A Highly Effective and Robust Membrane Potential-Driven Supervised Learning Method for Spiking Neurons

Zhang, Malu; Qu, Hong; Belatreche, Ammar; Chen, Yi; Zhang, Yi

doi:10.1109/tnnls.2018.2833077

Cited by 54 publications

(24 citation statements)

References 54 publications

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“…As mentioned in Section 1, the key aspect of most systems is power consumption and strategies for minimizing it. At the same time, the implementation of spiking networks is an area of interest of many IT corporations, as well as a subject of numerous scientific research dedicated to the problem of training [9,20] or hardware implementation [6,19]. Models of neurons shown in Figure 2 were developed for hardware implementation using modern nanometer CMOS technologies.…”

Section: Discussion and Summarymentioning

confidence: 99%

Spiking Neural Network Based on Cusp Catastrophe Theory

Huderek

Szczęsny

Rato

2019

Foundations of Computing and Decision Sciences

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This paper addresses the problem of effective processing using third generation neural networks. The article features two new models of spiking neurons based on the cusp catastrophe theory. The effectiveness of the models is demonstrated with an example of a network composed of three neurons solving the problem of linear inseparability of the XOR function. The proposed solutions are dedicated to hardware implementation using the Edge computing strategy. The paper presents simulation results and outlines further research direction in the field of practical applications and implementations using nanometer CMOS technologies and the current processing mode.

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Section: Discussion and Summarymentioning

confidence: 99%

Spiking Neural Network Based on Cusp Catastrophe Theory

Huderek

Szczęsny

Rato

2019

Foundations of Computing and Decision Sciences

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“…J. Wang et al 32 proposed OSNN algorithm having adaptive structure based supervised learning ability. There exist membrane potential driven learning algorithms proposed for SNN such as MPD-AL 33 , EMPD 34 , and MemPo-Learn 35 . In the development of MPD-AL 33 algorithm, two approaches were used namely firing less spikes than desired and firing more spikes than desired.…”

Section: Spifog: An Efficient Supervised Learning Algorithm For the Nmentioning

confidence: 99%

“…In 34 , two process namely at desired output times and at undesired output times were used. The error function proposed in 35 is formed by taking difference between membrane potential of output neuron and the firing threshold of its own. The ability of evolutionary strategies (ES) to work directly with real numbers without complex encoding technique drives researchers towards the investigation of ES to train SNN.…”

Section: Spifog: An Efficient Supervised Learning Algorithm For the Nmentioning

confidence: 99%

SpiFoG: an efficient supervised learning algorithm for the network of spiking neurons

Hussain

Thounaojam

2020

Sci Rep

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are mapped into spike times to yield 16 features (4×L). In the dataset, each class has 50 instances. In order to do a better comparison with the state-of-the-art algorithms, we have used the same number of training and testing samples as taken by the state-of-the-art algorithms. Therefore, for training, 50% of 150 instances are used and rest are used to test the performance. The WBC dataset 42 , represents two classes such as Benign (Class 1), and Malignant (Class 2). There are 699 instances with 16 missing values. For training, 333 instances are used and for testing 350 instances are used akin to SpikeProp algorithm 8 .

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“…On the other hand, a dataset has to be complex enough such that it simulates a real-world problem. There are some datasets that support the learning of temporal patterns (Zhang et al, 2017(Zhang et al, , 2018(Zhang et al, , 2019Wu et al, 2018a), whereby each pattern contains only a single label, such as a sound event or an isolated word. Such datasets are much simpler than those in deep learning studies (Graves et al, 2006), whereby a temporal pattern involves a sequence of labels, such as continuous speech.…”

Section: Introductionmentioning

confidence: 99%

An Efficient and Perceptually Motivated Auditory Neural Encoding and Decoding Algorithm for Spiking Neural Networks

Pan

Chua

et al. 2020

Front. Neurosci.

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The auditory front-end is an integral part of a spiking neural network (SNN) when performing auditory cognitive tasks. It encodes the temporal dynamic stimulus, such as speech and audio, into an efficient, effective and reconstructable spike pattern to facilitate the subsequent processing. However, most of the auditory front-ends in current studies have not made use of recent findings in psychoacoustics and physiology concerning human listening. In this paper, we propose a neural encoding and decoding scheme that is optimized for audio processing. The neural encoding scheme, that we call Biologically plausible Auditory Encoding (BAE), emulates the functions of the perceptual components of the human auditory system, that include the cochlear filter bank, the inner hair cells, auditory masking effects from psychoacoustic models, and the spike neural encoding by the auditory nerve. We evaluate the perceptual quality of the BAE scheme using PESQ; the performance of the BAE based on sound classification and speech recognition experiments. Finally, we also built and published two spikeversion of speech datasets: the Spike-TIDIGITS and the Spike-TIMIT, for researchers to use and benchmarking of future SNN research.

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A Highly Effective and Robust Membrane Potential-Driven Supervised Learning Method for Spiking Neurons

Cited by 54 publications

References 54 publications

Spiking Neural Network Based on Cusp Catastrophe Theory

Spiking Neural Network Based on Cusp Catastrophe Theory

SpiFoG: an efficient supervised learning algorithm for the network of spiking neurons

An Efficient and Perceptually Motivated Auditory Neural Encoding and Decoding Algorithm for Spiking Neural Networks

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