An Architecture for Spatial Audio Servers                             

David A. Burgess and Jouke C. Verlinden            
Graphics, Visualization, and Usability Center        
Georgia Institute of Technology              


ABSTRACT
Before spatial sound can be useful in large software systems,
there must be a suficient application programing 
resources. Researchers are using virtual environments 
requirements of such an interface.



REFERENCES
1.  Birrell, A.D., Nelson, B.J. (1984) Implementing
remote procedure calls, ACM Transactions on
Computer Systems, Vol. 2, No. 1, Feb. 1984, pp.
39-59.
2.  Blauert, J. (1983)Spatial Hearing: The Psychophysics
of Human Sound Localization, MIT Press: Cambridge, MA.
3.  Borish, J. (1984) Extension of the image method to
arbitrary polyhedra, J. Acoust. Soc. Am., 75, 1827-
1836.
4.  Burgess, D.A. (1992) Techniques for low cost spatial 
audio, Proceedings of the Fifth Annual Symposium
on User Interface Software and Technology
(UIST 92), ACM, New York, 1992, pp. 53-59.
5.  Liang, J., Shaw, C., Green, M., (1991) On temporal
spatial realism in the virtual reality environment,
Proceedings of the Fourth Annual Symposium on
User Interface SOftware and Technology (UIST
91), ACM, New York, 1991, pp.19-26.
6.  Postel, J. (1980) User datagram protocol, RFC 768,
Network Information Center, SRI International,
Menlo Park, Calif., August 1980.
7.  Verlinden, J.C., Kessler, A., Hodges, L.F. (1993)
The Simple Virtual Environment (SVE) Library:
Users Guide, Tech Report GIT-GVU-93-24.
8.  Wenzel, E.M. (1992) Localization in virtual acoustic
displays, Presence, 1, 80-107.