All trademarks are the property of their respective owners.
This document contains information for TLV4197-Q1 (TSSOP package) to aid in a functional safety system design. Information provided are:
Figure 1-1 shows the device functional block diagram for reference.
TLV4197-Q1 was developed using a quality-managed development process, but was not developed in accordance with the IEC 61508 or ISO 26262 standards.
This section provides Functional Safety Failure In Time (FIT) rates for TLV4197-Q1 based on two different industry-wide used reliability standards:
FIT IEC TR 62380 / ISO 26262 | FIT (Failures Per 109 Hours) |
---|---|
Total Component FIT Rate | 11 |
Die FIT Rate | 3 |
Package FIT Rate | 8 |
The failure rate and mission profile information in Table 2-1 comes from the Reliability data handbook IEC TR 62380 / ISO 26262 part 11:
Table | Category | Reference FIT Rate | Reference Virtual TJ |
---|---|---|---|
5 | CMOS, BICMOS Digital, analog / mixed | 25 FIT | 55°C |
The Reference FIT Rate and Reference Virtual TJ (junction temperature) in Table 2-2 come from the Siemens Norm SN 29500-2 tables 1 through 5. Failure rates under operating conditions are calculated from the reference failure rate and virtual junction temperature using conversion information in SN 29500-2 section 4.
The failure mode distribution estimation for TLV4197-Q1 in Table 3-1 comes from the combination of common failure modes listed in standards such as IEC 61508 and ISO 26262, the ratio of sub-circuit function size and complexity and from best engineering judgment.
The failure modes listed in this section reflect random failure events and do not include failures due to misuse or overstress.
Die Failure Modes | Failure Mode Distribution (%) |
---|---|
Incorrect channel selected | 15% |
Channel-channel short | 10% |
ADC output code bit error | 15% |
ADC gain out of specification | 20% |
ADC offset out of specification | 20% |
Communication error | 20% |
The FMD in Table 3-1 excludes short circuit faults across the isolation barrier. Faults for short circuit across the isolation barrier can be excluded according to ISO 61800-5-2:2016 if the following requirements are fulfilled:
Creepage and clearance requirements should be applied according to the specific equipment isolation standards of an application. Care should be taken to maintain the creepage and clearance distance of a board design to ensure that the mounting pads of the isolator on the printed-circuit board do not reduce this distance.
This section provides a Failure Mode Analysis (FMA) for the pins of the TLV4197-Q1. The failure modes covered in this document include the typical pin-by-pin failure scenarios:
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.
Class | Failure Effects |
---|---|
A | Potential device damage that affects functionality |
B | No device damage, but loss of functionality |
C | No device damage, but performance degradation |
D | No device damage, no impact to functionality or performance |
Figure 4-1 shows the TLV4197-Q1 pin diagram. For a detailed description of the device pins please refer to the Pin Configuration and Functions section in the TLV4197-Q1 data sheet.
Following are the assumptions of use and the device configuration assumed for the pin FMA in this section:
Pin Name | Pin No. | Description of Potential Failure Effect(s) | Failure Effect Class |
---|---|---|---|
OUT A |
1 |
Depending on the circuit configuration, the device is likely to be forced into a short-circuit condition with the OUT A voltage ultimately forced to the V– voltage. Prolonged exposure to short-circuit conditions could result in long-term reliability issues. |
A |
–IN A |
2 |
The device does not receive negative feedback. Depending on the circuit configuration, the output most likely moves to the negative supply. |
B |
+IN A |
3 |
Device common-mode is tied to the negative rail. Depending on the circuit configuration, the output likely does not respond because the device is in an invalid common-mode condition. |
C |
V+ |
4 |
Op-amp supplies are shorted together, leaving the V+ pin at some voltage between the V+ and V‒ sources (depending on the source impedance). |
A |
+IN B |
5 |
Device common-mode is tied to the negative rail. Depending on the circuit configuration, the output likely does not respond because the device is in an invalid common-mode condition. |
C |
–IN B |
6 |
The device does not receive negative feedback. Depending on the circuit configuration, the output most likely moves to the negative supply. |
B |
OUT B |
7 |
Depending on the circuit configuration, the device is likely to be forced into a short-circuit condition with the OUT B voltage ultimately forced to the V‒ voltage. Prolonged exposure to short-circuit conditions could result in long-term reliability issues. |
A |
OUT C |
8 |
