不固定作業關係之重複性工程排程模式之研究

Su-Ling Fan; 范素玲

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/35069

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DC 欄位	值	語言
dc.contributor.advisor	曾惠斌,王明德
dc.contributor.author	Su-Ling Fan	en
dc.contributor.author	范素玲	zh_TW
dc.date.accessioned	2021-06-13T06:40:08Z	-
dc.date.available	2005-08-01
dc.date.copyright	2005-08-01
dc.date.issued	2005
dc.date.submitted	2005-08-01
dc.identifier.citation	REFERENCE [1] AbouRizk, S. M., and Halpin, D. W. (1990). “Probabilistic simulation studies for repetitive construction process.” Journal of Construction Engineering and Management, ASCE 116(4), 575-594. [2] Adeli, H., and Karim, A. (1997). “Scheduling/Cost Optimization and Neural Dynamics Model for Construction.” Journal of Construction Engineering and Management, ASCE, 123(4), 450-458. [3] Arditi, D., and Albulak, M. Z. (1986). “Line-of-balance scheduling in pavement construction.” Journal of Construction Engineering and Management, ASCE, 112(3), 411-424. [4] Ashley, D. B. (1980). “Simulation of repetitive-unit construction.” Journal of Construction Engineering and Management, ASCE, 106(2), 185-194. [5] Avraham, S. (1991). “Scheduling of Programs with Repetitive Projects.” Project Management Journal, Vol. XXII, No.4, 49-53. [6] Booch, G. (1991). Object-oriented Design with Applications. Benjamin/Cummings Publishing, Redwood City, Calif. [7] Callahan, M. T., Quackenbush, D.G., and Rowing, J.E. (1992). Construction Project Scheduling, McGraw-Hill. [8] Carr, M. I., and Meyer, W. L. (1974). “Planning construction of repetitive building units.” Journal of Construction Division, ASCE, 100(3), 403-412. [9] Chrzanowski, E. N., and Johnston, D. W. (1998). “Application of linear scheduling.” Journal of Construction Engineering and Management, ASCE, 112(4), 476-491. [10] Coad, P. and Yourdon, E. (1991). Object-Oriented Analysis. Prentice-Hall. [11] Cohen, G. and Levitt, R. E. (1991). “An Object-Oriented Model of Information Sharing in Project Design Teams.” Proceedings of Construction Congress '91, Preparing for Construction in the 21st Century, ASCE, Cambridge, MA, 348-353. [12] Crandall, K.C. (1974). “Analysis of Schedule Simulations.” Journal of Construction Division, ASCE, 100(C01), 39-49. . [13] Echeverry, D., Ibbs, W., and Kim, S. (1991). ” Sequencing Knowledge for Construction Scheduling.” Journal of Construction Engineering and Management, ASCE, 117(1), 118-130. [14] Echeverry, D. (1991). “Factors for generating initial construction schedules.” USACERL technical manuscript. P-91/54, US Army Corps of Engineers, Construction Engineering Research Laboratory, Champaign, IL. [15] El-Rayes, K., and Moselhi, O. (2001). “Optimizing resource utilization for repetitive construction projects.” Journal of Construction Engineering and Management, ASCE, 127(1), 18-27. [16] El-Sersy, A. H. E. (1993). “An Intelligent Data Model for Scheduling Updating.” Ph.D. Dissertation, University of California, Berkeley, CA. [17] Fan, S.L., Tserng, H.P., and Wang M.T. (2003). “Development of an Object-oriented Scheduling Model for Construction Projects.” Automation in Construction, Elsevier 12, 283-302. [18] Harmelink, D. J. (1998). “Linear scheduling model: Float character.” Journal of Construction Engineering and Management, ASCE, 124(4), 263-268. [19] Harmelink, D.J., and Rowings, J.E. (1991). “Linear scheduling model: Development of controlling activity path.” Journal of Construction Engineering and Management, ASCE, .124(4), 263-268. [20] Hassanein and Moselhi (2004). “Planning and Scheduling Highway Construction.” Journal of Construction Engineering and Management, ASCE, 130(5), 638-646. [21] Hegazy, T., and Wassef, N. (2001). “Cost optimization in projects with repetitive nonserial activities.” Journal of Construction Engineering and Management, ASCE, 127(3), 183-191. [22] Johnston, D. W. (1981). “Linear scheduling method for highway construction.” Journal of Construction Division, ASCE, 107(2), 247-261. [23] Kang, L.S., Park, I.C., and Lee, B.H. (2001). “Optimal