SBOK045 March 2024 INA901-SP

7 Single-Event Transients (SET)

SETs are defined as heavy-ion-induced transients upsets on the OUT pin of the INA901-SP. SET testing was performed at room temperature (no external temperature control applied). The highest energy ion used for the SET testing was a Holmium (⁶⁷Ho) ion with an angle-of-incidence of 35° for an LET_EFF = 93MeV × cm² / mg. Flux of approximately 10⁴ ions / cm²× s and a fluence of approximately 1 × 10⁶ ions / cm².

V_OUT SETs were characterized using a window trigger of 6V ± 180mV (±3%) around the output voltage. The devices were characterized at three different V_CM levels of 12V, 15V, and 48V. The IN- pin was set to V_CM with a 300mV differential supply between IN- and IN+. The V_CC supply was set to 12V for all ion runs.

To capture the SETs a NI-PXI-5172 scope card was used to continuously monitor the OUT. The output voltage was monitored by using the INA_OUT test point on the EVM.

The scope triggering from OUT was programmed to record 10k samples with a sample rate of 2M samples per second (S / s) in case of an event (trigger).

Under heavy-ions, the INA901-SP transient upsets that are all recoverable without any need for external intervention such as a power down or reset. There were two distinct signatures seen on the output of the INA901-SP.

Test conditions and results are listed in Table 7-2.

Table 7-1 Summary of INA901 SET Test Condition and Results

Run Number	Unit Number	V_S(V)	V_CM(V)	V_DIFF(V)	Distance (mm)	Ion	Angle (°)	Flux (ions × cm² / mg)	Fluence (Number of ions)	LET_EFF (MeV × cm²/ mg)	Output Events
4	2	12V	12V	0.3	40	Ho	35°	1.00E+04	1.00E+06	93	1147
6	2	12V	15V	0.3	40	Ho	35°	1.00E+04	1.00E+06	93	1241
7	2	12V	48V	0.3	40	Ho	35°	1.00E+04	1.00E+06	93	1250
8	2	12V	12V	0.3	40	Ho	0°	1.00E+04	1.00E+06	75	1141
9	2	12V	15V	0.3	40	Ho	0°	1.00E+04	1.00E+06	75	1093
10	2	12V	48V	0.3	40	Ho	0°	1.00E+04	1.00E+06	75	1189
11	2	12V	12V	0.3	40	Ag	0°	1.00E+04	1.00E+06	48	697
13	2	12V	15V	0.3	40	Ag	0°	1.00E+04	1.00E+06	48.47	728
14	2	12V	48V	0.3	40	Ag	0°	1.00E+04	1.00E+06	48	808
16	2	12V	12V	0.3	40	Ag	35°	1.00E+04	1.00E+06	60	823
17	2	12V	15V	0.3	40	Ag	35°	1.00E+04	1.00E+06	60	808
18	2	12V	48V	0.3	40	Ag	35°	1.00E+04	1.00E+06	59.8	982
19	2	12V	12V	0.3	40	Ne	35°	1.00E+04	1.00E+06	3.44	1
20	2	12V	15V	0.3	40	Ne	35°	1.00E+04	1.00E+06	3.44	4
21	2	12V	48V	0.3	40	Ne	35°	1.00E+04	1.00E+06	3.44	3
22	2	12V	12V	0.3	40	Ne	0°	1.00E+04	1.00E+06	2.8	0
23	2	12V	15V	0.3	40	Ne	0°	1.00E+04	1.00E+06	2.8	2
24	2	12V	48V	0.3	40	Ne	0°	1.00E+04	1.00E+06	2.8	2

Using the MFTF method shown in Single-Event Effects (SEE) Confidence Interval Calculations , the upper-bound cross-section (using a 95% confidence level) is calculated for the different SETs as listed in Table 7-2, Table 7-3, and Table 7-4.

Table 7-2 Upper Bound Cross Section for Given LET_EFF for V_CM 12V

LET_EFF (MeV cm² / mg)	Upper Bound Cross Section (cm²/ device)
93	1.22E-03
76	1.21E-03
60	7.51E-04
48	8.81E-04
3.44	5.57E-06
2.8	3.69E-06

Table 7-3 Upper Bound Cross Section for Given LET_EFF for V_CM 15V

LET_EFF (MeV cm² / mg)	Upper Bound Cross Section (cm² / device)
93	1.31E-03
76	1.16E-03
60	7.83E-04
48	8.66E-04
3.44	1.02E-05
2.8	7.22E-06

Table 7-4 Upper Bound Cross Section for Given LET_EFF for V_CM 48V

LET_EFF (MeV cm²/mg)	Upper Bound Cross Section (cm² / device)
93	1.32E-03
76	1.26E-03
60	8.66E-04
48	1.05E-03
3.4	8.77E-06
2.8	7.22E-06

Figure 7-1 Histogram of the Amplitude for the Positive V_OUT SETs on Run 4, VCM = 12V, LET_EFF = 93MeV

Transients greater than 2.25V above the nominal output were limited by the measurement range of the digitizer. These limitations did not exist for negative transient which showed these disturbances can be as high as 5.6V.

Figure 7-2 Histogram of the Amplitude for the Negative V_OUT SETs on Run 4, VCM = 12V, LET_EFF= 93MeV

Figure 7-3 Histogram of the Pulse Width for the Positive V_OUT SETs on Run 4, VCM = 12V, LET_EFF= 93MeV

Figure 7-4 Histogram of the Amplitude for the Positive V_OUT SETs on Run 6, VCM = 15V, LET_EFF= 93MeV

Figure 7-5 Histogram of the Amplitude for the Negative V_OUT SETs on Run # 6, VCM = 15V, LET_EFF= 93MeV

Figure 7-6 Histogram of the Pulse Width for the Positive V_OUT SETs on Run 6, VCM = 15V, LET_EFF= 93MeV

Figure 7-7 Histogram of the Amplitude for the Positive V_OUT SETs on Run 7, VCM = 48V, LET_EFF= 93MeV

Figure 7-8 Histogram of the Amplitude for the Negative V_OUT SETs on Run 7, VCM = 48V, LET_EFF= 93MeV

Figure 7-9 Histogram of the Pulse Width for the Positive V_OUT SETs on Run 7, VCM = 48V, LET_EFF= 93MeV

Figure 7-10 Histogram of the Amplitude for the Positive V_OUT SETs on Run 19, VCM = 12V, LET_EFF= 3.44MeV

Figure 7-11 Histogram of the Pulse Width for the Positive V_OUT SETs on Run 19, VCM = 12V, LET= 3.44MeV

Figure 7-12 Histogram of the Amplitude for the Negative V_OUT SETs on Run 20, VCM = 15V, LET= 3.44MeV

There where no positive transients for Run 20.

Figure 7-13 Histogram of the Pulse Width for the Positive V_OUT SETs on Run 20, VCM = 15V, LET_EFF= 3.44MeV

Figure 7-14 Histogram of the Amplitude for the Positive V_OUT SETs on Run 21, VCM = 48V, LET_EFF= 3.44MeV

Figure 7-15 Histogram of the Pulse Width for the Positive V_OUT SETs on Run 21, VCM = 48V, LET_EFF= 3.44MeV

Figure 7-16 Most severe observed VOUT Transient, VCM = 15V, LET_EFF = 93MeV, Run 6