| Form of presentation | Articles in international journals and collections |
| Year of publication | 2023 |
| Язык | английский |
|
Akhmedova Alfira Mazitovna, author
Burnashev Rustam Arifovich, author
Enikeev Arslan Ilyasovich, author
|
|
Bolsunovskaya Marina Vladimirovna, author
|
|
Amer Ismail F O, postgraduate kfu
|
|
Enikeeva Adelya Iskanderovna, author
|
| Bibliographic description in the original language |
Burnashev R.A., Enikeeva A., Amer I.F., Akhmedova A.M., Bolsunovskaya M.V., Enikeev A.I. Building a fuzzy expert system for assessing the severity of pneumonia // Lecture Notes in Networks and Systems, 2023, 544 LNNS, pp. 380–396
|
| Annotation |
The paper describes the process of building a fuzzy expert system for assessing the severity of pneumonia. The use of fuzzy logic is an urgent direction in cases of incomplete certainty when making a medical diagnosis. Human health depends on making the right decision, as it can be difficult for a doctor to choose the correct diagnosis and treatment of pneumonia. To develop a medical expert system, we considered scales and algorithms for assessing the prognosis of the severity of community-acquired pneumonia PORT (PSI), CURB/CRB-65 and SMART-COP/SMART-CO. We strive to contribute the results of our research to the development of medical software products, namely, to increase the efficiency of medical services using artificial intelligence. Python and Prolog programming languages were used to develop the client-server application. The Django framework was used to develop the client part, and the PySwip module was used to process knowledge bases. The knowledge base of the expert system was developed using the SWI-Prolog software environment, which supports the necessary software libraries that provide the construction of the graphical shell of the expert system, as well as dynamic processing of fuzzy rules. The paper outlines the main stages of the life cycle of creating a system using fuzzy logic, which include all the key stages of system design. To test the knowledge base, a graphical interface of the system was developed using the XPCE cross-platform library, which is included in the SWI-Prolog software environment. The purpose of the study is to develop and implement a software module using fuzzy logical inference in a medical information system. |
| Keywords |
Expert systems; Fuzzy logic; Knowledge base; SWI-Prolog |
| The name of the journal |
Lecture Notes in Computer Science
|
| URL |
https://www.scopus.com/record/display.uri?eid=2-s2.0-85138316696&doi=10.1007%2f978-3-031-16075-2_27&origin=inward&txGid=6a72d6a5baad287ca52b0ef7686c71b1 |
| Please use this ID to quote from or refer to the card |
https://repository.kpfu.ru/eng/?p_id=278375&p_lang=2 |
Full metadata record  |
| Field DC |
Value |
Language |
| dc.contributor.author |
Akhmedova Alfira Mazitovna |
ru_RU |
| dc.contributor.author |
Burnashev Rustam Arifovich |
ru_RU |
| dc.contributor.author |
Enikeev Arslan Ilyasovich |
ru_RU |
| dc.contributor.author |
Bolsunovskaya Marina Vladimirovna |
ru_RU |
| dc.contributor.author |
Enikeeva Adelya Iskanderovna |
ru_RU |
| dc.contributor.author |
Amer Ismail F O |
ru_RU |
| dc.date.accessioned |
2023-01-01T00:00:00Z |
ru_RU |
| dc.date.available |
2023-01-01T00:00:00Z |
ru_RU |
| dc.date.issued |
2023 |
ru_RU |
| dc.identifier.citation |
Burnashev R.A., Enikeeva A., Amer I.F., Akhmedova A.M., Bolsunovskaya M.V., Enikeev A.I. Building a fuzzy expert system for assessing the severity of pneumonia // Lecture Notes in Networks and Systems, 2023, 544 LNNS, pp. 380–396
|
ru_RU |
| dc.identifier.uri |
https://repository.kpfu.ru/eng/?p_id=278375&p_lang=2 |
ru_RU |
| dc.description.abstract |
Lecture Notes in Computer Science |
ru_RU |
| dc.description.abstract |
The paper describes the process of building a fuzzy expert system for assessing the severity of pneumonia. The use of fuzzy logic is an urgent direction in cases of incomplete certainty when making a medical diagnosis. Human health depends on making the right decision, as it can be difficult for a doctor to choose the correct diagnosis and treatment of pneumonia. To develop a medical expert system, we considered scales and algorithms for assessing the prognosis of the severity of community-acquired pneumonia PORT (PSI), CURB/CRB-65 and SMART-COP/SMART-CO. We strive to contribute the results of our research to the development of medical software products, namely, to increase the efficiency of medical services using artificial intelligence. Python and Prolog programming languages were used to develop the client-server application. The Django framework was used to develop the client part, and the PySwip module was used to process knowledge bases. The knowledge base of the expert system was developed using the SWI-Prolog software environment, which supports the necessary software libraries that provide the construction of the graphical shell of the expert system, as well as dynamic processing of fuzzy rules. The paper outlines the main stages of the life cycle of creating a system using fuzzy logic, which include all the key stages of system design. To test the knowledge base, a graphical interface of the system was developed using the XPCE cross-platform library, which is included in the SWI-Prolog software environment. The purpose of the study is to develop and implement a software module using fuzzy logical inference in a medical information system. |
ru_RU |
| dc.language.iso |
ru |
ru_RU |
| dc.subject |
|
ru_RU |
| dc.title |
Building a fuzzy expert system for assessing the severity of pneumonia |
ru_RU |
| dc.type |
Articles in international journals and collections |
ru_RU |
|
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