BEGIN:VCALENDAR
VERSION:2.0
PRODID:IEEE vTools.Events//EN
CALSCALE:GREGORIAN
BEGIN:VTIMEZONE
TZID:Australia/Sydney
BEGIN:DAYLIGHT
DTSTART:20201004T030000
TZOFFSETFROM:+1000
TZOFFSETTO:+1100
RRULE:FREQ=YEARLY;BYDAY=1SU;BYMONTH=10
TZNAME:AEDT
END:DAYLIGHT
BEGIN:STANDARD
DTSTART:20200405T020000
TZOFFSETFROM:+1100
TZOFFSETTO:+1000
RRULE:FREQ=YEARLY;BYDAY=1SU;BYMONTH=4
TZNAME:AEST
END:STANDARD
END:VTIMEZONE
BEGIN:VEVENT
DTSTAMP:20200818T014519Z
UID:DDEA6859-1630-4842-84F8-BCC003140E28
DTSTART;TZID=Australia/Sydney:20200813T170000
DTEND;TZID=Australia/Sydney:20200813T180000
DESCRIPTION:Zoom Link: https://macquarie.zoom.us/u/ab5UH9fHA4\n\nhttps://ma
 cquarie.zoom.us/j/99098372785?pwd=NS8vOWJmdFEzUkhkRHEyU0M5KzNVdz09\n\nAbst
 ract: Magnetic sensors are one of the most pervasive sensors in industry a
 nd consumer devices. They have a very long history starting with the compa
 ss more than 2000 years ago. Many different magnetic sensors have been dev
 eloped\, exploiting various physical principles\, to obtain optimized perf
 ormance for specific applications with respect to sensitivity\, power cons
 umption\, size\, field range or resolution. In the era of ubiquitous sensi
 ng\, wearable devices and smart things\, the unique features of magnetic s
 ensing systems put them at the forefront of novel applications and new fea
 tures. This presentation provides insights into latest developments on fle
 xible magnetic skins and sensors\, which feature high performance\, biocom
 patibility and conformability. Such devices are employed in biomedical ins
 truments\, marine monitoring\, or machine-user interfaces\, enhancing func
 tionalities and capabilities. Flexible and wearable magnetic sensor system
 s can extend our senses\, provide contactless control or steering and add 
 intriguing new functionalities to our natural capabilities. Examples are f
 lexible magnetic tunnel junction sensors\, which are employed for 3-axes o
 rientation monitoring on biomedical instruments. On the other end of the s
 pectrum are printed graphene Hall effect sensors with less sensitivity but
  high temperature and corrosion resistance. Magnetic composites made of po
 lymers with magnetic materials as fillers combine mechanical flexibility w
 ith magnetic functionality. Such materials have been integrated with magne
 tic sensors to form bioinspired artificial cilia sensors\, resulting in lo
 w-power tactile sensors with multifunctional capabilities as artificial sk
 ins\, for flow sensing or brail reading. Ultra-flexible magnetic skins can
  be worn like tattoos or camouflaged with the color of the skin tone and e
 nable wireless operations\, ranging from tracking of eye movements to hand
 s-off machine control. Modern fabrication processes combined with the adva
 ntages of magnetic sensor systems are a strong combination\, which can lea
 d to a myriad of new sensor solutions and benefit smart things\, robotics\
 , medical devices and much more.\n\nCo-sponsored by: Prof. Subhas Mukhopad
 hyay\n\nSpeaker(s): Jürgen Kosel\, Dr. \, \n\nVia Zoom\, https://macquari
 e.zoom.us/u/ab5UH9fHA4  \, Sydney\, New South Wales\, Australia\, 2119
LOCATION:Via Zoom\, https://macquarie.zoom.us/u/ab5UH9fHA4  \, Sydney\, New
  South Wales\, Australia\, 2119
ORGANIZER:Subhas.Mukhopadhyay@mq.edu.au
SEQUENCE:2
SUMMARY:Wearable Magnetic Skins and Sensors 
URL;VALUE=URI:https://events.vtools.ieee.org/m/236106
X-ALT-DESC:Description: <br /><p>Zoom Link: <a href="https://macquarie.zoom
 .us/u/ab5UH9fHA4">https://macquarie.zoom.us/u/ab5UH9fHA4</a> &nbsp\;</p>\n
 <p><a href="https://macquarie.zoom.us/j/99098372785?pwd=NS8vOWJmdFEzUkhkRH
 EyU0M5KzNVdz09">https://macquarie.zoom.us/j/99098372785?pwd=NS8vOWJmdFEzUk
 hkRHEyU0M5KzNVdz09</a></p>\n<p>Abstract: Magnetic sensors are one of the m
 ost pervasive sensors in industry and consumer devices. They have a very l
 ong history starting with the compass more than 2000 years ago. Many diffe
 rent magnetic sensors have been developed\, exploiting various physical pr
 inciples\, to obtain optimized performance for specific applications with 
 respect to sensitivity\, power consumption\, size\, field range or resolut
 ion. In the era of ubiquitous sensing\, wearable devices and smart things\
 , the unique features of magnetic sensing systems put them at the forefron
 t of novel applications and new features. This presentation provides insig
 hts into latest developments on flexible magnetic skins and sensors\, whic
 h feature high performance\, biocompatibility and conformability. Such dev
 ices are employed in biomedical instruments\, marine monitoring\, or machi
 ne-user interfaces\, enhancing functionalities and capabilities. Flexible 
 and wearable magnetic sensor systems can extend our senses\, provide conta
 ctless control or steering and add intriguing new functionalities to our n
 atural capabilities. Examples are flexible magnetic tunnel junction sensor
 s\, which are employed for 3-axes orientation monitoring on biomedical ins
 truments. On the other end of the spectrum are printed graphene Hall effec
 t sensors with less sensitivity but high temperature and corrosion resista
 nce. Magnetic composites made of polymers with magnetic materials as fille
 rs combine mechanical flexibility with magnetic functionality. Such materi
 als have been integrated with magnetic sensors to form bioinspired artific
 ial cilia sensors\, resulting in low-power tactile sensors with multifunct
 ional capabilities as artificial skins\, for flow sensing or brail reading
 . Ultra-flexible magnetic skins can be worn like tattoos or camouflaged wi
 th the color of the skin tone and enable wireless operations\, ranging fro
 m tracking of eye movements to hands-off machine control. Modern fabricati
 on processes combined with the advantages of magnetic sensor systems are a
  strong combination\, which can lead to a myriad of new sensor solutions a
 nd benefit smart things\, robotics\, medical devices and much more.</p>
END:VEVENT
END:VCALENDAR