Five-channel fiber-based laser Doppler vibrometer for underwater acoustic field measurement

Jianhua Shang; Jianhua Shang; Jianhua Shang; Yang Liu; Jiatong Sun; Dae Wook Kim; Weibiao Chen; Yan He

doi:10.1364/AO.378788

Applied Optics
Vol. 59,
Issue 3,
pp. 676-682
(2020)
•https://doi.org/10.1364/AO.378788

Five-channel fiber-based laser Doppler vibrometer for underwater acoustic field measurement

Jianhua Shang, Yang Liu, Jiatong Sun, Dae Wook Kim, Weibiao Chen, and Yan He

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Jianhua Shang, Yang Liu, Jiatong Sun, Dae Wook Kim, Weibiao Chen, and Yan He, "Five-channel fiber-based laser Doppler vibrometer for underwater acoustic field measurement," Appl. Opt. 59, 676-682 (2020)

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Abstract

In this paper, a 1550 nm five-channel all-fiber homodyne laser Doppler vibrometer with high sensitivity and good signal probing probability is presented. Under the anechoic tank, standing on an airborne platform above the water surface 3 m away, the calibration experiments of the designed system are conducted. The minimum detectable sound pressure level is up to 101.73 dB re 1 µPa at 10 kHz under the hydrostatic water surface condition, and the time distribution of the final outputs are consistent with that of the underwater sound transducer. For the hydrodynamic detection capability, with the help of a 1064 nm high-pulse-energy laser whose pulse energy is 6J, pulse duration is about 8 ns, and repetition rate is 1 Hz, the system performance is tested in Qiandao Lake. And the signal probing probability of the whole sensing system is up to 59.77%.

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f/kHz	$M_{0} / d B$ re V/µPa	$U_{O C} / µ V$	$L_{S} / d B$ re V/µPa
6	−197.9	22	103.0247
10	−196.6	22	101.7247
20	−196.9	210	121.6207
50	−198.0	280	125.2194
100	−198.8	240	124.6805
150	−198.0	400	128.3175
200	−197.9	500	130.1557

	1st Channel	2nd Channel	3rd Channel	4th Channel	5th Channel
Effective detection points	14951552	30343936	33246080	10396288	58961280
Total detection points	$18368 \times 10^{4}$	$18368 \times 10^{4}$	$18368 \times 10^{4}$	$18368 \times 10^{4}$	$18368 \times 10^{4}$
Probing probability $P_{n}$	8.14%	16.52%	18.10%	5.66%	32.1%

f/kHz	$M_{0} / d B$ re V/µPa	$U_{O C} / µ V$	$L_{S} / d B$ re V/µPa
6	−197.9	22	103.0247
10	−196.6	22	101.7247
20	−196.9	210	121.6207
50	−198.0	280	125.2194
100	−198.8	240	124.6805
150	−198.0	400	128.3175
200	−197.9	500	130.1557

	1st Channel	2nd Channel	3rd Channel	4th Channel	5th Channel
Effective detection points	14951552	30343936	33246080	10396288	58961280
Total detection points	$18368 \times 10^{4}$	$18368 \times 10^{4}$	$18368 \times 10^{4}$	$18368 \times 10^{4}$	$18368 \times 10^{4}$
Probing probability $P_{n}$	8.14%	16.52%	18.10%	5.66%	32.1%

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Equations (7)

Applied Optics