On enduring more data through enabling page rewrite capability on multi-level-cell flash memory

Yu Ming Chang; Chien Chung Ho; Che Wei Tsao; Shu Hsien Liao; Wei Chen Wang; Tei Wei Kuo; Yuan Hao Chang

doi:10.1145/3477314.3507088

On enduring more data through enabling page rewrite capability on multi-level-cell flash memory

Yu Ming Chang, Chien Chung Ho, Che Wei Tsao, Shu Hsien Liao, Wei Chen Wang, Tei Wei Kuo, Yuan Hao Chang

研究成果: 書貢獻/報告類型 › 會議論文篇章

2 引文斯高帕斯（Scopus）

摘要

The technology of NAND flash memory grows swiftly in response to the huge and rapidly changing storage market in recent years. Meanwhile, the demand for large amounts of data is also growing at an unprecedented scale. How to store more and more data over flash-based systems in a cost-effective way presents immense pressure and challenges to the system design. This motivates us to propose a breakthrough solution on the existing multi-level-cell flash memories such as TLC, being adopted in the mainstream solid-state drives. More specifically, we propose a durable management design through enabling page rewrite capability and incorporate it with the existing flash translation layer to achieve enduring more data written, even beyond the theoretical limit. Moreover, our management design further considers the adverse effect brought by disturbance, which could usually deteriorate the data correctness. The encouraging results through a series of experiments demonstrate the feasibility and the capability of our design. With the best setting we studied, the total amount of data that can be written into the system could be improved up to 2.14 times the baseline without adding any hardware cost.

原文	英語
主出版物標題	Proceedings of the 37th ACM/SIGAPP Symposium on Applied Computing, SAC 2022
發行者	Association for Computing Machinery
頁面	107-115
頁數	9
ISBN（電子）	9781450387132
DOIs	https://doi.org/10.1145/3477314.3507088
出版狀態	已發佈 - 2022 4月 25
對外發佈	是
事件	37th ACM/SIGAPP Symposium on Applied Computing, SAC 2022 - Virtual, Online 持續時間: 2022 4月 25 → 2022 4月 29

出版系列

名字	Proceedings of the ACM Symposium on Applied Computing

會議

會議	37th ACM/SIGAPP Symposium on Applied Computing, SAC 2022
城市	Virtual, Online
期間	2022/04/25 → 2022/04/29

ASJC Scopus subject areas

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10.1145/3477314.3507088

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引用此

Chang, Y. M., Ho, C. C., Tsao, C. W., Liao, S. H., Wang, W. C., Kuo, T. W., & Chang, Y. H. (2022). On enduring more data through enabling page rewrite capability on multi-level-cell flash memory. 於 Proceedings of the 37th ACM/SIGAPP Symposium on Applied Computing, SAC 2022 (頁 107-115). (Proceedings of the ACM Symposium on Applied Computing). Association for Computing Machinery. https://doi.org/10.1145/3477314.3507088

On enduring more data through enabling page rewrite capability on multi-level-cell flash memory. / Chang, Yu Ming; Ho, Chien Chung; Tsao, Che Wei 等.
Proceedings of the 37th ACM/SIGAPP Symposium on Applied Computing, SAC 2022. Association for Computing Machinery, 2022. p. 107-115 (Proceedings of the ACM Symposium on Applied Computing).

研究成果: 書貢獻/報告類型 › 會議論文篇章

Chang, YM, Ho, CC, Tsao, CW, Liao, SH, Wang, WC, Kuo, TW & Chang, YH 2022, On enduring more data through enabling page rewrite capability on multi-level-cell flash memory. 於 Proceedings of the 37th ACM/SIGAPP Symposium on Applied Computing, SAC 2022. Proceedings of the ACM Symposium on Applied Computing, Association for Computing Machinery, 頁 107-115, 37th ACM/SIGAPP Symposium on Applied Computing, SAC 2022, Virtual, Online, 2022/04/25. https://doi.org/10.1145/3477314.3507088

Chang YM, Ho CC, Tsao CW, Liao SH, Wang WC, Kuo TW 等. On enduring more data through enabling page rewrite capability on multi-level-cell flash memory. 於 Proceedings of the 37th ACM/SIGAPP Symposium on Applied Computing, SAC 2022. Association for Computing Machinery. 2022. p. 107-115. (Proceedings of the ACM Symposium on Applied Computing). doi: 10.1145/3477314.3507088

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abstract = "The technology of NAND flash memory grows swiftly in response to the huge and rapidly changing storage market in recent years. Meanwhile, the demand for large amounts of data is also growing at an unprecedented scale. How to store more and more data over flash-based systems in a cost-effective way presents immense pressure and challenges to the system design. This motivates us to propose a breakthrough solution on the existing multi-level-cell flash memories such as TLC, being adopted in the mainstream solid-state drives. More specifically, we propose a durable management design through enabling page rewrite capability and incorporate it with the existing flash translation layer to achieve enduring more data written, even beyond the theoretical limit. Moreover, our management design further considers the adverse effect brought by disturbance, which could usually deteriorate the data correctness. The encouraging results through a series of experiments demonstrate the feasibility and the capability of our design. With the best setting we studied, the total amount of data that can be written into the system could be improved up to 2.14 times the baseline without adding any hardware cost.",

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AB - The technology of NAND flash memory grows swiftly in response to the huge and rapidly changing storage market in recent years. Meanwhile, the demand for large amounts of data is also growing at an unprecedented scale. How to store more and more data over flash-based systems in a cost-effective way presents immense pressure and challenges to the system design. This motivates us to propose a breakthrough solution on the existing multi-level-cell flash memories such as TLC, being adopted in the mainstream solid-state drives. More specifically, we propose a durable management design through enabling page rewrite capability and incorporate it with the existing flash translation layer to achieve enduring more data written, even beyond the theoretical limit. Moreover, our management design further considers the adverse effect brought by disturbance, which could usually deteriorate the data correctness. The encouraging results through a series of experiments demonstrate the feasibility and the capability of our design. With the best setting we studied, the total amount of data that can be written into the system could be improved up to 2.14 times the baseline without adding any hardware cost.

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On enduring more data through enabling page rewrite capability on multi-level-cell flash memory

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