SWRZ072B May   2017  – December 2020 AWR1642

 

  1. 1Introduction
  2. 2Device Nomenclature
  3. 3Device Markings
  4. 4Usage Notes
    1. 4.1 MSS: SPI Speed in 3-Wire Mode Usage Note
  5. 5Advisory to Silicon Variant / Revision Map
  6. 6Known Design Exceptions to Functional Specifications
    1.     MSS#10
    2.     MSS#11
    3.     MSS#12
    4.     MSS#14
    5.     MSS#16
    6.     MSS#17
    7.     MSS#18
    8.     MSS#19
    9.     MSS#20
    10.     MSS#22
    11.     MSS#37B
    12.     MSS#38A
    13.     MSS#39
    14.     MSS#40
    15.     MSS#42
    16.     MSS#43
    17.     MSS#44
    18.     MSS#45
    19.     ANA#06
    20.     ANA#08A
    21.     ANA#09A
    22.     ANA#10A
    23.     ANA#11A
    24.     ANA#12A
    25.     ANA#15
    26.     ANA#16
    27.     ANA#17A
    28.     ANA#18B
    29.     ANA#20
    30.     ANA#21A
    31.     ANA#22A
    32.     ANA#24A
    33.     ANA#27
    34.     DSS#01
    35.     DSS#02
    36.     DSS#03
    37.     DSS#04
    38.     DSS#05
    39.     DSS#06
    40.     DSS#07
  7. 7Trademarks
  8. 8Revision History

MSS#38A

GPIO Glitch During Power-Up

Revision(s) Affected:

AWR1642 ES1.0 and AWR1642 ES2.0

Description:

During the 3.3-V supply ramp, the GPIO outputs could possibly see a short glitch (rising above the 0 V for a short duration), if the 3.3V supply powers up before the 1.8V supply. This GPIO glitch cannot be avoided by just a pulldown resistor. If the GPIO glitch during boot-up is high enough, it could be falsely detected as a “high”.

Workaround(s):

Powering up the 1.8V supply before the 3.3V supply resolved the issue. Incase that is not feasible, AND the GPIO is used for critical controls where glitch cannot be tolerated, the GPIO output should be gated by the nRESET signal of the xWR device.

Using a tri-state buffer (for example: SN74LVC1G126-Q1) externally to isolate the GPIO output from the system until the nRESET of xWR device is released. At this point, all the supplies are expected to be stable.