SFFS348 December   2021 LM25148

 

  1.   Trademarks
  2. 1Overview
  3. 2Functional Safety Failure In Time (FIT) Rates
  4. 3Failure Mode Distribution (FMD)
  5. 4Pin Failure Mode Analysis (Pin FMA)

Pin Failure Mode Analysis (Pin FMA)

This section provides a Failure Mode Analysis (FMA) for the pins of the LM25148. The failure modes covered in this document include the typical pin-by-pin failure scenarios:

  • Pin short-circuited to Ground (see Table 4-2)
  • Pin open-circuited (see Table 4-3)
  • Pin short-circuited to an adjacent pin (see Table 4-4)
  • Pin short-circuited to supply (see Table 4-5)

Table 4-2 through Table 4-5 also indicate how these pin conditions can affect the device as per the failure effects classification in Table 4-1.

Table 4-1 TI Classification of Failure Effects
ClassFailure Effects
APotential device damage that affects functionality
BNo device damage, but loss of functionality
CNo device damage, but performance degradation
DNo device damage, no impact to functionality or performance

Figure 4-1 shows the LM25148 pin diagram. For a detailed description of the device pins please refer to the Pin Configuration and Functions section in the LM25148 data sheet.

Figure 4-1 Pin Diagram

Following are the assumptions of use and the device configuration assumed for the pin FMA in this section:

