Memristor-based signal processing for edge computing

Zhao, Han; Liu, Zhengwu; Tang, Jianshi; Gao, Bin; Zhang, Yufeng; Qian, Hui‐Fen; Wu, Huaqiang

doi:10.26599/tst.2021.9010043

Cited by 29 publications

(11 citation statements)

References 93 publications

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“…Traditional digital signal processing methods usually use analog signal sensors and digital processing units which are physically segmented from each other, leading to high latency and energy consumption for data transferring. IMCbased image processing has shown significant advantages not only in the parallel processing of MVM operations but also in taking advantage of the analog computing nature by reducing the distance between the signal sensing and processing in abundant techniques [121][122][123][124]. Furthermore, many new types of memristors, as well as other emerging nanodevices, have been developed as visual [125,126], auditory [127], and olfactory [128] sensors, etc., generating excitation from the applied signals and processing them in situ, and greatly improving the compactness, processing speed, and energy efficiency.…”

Section: Digital Image Processingmentioning

confidence: 99%

Toward memristive in-memory computing: principles and applications

Bao

Zhou

et al. 2022

Front. Optoelectron.

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With the rapid growth of computer science and big data, the traditional von Neumann architecture suffers the aggravating data communication costs due to the separated structure of the processing units and memories. Memristive in-memory computing paradigm is considered as a prominent candidate to address these issues, and plentiful applications have been demonstrated and verified. These applications can be broadly categorized into two major types: soft computing that can tolerant uncertain and imprecise results, and hard computing that emphasizes explicit and precise numerical results for each task, leading to different requirements on the computational accuracies and the corresponding hardware solutions. In this review, we conduct a thorough survey of the recent advances of memristive in-memory computing applications, both on the soft computing type that focuses on artificial neural networks and other machine learning algorithms, and the hard computing type that includes scientific computing and digital image processing. At the end of the review, we discuss the remaining challenges and future opportunities of memristive in-memory computing in the incoming Artificial Intelligence of Things era. Graphical Abstract

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Section: Digital Image Processingmentioning

confidence: 99%

Toward memristive in-memory computing: principles and applications

Bao

Zhou

et al. 2022

Front. Optoelectron.

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“…1a), showing appealing advantages in terms of energy efficiency and speed compared to conventional hardware [27][28][29] . Besides ANNs, there have also been attempts to use memristor arrays for implementing classic signal processing algorithms 30 , such as finite impulse response (FIR) filter 31 and discrete Fourier transformation (DFT) 32,33 , which has the potential to significantly accelerate medical image reconstruction speed and reduce energy consumption. In both applications, the most computationally intensive computations are vector-matrix multiplication (VMM); however, their actual implementations on memristor arrays are quite different in two aspects.…”

Section: Introductionmentioning

confidence: 99%

“…The left atrium MRI dataset used in our work is one of the ten datasets22,23,24,26,29,30) are used to further prove the consistent performance of MIR, as shown in Figs. Here, to simulate the MRI image reconstruction process, we first divide left atrium MRI image into several 64×64 patches for 64-point DFT computations on our memristor array.…”

mentioning

confidence: 98%

Energy-efficient high-fidelity image reconstruction with memristor arrays for medical diagnosis

Zhao

Liu

Tang

et al. 2022

Preprint

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Medical imaging is an important tool to make accurate medical diagnosis and disease intervention. Current medical image reconstruction algorithms mainly run on Si-based digital processors with von Neumann architecture, which faces critical challenges to process massive amount of data for high-speed and high-quality imaging. Here, we present a memristive image reconstructor (MIR) to greatly accelerate image reconstruction with discrete Fourier transformation (DFT) by computing-in-memory (CIM) with memristor. To implement DFT on memristor arrays efficiently, we proposed a high-accuracy quasi-analogue mapping (QAM) method and generic complex matrix transfer (CMT) scheme, to improve the mapping precision and transfer efficiency, respectively. With these two strategies, we used MIR to demonstrate high-fidelity magnetic resonance imaging (MRI) and computed tomography (CT) image reconstructions, achieving software-equivalent qualities with peak signal-to-noise ratios (PSNR) of 40.88 dB and 22.38 dB, respectively. The reconstructed images were then segmented using a popular nnU-Net algorithm to further evaluate the reconstruction quality. For the MRI task, the final DICE scores were 0.979 and 0.980 for MIR and software, respectively; while for the CT task, the DICE scores were 0.977 and 0.985 for MIR and software, respectively. These results validated the feasibility of using memristor-reconstructed images for medical diagnosis. Furthermore, our MIR also exhibited more than 153× and 79× improvements in energy efficiency and normalized image reconstruction speed, respectively, compared to graphics processing unit (GPU). This work demonstrates MIR as a promising platform for high-fidelity image reconstruction for future medical diagnosis, and also largely extends the application of memristor-based CIM beyond artificial neural networks.

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“…1a), showing appealing advantages in terms of energy efficiency and speed compared to conventional hardware [30][31][32] . Besides ANNs, there have also been attempts to use memristor arrays for implementing classic signal processing algorithms 33 , such as finite impulse response (FIR) filter 34 and discrete Fourier transformation (DFT) 35,36 , which has the potential to significantly accelerate medical image reconstruction speed and reduce energy consumption. In both applications, the most computationally intensive computations are vector-matrix multiplication (VMM); however, their actual implementations on memristor arrays are quite different in two aspects.…”

mentioning

confidence: 99%

Energy-efficient high-fidelity image reconstruction with memristor arrays for medical diagnosis

et al. 2023

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Medical imaging is an important tool for accurate medical diagnosis, while state-of-the-art image reconstruction algorithms raise critical challenges in massive data processing for high-speed and high-quality imaging. Here, we present a memristive image reconstructor (MIR) to greatly accelerate image reconstruction with discrete Fourier transformation (DFT) by computing-in-memory (CIM) with memristor arrays. A high-accuracy quasi-analogue mapping (QAM) method and generic complex matrix transfer (CMT) scheme was proposed to improve the mapping precision and transfer efficiency, respectively. High-fidelity magnetic resonance imaging (MRI) and computed tomography (CT) image reconstructions were demonstrated, achieving software-equivalent qualities and DICE scores after segmentation with nnU-Net algorithm. Remarkably, our MIR exhibited 153× and 79× improvements in energy efficiency and normalized image reconstruction speed, respectively, compared to graphics processing unit (GPU). This work demonstrates MIR as a promising high-fidelity image reconstruction platform for future medical diagnosis, and also largely extends the application of memristor-based CIM beyond artificial neural networks.

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Memristor-based signal processing for edge computing

Cited by 29 publications

References 93 publications

Toward memristive in-memory computing: principles and applications

Toward memristive in-memory computing: principles and applications

Energy-efficient high-fidelity image reconstruction with memristor arrays for medical diagnosis

Energy-efficient high-fidelity image reconstruction with memristor arrays for medical diagnosis

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