FPGA-based Anomalous trajectory detection using SOFM

A system for automatically classifying the trajectory of a moving object in a scene as usual or suspicious is presented. The system uses an unsupervised neural network (Self Organising Feature Map) fully implemented on a reconfigurable hardware architecture (Field Programmable Gate Array) to cluster trajectories acquired over a period, in order to detect novel ones. First order motion information, including first order moving average smoothing, is generated from the 2D image coordinates (trajectories). The classification is dynamic and achieved in real-time. The dynamic classifier is achieved using a SOFM and a probabilistic model. Experimental results show less than 15\% classification error, showing the robustness of our approach over others in literature and the speed-up over the use of conventional microprocessor as compared to the use of an off-the-shelf FPGA prototyping board

Autonomous real-time surveillance system with distributed IP cameras

An autonomous Internet Protocol (IP) camera based object tracking and behaviour identification system, capable of running in real-time on an embedded system with limited memory and processing power is presented in this paper. The main contribution of this work is the integration of processor intensive image processing algorithms on an embedded platform capable of running at real-time for monitoring the behaviour of pedestrians. The Algorithm Based Object Recognition and Tracking (ABORAT) system architecture presented here was developed on an Intel PXA270-based development board clocked at 520 MHz. The platform was connected to a commercial stationary IP-based camera in a remote monitoring station for intelligent image processing. The system is capable of detecting moving objects and their shadows in a complex environment with varying lighting intensity and moving foliage. Objects moving close to each other are also detected to extract their trajectories which are then fed into an unsupervised neural network for autonomous classification. The novel intelligent video system presented is also capable of performing simple analytic functions such as tracking and generating alerts when objects enter/leave regions or cross tripwires superimposed on live video by the operator

Research & Technology Report Goddard Space Flight Center

The main theme of this edition of the annual Research and Technology Report is Mission Operations and Data Systems. Shifting from centralized to distributed mission operations, and from human interactive operations to highly automated operations is reported. The following aspects are addressed: Mission planning and operations; TDRSS, Positioning Systems, and orbit determination; hardware and software associated with Ground System and Networks; data processing and analysis; and World Wide Web. Flight projects are described along with the achievements in space sciences and earth sciences. Spacecraft subsystems, cryogenic developments, and new tools and capabilities are also discussed

Machine Learning

Machine Learning can be defined in various ways related to a scientific domain concerned with the design and development of theoretical and implementation tools that allow building systems with some Human Like intelligent behavior. Machine learning addresses more specifically the ability to improve automatically through experience

Segmentación y detección de objetos en imágenes y vídeo mediante inteligencia computacional

Finalmente, se exponen las conclusiones obtenidas tras la realización de esta tesis y unas posibles líneas futuras de investigación. Fecha de lectura de Tesis: 17 diciembre 2018.La presente tesis trata sobre el procesamiento y análisis de imágenes y video mediante sistemas informáticos. Primeramente se hace una introducción, especificando contexto, objetivos y metodología. Luego se muestran los antecedentes, los fundamentos de la videovigilancia, las dificultades existentes y diversos algoritmos del estado del arte, seguido de las principales características del aprendizaje profundo, transporte inteligente y sistemas con cámara PTZ, finalizando con la evaluación de métodos y distintos conjuntos de datos. Después se muestran tres partes. La primera comenta los estudios desarrollados que tratan sobre segmentación. Aquí se explican diferentes modelos desarrollados cuyo objetivo es la detección de objetos, tanto usando hardware genérico o especifico como en ámbitos específicos, o un estudio de cómo influye la reducción del tamaño de las imágenes al rendimiento de los algoritmos. La segunda parte describe los trabajos que utilizan una cámara PTZ. El primero trabajo hace un seguimiento del objeto más anómalo del escenario, siendo el propio sistema el que decide cuáles son anómalos y cuáles no; el segundo muestra un sistema que indica a la cámara los movimientos a realizar en función de la salida producida por un modelo de fondo no panorámico y mejorada con un gas neuronal creciente. La tercera parte trata sobre los estudios desarrollados con relación con el transporte inteligente, como es la clasificación de los vehículos que aparecen en secuencias de tráfico. El primer trabajo aplica técnicas tradicionales como segmentación y extracción de rasgos; el segundo utiliza segmentación y redes convolucionales, complementado con un estudio del redimensionado de imágenes para proveerlas en el formato necesario a cada red; y el tercero emplea un modelo que detecta y clasifica objetos, estimando posteriormente la contaminación generada por los vehículos

FPGA-based anomalous trajectory detection using SOFM

A system for automatically classifying the trajectory of a moving object in a scene as usual or suspicious is presented. The system uses an unsupervised neural network (Self Organising Feature Map) fully implemented on a reconfigurable hardware architecture (Field Programmable Gate Array) to cluster trajectories acquired over a period, in order to detect novel ones. First order motion information, including first order moving average smoothing, is generated from the 2D image coordinates (trajectories). The classification is dynamic and achieved in real-time. The dynamic classifier is achieved using a SOFM and a probabilistic model. Experimental results show less than 15\% classification error, showing the robustness of our approach over others in literature and the speed-up over the use of conventional microprocessor as compared to the use of an off-the-shelf FPGA prototyping board