Realistic simulation and animation of clouds using SkewT-LogP diagrams

Nuvens e clima são tópicos importantes em computação gráfica, nomeadamente na simulação e animação de fenómenos naturais. Tal deve-se ao facto de a simulação de fenómenos naturais−onde as nuvens estão incluídas−encontrar aplicações em filmes, jogos e simuladores de voo. Contudo, as técnicas existentes em computação gráfica apenas permitem representações de nuvens simplificadas, tornadas possíveis através de dinâmicas fictícias que imitam a realidade. O problema que este trabalho pretende abordar prende-se com a simulação de nuvens adequadas para utilização em ambientes virtuais, isto é, nuvens com dinâmica baseada em física que variam ao longo do tempo. Em meteorologia é comum usar técnicas de simulação de nuvens baseadas em leis da física, contudoossistemasatmosféricosdeprediçãonuméricasãocomputacionalmente pesados e normalmente possuem maior precisão numérica do que o necessário em computação gráfica. Neste campo, torna-se necessário direcionar e ajustar as características físicas ou contornar a realidade de modo a atingir os objetivos artísticos, sendo um fator fundamental que faz com que a computação gráfica se distinga das ciências físicas. Contudo, simulações puramente baseadas em física geram soluções de acordo com regras predefinidas e tornam-se notoriamente difíceis de controlar. De modo a enfrentar esses desafios desenvolvemos um novo método de simulação de nuvens baseado em física que possui a característica de ser computacionalmente leve e simula as propriedades dinâmicas relacionadas com a formação de nuvens. Este novo modelo evita resolver as equações físicas, ao apresentar uma solução explícita para essas equações através de diagramas termodinâmicos SkewT/LogP. O sistema incorpora dados reais de forma a simular os parâmetros necessários para a formação de nuvens. É especialmente adequado para a simulação de nuvens cumulus que se formam devido ao um processo convectivo. Esta abordagem permite não só reduzir os custos computacionais de métodos baseados em física, mas também fornece a possibilidade de controlar a forma e dinâmica de nuvens através do controlo dos níveis atmosféricos existentes no diagrama SkewT/LogP. Nestatese,abordámostambémumoutrodesafio,queestárelacionadocomasimulação de nuvens orográficas. Do nosso conhecimento, esta é a primeira tentativa de simular a formação deste tipo de nuvens. A novidade deste método reside no fato de este tipo de nuvens serem não convectivas, oque se traduz nocálculodeoutrosníveis atmosféricos. Além disso, atendendo a que este tipo de nuvens se forma sobre montanhas, é também apresentadoumalgoritmoparadeterminarainfluênciadamontanhasobreomovimento da nuvem. Em resumo, esta dissertação apresenta um conjunto de algoritmos para a modelação e simulação de nuvens cumulus e orográficas, recorrendo a diagramas termodinâmicos SkewT/LogP pela primeira vez no campo da computação gráfica.Clouds and weather are important topics in computer graphics, in particular in the simulation and animation of natural phenomena. This is so because simulation of natural phenomena−where clouds are included−find applications in movies, games and flight simulators. However, existing techniques in computer graphics only offer the simplified cloud representations, possibly with fake dynamics that mimic the reality. The problem that this work addresses is how to find realistic simulation of cloud formation and evolution, that are suitable for virtual environments, i.e., clouds with physically-based dynamics over time. It happens that techniques for cloud simulation are available within the area of meteorology, but numerical weather prediction systems based on physics laws are computationally expensive and provide more numerical accuracy than the required accuracy in computer graphics. In computer graphics, we often need to direct and adjust physical features, or even to bend the reality, to meet artistic goals, which is a key factor that makes computer graphics distinct from physical sciences. However, pure physically-based simulations evolve their solutions according to pre-set physics rules that are notoriously difficult to control. In order to face these challenges we have developed a new lightweight physically-based cloudsimulationschemethatsimulatesthedynamicpropertiesofcloudformation. This new model avoids solving the physically-based equations typically used to simulate the formation of clouds by explicitly solving these equations using SkewT/LogP thermodynamic diagrams. The system incorporates a weather model that uses real data to simulate parameters related to cloud formation. This is specially suitable to the simulation of cumulus clouds, which result from a convective process. This approach not only reduces the computational costs of previous physically-based methods, but also provides a technique to control the shape and dynamics of clouds by handling the cloud levels in SkewT/LogP diagrams. In this thesis, we have also tackled a new challenge, which is related to the simulation oforographic clouds. From ourknowledge, this isthefirstattempttosimulatethis type of cloud formation. The novelty in this method relates to the fact that these clouds are non-convective, so that different atmospheric levels have to be determined. Moreover, since orographic clouds form over mountains, we have also to determine the mountain influence in the cloud motion. In summary, this thesis presents a set of algorithms for the modelling and simulation of cumulus and orographic clouds, taking advantage of the SkewT/LogP diagrams for the first time in the field of computer graphics

