La récupération du nom propre d'une personne : éléments fondamentaux sur les informations sémantiques en mémoire et éléments appliqués pour la prise en charge de la maladie d'Elzheimer.

Germain, Veronique

28 May 2013

Pouvoir identifier la personne en face de soi et être capable de retrouver son nom apparaissent des activités indispensables aux interactions sociales quotidiennes. Or, le nom propre s‟avère être une information spécifique comparée aux autres informations disponibles sur une personne. La récupération de cette information est souvent décrite comme difficile. Pour autant, si les auteurs s‟accordent sur la spécificité du nom propre, l‟examen de l‟organisation en mémoire du nom propre et des informations sémantiques liées aux personnes sera l‟objet de ce travail. De plus, l‟accès aux informations sémantiques s‟avère déficitaire dans la maladie d‟Alzheimer.Une première expérience a permis d‟élaborer un matériel normé sur 210 visages/noms, permettant la sélection précise de stimuli. Afin d'étudier la question de l‟organisation en mémoire des informations sémantiques et plus particulièrement l‟information nom propre, deux études comportementales et trois études électrophysiologiques ont été menées. Dans les deux dernières études, nous avons travaillé sur l‟apprentissage et le maintien en mémoire de l‟information spécifique nom propre auprès d‟une population Alzheimer. La discussion des différents résultats s‟appuie sur les connaissances théoriques actuelles sur le sujet. / Being able to identify the person in front of us and being able to remember his or her name appear to be essential activities to daily social interactions. However, compared to other available information related to a person, the proper name seems to be specific information. Proper name retrieval has been very often described as particularly difficult. Although this work aims to study the organization of semantic information in memory, and more specifically the proper name information. Moreover, access to semantic information is known be deficient for Alzheimer disease.A first study has allowed to develope out a standardized material of 210 faces/names, permitting an accurate selection of stimuli. Two behavioural and three electrophysiological studies have been carried out to study the organization of semantic information in memory, and more specifically the proper name. For the last two experiments, we have worked on learning and how to keep specific information « proper name » into memory for Alzheimer‟s disease patients. Discussion of the different results is based on current theorical knowledge on the subject.

Nom propre de personnes

Informations sémantiques

Organisation en mémoire

Catégoriel associé

Interférence

Alzheimer

Proper name

Semantic knowledge

Memory organization

Categorical

Associative

Interference

Alzheimer

150

Brain inspired approach to computational face recognition

da Silva Gomes, Joao Paulo

January 2015

Face recognition that is invariant to pose and illumination is a problem solved effortlessly by the human brain, but the computational details that underlie such efficient recognition are still far from clear. This thesis draws on research from psychology and neuroscience about face and object recognition and the visual system in order to develop a novel computational method for face detection, feature selection and representation, and memory structure for recall. A biologically plausible framework for developing a face recognition system will be presented. This framework can be divided into four parts: 1) A face detection system. This is an improved version of a biologically inspired feedforward neural network that has modifiable connections and reflects the hierarchical and elastic structure of the visual system. The face detection system can detect if a face is present in an input image, and determine the region which contains that face. The system is also capable of detecting the pose of the face. 2) A face region selection mechanism. This mechanism is used to determine the Gabor-style features corresponding to the detected face, i.e., the features from the region of interest. This region of interest is selected using a feedback mechanism that connects the higher level layer of the feedforward neural network where ultimately the face is detected to an intermediate level where the Gabor style features are detected. 3) A face recognition system which is based on the binary encoding of the Gabor style features selected to represent a face. Two alternative coding schemes are presented, using 2 and 4 bits to represent a winning orientation at each location. The effectiveness of the Gabor-style features and the different coding schemes in discriminating faces from different classes is evaluated using the Yale B Face Database. The results from this evaluation show that this representation is close to other results on the same database. 4) A theoretical approach for a memory system capable of memorising sequences of poses. A basic network for memorisation and recall of sequences of labels have been implemented, and from this it is extrapolated a memory model that could use the ability of this model to memorise and recall sequences, to assist in the recognition of faces by memorising sequences of poses. Finally, the capabilities of the detection and recognition parts of the system are demonstrated using a demo application that can learn and recognise faces from a webcam.

