Convolutional Neural Network Based Symbol Detector for Two-Dimensional Magnetic Recording

Jinlu Shen, B. Belzer, K. Sivakumar, K. Chan, Ashish James
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引用次数: 1

Abstract

Conventional detection systems in hard disk drives (HDD) typically include a 2D partial response (PR) equalizer that pre-processes the readback signals and shapes the output to a controlled target response, followed by a maximum likelihood (ML) or maximum a posteriori (MAP) detector which outputs log-likelihood ratios (LLRs) to be passed to a channel decoder. Pattern dependent noise prediction (PDNP) algorithm [1] is usually incorporated into the metric computation of the trellis in the ML/MAP detector to combat media noise intrinsic to the magnetic recording (MR) channel. For next generation two-dimensional magnetic recording (TDMR) HDDs, such conventional systems would suffer from impractically large trellis state cardinality when performing multi-track detection, and they may no longer be capable of handling the increased nonlinearities in high density recording channels. This work investigates applying advanced machine learning techniques to TDMR. Convolutional neural networks (ConvNets) are employed in place of the PR equalizer and ML/MAP detector with PDNP to directly process the un-equalized readback signals and output soft estimates. ConvNets are special deep neural networks (DNNs) that assume the inputs are images and perform convolution instead of affine function in the network forward pass [2]. This enables far fewer parameters in ConvNets than regular DNNs of the same depth and therefore allows for deeper networks. The motivation to use ConvNets is the resemblance between data detection problem in MR and typical image processing problems. In MR channels, the write process converts temporal data into spatial patterns recorded on a magnetic medium, which transforms sequential correlation into spatial ISI/ITI. Data detection can be viewed as an image processing problem, proceeding from the 2D image of the shingled bits (see Fig. 1), to higher level abstractions of features by means of convolutional layers that finally allow classification of individual bits. Several variations of ConvNets are compared in terms of network complexity and performance. The best performing ConvNet detector can provide data storage density of up to 3.7489 Terabits/in 2 on low track pitch TDMR channel simulated with a grain flipping probabilistic (GFP) model.
基于卷积神经网络的二维磁记录符号检测器
硬盘驱动器(HDD)中的传统检测系统通常包括一个2D部分响应(PR)均衡器,该均衡器对读回信号进行预处理,并将输出形成受控目标响应,然后是一个最大似然(ML)或最大后验(MAP)检测器,其输出对数似然比(llr),将其传递给信道解码器。模式相关噪声预测(PDNP)算法[1]通常被纳入ML/MAP检测器中栅格的度量计算中,以对抗磁记录(MR)通道固有的媒体噪声。对于下一代二维磁记录(TDMR) hdd,这样的传统系统在执行多磁道检测时可能会受到不切实际的大栅格状态基数的影响,并且它们可能不再能够处理高密度记录通道中增加的非线性。这项工作研究了将先进的机器学习技术应用于TDMR。采用卷积神经网络(ConvNets)代替PR均衡器和带PDNP的ML/MAP检测器,直接处理不均衡的读回信号并输出软估计。ConvNets是一种特殊的深度神经网络(dnn),它假设输入是图像,并在网络前向传递中执行卷积而不是仿射函数[2]。这使得卷积神经网络中的参数比相同深度的常规dnn少得多,因此允许更深的网络。使用卷积神经网络的动机是MR中的数据检测问题与典型图像处理问题之间的相似性。在磁流变通道中,写入过程将时间数据转换为记录在磁介质上的空间模式,从而将顺序相关性转换为空间ISI/ITI。数据检测可以看作是一个图像处理问题,从二维图像的拼接位(见图1)开始,通过卷积层对特征进行更高层次的抽象,最终允许对单个位进行分类。比较了几种不同的卷积神经网络在网络复杂度和性能方面的差异。在用颗粒翻转概率(GFP)模型模拟的低径距TDMR信道上,性能最好的ConvNet检测器可以提供高达3.7489 tb /in 2的数据存储密度。
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