Depending on the circuit configuration, the device is likely to be forced into a short-circuit condition with the OUT C voltage ultimately forced to the V‒ voltage. Prolonged exposure to short-circuit conditions could result in long-term reliability issues. |
A |
–IN C |
9 |
The device does not receive negative feedback. Depending on the circuit configuration, the output most likely moves to the negative supply. |
B |
+IN C |
10 |
Device common-mode is tied to the negative rail. Depending on the circuit configuration, the output likely does not respond because the device is in an invalid common-mode condition. |
C |
+IN D |
12 |
Device common-mode is tied to the negative rail. Depending on the circuit configuration, the output likely does not respond because the device is in an invalid common-mode condition. |
C |
–IN D |
13 |
The device does not receive negative feedback. Depending on the circuit configuration, the output most likely moves to the negative supply. |
B |
OUT D |
14 |
Depending on the circuit configuration, the device is likely to be forced into a short-circuit condition with the OUT D voltage ultimately forced to the V‒ voltage. Prolonged exposure to short-circuit conditions could result in long-term reliability issues. |
A |
Pin Name | Pin No. | Description of Potential Failure Effect(s) | Failure Effect Class |
---|---|---|---|
OUT A |
1 |
No negative feedback or ability for OUT A to drive the application. |
B |
–IN A |
2 |
Inverting pin of the op amp is left floating. Negative feedback is not provided to the device, likely resulting in the device output moving between the positive and negative rails. The ‒IN A pin voltage likely ends up at the positive or negative rail because of leakage on the ESD diodes. |
B |
+IN A |
3 |
Device common-mode is disconnected. The op amp is not provided with common-mode bias, and the device output likely ends up at the positive or negative rail. The +IN A pin voltage likely ends up at the positive or negative rail because of leakage on the ESD diodes. |
B |
V+ |
4 |
Positive supply is left floating. The op amp ceases to function because no current can source or sink to the device. |
A |
+IN B |
5 |
Device common-mode is disconnected. The op amp is not provided with common-mode bias, and the device output likely ends up at the positive or negative rail. The +IN B pin voltage likely ends up at the positive or negative rail because of leakage on the ESD diodes. |
B |
–IN B |
6 |
Inverting pin of the op amp is left floating. Negative feedback is not provided to the device, likely resulting in the device output moving between the positive and negative rails. The ‒IN B pin voltage likely ends up at the positive or negative rail because of leakage on the ESD diodes. |
B |
OUT B |
7 |
No negative feedback or ability for OUT B to drive the application. |
B |
OUT C |
8 |
No negative feedback or ability for OUT C to drive the application. |
B |
–IN C |
9 |
Inverting pin of the op amp is left floating. Negative feedback is not provided to the device, likely resulting in the device output moving between the positive and negative rails. The ‒IN C pin voltage likely ends up at the positive or negative rail because of leakage on the ESD diodes. |
B |
+IN C |
10 |
Device common-mode is disconnected. The op amp is not provided with common-mode bias, and the device output likely ends up at the positive or negative rail. The +IN C pin voltage likely ends up at the positive or negative rail because of leakage on the ESD diodes. |
B |
V– |
11 |
Negative supply is left floating. The op amp ceases to function because no current can source or sink to the device. |
B |
+IN D |
12 |
Device common-mode is disconnected. The op amp is not provided with common-mode bias, and the device output likely ends up at the positive or negative rail. The +IN D pin voltage likely ends up at the positive or negative rail because of leakage on the ESD diodes. |
B |
–IN D |
13 |
Inverting pin of the op amp is left floating. Negative feedback is not provided to the device, likely resulting in the device output moving between the positive and negative rails. The ‒IN D pin voltage likely ends up at the positive or negative rail because of leakage on the ESD diodes. |
B |
OUT D |
14 |
No negative feedback or ability for OUT D to drive the application. |
B |
Pin Name | Pin No. | Shorted to | Description of Potential Failure Effect(s) | Failure Effect Class |
---|---|---|---|---|
OUT A |
1 |
2 |
Depending on the circuit configuration, the circuit gain is reduced to unity gain, and the application might not function as intended. |
B |
–IN A |
2 |
3 |
Both inputs are tied together. Depending on the offset of the device, the output voltage likely moves to near midsupply. |
D |
+IN A |
3 |
4 |
Depending on the circuit configuration, the application is likely not to function because device common-mode voltage is connected to +IN A. |
