A framework for adaptive e-learning for continuum mechanics and structural analysis

This paper presents a project for providing the students of Structural Engineering with the flexibility to learn outside classroom schedules. The goal is a framework for adaptive E-learning based on a repository of open educational courseware with a set of basic Structural Engineering concepts and fundamentals. These are paramount for students to expand their technical knowledge and skills in structural analysis and design of tall buildings, arch-type structures as well as bridges. Thus, concepts related to structural behaviour such as linearity, compatibility, stiffness and influence lines have traditionally been elusive for students. The objective is to facilitate the student a teachinglearning process to acquire the necessary intuitive knowledge, cognitive skills and the basis for further technological modules and professional development in this area. As a side effect, the system is expected to help the students improve their preparation for exams on the subject. In this project, a web-based open-source system for studying influence lines on continuous beams is presented. It encompasses a collection of interactive user-friendly applications accessible via Web, written in JavaScript under JQuery and Dygraph Libraries, taking advantage of their efficiency and graphic capabilities. It is performed in both Spanish and English languages. The student is enabled to set the geometric, topologic, boundary and mechanic layout of a continuous beam. While changing the loading and the support conditions, the changes in the beam response prompt on the screen, so that the effects of the several issues involved in structural analysis become apparent. This open interaction with the user allows the student to simulate and virtually infer the structural response. Different levels of complexity can be handled, whereas an ongoing help is at hand for any of them. Students can freely boost their experiential learning on this subject at their own pace, in order to further share, process, generalize and apply the relevant essential concepts of Structural Engineering analysis. Besides, this collection is being added to the "Virtual Lab of Continuum Mechanics" of the UPM, launched in 2013 (http://serviciosgate.upm.es/laboratoriosvirtuales/laboratorios/medios-continuos-en-construcci%C3%B3n)

Desarrollo de una herramienta para analizar métodos de reconocimiento de emociones

Desde hace más de 20 años, muchos grupos de investigación trabajan en el estudio de técnicas de reconocimiento automático de expresiones faciales. En los últimos años, gracias al avance de las metodologías, ha habido numerosos avances que hacen posible una rápida detección de las caras presentes en una imagen y proporcionan algoritmos de clasificación de expresiones. En este proyecto se realiza un estudio sobre el estado del arte en reconocimiento automático de emociones, para conocer los diversos métodos que existen en el análisis facial y en el reconocimiento de la emoción. Con el fin de poder comparar estos métodos y otros futuros, se implementa una herramienta modular y ampliable y que además integra un método de extracción de características que consiste en la obtención de puntos de interés en la cara y dos métodos para clasificar la expresión, uno mediante comparación de desplazamientos de los puntos faciales, y otro mediante detección de movimientos específicos llamados unidades de acción. Para el entrenamiento del sistema y la posterior evaluación del mismo, se emplean las bases de datos Cohn-Kanade+ y JAFFE, de libre acceso a la comunidad científica. Después, una evaluación de estos métodos es llevada a cabo usando diferentes parámetros, bases de datos y variando el número de emociones. Finalmente, se extraen conclusiones del trabajo y su evaluación, proponiendo las mejoras necesarias e investigación futura. ABSTRACT. Currently, many research teams focus on the study of techniques for automatic facial expression recognition. Due to the appearance of digital image processing, in recent years there have been many advances in the field of face detection, feature extraction and expression classification. In this project, a study of the state of the art on automatic emotion recognition is performed to know the different methods existing in facial feature extraction and emotion recognition. To compare these methods, a user friendly tool is implemented. Besides, a feature extraction method is developed which consists in obtaining 19 facial feature points. Those are passed to two expression classifier methods, one based on point displacements, and one based on the recognition of facial Action Units. Cohn-Kanade+ and JAFFE databases, both freely available to the scientific community, are used for system training and evaluation. Then, an evaluation of the methods is performed with different parameters, databases and varying the number of emotions. Finally, conclusions of the work and its evaluation are extracted, proposing some necessary improvements and future research.

