2021
DOI: 10.46586/tches.v2021.i4.388-411
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Low-Latency Keccak at any Arbitrary Order

Abstract: Correct application of masking on hardware implementation of cryptographic primitives necessitates the instantiation of registers in order to achieve the non-completeness (commonly said to stop the propagation of glitches). This sometimes leads to a high latency overhead, making the implementation not necessarily suitable for the underlying application. As a concrete example, this holds for Keccak. Application of d + 1 Domain Oriented Masking (DOM) on a round-based implementation of Keccak leads to the introdu… Show more

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Cited by 7 publications
(2 citation statements)
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“…In particular, we perform non-specific fixed versus random t-tests, where we aim to determine the validity of the null hypothesis that encryptions with a fixed and uniformly sampled plaintext admit the same mean power consumption (i.e., are indistinguishable under first-order statistical analysis). Following the state of the art [1,24,30], we set a threshold |t| > 4.5 for any t-value to reject the null hypothesis.…”
Section: T-testsmentioning
confidence: 99%
“…In particular, we perform non-specific fixed versus random t-tests, where we aim to determine the validity of the null hypothesis that encryptions with a fixed and uniformly sampled plaintext admit the same mean power consumption (i.e., are indistinguishable under first-order statistical analysis). Following the state of the art [1,24,30], we set a threshold |t| > 4.5 for any t-value to reject the null hypothesis.…”
Section: T-testsmentioning
confidence: 99%
“…In particular, we perform non-specific fixed versus random t-tests, where we aim to determine the validity of the null hypothesis that encryptions with a fixed and uniformly sampled plaintext admit the same mean power consumption (i.e., are indistinguishable under first-order statistical analysis). Following the state of the art [1,24,30], we set a threshold |t| > 4.5 for any t-value to reject the null hypothesis.…”
Section: T-testsmentioning
confidence: 99%