Timing Resilience for Efficient and Secure Circuits

2020 25th Asia and South Pacific Design Automation Conference (ASP-DAC) Pub Date : 2020-01-01 DOI:10.1109/ASP-DAC47756.2020.9045352

Grace Li Zhang, M. Brunner, Bing Li, G. Sigl, Ulf Schlichtmann

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Abstract

In this paper, we will cover several techniques that can enhance the resilience of timing of digital circuits. Using post-silicon tuning components, the clock arrival times at flip-flops can be modified after manufacturing to balance delays between flip-flops. The actual delay properties of flip-flops will be examined to exploit the natural flexibility of such components. Wave-pipelining paths spanning several flip-flop stages can be integrated into a synchronous design to improve the circuit performance and to reduce area. In addition, with this technique, it cannot be taken for granted anymore that all the combinational paths in a circuit work with respect to one clock period. Therefore, a netlist alone does not represent all the design information. This feature enables the potential to embed wave-pipelining paths into a circuit to increase the complexity of reverse engineering. In order to replicate a design, attackers therefore have to identify the locations of the wave-pipelining paths, in addition to the netlist extracted from reverse engineering. Therefore, the security of the circuit against counterfeiting can be improved.

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有效和安全电路的时序弹性

在本文中，我们将介绍几种可以增强数字电路时序弹性的技术。使用后硅调谐元件，触发器的时钟到达时间可以在制造后修改，以平衡触发器之间的延迟。我们将研究人字拖的实际延迟特性，以利用这些元件的自然灵活性。跨越多个触发器级的波管道路径可以集成到一个同步设计中，以提高电路性能并减少面积。此外，使用这种技术，不能再想当然地认为电路中的所有组合路径都相对于一个时钟周期工作。因此，网表本身并不能代表所有的设计信息。这一特性使嵌入波管道路径到电路的潜力，以增加逆向工程的复杂性。为了复制设计，攻击者因此除了从逆向工程中提取的网络列表外，还必须确定波浪管道路径的位置。因此，可以提高电路的防伪安全性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2020 25th Asia and South Pacific Design Automation Conference (ASP-DAC)

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