2013
DOI: 10.3389/fnins.2013.00178
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Real-time classification and sensor fusion with a spiking deep belief network

Abstract: Deep Belief Networks (DBNs) have recently shown impressive performance on a broad range of classification problems. Their generative properties allow better understanding of the performance, and provide a simpler solution for sensor fusion tasks. However, because of their inherent need for feedback and parallel update of large numbers of units, DBNs are expensive to implement on serial computers. This paper proposes a method based on the Siegert approximation for Integrate-and-Fire neurons to map an offline-tr… Show more

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Cited by 321 publications
(324 citation statements)
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References 53 publications
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“…One of them that has been implemented on SpiNNaker is the model using RBM [61], which basically implements a spike-based DBN proposed by [62]. Since RBM is a stochastic model, the most convenient method to approach it in a spiking neuron models is by using firing rate.…”
Section: Dbn On Spinnakermentioning
confidence: 99%
See 1 more Smart Citation
“…One of them that has been implemented on SpiNNaker is the model using RBM [61], which basically implements a spike-based DBN proposed by [62]. Since RBM is a stochastic model, the most convenient method to approach it in a spiking neuron models is by using firing rate.…”
Section: Dbn On Spinnakermentioning
confidence: 99%
“…The network that consists of 4 layers were used: one input layer with 784 neurons, two hidden layers with 500 neurons each, and a 10 neuron output layer (see Figure 8(b)). Static images are transformed into spike trains by converting each pixel of an MNIST image into a Poisson spike-train with a rate proportional to its intensity, while all firing rates are scaled such that the total firing rate of the population is constant [62]. The firing rate of neuron populations are depicted in Figure 8(c).…”
Section: Dbn On Spinnakermentioning
confidence: 99%
“…Their applications include approximation of arbitrary functions and probability distributions as well as modeling of biological neuronal activity. Some studies have modified spiking neural network models to act as Boltzmann machines [16][17][18]. They employ stochastic state transitions or strong noise induction to implement the stochastic units.…”
Section: Introductionmentioning
confidence: 99%
“…An interesting initiative to notice is the approach that mimics how a doctor or a sound engineer use their eyes to analyse the results of an ECG or a spectrogram, by transforming sensors data to image data [14]. These approaches are also useful when it is necessary to fusion multiple sensors sources [15][16][17].…”
Section: Deep Learning For Signal and Image Processingmentioning
confidence: 99%