A parsimonious computational model of visual target position encoding in the superior colliculus

Taouali, Wahiba; Goffart, Laurent; Alexandre, Frédéric; Rougier, Nicolas P.

doi:10.1007/s00422-015-0660-8

Cited by 17 publications

(25 citation statements)

References 65 publications

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“…Finally, a preference for orienting gaze shifts that bring the target near the center of the visual field was here assumed. Explanatory reasons for favoring such saccades can be computationally evaluated, for instance by adopting a retinotopic yet non-homogeneous representation of the visual field (with a greater accuity in the fovea, at the center of the retina), as developed in Taouali et al (2015). In addition to limiting the extent of the sensorimotor regularities to be learned, a saccade then also leads to the magnification of the target image.…”

Section: Conclusion and Discussionmentioning

confidence: 99%

“…Therefore, they are not in principle limited to the detection of stimuli defined by a single lateral connectivity profile (for an instance of complex preprocessing to abstract from raw input images, see Maggiani, Bourrasset, Quinton, Berry, & Sérot, 2016). Also, complex transformations and projections can be considered, for instance using alog-polar representation of the visual field (Taouali, Goffart, Alexandre, & Rougier, 2015) or relying on self-organizing maps (Lefort, Boniface, & Girau, 2011). While Taouali et al (2015) provide details on how the DNF approach can account for the encoding of target location in the deep superior colliculus, Gandhi and Katnani (2011) review the different plausible decoding mechanisms from a topologically organized population of neurons, focusing on saccade generation.…”

Section: Dynamic Neural Fieldsmentioning

confidence: 99%

“…Also, complex transformations and projections can be considered, for instance using alog-polar representation of the visual field (Taouali, Goffart, Alexandre, & Rougier, 2015) or relying on self-organizing maps (Lefort, Boniface, & Girau, 2011). While Taouali et al (2015) provide details on how the DNF approach can account for the encoding of target location in the deep superior colliculus, Gandhi and Katnani (2011) review the different plausible decoding mechanisms from a topologically organized population of neurons, focusing on saccade generation. They compare the "vector summation" and "vector averaging" approaches, the latter being preferred in most of the DNF literature, as well as in the current paper.…”

Section: Dynamic Neural Fieldsmentioning

confidence: 99%

“…Learning to foveate the target and keep it in the central visual field will reduce the problem to processing the motion signals and characterize the dynamics of the input stimulus. Also pointing in such direction, a model of target position encoding in the superior colliculus has been recently proposed in Taouali et al (2015), demonstrating that apparently complex foveation performance can be accounted for by dynamical properties of neural field and retinotopic stimulation (using a log-polar representation of the visual field).…”

Section: Predictive Neural Field (Pnf)mentioning

confidence: 99%

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A unified dynamic neural field model of goal directed eye movements

Quinton

Goffart

2018

Connection Science

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Primates heavily rely on their visual system, which exploits signals of graded precision based on the eccentricity of the target in the visual field. The interactions with the environment involve actively selecting and focusing on visual targets or regions of interest, instead of contemplating an omnidirectional visual flow. Eye-movements specifically allow foveating targets and track their motion. Once a target is brought within the central visual field, eye-movements are usually classified into catch-up saccades (jumping from one orientation or fixation to another) and smooth pursuit (continuously tracking a target with low velocity). Building on existing dynamic neural field equations, we introduce a novel model that incorporates internal projections to better estimate the current target location (associated to a peak of activity). Such estimate is then used to trigger an eye movement, leading to qualitatively different behaviors depending on the dynamics of the whole oculomotor system: 1) fixational eye-movements due to small variations in the weights of projections when the target is stationary, 2) interceptive and catch-up saccades when peaks build and relax on the neural field, 3) smooth pursuit when the peak stabilizes near the center of the field, the system reaching a fixed point attractor. Learning is nevertheless required for tracking a rapidly moving target, and the proposed model thus replicates recent results in the monkey, in which repeated exercise permits the maintenance of the target within in the central visual field at its current (here-and-now) location, despite the delays involved in transmitting retinal signals to the oculomotor neurons.

