Multi-Objective Optimization for Size and Resilience of Spiking Neural Networks

Dimovska, Mihaela; Johnston, Travis; Schuman, Catherine D.; Mitchell, J. Parker; Potok, Thomas E.

doi:10.1109/uemcon47517.2019.8992983

Cited by 8 publications

(7 citation statements)

References 28 publications

(32 reference statements)

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“…GA requires no a priori knowledge about what it is trying to optimise as domain specific knowledge is contained in the fitness function and the genetic operators defined for the problem. In previous applications of GA to SNNs, [11] proposed a discrete objective function to optimise the size and resilience of SNNs, while [18] used GA to train spiking neural networks to compete for limited resources in simulated environment.…”

Section: Introductionmentioning

confidence: 99%

“…Despite their advantages, the modelling of SNNs poses several challenges. Given the larger number of parameters as compared to classic neural networks, a major challenge is the time-consuming process of model parameter searching [11]. Commonly, optimisation methods are required, which are processes in searching for some optimal solution(s) with respect to the model parameter(s) and some specified goal(s) (via some objective mathematical function(s)) [12].…”

Section: Introductionmentioning

confidence: 99%

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Multi-Objective Optimisation of Cortical Spiking Neural Networks With Genetic Algorithms

Fitzgerald

Wong‐Lin

2021

2021 32nd Irish Signals and Systems Conference (ISSC)

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Spiking neural networks (SNNs) communicate through the all-or-none spiking activity of neurons. However, fitting the large number of SNN model parameters to observed neural activity patterns, for example, in biological experiments, remains a challenge. Previous work using genetic algorithm (GA) optimisation on a specific efficient SNN model, using the Izhikevich neuronal model, was limited to a single parameter and objective. This work applied a version of GA, called nondominated sorting GA (NSGA-III), to demonstrate the feasibility of performing multi-objective optimisation on the same SNN, focusing on searching network connectivity parameters to achieve target firing rates of excitatory and inhibitory neuronal types, including across different network connectivity sparsity. We showed that NSGA-III could readily optimise for various firing rates. Notably, when the excitatory neural firing rates were higher than or equal to that of inhibitory neurons, the errors were small. Moreover, when connectivity sparsity was considered as a parameter to be optimised, the optimal solutions required sparse network connectivity. We also found that for excitatory neural firing rates lower than that of inhibitory neurons, the errors were generally larger. Overall, we have successfully demonstrated the feasibility of implementing multi-objective GA optimisation on network parameters of recurrent and sparse SNN.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Multi-Objective Optimisation of Cortical Spiking Neural Networks With Genetic Algorithms

Fitzgerald

Wong‐Lin

2021

2021 32nd Irish Signals and Systems Conference (ISSC)

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“…Pruning has been extensively studied in ANNs because of its great success, whereas a very limited amount of works have been done in SNNs [15][16][17][18]. In Reference [15], authors propose pruning neurons by comparing their class-wise dominance with a certain threshold in a supervised way.…”

Section: Introductionmentioning

confidence: 99%

“…In Reference [15], authors propose pruning neurons by comparing their class-wise dominance with a certain threshold in a supervised way. In Reference [17], a post-training neuron pruning method was used to reduce the network size by comparing the spiking frequency of a neuron with average output spike frequency. In Reference [18], a supervised pruning strategy was demonstrated by evaluating the similarity between neurons and pruning similar neurons.…”

Section: Introductionmentioning

confidence: 99%

Towards Efficient Neuromorphic Hardware: Unsupervised Adaptive Neuron Pruning

et al. 2020

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To solve real-time challenges, neuromorphic systems generally require deep and complex network structures. Thus, it is crucial to search for effective solutions that can reduce network complexity, improve energy efficiency, and maintain high accuracy. To this end, we propose unsupervised pruning strategies that are focused on pruning neurons while training in spiking neural networks (SNNs) by utilizing network dynamics. The importance of neurons is determined by the fact that neurons that fire more spikes contribute more to network performance. Based on these criteria, we demonstrate that pruning with an adaptive spike count threshold provides a simple and effective approach that can reduce network size significantly and maintain high classification accuracy. The online adaptive pruning shows potential for developing energy-efficient training techniques due to less memory access and less weight-update computation. Furthermore, a parallel digital implementation scheme is proposed to implement spiking neural networks (SNNs) on field programmable gate array (FPGA). Notably, our proposed pruning strategies preserve the dense format of weight matrices, so the implementation architecture remains the same after network compression. The adaptive pruning strategy enables 2.3× reduction in memory size and 2.8× improvement on energy efficiency when 400 neurons are pruned from an 800-neuron network, while the loss of classification accuracy is 1.69%. And the best choice of pruning percentage depends on the trade-off among accuracy, memory, and energy. Therefore, this work offers a promising solution for effective network compression and energy-efficient hardware implementation of neuromorphic systems in real-time applications.

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“…Many of the results providing consistent reconstruction generally assume that the system dynamics is strictly causal Granger (1969); Yue et al (2017); Gonc ¸alves and Warnick (2008); Etesami and Kiyavash (2014). However, in practice, the necessity of using models with non-necessarily strictly causal dynamics arises in many areas, such as biology Schiatti et al (2015); Faes et al (2015), finance Materassi and Innocenti (2009) or neuroscience Seth et al (2015) and brain-inspired neural network models Dimovska et al (2019). For this reason, there are methods that, at least in the linear case, try to deal with direct feedthroughs, too.…”

Section: Introductionmentioning

confidence: 99%

An algorithm for reconstruction of triangle-free linear dynamic networks with verification of correctness

Dimovska,

Materassi

2020

Preprint

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Reconstructing a network of dynamic systems from observational data is an active area of research. Many approaches guarantee a consistent reconstruction under the relatively strong assumption that the network dynamics is governed by strictly causal transfer functions. However, in many practical scenarios, strictly causal models are not adequate to describe the system and it is necessary to consider models with dynamics that include direct feedthrough terms. In presence of direct feedthroughs, guaranteeing a consistent reconstruction is a more challenging task. Indeed, under no additional assumptions on the network, we prove that, even in the limit of infinite data, any reconstruction method is susceptible to inferring edges that do not exist in the true network (false positives) or not detecting edges that are present in the network (false negative). However, for a class of triangle-free networks introduced in this article, some consistency guarantees can be provided. We present a method that either exactly recovers the topology of a triangle-free network certifying its correctness or outputs a graph that is sparser than the topology of the actual network, specifying that such a graph has no false positives, but there are false negatives.

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Multi-Objective Optimization for Size and Resilience of Spiking Neural Networks

Cited by 8 publications

References 28 publications

Multi-Objective Optimisation of Cortical Spiking Neural Networks With Genetic Algorithms

Multi-Objective Optimisation of Cortical Spiking Neural Networks With Genetic Algorithms

Towards Efficient Neuromorphic Hardware: Unsupervised Adaptive Neuron Pruning

An algorithm for reconstruction of triangle-free linear dynamic networks with verification of correctness

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