Biofeedback, Sound and Performance

Text by Victoria Gray

Form and Context

The question of context is at the foreground in this stage of the project. It became interesting to explore the uses of sEMG in its original context, that being the medical field. This would enable greater understanding of the need for the emergence of this technology.

Previously, sEMG has only been available as expensive medical grade equipment, therefore an initial meeting with Glyn Blackett at the clinic Biofeedback in York at York Science Park enabled expert advice on the uses of sEMG in health contexts. In a medical framework, biofeedback in general can aid development of an integrated mind-body awareness enabling a patient or client to obtain greater somatic intelligence. By monitoring changes in bodily responses (this can include muscle rate, heart rate and cardiovascular activity) biofeedback sensors feed data to a computer which is represented as interpretable data for the patient/client – usually as a visual graph or a sound trigger. Here, a feedback loop occurs between the body and the data. In this case, the technology is particularly useful for people with anxiety and is an excellent ‘self-help’ method since it can bring an awareness to the relationship between bodily tension (muscular) and mental health. However, the obvious limitations are that it is a highly expensive technology. Therefore, patients or clients, most commonly access the technology via a medical provider or an independent clinic with home-use being less common. This points to the efficacy of MyoLink as an affordable, portable and wireless piece of technology.

In an initial research consultation, Glyn Blackett kindly facilitated a 1 hour session in biofeedback so as to experience what the technology can do in an embodied way. This included a discussion of the various visual and audio representations that are used to map data and the bespoke software that Glyn himself had developed for use in his own clinic. This aspect was most relevant since it is the interactive software that we will be developing in this project. It was interesting to note that Glyn had developed his own software, indicating that existing software’s would be amenable and adaptable by Oliver and myself. Through a colleague at The University of York, Music Research Centre, we also learned that artists were already developing their own softwares for uses in art contexts, such as Marco Donnarumma (although not necessarily sEMG and in specific music contexts). Donnarumma’s Xth Sense Digital Interface, Trixtone~ and C::NTR::L are freely downloadable examples of software developments.

This session raised a number of questions that needed to be addressed. Whilst interested in the health benefits, our project does not intend to situate itself within a pedagogic or therapeutic context. Also, after seeing and hearing my muscles as data in this session, there were important aesthetic questions to be asked, such as; What sound do we want the muscles to make? Why do we want to render this particular quality of sound? Do we want the sensors and computer to be visible in the performance context or is this an aesthetic distraction? How will the sound be installed in space? If we want continuous sound can this be achieved using MyoLink? What is the battery life of the sensors if used in a durational performance of up to nine hours (for example)?

These questions would require going back to Alex at Somaxis to ask for clarification on the technical specifications of MyoLink and its software.

Text by Victoria Gray

How can movement become sound?

To answer this question, myself, Victoria Gray, a visual artist specializing in video and performance, and, Oliver Larkin, a musician and software programmer, have embarked on a collaborative initiative. This initiative develops our mutual interest in experimental sound practices by using sEMG (Surface Electromyography) sensors. sEMG sensors measure human bio-dynamics, specifically, the electrical activity produced by muscles in the body when active.

We are developing our project using MyoLink sensors. MyoLink is an innovative, wearable and wireless bio-sensor that is affordable on the open market. The sensor was developed by Alex Grey (BsC Molecular Biology) and produced by Somaxis, Palo Alto, California, USA, of which Grey is co-founder, system designer, algorithm designer, and patent author of the technology.

Through MyoLink technology the intention is to create environments and soundscapes which are sonic representations of physiological movements that occur during my body in performance. In order to do this, Oliver (BA Hons Sonic Arts), who is Research Support Programmer at The University of York, Department of Music, Music Research Centre, and myself, will begin the first phase of developing a brand-new software. This software will process the raw data coming from the MyoLink sensor when attached to my muscles. Due to Somaxis’s software being developed for the digital health market with a training analysis purpose, it is necessary for myself and Oliver to re-develop the software anew so that it is compatible for use in art contexts.

It is clear that this contextual difference has both a technological and aesthetic impact on the project. In June 2013 I was privileged to visit Somaxis in Palo Alto to experiment with the early pre-beta kit models of the MyoLink sensor and software. During this preliminary visit I met with Alex to interact with the sensor and the software firsthand. Whilst there I also participated in the Quantified Self, Bay Area Meet Up Groups whereby like-minded technologists came together to trial and discuss the potentials and limitations of the sensors in a variety of contexts. The technology would then be tested in these contexts via a broad range of users (pre-release beta-testers) of which I became one.

Reflecting on this with Oliver in the UK, it became clear to that our uses were not market driven. Therefore, our technical needs were very different to that of the initial spec for the sensor. For example, Somaxis developed MyoLink to quantify and objectively measure changes in musculature and physical performance in order to analyse improvements. In our use case, we are not interested in the ‘objective’ and ‘quantitive’ data as ‘evidence’ but rather, we want to foreground the ‘subjective’ and ‘qualitative’ aesthetic properties of the sensor. Particularly, the ability to render bodily movement (‘data’) as sound. It became very clear that as artists, this project has very clear conceptual, aesthetic and somaesthetic concerns which work in productive tension with the original intended uses of MyoLink. We also conceive that our uses in an art context might help develop the sensor in ways which Somaxis had not yet considered, but which would be beneficial to their product.

* I would like to acknowledge the advice of Jiajun Yang, PhD Researcher at Audio Lab, Electronics Department, University of York, for directing me to Somaxis.