文章详情_毕业论文网

登录

  • 登录
  • 忘记密码?点击找回

注册

  • 获取手机验证码 60
  • 注册

找回密码

  • 获取手机验证码60
  • 找回
毕业论文网 > 文章详情

基于机器学习的控制器性能评价与监测开题报告

 2020-02-20 10:00:01  

1. 研究目的与意义(文献综述)

owing to wide applications of automatic control systems in the process industries, the impacts of controller performance on industrial processes are becoming increasingly significant. consequently, controller maintenance is critical to guarantee routine operations of industrial processes. the workflow of controller maintenance generally involves the following steps: monitor operating controller performance and detect performance degradation, diagnose probable root causes of control system malfunctions, and take specific actions to resolve associated problems. in this article, a comprehensive overview of the mainstream of control loop monitoring and diagnosis is provided, and some existing problems are also analyzed and discussed. from the viewpoint of synthesizing abundant information in the context of big data, some prospective ideas and promising methods are outlined to potentially solve problems in industrial applications.

in a typical continuous process industry facility, the number of control loops can be about between 500 and 5000. in contrast to the wide applications of controllers, only a small portion of industrial controllers operates at healthy states, as pointed out by some existing investigations . it is therefore necessary to monitor industrial controllers and evaluate their closed-loop performance. however, the labor cost of manual monitoring is huge due to the large number of control loops, and thus achieving online and automated controller monitoring is an urgent demand from a practical perspective. to this aim, the technique of controller performance assessment (cpa), the objective of which is to detect performance degradation by analyzing routine closed-loop operating data, has gained considerable attention from both academia and industry in recent decades.

detection of performance degradation is a prerequisite to improve controller performance. then an important step afterwards is to diagnose probable root causes, which furnishes useful information for further maintenance. in general, possible causes of performance degradation can be enumerated as controller problems, equipment malfunctions and external disturbances. for controller problems, there is a need of intelligent guidelines about controller maintenance, and for problems like equipment malfunctions and external disturbances, it is imperative to report the corresponding faults timely such that specific actions can be taken to fix the related problems. from a pragmatic standpoint, an orient–decide–act–improve workflow should be followed, which includes the following steps

剩余内容已隐藏,您需要先支付后才能查看该篇文章全部内容!

2. 研究的基本内容与方案

control loops are the most important components in automation systems, the important indicators such as product quality, operational safety, and energy consumption are directly related to the performance of the control loops. it is of great significance to monitor the deviation or degradation of the performance of control loops, as well as diagnose root-causes of poor performance. in this article, a date-driven framework for automatically assessing and monitoring the performance of control loops is studied. specially, the main contents of this article are as follows:

for performance assessment, this article implement the application of filtering and correlation analysis (fcor) and linear regression (lr) after researching on several categories of existing methods and understanding the theory and derivation of the minimum variance benchmark

for performance monitoring, two aspects of control indicators in closed-loop system are considered, namely the change speed and the timing correlation of variables. in aspect of change speed, sfa is used to extract most slowly varying components to monitor performance of closed-loop control system, and the application results of sfa on tennessee-eastman process data were analyzed.

剩余内容已隐藏,您需要先支付后才能查看该篇文章全部内容!

3. 研究计划与安排

3月1日—3月14日:进一步查阅相关资料

尝试写出综述,详细了解控制器性能评价与监测的大部分方法,并从中总结出每种方法的关键及不足。

3月14日—3月25日:控制器性能评价算法

剩余内容已隐藏,您需要先支付后才能查看该篇文章全部内容!

