應用物件導向設計結構矩陣設計工業4.0環境中的即時監控系統

以作者查詢圖書館館藏

、以作者查詢臺灣博碩士

、以作者查詢全國書目

、勘誤回報

、線上人數：66

、訪客IP：3.144.6.223

姓名

蔡明叡(Ming-Jui Tsai) 查詢紙本館藏

畢業系所

工業管理研究所

論文名稱

應用物件導向設計結構矩陣設計工業4.0環境中的即時監控系統
(Applying Object-Oriented Design Structure Matrix to Design the Real-time Monitoring System of Industry 4.0)

相關論文

★ 應用MFM 與PPM 監控協同設計之執行流程	★ 應用DSM與DRFT於汽車電子之協同開發流程
★ 一協同設計專案團隊組成方法- 以安全監視器產品為例	★ 應用認知工程開發全球化光纖通訊系統
★ 羽絨產業策略規劃-應用品質機能展開分析法	★ 重電業協同專案管理績效之研究-以變電所統包工程為例
★ 以屬性導向新產品開發之流程塑模與分析– 以醫療器材產業為案例	★ 以品質機能展開法應用於主管管理職能之建構
★ 應用參考模型以及流程建模改善供應鏈績效-以投影機產業為例	★ 協同產品開發之流程管理 - 以汽車零件為例
★ 配電系統之高壓電纜接頭供應商評選	★ 應用品質機能展開於產品開發之流程分析-以刀鋒式伺服器為例
★ 實施精實六標準差改進製程良率－以機頂盒表面黏著技術為例	★ 太陽能模組產業之決策營運研究
★ 新產品開發階段導入替代料之流程建模及潛在風險分析	★ 應用實驗設計研發PET複合膜及改善厚膜翹曲問題

檔案

[Endnote RIS 格式]

[Bibtex 格式]

[相關文章]

[文章引用]

[完整記錄]

[館藏目錄]

[檢視]

[下載]

本電子論文使用權限為同意立即開放。
已達開放權限電子全文僅授權使用者為學術研究之目的，進行個人非營利性質之檢索、閱讀、列印。
請遵守中華民國著作權法之相關規定，切勿任意重製、散佈、改作、轉貼、播送，以免觸法。

摘要(中)

於第三次工業革命，全球推展數位化與網際網路以交換巨量資訊，進而整合製造、服務、能源、交通、電子產品等產業，因此創新出更多樣的商業模式。如今在此資訊爆炸的時代，我們正在經歷第四次工業革命，也就是通稱的工業4.0。在工業4.0的環境中，將有更多更新的商業模式、科技技術、工作流程以及產品開發方法，而這些變化也將劇烈的影響商務與社會。
與工業4.0息息相關的網宇實體系統 (Cyber-Physical System, CPS)日漸發展成熟。有別於之前強調內嵌式系統之間的整合與機器運算能力，CPS更為強調各個實體裝置、電腦運算網路、以及物聯網之間的連結關係。本研究首先針對CPS的整合問題，於傳統的資料獲取與監視控制系統 (Supervisory Control And Data Acquisition, SCADA)中，加入擴增實境(Augmented Reality, AR)的應用技術，將CPS定義為整合式控制系統。其中，SCADA用以遠距蒐集即時資料以及控制設備與製程，AR則用以疊加與呈現真實世界以及虛擬世界的資訊。
關於系統分析與設計，本研究首先應用物件導向設計(Object-Oriented Design, OOD)建立CPS各種元件之間的關聯性，繼而以設計結構矩陣(Design Structure Matrix, DSM)，建立物件關係矩陣以建構系統的基本架構，進而設計CPS的即時監控系統。

摘要(英)

In the third industrial revolution, the digitization and the internet were expanded all over the world to exchange the huge amount of information, integrated manufacturing, services, energy, transportation, electronic product, and so on. As a result, new innovative business models are created. In the new era of Information explosion, we are currently experiencing the fourth Industrial Revolution, which is known as the industry 4.0. In industry 4.0, more and more new business models, technologies, workflows and product development methods; therefore, these changes will be greatly affected business and society.
Cyber Physical System (CPS) which is closely related to Industry 4.0 is increasingly mature. Compare to the previous emphasize integration, the most difference between the machine computing embedded systems is that CPS has strong emphases on each physical device, computer network operation, Internet of Things (IoT) and the connection between them. In this research, we focus on the integration of the CPS. Adding the Augmented Reality (AR) application technology to the Supervisory Control and Data Acquisition (SCADA), the CPS is defined as an integrated control system. SCADA is a system for remoting real-time data collection and controlling equipment and processes. AR is superimposed to show the real world and the virtual world of information. AR provides a view of the real world relied on superimposed information which has been applied to the virtual world.
About the system analysis and design, this research will apply Object-Oriented Design (OOD) technology to create the correlation between the components, and the framework of the system referring to the concept of Design Structure Matrix (DSM) is evaluated. Based on this, we can design a CPS real-time monitoring system.

