Analysing the Creative Process through a Modelling of Tools and Methods for Composition in Hans Tutschku’s Entwurzelt

The analysis of the creative processes involved in electroacoustic music may to a large extent rely on the thorough study of the technological tools used for the realisation of a musical work, both on the composition and on the performance sides. Understanding the behaviour and potential range of aesthetic results of such tools enables the musicologist to approach the studied work much beyond its final form, as presented on tape or as performed on a particular occasion: gaining knowledge on a wider technological context leads to considering the actual artistic decisions in the perspective of the potential outcomes that the composer and performer could face but not necessarily adopt. Hence, analysing an electroacoustic work on the basis of the study of its creative context, technological tools and compositional methods may constitute a useful approach to a better understanding of its related creative processes. However, the implementation of such an approach, mainly based on the hardware or software elements used during the creation of a given work, is not straightforward. First, it implies that the considered technologies are still in use and have not be come irreversibly obsolete. In this matter, new performances of a work are good opportunities for such investigations, as they often provide a technical update and require a deep understanding of the composer’s intentions. The musicologist also needs to have access to the resources, which may not be available without a direct contact with the composer. Assuming these conditions are reached,the musicological and organological studies can encounter another issue, particularly in the digital domain: the sources are not always presented under forms that are directly readable by the analyst, for instance with a specific programming language. Despite all these possible difficulties, many cases of technological tools lean themselves to an in-depth investigation, leading to relevant conclusions on some of the creative processes appearing in the field of electroacoustic music. In the context of a common session of several analytical approaches to a same electroacoustic piece, Hans Tutschku’s Entwurzelt for six singers and electronics (2012), this article focuses on the investigation and modelling of tools and methods of the compositional stage of the realisation of the work. During a performance of Entwurzelt, the electronic materials are simply triggered as events by one of the singers, without further interactivity–thus, the essential part of the research on the electroacoustic realisation aims at exploring the processes used during the compositional stage itself. As the electronics are used as an extension of the live vocal expression by the means of harmonic amplification and complex texturing, the tools for generation and processing of both symbolic representations and audio explored. Since the software tools that constitute the primary sources for our research were not directly designed to be used beyond their creative purposes, this talk presents software modelling implemented by the two authors to demonstrate the technological context in which Tutschku could compose Entwurzelt, emphasizing his creative methods and the decisions he could make upon a wider range of possible materials and processing techniques

Comment développer des outils généraux pour l’étude des instruments de musique numériques ? Un prototype en JavaScript pour l’investigation de programmes Max [How to Develop General Tools for the Study of Digital Musical Instruments? A JavaScript protoype for the investigation of Max programs]

La musicologie des pratiques électroacoustiques reposant sur des dispositifs numériques peut largement s’appuyer sur l’étude des environnements informatiques eux-mêmes. À partir d’un prototype de visualisation et de navigation de programmes Max écrit en JavaScript1, cet article interroge la possibilité et l’utilité de développer des outils permettant une investigation organologique dépassant le cadre d’une seule étude de cas

A permissive graphical patcher for supercollider synths

This article presents the first version of a permissive graphical patcher (referred to in the text as SCPGP) dedicated to fluid interconnection and control of SuperCollider Synths. With SCPGP, the user programs her/his SynthDefs normally as code in the SuperCollider environment, along with a minimal amount of additional information on these SynthDefs, and programs Patterns according to a simple SuperCollider-compliant syntax. From the execution of this SuperCollider session, the SCPGP interface allows for the definition of higher-level Units, composed of one or several SynthDefs. These Units can then be used in the graphical patcher itself, where the user can easily create graphs of Units, set their parameters, and, where applicable, assign them Buffers and Patterns. Permissiveness is a key principle of SCPGP: once SynthDefs have been successively tested as valid SuperCollider code, the user must be able to interconnect them with no limitation regarding connector properties (signal rate, number of channels) or the order of execution on the SuperCollider tree of Nodes. SCPGP offers a range of flexible patching operations, to foster a fully fluid and open-ended experimentation from a network of user-defined SuperCollider Synth

Barry Truax Riverrun (1986/2004), a case study from the TaCEM project, exploring new approaches to techniques of analysis and re-synthesis in the study of concert electroacoustic works

