This paper describes a new technique for integrating asynchronous modules within a high-speed synchronous pipeline. Our design eliminates potential metastability problems by using a clock generated by a stoppable ring oscillator, which is capable of driving the large clock load found in present day microprocessors. Using the ATACS design tool, we designed highly optimized transistor-level circuits to control the ring oscillator and generate the clock and handshake signals with minimal overhead. Our interface architecture requires no redesign of the synchronous circuitry. Incorporating asynchronous modules in a high-speed pipeline improves performance by exploiting data-dependent delay variations. Since the speed of the synchronous circuitry tracks the speed of the ring oscillator under different processes, temperatures, and voltages, the entire chip operates at the speed dictated by the current operating conditions, rather than being governed by the worst case conditions. These two factors together can lead to a significant improvement in average-case performance. The interface design is simulated using the 0.6-/spl mu/m HP CMOS14B process in HSPICE.
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机译:本文介绍了一种用于在高速同步管道中集成异步模块的新技术。我们的设计通过使用可停止的环形振荡器产生的时钟消除了潜在的亚稳性问题,该时钟能够驱动当今微处理器中的大时钟负载。使用ATACS设计工具,我们设计了高度优化的晶体管级电路,以控制环形振荡器并以最小的开销生成时钟和握手信号。我们的接口体系结构不需要重新设计同步电路。通过利用依赖于数据的延迟变化,在高速管线中集成异步模块可提高性能。由于同步电路的速度在不同的过程,温度和电压下跟踪环形振荡器的速度,因此整个芯片将以当前工作条件所决定的速度工作,而不是由最坏情况下的条件所控制。这两个因素共同导致平均性能的显着提高。接口设计是使用HSPICE中的0.6- / splμ/ m HP CMOS14B工艺进行仿真的。
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