@Article{cmc.2023.032557, AUTHOR = {Bin Lin, Zhengyu Li, Dong Wen, Jianchao Liu, Shan Yang, Yong Zhou, Chao Lu, Qian Qiu,5}, TITLE = {The Fusion Model of Catalytic Combustion and Thermal Conductivity}, JOURNAL = {Computers, Materials \& Continua}, VOLUME = {74}, YEAR = {2023}, NUMBER = {1}, PAGES = {1509--1521}, URL = {http://www.techscience.com/cmc/v74n1/49865}, ISSN = {1546-2226}, ABSTRACT = {The further development of catalytic elements has been plagued by activation and binary problems. The automatic shift model that has emerged in recent years helps components achieve full range. However, the detection data still remains unstable in the shift area (7%~13%). This paper proposes a Catalytic Combustion and Thermal Conductivity (CCTC) model for the specified range, which can be explained from two aspects based on the existing methods. On the one hand, it uses iterative location search to process heterogeneous data, judges the prediction position of data points, and then gives weight evaluation. On the other hand, it corrects the abnormal points, determines the abnormal points in the horizontal direction, and gives the replacement value through the data of adjacent points. The experimental results show that the CCTC model reduces the sum of variance from 17 of the automatic shift model to 13, and the comparison of experimental variance is reduced by 23%. In the full-scale real-time data, the experimental variance of CCTC model and automatic shift model is reduced by 18%. In conclusion, CCTC is a cross section stability framework for full-scale methane measurement, in which the specified heterogeneous combination and anomaly point correction methods improve the stability.}, DOI = {10.32604/cmc.2023.032557} }