fuzzy Parameters

Authors: Surapati Pramanik Partha P. Dey Florentin Smarandache

Subject Terms: applied_mathematics, 0202 electrical engineering, electronic engineering, information engineering, 02 engineering and technology

File Description: application/pdf

Access URL: https://www.preprints.org/manuscript/201802.0105/v1/download
https://www.preprints.org/manuscript/201802.0105/v1
http://www.preprints.org/manuscript/201802.0105/v1
https://www.preprints.org/manuscript/201802.0105/v1/download

An explicit solution to the multi-level programming problem

Authors: James E. Falk Jonathan F. Bard

Source: Computers & Operations Research. 9:77-100

Subject Terms: 0211 other engineering and technologies, 0202 electrical engineering, electronic engineering, information engineering, 02 engineering and technology

An Explicit Solution to the Multi-level Programming Problem.

Authors: GEORGE WASHINGTON UNIV WASHINGTON D C PROGRAM IN LOGISTICS Bard,Jonathan F Falk,James E

Source: DTIC AND NTIS

Index Terms: Numerical Mathematics, NONCONVEX PROGRAMMING, OPTIMIZATION, MINIMAX TECHNIQUE, Complementarity Problem, Two Person Games, Bilinear Programming, Kuhn-Tucker Theory, Branch and Bound Method, Trees(Mathematics), WUNR347020, Text

URL: https://apps.dtic.mil/docs/citations/ADA069310

A Linear Programming Approach for Linear Multi-Level Programming Problems

Authors: Sinha, S.

Source: The Journal of the Operational Research Society, 2004 Mar 01. 55(3), 312-316.

Access URL: https://www.jstor.org/stable/4102011

An algorithm for multi-level programming problem using goal programming.

Authors: Arora, S. Gupta, Ritu

Source: OPSEARCH; Mar2008, Vol. 45 Issue 1, p1-11, 11p

Three essays on multi-level optimization models and applications

Authors: Rahdar, Mohammad Lizhi Wang Guiping Hu et al.

Contributors: Rahdar, Mohammad Lizhi Wang Guiping Hu et al.

Subject Terms: Optimization, Algorithm design, Multi-level programming problem, Industrial Engineering, Operational Research, bilevel programming problem, 7. Clean energy

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Access URL: https://dr.lib.iastate.edu/bitstreams/4af0715f-d707-4181-a784-f6d1a1bc6326/download
https://lib.dr.iastate.edu/cgi/viewcontent.cgi?article=6802&context=etd
https://lib.dr.iastate.edu/etd/15795/
https://ui.adsabs.harvard.edu/abs/2016PhDT.......116R/abstract

A linear programming approach for linear multi-level programming problems

Authors: Surabhi Sinha Sucheta Sinha

Source: Journal of the Operational Research Society. 55:312-316

Subject Terms: Linear programming, ideal/optimal solution, 0211 other engineering and technologies, 0202 electrical engineering, electronic engineering, information engineering, fuzzy weights, sequential linear goal programming, Fuzzy and other nonstochastic uncertainty mathematical programming, 02 engineering and technology, linear multi-level programming problem, satisfactory/compromise solution, weighting method

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Access URL: https://dblp.uni-trier.de/db/journals/jors/jors55.html#SinhaS04
https://link.springer.com/content/pdf/10.1057%2Fpalgrave.jors.2601701.pdf
https://ideas.repec.org/a/pal/jorsoc/v55y2004i3d10.1057_palgrave.jors.2601701.html
https://doi.org/10.1057/palgrave.jors.2601701
https://link.springer.com/article/10.1057%2Fpalgrave.jors.2601701
https://www.tandfonline.com/doi/full/10.1057/palgrave.jors.2601701

An Explicit Solution to the Multi-level Programming Problem.