scheduling planning for multiple, repetitive construction process.” Journal of Construction Engineering and Management, ASCE, 127(5), 382-390. [24] Karim, A., and Adeli, H. (1999). “CONSCOM : An OO Construction Scheduling and Change Management System.” Journal of Construction Engineering and Management, ASCE, 125(5), 368-376. [25] Kavanagh, D. P. (1985). “SIREN: A repetitive construction simulation model.” Journal of Construction Engineering and Management, ASCE, 111(3), 308-323. [26] Leu, and Hwang (2001). “Optimal repetitive scheduling model with shareable resource constraint.” Journal of Construction Engineering and Management, ASCE, 127(4), 270-280. [27] Levit, R., and Kunz J. (1985). “Using Knowledge of Construction and Project Management for Automated Scheduling Updating.” Project Management Journal, Vol. XV, No.5. [28] Liberty, J. (2005). Visual C# 2005: A Developer’s Notebook. O’Reilly. [29] Lutz, J.D., and Hijazi, A.(1993). “Planning repetitive construction: Current practices.” Journal of Construction Management and Economics, London 11, 99-110. [30] Madan, A. (2004). “Object-Oriented Paradigm in Programming for Computer-Aided Analysis of Structures. “ Journal of Computing in Civil Engineering, ASCE 18(3), 226-236. [31] Moselhi, and Hassanein (2003). “Optimized Scheduling of Linear Projects.” Journal of Construction Engineering and Management, ASCE, 129 (6), 664-673. [32] Moselhi, O., and El-Rayes, K. (1993). “Scheduling of repetitive projects with cost optimization.” Journal of Construction Engineering and Management, ASCE, 119(4), 681-697. [33] O’Brien, J. J. (1975). “VPM scheduling for high-rise buildings.” Journal of Construction Division, ASCE, 101(4), 895-905. [34] O’Brien, J. J., Kreitzberg, F. C., and Mikes, W.F. (1985). “Network scheduling variations for repetitive work.” Journal of Construction Engineering and Management, ASCE, 111(2), 105-116. [35] Perera, S. (1982). “Network planning of project comprising repetitive activities.” IAHS Conference on Impact of Economy and Technology, International Association of Housing Science, Vienna, Austria, 927-985. [36] Pilcher, R. (1976). Principals of construction management. 2nd Ed., McGraw-Hill, London. [37] Pristker, A., and Whitehouse, G. (1966). “GERT: Graphical Evaluation and Review Technique, Part II. Application.” Journal of Industrial Engineering, 17(5), 293-301. [38] Reda, R. (1990). “RPM: Repetitive project modeling.” Journal of Construction Engineering and Management, ASCE, 116(2), 316-330. [39] Rhabar, F. F., and Rowings J.E. (1992). “Repetitive Activity Scheduling Process.” ASCE Transaction. 36th Annual Meeting, Orlando, Fla., O.5.1-O.5.8. [40] Rumbaugh, J., et al. (1991). Object-Oriented Modeling and Design. Prentice-Hall. [41] Russell, A. D., and Wong, W.C.M. (1993). “New Generation of Planning Structures.” Journal of Construction Engineering and Management, ASCE, 119(2), 196-214. [42] Sahail, S. A., and Neale, R. H. (1994). “CPM / LOB: New methodology to Integrate CPM and Line of Balance.” Journal of Construction Engineering and Management, ASCE, 120(3), 667-684. [43] Sarraj, Al.(1990). “Formal Development of Line-of-Balance.” Journal of Construction Engineering and Management, ASCE, 116(4), 411-424. [44] Selinger, S. (1980). “Construction planning for linear projects.” Journal of Construction Division, ASCE 106(2), 195-205. [45] Senior, B.A., and Halpin, D.W. (1998), “Simplified Simulation System for Construction Projects”. Journal of Construction Engineering and Management, ASCE, 124(1), 72-81. [46] Shoderbek, P. P., and Digman, L.A. (1967), “Third Generation, PERT / LOB.” Harvard Business Review, 45(5), 196-214. [47] Tamimi, S., and Diekmann, J. (1988). “Soft logic in network analysis.” Journal of Construction Engineering and Management, ASCE, 2(3), 289-330. [48] Thabet, W.Y., and Beliveau, Y. J. (1997). “SCaRC: Space-constrained resource-constrained scheduling system.” Journal of Computing in Civil Engineering, ASCE , 11(1), 48-59. [49] Vorster, M.C., and Bafna, T. (1992). “Discussion of “Formal development of line-of-balance technique” by Z.M. Al Sarraj.” Journal of Construction Engineering and Management, ASCE, 118(1), 210-211. [50] Yi, K.J., Lee, H.S., and Choi, Y.K. (2002). “Network creation and development for repetitive-unit projects.” Journal of Construction Engineering and Management, ASCE, 128(3), 257-264.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/35069	-
