Compact and high-speed hardware architectures and logic optimization methods for the AES algorithm Rijndael are described. Encryption and decryption data paths are combined and all arithmetic components are reused. By introducing a new composite field, the S-Box structure is also optimized. An extremely small size of 5.4 Kgates is obtained for a 128-bit key Rijndael circuit using a 0.11-µm CMOS standard cell library. It requires only 0.052 mm 2 of area to support both encryption and decryption with 311 Mbps throughput. By making effective use of the SPN parallel feature, the throughput can be boosted up to 2.6 Gbps for a high-speed implementation whose size is 21.3 Kgates.
This paper presents a new type of wireless networking applications in data centers using steered-beam mmWave links. By taking advantage of clean LOS channels on top of server racks, robust wireless packet-switching network can be built. The transmission latency can be reduced by flexibly bridging adjacent rows of racks wirelessly without using long cables and multiple switches. Eliminating cables and switches also reduces equipment costs as well as server installation and reconfiguration costs. Security can be physically enhanced with controlled directivity and negligible wall penetration. The aggregate data transmission BW per given volume is expected to scale as the fourth power of carrier frequency. The paper also deals with the architecture of such network configurations and a preliminary demonstration system.
In System on Chip (SoC) design, growing design complexity has forced designers to start designs at higher abstraction levels. This paper proposes an SoC design methodology that makes full use of FPGA capabilities. Design modules in different abstraction levels are all combined and run together in an FPGA prototyping system that fully emulates the target SoC. The higher abstraction level design modules run on microprocessors embedded in the FPGAs, while lower-level synthesizable RTL design modules are directly mapped onto FPGA reconfigurable cells. We made a hardware wrapper that gets the embedded microprocessors to interface with the fully synthesized modules through IBM CoreConnect buses. Using this methodology, we developed an image processor SoC with cryptographic functions, and we verified the design by running real firmware and application programs. For the designs that are too large to be fit into an FPGA, dynamic reconfiguration method is used.
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