A Decade of Neural Networks: Practical Applications and Prospects

The Jet Propulsion Laboratory Neural Network Workshop, sponsored by NASA and DOD, brings together sponsoring agencies, active researchers, and the user community to formulate a vision for the next decade of neural network research and application prospects. While the speed and computing power of microprocessors continue to grow at an ever-increasing pace, the demand to intelligently and adaptively deal with the complex, fuzzy, and often ill-defined world around us remains to a large extent unaddressed. Powerful, highly parallel computing paradigms such as neural networks promise to have a major impact in addressing these needs. Papers in the workshop proceedings highlight benefits of neural networks in real-world applications compared to conventional computing techniques. Topics include fault diagnosis, pattern recognition, and multiparameter optimization

A Review of the Teaching and Learning on Power Electronics Course

—In this review, we describe various kinds of problem and solution related teaching and learning on power electronics course all around the world. The method was used the study of literature on journal articles and proceedings published by reputable international organizations. Thirtynine papers were obtained using Boolean operators, according to the specified criteria. The results of the problems generally established that student learning motivation was low, teaching approaches that are still teacher-centered, the scope of the curriculum extends, and the physical limitations of laboratory equipment. The solutions offered are very diverse ranging from models, strategies, methods and learning techniques supported by information and communication technology

Digital Pathology: The Time Is Now to Bridge the Gap between Medicine and Technological Singularity

Digitalization of the imaging in radiology is a reality in several healthcare institutions worldwide. The challenges of filing, confidentiality, and manipulation have been brilliantly solved in radiology. However, digitalization of hematoxylin- and eosin-stained routine histological slides has shown slow movement. Although the application for external quality assurance is a reality for a pathologist with most of the continuing medical education programs utilizing virtual microscopy, the abandonment of traditional glass slides for routine diagnostics is far from the perspectives of many departments of laboratory medicine and pathology. Digital pathology images are captured as images by scanning and whole slide imaging/virtual microscopy can be obtained by microscopy (robotic) on an entire histological (microscopic) glass slide. Since 1986, services using telepathology for the transfer of images of anatomic pathology between detached locations have benefited countless patients globally, including the University of Alberta. The purpose of specialist recertification or re-validation for the Royal College of Pathologists of Canada belonging to the Royal College of Physicians and Surgeons of Canada and College of American Pathologists is a milestone in virtual reality. Challenges, such as high bandwidth requirement, electronic platforms, the stability of the operating systems, have been targeted and are improving enormously. The encryption of digital images may be a requirement for the accreditation of laboratory services—quantum computing results in quantum-mechanical phenomena, such as superposition and entanglement. Different from binary digital electronic computers based on transistors where data are encoded into binary digits (bits) with two different states (0 and 1), quantum computing uses quantum bits (qubits), which can be in superpositions of states. The use of quantum computing protocols on encrypted data is crucial for the permanent implementation of virtual pathology in hospitals and universities. Quantum computing may well represent the technological singularity to create new classifications and taxonomic rules in medicine

Proceedings of the Third International Workshop on Neural Networks and Fuzzy Logic, volume 2

Papers presented at the Neural Networks and Fuzzy Logic Workshop sponsored by the National Aeronautics and Space Administration and cosponsored by the University of Houston, Clear Lake, held 1-3 Jun. 1992 at the Lyndon B. Johnson Space Center in Houston, Texas are included. During the three days approximately 50 papers were presented. Technical topics addressed included adaptive systems; learning algorithms; network architectures; vision; robotics; neurobiological connections; speech recognition and synthesis; fuzzy set theory and application, control and dynamics processing; space applications; fuzzy logic and neural network computers; approximate reasoning; and multiobject decision making

Investigating the neural substrates of gambling disorder using multiple neuromodulation and neuroimaging approaches