Educational Technology and Related Education Conferences for June to December 2015

The 33rd edition of the conference list covers selected events that primarily focus on the use of technology in educational settings and on teaching, learning, and educational administration. Only listings until December 2015 are complete as dates, locations, or Internet addresses (URLs) were not available for a number of events held from January 2016 onward. In order to protect the privacy of individuals, only URLs are used in the listing as this enables readers of the list to obtain event information without submitting their e-mail addresses to anyone. A significant challenge during the assembly of this list is incomplete or conflicting information on websites and the lack of a link between conference websites from one year to the next

Agora : unified framework for crowd simulation research

Crowd simulation focuses on modeling the movements and behaviors of large groups of people. This area of study has become increasingly important because of its several applications in various fields such as urban planning, safety, and entertainment. In each of these domains, the presence of virtual agents exhibiting realistic behavior greatly enhances the quality of the simulations. However, the inherently multifaceted and intricate nature of human behavior presents a unique challenge, necessitating the effective combination of multiple behavior models. This thesis introduces a novel theoretical framework for modeling human behavior in crowd simulations, addressing the unresolved issue of combining a plethora of behavior models, often developed in isolation. The proposed framework decomposes human behavior into fundamental driving stimuli, which are then represented graphically through the heatmap paradigm. Subsequently, the agent behavior is influenced by the heatmaps, which guide them toward attractive areas and steer them away from repulsive locations based on the encoded stimuli. A key advantage of this approach lies in the ability to combine heatmaps using well-defined color operations, effectively integrating different aspects of human behavior. Furthermore, the heatmap paradigm facilitates objective comparison of simulation output with real-world data, employing image similarity metrics to evaluate model accuracy. To realize this framework, the thesis presents a modular software architecture designed to support various tasks involved in crowd simulation, emphasizing the separation of concerns for each task. This architecture comprises a collection of abstract modules, which are subsequently implemented using appropriate software components to realize the underlying features, resulting in the Agora framework. To assess the ability of Agora to support the various tasks involved in crowd simulation, two case studies are implemented and analyzed. The first case study simulates tourists visiting Þingvellir national park in Iceland, examining how their behavior is influenced by the visibility of the surrounding environment. The second case study employs Agora to model the thermal and density comfort levels of virtual pedestrians in an urban setting. The results demonstrate that Agora successfully supports the