22.3 A 128Gb 8-High 512GB/s HBM2E DRAM with a Pseudo Quarter Bank Structure, Power Dispersion and an Instruction-Based At-Speed PMBIST

Dong-Uk Lee,Ho Sung Cho,Jihwan Kim,Young Jun Ku,Sangmuk Oh,Chul Kim,Hyun-Woo Kim,Woo-Young Lee,Tae-Kyun Kim,Tae Sik Yun,Min-Jeong Kim,SeungGyeon Lim,Seong Hee Lee,Byung Kuk Yun,Jun Il Moon,Ji Hwan Park,Seokwoo Choi,Young Jun Park,Chang Kwon Lee,Chun-Seok Jeong,Jae-Seung Lee,Sang Hun Lee,Woo Sung We,Jong Chan Yun,Doobock Lee,Junghyun Shin,Seung-chan Kim,Jung-Hwan Lee,Jiho Choi,Yucheon Ju,Myeong-Jae Park,Kang-Seol Lee,Youngdo Hur,Daeyong Shim,Sang-kwon Lee,Junhyun Chun,Kyo-Won Jin

22.3 A 128Gb 8-High 512GB/s HBM2E DRAM with a Pseudo Quarter Bank Structure, Power Dispersion and an Instruction-Based At-Speed PMBIST

2020

There is enormous demand for high-bandwidth DRAM: in application such as HPC, graphics, high-end server and artificial intelligence. HBM DRAM was developed [1] using the advances in package technology: TSV, microbump and silicon-interposer. Owing to these advances, HBM has a much higher bandwidth, at a lower pin speed rate, than conventional DRAM. However, the 3D-stack structure causes TSV interface and PDN problems: TSV connection failure and 3D-accumulation of IR drop, which increases the total cost of HBM. Moreover, as memory bandwidth increases DRAM architectural challenges arise, power consumption and associated thermal problems increase as well.

Keywords:

Dispersion (optics)
Electrical engineering
Electronic engineering
Graphics
Bandwidth (signal processing)
Computer science
Memory bandwidth
power consumption
Power network design
Dram
random access memory

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