Augmented reality applications for cultural heritage using Kinect

AbstractThis paper explores the use of data from the Kinect sensor for performing augmented reality, with emphasis on cultural heritage applications. It is shown that the combination of depth and image correspondences from the Kinect can yield a reliable estimate of the location and pose of the camera, though noise from the depth sensor introduces an unpleasant jittering of the rendered view. Kalman filtering of the camera position was found to yield a much more stable view. Results show that the system is accurate enough for in situ augmented reality applications. Skeleton tracking using Kinect data allows the appearance of participants to be augmented, and together these facilitate the development of cultural heritage applications.</jats:p

Collaborative Augmented Reality

Over the past number of years augmented reality (AR) has become an increasingly pervasive as a consumer level technology. The principal drivers of its recent development has been the evolution of mobile and handheld devices, in conjunction with algorithms and techniques from fields such as 3D computer vision. Various commercial platforms and SDKs are now available that allow developers to quickly develop mobile AR apps requiring minimal understanding of the underlying technology. Much of the focus to date, both in the research and commercial environment, has been on single user AR applications. Just as collaborative mobile applications have a demonstrated role in the increasing popularity of mobile devices, and we believe collaborative AR systems present a compelling use-case for AR technology. The aim of this thesis is the development a mobile collaborative augmented reality framework. We identify the elements required in the design and implementation stages of collaborative AR applications. Our solution enables developers to easily create multi-user mobile AR applications in which the users can cooperatively interact with the real environment in real time. It increases the sense of collaborative spatial interaction without requiring complex infrastructure. Assuming the given low level communication and AR libraries have modular structures, the proposed approach is also modular and flexible enough to adapt to their requirements without requiring any major changes

Collaborative Augmented Reality

Over the past number of years augmented reality (AR) has become an increasingly pervasive as a consumer level technology. The principal drivers of its recent development has been the evolution of mobile and handheld devices, in conjunction with algorithms and techniques from fields such as 3D computer vision. Various commercial platforms and SDKs are now available that allow developers to quickly develop mobile AR apps requiring minimal understanding of the underlying technology. Much of the focus to date, both in the research and commercial environment, has been on single user AR applications. Just as collaborative mobile applications have a demonstrated role in the increasing popularity of mobile devices, and we believe collaborative AR systems present a compelling use-case for AR technology. The aim of this thesis is the development a mobile collaborative augmented reality framework. We identify the elements required in the design and implementation stages of collaborative AR applications. Our solution enables developers to easily create multi-user mobile AR applications in which the users can cooperatively interact with the real environment in real time. It increases the sense of collaborative spatial interaction without requiring complex infrastructure. Assuming the given low level communication and AR libraries have modular structures, the proposed approach is also modular and flexible enough to adapt to their requirements without requiring any major changes

Técnicas de coste reducido para el posicionamiento del paciente en radioterapia percutánea utilizando un sistema de imágenes ópticas