Authors: Bard,Jonathan F Falk,James E GEORGE WASHINGTON UNIV WASHINGTON D C PROGRAM IN LOGISTICS

Contributors: Bard,Jonathan F Falk,James E GEORGE WASHINGTON UNIV WASHINGTON D C PROGRAM IN LOGISTICS

Source: DTIC AND NTIS

Subject Terms: Numerical Mathematics, NONCONVEX PROGRAMMING, OPTIMIZATION, MINIMAX TECHNIQUE, Complementarity Problem, Two Person Games, Bilinear Programming, Kuhn-Tucker Theory, Branch and Bound Method, Trees(Mathematics), WUNR347020

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Relation: http://www.dtic.mil/docs/citations/ADA069310

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Multi-level Nonlinear Programming Problem with Some Multi-choice Parameter.

Authors: Pradhan, Avik Biswal, M. P.

Source: Mathematics & Computing 2013; 2014, p91-101, 11p

Solving Dual-Channel Supply Chain Pricing Strategy Problem with Multi-Level Programming Based on Improved Simplified Swarm Optimization.

Authors: Yeh, Wei-Chang Liu, Zhenyao Yang, Yu-Cheng et al.

Source: Technologies (2227-7080); Jun2022, Vol. 10 Issue 3, pN.PAG-N.PAG, 35p

Subject Terms: SUPPLY chains, SUPPLY chain disruptions, BUSINESS negotiation, MULTILEVEL models, GAME theory

Uncertain Multi Level Four Dimensional Multi Item Fractional Transportation Problem.

Authors: Revathi, A. N. Mohanaselvi, S.

Source: International Journal of Intelligent Engineering & Systems; 2021, Vol. 14 Issue 6, p629-641, 13p

Subject Terms: FRACTIONAL programming, GOAL programming, MODEL theory, DECISION making

A Trilevel Transportation Problem for Traffic Management in Neutrosophic Environment.

Authors: Raut, Prasanta Kumar Rajalakshmi, R. Mishra, Ananya et al.

Source: Neutrosophic Sets & Systems; 2025, Vol. 90, p315-342, 28p

Subject Terms: URBAN transportation, TRANSPORTATION management, TRANSPORTATION policy, GOAL programming, CITY traffic

A bi-level model for a closed-loop agricultural supply chain considering biogas and compost.

Authors: Cheraghalipour, Armin Roghanian, Emad

Source: Environment, Development & Sustainability; Oct2025, Vol. 27 Issue 10, p23265-23311, 47p

Subject Terms: BIOGAS, COMPOSTING, GENETIC algorithms, METAHEURISTIC algorithms, SUSTAINABILITY, AGRICULTURAL productivity, MULTILEVEL models

Stackelberg equilibrium water allocation patterns in shallow groundwater area under uncertainties.

Authors: Zhang, Xiaoxing Li, Chen Guo, Ping

Source: Journal of Hydrology. Sep2022:Part B, Vol. 612, pN.PAG-N.PAG. 1p.

Subject Terms: *WATER management, *WATER rights, *WATER diversion, *GROUNDWATER, *DECISION support systems, *MULTILEVEL models

Geographic Terms: CHINA

臺灣廢主機回收補貼費率制定之研究 : 以基因演算法求解多階非線性規劃問題 ; A study on setting recycling subsidy for waste desktop computers in Taiwan : solving multi-level nonlinear programming model through genetic algorithm ; 台灣廢主機回收補貼費率制定之研究 : 以基因演算法求解多階非線性規劃問題

Authors: 許家瑋 Hsu, Chia-wei 淡江大學管理科學研究所碩士班 et al.

Contributors: 許家瑋 Hsu, Chia-wei 淡江大學管理科學研究所碩士班 et al.

