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The authors present a new inverse, interactive approach to acoustic design that applies optimization techniques to an acoustic simulation system. For a new building, the system may suggest optimal configurations that would not otherwise be considered; for a hall with modifiable components or for a renovation project, it may assist in optimizing an existing configuration. Our system allows the designer to constrain changes to the environment and specify acoustic performance goals as a function of time. The constraints include the specification of a range of allowable materials as well as geometric modifications for surfaces in the hall. The designer also specifies goals for acoustic performance in space and time via high-level acoustic qualities such as decay time and sound level. Using this information, the system performs a constrained optimization of surface material and geometric parameters for a subset of elements in the environment. The system operates at varying accuracy levels, offering trade-offs between time and quality. Visualization tools facilitate an intuitive assessment of the complex time-dependent nature of sound, and they provide a means to express desired performance. By using optimization routines within an interactive application, our system reveals complex acoustic properties and steers the design process toward the designer's goals.
Monks et al. (Sat,) studied this question.