Abstract-While process variations are becoming more significant with each new IC technology generation, they are often modeled via linear regression models so that the resulting performance variations can be captured via normal distributions. Nonlinear response surface models (e.g., quadratic polynomials) can be utilized to capture larger scale process variations; however, such models result in nonnormal distributions for circuit performance. These performance distributions are difficult to capture efficiently since the distribution model is unknown. In this paper, an asymptoticprobability-extraction (APEX) method for estimating the unknown random distribution when using a nonlinear response surface modeling is proposed. The APEX begins by efficiently computing the high-order moments of the unknown distribution and then applies moment matching to approximate the characteristic function of the random distribution by an efficient rational function. It is proven that such a moment-matching approach is asymptotically convergent when applied to quadratic response surface models. In addition, a number of novel algorithms and methods, including binomial moment evaluation, PDF/CDF shifting, nonlinear companding and reverse evaluation, are proposed to improve the computation efficiency and/or approximation accuracy. Several circuit examples from both digital and analog applications demonstrate that APEX can provide better accuracy than a Monte Carlo simulation with 10 4 samples and achieve up to 10× more efficiency. The error, incurred by the popular normal modeling assumption for several circuit examples designed in standard IC technologies, is also shown.
Since performance on FPGAs is dominated by the routing architecture rather than wirelength, we propose a new architecture-aware approach to initial FPGA placement that models the relationship between performance and the routing grid, using concepts from graph embedding and metric geometry. Our approach, CAPRI, can be viewed as an embedding of a graph representing the netlist into a metric space that is representative of the FPGA. First, we develop an analytic metric of distance that models delays along the FPGA routing grid. We then embed a netlist into the defined metric space using matrix projections and online bipartite matching. Experimental comparisons with the popular FPGA tool, VPR, show that with CAPRI's initial solution, the resulting placements show median improvements of 10% in critical path delays for the larger MCNC benchmarks. Total placement runtime is also improved by 2x on average.
Since performance on FPGAs is dominated by the routing architecture rather than wirelength, we propose a new architecture-aware approach to initial FPGA placement that models the relationship between performance and the routing grid, using concepts from graph embedding and metric geometry. Our approach, CAPRI, can be viewed as an embedding of a graph representing the netlist into a metric space that is representative of the FPGA. First, we develop an analytic metric of distance that models delays along the FPGA routing grid. We then embed a netlist into the defined metric space using matrix projections and online bipartite matching. Experimental comparisons with the popular FPGA tool, VPR, show that with CAPRI's initial solution, the resulting placements show median improvements of 10% in critical path delays for the larger MCNC benchmarks. Total placement runtime is also improved by 2x on average.
The advent of deep sub-micron technologies has created a number of problems for existing design methodologies. Most prominent among them is the problem of timing closure, whereby design time is dramatically increased due to iterations between gate-level synthesis and physical design. It is well known that the heart of this problem lies in the use of wireload models based on wirelength statistics from legacy designs. Some technology projections in [3] have suggested that wireload models will remain effective to block sizes on the order of 50k gates. This suggests that synthesis will not have to be changed much since this is approximately the maximum size for which logic synthesis is effective. However, our analyses on production designs show that the problem is not quite so straightforward, and the efficacy of synthesis using wireload models depends upon technology data as well as specific characteristics of the design. We analyze these effects and dependencies in detail in this paper, and draw some conclusions about the amount of physical information that is required for synthesis to be effective. Finally, we discuss the implications on hierarchical design flows, and propose a solution via physical prototyping.
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