B |
V+ |
4 |
5 |
Depending on the circuit configuration, the application is likely not to function because device common-mode voltage is connected to V+. |
B |
+IN B |
5 |
6 |
Both inputs are tied together. Depending on the offset of the device, the output voltage likely moves to near midsupply. |
D |
–IN B |
6 |
7 |
Depending on the circuit configuration, the circuit gain is reduced to unity gain, and the application might not function as intended. |
B |
OUT B |
7 |
8 |
Depending on the circuit configuration, the device is likely to be forced into a short-circuit condition with the OUT B voltage ultimately forced to the OUT C voltage or vice versa. Prolonged exposure to short-circuit conditions might result in long-term reliability issues. |
A |
OUT C |
8 |
9 |
Depending on the circuit configuration, the circuit gain is reduced to unity gain, and the application might not function as intended. |
B |
–IN C |
9 |
10 |
Both inputs are tied together. Depending on the offset of the device, the output voltage likely moves to near midsupply. |
D |
+IN C |
10 |
11 |
Device common-mode is tied to the negative rail. Depending on the circuit configuration, the output likely does not respond because the device is in an invalid common-mode condition. |
C |
V– |
11 |
12 |
Device common-mode is tied to the negative rail. Depending on the circuit configuration, the output likely does not respond because the device is in an invalid common-mode condition. |
C |
+IN D |
12 |
13 |
Both inputs are tied together. Depending on the offset of the device, the output voltage likely moves to near midsupply. |
D |
–IN D |
13 |
14 |
Depending on the circuit configuration, the circuit gain is reduced to unity gain, and the application might not function as intended. |
B |
OUT D |
14 |
1 |
Depending on the circuit configuration, the device is likely to be forced into a short-circuit condition with the OUT D voltage ultimately forced to the OUT A voltage or vice versa. Prolonged exposure to short-circuit conditions might result in long-term reliability issues. |
A |
Pin Name | Pin No. | Description of Potential Failure Effect(s) | Failure Effect Class |
---|---|---|---|
OUT A |
1 |
Depending on the circuit configuration, the device is likely to be forced into a short-circuit condition with the OUT A voltage ultimately forced to the V+ voltage. Prolonged exposure to short-circuit conditions could result in long-term reliability issues. |
A |
–IN A |
2 |
The device does not receive negative feedback. Depending on the noninverting input voltage and circuit configuration, the output most likely moves to the negative supply. |
B |
+IN A |
3 |
Depending on the circuit configuration, the application is likely not to function because device common-mode voltage is connected to +IN A. |
B |
+IN B |
5 |
Depending on the circuit configuration, the application is likely not to function because device common-mode voltage is connected to +IN B. |
B |
–IN B |
6 |
The device does not receive negative feedback. Depending on the noninverting input voltage and circuit configuration, the output most likely moves to the negative supply. |
B |
OUT B |
7 |
Depending on the circuit configuration, the device is likely to be forced into a short-circuit condition with the OUT B voltage ultimately forced to the V+ voltage. Prolonged exposure to short-circuit conditions could result in long-term reliability issues. |
A |
OUT C |
8 |
Depending on the circuit configuration, the device is likely to be forced into a short-circuit condition with the OUT C voltage ultimately forced to the V+ voltage. Prolonged exposure to short-circuit conditions could result in long-term reliability issues. |
A |
–IN C |
9 |
The device does not receive negative feedback. Depending on the noninverting input voltage and circuit configuration, the output most likely moves to the negative supply. |
B |
+IN C |
10 |
Depending on the circuit configuration, the application is likely not to function because device common-mode voltage is connected to +IN C. |
B |
V– |
11 |
Op-amp supplies are shorted together, leaving the V‒ pin at some voltage between the V‒ and V+ sources (depending on the source impedance). |
A |
+IN D |
12 |
Depending on the circuit configuration, the application is likely not to function because device common-mode voltage is connected to +IN D. |
B |
–IN D |
13 |
The device does not receive negative feedback. Depending on the noninverting input voltage and circuit configuration, the output most likely moves to the negative supply. |
B |
OUT D |
14 |
Depending on the circuit configuration, the device is likely to be forced into a short-circuit condition with the OUT D voltage ultimately forced to the V+ voltage. Prolonged exposure to short-circuit conditions could result in long-term reliability issues. |
A |