User-Study and Dataset - Exploring Dynamic Vibrotactile Feedback for Layer-based Interaction on Elastic Displays

Müller, Mathias

User-Study and Dataset - Exploring Dynamic Vibrotactile Feedback for Layer-based Interaction on Elastic Displays

datacite.FundingReference.funderName datacite.FundingReference.funderName	Europäische Union
Contributing person datacite.contributor.ProjectLeader	Kammer, Dietrich (orcid: 0000-0002-3822-6043)
Contributing person datacite.contributor.Researcher	Ramian, Alexander
Contributing person datacite.contributor.WorkPackageLeader	Freitag, Georg
Contributing person datacite.contributor.WorkPackageLeader	Wittchen, Dennis
Documentation of the data datacite.description.TechnicalInfo	Resource Type: - tracking data of user study on elastic display - SPSS stats files - 3D models of actuator enclosures for 3D-printing - Jupyter notebooks for data analysis Data Acquisition: laboratory study with elastic display incl. observation protocols Data Processing: 1. Jupyter notebooks for data exploration, data wrangling 2. SPSS for statistical analysis
References to related material datacite.relatedItem.IsSupplementTo	10.1145/3603555.3608534
Description of the data datacite.resourceType	Investigating Usability and User Experience of Layer-based Interaction with a Deformable Elastic Display(IUUELIDED) Description: Elastic displays afford a natural stacking of information layers in their haptic interaction space. So far, research has focused on technical issues and interaction concepts by pushing and pulling the surface of such displays. We report a study with 24 participants that investigates the feasibility and limitations of interaction with 6 to 21 layers. We measured completion times and error rates for reaching and holding specific target layers and observed performed gestures. Our findings show that solution time increases with more layers while precision is maintained with a mean success rate of holding a layer of 70 %, even when using up to 21 layers. User experience measurements show that hedonic qualities of the interaction were rated higher than pragmatic qualities. Our investigation proves the general feasibility of using layer-based interaction with an elastic display and provides guidelines on the limitations.
Type of the data datacite.resourceTypeGeneral	Text
Type of the data datacite.resourceTypeGeneral	Dataset
Type of the data datacite.resourceTypeGeneral	Model
Type of the data datacite.resourceTypeGeneral	Software
Type of the data datacite.resourceTypeGeneral	Other
Total size of the dataset datacite.size	312038255
Author dc.contributor.author	Müller, Mathias
Upload date dc.date.accessioned	2024-04-19T13:47:31Z
Publication date dc.date.available	2024-04-19T13:47:31Z
Publication date dc.date.available	2026-06-12T12:50:22Z
Data of data creation dc.date.created	2023
Publication date dc.date.issued	2024-04-19
Abstract of the dataset dc.description.abstract	Study data, analysis and supplemental material for short paper "Exploring Dynamic Vibrotactile Feedback for Layer-based Interaction on Elastic Displays" published at Mensch und Computer 2023 - DOI: 10.1145/3603555.3608534
Public reference to this page dc.identifier.uri	https://opara.zih.tu-dresden.de/handle/123456789/2715
Public reference to this page dc.identifier.uri	https://doi.org/10.25532/OPARA-295
dc.language dc.language	eng
Publisher dc.publisher	Hochschule für Technik und Wirtschaft Dresden
Licence dc.rights	CC0 1.0 Universal	en
URI of the licence text dc.rights.uri	http://creativecommons.org/publicdomain/zero/1.0/
Specification of the discipline(s) dc.subject.classification	4::44::409
Title of the dataset dc.title	User-Study and Dataset - Exploring Dynamic Vibrotactile Feedback for Layer-based Interaction on Elastic Displays
Research instruments opara.descriptionInstrument	Azure Kinect DK
Underlying research object opara.descriptionObject.People	performance data (2.5D tracking system)
Software opara.descriptionSoftware.ResourceProduction	Reflex Framework (Version 0.9.8)
Project abstract opara.project.description	Shape-changing interfaces are a type of user interface in human-computer interaction that can physically transform or change their form to convey information, provide feedback, or enhance user interaction. These interfaces use physical changes, such as altering their shape, texture, or tangible properties, to communicate information and create more intuitive and engaging interactions between humans and computers. We are researching this topic at the University of Applied Sciences in Dresden at the Chair of Visual Engineering (Professur für Technische Visualistik). Shape-changing displays represent an exciting area of research with numerous potential applications across various domains. By integrating advanced materials, mechanics, and electronics, these innovative systems have the potential to transform our interactions with information and technology, paving the way for new forms of expression, communication, and user experience. As this field continues to evolve, we can expect to see even more sophisticated and versatile shape-changing displays that push the boundaries of what is possible in display technologies.
Project title opara.project.title	Shape-changing Interfaces (SCI)

Files

Original bundle

Now showing 1 - 6 of 6

Name:: code.zip
Size:: 2.76 MB
Format:
Description:: jupyter notebooks for cleaning/converting data, plots, descriptive statistics

Download

Name:: data.zip
Size:: 278.78 MB
Format:
Description:: raw study data

Download

Name:: export.zip
Size:: 12.39 MB
Format:
Description:: data generated by jupyter notebooks (large files / images are excluded from source control)

Download