RU2106072C1 - Two-ring fiber-optical hydrophone - Google Patents

Abstract

FIELD: underwater acoustics. SUBSTANCE: invention can be used to measure parameters of noise radiation of underwater and surface sources of sound in natural water basins and underwater acoustic ponds. In proposed two-ring fiber-optical hydrophone signal coil is partially overlapped by mobile acoustic screen which makes it possible to vary sensitivity of hydrophone depending on level of sound pressure of input signal. Special electron system changes sensitivity of two-ring fiber-optical hydrophone in such way that level of input action always remains within dynamic range of hydrophone. EFFECT: enhanced operational characteristics. 5 cl, 5 dwg

Description

 The invention relates to the field of hydroacoustics and can be used to measure noise parameters of underwater and surface sound sources in natural reservoirs and hydroacoustic pools.

 Currently, based on single-mode ring fiber-optic interferometers, schemes have been implemented that can be used in fiber-optic sensors, in particular in hydrophones [1]. Of particular interest in hydroacoustics are double-ring fiber-optic interferometers, which, in comparison with traditionally used Zender interferometers Mach [1] make it possible to increase the sensitivity of the hydrophone due to the multiple passage of radiation in the signal ring.

 Although such multi-beam fiber-optic interferometers are also known [2] (Fabry-Perot interferometers), double-ring multi-beam interferometers allow the detection of signals by a two-beam scheme, observing the interference of waves that have passed the same optical path through the first and second rings. And, in addition, they allow the use of radiation sources with a short coherence length.

As a prototype adopted double-ring fiber-optic interferometer (resonator), which can be used as a hydrophone [3]
The prototype contains a coherent light source and a photodetector, optically matched through a segment of a single-mode fiber, as well as a signal and reference ring fiber coils that are optically coupled through a 3x3 line coupler with a single-mode fiber, and a high-pass filter, an amplifier, and a recorder connected in series.

The disadvantage of the prototype is the narrow operating range of the hydrophone, implemented on the basis of a multipath interferometer, which, as you know, does not exceed λ / 300, where l / wavelength of the source of coherent radiation [4]
A prototype can measure either high levels of sound pressure if the lengths of the optical fibers in the fiber coils are small, or low if the lengths of the fibers in them are significant.

 The technical effect obtained from the implementation of the invention is the creation of a hydrophone of variable sensitivity due to the possibility of changing the length of the fiber in the signal fiber coil, interacting with the recorded acoustic wave.

 This technical result is achieved due to the fact that the known double-ring fiber-optic hydrophone (DVOG), containing a coherent light source and a photodetector, optically matched through a segment of a single-mode fiber, as well as signal and reference ring fiber coils, which are optically coupled through a 3x3 linear coupler with a single-mode fiber and a series-connected high-pass filter, an amplifier and a recorder connected to the output of the photodetector, further comprises an acoustic A screen configured to bias relative to the signal fiber coil, a screen position sensor, an automatic sensitivity adjustment unit, a control voltage generation unit, a power amplifier, an actuator and a scaling amplifier, while the input of the automatic sensitivity adjustment unit is connected to the amplifier output and the output to the input of the control voltage generating unit, the output of which through the power amplifier is connected to the actuator associated with the acoustic screen, and the output of the amplifier is connected to the recorder through a scaling amplifier, the control input of which is connected to the output of the screen position sensor.

 The automatic sensitivity adjustment unit can be made in the form of an integrator, two comparators and two blocks of reference voltages, with the integrator input connected to the amplifier output and the output connected in parallel to the first inputs of the comparators, the second inputs of which are connected to different voltage sources, and the outputs are the inputs of the control voltage generating unit.

 The ARG may also contain two phase-shifting devices, mainly installed in the reference fiber coil, an electronic key and an automatic phase difference initialization unit made in the form of a harmonic oscillation generator, a sawtooth pulse generator and an extremator, while the harmonic oscillation generator is connected to the first phase-shifting device, and the sawtooth pulse generator is connected by the output to the second phase-shifting device, and by its control input to the output of the extremator, soy dyno input with the output of the amplifier, and the control input of the electronic key is connected to the output of the position sensor, and the output with the supply circuits of the block automatically adjust the sensitivity and block automatically adjusts the initial phase difference.

 The signal fiber coil and the movable acoustic screen can be made in the form of concentric cylindrical surfaces, and the acoustic screen can be made in the form of an external cylindrical surface with the possibility of displacement along the axis.

 ARCA may further comprise a fixed acoustic screen, behind which a support fiber coil is arranged.

 In this case, the stationary acoustic screen can be made in the form of a cylindrical surface, coaxial to the cylindrical surface of the movable acoustic screen.

 The hydrophone actuator is expediently implemented as a stepper motor.

 In FIG. 1 is an optical diagram of a hydrophone; figure 2 is a structural diagram of the DVOG; in FIG. 3 electronic circuit of the device; in FIG. 4,5 time diagrams explaining the principle of operation of the hydrophone.

