Ultra-High-Throughput Multi-Core AES Encryption Hardware Architecture

Pham-Khoi Dong, Hung K. Nguyen, F. Hussin, Xuan-Tu Tran
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引用次数: 1

Abstract

Security issues in high-speed data transfer between devices are always a big challenge. On the other hand, new data transfer standards such as IEEE P802.3bs 2017 stipulate the maximum data rate up to 400 Gbps. So, security encryptions need high throughput to meet data transfer rates and low latency to ensure the quality of services. In this paper, we propose a multi-core AES encryption hardware architecture to achieve ultra-high-throughput encryption. To reduce area cost and power consumption, these cores share the same KeyExpansion blocks. Fully parallel, outer round pipeline technique is also applied to the proposed architecture to achieve low latency encryption. The design has been modelled at RTL (Register-Transfer-Level) in VHDL and then synthesized with a CMOS 45nm technology using Synopsys Design Compiler. With 10-cores fully parallel and outer round pipeline, the implementation results show that our architecture achieves a throughput of 1 Tbps at the maximum operating frequency of 800 MHz. These results meet the speed requirements of future communication standards. In addition, our design also achieves a high power-efficiency of 2377 Gbps/W and area-efficiency of 833 Gbps/mm2, that is 2.6x and 4.5x higher than those of the other highest throughput of single-core AES, respectively.
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超高吞吐量多核AES加密硬件架构
设备间高速数据传输的安全问题一直是一个巨大的挑战。另一方面,IEEE P802.3bs 2017等新的数据传输标准规定了最高400gbps的数据传输速率。因此,安全加密需要高吞吐量来满足数据传输速率,同时需要低延迟来保证服务质量。在本文中,我们提出了一个多核AES加密硬件架构,以实现超高吞吐量加密。为了降低面积成本和功耗,这些核心共享相同的KeyExpansion模块。完全并行的外圆管道技术也被应用到该架构中,以实现低延迟加密。该设计已在VHDL的RTL (Register-Transfer-Level)中建模,然后使用Synopsys design Compiler使用CMOS 45nm技术进行合成。采用10核全并行和外圆管道,实现结果表明,我们的架构在800mhz的最高工作频率下实现了1 Tbps的吞吐量。这些结果满足了未来通信标准对速度的要求。此外,我们的设计还实现了2377 Gbps/W的高功率效率和833 Gbps/mm2的面积效率,分别比其他最高吞吐量的单核AES高2.6倍和4.5倍。
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