Themes of Work

Our research centres around the body and how technology can be used to improve how that body exists and interacts with the surrounding environment. We focus on haptic and aural modalities, using textiles as the physical medium for building wearable computational systems. Some of the research projects we undertake focus exclusively on textile sensing and interfaces whilst other focus solely on how auditory displays can be improved for users. A growing area of our work is looking towards how these two complementary technologies can be brought together in novel applications.

Below is a selection of projects grouped by theme of work:

Research Themes

Stripes of textile pressure sensors connected to conductive threads

Motion Sensing Textiles

Utilising novel textiles or electronic integrations to track and measure different forms of motion directly through fabric interventions.

Textile Haptic Actuation

Investigating next-generation haptic outputs embedded within textiles, with the unique ability to provide localised bodily sensations and tactile effects currently unavailable from other technologies.

Sustainable Approaches to E-Textiles

Utilising novel textiles or electronic integrations to track and measure different forms of motion directly through fabric interventions.

Seed Fund Summaries 2023 Virtual Audio

Controlling Audio with Textiles

Utilising novel textiles or electronic integrations to track and measure different forms of motion directly through fabric interventions.

Research Video of SensiKnit System

This work has been published in Advanced intelligent Systems - Zhou, Y. et al (2024), A Highly Durable and UV-Resistant Graphene-Based Knitted Textile Sensing Sleeve for Human Joint Angle Monitoring and Gesture Differentiation. Play video
This work has been published in Advanced intelligent Systems - Zhou, Y. et al (2024), A Highly Durable and UV-Resistant Graphene-Based Knitted Textile Sensing Sleeve for Human Joint Angle Monitoring and Gesture Differentiation.

The most developed strand of research in the group is tracking human motion through textile sensors. SensiKnit was developed by Dr Yi (Joy) Zhou during her PhD. SensiKnit is a graphene-based wearable monitoring system. The ergonomic sensors, crafted with digital knitting and laser-cutting, ensure close skin contact for accurate data collection and allow a full range of motion for user comfort. Integrated into wearables, SensiKnit can monitor body movements, such as knee bends and arm gestures, making it ideal for exercise interfaces and injury rehabilitation. Resistant to UV rays and washing, it offers consistent, real-time activity feedback under any condition.

This work has been published in Advanced intelligent Systems (Zhou, Y., Sun, Y., Li, Y., Shen, C., Lou, Z., Min, X. and Stewart, R. (2024), A Highly Durable and UV-Resistant Graphene-Based Knitted Textile Sensing Sleeve for Human Joint Angle Monitoring and Gesture Differentiation. Adv. Intell. Syst. 2400124. https://doi.org/10.1002/aisy.202400124).

The video was filmed and produced by Xiannuo Phoenix Zhao (Xcellent Productions Ltd). 

Current EU Funded Projects

SONICOM

SONICOM is a research project that aims to revolutionise the way we interact socially within augmented and virtual reality (AR/VR) environments and applications, from online meetings to VR gaming.

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STELEC

STELEC, short for Sustainable Textile ELECtronics, is an interdisciplinary research project funded by the European Innovation Council (EIC) under the Pathfinder programmes in the responsible electronics topic seeking cutting-edge innovation with an end goal at TRL 2-3. The project is a multinational collaboration of research institutes, universities and companies across Europe. It aims at developing next generation textile-based electronics in applications from sensing, processing to AI, with a commitment to full lifecycle sustainability.

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Publications

Citation

BibTex format

@article{Aziz:2022:10.1145/3531529,
author = {Aziz, N and Stockman, T and Stewart, R},
doi = {10.1145/3531529},
journal = {ACM Trans. Access. Comput.},
pages = {1--48},
title = {Planning your journey in audio: design and evaluation of auditory route overviews},
url = {http://dx.doi.org/10.1145/3531529},
volume = {15},
year = {2022}
}
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RIS format (EndNote, RefMan)

TY  - JOUR
AB  - Auditory overviews of routes can provide routing and map information to blind users enabling them to preview route maps before embarking on a journey. This paper investigates the usefulness of a system designed to do this through a Preliminary Survey, followed by a Design Study to gather the design requirements, development of a prototype and evaluation through a Usability Study. The design is drawn in 2-stages with 8 audio designers and 8 potential blind users. The auditory route overview is sequential and automatically generated as integrated audio. It comprises auditory icons to represent points of interest, earcons for auditory brackets encapsulating repeating points of interest, and speech for directions. A prototype based on this design is developed and evaluated with 22 sighted and 8 blind participants. The software architecture of the prototype including the route information retrieval and mapping onto audio has been included. The findings show that both groups perform well in route reconstruction and recognition tasks. Moreover, the functional route information and auditory icons are effectively designed and useful in forming a mental model of the route, which improves over time. However, the design of auditory brackets needs further improvement and testing. At all stages of the system development, input has been acquired from the end-user population and the design is adapted accordingly.
AU  - Aziz,N
AU  - Stockman,T
AU  - Stewart,R
DO  - 10.1145/3531529
EP  - 48
PY  - 2022///
SN  - 1936-7228
SP  - 1
TI  - Planning your journey in audio: design and evaluation of auditory route overviews
T2  - ACM Trans. Access. Comput.
UR  - http://dx.doi.org/10.1145/3531529
UR  - https://doi.org/10.1145/3531529
VL  - 15
ER  -
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