 The double-ring fiber-optic hydrophone contains (Fig. 1) a coherent light source 1 and a photodetector 2 optically matched through a segment of a single-mode fiber optic fiber 3. There are also signal and reference ring fiber coils 4, 5, which are optically coupled through a 3x3 linear coupler 6 to a single-mode optical fiber 3.

 Elements 1-6 are optically matched to a double-ring fiber optic interferometer. Moreover, in one embodiment, the signal fiber coil 5 is located overboard 7 of the carrier (not shown), and the remaining elements of the interferometer are located inside the carrier (Fig. 1).

 The optical system of the ADR also includes two phase-shifting devices 8, 9 installed, for example, in the reference fiber coil 4. The signal fiber coil 5 is wound along a cylindrical surface and partially overlaps with a movable acoustic screen 10, the position of which relative to the signal coil 5 is monitored by a position sensor 11 (Fig. 2). The reference fiber coil 4 in the second embodiment can be located like the signal coil 5 in the test medium, but it is completely blocked by a fixed acoustic screen 12 (for example, a cylindrical shape) from the influence of sound signals (in Fig. 2 the reference fiber coil is not shown) .

 Movable and fixed screens can be made coaxial. In this case, the stationary acoustic screen 10 is connected to the shaft of the controlled actuator 13 (Fig. 3), made, for example, in the form of a stepper motor.

 The DVOG electronic circuit (Fig. 3) includes a high-pass filter 14, an amplifier 15, a hydrophone sensitivity automatic adjustment unit 16, a scaling amplifier 17 and a recorder 18, as well as a control voltage generating unit 19 and a power amplifier 20. The circuit also contains a block 21 for automatically adjusting the initial phase difference and an electronic key 22. Moreover, the block 16 for automatically adjusting the sensitivity is made in the form of an integrator 23, comparators 24, 25 and blocks 26, 27 of the reference voltage. Block 21 of the automatic adjustment of the initial phase difference is made in the form of a generator 28 of harmonic oscillations, a generator 29 of sawtooth pulses and an extremator 30.

 The electrical connection diagram of all blocks is presented in figure 3.

 Optical elements and electronic components have no features. Optical element 6, both in foreign literature [3] and in domestic [1] literature, entered under the name "3x3 linear coupler", and therefore the applicant is forced to use it in the claims and description.

 Blocks 13, 19, 20, 24-27, 30 are presented in the literature on automatic regulation.

 Double-ring fiber optic hydrophone operates as follows.

 Before starting work, as well as in between measurements, a multibeam interferometer is tuned directly in the working environment. To do this, by manually adjusting the position of the movable acoustic screen 10, the latter is shifted to the left to the limit, completely blocking the signal coil 5 from exposure to acoustic waves. With this position of the movable acoustic screen, a command signal is received from the position sensor 11 to the electronic switch 22, which turns off the automatic sensitivity adjustment unit 16 and includes an automatic phase difference initialization unit 21.

 The output curve of the multipath interferometer is shown in FIG. 4 under position 31. It represents extremely sharpened interference bands following through a distance equal to l / 2. As already noted, the working range of the hydrophone does not exceed l / 300. In this case, the operating point A on the output curve 31 should be located on the slope of the interference band in the middle of the linear section. To do this, from the generator 28 of harmonic oscillations to the phase-shifting device 8, a sinusoidal signal is supplied. Denote it in FIG. 4 under 32. This signal causes pulsations of the photocurrent at the output of the photodetector 2, which, passing through the high-pass filter 14, are amplified by an amplifier 15 and fed to an extremator 30. At the same time, a sawtooth pulse generator 29 of a sufficiently long period causes the second phase shifter 9 to sequentially shift the working point A along the output curve 31 of the interferometer. When point A is in the middle of the slope of the interference band, the harmonic output signal (key 33) will be maximum. At this moment, the extremator 30 provides a command signal to turn it on to the control input of the generator 29.

 Using manual adjustment, the signal fiber coil 5 is opened and exposed to acoustic waves (direction perpendicular to the OO ′ axis). In this case, the electronic key 22 disables the block 21 for automatically adjusting the initial phase difference and turns on the block 16 for automatically adjusting the sensitivity. Let now conditionally over the position 32 (Fig. 3) indicated the input signal ADR. A temporary change in the acoustic input signal can be very different. At the output of the photodetector 2, a photo current signal 34 appears (Fig. 5), displaying the acoustic input. The signal 34 is present against the background of a constant component, which is filtered by a high-pass filter 14. After amplification in the amplifier 15, the signal is fed to a scaling amplifier 17, the gain of which is set by the output signal of the acoustic position sensor 11. This allows the recorder 18 to display the acoustic input in one scale, regardless of the sensitivity of the ARR, i.e. regardless of the position of the movable screen 10. At the same time, the signal 34 from the amplifier 15 is also sent to the integrator 23, in which the signal is smoothed to level 35 and then sent to the first inputs of the comparators 24 and 25. The reference signals 36 and 37 are fed to the second inputs of the comparators 24 and 25 respectively, from blocks 26 and 27 of the reference voltage. The values of the reference signals are selected based on the magnitude of the linear section on the output curve 31 in the vicinity of point A (Fig. 4).

