SLAZ102AB Errata | 德州仪器 TI.com.cn

SLAZ102AB October 2012 – May 2021 CC430F6137

1Functional Advisories
2Preprogrammed Software Advisories
3Debug Only Advisories
4Fixed by Compiler Advisories
5Nomenclature, Package Symbolization, and Revision Identification
6Advisory Descriptions
1. 6.1 ADC24
2. 6.2 ADC25
3. 6.3 ADC27
4. 6.4 ADC29
5. 6.5 ADC42
6. 6.6 ADC69
7. 6.7 AES1
8. 6.8 BSL7
9. 6.9 COMP4
10. 6.10 COMP10
11. 6.11 CPU18
12. 6.12 CPU20
13. 6.13 CPU21
14. 6.14 CPU22
15. 6.15 CPU23
16. 6.16 CPU24
17. 6.17 CPU25
18. 6.18 CPU26
19. 6.19 CPU27
20. 6.20 CPU28
21. 6.21 CPU29
22. 6.22 CPU30
23. 6.23 CPU31
24. 6.24 CPU32
25. 6.25 CPU33
26. 6.26 CPU34
27. 6.27 CPU35
28. 6.28 CPU39
29. 6.29 CPU40
30. 6.30 CPU46
31. 6.31 CPU47
32. 6.32 DMA4
33. 6.33 DMA7
34. 6.34 DMA8
35. 6.35 DMA10
36. 6.36 EEM8
37. 6.37 EEM9
38. 6.38 EEM11
39. 6.39 EEM13
40. 6.40 EEM14
41. 6.41 EEM16
42. 6.42 EEM17
43. 6.43 EEM19
44. 6.44 EEM23
45. 6.45 FLASH29
46. 6.46 FLASH31
47. 6.47 FLASH37
48. 6.48 JTAG20
49. 6.49 JTAG26
50. 6.50 JTAG27
51. 6.51 LCDB1
52. 6.52 LCDB3
53. 6.53 LCDB4
54. 6.54 LCDB5
55. 6.55 LCDB6
56. 6.56 MPY1
57. 6.57 PMAP1
58. 6.58 PMM8
59. 6.59 PMM9
60. 6.60 PMM10
61. 6.61 PMM11
62. 6.62 PMM12
63. 6.63 PMM14
64. 6.64 PMM15
65. 6.65 PMM17
66. 6.66 PMM18
67. 6.67 PMM20
68. 6.68 PORT15
69. 6.69 PORT16
70. 6.70 PORT17
71. 6.71 PORT19
72. 6.72 PORT21
73. 6.73 RF1A1
74. 6.74 RF1A2
75. 6.75 RF1A3
76. 6.76 RF1A5
77. 6.77 RF1A6
78. 6.78 RF1A8
79. 6.79 RTC3
80. 6.80 RTC6
81. 6.81 SYS16
82. 6.82 TAB23
83. 6.83 UCS6
84. 6.84 UCS7
85. 6.85 UCS9
86. 6.86 UCS10
87. 6.87 UCS11
88. 6.88 USCI26
89. 6.89 USCI30
90. 6.90 USCI31
91. 6.91 USCI34
92. 6.92 USCI35
93. 6.93 USCI39
94. 6.94 USCI40
95. 6.95 WDG4
7Revision History

6.47 FLASH37

FLASH Module

Function

Corrupted flash read when SVM low-side flag is triggered

Description

If the SVM low side is enabled, a change in the VCORE voltage level (an increase in the VCORE level) may cause the currently executed read operation from flash to be incorrect and may lead to unexpected code execution or incorrect data. This can happen under any one of the following conditions:

- When the VCORE is changed in application, the SVM low side is used to indicate if the core voltage has settled by using the SVMDLYIFG flag. The failure occurs only when a flash access is concurrent to the expiration of the settling time delay.

- Unexpected changes in the VCORE voltage level

For code examples and detailed guidance on the PMM operation and software APIs for PMM configuration see the driverlib APIs from 430Ware (MSP430Ware).

Workaround

- Execute the procedure to change the VCORE level from RAM.

or

- If executing from flash, follow the procedure below when increasing the VCORE level. Note: To apply this workaround, the SVM low-side comparator must operate in normal mode (SVMLFP = 0 in SVMLCTL).

// Set SVM highside to new level and check if a VCore increase is possible
  SVSMHCTL = SVMHE | SVSHE | (SVSMHRRL0 * level);
  // Wait until SVM highside is settled
  while ((PMMIFG & SVSMHDLYIFG) == 0);
  // Clear flag
  PMMIFG &= ~SVSMHDLYIFG;

  // Set also SVS highside to new level
  // Vcc is high enough for a Vcore increase
  SVSMHCTL |= (SVSHRVL0 * level);
  // Wait until SVM highside is settled
  while ((PMMIFG & SVSMHDLYIFG) == 0);
  // Clear flag
  PMMIFG &= ~SVSMHDLYIFG;

//**************flow change for errata workaround ************
  // Set VCore to new level
  PMMCTL0_L = PMMCOREV0 * level;

  // Set SVM, SVS low side to new level
  SVSMLCTL = SVMLE | (SVSMLRRL0 * level)| SVSLE | (SVSLRVL0 * level);
  // Wait until SVM, SVS low side is settled
  while ((PMMIFG & SVSMLDLYIFG) == 0);
  // Clear flag
  PMMIFG &= ~SVSMLDLYIFG;

//**************flow change for errata workaround ************

6.47 FLASH37

Category

Function

Description

Workaround