SPRZ422K August   2014  – May 2024 TMS320F28374S , TMS320F28375S , TMS320F28375S-Q1 , TMS320F28376S , TMS320F28377S , TMS320F28377S-Q1 , TMS320F28378S , TMS320F28379S

 

  1.   1
  2.   Abstract
  3. 1Usage Notes and Advisories Matrices
    1. 1.1 Usage Notes Matrix
    2. 1.2 Advisories Matrix
  4. 2Nomenclature, Package Symbolization, and Revision Identification
    1. 2.1 Device and Development Support Tool Nomenclature
    2. 2.2 Devices Supported
    3. 2.3 Package Symbolization and Revision Identification
  5. 3Silicon Revision C Usage Notes and Advisories
    1. 3.1 Silicon Revision C Usage Notes
      1. 3.1.1 PIE: Spurious Nested Interrupt After Back-to-Back PIEACK Write and Manual CPU Interrupt Mask Clear
      2. 3.1.2 Caution While Using Nested Interrupts
      3. 3.1.3 SYS/BIOS: Version Implemented in Device ROM is not Maintained
      4. 3.1.4 SDFM: Use Caution While Using SDFM Under Noisy Conditions
      5. 3.1.5 McBSP: XRDY Bit can Hold the Not-Ready Status (0) if New Data is Written to the DX1 Register Without Verifying if the XRDY Bit is in its Ready State (1)
    2. 3.2 Silicon Revision C Advisories
      1.      Advisory
      2.      Advisory
      3.      Advisory
      4.      Advisory
      5.      Advisory
      6.      Advisory
      7.      Advisory
      8.      Advisory
      9.      Advisory
      10.      Advisory
      11.      Advisory
      12.      Advisory
      13.      Advisory
      14.      Advisory
      15.      Advisory
      16.      Advisory
      17.      Advisory
      18.      Advisory
      19.      Advisory
      20.      Advisory
      21.      Advisory
      22.      Advisory
      23.      Advisory
      24.      Advisory
      25.      Advisory
      26.      Advisory
      27.      Advisory
      28.      Advisory
      29.      Advisory
      30.      Advisory
      31.      Advisory
      32.      Advisory
      33.      Advisory
      34.      Advisory
      35.      Advisory
      36.      Advisory
      37.      Advisory
  6. 4Silicon Revision B Usage Notes and Advisories
    1. 4.1 Silicon Revision B Usage Notes
    2. 4.2 Silicon Revision B Advisories
      1.      Advisory
      2.      Advisory
      3.      Advisory
      4.      Advisory
      5.      Advisory
      6.      Advisory
      7.      Advisory
      8.      Advisory
      9.      Advisory
  7. 5Documentation Support
  8. 6Trademarks
  9. 7Revision History

Advisory

SDFM: Manchester Mode (Mode 2) Does Not Produce Correct Filter Results Under Several Conditions

Revisions Affected

B, C

Details

The Manchester decoding algorithm samples the Manchester bitstream with SYSCLK in a calibration window of 1024 SDx_Dy signal transitions. The derived clock from the Manchester bitstream is used to sample for data in the subsequent calibration window cycle.

There are several scenarios that can cause large errors in the filter results:

  • Any single noise event on SDx_Dy can corrupt the decoded Manchester clock and cause subsequent data to be sampled at an incorrect frequency.
  • If the Manchester bitstream clock rate is a near exact integer multiple of SYSCLK, then an occasional Manchester bit can be skipped when the phases of the Manchester stream and internal SYSCLK drift past each other in phase before the next 1024 transition calibration window becomes effective. Deviations in duty cycle from 50% of the Manchester clock also need to be accounted for to ensure the longer Manchester pulses are not an integer multiple of SYSCLK. This situation can be unavoidable if the clock sources for either the SD modulator or this device have a wide variation since a wide range of keep out frequencies become problematic
  • If the Manchester edge delay variation between rising and falling (duty cycle of the bitstream) is greater than one SYSCLK, then the SDFM clock decode algorithm can incorrectly identify the clock period as shorter than it is.

Workarounds

The workarounds available are:

  • Avoid using Manchester mode and consider using Mode 0, which provides the best filter performance under noisy conditions. This is the recommended workaround.
  • Avoid any noise on the Manchester bitstream and avoid integer multiples of SYSCLK for the selected Manchester clock source. A precision clock source for the modulator and this device must be used.
  • Ensure rising and falling edge delays (high and low pulses) are within one SYSCLK of each other in length.
  • Design an application-level algorithm that is robust against occasional incorrect SDFM results.