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XLP nanoWatt Microcontrollers

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XLP nanoWatt Microcontrollers & Low Power Management Industry Trend Many types of portable electronics Metering applications Medical devices Power consumption becomes ... – PowerPoint PPT presentation

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Title: XLP nanoWatt Microcontrollers


1
XLP nanoWatt Microcontrollers
  • Low Power Management

2
Industry Trend
  • Many types of portable electronics
  • Metering applications
  • Medical devices
  • Power consumption becomes one of the most
    important concerns for designers

3
Power Consumption
  • Dynamic
  • Power used by the switching of the digital logic
  • Voltage and temperature impact power usage in a
    small way
  • Mainly influenced by clock speed
  • Static
  • Power consumption when clock is disabled
  • Transistor leakage currents
  • Power used by voltage supervisors and other
    circuits needed to resume normal operation from
    static mode
  • Higher impact from voltage and temperature

4
Power Saving Modes
  • Deep sleep mode
  • The lowest of the static power modes
  • Except a few RAM locations, the wake-up circuitry
    and in some cases a low power oscillator used for
    RTCC, everything is powered down
  • Wake-up resets the device, and the firmware has
    to check special registers to resume normal
    operation state
  • Used when long sleep times and very long battery
    life are required
  • Accurate timekeeping is possible
  • No peripherals may run during deep sleep
  • Typical power consumption is less than 50nA

5
Power Saving Modes
  • Sleep mode
  • Standard low power mode that predates nanoWatt
    technology
  • Core and most peripheral clocks are shut down
  • General purpose RAM, registers and Program
    Counter are preserved
  • Wake-up times are very short, with little
    firmware overhead
  • Used when shorter sleep times and very short
    wake-up times are required.
  • ADC (with own RC oscillator) and comparators may
    be used during sleep
  • Typical power consumption is between 50-100nA

6
Power Saving Modes
  • Idle mode
  • Dynamic reduction mode intended to allow for
    greater peripheral functionality than the static
    modes
  • Core clock is removed while still provided to the
    peripherals
  • On some devices it is possible to apply the
    system clock only to selected peripherals
  • Idle mode consumes significantly more power than
    any of the static modes
  • Useful in cases in which high speed ADC,
    time-critical communications or DMA transfers are
    needed
  • It may significantly reduce power usage when the
    device is waiting for data transfers, timer
    overflows and output compare events
  • Typical current consumption around 25 of normal
    run mode

7
Power Saving Modes
  • Doze mode
  • Dynamic reduction mode allowing full peripheral
    and some core functionality
  • System clock is applied to peripherals
  • A user defined fraction of this clock is still
    applied to the core
  • Similar to IDLE mode, but core continues to run
    at reduced speed
  • Power consumption up to 75 of normal run mode
    depending on application

8
Clock Switching
  • IDLE and DOZE modes allow reduction of core power
    consumption while peripherals are still clocked
    at full speed
  • Clock switching allows reducing the speed of
    clocks for the entire device
  • The system clock source may be selected depending
    upon the situation
  • Slower crystals or internal RC clocks may be used
    in code sections that are not time critical
  • Computation intensive code or time critical
    sections may conveniently switch back to a high
    speed clock source

9
Application Examples
  • Methane gas / smoke sensor
  • Device enters deep sleep and wakes up every
    second to sample sensor data
  • If data over threshold device switches to
    standard sleep mode and samples sensor data 10
    times faster to confirm readings
  • Alarm is raised after confirmation
  • Device reverts to normal operation

10
Application Examples
  • Normal consumption _at_ 4MIPS is 4mA
  • Current consumption in sleep mode with 32kHz
    watch crystal running on TIMER1 is 500nA100nA
    static
  • Acquiring 8 ADC samples and deciding if values
    over threshold takes less than 500us
  • Duty cycle estimated to 0.05 (500us out of 1s)
  • Average current consumption is 4000uA0.050.6uA
    99.952.5997uA
  • Excluding leakage, device may run 22 years using
    a pair of 500mAh AAA batteries

11
Thank you!
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