Thermal Wave Variation Anticipation under Minute Scale Time-Advance with Low-Pass NGD Digital Circuit

• Published in: IEEE access Vol. 10; p. 1
• Main Authors: Ravelo, Blaise, Guerin, Mathieu, Frnda, Jaroslav, Rajaoarisoa, Lala, Rahajandraibe, Wenceslas
• Format: Journal Article
• Language: English
• Published: Piscataway IEEE 01.01.2022; The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
• Subjects: Building control; Circuit design; Control systems; Data processing; Digital electronics; Engineering Sciences; Experimental study; Experimentation; Frequency analysis; Frequency domain analysis; Group delay; Group delay (NGD); Low-pass (LP) NGD; Mathematical analysis; Microcontrollers; Negative group delay (NGD); NGD analysis method; NGD application; NGD design; NGD digital circuit; Real time; Real-time anticipation; Room temperature; Sensors; Smart sensors; System failures; Thermal wave; Time-advance; Waveforms; Negative group delay (NGD); NGD application; Thermal wave; Experimental study; NGD digital circuit; NGD analysis method; Real-time anticipation; Time-advance; Low-pass (LP) NGD; NGD design
• ISSN: 2169-3536; 2169-3536
• DOI: 10.1109/ACCESS.2022.3226514

Over the emerging industry 4.0 era, the building control system performance depends on the development of smart sensor technology. Nowadays, the building control engineers challenge on the design of high-capacity smart sensor susceptible to operate with high speed of data processing. In this context, this paper introduces a pioneer research work on the negative group delay (NGD) circuit original application for room temperature anticipation useful for smart-building control. The real-time anticipation of sensor data by using a low-pass (LP) NGD digital circuit is studied. This approach enables minimizing the latency time for optimizing control action. The unfamiliar LP-NGD digital circuit design method and theoretical formulation are described for anticipating thermal wave experimentation in real-time. The digital circuit equation coefficients are computed regarding the time-advance of anticipated thermal completely arbitrary waveform signal. The main interest of using the NGD method-based for thermal wave anticipation regarding temperature variation from heater and freezer control is demonstrated. The anticipation feasibility is illustrated from the minute scale time-advance LP-NGD digital circuit implemented on the STM32® microcontroller unit. The NGD characterization is performed from frequency domain analysis and cosine waveform pulse transient test. Then, the -30 seconds to -10 seconds real-time-advance of temperature variation is verified by calculation and experimentation. The present study result opens a promising NGD method application for the advanced fault control of a future industrial system by anticipating system failures.