Scalable Chiplet package using Fan-Out Embedded Bridge

As silicon scaling closer to physical limit, future reduction of the gate oxide does not lower down the cost per transistor. But the demand of higher functionality and lower cost of electronic devices do not slow down. Development of electronic devices metaphor to high-density package integration. W...

Full description

Saved in:
Bibliographic Details
Main Authors: Lin, Joe, Chung, C. Key, Lin, C. F., Liao, Ally, Lu, Ying Ju, Shuang Chen, Jia, Ng, Daniel
Format: Conference Proceeding
Language:English
Subjects:
2.5D
Bridges
Compounds
Embedded bridge
FCBGA
FOEB
FOMCM
Glass
Line space
RDL
Reliability
Scalable chiplets
Silicon
Stress
Substrates
Online Access:Request full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:As silicon scaling closer to physical limit, future reduction of the gate oxide does not lower down the cost per transistor. But the demand of higher functionality and lower cost of electronic devices do not slow down. Development of electronic devices metaphor to high-density package integration. What the electronic industries do is to break down a large die to a chiplet-based devices for improving yield and lower the total cost. Chiplet package become a key technology to continue Moore's law. With the intensive researches, multiple chiplet packages are evolved such as multi chips on Si interposer using TSV (2.5D), die to die stack on each other (3D), Fan-Out Multi Chip Module (FOMCM), and EMIB (Embedded Multi-Die Interconnect Bridge). These packages are developed for the server, high performance computing, router, and switcher markets.But, the integration of high bandwidth memory devices and multiple ASIC dies together requires very high I/O counts and signal transmitting. Thus, a much higher RDL (Redistribution Layer) layer counts, finer bump pitch and smaller line- space (L/S) are designed. Each of these chiplets has its limitations. Large 2.5D package has its cost concerns on large Si interposer and mismatch of the Si interposer with substrate on reliability test. Whereas, large FO-MCM technology is limited by finer L/S and higher layers count of RDL. Presently, the package is heading the bottleneck at 1/1 μm L/S, 5 layers RDL and 2 reticle size chip module. As for EMIB technology, it is constrained by L/S that could only down to 5/5 μm.In this paper, we have successfully developed a scalable chiplet package technology, namely Fan-Out Embedded Bridge (FOEB). This chiplet package enables near monolithic short reach BEOL connections between dies. FOEB can have multiple RDL layers and Si bridge that has much finer L/S for interconnection. In addition to, multiple dies can be bridged together into one single chip module. In this paper, the demonstration of FOEB test vehicle, which integrate chips by 1 ASIC die and 4 memory dies (1+4) with 4 embedded bridge dies on mold-based interposer, 3 layers of RDL are presented. By comparing packages using FOMCM and 2.5D to fabricate. FOEB package has much lower warpage and 2 x lower stress value as compare to 2.5D. But similar to FOMCM. Owing to this reason, the FOEB chiplet package were tested 2x longer temperature cycle with condition-G without single failure as compared to 2.5D. The assembly yield of FOEB is comp
ISSN:2377-5726
DOI:10.1109/ECTC32862.2020.00015