{"title":"CAD Model of Cole Cole Representation for Analyzing Performance of Microstrip Moisture Sensing Applications","authors":"Settapong Malisuwan, Jesada Sivaraks, Wasan Jaiwong, Veerapat Sanpanich","volume":81,"journal":"International Journal of Electrical and Computer Engineering","pagesStart":1140,"pagesEnd":1145,"ISSN":"1307-6892","URL":"https:\/\/publications.waset.org\/pdf\/16613","abstract":"
In the past decade, the development of microstrip
\r\nsensor application has evolved tremendously. Although cut and trial
\r\nmethod was adopted to develop microstrip sensing applications in the
\r\npast, Computer-Aided-Design (CAD) is a more effective as it ensures
\r\nless time is consumed and cost saving is achieved in developing
\r\nmicrostrip sensing applications. Therefore microstrip sensing
\r\napplications has gained popularity as an effective tool adopted in
\r\ncontinuous sensing of moisture content particularly in products that is
\r\nadministered mainly by liquid content. In this research, the Cole-Cole
\r\nrepresentation of reactive relaxation is applied to assess the
\r\nperformance of the microstrip sensor devices. The microstrip sensor
\r\napplication is an effective tool suitable for sensing the moisture
\r\ncontent of dielectric material. Analogous to dielectric relaxation
\r\nconsideration of Cole-Cole diagrams as applied to dielectric
\r\nmaterials, a “reactive relaxation concept” concept is introduced to
\r\nrepresent the frequency-dependent and moisture content
\r\ncharacteristics of microstrip sensor devices.<\/p>\r\n","references":"
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