Introduction : Le trouble du jeu de hasard et d'argent (GD) est caractérisé par un comportement de jeu inadapté qui interfère avec les activités personnelles ou professionnelles. Ce trouble psychiatrique est difficile à traiter avec les thérapies actuelles et les rechutes sont fréquentes. Les symptômes dépressifs et cognitifs (e.g., l'impulsivité), ainsi que le "craving" (désir intense de jouer) sont des facteurs prédictifs de rechutes. Une meilleure compréhension des substrats neuronaux et leurs significations cliniques pourraient mener au développement de nouveaux traitements. La stimulation transcrânienne à courant direct (tDCS) pourrait être l'un de ceux-ci car elle permet de cibler des circuits neuronaux spécifiques. De plus, la tDCS ciblant le cortex dorsolatéral préfrontal (DLPFC) pourrait améliorer les symptômes dépressifs et cognitifs et réduire le craving. Cependant, les effets précis de la tDCS sur la fonction cérébrale, ainsi que leurs significations cliniques, demeurent à être élucidés. Par ailleurs, étant donné que les patients avec GD présentent souvent des différences morphométriques par rapport aux individus en santé, il est possible de faire l'hypothèse que la morphométrie cérébrale influence les effets de la tDCS. Objectifs : Ce travail avait trois objectifs principaux. Le premier objectif était d'explorer s'il y avait des associations entre les substrats neuronaux et les symptômes cliniques et cognitifs. Le deuxième objectif était d'examiner les effets de la tDCS sur la fonction cérébrale. Le troisième objectif était d'explorer si la morphométrie du site de stimulation (DLPFC) pouvait influencer les effets de la tDCS sur les substrats neuronaux. Méthode : Nous avons réalisé quatre études différentes. Dans la première étude, nous avons mesuré la morphométrie cérébrale en utilisant l'imagerie par résonance magnétique (IRM) structurelle. Nous avons mesuré les corrélations entre la morphométrie et les symptômes cliniques (dépression, sévérité et durée du GD) et cognitifs (impulsivité). De plus, nous avons comparé la morphométrie des patients à celui d'une base de données normative (individus en santé) en contrôlant pour plusieurs facteurs comme l'âge. Dans la deuxième étude, nous avons mesuré la fonction cérébrale (connectivité fonctionnelle) des patients avec l'IRM fonctionnelle. Nous avons examiné s'il y avait des liens entre la connectivité fonctionnelle et les symptômes cognitifs (impulsivité et prise de risque) et cliniques (sévérité et durée du GD). Dans la troisième étude, nous avons étudié les effets de la tDCS sur la connectivité fonctionnelle et si la morphométrie du DLPFC pouvait influencer ces effets. Dernièrement, dans la quatrième étude, nous avons examiné si la morphométrie du DLPFC pouvait influencer les effets de la tDCS sur la neurochimie (avec la spectroscopie par résonance magnétique). Résultats : Nous avons démontré deux corrélations positives entre la superficie du cortex occipital et les symptômes dépressifs (étude I). Nous avons également mis en évidence une corrélation positive entre la connectivité fonctionnelle d'un réseau occipital et l'impulsivité (étude II). De plus, il y avait une corrélation positive entre la connectivité fonctionnelle de ce réseau et la sévérité du GD. Par ailleurs, il y avait des corrélations positives entre la connectivité fonctionnelle de l'opercule frontal droit et la prise de risque (étude II). En outre, la connectivité fonctionnelle d'un réseau cérébelleux était corrélée avec les symptômes dépressifs (étude II). Les patients avaient aussi plusieurs différences morphométriques par rapport aux individus en santé (cortex occipital, préfrontal, etc.). Nous avons démontré également que la tDCS appliquée sur le DLPFC a augmenté la connectivité fonctionnelle d'un réseau fronto-pariétal (étude III). Finalement, cette thèse a montré que la morphométrie du DLPFC influence les augmentations induites par la tDCS sur la connectivité fonctionnelle du réseau fronto-pariétal (étude III) et le niveau de GABA frontal (étude IV). Conclusions : Cette thèse démontre une importance clinique potentielle pour les régions occipitales, frontales et cérébelleuses, particulièrement pour les patients ayant des symptômes dépressifs ou cognitifs. De plus, elle montre que la tDCS peut renforcer le fonctionnement d'un réseau fronto-pariétal connu pour son rôle dans les fonctions exécutives. Il reste à déterminer si un plus grand nombre de sessions pourrait apporter des bénéfices cliniques additionnels afin d'aider les patients à résister le jeu. Finalement, les résultats de cette thèse suggèrent que la morphométrie des régions sous les électrodes pourrait aider à identifier les meilleurs candidats pour la tDCS et pourrait être considéré pour la sélection des cibles de stimulation.Introduction: Gambling disorder (GD) is characterised by maladaptive gambling behaviour that interferes with personal or professional activities. This psychiatric disorder is difficult to treat with currently available treatments and relapse rates are high. Several factors can predict relapse, including depressive and cognitive (e.g., impulsivity, risk taking) symptoms, in addition to craving (strong desire to