IEEE (Institute of Electrical and Electronics Engineers,電機電子工程師學會) 的EPS (Electronics Packaging Society,電子封裝學會於2月舉行了「2025異質整合藍圖第8屆年會」[1]。在為期3天的年會中,來自產、學、研不同領域的專家針對先進封裝如何提升性能表現及降低能耗方面的議題發表了精闢的研究成果;很明顯的,AI成為了先進封裝的發展核心。在摩爾定律已走到盡頭的時候,為了達到AI訓練及運作的高性能需求,封裝技術的再精進似乎成了唯一選項。由賓州州立大學(Penn State University)電機工程系系主任Madhavan Swaminathan教授主導的CHIMES研究中心,正在積極探索異質整合在AI硬體上的應用與挑戰。CHIMES(Center for Heterogeneous Integration of Micro Electronic Systems)由美國賓州州立大學主導,整合了來自喬治亞理工、UCLA、MIT等多所名校與產業夥伴,是JUMP 2.0計畫[2]的旗艦研究中心。
圖1. 龐大的AI模型背後代表龐大能耗支出。 圖片來源:“Is Heterogeneous Integration (HI) ready for Artificial Intelligence (AI) ?”, Madhavan Swaminathan, Dept. Head of Electrical Engineering, William E. Leonhard Endowed Chair, and Director, CHIMES (an SRC JUMP 2.0 Center) of Pennsylvania State University; Emeritus Professor, ECE & MSE, Georgia Tech and Former Director, 3D Systems Packaging Research Center (PRC), Georgia Tech.(Madhavan Swaminathan教授簡報資料)
圖4.CHIMES目標的高效率電源架構; 圖片來源:“Is Heterogeneous Integration (HI) ready for Artificial Intelligence (AI) ?”, Madhavan Swaminathan, Dept. Head of Electrical Engineering, William E. Leonhard Endowed Chair, and Director, CHIMES (an SRC JUMP 2.0 Center) of Pennsylvania State University; Emeritus Professor, ECE & MSE, Georgia Tech and Former Director, 3D Systems Packaging Research Center (PRC), Georgia Tech.(Madhavan Swaminathan教授簡報資料)
(2) 挑戰2:散熱 — 不能讓AI燒掉自己
AI晶片密度高,散熱壓力巨大。CHIMES發展出以下解方:
AlN高導熱散熱塗層:晶粒間隙填充可導熱材料,提升熱擴散效率。
蒸發式冷卻與微流體通道:直接導入晶粒背面,解決超過30kW/cm²的熱通量。
內嵌冷卻晶片:將冷卻結構嵌入晶片與基板之間,提升本體熱控能力。
圖5.CHIMES為高密度AI晶片發展出解方; 圖片來源:“Is Heterogeneous Integration (HI) ready for Artificial Intelligence (AI) ?”, Madhavan Swaminathan, Dept. Head of Electrical Engineering, William E. Leonhard Endowed Chair, and Director, CHIMES (an SRC JUMP 2.0 Center) of Pennsylvania State University; Emeritus Professor, ECE & MSE, Georgia Tech and Former Director, 3D Systems Packaging Research Center (PRC), Georgia Tech.(Madhavan Swaminathan教授簡報資料)
(3) 挑戰3:如何快速設計如此複雜的系統?
面對橫跨50,000mm²的系統封裝,傳統EDA設計工具顯得力不從心。CHIMES提出:
跨層級自動化設計平台:整合電路、熱控、封裝與可靠性考量。
全新驗證與簽核流程:支援M3D(Monolithic 3D)架構的設計與整合。
圖6.CHIMES為大型系統封裝提出解方 (目標);圖片來源:“Is Heterogeneous Integration (HI) ready for Artificial Intelligence (AI) ?”, Madhavan Swaminathan, Dept. Head of Electrical Engineering, William E. Leonhard Endowed Chair, and Director, CHIMES (an SRC JUMP 2.0 Center) of Pennsylvania State University; Emeritus Professor, ECE & MSE, Georgia Tech and Former Director, 3D Systems Packaging Research Center (PRC), Georgia Tech.(Madhavan Swaminathan教授簡報資料)
圖7. 用於基板資料傳輸的 3D 整合波導;圖片來源:“Is Heterogeneous Integration (HI) ready for Artificial Intelligence (AI) ?”, Madhavan Swaminathan, Dept. Head of Electrical Engineering, William E. Leonhard Endowed Chair, and Director, CHIMES (an SRC JUMP 2.0 Center) of Pennsylvania State University; Emeritus Professor, ECE & MSE, Georgia Tech and Former Director, 3D Systems Packaging Research Center (PRC), Georgia Tech.(Madhavan Swaminathan教授簡報資料)
HI不只是技術,更是AI時代的基礎建設
Swaminathan教授表示,CHIMES計畫不僅代表前瞻技術,更揭示一個趨勢:AI的創新,不能只靠演算法與模型,硬體創新必須跟上,甚至領先。從多晶粒封裝、熱管理、電源轉換到光子傳輸,異質整合技術正在構築AI時代的基礎建設。當Moore’s Law 已不再是黃金定律,HI正帶領我們走向摩爾的下一站。
圖8. AI的創新,不能只靠演算法與模型,硬體創新必須跟上,甚至領先;圖片來源:“Is Heterogeneous Integration (HI) ready for Artificial Intelligence (AI) ?”, Madhavan Swaminathan, Dept. Head of Electrical Engineering, William E. Leonhard Endowed Chair, and Director, CHIMES (an SRC JUMP 2.0 Center) of Pennsylvania State University; Emeritus Professor, ECE & MSE, Georgia Tech and Former Director, 3D Systems Packaging Research Center (PRC), Georgia Tech.(Madhavan Swaminathan教授簡報資料)
[2] Joint University Microelectronics Program 2.0 (JUMP 2.0)
參考資料:
1.“Is Heterogeneous Integration (HI) ready for Artificial Intelligence (AI) ?”, Madhavan Swaminathan, Dept. Head of Electrical Engineering, William E. Leonhard Endowed Chair, and Director, CHIMES (an SRC JUMP 2.0 Center) of Pennsylvania State University; Emeritus Professor, ECE & MSE, Georgia Tech and Former Director, 3D Systems Packaging Research Center (PRC), Georgia Tech.
