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Main Authors: Samanta, Anirban, Lee, Shun-Hung, Cheng, Chun-Yi, Palermo, Samuel, Yoo, S. J. Ben
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.03943
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author Samanta, Anirban
Lee, Shun-Hung
Cheng, Chun-Yi
Palermo, Samuel
Yoo, S. J. Ben
author_facet Samanta, Anirban
Lee, Shun-Hung
Cheng, Chun-Yi
Palermo, Samuel
Yoo, S. J. Ben
contents 3D interconnects have emerged as a solution to address the scaling issues of interconnect bandwidth and the memory wall problem in high-performance computing (HPC), such as High-Bandwidth Memory (HBM). However, the copper-based electrical interconnect retains fundamental limitations. Dense I/O for high-speed signals lead to degraded signal quality for end-to-end links, necessitating additional circuits to mitigate signal impairments and resulting in poor energy efficiency. We propose a 3D chiplet stacking electronic-photonic interconnect (EPIC) platform, which offers a solution by moving the high-speed data communication interface to the optical domain across the 3D stack by using Through Silicon Optical Vias (TSOV), while retaining the functionality of electrical TSVs and 2.5D interconnects for power delivery and short-reach low-latency communications. We then benchmark the proposed model against state-of-the-art 3D electrical interconnects to demonstrate our 3D EPIC platform beating the 3D electrical interconnects to $>$10 TB/s/$mm^2$ bandwidth density. We present a pathway to extend our demonstrated, industry-ready design to achieving $\leq$100 fJ/bit high-speed communication.
format Preprint
id arxiv_https___arxiv_org_abs_2510_03943
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle 3D Electronic-Photonic Heterogenous Interconnect Platforms Enabling Energy-Efficient Scalable Architectures For Future HPC Systems
Samanta, Anirban
Lee, Shun-Hung
Cheng, Chun-Yi
Palermo, Samuel
Yoo, S. J. Ben
Systems and Control
3D interconnects have emerged as a solution to address the scaling issues of interconnect bandwidth and the memory wall problem in high-performance computing (HPC), such as High-Bandwidth Memory (HBM). However, the copper-based electrical interconnect retains fundamental limitations. Dense I/O for high-speed signals lead to degraded signal quality for end-to-end links, necessitating additional circuits to mitigate signal impairments and resulting in poor energy efficiency. We propose a 3D chiplet stacking electronic-photonic interconnect (EPIC) platform, which offers a solution by moving the high-speed data communication interface to the optical domain across the 3D stack by using Through Silicon Optical Vias (TSOV), while retaining the functionality of electrical TSVs and 2.5D interconnects for power delivery and short-reach low-latency communications. We then benchmark the proposed model against state-of-the-art 3D electrical interconnects to demonstrate our 3D EPIC platform beating the 3D electrical interconnects to $>$10 TB/s/$mm^2$ bandwidth density. We present a pathway to extend our demonstrated, industry-ready design to achieving $\leq$100 fJ/bit high-speed communication.
title 3D Electronic-Photonic Heterogenous Interconnect Platforms Enabling Energy-Efficient Scalable Architectures For Future HPC Systems
topic Systems and Control
url https://arxiv.org/abs/2510.03943