This paper introduces a suite of Window Managers purposed for the technologically enhanced classroom. The overall objective is to instantiate a common look and feel across various classroom artifacts, thus providing a unified working environment for the students and teachers. To achieve optimal interaction and application display, the workspaces for each artifact are designed keeping in mind both the platform’s characteristics and the user’s requirements. The usability evaluation of the developed system is reported.

A frequent need of museums is to provide visitors with context-sensitive information about exhibits in the form of maps, or scale models. This paper suggests an augmented-reality approach for supplementing physical surfaces with digital information, through the use of pieces of plain paper that act as personal, location-aware, interactive screens. The technologies employed are presented, along with the interactive behavior of the system, which was instantiated and tested in the form of two prototype setups: a wooden table covered with a printed map and a glass case containing a scale model. The paper also discusses key issues stemming from experience and observations in the course of qualitative evaluation sessions.

Taking into account the potential of ICT in education and recognizing the need for smart environments and artifacts, this paper presents Study-Buddy, a context aware system aiming to augment the learning process. The system is constituted of an intelligent reading lamp that monitors students’ interaction with reading material and provides appropriate information through any near computational device (e.g., tablet, notebook, etc.). Study-Buddy is accompanied by LexiMedia, an educational software targeted to language learning.

In this paper, the design and implementation of a hardware/ software platform for parallel and distributed multiview vision processing is presented. The platform is focused at supporting the monitoring of human presence in indoor environments. Its architecture is focused at increased throughput through process pipelining as well as at reducing communication costs and hardware requirements. Using this platform, we present efficient implementations of basic visual processes such as person tracking, textured visual hull computation and head pose estimation. Using the proposed platform multiview visual operations can be combined and third-party ones integrated, to ultimately facilitate the development of interactive applications that employ visual input. Computational performance is benchmarked comparatively to state of the art and the efficacy of the approach is qualitatively assessed in the context of already developed applications related to interactive environments.

This paper discusses the opportunities and challenges of Ambient Intelligence (AmI) technologies in the context of classroom education, and presents the methodology and preliminary results of the development of an augmented school desk which integrates various AmI educational applications. The overall objective is to assess how AmI technologies can contribute to support common learning activities and enhance the learner’s experience in the classroom. Young learners were involved from the first phases of the design of the desk and its applications using scenario-based techniques.

This paper presents a system that supports the exploration of digital representations of large-scale museum artifacts in through non-instrumented, location-based interaction. The system employs a state-of-the-art computer vision system, which localizes and tracks multiple visitors. The artifact is presented in a wall-sized projection screen and it is visually annotated with text and images according to the location as well as walkthrough trajectories of the tracked visitors. The system is evaluated in terms of computational performance, localization accuracy, tracking robustness and usability.

This paper introduces booTable, an interactive coffee table prototype constructed by recycled paper aiming to build upon the paradigm of surface computing, but endeavoring to overcome a number of identified limitations of current design practice. In this respect, the paper first runs through the design requirements, decisions and rationale towards creating a first version of the prototype. Then, the outcomes of the prototyping process are described, along with the results of an informal assessment session and related critique. Following that, the revisions made towards the development of a second version of the prototype are laid out and the final result is presented.

We present the development of a multi-touch display based on computer vision techniques. The developed system is built upon low cost, off-the-shelf hardware components and a careful selection of computer vision techniques. The resulting system is capable of detecting and tracking several objects that may move freely on the surface of a wide projection screen. It also provides additional information regarding the detected and tracked objects, such as their orientation, their full contour, etc. All of the above are achieved robustly, in real time and regardless of the visual appearance of what may be independently projected on the projection screen. We also present indicative results from the exploitation of the developed system in three application scenarios and discuss directions for further research.

This paper presents the process and tangible outcomes of a rapid prototyping activity towards the creation of a demonstrator, showcasing the potential use and effect of Ambient Intelligence technologies in a typical office environment. In this context, the hardware and software components used are described, as well as the interactive behavior of the demonstrator. Additionally, some conclusions stemming from the experience gained are presented, along with pointers for future research and development work.