检索规则说明:AND代表“并且”;OR代表“或者”;NOT代表“不包含”;(注意必须大写,运算符两边需空一格)
检 索 范 例 :范例一: (K=图书馆学 OR K=情报学) AND A=范并思 范例二:J=计算机应用与软件 AND (U=C++ OR U=Basic) NOT M=Visual
名 称:
注 释:
机构地区:[1]华东理工大学机械与动力工程学院,上海200237
出 处:《华东理工大学学报(自然科学版)》2010年第1期134-140,共7页Journal of East China University of Science and Technology
基 金:国家自然科学基金项目(60974061)
摘 要:为解决流程工业中大范围过程变量波动时波动传播路径的确定和波动源所在回路的定位问题,提出了一种基于格兰杰因果检验的分析方法。该方法结合已有的频域分析方法,筛选出含相近频率成分的受扰波动变量,对其进行格兰杰因果检验,检验得到的回路变量间的因果影响关系表征了波动干扰的传播路径,以因果关系图的形式直观表达。利用先验过程知识化简因果关系图,并通过切除阈值搜索方式过滤掉次要因果关系分支,得到波动干扰的主要传播路径,由此定位波动源。仿真及工业数据的验证结果表明该方法是可行的。To identify the propagation paths of multi-loop process oscillations in process industry and locate the origin of the oscillation disturbance, a novel method based on Granger causality test is proposed. Pre-processed by existed spectral analysis, process variables of oscillatory control loops with similar frequency components are selected for Granger causality test, which can reveal the complex causality among the selected process variables. The causality is visualized in the form of causality diagram, which represent the propagation paths of the oscillations and can be further simplified by the understanding of process knowledge. Less significant causality pathways are filtered out by manual cutting-off threshold searching. The resulting diagram represents the main oscillation propagation paths, which is traced to identify the source of the oscillation disturbance. Both simulated and real plant data tests are presented that the proposed method is feasible.
关 键 词:回路波动 格兰杰因果检验 过程知识 传播路径 根源识别
分 类 号:TP277[自动化与计算机技术—检测技术与自动化装置]
正在载入数据...
正在载入数据...
正在载入数据...
正在载入数据...
正在载入数据...
正在载入数据...
正在载入数据...
正在链接到云南高校图书馆文献保障联盟下载...
云南高校图书馆联盟文献共享服务平台 版权所有©
您的IP:3.137.202.126