Ultra High Performance Digital Circuit Design and Synthesis

超高性能数字电路设计与综合

• 批准号: 0204010
• 负责人: Carl Sechen
• 金额: $ 20万
• 依托单位: University of Washington
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2002
• 资助国家: 美国
• 起止时间: 2002-07-01 至 2007-03-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0204010&HistoricalAwards=false
• 关键词: Ultra; Performance; Digital; Circuit; Design

The focus of this proposal is on extremely high performance (very high speed, but also energy efficient) digital IC design. The proposed research has three tasks: 1) high performance digital logic techniques, 2) CAD tool development to aid rapid deployment of the high performance logic techniques, and 3) applications of the high performance logic techniques; in particular, the design of circuit blocks that demonstrate unprecedented speed, while still having reasonable energy efficiencyTask 1: Research on High Performance Digital Logic Techniques: Focus is on maximizing the performance of the output prediction logic (OPL) technique, and developing yet faster and/or more energy efficient logic techniques.Task 2: CAD for Rapid Implementation of High Performance Digital Logic:TechniquesTwo CAD tools will be developed to ease design and verification of OPL circuits under this proposal: 1) A static timing analysis tool for OPL circuits, and 2) an automatic transistor/gate sizing tool for OPL circuits that minimizes energy consumption subject to delay goals. Also a powerful convex-optimization-based tool for automatic transistor and gate sizing for OPL circuits is being investigated. The tool will minimize energy consumption while achieving a specified delay target.Task 3: Research on Applications of High Performance Digital LogicTechniques:Applications include: 1) a new 64b adder architecture having a simulated worst-casedelay (under severe process, voltage and temperature variations) of 3.3fanout-of-four inverter delays. 2) a very fast floating-point divider with the possibility of a latency of 6ns for a 0.20-micron TSMC process. This divider will run at a frequency of at least 3 GHz in this 0.20-micron process, enabling the use of division for the very first time in signal processing and communications circuits. 3) a new FPGA architecture, called OPL-FPGA, which suggests an FPGA could approach the circuit speeds obtained by standard cell ASICs. Mapping common datapath circuits to this architecture further suggests that speedups of at least 3.3X over state-of-the-art commercial FPGAs are attainable.

该提案的重点是极高性能（非常高的速度，但也节能）的数字IC设计。该研究有三个任务：1）高性能数字逻辑技术，2）CAD工具开发，以帮助快速部署高性能逻辑技术，以及3）高性能逻辑技术的应用;特别是，电路块的设计，表现出前所未有的速度，同时仍然具有合理的能源效率任务1：高性能数字逻辑技术的研究：重点是最大限度地提高输出预测逻辑（OPL）技术的性能，并开发更快和/或更节能的逻辑技术。任务2：用于快速实现高性能数字逻辑的CAD：技术将开发两种CAD工具，以简化OPL电路的设计和验证。1）用于OPL电路的静态时序分析工具，以及2）用于OPL电路的自动晶体管/栅极尺寸调整工具，其最小化受制于延迟目标的能量消耗。此外，一个功能强大的凸优化为基础的工具，自动晶体管和OPL电路的门尺寸正在研究。任务3：高性能数字逻辑应用研究技术：应用包括：1）一种新的64位加法器结构，其模拟的最坏情况延迟（在严重的工艺、电压和温度变化下）为3. 3 fanout of four inverter延迟。2)一个非常快速的浮点除法器，对于0.20微米的TSMC工艺，延迟可能为6 ns。该分频器将在0.20微米工艺中以至少3 GHz的频率运行，首次在信号处理和通信电路中使用分频。3)一种新的FPGA架构，称为OPL-FPGA，这表明FPGA可以接近标准单元ASIC所获得的电路速度。将通用数据路径电路映射到这种架构进一步表明，与最先进的商业FPGA相比，至少可以实现3.3倍的加速比。