關鍵字(中)

★ 工業4.0
★ 網宇實體系統
★ 資料獲取與監視控制系統
★ 擴增實境
★ 設計結構矩陣
★ 系統設計

關鍵字(英)

★ Industry 4.0
★ Cyber-Physical System
★ Supervisory Control And Data Acquisition
★ Augmented Reality
★ Design Structure Matrix
★ System Design

論文目次

中文摘要 I
Abstract II
Table of Contents IV
List of Figures VI
List of Tables VIII
Abbreviations IX
Chapter 1 Introduction 1
1.1. Background 1
1.2. Motivation & Objectives 2
1.3. Research Overview 3
Chapter 2 Literature Review 5
2.1. Cyber-Physical System 5
2.2. Supervisory Control and Data Acquisition 11
2.3. Augmented Reality 17
Chapter 3 Methodology 20
3.1. Methodology framework 20
3.2. Overview of Methodology 23
3.2.1. Object-Oriented Analysis 23
3.2.2. Object-Oriented Design 24
3.2.3. Design Structure Matrix 27
3.2.3.1. Introduction 27
3.2.3.2. Categories 30
3.2.3.3. Partitioning 31
Chapter 4 Application 33
4.1. The Real-time Monitoring System Design (I4RMS) 34
4.2. The Functions of Components 37
4.3. Methodology Implement 46
4.4. Analysis of DSM 46
Chapter 5 Conclusions and Future Research 56
5.1. Conclusions 56
5.2. Future Research 57
References 58

參考文獻

Ali, S., Qaisar, Saad B., Saeed, H., Khan, M. F., Naeem, M., and Anpalagan, A. "Network Challenges for Cyber Physical Systems with Tiny Wireless Devices: A Case Study on Reliable Pipeline Condition Monitoring." Sensors 15, no. 4, 71-72, (2015).

Azuma, R., Baillot, Y., Behringer, R., Feiner S., Julier, S., and MacIntyre, B. "Recent Advances in Augmented Reality." IEEE Comput. Graph. Appl. 21, no. 6, 34-47, (2001).

Bailey, D. and Wright E. Practical Scada for Industry: Newnes, (2003).

Bauernhansl, T., Ten Hompel, M. and Vogel-Heuser, B. Industrie 4.0 in Produktion, Automatisierung Und Logistik: Anwendung· Technologien· Migration: Springer-Verlag, (2014).

Browning, T. R. "Applying the Design Structure Matrix to System Decomposition and Integration Problems: A Review and New Directions." IEEE Transactions on Engineering Management 48, no. 3, 292-306, (2001).

Browning, T. R. "Process Integration Using the Design Structure Matrix." Systems Engineering 5, no. 3, 180-193, (2002).

Eden, A. H. "A Theory of Object-Oriented Design." Information Systems Frontiers 4, no. 4, 349-391, (2002).

Gölzer, P., Cato, P. and Amberg, M. "Data Processing Requirements of Industry 4.0-Use Cases for Big Data Applications." Data Processing, (2015).

Gorecky, D., Schmitt, M., Loskyll, M., Zühlke, D. "Human-Machine-Interaction in the Industry 4.0 Era." In 2014 12th IEEE International Conference on Industrial Informatics (INDIN), 289-294, (2014).

Jacobson, I. "Object-Oriented Development in an Industrial Environment." In ACM SIGPLAN Notices, 22, 183-191: ACM, (1987).

Jacobson, I. Object-Oriented Software Engineering: A Use Case Driven Approach: Addison Wesley Longman Publishing Co., Inc., (2004).

Jazdi, N. "Cyber Physical Systems in the Context of Industry 4.0." In Automation, Quality and Testing, Robotics, 2014 IEEE International Conference on, 1-4, (2014).

Kao, H. A., Jin, W., Siegel, D. and Lee, J. "A Cyber Physical Interface for Automation Systems—Methodology and Examples." Machines 3, no. 2, 93-106, (2015).

