Long-range, underwater, acoustic systems require low frequency signals covering a broad frequency band. We have exploited a novel approach, using a narrowband medium-output high-efficiency resonator, which transmits a frequency sweep by mechanically tuning a resonator to match the frequency and phase of the reference signal. The design begins with a symmetrical pressure balanced Tonpilz driver consisting of two pistons separated by preloaded ceramic stacks. The driver is placed between two coaxially mounted resonator tubes. This is a simple, efficient, narrow-band projector, which operates at any ocean depth. The resonant tubes have slots (or vents) progressively covered or uncovered by sliding coaxial sleeves over them. The frequency is varied by the sleeve position. A computer-controlled, electro-mechanical actuator moves the sleeves along the resonator tubes keeping the projector in resonance at the instantaneous frequency of a swept frequency modulated signal. The projector prototype was first tested at the Woods Hole Oceanographic Institution (WHOI) dock in Woods Hole, MA, and later in the Pacific Ocean during a voyage of the research vessel "PT SUR", November 2001.
[1]
G. W. McMahon.
Performance of Open Ferroelectric Ceramic Cylinders in Underwater Transducers
,
1964
.
[2]
J. Ellis,et al.
An Efficient Sound Source for Wide-Area RAFOS Navigation
,
1993
.
[3]
Carl Wunsch,et al.
Ocean acoustic tomography: a scheme for large scale monitoring
,
1979
.
[4]
Timothy F. Duda.
Analysis of finite-duration wide-band frequency sweep signals for ocean tomography
,
1993
.
[5]
J. N. Decarpigny,et al.
The design of low frequency underwater acoustic projectors: present status and future trends
,
1991
.
[6]
Ralph S. Woollett,et al.
Basic problems caused by depth and size constraints in low‐frequency underwater transducers
,
1979
.