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1. Reliability Improvement in RRAM-based DNN for Edge Computing

   https://doi.org/10.1109/ISCAS48785.2022.9937260  

   Oli-Uz-Zaman, Md. ; Khan, Saleh Ahmad ; Yuan, Geng ; Wang, Yanzhi ; Liao, Zhiheng ; Fu, Jingyan ; Ding, Caiwen ; Wang, Jinhui ( January 2022 , 2022 IEEE International Symposium on Circuits and Systems (ISCAS))

   Recently, the Resistive Random Access Memory (RRAM) has been paid more attention for edge computing applications in both academia and industry, because it offers power efficiency and low latency to perform the complex analog in-situ matrix-vector multiplication – the most fundamental operation of Deep Neural Networks (DNNs). But the Stuck at Fault (SAF) defect makes the RRAM unreliable for the practical implementation. A differential mapping method (DMM) is proposed in this paper to improve reliability by mitigate SAF defects from RRAM-based DNNs. Firstly, the weight distribution for the VGG8 model with the CIFAR10 dataset is presented and analyzed. Then the DMM is used for recovering the inference accuracies at 0.1% to 50% SAFs. The experiment results show that the DMM can recover DNNs to their original inference accuracies (90%), when the ratio of SAFs is smaller than 7.5%. And even when the SAF is in the extreme condition 50%, it is still highly efficient to recover the inference accuracy to 80%. What is more, the DMM is a highly reliable regulator to avoid power and timing overhead generated by SAFs. 

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2. Noise Injection Adaption: End-to-End ReRAM Crossbar Non-ideal Effect Adaption for Neural Network Mapping

   https://doi.org/10.1145/3316781.3317870  

   He, Zhezhi ; Lin, Jie ; Ewetz, Rickard ; Yuan, Jiann-Shiun ; Fan, Deliang ( June 2019 , Proceedings of the 56th Annual Design Automation Conference 2019)

   In this work, we investigate various non-ideal effects (Stuck-At-Fault (SAF), IR-drop, thermal noise, shot noise, and random telegraph noise)of ReRAM crossbar when employing it as a dot-product engine for deep neural network (DNN) acceleration. In order to examine the impacts of those non-ideal effects, we first develop a comprehensive framework called PytorX based on main-stream DNN pytorch framework. PytorX could perform end-to-end training, mapping, and evaluation for crossbar-based neural network accelerator, considering all above discussed non-ideal effects of ReRAM crossbar together. Experiments based on PytorX show that directly mapping the trained large scale DNN into crossbar without considering these non-ideal effects could lead to a complete system malfunction (i.e., equal to random guess) when the neural network goes deeper and wider. In particular, to address SAF side effects, we propose a digital SAF error correction algorithm to compensate for crossbar output errors, which only needs one-time profiling to achieve almost no system accuracy degradation. Then, to overcome IR drop effects, we propose a Noise Injection Adaption (NIA) methodology by incorporating statistics of current shift caused by IR drop in each crossbar as stochastic noise to DNN training algorithm, which could efficiently regularize DNN model to make it intrinsically adaptive to non-ideal ReRAM crossbar. It is a one-time training method without the request of retraining for every specific crossbar. Optimizing system operating frequency could easily take care of rest non-ideal effects. Various experiments on different DNNs using image recognition application are conducted to show the efficacy of our proposed methodology. 

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3. ADMM-NN: An Algorithm-Hardware Co-Design Framework of DNNs Using Alternating Direction Methods of Multipliers

   https://doi.org/10.1145/3297858.3304076  

   Ren, Ao ; Zhang, Tianyun ; Ye, Shaokai ; Li, Jiayu ; Xu, Wenyao ; Qian, Xuehai ; Lin, Xue ; Wang, Yanzhi ( April 2019 , the Twenty-Fourth International Conference on Architectural Support for Programming Languages and Operating Systems)

   Model compression is an important technique to facilitate efficient embedded and hardware implementations of deep neural networks (DNNs), a number of prior works are dedicated to model compression techniques. The target is to simultaneously reduce the model storage size and accelerate the computation, with minor effect on accuracy. Two important categories of DNN model compression techniques are weight pruning and weight quantization. The former leverages the redundancy in the number of weights, whereas the latter leverages the redundancy in bit representation of weights. These two sources of redundancy can be combined, thereby leading to a higher degree of DNN model compression. However, a systematic framework of joint weight pruning and quantization of DNNs is lacking, thereby limiting the available model compression ratio. Moreover, the computation reduction, energy efficiency improvement, and hardware performance overhead need to be accounted besides simply model size reduction, and the hardware performance overhead resulted from weight pruning method needs to be taken into consideration. To address these limitations, we present ADMM-NN, the first algorithm-hardware co-optimization framework of DNNs using Alternating Direction Method of Multipliers (ADMM), a powerful technique to solve non-convex optimization problems with possibly combinatorial constraints. The first part of ADMM-NN is a systematic, joint framework of DNN weight pruning and quantization using ADMM. It can be understood as a smart regularization technique with regularization target dynamically updated in each ADMM iteration, thereby resulting in higher performance in model compression than the state-of-the-art. The second part is hardware-aware DNN optimizations to facilitate hardware-level implementations. We perform ADMM-based weight pruning and quantization considering (i) the computation reduction and energy efficiency improvement, and (ii) the hardware performance overhead due to irregular sparsity. The first requirement prioritizes the convolutional layer compression over fully-connected layers, while the latter requires a concept of the break-even pruning ratio, defined as the minimum pruning ratio of a specific layer that results in no hardware performance degradation. Without accuracy loss, ADMM-NN achieves 85× and 24× pruning on LeNet-5 and AlexNet models, respectively, --- significantly higher than the state-of-the-art. The improvements become more significant when focusing on computation reduction. Combining weight pruning and quantization, we achieve 1,910× and 231× reductions in overall model size on these two benchmarks, when focusing on data storage. Highly promising results are also observed on other representative DNNs such as VGGNet and ResNet-50. We release codes and models at https://github.com/yeshaokai/admm-nn. 

