Multi-Die Assemblies Complicate Parasitic Extraction
What used to be an afterthought is now a first-order concern for performance and power at the leading edge.
By Ann Mutschler, Semiconductor Engineering | June 12, 2025
The shift from planar designs to multi-die assemblies with complex interconnects is transforming what had become almost an afterthought in the design process into a first-order challenge.
Parasitics include things like inductance, capacitance, and resistance, which have become more problematic at advanced nodes due to increasing logic density, thinner interconnects and insulators, and a spike in the amount of data that needs to be processed, moved, and stored. In order to circumvent the size limitations of a reticle, large chipmakers have shifted away from planar SoCs to multi-die assemblies in custom-designed packages. But in doing so, they have added many more interconnects and complex interactions, making it much harder to identify and mitigate parasitic effects.
To read the full article, click here
Related Chiplet
- DPIQ Tx PICs
- IMDD Tx PICs
- Near-Packaged Optics (NPO) Chiplet Solution
- High Performance Droplet
- Interconnect Chiplet
Related News
- Benefits And Challenges In Multi-Die Assemblies
- Distributing Intelligence Inside Multi-Die Assemblies
- Multi-Die Design Complicates Data Management
- Eliyan Supports Latest Version of UCIe Chiplet Interconnect Standard, Continues to Drive Performance and Bandwidth Capabilities to 40Gbps and Beyond to Help Meet the Needs of the Multi-die Era
Latest News
- Photonics: A Foundational Scaling Layer for AI-Era Computing
- Ayar Labs Joins NVIDIA NVLink™ Fusion Ecosystem to Bring Co-Packaged Optics to Rack-Scale AI Infrastructure
- Lightmatter Joins NVIDIA NVLink Fusion and Powers Next-Generation AI Infrastructure with Photonic Interconnects
- Sivers & GlobalFoundries Advance AI Data Center Optical Solutions
- Wiwynn and Ecosystem Partners to Showcase Co-Packaged Optics Innovations at Computex 2026