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|a Mansor, Muhammad Saiful Badri
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|a Zakaria, Zulkarnay
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|a Balkhis, Ibrahim
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|a Abdul Rahim, Ruzairi
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|a Abdul Sahib, Mohd. Fadzli
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|a Md. Yunos, Yusri
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|a Sahlan, Shafishuhaza
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|a Bunyamin, Salinda
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|a Abas, Khairul Hamimah
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|a Ishak, Mohd. Hafis Izran
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|a Danapalasingam, Kumeresan A.
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|a Magnetic induction tomography: a brief review
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|b Penerbit UTM Press,
|c 2015-02.
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|z Get fulltext
|u http://eprints.utm.my/id/eprint/56087/1/RuzairiAbdulRahim2015_MagneticInductionTomographyaBriefReview.pdf
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|a Magnetic Induction Tomography (MIT) is a contactless non-invasive imaging technique that interested in mapping the passive electrical properties of a material; conductivity, permittivity and permeability. This paper presents the criteria and previous functional specification involving the development of MIT, focusing in conductivity imaging. Various ways have been implemented from a simple electronic configuration of the front-end sensory circuit, data acquisition system, reconstruction algorithm and graphical user interfacing (GUI) tools. Induction sensors are paramount as it does provide the signal source for time varying magnetic field to the coils. The advantages and limitations of MIT are also presented. Many more advancement can be expected to enhance the lack of MIT especially in spatial resolution and dynamic response of the sensor.
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|a T Technology (General)
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