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DTSTAMP:20190329T112521Z
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DTSTART;TZID=Asia/Kolkata:20190329T120000
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DESCRIPTION:Electromagnetic Interference (EMI) is becoming an exceptionally
  crucial issue in the era of modern electronics and electrical equipment. 
 All these equipments and systems pose a serious environmental pollution pr
 oblem in the form of unwanted electromagnetic emission\, which is known as
  Electromagnetic Interference (EMI). An electronic system that is able to 
 function compatibly with other electronic systems and not produce or be su
 sceptible to interface is said to be electromagnetically compatible with i
 ts environment. Designing for EMC is not only important for the desired fu
 nctional performance\, but the device must also meet legal requirements in
  virtually all countries of the world before it can be sold. The transfer 
 of electromagnetic energy (with regard to the prevention of interference) 
 can be divided into four subgroups: radiated emissions\, radiated suscepti
 bility\, conducted emissions\, and conducted susceptibility. To avoid this
  EMI related problems\, different regulatory committees in different count
 ries had specified some standards of electromagnetic emission such as the 
 Federal Communications Commission (FCC) in the US\, VDE (Germany)\, CISPR 
 and IEC (International) and so on. The frequency range of conducted emissi
 on standards extends from 450 KHz to 30 MHz and that for radiated emission
 s begins at 30 MHz and extends to 40 GHz. By measuring the radiated electr
 ic field due to that equipment\, the compliance of the devices conforming 
 to the standards of interference is tested. The measurement is performed i
 nside an anechoic chamber\, Gigahertz Transverse Electromagnetic (GTEM) Ce
 ll\, shielded chamber or in Open Area Test Site (OATS) which are made free
  from other electromagnetic radiation by putting the receiver at a specifi
 c distance from the device under test. The EMI sensors in common use are d
 ipoles or loop antennas (e.g. Anritsu dipole MP651A / B). The Electromagne
 tic Group of Department of E & ECE\, I.I.T. Kharagpur has been engaged on 
 the studies of analysis\, design and development of Gigahertz Transverse E
 lectromagnetic (GTEM) Cell and also different low and high frequency EMI s
 ensors.\n\nSpeaker(s): Prof. Ajay Chakrabarty\, \n\nAgenda: \nElectromagne
 tic Interference (EMI) and Electromagnetic Compatibility (EMC)\n\nBldg: EC
 E\, Conference room\, IIT Roorkee\, Roorkee\, Uttaranchal\, India\, 247667
LOCATION:Bldg: ECE\, Conference room\, IIT Roorkee\, Roorkee\, Uttaranchal\
 , India\, 247667
ORGANIZER:ieee.mtts.iitr.sbc@gmail.com
SEQUENCE:0
SUMMARY:Electromagnetic Interference (EMI) and Electromagnetic Compatibilit
 y (EMC)
URL;VALUE=URI:https://events.vtools.ieee.org/m/196770
X-ALT-DESC:Description: <br /><p><strong>&nbsp\;</strong><span style="font-
 family: 'Times New Roman'\, serif\;">Electromagnetic Interference (EMI) is
  becoming an exceptionally crucial issue in the era&nbsp\;of modern electr
 onics and electrical equipment. All these equipments&nbsp\;and systems pos
 e a&nbsp\;</span>serious environmental pollution problem in the form of un
 wanted electromagnetic&nbsp\;emission\, which is known as Electromagnetic 
 Interference (EMI). An electronic system&nbsp\;that is able to function co
 mpatibly with other electronic systems and not produce or be&nbsp\;suscept
 ible to interface is said to be electromagnetically compatible with its en
 vironment.&nbsp\;Designing for EMC is not only important for the desired f
 unctional performance\, but the&nbsp\;device must also meet legal requirem
 ents in virtually all countries of the world before it&nbsp\;can be sold. 
 The transfer of electromagnetic energy (with regard to the prevention of&n
 bsp\;interference) can be divided into four subgroups: radiated emissions\
 , radiated&nbsp\;susceptibility\, conducted emissions\, and conducted susc
 eptibility. To avoid this EMI&nbsp\;related problems\, different regulator
 y committees in different countries had specified&nbsp\;some standards of 
 electromagnetic emission such as the Federal Communications&nbsp\;Commissi
 on (FCC) in the US\, VDE (Germany)\, CISPR and IEC (International) and so&
 nbsp\;on. The frequency range of conducted emission standards extends from
  450 KHz to 30&nbsp\;MHz and that for radiated emissions begins at 30 MHz 
 and extends to 40 GHz. By&nbsp\;measuring the radiated electric field due 
 to that equipment\, the compliance of the devices&nbsp\;conforming to the 
 standards of interference is tested. The measurement is performed&nbsp\;in
 side an anechoic chamber\, Gigahertz Transverse Electromagnetic (GTEM) Cel
 l\,&nbsp\;shielded chamber or in Open Area Test Site (OATS) which are made
  free from other&nbsp\;electromagnetic radiation by putting the receiver a
 t a specific distance from the device&nbsp\;under test. The EMI sensors in
  common use are dipoles or loop antennas (e.g. Anritsu&nbsp\;dipole MP651A
  / B). The Electromagnetic Group of Department of E &amp\; ECE\, I.I.T.&nb
 sp\;Kharagpur has been engaged on the studies of analysis\, design and dev
 elopment of&nbsp\;Gigahertz Transverse Electromagnetic (GTEM) Cell and als
 o different low and high&nbsp\;frequency EMI sensors.</p><br /><br />Agend
 a: <br /><p>Electromagnetic Interference (EMI) and Electromagnetic Compati
 bility (EMC)</p>
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