说明性时间间隔:一种基于粒子模拟的说明性可视化技术

Mathieu Le Muzic, Manuela Waldner, J. Parulek, I. Viola
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引用次数: 12

摘要

动画电影是向广大观众传达细胞生物学中复杂现象的一种流行方式。动画艺术家运用复杂的插图技术来传达一个故事,同时试图保持一个复杂的动态环境的现实表现。由于这种手工制作的动画是耗时和成本密集的创建,我们的目标是形式化的插图技术使用的艺术家,以促进从中尺度粒子为基础的分子模拟生成的可视化的自动创建。我们的技术说明时间间隔支持动态环境中复杂生化过程的视觉探索,通过(1)无缝的时间缩放来观察不同时间分辨率的现象,(2)分子轨迹的视觉抽象,以确保观察者能够在视觉上跟随主要参与者,(3)增加对感兴趣事件的视觉关注,以及(4)镜头效果来保持环境的真实表现。第一个用户研究的结果表明,轨迹的视觉抽象提高了用户跟随故事的能力,也受到了用户的赞赏。透镜效应增加了环境中分子运动的感知量,同时牺牲了单个分子的可追溯性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Illustrative Timelapse: A technique for illustrative visualization of particle-based simulations
Animated movies are a popular way to communicate complex phenomena in cell biology to the broad audience. Animation artists apply sophisticated illustration techniques to communicate a story, while trying to maintain a realistic representation of a complex dynamic environment. Since such hand-crafted animations are time-consuming and cost-intensive to create, our goal is to formalize illustration techniques used by artists to facilitate the automatic creation of visualizations generated from mesoscale particle-based molecular simulations. Our technique Illustrative Timelapse supports visual exploration of complex biochemical processes in dynamic environments by (1) seamless temporal zooming to observe phenomena in different temporal resolutions, (2) visual abstraction of molecular trajectories to ensure that observers are able to visually follow the main actors, (3) increased visual focus on events of interest, and (4) lens effects to preserve a realistic representation of the environment in the context. Results from a first user study indicate that visual abstraction of trajectories improves the ability to follow a story and is also appreciated by users. Lens effects increased the perceived amount of molecular motion in the environment while trading off traceability of individual molecules.
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