Increasing flash memory lifetime by dynamic voltage allocation for constant mutual information

Chen, Tsung‐Yi; Williamson, Adam R.; Wesel, Richard D.

doi:10.1109/ita.2014.6804242

Cited by 15 publications

(27 citation statements)

References 29 publications

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“…This paper systematically explains and demonstrates the concept of dynamic voltage allocation, and addresses several issues to support a practical implementation. This paper extends our previous work [22], [23] in the following ways: 1) Adding programming error and cell-to-cell interference to the ground truth channel model; 2) Analyzing DVA's performance when both estimation and scale-factor adjustment algorithms are simplified by using a simple Gaussian model to approximate the underlying (and more complex) ground truth channel; 3) Designing and analyzing DVA specialized to match an even-odd structure for writing to cells; 4) Exploring the improvement obtained by DVA over DTA; 5) Analyzing DVA's performance when both write and read voltage values are restricted to a finite set of available voltages; 6) Analyzing DVA's complexity. This paper begins by introducing DVA in an idealized setting and then removes ideal assumptions about channel knowledge and threshold resolution to conclude with a practical scheme that has performance similar to that of the idealized setting.…”

Section: Introductionsupporting

confidence: 89%

“…As the read channel becomes more degraded, the threshold voltages are gradually increased to what would be the nominal values in a standard device not employing DVA. As shown in our precursor conference papers [22], [23], DVA maintains the required mutual information while significantly extending lifetime. Fig.…”

Section: Introductionmentioning

confidence: 85%

“…Based on [26]- [37], our precursor conference papers [22] and [23] propose a parameterized channel model characterizing the noise as having three additive components: programming noise, wear-out noise, and retention noise. This paper improves the model of [22] and [23] by adding the effects of cell-to-cell interference and programming error.…”

Section: Modeling Channel Parameters and Degradationmentioning

confidence: 99%

“…This paper begins by introducing DVA in an idealized setting and then removes ideal assumptions about channel knowledge and threshold resolution to conclude with a practical scheme that has performance similar to that of the idealized setting. DVA is first explored under the assumption of perfect knowledge of the channel state as in our precursor conference paper [22], except with a more complex read channel that includes cell-to-cell interference and programming errors.…”

Section: Introductionmentioning

confidence: 99%

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Using Dynamic Allocation of Write Voltage to Extend Flash Memory Lifetime

Wang

Wong

Chen³

et al. 2016

IEEE Trans. Commun.

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Abstract-The read channel of a Flash memory cell degrades after repetitive program and erase (P/E) operations. This degradation is often modeled as a function of the number of P/E cycles. In contrast, this paper models the degradation as a function of the cumulative effect of the charge written and erased from the cell. Based on this modeling approach, this paper dynamically allocates voltage using lower-voltage write thresholds at the beginning of the device lifetime and increasing the thresholds as needed to maintain the mutual information of the read channel in the face of degradation. The paper introduces the technique in an idealized setting and then removes ideal assumptions about channel knowledge and available voltage resolution to conclude with a practical scheme with performance close to that of the idealized setting.

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Section: Introductionsupporting

confidence: 89%

Section: Introductionmentioning

confidence: 85%

Section: Modeling Channel Parameters and Degradationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Using Dynamic Allocation of Write Voltage to Extend Flash Memory Lifetime

Wang

Wong

Chen³

et al. 2016

IEEE Trans. Commun.

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“…They are caused by the leakage of the charges from the floating gate over time, which leads to a decrease of the threshold voltage. Following [20,28,29], the retention noise is assumed to follow the Gaussian distribution, given by…”

Section: Data Retention Noisementioning

confidence: 99%

Deep Learning-Aided Dynamic Read Thresholds Design for Multi-Level-Cell Flash Memories

Mei

Cai

2020

IEEE Trans. Commun.

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The practical NAND flash memory suffers from various non-stationary noises that are difficult to be predicted. Furthermore, the data retention noise induced channel offset is unknown during the readback process. This severely affects the data recovery from the memory cell. In this paper, we first propose a novel recurrent neural network (RNN)-based detector to effectively detect the data symbols stored in the multi-levelcell (MLC) flash memory without any prior knowledge of the channel. However, compared with the conventional threshold detector, the proposed RNN detector introduces much longer read latency and more power consumption. To tackle this problem, we further propose an RNN-aided (RNNA) dynamic threshold detector, whose detection thresholds can be derived based on the outputs of the RNN detector. We thus only need to activate the RNN detector periodically when the system is idle. Moreover, to enable soft-decision decoding of error-correction codes, we first show how to obtain more read thresholds based on the hard-decision read thresholds derived from the RNN detector. We then propose integer-based reliability mappings based on the designed read thresholds, which can generate the soft information of the channel. Finally, we propose to apply density evolution (DE) combined with differential evolution algorithm to optimize the read thresholds for LDPC coded flash memory channels. Computer simulation results demonstrate the effectiveness of our RNNA dynamic read thresholds design, for both the uncoded and LDPC-coded flash memory channels, without any prior knowledge of the channel.

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Variable-Node-Based Belief-Propagation Decoding With Message Pre-Processing for NAND Flash Memory

2019

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With the fast development of non-volatile storage technology, NAND flash memory faces more and more challenges such as data reliability and lifetime. To overcome the issue of the reliability, low-density parity-check (LDPC) codes are considered as a main candidate of error-correction-codes (ECCs) for NAND flash storages. However, conventional soft decoding algorithms for LDPC codes suffer from the drawback of slow convergence speed, which increases the decoding latency. For achieving fast convergence speed, a variable-node-based belief-propagation with message pre-processing (VNBP-MP) decoding algorithm for binary LDPC codes and a non-binary VNBP-MP (NVNBP-MP) decoding algorithm for non-binary LDPC codes are proposed. Both of the algorithms utilize the characteristics of the NAND flash channel to perform the message pre-processing operations. In theory, the propagation of unreliable messages can be effectively prevented and the propagation of reliable messages can be speeded up. To further improve the decoding convergence, the treatment for oscillating variable nodes is considered after the message pre-processing operations. The simulation results also show that the proposed algorithms both have a noticeable improvement in convergence speed and latency, without compromising error-correction performance, compared with the existing soft decoding algorithms. INDEX TERMS NAND flash memory, low-density parity-check (LDPC) code, message pre-processing, belief-propagation decoding, error-correction performance.

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Increasing flash memory lifetime by dynamic voltage allocation for constant mutual information

Cited by 15 publications

References 29 publications

Using Dynamic Allocation of Write Voltage to Extend Flash Memory Lifetime

Using Dynamic Allocation of Write Voltage to Extend Flash Memory Lifetime

Deep Learning-Aided Dynamic Read Thresholds Design for Multi-Level-Cell Flash Memories

Variable-Node-Based Belief-Propagation Decoding With Message Pre-Processing for NAND Flash Memory

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