Implementación de plug-ins para REAPER: módulo de reverberación convolutiva en tiempo real y sistema para la medición de respuestas acústicas en salas

Existen en el mercado numerosas aplicaciones para la generación de reverberación y para la medición de respuestas al impulso acústicas. Sin embargo, éstas son de precios muy elevados y/o no se permite acceder a su código y, mucho menos, distribuir de forma totalmente libre. Además, las herramientas que ofrecen para la medición de respuestas al impulso requieren de un tedioso proceso para la generación de la señal de excitación, su reproducción y grabación y, finalmente, su post-procesado. Este procedimiento puede llevar en ocasiones al usuario a cometer errores debido a la falta de conocimientos técnicos. El propósito de este proyecto es dar solución a algunos de los inconvenientes planteados. Con tal fin se llevó a cabo el desarrollo e implementación de un módulo de reverberación por convolución particionada en tiempo real, haciendo uso de software gratuito y de libre distribución. En concreto, se eligió la estación digital de trabajo (DAW. Digital Audio Worksation) REAPER de la compañía Cockos. Además de incluir las funcionalidades básicas de edición y secuenciación presentes en cualquier DAW, el programa incluye un entorno para la implementación de efectos de audio en lenguaje JS (Jesusonic), y se distribuye con licencias completamente gratuitas y sin limitaciones de uso. Complementariamente, se propone una extensión para REAPER que permite la medición de respuestas al impulso de recintos acústicos de una forma completamente automatizada y amigable para el usuario. Estas respuestas podrán ser almacenadas y posteriormente cargadas en el módulo de reverberación, permitiendo aplicar sobre nuestras pistas de audio la respuesta acústica de cualquier recinto en el que se hayan realizado medidas. La implementación del sistema de medida de respuestas se llevó a cabo empleando la herramienta ReaScript de REAPER, que permite la ejecución de pequeños scripts Python. El programa genera un Barrido Sinusoidal Logarítmico que excita el recinto acústico cuya respuesta se desea medir, grabando la misma en un archivo .wav. Este procedimiento es sencillo, intuitivo y está al alcance de cualquier usuario doméstico, ya que no requiere la utilización de sofisticado instrumental de medida. ABSTRACT. There are numerous applications in the market for the generation of reverb and measurement of acoustic impulse responses. However, they are usually very costly and closed source. In addition, the provided tools for measuring impulse responses require tedious processes for the generation and reproduction of the excitation signal, the recording of the response and its final post-processing. This procedure can sometimes drive the user to make mistakes due to the lack of technical knowledge. The purpose of this project is to solve some of the mentioned problems. To that end we developed and implemented a real-time partitioned convolution reverb module using free open source software. Specifically, the chosen software was the Cockos’ digital audio workstation (DAW) REAPER. In addition to the basic features included in any DAW, such as editing and sequencing, the program includes an environment for implementing audio effects in JS (Jesusonic) language of free distribution and features an unrestricted license. As an extension for REAPER, we propose a fully automated and user-friendly method for measuring rooms’ acoustic impulse responses. These will be stored and then loaded into the reverb module, allowing the user to apply the acoustical response of any room where measurement have been taken to any audio track. The implementation of the impulse response measurement system was done using REAPER’s ReaScript tool that allows the execution of small Python scripts. The program generates a logarithmic sine sweep that excites the room and its response is recorded in a .wav file. This procedure is simple, intuitive and it is accessible to any home user as it does not require the use of sophisticated measuring equipment.

Human-computer interaction based on visual hand-gesture recognition using volumetric spatiograms of local binary patterns

A more natural, intuitive, user-friendly, and less intrusive Human–Computer interface for controlling an application by executing hand gestures is presented. For this purpose, a robust vision-based hand-gesture recognition system has been developed, and a new database has been created to test it. The system is divided into three stages: detection, tracking, and recognition. The detection stage searches in every frame of a video sequence potential hand poses using a binary Support Vector Machine classifier and Local Binary Patterns as feature vectors. These detections are employed as input of a tracker to generate a spatio-temporal trajectory of hand poses. Finally, the recognition stage segments a spatio-temporal volume of data using the obtained trajectories, and compute a video descriptor called Volumetric Spatiograms of Local Binary Patterns (VS-LBP), which is delivered to a bank of SVM classifiers to perform the gesture recognition. The VS-LBP is a novel video descriptor that constitutes one of the most important contributions of the paper, which is able to provide much richer spatio-temporal information than other existing approaches in the state of the art with a manageable computational cost. Excellent results have been obtained outperforming other approaches of the state of the art.