Toward Secured FPGA: Silicon Proven CLB with Reduced Information Leakage

David Zooker; Or Ohev Shalom; Yoav Weizman; Alexander Fish; Osnat Keren

doi:10.1109/LSSC.2020.3008704

Toward Secured FPGA: Silicon Proven CLB with Reduced Information Leakage

David Zooker, Or Ohev Shalom, Yoav Weizman, Alexander Fish, Osnat Keren

Bar-Ilan University - The Alexander Kofkin Faculty of Engineering

Bar-Ilan University

Research output: Contribution to journal › Article › peer-review

Abstract

The ubiquity of FPGAs in security applications makes it imperative to design a secured configurable logic block (sCLB) that is resilient to side channel attacks. In this letter, we take a step toward secured FPGA by introducing new design circuit level methodology for the implementation of an sCLB. The security level of the sCLB is significantly enhanced by the design of its combinational part (LUT block) based on a dual-rail precharge MUX (DPMUX). The sCLB was implemented in a configurable array and fabricated in 65-nm CMOS technology. Silicon measurements proved the effectiveness of the approach. The security level was evaluated using advanced power analysis techniques. In particular, the number of secret bits that can be learned (mutual information) by a CPA attack dropped from 4 b (out of 4) after 1200 power traces for a conventional LUT design to only 2.56 b after 19.2-M power traces.

Original language	American English
Article number	9139327
Pages (from-to)	146-149
Number of pages	4
Journal	IEEE Solid-State Circuits Letters
Volume	3
DOIs	https://doi.org/10.1109/LSSC.2020.3008704
State	Published - 1 Jan 2020

Keywords

Configurable logic block (CLB)
dual-rail precharge MUX (DPMUX)
hardware security
secure FPGA

All Science Journal Classification (ASJC) codes

Electrical and Electronic Engineering

Access to Document

10.1109/LSSC.2020.3008704

Cite this

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title = "Toward Secured FPGA: Silicon Proven CLB with Reduced Information Leakage",

abstract = "The ubiquity of FPGAs in security applications makes it imperative to design a secured configurable logic block (sCLB) that is resilient to side channel attacks. In this letter, we take a step toward secured FPGA by introducing new design circuit level methodology for the implementation of an sCLB. The security level of the sCLB is significantly enhanced by the design of its combinational part (LUT block) based on a dual-rail precharge MUX (DPMUX). The sCLB was implemented in a configurable array and fabricated in 65-nm CMOS technology. Silicon measurements proved the effectiveness of the approach. The security level was evaluated using advanced power analysis techniques. In particular, the number of secret bits that can be learned (mutual information) by a CPA attack dropped from 4 b (out of 4) after 1200 power traces for a conventional LUT design to only 2.56 b after 19.2-M power traces.",

keywords = "Configurable logic block (CLB), dual-rail precharge MUX (DPMUX), hardware security, secure FPGA",

author = "David Zooker and Shalom, {Or Ohev} and Yoav Weizman and Alexander Fish and Osnat Keren",

note = "Publisher Copyright: {\textcopyright} 2018 IEEE.",

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doi = "10.1109/LSSC.2020.3008704",

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AU - Fish, Alexander

AU - Keren, Osnat

PY - 2020/1/1

Y1 - 2020/1/1

N2 - The ubiquity of FPGAs in security applications makes it imperative to design a secured configurable logic block (sCLB) that is resilient to side channel attacks. In this letter, we take a step toward secured FPGA by introducing new design circuit level methodology for the implementation of an sCLB. The security level of the sCLB is significantly enhanced by the design of its combinational part (LUT block) based on a dual-rail precharge MUX (DPMUX). The sCLB was implemented in a configurable array and fabricated in 65-nm CMOS technology. Silicon measurements proved the effectiveness of the approach. The security level was evaluated using advanced power analysis techniques. In particular, the number of secret bits that can be learned (mutual information) by a CPA attack dropped from 4 b (out of 4) after 1200 power traces for a conventional LUT design to only 2.56 b after 19.2-M power traces.

AB - The ubiquity of FPGAs in security applications makes it imperative to design a secured configurable logic block (sCLB) that is resilient to side channel attacks. In this letter, we take a step toward secured FPGA by introducing new design circuit level methodology for the implementation of an sCLB. The security level of the sCLB is significantly enhanced by the design of its combinational part (LUT block) based on a dual-rail precharge MUX (DPMUX). The sCLB was implemented in a configurable array and fabricated in 65-nm CMOS technology. Silicon measurements proved the effectiveness of the approach. The security level was evaluated using advanced power analysis techniques. In particular, the number of secret bits that can be learned (mutual information) by a CPA attack dropped from 4 b (out of 4) after 1200 power traces for a conventional LUT design to only 2.56 b after 19.2-M power traces.

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ER -

Toward Secured FPGA: Silicon Proven CLB with Reduced Information Leakage

Abstract

Keywords

All Science Journal Classification (ASJC) codes

Access to Document

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