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Addressing Multi-Physics Effects for High-Performing Multi-Die Systems

Kenneth Larsen, Shekhar Kapoor

Aug 22, 2023 / 4 min read

What are typically second- or third-order effects in 2D chip designs are elevated into primary effects in multi-die systems. It¡¯s no wonder, given the many interdependencies in these complex architectures. For example, heat dissipation from one die could impact the performance of the component next to it, or the system as a whole. What¡¯s more, thermal and power delivery problems are exacerbated at 3D because dissipating heat becomes much more difficult. Similarly, signal integrity issues such as crosstalk and electromagnetic interference stemming from one chiplet can hamper the entire system. These are just a couple of examples that scratch the surface of the multi-physics effects that can impede multi-die systems.

The shift from monolithic SoCs to multi-die systems introduces many new considerations. In this new realm, design teams can¡¯t afford to view the package or single dies separately from the whole system. For an optimal system and a convergent, accelerated flow, it¡¯s essential to look at the whole system, from technology to dies and package together, and also to co-optimize it together, with guidance from tightly integrated multi-objective analyses. We refer to this hand-in-glove approach as System Technology Co-Optimization (STCO).

STCO ideally starts at the beginning when teams are conceiving their systems. From feasibility studies and architecture planning to implementation and signoff, a comprehensive die/package co-design approach that accounts for multi-physics effects is critical for design success. Read on to learn more about the importance of co-design and co-optimization. You can also gain additional insights by watching our on-demand, six-part webinar series, ¡°Requirements for Multi-Die System Success.¡± The series covers multi-die system trends and challenges, early architecture design, co-design and system analysis, die-to-die connectivity, verification, and system health.

multi-physics multi-die systems

Integration of Multiple Dies Creates Interdependencies

Workload-intensive applications such as high-performance computing (HPC) and AI drive demand for multi-die systems to deliver the performance, power, and area (PPA) these applications require. A single package integrating multiple individual dies containing different types of circuits, a multi-die system presents an efficient way to accelerate the scaling of system functionality. With key performance indicators (KPIs) in place, designers can plan their systems and components accordingly.

Multi-physics effects in monolithic SoCs are concerning but can typically be modeled and analyzed upfront and addressed with design adjustments. With multi-die systems, these effects, if unaddressed, become much more detrimental to the entire system.

For example:

  • With so many dies talking to each other via die-to-die interfaces, the system becomes more susceptible to signal integrity issues such as electromagnetic interference (EMI) and crosstalk
  • Thermal issues rise to the forefront, since all of the dies in the system, along with the interconnections between them, could trap heat and, thus, impact the system¡¯s performance and/or timing
  • The robustness of the system¡¯s power distribution network in alleviating effects like EMI while providing the power needed for the entire die system is critical
  • Mechanical stress stemming from the fabrication, assembly, and packaging of chips can affect the electrical performance of the system
  • Process variation occurring in the system¡¯s individual dies can impact system performance

To address these effects, analyses of the system must be performed in the context of the multi-die system, examining all the physical aspects and interactions to validate and optimize the system. Multiple properties, from electrical and thermal effects to structural mechanics, must be simulated together to identify power and signal integrity impacts at the system level. What¡¯s needed to accomplish this is a unified STCO solution that can deliver full-spectrum design closure and convergence for optimal PPA per cubic mm. 


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Understanding Design Tradeoffs Early On

STCO starts at the beginning when design teams are planning the architecture. As they determine their system¡¯s components and how it should all be partitioned, they need to be able to perform ¡°what if?¡± analysis to understand their tradeoffs. The more granularity they have as they move toward implementation, the better as they converge toward signoff. At this early design stage, limited information is available; however, system prototyping helps answer several questions: How many dies are needed? How should the die be stacked? What are the tradeoffs of mixing older and newer nodes in the system? How should the power distribution network be designed? What kinds of thermal issues might arise? As the team converges on an architecture to meet their requirements, they can take outputs from feasibility studies and move into system planning and building prototypes.

The Synopsys Multi-Die System Solution provides a comprehensive platform for fast 2.5D and 3D heterogeneous integration to support an STCO approach that helps answer the ¡°what if?¡± questions. Two key components of the solution that address multi-physics effects are:

  • Synopsys 3DIC Compiler multi-die/package co-design and co-optimization platform, which provides modeling capabilities and the associated data points that can guide the development of a system floorplan that delivers the targeted PPA. Built on the standard, single-data-model Fusion infrastructure of the Synopsys Digital Design Family, 3DIC Compiler provides a complete architecture-to-signoff platform.
  • Design analysis and signoff technologies, which address static timing, signal integrity, power integrity, thermal, parasitics, and electromigration/IR-drop. 3DIC Compiler and Synopsys signoff solutions are integrated with , which provides multi-physics power integrity, signal integrity, thermal integrity, and mechanical stress simulation and analysis for 2.5D/3D multi-die systems.

Since the Multi-Die System Solution¡¯s components are tightly integrated, design teams can find and resolve problems earlier on to achieve better yields. Disparate tools can be used for this analysis, but if they¡¯re not well connected, they could miss important ¡°red flags¡± along the way, potentially forcing design teams to address problems closer to tape-out when it is much more costly to do so. Synopsys continually assesses emerging multi-die system effects, and enhances its solution accordingly.

Summary

In multi-die systems, multi-physics effects must be addressed from a system standpoint, with the design and optimization processes factoring in all the interdependencies. A system technology co-optimization approach backed by integrated and scalable co-design, analysis, and signoff solutions can help design teams efficiently achieve the PPA promise of their multi-die systems. 

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