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PRODID:IEEE vTools.Events//EN
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TZID:Brazil/East
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DTSTART:20380119T001407
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DTSTART:20190216T230000
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BEGIN:VEVENT
DTSTAMP:20211125T224639Z
UID:89633994-13DF-449D-A16C-50BF4EB7DD76
DTSTART;TZID=Brazil/East:20210730T160000
DTEND;TZID=Brazil/East:20210730T170000
DESCRIPTION:Nowadays\, most electronic-powered devices have a Battery Manag
 ement System (BMS) architecture designed and implemented running a set of 
 mechanisms to protect the battery from anomalous behavior. A battery manag
 ement system working in a smartphone is very similar to the one operating 
 an electric car's battery. However\, the functionality of these two system
 s may be totally different. The design complexity depends on the battery c
 haracteristics that you need to monitor with your BMS. Normally\, BMS feat
 ures include monitoring the battery cells\, controlling the recharge phase
  (with charge equalization between the cells)\, and estimating the interna
 l states of the battery (i.e. state of charge (SOC)). Advanced BMS should 
 also be able to provide an accurate estimation of SOH\, from which the rem
 aining useful life (RUL) and the end of life (EOL) of the battery can be c
 alculated. Power management is addressed in the context of embedded system
 s from energy-aware design to energy-efficient implementation. Here\, you 
 will get to know more about BMS functionality\, and battery states and how
  you can estimate them by an embedded system.\n\nSpeaker(s): Janislley Oli
 veira\, \n\nVirtual: https://events.vtools.ieee.org/m/278371
LOCATION:Virtual: https://events.vtools.ieee.org/m/278371
ORGANIZER:yp.northeastbr@ieee.org
SEQUENCE:1
SUMMARY:Embedded Software Overview for Battery Management Systems (BMS)
URL;VALUE=URI:https://events.vtools.ieee.org/m/278371
X-ALT-DESC:Description: <br /><p>Nowadays\, most electronic-powered devices
  have a Battery Management System (BMS) architecture designed and implemen
 ted running a set of mechanisms to protect the battery from anomalous beha
 vior. A battery management system working in a smartphone is very similar 
 to the one operating an electric car's battery. However\, the functionalit
 y of these two systems may be totally different. The design complexity dep
 ends on the battery characteristics that you need to monitor with your BMS
 . Normally\, BMS features include monitoring the battery cells\, controlli
 ng the recharge phase (with charge equalization between the cells)\, and e
 stimating the internal states of the battery (i.e. state of charge (SOC)).
  Advanced BMS should also be able to provide an accurate estimation of SOH
 \, from which the remaining useful life (RUL) and the end of life (EOL) of
  the battery can be calculated. Power management is addressed in the conte
 xt of embedded systems from energy-aware design to energy-efficient implem
 entation. &nbsp\;Here\, you will get to know more about BMS functionality\
 , and battery states and how you can estimate them by an embedded system.&
 nbsp\;</p>
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