以信息熵控制作为生产系统控制手段的图形动力系统

Q4 Materials Science

Radioelektronika, Nanosistemy, Informacionnye Tehnologii Pub Date : 2023-01-19 DOI:10.17587/it.29.47-50

Y. Polishuk

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引用次数: 0

摘要

确保产品质量和提高生产系统运行的安全水平是所有行业的主要任务。第二项任务与危险性增加的技术系统最为相关，其中包括石油和天然气工业的生产系统。生产系统的管理和选定任务的解决由决策者进行，使用在系统诊断和监测过程中获得的参数。生产系统诊断参数复合体的形成由决策者在考虑到信息丢失的情况下实施，其特点是参数控制不完全。在识别生产系统的状态时，决策者不仅要考虑诊断参数的值，还要考虑它们所形成的系统信息熵的值，因为“熵表征了控制的不确定性，即其管理质量”。因此，只有决策者对系统的信息熵进行强制控制，才能对生产系统的状态进行识别和管理。后者证实了控制系统的综合与控制其信息熵状态的相关性。把生产系统看作是一个图形动力学系统。表征其输入、输出、内部状态和控制动作的数据将以图形的形式呈现。决策者通过对诊断参数的分析，确定生产系统的状态。诊断参数的获取和分析需要花费一定的时间，在某些情况下，这些时间可能会很重要，并导致被控系统的信息熵值增加，从而导致系统的实际状态与决策者处理的图像不匹配。在大型生产系统的情况下，考虑到资金限制或其他原因，可能会违反对系统诊断参数的监测频率。这将导致被控系统的信息熵显著增加，从而导致其控制质量较低。本文提出的集束系统的控制方法，通过对集束系统的信息熵状态进行控制，可以提高集束系统的控制质量。开发的收集凝析油田产品的集热器束系统数据存储的图形动态模型使决策者能够分析其在任何运行时期的状态。

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Graphodynamic System with Information Entropy Control as a Means of Control of Production Systems

Ensuring the quality of products and increasing the level of safety in the operation of production systems are the main tasks of all industries. The second task is the most relevant for technogenic systems of increased danger, which include, among other things, the production systems of the oil and gas industry. The management of production systems and the solution of selected tasks is carried out by the decision maker, using the parameters obtained during the diagnosis and monitoring of the system. The formation of a complex of diagnostic parameters of the production system is implemented by the decision maker, taking into account the loss of information, characterized by incomplete control of the parameters. When identifying the state of the production system, the decision maker must take into account not only the values of diagnostic parameters, but also the value of the information entropy of the system that they form, since "entropy characterizes the uncertainty of control, i.e. its management quality". Thus, the identification of the state of the production system and its management are only possible with the mandatory control of the information entropy of the system by the decision maker. The latter confirms the relevance of the synthesis of control systems with control of the state of their information entropy. Consider the production system as a graphodynamic system. The data characterizing its input, output, internal state and control action will be presented in the form of graphs. Through the analysis of diagnostic parameters, the decision maker identifies the state of the production system. A certain time is spent on obtaining and analyzing diagnostic parameters, which in some cases can be significant and lead to an increase in the value of the information entropy of the controlled system, which leads to a mismatch between the actual state of the system and its image processed by the decision maker. In the conditions of big production systems, taking into account funding constraints or other reasons, the frequency of monitoring the diagnostic parameters of the system may be violated. This leads to a significant increase in the information entropy of the controlled system and, accordingly, to a low quality of its control. The proposed method for controlling a collector-beam system for collecting products from a gas condensate field makes it possible to improve the quality of its control by implementing control of its state of information entropy. The developed graph-dynamic model of data storage of a collector-beam system for collecting gas condensate field products allows the decision maker to analyze its state in any period of operation.

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来源期刊

Radioelektronika, Nanosistemy, Informacionnye Tehnologii Materials Science-Materials Science (miscellaneous)

CiteScore

0.60

自引率

0.00%

发文量

期刊介绍： Journal “Radioelectronics. Nanosystems. Information Technologies” (abbr RENSIT) publishes original articles, reviews and brief reports, not previously published, on topical problems in radioelectronics (including biomedical) and fundamentals of information, nano- and biotechnologies and adjacent areas of physics and mathematics. The authors of the journal are academicians, corresponding members and foreign members of the Russian Academy of Natural Sciences (RANS) and their colleagues, as well as other russian and foreign authors on the proposal of the members of RANS, which can be obtained by the author before sending articles to the editor or after its arrival on the recommendation of a member of the editorial board or another member of the RANS, who gave the opinion on the article at the request of the editior. The editors will accept articles in both Russian and English languages. Articles are internally peer reviewed (double-blind peer review) by members of the Editorial Board. Some articles undergo external review, if necessary. Designed for researchers, graduate students, physics students of senior courses and teachers. It turns out 2 times a year (that includes 2 rooms)