development, combination, and evaluation of crowd simulation models against real-world data. The authoring process, assisted by Agora, is significantly more streamlined compared to its native counterpart. The integration of multiple models is achieved by combining the heatmaps, resulting in plausible behavior, and the model assessment is made convenient through the evaluator within the framework. The thesis concludes by discussing the implications of these findings for the field of crowd simulation, highlighting the contributions and potential future directions of the Agora framework.Mannfjöldahermun fæst við gerð líkana af hreyfingu og hegðun stórra hópa af fólki. Mikilvægi þessa rannsóknasviðs hefur vaxið stöðugt vegna hagnýtingar á margvíslegum vetvangi, eins og til dæmis á vetvangi borgarskipulags, öryggis og afþreyingar. Þegar sýndarmenni hegða sér á sannfærandi hátt, leiðir það til betri hermunar fyrir þessi notkunarsvið. En mannleg hegðun er í eðli sínu margbrotin og flókin og því er það sérstök áskorun við smíði sýndarmenna að sameina, með áhrifaríkum hætti, mörg mismunandi hegðunarlíkön. Þessi ritgerð kynnir nýja fræðilega umgjörð líkanasmíði mannlegrar hegðunar fyrir mannfjöldahermun, sem tekur á þeim óleysta vanda að sameina fjölda hegðunarlíkana, sem oft eru þróuð með aðskildum hætti. Umgjörðin brýtur mannlega hegðun niður í grundvallar drifáreiti, sem eru sett fram grafískt útfrá hugmyndafræði hitakorta. Sýndarmennin hegða sér síðan undir áhrifum frá hitakortunum, sem vísa þeim í áttina að aðlaðandi svæðum og stýra þeim burt frá fráhrindandi svæðum, útfrá hinu umritaða áreiti. Lykilkostur þessarar nálgunar er sá eiginleiki að geta blandað saman hitakortum með vel skilgreindum litaaðgerðum, sem eru þá í raun samþætting mismunandi hliða mannlegrar hegðunar. Hitakortshugmyndafræðin auðveldar ennfremur hlutlægan samanburð hermunarúttaks og raungagna með notkun myndsamanburðarmælinga, til að meta nákvæmni líkana. Varðandi útfærslu, þá kynnir þessi ritgerð einingadrifna hugbúnaðarhögun sem er hönnuð til að styðja við ýmsa ferla mannfjöldahermunar, með áherslu á aðskilnað helstu viðfangsefna hvers ferlis. Þessi högun inniheldur safn huglægra eininga, sem síðan eru útfærðar með viðeigandi hugbúnaðarhlutum, sem raungera undirliggjandi eiginleika. Útkoman er sjálf Agora umbjörðin. Tvö sýnidæmi eru útfærð og greind til að meta getu Agoru til að styðja við ýmis mannfjöldahermunarverkefni. Fyrra dæmið hermir eftir ferðamönnum sem heimsækja Þingvallaþjóðgarð, og skoðar hvernig hegðun þeirra verður fyrir áhrifum sýnileika umhverfisins sem umleikur þá. Seinna dæmið nýtir Agoru til að smíða líkan af hitauppstreymis- og þéttleikaþægindum hjá sýndarvegfarendum í borgarumhverfi. Niðurstöðurnar sýna góðan árangur Agoru við að styðja þróun, samþættingu og mat mannfjöldahermunarlíkana gagnvart raungögnum. Þróunarferlið er verulega þjálla með Agoru en með hefðbundnum aðferðum. Samþætting margra líkana tókst með blöndun hitakorta, möguleg hegðun var framkölluð og mat á líkönunum varð þægilegra með umgjörðinni. Ritgerðinni lýkur með því að fjalla um áhrif þessara niðurstaðna á svið mannfjöldahegðunar, með áherslu á nýstálegt framlag þessarar rannsóknar og mögulega framtíðarþróun Agora umgjarðarinnar

