A 16-GB 640-GB/s HBM2E DRAM With a Data-Bus Window Extension Technique and a Synergetic On-Die ECC Scheme
Ki Chul Chun, Yong Ki Kim, Yesin Ryu, Jaewon Park, Chi Sung Oh, Young Yong Byun, Soyoung Kim, Dong Hak Shin, Jun Gyu Lee, Byung-Kyu Ho, Min Sang Park, Seong-Jin Cho, Seung-Han Woo, Byoung Mo Moon, Beomyong Kil, Sungoh Ahn, Jae‐Hoon Lee, Soo Young Kim, Seouk-Kyu Choi, Jae-Seung Jeong, Sung-Gi Ahn, Jihye Kim, Jun Jin Kong, Kyomin Sohn, Nam Sung Kim, Jung-Bae Lee
Abstract
Circuit and design techniques are presented for enhancing the performance and reliability of a 3-D-stacked high bandwidth memory-2 extension (HBM2E). A data-bus window extension technique is implemented to cope with reduced clock cycle time ranging from data-path architecture, through-silicon via (TSV) placement, and TSV-PHY alignment. A power TSV placement in the middle of array and at the chip edge along with a dedicated top metal for power mesh improves power IR drop by 62%. An on-die ECC (OD-ECC) scheme featuring a self-scrubbing function is designed to be orthogonal to system ECC. An uncorrectable bit error rate (UBER) is improved by 10 <sup xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">5</sup> times with the proposed OD-ECC and scrubbing scheme. A memory built-in self-test (MBIST) block supports low-frequency cell and core test in a parallel manner and all channel at-speed operation with adjustable ac parameters. The proposed parallel-bit MBIST reduces test time by 66%. A 16-GB HBM2E fabricated in the second generation of 10-nm class DRAM process achieves a bandwidth up to 640 GB/s (5 Gb/s/pin) and provides a stable bit-cell operation at a high temperature (e.g., 105 ° C).