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Section: Conclusion and Discussionmentioning

confidence: 99%

Section: Dynamic Neural Fieldsmentioning

confidence: 99%

Section: Dynamic Neural Fieldsmentioning

confidence: 99%

Section: Predictive Neural Field (Pnf)mentioning

confidence: 99%

See 2 more Smart Citations

A unified dynamic neural field model of goal directed eye movements

Quinton

Goffart

2018

Connection Science

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“…It is composed of several layers, some receiving mainly visual information from many regions in the brain, including directly from the retina. The more super cial sensory layers are topographic maps of the surrounding environment and are in direct association with deeper motor layers for eye movements towards the place elected by competition in the sensory layer (Taouali et al, 2015). It has been remarked that this structure can also perform direct sensorimotor associations for orientation of the whole body for tracking novel stimuli, for defensive movements and ight in case of a danger (Dean et al, 1989).…”

Section: Where -The Superior Colliculusmentioning

confidence: 99%

A global framework for a systemic view of brain modeling

Alexandre

2020

Preprint

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Background: The brain is a complex system, due to the heterogeneity of its structure, the diversity of the functions in which it participates and to its reciprocal relationships with the body and the environment. Researchers in cognitive computational neuroscience generally focused on one specific task, lack this global view and a clear understanding of how their model is inserted in a global cognitive architecture. A systemic description of the brain is presented here, as a general framework where specific models in computational neuroscience can be integrated and associated with global information flows and cognitive functions. Results: In an enactive view, this framework integrates the fundamental organization of the brain in sensorimotor loops with the internal and the external worlds, answering four fundamental questions (what, why, where and how). Our survival-oriented definition of behavior gives a prominent role to pavlovian and instrumental conditioning, augmented during phylogeny by the specific contribution of other kinds of learning, related to semantic memory in the posterior cortex, episodic memory in the hippocampus and working memory in the frontal cortex. Conclusions: This framework highlights that responses can be prepared in different ways, from pavlovian reflexes and habitual behavior to deliberations for goal-directed planning and reasoning, and explains that these different kinds of responses coexist, collaborate and compete for the control of behavior. It also lays emphasis on the fact that cognition can be described as a dynamical system of interacting memories, some acting to provide information to others, to replace them when they are not efficient enough, or to help for their improvement. Describing the brain as an architecture of learning systems has also strong implications in Machine Learning. Our biologically informed view of pavlovian and instrumental conditioning can be very precious to revisit classical Reinforcement Learning and provide a basis to ensure really autonomous learning.

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A Behavioral Framework for Information Representation in the Brain

Alexandre

2017

Computational Models of Brain and Behavior

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Along evolution, increasingly complex cognitive functions have been attributed to an increasingly complex brain architecture. Nevertheless, the brain remains anchored on an organization dedicated to survival. We believe that keeping this principle in mind is an excellent way to better decipher cerebral mechanisms and corresponding cognitive functions. Accordingly, we describe here the main characteristics and constraints of an intelligent agent learning to survive in an intelligent environment, in terms of information flows and learning principles. On this basis, we propose a framework of description for the architecture of the brain of mammals, organized around four fundamental questions to be answered. These questions define the identity of the goal (what ?) and the motivation to choose it (why ?), its location (where ?) and the way to get it (how ?). Then we explain how the main requirements of respondent and operant conditioning can be addressed within this architecture and how it is also compatible with the elaboration of more complex cognitive mechanisms. This can be seen as the validation of this framework to explore how cognitive functions might emerge from cerebral circuits and how they have been made more complex along evolution. It also proposes a systemic view of the brain, useful to develop the cognitive architecture of an intelligent agent exploring autonomously its environment and to propose to machine learning innovative algorithms.

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A parsimonious computational model of visual target position encoding in the superior colliculus

Cited by 17 publications

References 65 publications

A unified dynamic neural field model of goal directed eye movements

A unified dynamic neural field model of goal directed eye movements

A global framework for a systemic view of brain modeling

A Behavioral Framework for Information Representation in the Brain

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