Lange, D. B. "An Object-Oriented Design Method for Hypermedia Information Systems." In System Sciences, 1994. Proceedings of the Twenty-Seventh Hawaii International Conference on, 3, 366-375: IEEE, (1994).

Lee, J., Bagheri, B. and Kao, H. A. "A Cyber-Physical Systems Architecture for Industry 4.0-Based Manufacturing Systems." Manufacturing Letters 3, 18-23, (2015).

Li, K., Dewar, R. G. and Pooley, R. J. "Object-Oriented Analysis Using Natural Language Processing." Linguistic Analysis, (2005).

MacDougall, W. Industrie 4.0: Smart Manufacturing for the Future: Germany Trade & Invest, (2014).

Office of the Manager. "National Communications System: Supervisory Control and Data Acquisition (Scada) Systems: Technical Information Bulletin 04-1." National communications system, (2004).

Milgram, P., Takemura, H., Utsumi, A. and Kishino, F. "Augmented Reality: A Class of Displays on the Reality-Virtuality Continuum." In Telemanipulator and Telepresence Technologies (1994) – SPIE Vol. 2351, 282-292: International Society for Optics and Photonics, (1994).

Paelke, V. "Augmented Reality in the Smart Factory: Supporting Workers in an Industry 4.0. Environment." In Proceedings of the 2014 IEEE Emerging Technology and Factory Automation (ETFA), 1-4, (2014).

Pentenrieder, K., Bade, C., Doil, F. and Meier, P. "Augmented Reality-Based Factory Planning - an Application Tailored to Industrial Needs." In Mixed and Augmented Reality, 2007. ISMAR 2007. 6th IEEE and ACM International Symposium on, 31-42, (2007).

Pentenrieder, K. "Augmented Reality Based Factory Planning." Technische Universität München, (2009).

Rüßmann, M., Lorenz, M., Gerbert, P., Waldner, M., Justus, J., Engel, P. and Harnisch, M. "Industry 4.0: The Future of Productivity and Growth in Manufacturing Industries." BCG Perspectives, April 9, (2015).

Sargent, R. W. H. and Westerberg A. W. ""Speedup" (Simulation Programme for the Economic Evaluation and Design of Unsteady-State Processes) in Chemical Engineering Design." Transactions of the Institution of Chemical Engineers, (1964).

Scheuermann, C., Verclas, S. and Bruegge, B. "Agile Factory - an Example of an Industry 4.0 Manufacturing Process." In Cyber-Physical Systems, Networks, and Applications (CPSNA), 2015 IEEE 3rd International Conference on, 43-47, (2015).

Schoenfelder, R. and Schmalstieg, D. "Augmented Reality for Industrial Building Acceptance." In 2008 IEEE Virtual Reality Conference, 83-90, (2008).

Sendler, U. Industrie 4.0: Beherrschung Der Industriellen Komplexität Mit Syslm: Springer-Verlag, (2013).

Tan, Y., Goddard, S. and Perez, L. C. "A Prototype Architecture for Cyber-Physical Systems." ACM Sigbed Review 5, no. 1, 26, (2008).

Wang, X., Truijens, M., Hou, L., Wang, Y. and Zhou, Y. "Integrating Augmented Reality with Building Information Modeling: Onsite Construction Process Controlling for Liquefied Natural Gas Industry." Automation in Construction 40, 96-105, (2014).

Wiedenmaier, S., Oehme, O., Schmidt, L. and Luczak, H. "Augmented Reality (Ar) for Assembly Processes Design and Experimental Evaluation." International journal of Human-Computer interaction 16, no. 3, 497-514, (2003).

Yen, C. T., Liu, Y. C., Lin, C. C., Kao, C. C., Wang, W. B. and Hsu, Y. R. "Advanced Manufacturing Solution to Industry 4.0 Trend through Sensing Network and Cloud Computing Technologies." In 2014 IEEE International Conference on Automation Science and Engineering (CASE), 1150-1152, (2014).

Yu, C., Jing, S. and Li, X. "An Architecture of Cyber Physical System Based on Service." In Computer Science & Service System (CSSS), 2012 International Conference on, 1409-1412, (2012).

Zhang, L. "Designing Big Data Driven Cyber Physical Systems Based on Aadl." In 2014 IEEE International Conference on Systems, Man, and Cybernetics (SMC), 3072-3077, (2014).

指導教授

高信培(Hsing-Pei Kao)

審核日期

2016-7-19

推文