TY - JOUR N2 - Automation of data processing of contactless diagnostics (detection) of the technical condition of the majority of nodes and aggregates of railway transport (RWT) minimizes the damage from failures of these systems in operating modes. This becomes possible due to the rapid detection of serious defects at the stage of their origin. Basically, in practice, the control of the technical condition of the nodes and aggregates of the RWT is carried out during scheduled repairs. It is not always possible to identify incipient defects. Consequently, it is not always possible to warn personnel (machinists, repairmen, etc.) of significant damage to the RWT systems until their complete failure. The difficulties of obtaining diagnostic information is that there is interdependence between the main nodes of the RWT. This means that if physical damage occurs at any of the RWT nodes, in other nodes there can also occur malfunctions. As the main way to improve the efficiency of state detection of the nodes and aggregates of RWT, we see the direction of giving the adaptability property for an automated data processing system from various contactless diagnostic information removal systems. The global purpose can be achieved, in particular, through the use of machine learning methods and failure recognition (recognition objects). In order to improve the operational reliability and service life of the main nodes and aggregates of RWT, there are proposed an appropriate model and algorithm of machine learning of the operator control system of nodes and aggregates. It is proposed to use the Shannon normalized entropy measure and the Kullback-Leibler distance information criterion as a criterion of the learning effectiveness of the automated detection system and operator node state control of RWT. The article describes the application of the proposed method on the example of an automatic detection system (ADS) of the state of a traction motor of an electric locomotive. There are given the test data of the model and algorithm in the MATLAB environment. L1 - http://journals.pan.pl/Content/113308/PDF/66.pdf L2 - http://journals.pan.pl/Content/113308 PY - 2019 IS - No 3 EP - 496 DO - 10.24425/ijet.2019.129804 KW - information intellectual technology of failure detection KW - functional control KW - learning matrix KW - learning algorithm KW - operator effectiveness criterion KW - nodes and aggregates KW - railway transport A1 - Akhmetov, Bakhytzhan A1 - Lakhno, Valeriy A1 - Oralbekova, Ayaulym A1 - Kaskatayev, Zhanat A1 - Mussayeva, Gulmira PB - Polish Academy of Sciences Committee of Electronics and Telecommunications VL - vol. 65 DA - 2019.09.06 T1 - Automated Self-trained System of Functional Control and State Detection of Railway Transport Nodes SP - 491 UR - http://journals.pan.pl/dlibra/publication/edition/113308 T2 - International Journal of Electronics and Telecommunications ER -