Patient positioning is an important part of radiation therapy which is one of the main solutions for the treatment of malignant tissue in the human body. Currently, the most common patient positioning methods expose healthy tissue of the patient's body to extra dangerous radiations. Other non-invasive positioning methods are either not very accurate or are very costly for an average hospital. In this thesis, we explore the possibility of developing a system comprised of affordable hardware and advanced computer vision algorithms that facilitates patient positioning. Our algorithms are based on the usage of affordable RGB-D sensors, image features, ArUco planar markers, and other geometry registration methods. Furthermore, we take advantage of consumer-level computing hardware to make our systems widely accessible. More specifically, we avoid the usage of approaches that need to take advantage of dedicated GPU hardware for general-purpose computing since they are more costly. In different publications, we explore the usage of the mentioned tools to increase the accuracy of reconstruction/localization of the patient in its pose. We also take into account the visualization of the patient's target position with respect to their current position in order to assist the person who performs patient positioning. Furthermore, we make usage of augmented reality in conjunction with a real-time 3D tracking algorithm for better interaction between the program and the operator. We also solve more fundamental problems about ArUco markers that could be used in the future to improve our systems. These include highquality multi-camera calibration and mapping using ArUco markers plus detection of these markers in event cameras which are very useful in the presence of fast camera movement. In the end, we conclude that it is possible to increase the accuracy of 3D reconstruction and localization by combining current computer vision algorithms with fiducial planar markers with RGB-D sensors. This is reflected in the low amount of error we have achieved in our experiments for patient positioning, pushing forward the state of the art for this application.En el tratamiento de tumores malignos en el cuerpo, el posicionamiento del paciente en las sesiones de radioterapia es una cuestión crucial. Actualmente, los métodos más comunes de posicionamiento del paciente exponen tejido sano del mismo a radiaciones peligrosas debido a que no es posible asegurar que la posición del paciente siempre sea la misma que la que tuvo cuando se planificó la zona a radiar. Los métodos que se usan actualmente, o no son precisos o tienen costes que los hacen inasequibles para ser usados en hospitales con financiación limitada. En esta Tesis hemos analizado la posibilidad de desarrollar un sistema compuesto por hardware de bajo coste y métodos avanzados de visión por ordenador que ayuden a que el posicionamiento del paciente sea el mismo en las diferentes sesiones de radioterapia, con respecto a su pose cuando fue se planificó la zona a radiar. La solución propuesta como resultado de la Tesis se basa en el uso de sensores RGB-D, características extraídas de la imagen, marcadores cuadrados denominados ArUco y métodos de registro de la geometría en la imagen. Además, en la solución propuesta, se aprovecha la existencia de hardware convencional de bajo coste para hacer nuestro sistema ampliamente accesible. Más específicamente, evitamos el uso de enfoques que necesitan aprovechar GPU, de mayores costes, para computación de propósito general. Se han obtenido diferentes publicaciones para conseguir el objetivo final. Las mismas describen métodos para aumentar la precisión de la reconstrucción y la localización del paciente en su pose, teniendo en cuenta la visualización de la posición ideal del paciente con respecto a su posición actual, para ayudar al profesional que realiza la colocación del paciente. También se han propuesto métodos de realidad aumentada junto con algoritmos para seguimiento 3D en tiempo real para conseguir una mejor interacción entre el sistema ideado y el profesional que debe realizar esa labor. De forma añadida, también se han propuesto soluciones para problemas fundamentales relacionados con el uso de marcadores cuadrados que han sido utilizados para conseguir el objetivo de la Tesis. Las soluciones propuestas pueden ser empleadas en el futuro para mejorar otros sistemas. Los problemas citados incluyen la calibración y el mapeo multicámara de alta calidad utilizando los marcadores y la detección de estos marcadores en cámaras de eventos, que son muy útiles en presencia de movimientos rápidos de la cámara. Al final, concluimos que es posible aumentar la precisión de la reconstrucción y localización en 3D combinando los actuales algoritmos de visión por ordenador, que usan marcadores cuadrados de referencia, con sensores RGB-D. Los resultados obtenidos con respecto al error que el sistema obtiene al reproducir el posicionamiento del paciente suponen un importante avance en el estado del arte de este tópico

Application of augmented reality and robotic technology in broadcasting: A survey

As an innovation technique, Augmented Reality (AR) has been gradually deployed in the broadcast, videography and cinematography industries. Virtual graphics generated by AR are dynamic and overlap on the surface of the environment so that the original appearance can be greatly enhanced in comparison with traditional broadcasting. In addition, AR enables broadcasters to interact with augmented virtual 3D models on a broadcasting scene in order to enhance the performance of broadcasting. Recently, advanced robotic technologies have been deployed in a camera shooting system to create a robotic cameraman so that the performance of AR broadcasting could be further improved, which is highlighted in the paper

Soccer on Your Tabletop

We present a system that transforms a monocular video of a soccer game into a moving 3D reconstruction, in which the players and field can be rendered interactively with a 3D viewer or through an Augmented Reality device. At the heart of our paper is an approach to estimate the depth map of each player, using a CNN that is trained on 3D player data extracted from soccer video games. We compare with state of the art body pose and depth estimation techniques, and show results on both synthetic ground truth benchmarks, and real YouTube soccer footage.Comment: CVPR'18. Project: http://grail.cs.washington.edu/projects/soccer