Thought Leadership

Part 12: The 2016 Wilson Research Group Functional Verification Study

ASIC/IC Verification Results

This blog is a continuation of a series of blogs related to the 2016 Wilson Research Group Functional Verification Study (click here).  In my previous blog (click here), I provided data related to designs that actively manage power. In this blog, I present verification results findings in terms of schedules, number of required spins, and classification of functional bugs.

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Figure 1. Design Completion Compared to Original Schedule

Figure 1 presents the design completion time compared to the project’s original schedule. While the data suggest that in 2014 there might have been a slight improvement in projects meeting their original schedule, the 2016 findings are consistent with the 2007 and 2012 studies. The bottom line is that meeting the originally planned schedule is still a challenge for most of the industry.

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Figure 2. Required Number of Spins

Other results trends worth examining relate to the number of spins required between the start of a project and final production. Figure 2 shows this industry trend from 2012 through 2016. Even though designs have increased in complexity, the data suggest that achieving first silicon success is not getting any worse in terms of the number of required spins before production. Still, only a little more than 30 percent of today’s projects are able to achieve first silicon success. In addition, it is worth noting that achieving second silicon success is getting worse.

Figure 3 shows various categories of flaws that are contributing to respins. Again, you might note that the sum is greater than 100 percent on this graph, which is because multiple flaws can trigger a respin.

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Figure 3. Types of Flaws Resulting in Respins

Logic and functional flaws remain the leading causes of respins. One observation from the 2016 study is that there seems to have been a spike in the number of respins due to power issues.

Figure 4 examines the root cause of logical or functional flaws (previously identified in Figure 3) by various categories. The data suggest design errors are the leading cause of functional flaws, and the situation is worsening. In addition, problems associated with changing, incorrect, and incomplete specifications are a common theme often voiced by many verification engineers and project managers.

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Figure 4. Root Cause of Functional Flaws

In my next blog (click here), I provide some concluding remarks and observations.

Quick links to the 2016 Wilson Research Group Study results

Harry Foster

Harry Foster is Chief Scientist Verification for the Design Verification Technology Division of Mentor, A Siemens Business; and is the Co-Founder and Executive Editor for the Verification Academy. In addition, Harry is serving as the 2021 Design Automation Conference General Chair. He holds multiple patents in verification and has co-authored six books on verification. Harry was the 2006 recipient of the Accellera Technical Excellence Award for his contributions to developing industry standards, and was the original creator of the Accellera Open Verification Library (OVL) standard.

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This article first appeared on the Siemens Digital Industries Software blog at https://blogs.stage.sw.siemens.com/verificationhorizons/2016/12/02/part-12-the-2016-wilson-research-group-functional-verification-study/