Composing DTI Visualizations with End-user Programming

TL;DR

This paper introduces Zifazah, a domain-specific language designed for end users to compose 3D DTI visualizations, emphasizing intuitive syntax, spatial relationships, and flexible data encoding based on user-centered analysis.

Contribution

It presents the design principles and implementation of Zifazah, a visualization language tailored for scientists, enabling them to create complex DTI visualizations without programming expertise.

Findings

Zifazah supports intuitive, declarative visualization scripting.

End users successfully created new DTI visualizations with Zifazah.

The language incorporates visual symbolism and spatial relationships for scientific data.

Abstract

We present the design and prototype implementation of a scientific visualization language called Zifazah for composing 3D visualizations of diffusion tensor magnetic resonance imaging (DT-MRI or DTI) data. Unlike existing tools allowing flexible customization of data visualizations that are programmer-oriented, we focus on domain scientists as end users in order to enable them to freely compose visualizations of their scientific data set. We analyzed end-user descriptions extracted from interviews with neurologists and physicians conducting clinical practices using DTI about how they would build and use DTI visualizations to collect syntax and semantics for the language design, and have discovered the elements and structure of the proposed language. Zifazah makes use of the initial set of lexical terms and semantics to provide a declarative language in the spirit of intuitive syntax and usage. This work contributes three, among others, main design principles for scientific visualization language design as well as a practice of such language for DTI visualization with Zifazah. First, Zifazah incorporated visual symbolic mapping based on color, size and shape, which is a sub-set of Bertin's taxonomy migrated to scientific visualizations. Second, Zifazah is defined as a spatial language whereby lexical representation of spatial relationship for 3D object visualization and manipulations, which is characteristic of scientific data, can be programmed. Third, built on top of Bertin's semiology, flexible data encoding specifically for scientific visualizations is integrated in our language in order to allow end users to achieve optimal visual composition at their best. Along with sample scripts representative of our language design features, some new DTI visualizations as the running results created by end users using the novel visualization language have also been presented.