gamble). A better understanding of neural substrates and their clinical significance could help develop new treatments. Transcranial direct current stimulation (tDCS) might be one of these since it can target specific neural circuits. In addition, tDCS targeting the dorsolateral prefrontal cortex (DLPFC) could improve depressive and cognitive symptoms as well as reduce craving. However, the precise effects of tDCS on brain function, as well as their clinical significance, remain to be elucidated. Furthermore, considering that patients with GD often display morphometric differences as compared to healthy individuals, it may be worth investigating whether brain morphometry influences the effects of tDCS. Objectives: This work had three main objectives. The first objective was to explore whether there were associations between neural substrates and clinical and cognitive symptoms. The second objective was to examine the effects of tDCS on brain function. The third objective was to explore whether morphometry of the stimulation site (DLPFC) influenced the effects of tDCS on neural substrates. Methods: We carried out four different studies. In the first study, we investigated brain morphometry using structural magnetic resonance imaging (MRI). We tested for correlations between morphometry and clinical symptoms (depression, GD severity, GD duration) and cognitive symptoms (impulsivity). In addition, we compared the morphometry of patients with GD to that of a normative database (healthy individuals) while controlling for several factors such as age. In a second study, we assessed brain function (functional connectivity) in patients with functional MRI (fMRI). We examined whether there were associations between brain function and cognitive symptoms (impulsivity and risk taking) as well as clinical symptoms (GD severity and duration). In the third study, we examined tDCS-induced effects on brain function and whether morphometry of the DLPFC influenced these effects. Lastly, in the fourth study, we examined whether DLPFC morphometry influenced tDCS-induced effects on neurochemistry (using magnetic resonance spectroscopy imaging). Results: Firstly, we found two positive correlations between surface area of the occipital cortex and depressive symptoms (study I). We also showed a positive correlation between functional connectivity of an occipital network and impulsivity (study II). In addition, there was a positive correlation between functional connectivity of this network and GD severity (study II). In addition, there were positive correlations between functional connectivity of the right frontal operculum and risk-taking (study II). Also, functional connectivity of a cerebellar network was positively correlated with depressive symptoms (study II). Moreover, patients with GD had several morphometric differences as compared to healthy individuals (occipital and prefrontal cortices, etc.). Furthermore, we observed that tDCS over the DLPFC increased functional connectivity of a fronto-parietal circuit during stimulation (study III). Lastly, this thesis indicated that DLPFC morphometry influenced tDCS-induced elevations on fronto-parietal functional connectivity (study III) and frontal GABA levels (study IV). Conclusions: This thesis suggests the potential clinical relevance of occipital, frontal, and cerebellar regions, particularly for those with depressive and cognitive symptoms. It also indicates that tDCS can strengthen the functioning of a fronto-parietal network known to be implicated in executive functions. It remains to be seen whether a greater number of tDCS sessions could lead to clinical benefits to help patients resist gambling. Finally, the results of this thesis suggest that morphometry of the regions under the electrodes might help predict better candidates for tDCS and could be considered to select stimulation targets

Sensing and Signal Processing in Smart Healthcare

In the last decade, we have witnessed the rapid development of electronic technologies that are transforming our daily lives. Such technologies are often integrated with various sensors that facilitate the collection of human motion and physiological data and are equipped with wireless communication modules such as Bluetooth, radio frequency identification, and near-field communication. In smart healthcare applications, designing ergonomic and intuitive human–computer interfaces is crucial because a system that is not easy to use will create a huge obstacle to adoption and may significantly reduce the efficacy of the solution. Signal and data processing is another important consideration in smart healthcare applications because it must ensure high accuracy with a high level of confidence in order for the applications to be useful for clinicians in making diagnosis and treatment decisions. This Special Issue is a collection of 10 articles selected from a total of 26 contributions. These contributions span the areas of signal processing and smart healthcare systems mostly contributed by authors from Europe, including Italy, Spain, France, Portugal, Romania, Sweden, and Netherlands. Authors from China, Korea, Taiwan, Indonesia, and Ecuador are also included