Single-Rail Adiabatic Logic for Energy-Efficient and CPA-Resistant Cryptographic Circuit in Low-Frequency Medical Devices

Abstract: Designing energy-efficient and secure cryptographic circuits in low-frequency medical devices are challenging due to low-energy requirements. Also, the conventional CMOS logic-based cryptographic circuits solutions in medical devices can be vulnerable to side-channel attacks (e.g. correlation power analysis (CPA)). In this article, we explored single-rail Clocked CMOS Adiabatic Logic (CCAL) to design an energy-efficient and secure cryptographic circuit for low-frequency medical devices. The performance of the … Show more

“…Because of their use of charge recovery, adiabatic circuits not only have increased efficiency but also present much more uniform power draw profiles. The authors of [51] take advantage of this second fact to design a high-efficiency cryptographic accelerator that is much more resistant to power-based sidechannel attacks than similar designs implemented in conventional logic. The authors of [52] take this concept one step farther, implementing the entire medical device in adiabatic logic.…”

Survey of Novel Architectures for Energy Efficient High-Performance Mobile Computing Platforms

“…Because of their use of charge recovery, adiabatic circuits not only have increased efficiency but also present much more uniform power draw profiles. The authors of [51] take advantage of this second fact to design a high-efficiency cryptographic accelerator that is much more resistant to power-based sidechannel attacks than similar designs implemented in conventional logic. The authors of [52] take this concept one step farther, implementing the entire medical device in adiabatic logic.…”

Survey of Novel Architectures for Energy Efficient High-Performance Mobile Computing Platforms

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