At last year’s EMS in Lisbon we introduced the TaCEM project (Technology and Creativity in Electroacoustic Music), a 30-month project funded by the UK’s Arts and Humanities Research Council, and demonstrated the generic TIAALS software being produced as part of this project. This year we present an update on the project, focusing particularly on the first of our case studies, Barry Truax’s Riverrun. Eight works have been selected for the project, taking into account criteria such as historical context, the nature of the synthesis techniques employed, and the aesthetics that have underpinned their realisation. Key considerations have included the accessibility of the technical resources and composing materials used in their production, and opportunities to pursue particular lines of enquiry with the composer concerned. In selecting the eight works for detailed study, a further consideration has been the extent to which the composers explored techniques that were already available at the time in ways that are unique and distinctive, or alternatively developed entirely new methods of synthesis in pursuit of their creative goals. The pioneering work of Barry Truax in terms of developing techniques of granular synthesis assign his achievements almost exclusively to the latter classification, and the composition of Riverrun (1986/2004) is a landmark achievement in this regard. Truax’s composing environment evolved from the early study of interactive real-time synthesis techniques at the Institute of Sonology, Utrecht 1971-73, exploring the possibilities of using Poisson-ordered distributions in the generation of microsound, to the emergence of entirely granular techniques at Simon Fraser University, British Columbia a decade later, culminating in the development of his program GSX designed specifically for waveform-based synthesis and first used to compose Riverrun, and its later extension, GSAMX, that extended these granular techniques to include the manipulation of previously sampled sound material. At the time of composition conventional minicomputers still lacked the capacity to generate multiple voices of granulated sound material in real time, but for Truax the acquisition in 1982 of a high speed bit slice array processor, the DMX-1000, provided the enhancedprocessing power necessary for achieving such a goal. The unique characteristics of its special hardware and associated programming environment, managed in turn via a host PDP 11/23 computer, both empowered his creative objectives and also materially shaped and influenced the ways in which they could be practically achieved. The significance of such causal relationships in the evolution of the electroacoustic music repertory has yet to be widely understood, and this study of Riverrun corroborates the importance of such a line of investigation. In this case it has been possible to carry out a detailed study of the original system, still maintained in working order by Truax, leading to a reconstruction of key elements of Riverrun using a Max-based simulation of GSX, the authenticity of the results being assessed both subjectively by means of a direct aural comparison and also measured objectively using software. Our presentation at this year’s EMS in Berlin included a demonstration of examples of the software we have developed to enable readers to engage with Riverrun interactively, both by analysing the original recordings and by using our emulation of the GSX system to be able to recreate passages of the work and manipulate the techniques employed in order to learn more about them. We also gave examples of other materials we have collected in relation to this case study, including videos of the composer himself working with the GSX system and discussing the composition of Riverrun

Introducing TaCEM and the TIAALS software.

This paper introduces the TaCEM project (Technology and Creativity in Electroacoustic Music), funded for 30 months by the Arts and Humanities Research Council in the UK, investigating the relationship between technological innovation and creative practice in electroacoustic music of the last 40 years (http://www.hud.ac.uk/research/researchcentres/tacem/). It is a collaborative project between the universities of Huddersfield and Durham in the UK and outputs from the project will include a book and freely available interactive software. This paper explains the context for the project and its goals, and discusses some of the generic software that is being developed as part of the project, intended not only for use in the project itself but also to be freely available for others to use in the study of any electroacoustic work as appropriate

From Technological Investigation and Software Emulation to Music Analysis: An integrated approach to Barry Truax's Riverrun

This paper presents an approach to studying Barry Truax’s Riverrun as it is being carried out within the TaCEM project (Technology and Creativity in Electroacoustic Music), a collaboration between the Universities of Huddersfield and Durham funded for 30 months (2012-2015) by the Arts and Humanities Research Council in the United Kingdom. This approach aims at realising an Interactive Aural Analysis with which the user can explore the creative and technological environment used by the composer to build his oeuvre, as well as navigate aurally through the results of the musicological study. It involves an important technological investigation of Truax’s GSX program for digital granular synthesis, leading to the implementation, in the Max environment, of emulation software allowing for the live recreation of each of Riverrun’s sequences, along with further tools dedicated to the musical analysis of the piece. This paper presents the technological investigation and its issues, the pieces of software for the Interactive Aural Analysis of the work, and musicological observations drawn from such an approach

TIAALS: A New Generic Set of Tools for the Interactive Aural Analysis of Electroacoustic Music

TIAALS is a development from earlier Interactive Aural Analyses. As well as playing an important role in the TaCEM project, TIAALS provides a set of generic tools that can be used by any analyst seeking a means of working interactively with the sound of a piece in creating and presenting their analyses. IAA is not a method of automated analysis by computer (although we may build some automated options into later versions); it is primarily a set of tools for an analyst to use to help in their own interactive aural investigation of works and in the presentation of their findings. It is envisaged that TIAALS will be further refined and extended in response to our own needs in relation to the TaCEM project over the next two years and in response to feedback from other users

Control del error en la optimización de forma de estructuras bidimensionales

El objetivo de este trabajo es presentar un método automático de optimización de forma de estructuras bidimensionales, cuyos resultados garanticen una cierta precisión. Se trata de conciliar del modo más eficaz las técnicas de optimización de forma y de control de la calidad de la solución del método de elementos finitos. Un ejemplo numérico es presentado con objeto de mostrar la validez del procedimiento.The goal of this paper is to present an automatic optimization procedure which ensure the validity of the final design. The main objective of this work is to find out the best, way to combine shape optimization with finite element error estimation techniques. A numierical example shows the advantages of the procedure.Peer Reviewe