Table 4-2 Pin FMA for Device Pins Short-Circuited to Ground
Pin Name Pin No. Description of Potential Failure Effect(s) Failure Effect Class
NC 1 NC can be connected to Ground for improved heat spreading. D
NC 2 NC can be connected to Ground for improved heat spreading. D
CNFG 3 VOUT is unaffected. C
RT 4 VOUT will attempt to regulate at maximum fSW, causing maximum power dissipation. B
EXTCOMP 5 VOUT = 0 V B
FB 6 Internal FB mode, VOUT = expected VOUT D
External FB mode, VOUT = VIN A
AGND 7 AGND is GND. VOUT = expected VOUT D
VDDA 8 VOUT = 0 V, no switching, loaded VCC output B
VCC 9 VOUT = 0 V, no switching, loaded VCC output B
PGND 10 PGND is GND. VOUT = expected VOUT D
LO 11 VOUT = 0 V, the VCC regulator loaded to current limit. B
VIN 12 VOUT = 0 V B
HO 13 VOUT = 0 V, the VCC regulator loaded to current limit. B
SW 14 VOUT = 0 V. High-side FET is shorted from VIN to GND. A
CBOOT 15 VOUT = 0 V, the VCC regulator loaded to current limit. B
VCCX 16 VOUT = expected VOUT. Internal VCC regulator provides bias voltage. C
PG 17 If in single phase, PG has no effect on operation. VOUT = expected VOUT C
If in interleaved primary mode, the secondary will detect no clock input and will shut down. Secondary phase is disabled and primary phase can current limit. B
PFM/SYNC 18 VOUT = expected VOUT. No synchronization will be available and LM25148 will be in FPWM mode. C
EN 19 VOUT = 0 V, the LM25148 enters shutdown. C
ISNS+ 20 VOUT = 0 V, HO damaged A
VOUT 21 VOUT = 0 V. Current limit reached, hiccup mode occurs. B
NC 22 NC can be connected to Ground for improved heat spreading. D
NC 23 NC can be connected to Ground for improved heat spreading. D
NC 24 NC can be connected to Ground for improved heat spreading. D
Table 4-3 Pin FMA for Device Pins Open-Circuited
Pin Name Pin No. Description of Potential Failure Effect(s) Failure Effect Class
NC 1 NC can be open-circuited. D
NC 2 NC can be open-circuited. D
CNFG 3 VOUT will continue operating normally. CNFG is used during start-up. C
RT 4 RT will regulate to 500 mV, but the internal oscillator will not function. B
EXTCOMP 5 VOUT will oscillate. If VOUT oscillates to VIN, damage can occur if VIN > 36 V. A
FB 6 Internal FB mode, VOUT = expected VOUT D
External FB mode, VOUT = VIN A
AGND 7 VOUT is indeterminate. B
VDDA 8 Poor noise immunity C
VCC 9 VOUT = 0 V B
PGND 10 VOUT = 0 V B
LO 11 VOUT = expected VOUT with reduced efficiency. C
VIN 12 VOUT = 0 V C
HO 13 If HO is opened while HO to SW has voltage, the high-side FET will never turn off. VOUT = VIN A
SW 14 VOUT is indeterminate. The CBOOT floating rail has no reference to the actual SW node. VOUT = VIN A
CBOOT 15 VOUT = 0 V B
VCCX 16 VCCX held to ground by weak pulldown, VOUT = expected VOUT D
PG 17 If in single phase, PG has no effect on operation. VOUT = expected VOUT C
If in interleaved primary mode, the secondary will detect no clock input and will shut down. Secondary phase is disabled and primary phase can current limit. B
PFM/SYNC 18 VOUT = expected VOUT D
EN 19 VOUT = expected VOUT D
ISNS+ 20 The OPEN ISNS+ pin will block current limit and cause VOUT oscillations. A
VOUT 21 VOUT = 0 V B
NC 22 NC can be open-circuited. D
NC 23 NC can be open-circuited. D
NC 24 NC can be open-circuited. D
Table 4-4 Pin FMA for Device Pins Short-Circuited to Adjacent Pin
Pin Name Pin No. Shorted to Description of Potential Failure Effect(s) Failure Effect Class
NC 1 NC No impact D
NC 2 CNFG No impact D
CNFG 3 RT VOUT = expected VOUT with erratic switching B
RT 4 EXTCOMP COMP cannot regulate down due to clamping by internal RT. B
EXTCOMP 5 FB External FB mode: COMP will regulate to 0.8 V and output will be unregulated. VOUT = indeterminate B
Internal FB mode: COMP will rise up to VDDA. VOUT = VIN A
FB 6 AGND External FB mode: VOUT = VIN A
Internal FB mode: VOUT = expected VOUT D
AGND 7 VDDA VDDA will be grounded. VOUT = 0 V B
VDDA 8 VCC VOUT = expected VOUT D
VCC 9 PGND VCC will be grounded. VOUT = 0 V B
PGND 10 LO VOUT = 0 V. VCC is loaded by the LO driver. B
LO 11 VIN VOUT = 0 V. The driver will be damaged if VIN > 6.5 V. A
VIN 12 HO VOUT = VIN A
HO 13 SW VOUT = 0 V B
SW 14 CBOOT VOUT = 0 V B
CBOOT 15 VCCX VOUT < 5 V A
VCCX 16 PG PG pulldown can damage, VOUT = expected VOUT A
PG 17 PFM/SYNC VOUT = expected VOUT C
PFM/SYNC 18 EN VOUT = expected VOUT A
EN 19 ISNS+ EN is high-voltage rated. VOUT = expected VOUT if VOUT > 1 V. If VOUT < 1 V, the device is disabled. B
ISNS+ 20 VOUT Current limit is disabled since the current limit resistor would be shorted. VOUT cannot regulate since current mode feedback is shorted. A
VOUT 21 NC No impact D
NC 22 NC No impact D
NC 23 NC No impact D
NC 24 NC No impact D
Table 4-5 Pin FMA for Device Pins Short-Circuited to VIN
Pin Name Pin No. Description of Potential Failure Effect(s) Failure Effect Class
NC 1 No impact D
NC 2 No impact D
CNFG 3 VOUT = VIN A
RT 4 VOUT = 0 V, high VIN current A
EXTCOMP 5 This will bring VDDA up to VIN. VOUT = VIN A
FB 6 This will bring VDDA up to VIN. VOUT = VIN A
AGND 7 VOUT = VIN, high VIN current A
VDDA 8 If VIN < 6.5 V, VOUT = expected VOUT D
If VIN > 6.5 V, exceeds maximum ratings and VDDA is damaged. A
VCC 9 If VIN < 6.5 V, VOUT = expected VOUT D
If VIN > 6.5 V, exceeds maximum ratings and VCC is damaged. A
PGND 10 VOUT = VIN, high VIN current A
LO 11 For VIN < 6.5 V, VOUT = 0; excess current from VIN B
For VIN > 6.5 V, exceeds maximum ratings and the LO pin is damaged. A
VIN 12 N/A D
HO 13 For VIN < 6.5 V, VOUT = dropout lower than VIN, no switching, and excess current from VIN B
For VIN > 6.5 V, exceeds maximum ratings and the HO pin is damaged, VOUT = VIN A
SW 14 VOUT = VIN, excess current from VIN. LO turns on and shorts against VIN. A
CBOOT 15 For VIN < 6.5 V, VOUT = expected VOUT, erratic switching B
For VIN > 6.5 V, exceeds maximum ratings and the CBOOT pin is damaged, HO damaged. VOUT = VIN A
VCCX 16 If VCCX = VOUT, for VIN < 6.5 V, VOUT = VIN B
For VIN > 6.5 V, exceeds maximum ratings and the VCCX pin is damaged. A
PG 17 For VIN < 6.5 V, VOUT = regulated and PG forced high B
For VIN > 6.5 V, exceeds maximum ratings and PG is destroyed. A
PFM/SYNC 18 If PFM = GND, VOUT=0 V, excess current from VIN B
If PFM = VDDA and VIN < 6.5 V, VOUT = expected VOUT. Erratic switching B
If VIN > 6.5 V, exceeds maximum ratings and the PFM/SYNC pin is damaged, VOUT = expected VOUT A
EN 19 The LM25148 will be always on. VOUT = expected VOUT C
ISNS+ 20 If VIN < 36 V, VOUT = VIN B
If VIN > 36 V, exceeds maximum ratings and the CS pin is damaged. A
VOUT 21 If VIN < 36 V, VOUT = VIN B
If VIN > 36 V, exceeds maximum ratings and the CS pin is damaged. A
NC 22 No impact D
NC 23 No impact D
NC 24 No impact D