- 1 TITLES:
- 2 AUTHORS (order ok?):
- 3 ABSTRACT
- 4 I. Introduction + Motivation
- 5 II. Previous Work
- 6 III. Feature-based Sound Design
- 7 IV. Results
- 8 V. Conclusion and Future Work
- 9 VI. References
- The smartest sound editor ever built
- (Feature-based Sound Design Framework/Workbench/System/null)
- (Feature-aware TAPESTREA: A Integrated/Comprehensive/Smart/Interactive Approach to Sound Design Workbench)
- (TAPESTREA: Augmenting Interactive Sound Design with Feature-based Audio Analysis)
- Interactive Content Retrieval for Intelligent/Template-aware Sound Design
- Interactive Sound Design by Example
- FAT-APE-STREAT: Sound Design by Querying
- Sound Design-by-Querying and by-Example
- Finding New Examples to Sound Design By
- Extending Sound Scene Modeling By Example with Examples
- Integrating Sound Scene Modeling and Query-by-example
- Sound Scene Modeling by Example with Integrated Audio Retrieval
- Facilitating Sound Design using Query-by-example
- Enriching/Extending/Expanding Sound Scene Modeling By Examples using Audio Information Retrieval
- Enhancing the Palette: Querying in the Service of Interactive Sound Design
- Expanding the Palette: Audio Information Retrieval for Intelligent Sound Design
- Expanding the Palette: Audio Information Retrieval for Intelligent Data-driven Sound Design
- Enhancing the Palette: Audio Information Retrieval for TAPESTREA
- Expanding the Palette: Audio Information Retrieval for Sound Scene Modeling by Example
- Enhancing the Palette: Template-based Retrieval for Intelligent Sound Design
- Enhancing the Palette: Using Audio Information Retrieval to Expand the Transformative Power of TAPESTREA
AUTHORS (order ok?):
Ananya Misra, Matt Hoffman, Perry R. Cook, Ge Wang
(no. down with order.)
We integrate music information retrieval technologies with TAPESTREA techniques to facilitate and enhance sound design, providing a new class of "intelligent" sound design workbench.
I. Introduction + Motivation
Sound designers who work with environmental or natural sounds are faced with a large selection of existing audio samples, including sound effects, field recordings, and soundtracks from movies and television, as a starting point. The TAPESTREA system [cite] facilitates the reuse of existing recordings by offering a new framework for interactively extracting desired components of sounds, transforming these individually, and flexibly resynthesizing them to create new sounds. However, the corpus of existing audio remains unstructured and largely unlabeled, making it difficult to locate desired sounds without minute knowledge of the available database. This paper explores ways to leverage audio analysis at multiple levels in interactive sound design, via TAPESTREA. It also considers methods for TAPESTREA in turn to aid audio analysis.
The main goals of this work include: (1) aiding sound designers in creating varied and interesting sound scenes by combining elements of existing sounds, and (2) enabling a human operator to quickly identify similar sounds in a large collection or database. Combined with TAPESTREA's analysis-transformation-synthesis techniques and paradigms, this presents an extended "query by example" framework, where feature-based querying can enhance both the analysis and synthesis aspects of interactive sound recomposition. The constructs discussed here can also be useful in forensic audio applications and watermarking.
- Large corpus of unstructured and largely unlabled audio
(sound effects, field recordings, soundtracks from movies and TV, etc.)
- leverage audio analysis in interactive sound design (via TAPS)
- vice versa
- To aid sound designers in creating varied and interesting scenes (standard TAPS stuff)
- To enable a human operator to quickly identify similar sounds in a large collection of sounds.
- can be also useful for forensic audio applications, watermarking */
II. Previous Work
- see references
- Marsyas, Taps (sine+noise, transient, wavelet), feature-based synthesis
- related systems generally falls into one of two categories, (1) "intelligent" audio editors,
which generally extracted musical information, or (2) sonic browsers for search and retrieval.
- Sound-scene modeling by example / Content-aware tapestrea analysis interface
- Re-composing natural sounds
III. Feature-based Sound Design
Interactive template-based similarity search (database)
quering/marking recorded sounds for template discovery
V. Conclusion and Future Work
Bregman, A. Auditory Scene Analysis. MIT Press, Cambridge, 1990.
* NOT what taps does.
Chafe, C., B. Mont-Reynaud, and L. Rush. (1982). "Towards an intelligent editor of digital audio: Recognition of musical constructs," Computer Music Journal 6(1): .
* 1st paper to deal with transcription without dealing with identifying notes
Dubnov, S., Z. Bar-Joseph, R. El-Yaniv, D. Lischinski, and M. Werman (2002). "Synthesizing sound textures through wavelet tree learning,". IEEE Computer Graphics and Applications 22(4).
Fernstrom, M. and E. Brazil. (2001)."Sonic Browsing: an auditory tool for multimedia asset management," In Proceedings of the International Conference on Auditory Display.
* deals more with musical structures and notes
Foote, J. (1999). "An overview of audio information retrieval," ACM Multimedia Systems, 7:2(10).
Jolliffe, L. (1986). Principal Component Analysis. Springer-Verlag, New York.
Kang, H. and B. Shneiderman. (2000). "Visualization Methods for Personal Photo Collections: Browsing and Searching in the PhotoFinder," In Proceedings of the International Conference on Multimedia and Expo, New York, IEEE.
Kashino, Tanaka. (1993). "A sound source separation system with the ability of automatic tone modeling," International Computer Music Conference.
* uses of clustering techniques for identifying sound sources
Misra, A., P. Cook, and G. Wang. (2006). "Musical Tapestry: Re-composing Natural Sounds," International Computer Music Conference. Submitted.
Misra, A., P. Cook, and G. Wang. (2006). "TAPESTREA: Sound Scene Modeling By Example," International Conference on Digital Audio Effects. Submitted.
Serra, X. (1989). "A System for Sound Analysis Transformation Synthesis based on a Deterministic plus Stochastic Decomposition," PhD thesis, Stanford University.
Shneiderman, B. (1998). Designing the User Interface: Strategies for Effective Human- Computer Interaction. Addison-Wesley, 3rd edition.
Tzanetakis G. and P. Cook. (2000). "MARSYAS: A Framework for Audio Analysis" Organized Sound, Cambridge University Press 4(3).
Tzanetakis, G. and P. Cook. (2001). "MARSYA3D: A prototype audio browser-editor using a large scale immersive visual and audio display," In Proceedings of the International Conference on Auditory Display.