Electron-Induced Single-Event Effect in 28 nm SRAM-Based FPGA

Tian, Jiayu; Cao, Rongxing; Liu, Yan; Cai, Yulong; Mei, Bo; Zhao, Lin; Cui, Shuai; Lv, He; Xue, Yuxiong

doi:10.3390/electronics13122233

Electronics

2024

DOI: 10.3390/electronics13122233

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Electron-Induced Single-Event Effect in 28 nm SRAM-Based FPGA

Jiayu Tian,

Rongxing Cao,

Yan Liu

et al.

Abstract: As the feature size of integrated circuit decreases, the critical charge of single-event effect decreases as well, making nano-scale devices more susceptible to the high-energy charged particles during their application in space. Here, we study the electron-induced single-event effect in 28 nm static random-access memory (SRAM)-based field programmable gate array (FPGA) utilizing high-energy electrons with energy of 1 MeV~5 MeV. The experimental results demonstrate that the 3 MeV electrons can cause single-eve… Show more

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Proposal of an External Remote Sensing Circuitry for Switching-Mode Power Supplies

Salavarin,

Placinta,

Ravariu

2024

Electronics

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This work proposes a low-cost and easy-to-implement solution for a remote voltage-sensing circuitry that can be used to ensure stability and good voltage regulation in applications with power supplies driving currents over long paths. The circuitry is implemented with general-purpose electronic components and is provided as an external feature to be attached to power supplies without remote sensing. To demonstrate its capabilities, a test bench was put together alongside a power supply module which has local sensing only. With the test bench, the output voltage from the power supply was delivered in various scenarios to an electronic load. Multiple parameters were monitored in order to assess the power supply performance to which the proposed remote voltage-sensing circuitry is attached. The measurements include stability and transient response tests, and the results were compared with the ones obtained with the standard local sensing. The tests reveal that the power supply module kept its output voltage stable with less than +/−10% voltage variation, and the average transient recovery time was less than 100 µs. The results are given for two different output voltage values of 1.2 V and 3.3 V and at high current capabilities of 3.5 A.

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Proposal of an External Remote Sensing Circuitry for Switching-Mode Power Supplies

Salavarin,

Placinta,

Ravariu

2024

Electronics

View full text Add to dashboard Cite

show abstract

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Electron-Induced Single-Event Effect in 28 nm SRAM-Based FPGA

Cited by 1 publication

References 22 publications

Proposal of an External Remote Sensing Circuitry for Switching-Mode Power Supplies

Proposal of an External Remote Sensing Circuitry for Switching-Mode Power Supplies

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