SBAK021 December   2024 AFE7950-SP

 

  1.   1
  2.   2
  3.   Trademarks
  4. 1Introduction
  5. 2Single-Event Effects
  6. 3Device and Test Board Information
  7. 4Irradiation Facility and Setup
  8. 5Test Setup and Procedures
  9. 6Destructive Single-Event Effects (DSEE)
  10. 7Single-Event Effects (SEE)
  11. 8Event Rate Calculations
  12. 9References

Single-Event Effects (SEE)

Single Event Upsets

Deviations in AC performance of the RX channel were used as a figure of merit for SEU. SNR degradation was treated as the main indicator of an upset to the AFE7950-SP. Prior to an SEU beam run, the AFE7950-SP was power-cycled, programmed, and baseline FFTs were stored for all RX and TX channels. When the SNR noisefloor degraded from the baseline of 100dB, the beam stops and device is re-programmed (no power cycle involved) and have the fluence recorded. To determine the correlation between channels, a snapshot of the status of all the channels was recorded when RX channel 1 recorded an SEU event.Figure 7-1 shows the summary of what other channels failed at end of run.

AFE7950-SP State of Channels Post
                    Beam Figure 7-1 State of Channels Post Beam
Table 7-1 SEU Runs

Run #

LETEFF (MeV∙cm²/mg)

Fluence (ions/cm2)

Flux (ions/[cm2·s])

Uniformity

Run Time

1

Ag

57.73

3.89 x 103

9.71 x 102

40.06

2

57.73

1.67 x 104

9.58 x 102

174.00

3

57.73

3.79 x 104

9.047 x 102

97.00

418.88

4

57.73

1.97 x 104

8.83 x 102

98.00

223.35

5

57.73

1.47 x 104

9.83 x 102

98.00

149.28

6

57.73

1.02 x 104

8.75 x 102

98.00

117.00

7

57.73

1.13 x 104

1.17 x 102

95.00

96.25

8

57.73

6.67 x 103

1.22 x 102

95.00

54.37

9

57.73

3.98 x 103

1.21 x 102

96.00

32.83

10

57.73

1.46 x 104

1.23 x 102

97.00

118.66

1

Cu

24.54

1.71 x 104

1.25 x 102

92

137.08

2

24.54 2.14 x 104 1.14 x 102

94

167.9

3

24.54 2.75 x 103 1.08 x 102

95

25.31

4

24.54 9.65 x 104 1.10 x 102

91

877.87

5

24.54 1.31 x 104 1.05 x 102

90

124.68

6

24.54 2.60 x 104 1.06 x 102

94

244.22

7

24.54 3.46 x 104 1.35 x 102

100

255.88

8

24.54 9.20 x 103 1.37 x 102

95

67.25

9

24.54 1.37 x 104 1.34 x 102

93

102.37

10

24.54 1.94 x 104 1.57 x 102

97

123.42

11

24.54 3.34 x 104 1.55 x 102

97

215.81

1

Ar

9.75

6.17 x 104

1.20 x 102

94.00

557.00

2

9.75

2.52 x 104

1.17 x 103

95.00

22.00

3

9.75

4.89 x 104

1.16 x 103

95.00

42.08

4

9.75

9.44 x 104

1.25 x 103

94.00

75.40

5

9.75

1.82 x 104

1.18 x 103

95.00

15.50

6

9.75

1.34 x 104

1.24 x 103

95.00

10.78

Single-Event Functional Interrupts

The single events that needed power-cycling and reprogramming were classified as a SEFI event. Our procedure for recording SEFIs was to run the beam for a predetermined amount of time based on the flux level. The typical time period was 5 minutes for a flux of 1E2. At the end of the interval, the beam was paused and the device was re-programmed to the original state. If the RX channel 1 SNR came back to a SNR noisefloor of a 100dB then the beam continues for the next period of time. If the noise floor did not recover, reconfiguration of the device is done after power cycling the device. The fluence that accumulated so far is used to calculate the cross section of SEFI for the particular LET.

Table 7-2 SEFI Runs
Flux (ions·cm2/s) Ion LET (MeV∙cm²/mg) Time Fluence SEFI?
1.00 × 104 Ar 9.75 25 sec 2.45 × 105 No
1.00 × 104 50 sec 4.88 × 105 No
1.00 × 104 75 sec 7.15 × 105 No
1.00 × 104 100 sec 9.53 × 105 Yes
1.00 × 102 Cu 24.54 5 min 4.43 × 104 No
1.00 × 102 10 min 8.79 × 104 No
1.00 × 102 15 min 1.28 × 105 No
1.00 × 102 20 min 1.71 × 105 No
1.00 × 102 25 min 2.16 × 105 No
1.00 × 102 30 min 2.56 × 105 No
1.00 × 102 35 min 3.00 × 105 Yes
1.00 × 102 Ag 57.73 5 min 3.92 × 104 No
1.00 × 102 20 min 1.60 × 105 No
1.00 × 102 25 min 2.00 × 105 No
1.00 × 102 30 min 2.39 × 105 Yes