Commande des robotsRobotic control is the system that contributes to the movement of robots. This involves the mechanical aspects and programmable systems that makes it possible to control robots. Robotics can be controlled by various means including manual, wireless, semi-autonomous (a mix of fully automatic and wireless control), and fully autonomous (using artificial intelligence). In the medical field, robots are used to make precise movements that are difficult for humans.
Robotique industriellevignette|droite|Un robot industriel Kawasaki FS-03N, robot de soudage La robotique industrielle est officiellement définie par l'Organisation Internationale de Normalisation (ISO) comme étant un système commandé automatiquement, multi-applicatif, reprogrammable, polyvalent, manipulateur et programmable sur trois axes ou plus. Les applications typiques incluent les robots de soudage, de peinture et d'assemblage. L'avantage de la robotique industrielle est sa rapidité d'exécution et sa précision ainsi que la répétition de cette précision dans le temps.
Finger trackingIn the field of gesture recognition and , finger tracking is a high-resolution technique developed in 1969 that is employed to know the consecutive position of the fingers of the user and hence represent objects in 3D. In addition to that, the finger tracking technique is used as a tool of the computer, acting as an external device in our computer, similar to a keyboard and a mouse. The finger tracking system is focused on user-data interaction, where the user interacts with virtual data, by handling through the fingers the volumetric of a 3D object that we want to represent.
TrackingVideo tracking is the process of locating a moving object (or multiple objects) over time using a camera. It has a variety of uses, some of which are: human-computer interaction, security and surveillance, video communication and compression, augmented reality, traffic control, medical imaging and video editing. Video tracking can be a time-consuming process due to the amount of data that is contained in video. Adding further to the complexity is the possible need to use object recognition techniques for tracking, a challenging problem in its own right.
Visual odometryIn robotics and computer vision, visual odometry is the process of determining the position and orientation of a robot by analyzing the associated camera images. It has been used in a wide variety of robotic applications, such as on the Mars Exploration Rovers. In navigation, odometry is the use of data from the movement of actuators to estimate change in position over time through devices such as rotary encoders to measure wheel rotations.
Facial motion captureFacial motion capture is the process of electronically converting the movements of a person's face into a digital database using cameras or laser scanners. This database may then be used to produce computer graphics (CG), computer animation for movies, games, or real-time avatars. Because the motion of CG characters is derived from the movements of real people, it results in a more realistic and nuanced computer character animation than if the animation were created manually.
Self-reconfiguring modular robotModular self-reconfiguring robotic systems or self-reconfigurable modular robots are autonomous kinematic machines with variable morphology. Beyond conventional actuation, sensing and control typically found in fixed-morphology robots, self-reconfiguring robots are also able to deliberately change their own shape by rearranging the connectivity of their parts, in order to adapt to new circumstances, perform new tasks, or recover from damage.
Capture de mouvementLa capture de mouvement (motion capture en anglais, parfois abrégé en mocap) est une technique permettant d'enregistrer les positions et rotations d'objets ou de membres d'êtres vivants, pour en contrôler une contrepartie virtuelle sur ordinateur (caméra, modèle 3D, ou avatar). Une restitution visuelle de ces mouvements en temps réel est faite via le moteur de rendu 3D de l'application interfacée avec le matériel utilisé qui peut les stocker dans un fichier d'animation de type BVH pour être traités ultérieurement dans un logiciel 3D classique (Maya, 3dsMax, XSI, Cinema4d, etc.
Behavior-based roboticsBehavior-based robotics (BBR) or behavioral robotics is an approach in robotics that focuses on robots that are able to exhibit complex-appearing behaviors despite little internal variable state to model its immediate environment, mostly gradually correcting its actions via sensory-motor links. Behavior-based robotics sets itself apart from traditional artificial intelligence by using biological systems as a model. Classic artificial intelligence typically uses a set of steps to solve problems, it follows a path based on internal representations of events compared to the behavior-based approach.