Effizienz und Ergonomie von Multitouch-Interaktion : Studien und Prototypen zur Bewertung und Optimierung zentraler Interaktionstechniken

Die vorliegende Arbeit beschäftigt sich mit Grundfragen der Effektivität, Effizienz und Zufriedenheit von Multitouch-Interaktionen. Mithilfe einer Multitouch-Steuerung für 3D-Animation konnte gezeigt werden, dass selbst unerfahrene Multitouch-Nutzer in der Lage sind, hoch komplexe Aufgaben koordiniert und effizient zu lösen. Ein neu entwickeltes Koordinationsmaß bestätigt, dass Nutzer den Vorteil eines Multitouch nutzen, indem sie koordiniert mehrere Finger gleichzeitig für 3D-Animationen in Echtzeit einsetzen. In drei weiteren Studien zu zentralen Multitouch-Interaktionstechniken konnte gezeigt werden, dass die Originalformulierung von Fitts’ Gesetz nicht ausreicht, um die Effizienz von Multitouch-Interaktionen adäquat zu bewerten und zu analysieren. Fitts’ Gesetz ist ein Modell zur Vorhersage und Analyse von Interaktionszeiten und beinhaltet ursprünglich nur die Distanz der Interaktionsbewegung und die Zielgröße. Diese Arbeit zeigt, dass Vorhersagen mit Fitts’ Gesetz bessere Ergebnisse liefern, wenn sie neben diesen beiden Faktoren auch Bewegungsrichtung, Startpunkt der Bewegung und Neigung des Multitouch-Display berücksichtigen. Die Ergebnisse dieser Arbeitliefern Anhaltspunkte, um effiziente und benutzerfreundliche Interaktionstechniken zu entwickeln. Zudem könnten sie eingesetzt werden, um Analysen von Intertaktionstechniken für Multitouch teilautomatisch durchzuführen.This thesis deals with fundamental questions of efficiency, effectiveness and satisfaction of multitouch interactions. Using a novel multitouch interface for 3D animation it could be shown that even inexperienced multitouch users are capable of solving highly complex tasks in a coordinated and efficient way. A newly developed measure for coordination confirms that users take advantage of multitouch by using several fingers simultaneously to create a 3D real-time animation. In three additional studies on central interaction techniques for multitouch it was shown that the original Fitts’ law is not sufficient to adequately describe and analyse the efficiency of multitouch interactions. Fitts’ law is a model for the prediction and analysis of interaction time which originally only takes into account the distance of interaction movements and the target size. This work shows that predictions based on Fitts’ law provide better results when, in addition to these two factors, the direction of the movement, the starting point and the tilt of the display are considered, as well. The present results provide approaches to developing efficient interaction techniques with high usability. Furthermore, they can be used to conduct a semi-automatic analysis of interaction techniques for multitouch

Effizienz und Ergonomie von Multitouch-Interaktion : Studien und Prototypen zur Bewertung und Optimierung zentraler Interaktionstechniken

Die vorliegende Arbeit beschäftigt sich mit Grundfragen der Effektivität, Effizienz und Zufriedenheit von Multitouch-Interaktionen. Mithilfe einer Multitouch-Steuerung für 3D-Animation konnte gezeigt werden, dass selbst unerfahrene Multitouch-Nutzer in der Lage sind, hoch komplexe Aufgaben koordiniert und effizient zu lösen. Ein neu entwickeltes Koordinationsmaß bestätigt, dass Nutzer den Vorteil eines Multitouch nutzen, indem sie koordiniert mehrere Finger gleichzeitig für 3D-Animationen in Echtzeit einsetzen. In drei weiteren Studien zu zentralen Multitouch-Interaktionstechniken konnte gezeigt werden, dass die Originalformulierung von Fitts’ Gesetz nicht ausreicht, um die Effizienz von Multitouch-Interaktionen adäquat zu bewerten und zu analysieren. Fitts’ Gesetz ist ein Modell zur Vorhersage und Analyse von Interaktionszeiten und beinhaltet ursprünglich nur die Distanz der Interaktionsbewegung und die Zielgröße. Diese Arbeit zeigt, dass Vorhersagen mit Fitts’ Gesetz bessere Ergebnisse liefern, wenn sie neben diesen beiden Faktoren auch Bewegungsrichtung, Startpunkt der Bewegung und Neigung des Multitouch-Display berücksichtigen. Die Ergebnisse dieser Arbeitliefern Anhaltspunkte, um effiziente und benutzerfreundliche Interaktionstechniken zu entwickeln. Zudem könnten sie eingesetzt werden, um Analysen von Intertaktionstechniken für Multitouch teilautomatisch durchzuführen.This thesis deals with fundamental questions of efficiency, effectiveness and satisfaction of multitouch interactions. Using a novel multitouch interface for 3D animation it could be shown that even inexperienced multitouch users are capable of solving highly complex tasks in a coordinated and efficient way. A newly developed measure for coordination confirms that users take advantage of multitouch by using several fingers simultaneously to create a 3D real-time animation. In three additional studies on central interaction techniques for multitouch it was shown that the original Fitts’ law is not sufficient to adequately describe and analyse the efficiency of multitouch interactions. Fitts’ law is a model for the prediction and analysis of interaction time which originally only takes into account the distance of interaction movements and the target size. This work shows that predictions based on Fitts’ law provide better results when, in addition to these two factors, the direction of the movement, the starting point and the tilt of the display are considered, as well. The present results provide approaches to developing efficient interaction techniques with high usability. Furthermore, they can be used to conduct a semi-automatic analysis of interaction techniques for multitouch