The winnerless competition paradigm in cellular nonlinear networks: Models and applications

Arena, Paolo; Fortuna, Luigi; Lombardo, Davide; Patané, Luca; Velarde, Manuel G.

doi:10.1002/cta.567

Cited by 18 publications

(5 citation statements)

References 25 publications

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“…On the other hand, the different dynamical modes observed in the network are relevant in the context of multiple technical applications. Winnerless competition is usually associated to sequential information processing (Seliger et al, 2003; Rabinovich et al, 2006a; Arena et al, 2009; Kiebel et al, 2009; Latorre et al, 2013b), which has a wide application in many artificial intelligent systems in tasks such as inference, planning, reasoning, natural language processing, and others (Sun and Giles, 2001; Wörgötter and Porr, 2005). Similarly, pattern recognition in different spiking ANNs is based on winner-take-all dynamics (Bohte et al, 2002a; Gütig and Sompolinsky, 2006; Schmuker et al, 2014).…”

Section: Discussionmentioning

confidence: 99%

Implementing Signature Neural Networks with Spiking Neurons

Carrillo-Medina

Latorre

2016

Front. Comput. Neurosci.

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Spiking Neural Networks constitute the most promising approach to develop realistic Artificial Neural Networks (ANNs). Unlike traditional firing rate-based paradigms, information coding in spiking models is based on the precise timing of individual spikes. It has been demonstrated that spiking ANNs can be successfully and efficiently applied to multiple realistic problems solvable with traditional strategies (e.g., data classification or pattern recognition). In recent years, major breakthroughs in neuroscience research have discovered new relevant computational principles in different living neural systems. Could ANNs benefit from some of these recent findings providing novel elements of inspiration? This is an intriguing question for the research community and the development of spiking ANNs including novel bio-inspired information coding and processing strategies is gaining attention. From this perspective, in this work, we adapt the core concepts of the recently proposed Signature Neural Network paradigm—i.e., neural signatures to identify each unit in the network, local information contextualization during the processing, and multicoding strategies for information propagation regarding the origin and the content of the data—to be employed in a spiking neural network. To the best of our knowledge, none of these mechanisms have been used yet in the context of ANNs of spiking neurons. This paper provides a proof-of-concept for their applicability in such networks. Computer simulations show that a simple network model like the discussed here exhibits complex self-organizing properties. The combination of multiple simultaneous encoding schemes allows the network to generate coexisting spatio-temporal patterns of activity encoding information in different spatio-temporal spaces. As a function of the network and/or intra-unit parameters shaping the corresponding encoding modality, different forms of competition among the evoked patterns can emerge even in the absence of inhibitory connections. These parameters also modulate the memory capabilities of the network. The dynamical modes observed in the different informational dimensions in a given moment are independent and they only depend on the parameters shaping the information processing in this dimension. In view of these results, we argue that plasticity mechanisms inside individual cells and multicoding strategies can provide additional computational properties to spiking neural networks, which could enhance their capacity and performance in a wide variety of real-world tasks.

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Section: Discussionmentioning

confidence: 99%

Implementing Signature Neural Networks with Spiking Neurons

Carrillo-Medina

Latorre

2016

Front. Comput. Neurosci.

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“…The cognitive tasks were handled by the four-layer neural network with the time and path optimization.Ref. [ 155 ] presented a winnerless competition paradigm, and the spatial input determined the sequence of saddle points of the path and then reflected the spatial–temporal motion. The framework was an action-oriented perception based on Lotka–Volterra system with cellular nonlinear networks and distance sensors.…”

Section: Multimodal Navigationmentioning

confidence: 99%

Bioinspired Perception and Navigation of Service Robots in Indoor Environments: A Review

2023

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Biological principles draw attention to service robotics because of similar concepts when robots operate various tasks. Bioinspired perception is significant for robotic perception, which is inspired by animals’ awareness of the environment. This paper reviews the bioinspired perception and navigation of service robots in indoor environments, which are popular applications of civilian robotics. The navigation approaches are classified by perception type, including vision-based, remote sensing, tactile sensor, olfactory, sound-based, inertial, and multimodal navigation. The trend of state-of-art techniques is moving towards multimodal navigation to combine several approaches. The challenges in indoor navigation focus on precise localization and dynamic and complex environments with moving objects and people.

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“…Then, in the presence of a weak perturbation (e.g., noise, for detail see [26] and references therein) a trajectory can wander in the phase space from one saddle to another, thus implementing a particular temporal pattern of neuronal excitation. This provides extremely rich behaviors even in small-size neural networks (see, e.g., [17,[27][28][29]).…”

Section: Introductionmentioning

confidence: 99%

Fast social-like learning of complex behaviors based on motor motifs

2018

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Social learning is widely observed in many species. Less experienced agents copy successful behaviors exhibited by more experienced individuals. Nevertheless, the dynamical mechanisms behind this process remain largely unknown. Here we assume that a complex behavior can be decomposed into a sequence of n motor motifs. Then a neural network capable of activating motor motifs in a given sequence can drive an agent. To account for (n-1)! possible sequences of motifs in a neural network, we employ the winnerless competition approach. We then consider a teacher-learner situation: one agent exhibits a complex movement, while another one aims at mimicking the teacher's behavior. Despite the huge variety of possible motif sequences we show that the learner, equipped with the provided learning model, can rewire "on the fly" its synaptic couplings in no more than (n-1) learning cycles and converge exponentially to the durations of the teacher's motifs. We validate the learning model on mobile robots. Experimental results show that the learner is indeed capable of copying the teacher's behavior composed of six motor motifs in a few learning cycles. The reported mechanism of learning is general and can be used for replicating different functions, including, for example, sound patterns or speech.

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The winnerless competition paradigm in cellular nonlinear networks: Models and applications

Cited by 18 publications

References 25 publications

Implementing Signature Neural Networks with Spiking Neurons

Implementing Signature Neural Networks with Spiking Neurons

Bioinspired Perception and Navigation of Service Robots in Indoor Environments: A Review

Fast social-like learning of complex behaviors based on motor motifs

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