F. Blackmon scite author profile

Generating underwater acoustic signals from a remote, aerial location by use of a high-energy pulsed infrared laser has been demonstrated. The laser beam is directed from the air and focused onto the water surface, where the optical energy was converted into a propagating acoustic wave. Sound pressure levels of 185 dB re microPa (decibel re microPa) were consistently recorded under freshwater laboratory conditions at laser-pulse repetition rates of up to 1000 pulses/s. The nonlinear optoacoustic transmission concept is outlined, and the experimental results from investigation of the time-domain and frequency-domain characteristics of the generated underwater sound are provided. A high repetition rate, high-energy per pulse laser was used in this test under freshwater laboratory conditions. A means of deterministically controlling the spectrum of the underwater acoustic signal was investigated and demonstrated by varying the laser-pulse repetition rate.

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Performance comparison of RAKE and hypothesis feedback direct sequence spread spectrum techniques for underwater communication applications

Blackmon

Sozer

Stojanovic

et al.

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Experimental Detection and Reception Performance for Uplink Underwater Acoustic Communication Using a Remote, In-Air, Acousto-Optic Sensor

Blackmon

Antonelli

2006

IEEE J. Oceanic Eng.

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F. Blackmon

Iterative equalization and decoding techniques for shallow water acoustic channels

Linear optoacoustic underwater communication

Performance comparison of RAKE and hypothesis feedback direct sequence spread spectrum techniques for underwater communication applications

Experimental Detection and Reception Performance for Uplink Underwater Acoustic Communication Using a Remote, In-Air, Acousto-Optic Sensor

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