米6体育平台手机版

SWRZ102B November 2021 – October 2023 AWR2944

PRODUCTION DATA

1
1Introduction
2Device Nomenclature
3Device Markings
4Advisory to Silicon Variant / Revision Map
5Known Design Exceptions to Functional Specifications
1. MSS#25
2. MSS#27
3. MSS#28
4. MSS#29
5. MSS#30
6. MSS#33
7. MSS#40
8. 5.1 MSS#46
9. 5.2 MSS#48
10. 5.3 MSS#49
11. 5.4 MSS#52
12. 5.5 MSS#53
13. 5.6 MSS#54
14. 5.7 MSS#55
15. 5.8 MSS#56
16. 5.9 MSS#57
17. 5.10 MSS#58
18. 5.11 MSS#59
19. 5.12 MSS#60
20. 5.13 MSS#61
21. 5.14 MSS#62
22. 5.15 ANA#12A
23. ANA#32A
24. ANA#33A
25. ANA#34A
26. ANA#35A
27. ANA#36
28. ANA#37A
29. ANA#38A
30. ANA#39
31. ANA#43
32. ANA#44
33. ANA#45
34. ANA#46
35. ANA#47
Trademarks
Revision History

ANA#47

RX Spurs observed across RXs in Idle Channel Scenario

Revision(s) Affected:

AWR294x ES1.0, ES2.0

Description:

In scenarios of no object being present, or a very weak object being present in the vicinity, the sigma delta ADC output could have spurs in the RX spectrum. This is observed only for low RX gain settings. The spur frequency could vary across RX channels. In presence of a real object, this would not be observed.

Workaround(s):

Workaround#1 : Use higher rx gain (>40dB) in these situations.

Workaround#2 : Idle channel spur is spread across all doppler bins in 2DFFT at the spur range bin. While detecting peaks in 2D-FFT, users can apply 2D neighborhood peak search (e.g. 2D CFAR-CA), which compares the level with all surrounding bins. This can help avoid detection of idle channel spur as ghost object.