Jeffrey Christopher Chromczak

A comprehensive approach to modeling, characterizing and optimizing for metastability in FPGAs

Metastability is a phenomenon that can cause system failures in digital circuits. It may occur whenever signals are being transmitted across asynchronous or unrelated clock domains. The impact of metastability is increasing as process geometries shrink and supply voltages drop faster than transistor Vts. FPGA technologies are significantly affected since leading edge FPGAs are amongst the first devices to adopt the most recent process nodes. In this paper, we present a comprehensive suite of techniques for modeling, characterizing and optimizing metastability effects in FPGAs. We first discuss a theoretical model of metastability, and verify the predictions using both circuit level simulations and board measurements. Next we show how designers have traditionally dealt with metastability problems and contrast that with the automatic CAD algorithms described in this paper that both analyze and optimize metastability-related issues. Through our detailed experimental results, we show that we can improve the metastability characteristics of a large suite of industrial benchmarks by an average of 268,000 times with our optimization techniques.

The Stratix™ 10 Highly Pipelined FPGA Architecture

This paper describes architectural enhancements in the Altera Stratix? 10 HyperFlex? FPGA architecture, fabricated in the Intel 14nm FinFET process. Stratix 10 includes ubiquitous flip-flops in the routing to enable a high degree of pipelining. In contrast to the earlier architectural exploration of pipelining in pass-transistor based architectures, the direct drive routing fabric in Stratix-style FPGAs enables an extremely low-cost pipeline register. The presence of ubiquitous flip-flops simplifies circuit retiming and improves performance. The availability of predictable retiming affects all stages of the cluster, place and route flow. Ubiquitous flip-flops require a low-cost clock network with sufficient flexibility to enable pipelining of dozens of clock domains. Different cost/performance tradeoffs in a pipelined fabric and use of a 14nm process, lead to other modifications to the routing fabric and the logic element. User modification of the design enables even higher performance, averaging 2.3X faster in a small set of designs.