dc.description.abstract	工程實務上有許多相同的作業項目在不同的施工區域不斷地重複，這類工程稱之為重複性工程。例如高樓建築、集合住宅、公路工程及管涵工程等。網圖技術已廣泛應用於各類型之工程進度排程，然而其應用於重複性工程卻有許多缺點。本研究旨在解決應用網圖技術於重複性工程之三個缺點：一、網圖技術表達的複雜性：應用網圖技術表達重複性工程需要大量的作業項目，因此造成建立與更新進度時的困難度。二、無法表達不固定作業關係(Soft Logic)：網圖技術假定所有作業間關係皆為固定不變，然而工程實務上卻有許多作業間之關係是有各種不同排列組合的。三、無法確保工班連續性(Work Continuity) ：網圖技術僅考慮作業之前置後續關係，並未考量工班(資源)之連續性。本研究發展之模式包含以下三個模組：一、輸入模組：依據工期、施工區域、.基本施作流程、施工區域之結構及作業關係將重複性工程分為22222=32種類型，而後進一步發展可以表達各不同之重複性工程之界面，使排程者可輸入簡單之資料以表達重複性工程。二、進度模組：探討影響不固定作業關係排程之影響因素與排序之經驗法則，而後發展表達不固定作業關係及影響其排序因素之界面並利用物件導向技術發展不固定作業關係排序演算法。三、工班連續性模組：發展可確保工班連續性之演算法。	zh_TW
dc.description.abstract	Network techniques have been widely used as a project planning tool in the construction industry. However, the application of network techniques to repetitive projects has long been criticized. This research aims at overcoming three main drawbacks of applying network techniques in repetitive projects: 1) complexity of network representation 2) inability of representing soft logics and 3) difficulty of maintaining work continuity. This research develops a system which provides an input module which easily represents different types of repetitive projects in addition to scheduling and work continuity maintaining modules. The system simplifies the network generation and updates processes, which provides the near-shortest project duration logics or the start and finish dates to meet work continuity requirement.	en
dc.description.provenance	Made available in DSpace on 2021-06-13T06:40:08Z (GMT). No. of bitstreams: 1 ntu-94-D88521004-1.pdf: 961044 bytes, checksum: 1c2738176a7d02d1bec0eae33f7cb61c (MD5) Previous issue date: 2005	en
dc.description.tableofcontents	ABLE OF CONTENTS ACKNOWLEDGEMENT I ABSTRACT II TABLE OF CONTENTS III LIST OF FIGURES V LIST OF TABLES VII CHAPTER 1　INTRODUCTION 1 1.1 BACKGROUND AND MOTIVATION 1 1.2 PROBLEM STATEMENTS 2 1.3 RESEARCH OBJECTIVES 4 1.4 RESEARCH APPROACH 4 1.5 FRAMEWORK OF METHODOLOGY 5 1.6 FLOWCHART OF RESEARCH 7 1.7 STRUCTURE OF DISSERTATION 8 CHAPTER 2　LITERATURE REVIEW 9 2.1 SCHEDULING MODELS 9 2.2 REPETITIVE PROJECTS 15 2.3 SOFT LOGICS 15 2.4 OBJECT-ORIENTED TECHNIQUES 19 2.5 SUMMARY 22 CHAPTER 3　REPITITIVE PROJECTS WITH SOFT LOGICS 23 3.1 SOFT LOGICS 23 3.2 HEURISTIC FACTORS AND PRINCIPLES OF SOFT-LOGIC SEQUENCING 24 1. PREDEFINED PREFERENCE OR CONSIDERATION 24 2. SITE CONDITIONS AND RESOURCE LIMITATIONS 25 3.3 DATA INVOLVED IN REPRESENTING REPETITIVE PROJECTS WITH SOFT LOGICS 30 3.4 TYPES OF REPETITIVE PROJECTS WITH SOFT LOGICS 31 3.5 SUMMARY 35 CHAPTER 4　METHODOLOGY 36 4.1 INPUT MODULE 37 1. IDENTIFYING THE FIXED PRECEDENCE ACTIVITIES (FPA) 40 2. IDENTIFYING INTERCHANGEABLE ACTIVITIES 41 4.2 SCHEDULING MODULE 42 1. ASSUMPTIONS 42 2. ALGORITHMS 43 4.3 WORK CONTINUITY MAINTAINING MODULE 52 1. BACKWARD STAGE: 52 2. FORWARD STAGE 52 4.4 SUMMARY 53 CHAPTER 5 SYSTEM IMPLEMENTATION 54 5.1 SYSTEM IMPLEMENTATION 54 5.2 EXAMPLES AND DISCUSSION 56 1. INPUTTING 56 2. UPDATING 70 5.3 SUMMARY 72 CHAPTER 6　CONCLUSION 73 6.1 CONCLUSION 73 6.2 FUTURE WORK 74 REFERENCE 75 APPENDIX 80
dc.language.iso	en
dc.title	不固定作業關係之重複性工程排程模式之研究	zh_TW
dc.title	Development of Scheduling Model for Repetitive Projects with Soft Logics	en
dc.type	Thesis
dc.date.schoolyear	93-2
dc.description.degree	博士
dc.contributor.oralexamcommittee	葉文凱,呂守陞,王維志,楊亦東,黃榮堯
dc.subject.keyword	排程,物件導向,不固定作業關係,重複性工程,	zh_TW
dc.subject.keyword	Scheduling,Object-oriented,Soft Logics,Repetitive Projects,	en
dc.relation.page	83
dc.rights.note	有償授權
dc.date.accepted	2005-08-01
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	土木工程學研究所	zh_TW
顯示於系所單位：	土木工程學系

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