PROVISION OF RELIABILITY OF HOMOGENEOUS REGISTER MEDIA WITH PROGRAMMED SLIDING REDUNDANCY STRUCTURE

Objectives. The aim of the work is to solve reliability problems associated with the improvement of neural linear homogeneous media by means of the sliding structural redundancy method. Method. In the course of the studythe most effective method of ensuring product reliability structural redundancy, while in the structure of the product, along with the ―basic‖ elements, additional elements are included, which substitute for the function in cases where others have failed. Results. It is proposed that functional models of media elements be oriented towards the presence of their internal redunant elements; on the basis of the established functional dependence of the number of external redundant elements with the number of internal redundant elements, we calculated the reliability of redundant media, thus confirming reliability improvement. A comparative analysis of the existing functional element and their development is presented. A reliability calculation for homogeneous linear neural environments both with and without the presence of redundant components clearly demonstrates the numerous advantage of homogeneous linear neural environments with redundant elements. The necessity of the information exchange of connections among the elements of the environment when changing the redundancy ratio are also shown. Conclusion. The approach proposes to improve the reliability of media using elements which have existing connections with numerous other elements in the media, using ―informational redundancy‖ and the redundant elements within the structure, enabling the creation of homogeneous high reliability media with the possibility of ―information control‖. The proposed element enables the construction of media providing the ability to ―control‖ two failed elements, which implies the presence in the environment of two redundant elements that can be replaced in the case of the failure of any pair of key elements. 

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