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SLVK158A November 2023 – June 2024 TPS7H6003-SP , TPS7H6013-SP , TPS7H6023-SP

PRODUCTION DATA

7.1 Single-Event Latch-up (SEL) Results

During the SEL testing the device was heated to 125°C by using a Closed-Loop PID controlled heat gun (MISTRAL 6 System (120V, 2400W). The temperature of the die was verified using thermal camera prior to exposure to heavy ions.

The species used for the SEL testing was Homium (¹⁶⁵Ho at 15MeV / nucleon). For the ¹⁶⁵Ho ion an angle of incidence of 0° was used to achieve an LET_EFF = 75MeV × cm² / mg (for more details, see Ion LET_EFF, Depth, and Range in Silicon). The kinetic energy in the vacuum for this ions is 2.474GeV. Flux of approximately 10⁵ ions / cm²× s and a fluence of approximately 10⁷ ions / cm² per run was used. Run duration to achieve this fluence was approximately two minutes. The four devices were powered up and exposed to the heavy-ions using the maximum recommended input voltage and boot voltage of 14V. The ASW (High-Side Driver Signal Return) was set to 150V with respect to AGND (low-side driver signal return). The device was set in both PWM and IIM modes during testing. For more information see Single-Event Effects section. No SEL events were observed during all nine runs, indicating that the TPS7H60x3-SP is SEL-free up to 75MeV × cm² / mg. Table 8-4 shows the SEL test conditions and results. Figure 7-1 shows a plot of the current versus time for run 1.

Table 7-1 Summary of TPS7H60x3-SP SEL Test Condition and Results

Run Number	Unit Number	Variant	Ion	LET_EFF (MeV × cm² / mg)	Flux (ions × cm² / mg)	Fluence (Number of ions)	V_IN	V_BOOT	Mode	EN/HI	PWM/LI
1	1	TPS7H6003	¹⁶⁵Ho	75	6.22 × 10⁴	1 × 10⁷	14	14	PWM	14V_DC	14V_pk-pk 500kHz
2	1	TPS7H6003	¹⁶⁵Ho	75	6.26 × 10⁵	9.99 × 10⁶	14	14	PWM	14V_DC	14V_pk-pk 1MHz
3	1	TPS7H6003	¹⁶⁵Ho	75	6.19 × 10⁴	9.99 × 10⁶	14	14	PWM	14V_DC	14V_pk-pk 2MHz
4	2	TPS7H6003	¹⁶⁵Ho	75	6.23 × 10⁴	1.00 × 10⁷	14	14	IIM_ENST	14V_DC	0V
5	2	TPS7H6003	¹⁶⁵Ho	75	5.79 × 10⁴	1.00 × 10⁷	14	14	IIM_ENST	0V	14V_DC
6	3	TPS7H6003	¹⁶⁵Ho	75	7.46 × 10⁴	1.00 × 10⁷	14	14	IIM_ENSW	14V_pk-pk 500kHz	14V_pk-pk 500kHz
7	3	TPS7H6003	¹⁶⁵Ho	75	6.88 × 10⁴	1 × 10⁷	14	14	IIM_DISSW	14V_pk-pk 500kHz	14V_pk-pk 500 kHz
8	4	TPS7H6003	¹⁶⁵Ho	75	5.64 × 10⁴	1 × 10⁷	14	14	IIM_DISST	14V_DC	0V
9	4	TPS7H6003	¹⁶⁵Ho	75	5.78 × 10⁴	1 × 10⁷	14	14	IIM_DISST	0V	14V_DC
36	5	TPS7H6013	¹⁶⁵Ho	75	7 × 10⁴	1 × 10⁷	14	14	PWM	14V_DC	14V_pk-pk 500kHz
37	6	TPS7H6013	¹⁶⁵Ho	75	6.42 × 10⁴	1 × 10⁷	14	14	IIM_ENSW	14V_pk-pk 500 kHz	14V_pk-pk 500 kHz
38	7	TPS7H6013	¹⁶⁵Ho	75	8.58 × 10⁴	1 × 10⁷	14	14	IIM_DISSW	14V_pk-pk 500kHz	14V_pk-pk 500kHz
39	8	TPS7H6023	¹⁶⁵Ho	75	6.94 × 10⁴	1 × 10⁷	14	14	PWM	14V_DC	14V_pk-pk 500kHz
40	9	TPS7H6023	¹⁶⁵Ho	75	6.67 × 10⁴	1 × 10⁷	14	14	IIM_ENSW	14V_pk-pk 500kHz	14V_pk-pk 500kHz
41	10	TPS7H6023	¹⁶⁵Ho	75	5.59 × 10⁴	1 × 10⁷	14	14	IIM_DISSW	14V_pk-pk 500kHz	14V_pk-pk 500kHz

Using the MFTF method shown in Single-Event Effects (SEE) Confidence Interval Calculations and combining (or summing) the fluences of the four runs at 125°C (4 × 10⁷), the upper-bound cross-section (using a 95% confidence level) is calculated as:

Equation 1.

σ_{S E L} \leq 4.11 x 10^{- 8} {c m}^{2} / d e v i c e f o r {L E T}_{E F F} = 75 M e V \cdot {c m}^{2} / m g a n d T = 125 ° C

TPS7H6003-SP SEL Run 1 (PWM Mode,
fsw = 500kHz)

Figure 7-1 SEL Run 1 (PWM Mode, f_sw = 500kHz)

TPS7H6003-SP SEL Run 2 (PWM Mode,
fsw = 1MHz)

Figure 7-2 SEL Run 2 (PWM Mode, f_sw = 1MHz)

TPS7H6003-SP SEL Run 3 (PWM Mode,
fsw = 2MHz)

Figure 7-3 SEL Run 3 (PWM Mode, f_sw = 2MHz)

TPS7H6003-SP SEL Run 4 (IIM Enabled Mode,
PWM/LI = 14V)

Figure 7-4 SEL Run 4 (IIM Enabled Mode, PWM/LI = 14V)

TPS7H6003-SP SEL Run 9 (IIM Disabled Mode,
EN/HI = 14V)

Figure 7-5 SEL Run 9 (IIM Disabled Mode, EN/HI = 14V)