If the signal 35 will lie in the range of i _op2 i _{op1 of the} reference voltage, then at the output of the comparators 24, 25 there will be bipolar signals that do not cause the command signal to appear on the actuator 13 in the control voltage generating unit 19, and the acoustic screen 10 remains unchanged position. But if the signal 35 will be less or more, respectively, of the signals i _op1 , i _op2 , then at the outputs of the comparators 24 and 25 there will be unipolar signals and block 19 generates a signal 38 of positive voltage if both signals are “plus” and negative (39), if negative signals. In this case, the actuator 13 will shift the acoustic screen depending on the polarity of the signal to the right or left, changing the sensitivity of the device in accordance with the magnitude of the input signal.

 The sensor 11 of the position of the screen 10 all the time monitors the sensitivity value of the ARG, accordingly changing the gain of the scaling amplifier 17.

 The power amplifier 20 amplifies the control voltage to the value necessary for the operation of the actuator 13. When executing the actuator 13 in the form of a stepper motor, the sensitivity of the device changes discretely. With the location of the support fiber coil in a fixed screen 12 (Fig. 2), the hydrophysical factors of the test medium (temperature, hydrostatic pressure) do not affect the operation of the ADOG. That is, the second embodiment of the hydrophone is preferred for operation in a natural reservoir.

 Thus, the proposed hydrophone allows you to automatically change its sensitivity depending on the magnitude of the input exposure.

Sources of information taken into account when compiling a description of the application
1. A. G. Bulushev, A. V. Kuznetsov, O. G. Okhotnikov, V. A. Tsarev. Fiber optic interferometers. Proceedings of the Institute of General Physics, 1990, v. 23, 159-172.

 2. F. Farahi, l. D. C. Jones, D. A. Jackson. High speed thermometry utilizing multiplexed fiber Fabry-Perot interferometers. SPIE Vol. 838. Fiber Optic and Laser Sensors V, 1987, 216-222.

 3. G. Abd-el-Hamid, P. A. Devies. Fiber-optic double ring resonator. Electronics Letters, 1989, 25, N 3, 224-225 prototype.

 4. Yu. N. Vlasov, V.K. Maslov, S.V. Silvestrov. The principles of constructing hydroacoustic and hydrophysical field parameter meters based on optical conversion methods. Intermediate scientific and technical report on research "Metrology-7", stage 3, Mendeleevo, 1993.

Claims (6)

 1. A double-ring fiber-optic hydrophone containing a coherent light source optically connected through a segment of a single-mode fiber to a photodetector, as well as a signal and reference ring fiber coils, which are optically coupled through a 3 • 3 line coupler with a single-mode fiber, and serially connected upper filters frequencies, an amplifier and a recorder connected to the output of the photodetector, characterized in that it further comprises a movable acoustic screen configured to displacement relative to the signal fiber coil, screen position sensor, automatic sensitivity control unit, control voltage generation unit, power amplifier, actuator, while the input of automatic sensitivity adjustment unit is connected to the amplifier output, and the output to the input of the control voltage generation unit, the output of which through a power amplifier connected to an actuator associated with a movable acoustic screen, and the amplifier is made with controllable course, connected to the output of the sensor position of the movable baffle.  2. The hydrophone according to claim 1, characterized in that the automatic sensitivity control unit is made in the form of an integrator, two comparators and two blocks of reference voltages, while the output of the integrator is connected in parallel to the first inputs of the comparators, the second inputs of which are connected to various sources of reference voltages.  3. The hydrophone according to claim 1, characterized in that it further comprises two phase-shifting units installed mainly in the reference fiber coil, an electronic key and an automatic adjustment unit for the initial phase difference, made in the form of a harmonic oscillation generator, sawtooth pulse generator and an extremator, while the harmonic generator is connected to the first phase-shifting unit, and the sawtooth generator is connected by the output to the second phase-shifting unit, and its control input to the output an extremator connected by an input to the output of the amplifier, the control input of an electronic key connected to the output of the position sensor, and the output to the supply circuits of the automatic sensitivity adjustment unit and the automatic adjustment of the initial phase difference.  4. The hydrophone according to claim 1, characterized in that the signal fiber coil and the movable acoustic screen are made in the form of concentric cylindrical surfaces, and the acoustic screen is made in the form of an external cylindrical surface with the possibility of displacement along the axis.  5. The hydrophone according to claim 1, characterized in that it further comprises a fixed acoustic screen, behind which there is a reference fiber coil.  6. The hydrophone according to claims 1, 4 and 5, characterized in that the stationary acoustic screen is made in the form of a cylindrical surface, coaxial to the cylindrical surface of the stationary acoustic screen.

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