006.3

Machine Learning Techniques with Specific Application to the Early Olfactory System

Auffarth, Benjamin

January 2012

This thesis deals with machine learning techniques for the extraction of structure and the analysis of the vertebrate olfactory pathway based on related methods. Some of its main contributions are summarized below. We have performed a systematic investigation for classification in biomedical images with the goal of recognizing a material in these images by its texture. This investigation included (i) different measures for evaluating the importance of image descriptors (features), (ii) methods to select a feature set based on these evaluations, and (iii) classification algorithms. Image features were evaluated according to their estimated relevance for the classification task and their redundancy with other features. For this purpose, we proposed a framework for relevance and redundancy measures and, within this framework, we proposed two new measures. These were the value difference metric and the fit criterion. Both measures performed well in comparison with other previously used ones for evaluating features. We also proposed a Hopfield network as a method for feature selection, which in experiments gave one of the best results relative to other previously used approaches. We proposed a genetic algorithm for clustering and tested it on several realworld datasets. This genetic algorithm was novel in several ways, including (i) the use of intra-cluster distance as additional optimization criterion, (ii) an annealing procedure, and (iii) adaptation of mutation rates. As opposed to many conventional clustering algorithms, our optimization framework allowed us to use different cluster validation measures including those which do not rely on cluster centroids. We demonstrated the use of the clustering algorithm experimentally with several cluster validity measures as optimization criteria. We compared the performance of our clustering algorithm to that of the often-used fuzzy c-means algorithm on several standard machine learning datasets from the University of California/Urvine (UCI) and obtained good results. The organization of representations in the brain has been observed at several stages of processing to spatially decompose input from the environment into features that are somehow relevant from a behavioral or perceptual standpoint. For the perception of smells, the analysis of such an organization, however, is not as straightforward because of the missing metric. Some studies report spatial clusters for several combinations of physico-chemical properties in the olfactory bulb at the level of the glomeruli. We performed a systematic study of representations based on a dataset of activity-related images comprising more than 350 odorants and covering the whole spatial array of the first synaptic level in the olfactory system. We found clustered representations for several physico-chemical properties. We compared the relevance of these properties to activations and estimated the size of the coding zones. The results confirmed and extended previous studies on olfactory coding for physico-chemical properties. Particularly of interest was the spatial progression by carbon chain that we found. We discussed our estimates of relevance and coding size in the context of processing strategies. We think that the results obtained in this study could guide the search into olfactory coding primitives and the understanding of the stimulus space. In a second study on representations in the olfactory bulb, we grouped odorants together by perceptual categories, such as floral and fruity. By the application of the same statistical methods as in the previous study, we found clustered zones for these categories. Furthermore, we found that distances between spatial representations were related to perceptual differences in humans as reported in the literature. This was possibly the first time that such an analysis had been done. Apart from pointing towards a spatial decomposition by perceptual dimensions, results indicate that distance relationships between representations could be perceptually meaningful. In a third study, we modeled axon convergence from olfactory receptor neurons to the olfactory bulb. Sensory neurons were stimulated by a set of biologically-relevant odors, which were described by a set of physico-chemical properties that covaried with the neural and glomerular population activity in the olfactory bulb. Convergence was mediated by the covariance between olfactory neurons. In our model, we could replicate the formation of glomeruli and concentration coding as reported in the literature, and further, we found that the spatial relationships between representational zones resulting from our model correlated with reported perceptual differences between odor categories. This shows that natural statistics, including similarity of physico-chemical structure of odorants, can give rise to an ordered arrangement of representations at the olfactory bulb level where the distances between representations are perceptually relevant. / <p>QC 20120224</p>

feature selection

image features

pattern classification

relevance

redundancy

distributional similarity

divergence measure

genetic algorithms

clustering algorithms

annealing

olfactory coding

olfactory bulb

odorants

glomeruli

property-activity relationship

olfaction

plasticity

axonal guidance

odor category

perception

spatial coding

population coding

memory organization

odor quality