Enhanced Precision Through Multiple Reads for LDPC Decoding in Flash Memories

Wang, Jiadong; Vakilinia, Kasra; Chen, Tsung‐Yi; Courtade, Thomas A.; Dong, Guiqiang; Zhang, Tong; Shankar, Hari; Wesel, Richard D.

doi:10.1109/jsac.2014.140508

Cited by 104 publications

(93 citation statements)

References 26 publications

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“…Similarly, error correction using LDPC soft decoding (see Section 6.2) requires reading the same page using multiple sets of read reference voltages to provide fine-grained information on the probability of each cell representing a bit value 0 or a bit value 1. Another prior work optimizes the read reference voltages to increase the ECC correction capability without increasing the coding rate [184].…”

Section: Ecc Correction Capabilitymentioning

confidence: 99%

Error Characterization, Mitigation, and Recovery in Flash-Memory-Based Solid-State Drives

et al. 2017

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NAND flash memory is ubiquitous in everyday life today because its capacity has continuously increased and cost has continuously decreased over decades. This positive growth is a result of two key trends: (1) effective process technology scaling; and (2) multi-level (e.g., MLC, TLC) cell data coding. Unfortunately, the reliability of raw data stored in flash memory has also continued to become more difficult to ensure, because these two trends lead to (1) fewer electrons in the flash memory cell floating gate to represent the data; and (2) larger cell-to-cell interference and disturbance effects. Without mitigation, worsening reliability can reduce the lifetime of NAND flash memory. As a result, flash memory controllers in solid-state drives (SSDs) have become much more sophisticated: they incorporate many effective techniques to ensure the correct interpretation of noisy data stored in flash memory cells. In this article, we review recent advances in SSD error characterization, mitigation, and data recovery techniques for reliability and lifetime improvement. We provide rigorous experimental data from state-ofthe-art MLC and TLC NAND flash devices on various types of flash memory errors, to motivate the need for such techniques. Based on the understanding developed by the experimental characterization, we describe several mitigation and recovery techniques, including (1) cell-to-cell interference mitigation; (2) optimal multi-level cell sensing; (3) error correction using state-of-the-art algorithms and methods; and (4) data recovery when error correction fails. We quantify the reliability improvement provided by each of these techniques. Looking forward, we briefly discuss how flash memory and these techniques could evolve into the future.

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Section: Ecc Correction Capabilitymentioning

confidence: 99%

Error Characterization, Mitigation, and Recovery in Flash-Memory-Based Solid-State Drives

et al. 2017

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“…We also reuse Code 6 in this subsection (its parameters are stated in the previous subsection). Code 13 is the result of optimizing Code 6 for the asymmetric CHMM channel (with 6 reads) by attempting to remove the dominant GASTs (4, 4, 4, 6, 0), (6,4,4,11,0), and (7, 4, 3, 11, 1) in addition to the dominant OSTs (6, 5, 2, 11, 0), (7, 5, 3, 11, 1), (7,5,4,9,2), (7,6,6,8,2), (8,6,2,15,0), and (10,7,5,11,4) using the WCM framework.…”

Section: Effect Of Soft Information In Flash Channelsmentioning

confidence: 99%

A Combinatorial Methodology for Optimizing Non-Binary Graph-Based Codes: Theoretical Analysis and Applications in Data Storage

Hareedy

Lanka

Guo

et al. 2019

IEEE Trans. Inform. Theory

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“…However, as Flash capacity continued to rise and MLCs gave way to TLCs, more efficient ECCs were needed, resulting in a transition to soft decoding schemes. Low-density parity-check (LDPC) ECCs [42][43][44][45] are gaining traction in modern SSDs, while concatenated codes for NAND Flash have been also proposed [46][47][48][49].…”

Section: Nand Flash Memory Reliabilitymentioning

confidence: 99%

Reliability of NAND Flash Memories: Planar Cells and Emerging Issues in 3D Devices

2017

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Abstract:We review the state-of-the-art in the understanding of planar NAND Flash memory reliability and discuss how the recent move to three-dimensional (3D) devices has affected this field. Particular emphasis is placed on mechanisms developing along the lifetime of the memory array, as opposed to time-zero or technological issues, and the viewpoint is focused on the understanding of the root causes. The impressive amount of published work demonstrates that Flash reliability is a complex yet well-understood field, where nonetheless tighter and tighter constraints are set by device scaling. Three-dimensional NAND have offset the traditional scaling scenario, leading to an improvement in performance and reliability while raising new issues to be dealt with, determined by the newer and more complex cell and array architectures as well as operation modes. A thorough understanding of the complex phenomena involved in the operation and reliability of NAND cells remains vital for the development of future technology nodes.

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Enhanced Precision Through Multiple Reads for LDPC Decoding in Flash Memories

Cited by 104 publications

References 26 publications

Error Characterization, Mitigation, and Recovery in Flash-Memory-Based Solid-State Drives

Error Characterization, Mitigation, and Recovery in Flash-Memory-Based Solid-State Drives

A Combinatorial Methodology for Optimizing Non-Binary Graph-Based Codes: Theoretical Analysis and Applications in Data Storage

Reliability of NAND Flash Memories: Planar Cells and Emerging Issues in 3D Devices

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