4. 参考文献(12篇以上)

  1. Paulonis M A, Cox J W. A practical approach for large-scale controller performance assessment, diagnosis, and improvement[J]. Journal of Process Control, 2003, 13(2):155-168.Jelali M. Control Performance Management in Industrial Automation[M]. Springer London, 2013.
  2. Gao X, Yang F, Shang C, et al. A review of control loop monitoring and diagnosis: Prospects of controller maintenance in big data era ☆[J]. Chinese Journal of Chemical Engineering, 2016, 24(8):952-962.
  3. Huang B, Ding S X, Thornhill N. Practical solutions to multivariate feedback control performance assessment problem: reduced a-priori knowledge of interactor matrix[J]. Journal of Process Control, 2005, 15(5):573-583.
  4. 李晗,萧德云.基于数据驱动的故障诊断方法综述[J].控制与决策,2011,26(01):1-9 16.
  5. 彭宇,刘大同.数据驱动故障预测和健康管理综述[J].仪器仪表学报,2014,35(03):481-495.
  6. 胡昌华,施权,司小胜,张正新.数据驱动的寿命预测和健康管理技术研究进展[J].信息与控制,2017,46(01):72-82.
  7. Harris T J. Assessment of control loop performance[J]. Canadian Journal of Chemical Engineering, 1989, 67(5):856-861.
  8. 侯忠生,许建新.数据驱动控制理论及方法的回顾和展望[J].自动化学报,2009,35(06):650-667.
  9. Huang B, Shah S L, Miller R. Feedforward plus feedback controller performance assessment of MIMO systems[J]. IEEE Transactions on Control Systems Technology, 2002, 8(3):580-587.
  10. Desborough L, Harris T. Performance assessment measures for univariate feedforward/feedback control[J]. Canadian Journal of Chemical Engineering, 1993, 71(4):1186-1197.
  11. Jelali M. Performance assessment of control systems in rolling mills – application to strip thickness and flatness control[J]. Journal of Process Control, 2007, 17(10):805-816.
  12. Qin S J. Control performance monitoring — a review and assessment ☆[J]. Computers amp; Chemical Engineering, 1998, 23(2):173-186.
  13. Tyler M L, Morari M. Performance monitoring of control systems using likelihood methods[C]// American Control Conference, Proceedings of the. IEEE, 1995:1245-1249 vol.2
  14. Huang B. Minimum variance control and performance assessment of time-variant processes[J]. Journal of Process Control, 2002, 12(6):707-719.
  15. Folake B. Olaleye,#8224;, Biao Huang,,#8224; and, Edgar Tamayo#8225;. Feedforward and Feedback Controller Performance Assessment of Linear Time-Variant Processes[J]. Industrial amp; Engineering Chemistry Research, 2004, 43(2):589-596.
  16. Mcnabb C A, Qin S J. Projection based MIMO control performance monitoring: II––measured disturbances and setpoint changes[J]. Journal of Process Control, 2005, 15(1):89-102.
  17. Bakolas E. Constrained minimum variance control for discrete-time stochastic linear systems[J]. Systems amp; Control Letters, 2018, 113:109-116.
  18. 张庆跃. 基于最小方差基准的控制系统性能评价[D]. 厦门大学, 2014.
  19. Ghousiya B K, Seshagiri R A, Radhakrishnan T K. Performance assessment of control loops involving unstable systems for set point tracking and disturbance rejection[J]. Journal of the Taiwan Institute of Chemical Engineers, 2018.
  20. 杨叔子. 时间序列分析的工程应用[M]. 华中理工大学出版社, 1991.
  21. 徐祉娟. 控制系统性能评价方法的研究[D]. 东北大学, 2008.
  22. Li C, Huang B, Qian F. Hellinger distance based probability distribution approach to performance monitoring of nonlinear control systems ☆[J]. 中国化学工程学报(英文版), 2015, 23(12):1945-1950.
  23. Das L, Srinivasan B, Rengaswamy R. A novel framework for integrating data mining with control loop performance assessment[J]. Aiche Journal, 2016, 62(1):146-165.
  24. Li Q, Whiteley J R, Rhinehart R R. A relative performance monitor for process controllers[J]. International Journal of Adaptive Control amp; Signal Processing, 2010, 17(7-9):685-708.

剩余内容已隐藏,您需要先支付 10元 才能查看该篇文章全部内容!立即支付

企业微信

Copyright © 2010-2022 毕业论文网 站点地图