HEAL DSpace

A FEM simulation study of the optimization of the imaging attributes of a microwave radiometry system with possible functional imaging capabilities

Αποθετήριο DSpace/Manakin

Εμφάνιση απλής εγγραφής

dc.contributor.author Karathanasis, KT en
dc.contributor.author Karanasiou, IS en
dc.contributor.author Uzunoglu, NK en
dc.date.accessioned 2014-03-01T01:29:32Z
dc.date.available 2014-03-01T01:29:32Z
dc.date.issued 2009 en
dc.identifier.issn 1748-0221 en
dc.identifier.uri https://dspace.lib.ntua.gr/xmlui/handle/123456789/19294
dc.subject Models and simulations en
dc.subject Simulation methods and programs en
dc.subject.classification Instruments & Instrumentation en
dc.subject.other IN-VIVO en
dc.subject.other BRAIN TEMPERATURE en
dc.subject.other SPECTROSCOPY en
dc.subject.other THERMOMETRY en
dc.title A FEM simulation study of the optimization of the imaging attributes of a microwave radiometry system with possible functional imaging capabilities en
heal.type journalArticle en
heal.identifier.primary 10.1088/1748-0221/4/06/P06005 en
heal.identifier.secondary http://dx.doi.org/10.1088/1748-0221/4/06/P06005 en
heal.identifier.secondary P06005 en
heal.language English en
heal.publicationDate 2009 en
heal.abstract Microwave radiometry is a measurement technique which detects natural-thermal radiation emitted by matter. The human brain having certain temperature and specific electromagnetic properties emits chaotic radiation throughout the whole electromagnetic spectrum. A novel Microwave Radiometry Imaging System (MiRaIS) comprising an ellipsoidal conductive wall cavity and sensitive radiometric receivers, operating at low microwave frequencies (1-4GHz), has been used the past four years in various experiments to assess its value as a potential intracranial imaging device. With this view, current research aims at the improvement of the system's focusing properties using matching layers made of dielectric and left handed materials that are placed around a double layered human head model. Another approach tested, included filling of the whole ellipsoidal with a lossless dielectric material in conjunction with reduction of the ellipsoid's volume. The results show better focusing properties in the brain areas of interest and improvement of the system's spatial resolution. Future research including mainly phantom and human experiments implementing the above ideas will illustrate the value of the present simulation study. en
heal.publisher IOP PUBLISHING LTD en
heal.journalName JOURNAL OF INSTRUMENTATION en
dc.identifier.doi 10.1088/1748-0221/4/06/P06005 en
dc.identifier.isi ISI:000267942500016 en
dc.identifier.volume 4 en


Αρχεία σε αυτό το τεκμήριο

Αρχεία Μέγεθος Μορφότυπο Προβολή

Δεν υπάρχουν αρχεία που σχετίζονται με αυτό το τεκμήριο.

Αυτό το τεκμήριο εμφανίζεται στην ακόλουθη συλλογή(ές)

Εμφάνιση απλής εγγραφής