Powerful simulation engines perform extensive analysis of Frequency and Power across hundreds of process points, voltages and temperatures.
Further analysis provides full production distribution view, allowing design teams to make informed decisions for improved power, performance, area, and parametric yield.
At the push of a button, gain a higher volume and higher coverage parametric grading of your chip during Characterization and Qualification.
Achieve post-to-pre silicon correlation at every stage (Wafer Sort, Final Test and System Level Test), based on uploaded chip data that provide the expected performance of Agents and the design under monitor, for hundreds of Monte-Carlo simulations at many voltages and temperatures.
Additional insights are generated based on machine learning inference. Gain degradation monitoring visibility during HTOL.
During High Volume Manufacturing Increase chip quality and production throughput.
Gain early and fine-binning, conduct advanced outlier detection for reduced DPPM and gain parametric visibility during high volume production with characterization-like data, such as measurement of remaining margin on millions of internal paths.
Provide early indications of parametric yield fluctuations that allow proactive yield improvements to increase overall yield. Further correlation is achieved between Wafer Sort, Final Test, and System Level testing.
At system New Product Introduction, gain visibility into the performance of the device working in the system under many different workloads and tune applications for maximum performance.
Correlation of measured margins across paths to chip Final Test allows for optimization of both Final Test and assembly operations.
During system High Volume Manufacturing, production teams gain valuable insights into device performance in the target system.
The device acts as a sensor to identify and pinpoint system faults, such as a failing power supply, clock deficiencies, device system-specific or assembly issues.
Avoid piles of malfunctioning systems and labor intensive, low-quality touch-up activities.
Increase field reliability, maintain uninterrupted uptime and optimize electronics’ workload and performance, while managing remaining useful life, for continuous predictive maintenance.
