安全主题演讲:物联网平台的超低能耗安全电路原语

S. Mathew
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引用次数: 0

摘要

低区域节能安全原语是实现物联网平台端到端内容保护、用户身份验证和数据安全的关键构建模块。本演讲介绍了安全电路原语的设计,该设计采用节能电路技术和最佳硬件友好算法,可无缝集成到面积/电池受限的物联网系统中:1)在22nm CMOS中实现289gbps /W效率的2040门AES加速器,2)强化混合物理不可克隆功能(PUF)电路,以生成100%稳定的加密密钥。3)全数字TRNG实现>0.99 min-entropy,能量效率为3 pj /bit。讲座还将讨论与侧信道密钥信息泄漏相关的设计问题,以及如何在加密电路的设计中解决这些问题。最后,该演讲将触及维护安全电路完整性的现有挑战,同时仍然能够实现可测试性和后硅验证。
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Security keynote: Ultra-low-energy security circuit primitives for IoT platforms
Low-area energy-efficient security primitives are key building blocks for enabling end-to-end content protection, user authentication and data security in IoT platforms. This talk describes the design of security circuit primitives that employ energy-efficient circuit techniques with optimal hardware-friendly arithmetic for seamless integration into area/battery-constrained IoT systems: 1) A 2040-gate AES accelerator achieving 289-Gbps/W efficiency in 22-nm CMOS, 2) Hardened hybrid physically unclonablef Function (PUF) circuit to generate a 100% stable encryption key. 3) All-digital TRNG to achieve >0.99-min-entropy with 3-pJ/bit energy efficiency. The talk will also discuss design issues related to side-channel leakage of key information, and how they may be addressed during design of encryption circuits. Finally, the talk will touch upon existing challenges of maintaining the integrity of security circuits, while still enabling testability and post-silicon validation.
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