Subject Terms: 多階層規劃, 電腦資源回收, 補貼費率, 回收清除處理費率, 非線性規劃, 模糊趨近法, 基因演算法, Multi-level programming problem, desktop recycling, subsidy, Recycling and treatment fee, nonlinear programming, Fuzzy approach, Genetic Algorithm

File Description: 143 bytes; application/octet-stream

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(2002).An interactive approach for integrated multi-level systems in a fuzzy environment, Mathl. Comput. Modelling 36 (4/5), 569-585. 24. Shih, H. S., U.P. Wen, E. S. Lee, K.M. Lan & H.C. Hsiao (2004). A Neural Network Approach to Multiobjective and Multilevel Programming Problems. Computers and Mathematics with Applications 48, 95-108. 25. Shih, H. S., Y. Lai & E. S. Lee (1996). Fuzzy Approach for Multi-Level Programming Problems. Computer Operations Research, Vol. 23, No. 1, 73-91. 26. Sinha, S., (2003). “Fuzzy mathematical programming applied to multi-level programming problems”, Computers and Operations Research 30, 1259-1268. 27. Tanaka, H. and K. Asai, (1984). “Fuzzy linear programming problems with fuzzy numbers”, Fuzzy Sets and Systems 13, 275-289. 28. Tanaka, H., T. Okuda, and K. Asai, (1974). “On fuzzy mathematical programming”, Journal of Cybernetics 3, 37-46. 29. U.P. Wen, & W.T. Wend (2000). “A primal-dual interior point algorithm for solving bilevel programming problems”, Asia-Pacific J. of Operational Research 17 (2), 213-231. 30. Wen, U.P., & A.D. Hung (1996). “A Simple Tabu Search Method to Solve the Mixed-Integer Linear Bilevel Programming Problem”, European J of Operational Research, 88(3), 563-571. 31. Wen, U.P., (1981). Mathematical Methods for Multilevel Linear Programming. Unpublished doctoral dissertation, State University of New York, Buffalo, New York. 32. Zimmermann, H.J., (1978). “Fuzzy programming and linear programming with severalobjective functions”, Fuzzy Sets and Systems 1, 45-55.; https://tkuir.lib.tku.edu.tw/dspace/handle/987654321/33254; https://tkuir.lib.tku.edu.tw/dspace/bitstream/987654321/33254/1/

Availability: https://tkuir.lib.tku.edu.tw/dspace/handle/987654321/33254
https://tkuir.lib.tku.edu.tw/dspace/bitstream/987654321/33254/1/

Adjustable robust optimization through multi-parametric programming.

Authors: Avraamidou, Styliani Pistikopoulos, Efstratios N.

Source: Optimization Letters; Jun2020, Vol. 14 Issue 4, p873-887, 15p

應用兩階層規劃於提升臺灣廢主機回收率之研究 ; A study on increasing recycling rate of waste desktop computers by subsidy via bi-level programming in Taiwan

Authors: 許珀銜 Hsu, Po-Hsien 淡江大學管理科學研究所碩士班 et al.

Contributors: 許珀銜 Hsu, Po-Hsien 淡江大學管理科學研究所碩士班 et al.

Subject Terms: 多階層規劃, 廢電腦回收, 消費者補貼費率, KKT轉換, 0-1非線性規劃, 模糊趨近法, Multi-level programming problem, waste desktop recycling, subsidy, Recycling and treatment fee, KKT conditions, 0-1 nonlinear programming, Fuzzy approach

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Fuzzy Sets and Systems, 1(1), 45-55.; https://tkuir.lib.tku.edu.tw/dspace/handle/987654321/74247

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MULTI-LEVEL INTEGER PROGRAMMING PROBLEM WITH MULTIPLE OBJECTIVES AT EACH LEVEL.

Authors: Arora, Ritu Gupta, Kavita

Source: Investigación Operacional. 2019, Vol. 40 Issue 3, p313-329. 17p. 2 Diagrams, 2 Charts.

Subject Terms: *LINEAR programming, *MATHEMATICAL programming, *INTEGER programming, *FRACTIONAL programming, *MATHEMATICAL optimization

Optimizing multi-level decision-making: M-TOPSIS approach for quadratic fractional multiobjective problems.

Authors: Rani, Rozy Goyal, Vandana Gupta, Deepak

Source: International Journal of Systems Assurance Engineering & Management; Aug2025, Vol. 16 Issue 8, p2832-2840, 9p