Smart homes are changing with each passing day, and home automation has become a trend, with broad application prospects. This study is based on the design of the remote electrical control system for smart homes combined with the application of new ferroelectric material technology to conduct experiments, aiming to demonstrate the feasibility of adding new ferroelectric materials to improve the functions and performance of the remote electrical control system. The article first introduces the concepts and development of electrical control systems, smart home remote control and other parts in detail, which are applied to cloud computing, digital control systems, etc. Based on the previous theoretical foundation, this research also designs and implements a rule-based smart home device linkage engine, and expands the existing components of the "smart home platform" to add the ability to support device linkage, and finally realize a complete device linkage function. This part focuses on the performance of ferroelectric materials. Experimental results show that the smart home remote electrical control system designed by this research has been optimized to a large extent after applying new ferroelectric material technology. From the data obtained in this study, whether it is in the data transmission module or the receiving module, the stability and reliability of this process are more superior than the conventional electrical control system. Among them, from the perspective of stability, before the ferroelectric material is added, the stability of the data receiving and sending module of the conventional electrical control system is at a relatively low level. The application of ferroelectric materials makes the test results greater than 6 and even reaches 8.19 in the data receiving module.

Handelzalts Shirley. New Ferroelectric Material Technology in Remote Electrical Control System of Smart Home. Distributed Processing System (2021), Vol. 2, Issue 1: 58-74. https://doi.org/10.38007/DPS.2021.020105.

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