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引用次数: 12
摘要
随着规模的不断扩大,所有的晶体管都不再是平等的。在坐标(23,17)处的长度为4的水平路由段的延迟将不同于同一FPGA中的(12,14)段,也不同于另一个FPGA中的同一段。供应商的工具给出了这些延迟的保守值,但是确切地知道这些延迟是什么是非常宝贵的。在本文中,我们展示了如何仅使用FPGA上已经存在的组件(可配置锁相环,寄存器,逻辑和互连)以低成本获取此信息。我们提出的技术是通用的,可用于测量具有这些组件的FPGA上任何资源的延迟。我们提供了通用算法来识别一组有用的延迟分量,计算这些延迟分量所需的一组测量,以及执行计算所需的计算。我们在Altera Cyclone III (65nm)的互连上展示了我们的技术。因此,我们能够量化单个FPGA上名义上相同的路由段的延迟超过100 ps。
GROK-INT: Generating Real On-Chip Knowledge for Interconnect Delays Using Timing Extraction
With continued scaling, all transistors are no longer created equal. The delay of a length 4 horizontal routing segment at coordinates (23,17) will differ from one at (12,14) in the same FPGA and from the same segment in another FPGA. The vendor tools give conservative values for these delays, but knowing exactly what these delays are can be invaluable. In this paper, we show how to obtain this information, inexpensively, using only components that already exist on the FPGA (configurable PLLs, registers, logic, and interconnect). The techniques we present are general and can be used to measure the delays of any resource on any FPGA with these components. We provide general algorithms for identifying the set of useful delay components, the set of measurements necessary to compute these delay components, and the calculations necessary to perform the computation. We demonstrate our techniques on the interconnect for an Altera Cyclone III (65nm). As a result, we are able to quantify over a 100 ps spread in delays for nominally identical routing segments on a single FPGA.
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