Rich Katz, Grunt Engineer NASA Office of Logic Design

1. Briefing: Independent NASA Test of RTSX-SU FPGAsTesting and Conditions Rich Katz, Grunt Engineer NASA Office of Logic Design

2. Testing and Conditions: Outline • Accelerated Tests • Electrical Environment • Thermal Environment • ATE Testing • NASA and Tiger Team Test Comparison • SEE Testing Discussed Separately

3. Electrical Environment

4. DUT Electrical Environment • NASA Header/Driver Card • HCLK = 8 MHz • CLKA = 32 MHz • Supply Voltages • NASA Card: VCC = 5V • VCCI = 4.0V (voltage used to program magnitude of undershoot) • VCCA = 2.75V • I/O Shift Register • Frequency = 8 MHz • Number of SSO’s = 57 (40% of 143) • Pattern and Pattern Length = Ring counter, 5 bits • Average Undershoot = -1V (Room temperature measurement) • Array Shift Register • Frequency = 32 MHz • Pattern and Pattern Length = Ring counter, 2 bits (100% toggling) • Delay Line Frequency = 8 MHz ÷ 8 = 1 MHz

5. OvershootMAX(mV)

6. Thermal Environment

7. DUT Thermal Environment • Test Step Duration: 250 hours per step • Chamber Control Temperatures: • HTOL: +125 C • LTOL: -55 C • Device Power @ 125 C • Power (ICCI): 74mA x 4.00V = 0.295W • Power (ICCA): 350mA x 2.75V = 0.963W • Power (Total): 1.26 watts • Case and Junction Temperatures @ 125 C • Worst-Case Junction Temperature, TCASE = 125 C, no air flow: 153 C • Measured TCASE: 139 C • Absolute Maximum TJ = 150 C

8. ATE Testing

9. ATE Test Protocol • Post-Programming Testing • Tri-temperature testing (-55 C, +25 C, +125 C) • 5 minute soak time prior to tests • Intermediate Step Testing • +25 C • Key Point Testing • Tri-temperature testing (-55 C, +25 C, +125 C) • 5 minute soak time prior to tests • Test suite identical, over all temperatures and steps • Results reviewed by two independent teams • Any “out of family” results flagged • Devices either watched or pulled from population for analysis • Criteria can be either an absolute, a relative, or a delta value

10. Continuity and Shorts cont_setup continuity shorticca shorticci shortiks shortvsv shortvpp Delay Tests delay_test_LH delay_test_HL Functional Tests func_1Mhz_min func_50Mhz_min func_1Mhz_max func_50Mhz_max Leakage Currents, Device standby_icc_oe static_vca static_vci static_vks static_vsv static_vpp Leakage Currents, I/O highz_Max IIL_Inputs_Max_bpmu IIH_BiBuf_Max_bpmu IIL_Inputs_Max_bpmu IIH_BiBuf_Max_bpmu IIL_OE_Max_bpmu IIH_OE_Max_bpmu ATE TestsSorted, Not In Order Performed

11. Input Thresholds TTL_Vil_Min_Search TTL_Vil50_Min_Search TTL_Vih_Max_Search TTL_Vih50_Max_Search Cmos_Vil_Min_Search Cmos_Vil50_Min_Search Cmos_Vih_Max_Search Cmos_Vih50_Max_Search VOL Testing TTL_Vol1_Min_fun TTL_Vol1_BiBuf_Min_bpmu TTL_Vol1_Outs_Min_bpmu TTL_Vol2_Min_fun TTL_Vol2_BiBuf_Min_bpmu TTL_Vol2_Outs_Min_bpmu Cmos_Vol_Min_fun Cmos_Vol_BiBuf_Min_bpmu Cmos_Vol2_Min_fun Cmos_Vol2_BiBuf VOH Testing TTL_Voh1_Min_fun TTL_Voh1_BiBuf_Min_bpmu TTL_Voh1_Outs_Min_bpmu TTL_Voh2_Min_fun TTL_Voh2_BiBuf_Min_bpmu TTL_Voh2_Outs_Min_bpmu Cmos_Voh_Min_fun Cmos_Voh_BiBuf_Min_bpmu Cmos_Voh2_Min_fun Cmos_Voh2_BiBuf ATE TestsSorted, Not In Order Performed

12. NASA and Tiger Team Test Comparison

13. Differences: Tigger Team and NASA Testing (1)

14. Differences: Tigger Team and NASA Testing (2)

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