Title :
Single-mode excitation in the shallow-water acoustic channel using feedback control
Author :
Buck, John R. ; Preisig, James C. ; Johnson, Mark ; Catipovic, Josko
Author_Institution :
Res. Lab. of Electron., MIT, Cambridge, MA, USA
fDate :
4/1/1997 12:00:00 AM
Abstract :
The shallow-water acoustic channel supports far-field propagation in a discrete set of modes. Ocean experiments have confirmed the modal nature of acoustic propagation, but no experiment has successfully excited only one of the suite of mid-frequency trapped modes propagating in a coastal environment. The ability to excite a single mode would be a powerful tool for investigating shallow-water ocean processes. A feedback control algorithm incorporating elements of adaptive estimation, underwater acoustics, array processing, and control theory to generate a high-fidelity single mode is presented. This approach also yields a cohesive framework for evaluating the feasibility of generating a single mode with given array geometries, noise characteristics, and source power limitations. Simulations and laboratory wave guide experiments indicate the proposed algorithm holds promise for ocean experiments
Keywords :
adaptive control; adaptive estimation; digital simulation; feedback; oceanographic techniques; simulation; underwater sound; acoustic propagation; adaptive control; adaptive estimation; array processing; coastal environment; control theory; far-field propagation; feedback control; feedback control algorithm; high-fidelity single mode; laboratory wave guide experiments; mid-frequency trapped modes; noise characteristics; ocean experiments; shallow-water acoustic channel; simulation; single-mode excitation; source power limitations; underwater acoustics; Acoustic propagation; Adaptive estimation; Array signal processing; Character generation; Control theory; Feedback control; Oceans; Power generation; Sea measurements; Underwater acoustics;
Journal_Title :
Oceanic Engineering, IEEE Journal of
