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If you want to lower your risk and achieve SoC design success sooner, memory design and verification should be commanding your attention. This is even more true if your projects are safety-critical, including applications such as autonomous vehicles, smart medicine, life support in the cosmos, disaster prevention here on earth, you name it. In these critical applications, meeting or exceeding high reliability and functional safety can be the difference between life and death, chaos and order, success and failure. Simply put, you don¡¯t want your memory to fail.
Memory design must meet the moment as we trend toward a hyperconvergent, multi-die future. One-size-fits all, general-purpose memories no longer work for advanced applications. Today, a web of diverse analog and digital interconnects, a complex power distribution network (PDN), and new requirements for faster memory access all impact memory design, even while adapting to new protocols, technologies, and architectures. With all these balls in the air, how can you ensure that your memory design also remains reliable throughout its lifecycle?
Leveraging an article that recently appeared in , we¡¯re exploring the importance of memory reliability while addressing today¡¯s silicon design complexities. Read on to learn more about increasing memory reliability throughout the silicon lifecycle.
In electronic design, the terms ¡°safety¡± and ¡°reliability¡± are often conflated, but there are nuances that are important to understand. For instance, functional safety engineers design safety into a design by considering a lot of potential issues so problems are flagged for appropriate mitigation that is seamless and fast. On the other hand, designing reliability into an application minimizes the odds of those events happening and makes the design more resilient in case such events do happen anytime during the product lifecycle.
The good news is that electronic design automation (EDA) methods and tools already used in functional safety can be applied to memory, ensuring standards safety compliance for many applications, for instance, ISO 26262 in automotive. Reducing the number of faults, detecting them, and responding appropriately is critical to all the dies in your successful design. This is true throughout the lifecycle of your system and applies to your memory components as well. For memory, the biggest reliability hurdles happen in the early and late parts of the lifecycle and these challenges must be mitigated prior to tape out by performing static and dynamic analysis.
Here is a roadmap to better ensure memory reliability through every stage of life:
Early Life | Mid Life | End of Life | |
Memory Life-Stage Characteristics | Increased failures: Marginal devices are culled through failures, otherwise known as ¡°infant mortality¡± | Long period of low failure risk | Increased failures: Silicon aging decreases reliability and increases device failures |
Failure Mitigation through Static/Dynamic Analyses (prior to tape out) |
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Because you are anticipating the problems your memory encounters throughout its entire life¡ªdevelopment, manufacture, in the field, and beyond¡ªit¡¯s vital to ensure a cohesive methodology for a robust static and dynamic analysis that maps appropriately to the health of your chip. And¡ it¡¯s important to do this analysis prior to tape out. You will want a unified workflow with easy-to-use tools that will enable greater productivity while helping to solve any issues your chip may encounter before they become a problem.
Through Synopsys PrimeSim? Reliability Analysis and PrimeWave Design Environment, Synopsys delivers a complete solution for memory reliability that will lower your risk and ease your design process.
Synopsys PrimeSim Reliability Analysis provides a unified workflow of production-proven and foundry-certified reliability analysis technologies to enable full lifecycle reliability verification.
Synopsys PrimeWave Design Environment delivers a rich and consistent reliability verification experience across PrimeSim Reliability Analysis technologies and PrimeSim simulator engines with unified setup and results post-processing for better productivity and ease of use.
Synopsys PrimeSim Reliability Analysis includes:
PrimeSim Family of Simulators
The Synopsys PrimeWave Design Environment delivers a complete solution to ensure memory reliability from early life to end of life.
Silicon Lifecycle Management (SLM) Family of Products Complements the Synopsys PrimeWave Design Environment
Synopsys Silicon Lifecycle Management promotes silicon reliability and performance throughout your device¡¯s lifecycle as a complement to Synopsys PrimeSim Reliability Analysis and PrimeWave Design Environment:
Lifecycle Stage | ||||
In-Design | In-Ramp | In-Production | In-Field | |
Synopsys SLM Solution |
Silicon data from embedded monitors help you understand the dynamic environmental conditions in tandem with PrimeSim Reliability Analysis | Pinpoint systemic failures in silicon with the objective of attaining yield targets prior to production | Ongoing monitoring and analysis of test manufacturing data to optimize yield, quality, and reliability | Ongoing real-time monitoring and analysis of health/aging performance and power optimization
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From hyperconvergent data centers to the devices in your hand, memory reliability is critical to the functioning of our modern lives. If you would like to learn more about how to get full-spectrum insights on the health of your systems¡ªcertified by foundries, compliant with standards, and built for ease of use with a unified flow¡ªLearn more at Synopsys.com/memory or contact us.