Dr. Philip Wong: Currently at Stanford University, Wong’s research into nanoscale semiconductor devices has significantly contributed to the evolution of chiplet technology, considering the modular aspect of next-gen chip design.
Prof. Subhasish Mitra: Also at Stanford, Mitra has delved into robust systems design, where his understanding of chip architectures has implications for the development and integration of chiplets.
Dr. Gabriel Loh: As a Fellow at AMD, Loh’s expertise in high-performance architectures has provided significant insights into chiplet designs, especially in heterogeneous computing environments.
Prof. Michael Flynn: Working at the University of Michigan, Flynn focuses on digital and analog VLSI circuits. His insights into chip architectures extend to the burgeoning realm of chiplets.
Dr. Bryan Black: As a Senior Fellow at AMD, Black has been instrumental in pioneering modular designs that leverage chiplet architectures, notably the groundbreaking work on AMD’s Zen architectures.
Dr. John Poulton: At NVIDIA Research, Poulton’s work on high-speed links has implications for chiplet interconnects, ensuring efficient communication between chiplets.
Prof. Yuan Xie: A professor at Duke University, Xie’s extensive research in computer architecture includes explorations into chiplet-based architectures, evaluating their potential and challenges.
Dr. Ramune Nagisetty: At Intel, Nagisetty’s emphasis on advanced chip architectures brings her work to the forefront of chiplet-based design evolution, fostering innovation in modular chip designs.
Prof. Mark Hempstead: Operating out of Tufts University, Hempstead’s focus on energy-efficient architectures offers valuable perspectives on optimizing chiplet designs for better power consumption.
Dr. Burcin Kaplan: As part of the Google Pixel hardware team, Kaplan’s insights into SoC (System on Chip) designs extend to the modular approach offered by chiplets, enhancing performance and integration.
