To obtain a low-power and compact implementation of the advanced encryption standard (AES) S- box, an asynchronous pipeline architecture over composite field arithmetic was proposed in this paper. In the presented S-box, some improvements were made as follows. (1) Level-sensitive latches were inserted in data path to block the propagation Of the dynamic hazards, which lowered the power of data path circuit. (2) Operations of latches were controlled by latch controllers based on presented asynchronous sequence element: LC-element, which utilized static asymmetric C-element to construct a simple and power-efficient circuit structure. (3) Implementation of the data path circuit was a semi-custom standard-cell circuit on 0.25μm complementary mental oxide semiconductor (CMOS) process; and the full-custom design methodology was adopted in the handshake circuit design. Experimental results show that the resulting circuit achieves nearly 46% improvement with moderate area penalty ( 11.7% ) compared with the related composite field S-box in power performance. The presented S-box circuit can be a hardware intelli-gent property (IP) embedded in the targeted systems such as wireless sensor networks (WSN), smart-cards and radio frequency identification (RFID).
In this paper, an Ethernet controller SoC solution and its low power design for testability (DFT) for information appliances are presented. On a single chip, an enhanced one-cycle 8-bit micro controller unit (MCU), media access control (MAC) circuit and embedded memories such as static random access memory (SRAM), read only memory (ROM) and flash are all integrated together. In order to achieve high fault coverage, at the same time with low test power, different DFT techniques are adopted for different circuits: the scan circuit that reduces switching activity is implemented for digital logic circuits; BIST-based method is employed for the on-chip SRAM and ROM. According to the fault-modeling of embedded flash, we resort to a March-like method for flash built in self test (BIST). By all means above, the result shows that the fault coverage may reach 97%, and the SoC chip is implemented successfully by using 0.25 μm two-poly four-metal mixed signal complementary metal oxide semiconductor (CMOS) technology, the die area is 4.8×4.6 mm^2. Test results show that the maximum throughput of Ethemet packets may reach 7Mb·s^1.
The implementation of small size cryptography algorithm is a critical problem for wireless sensor network. A low cost compact intellectual property (IP) core of the entire advanced encryption standard (AES) algorithm for wireless sensor network is presented in this paper. A compact encryption and decryption system using only four sharing S-Boxes is obtained, employing sharing between the encryption and decryption processes. Our design proposes use of composite field data path for the SubBytes and InvSubBytes transformations. With an implementation of the AES block cipher with Virtex Ⅱ Pro FPGA using0.13μm and 90nm process technology, our area optimized consumes 16.8k equivalent gates. The speed of this implementation is also reduced to 0.45Gbits/s. Compared with previous implementations, our design achieves significant low-cost area with acceptable throughput.
易立华 Zou Xuecheng Liu Zhenglin Dan Yongping Zou Wanghui
