This mark is automatically generated based on current and recent activity in the IV/LAB.

* The number of lab members who have logged in to our linux machines in the past 24 hours is 1.
* The number of lab members who have logged in to our linux machines this week is 1.
* The current size of the directory for our published research papers is 24249631 KB.
* The lights in the lab are on.

A Lightweight Tangible 3D Interface for Interactive Visualization of Thin Fiber Structures

Journal Article

A Lightweight Tangible 3D Interface for Interactive Visualization of Thin Fiber Structures. Bret Jackson, Tung Yuen Lau, David Schroeder, Kimani C. Toussaint Jr., Daniel F. Keefe. IEEE Transactions on Visualization and Computer Graphic (Proceedings of Scientific Visualization / Information Visualization 2013) (2013) Volume 19, Number 12

Abstract

We present a prop-based, tangible interface for 3D interactive visualization of thin fiber structures. These data are commonly found in current bioimaging datasets, for example second-harmonic generation microscopy of collagen fibers in tissue. Our approach uses commodity visualization technologies such as a depth sensing camera and low-cost 3D display. Unlike most current uses of these emerging technologies in the games and graphics communities, we employ the depth sensing camera to create a fish-tank stereoscopic virtual reality system at the scientist's desk that supports tracking of small-scale gestures with objects already found in the work space. We apply the new interface to the problem of interactive exploratory visualization of three-dimensional thin fiber data. A critical task for the visual analysis of these data is understanding patterns in fiber orientation throughout a volume.The interface enables a new, fluid style of data exploration and fiber orientation analysis by using props to provide needed passive-haptic feedback, making 3D interactions with these fiber structures more controlled. We also contribute a low-level algorithm for extracting fiber centerlines from volumetric imaging. The system was designed and evaluated with two biophotonic experts who currently use it in their lab. As compared to typical practice within their field, the new visualization system provides a more effective way to examine and understand the 3D bioimaging datasets they collect.

Video
Projects

This publication is a part of the following research projects:

Links