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4. Robust Deep Reservoir Computing through Reliable Memristor with Improved Heat Dissipation Capability

   https://doi.org/10.1109/TCAD.2020.3002539  

   An, Hongyu ; Al-Mamun, Mohammad Shah ; Orlowski, Marius K. ; Liu, Lingjia ; Yi, Yang ( June 2020 , IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems)

   null (Ed.)

   Deep Neural Networks (DNNs), a brain-inspired learning methodology, requires tremendous data for training before performing inference tasks. The recent studies demonstrate a strong positive correlation between the inference accuracy and the size of the DNNs and datasets, which leads to an inevitable demand for large DNNs. However, conventional memory techniques are not adequate to deal with the drastic growth of dataset and neural network size. Recently, a resistive memristor has been widely considered as the next generation memory device owing to its high density and low power consumption. Nevertheless, its high switching resistance variations (cycle-tocycle) restrict its feasibility in deep learning. In this work, a novel memristor configuration with the enhanced heat dissipation feature is fabricated and evaluated to address this challenge. Our experimental results demonstrate our memristor reduces the resistance variation by 30% and the inference accuracy increases correspondingly in a similar range. The accuracy increment is evaluated by our Deep Delay-feed-back (Deep-DFR) reservoir computing model. The design area, power consumption, and latency are reduced by 48%, 42%, and 67%, respectively, compared to the conventional SRAM memory technique (6T). The performance of our memristor is improved at various degrees ( 13%-73%) compared to the state-of-the-art memristors. 

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5. SmartDeal: Remodeling Deep Network Weights for Efficient Inference and Training

   https://doi.org/10.1109/TNNLS.2021.3138056  

   Chen, Xiaohan ; Zhao, Yang ; Wang, Yue ; Xu, Pengfei ; You, Haoran ; Li, Chaojian ; Fu, Yonggan ; Lin, Yingyan ; Wang, Zhangyang ( March 2022 , IEEE Transactions on Neural Networks and Learning Systems)

   The record-breaking performance of deep neural networks (DNNs) comes with heavy parameter budgets, which leads to external dynamic random access memory (DRAM) for storage. The prohibitive energy of DRAM accesses makes it nontrivial for DNN deployment on resource-constrained devices, calling for minimizing the movements of weights and data in order to improve the energy efficiency. Driven by this critical bottleneck, we present SmartDeal, a hardware-friendly algorithm framework to trade higher-cost memory storage/access for lower-cost computation, in order to aggressively boost the storage and energy efficiency, for both DNN inference and training. The core technique of SmartDeal is a novel DNN weight matrix decomposition framework with respective structural constraints on each matrix factor, carefully crafted to unleash the hardware-aware efficiency potential. Specifically, we decompose each weight tensor as the product of a small basis matrix and a large structurally sparse coefficient matrix whose nonzero elements are readily quantized to the power-of-2. The resulting sparse and readily quantized DNNs enjoy greatly reduced energy consumption in data movement as well as weight storage, while incurring minimal overhead to recover the original weights thanks to the required sparse bit-operations and cost-favorable computations. Beyond inference, we take another leap to embrace energy-efficient training, by introducing several customized techniques to address the unique roadblocks arising in training while preserving the SmartDeal structures. We also design a dedicated hardware accelerator to fully utilize the new weight structure to improve the real energy efficiency and latency performance. We conduct experiments on both vision and language tasks, with nine models, four datasets, and three settings (inference-only, adaptation, and fine-tuning). Our extensive results show that 1) being applied to inference, SmartDeal achieves up to 2.44x improvement in energy efficiency as evaluated using real hardware implementations and 2) being applied to training, SmartDeal can lead to 10.56x and 4.48x reduction in the storage and the training energy cost, respectively, with usually negligible accuracy loss, compared to state-of-the-art training baselines. Our source codes are available at: https://github.com/VITA-Group/SmartDeal. 

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