JP6205680B2 - Interferometric fiber optic sensor - Google Patents

Description

  The present invention relates to an interference optical fiber sensor, for example, an interference optical fiber sensor that reduces noise in a demodulating band.

  The interference type optical fiber sensor uses a sensing fiber as an arm of an optical fiber interferometer. Specifically, the interference optical fiber sensor changes the physical quantity to be detected into the strain of the sensing fiber. As the sensing fiber is distorted, the interference light changes. Therefore, the interference type optical fiber sensor detects the physical quantity by utilizing the fact that the interference light changes according to the strain of the sensing fiber. Thereby, the interference type optical fiber sensor can detect various physical quantities.

  For example, Non-Patent Document 1 and Non-Patent Document 2, which will be described later, describe sensors that detect acoustic signals. Non-Patent Document 3 described below describes a sensor that detects a magnetic signal.

  FIG. 16 is an explanatory diagram of the method shown in Non-Patent Document 1 (hereinafter referred to as Prior Art 1). FIG. 16 shows the configuration of the interference type optical fiber sensor of the prior art 1 and its pulse waveform. First, the configuration of the interference type optical fiber sensor of the prior art 1 will be described. The interference type optical fiber sensor of the prior art 1 includes an oscillator 1, a pulse light source 2, an optical coupler 3, an optical frequency shifter 4, a delay compensation fiber 5, an optical coupler 6, an optical amplifier 7, an optical coupler 8, a sensing fiber 9, and a mirror 10. , A mirror 11, an O / E (Opto / Electronics) converter 12, a demodulator 13, and the like. The demodulator 13 includes an A / D converter 21, a reference signal generator 22, a reference signal generator 23, a multiplier 24, a multiplier 25, an LPF (Low Pass Filter) 26, an LPF 27, an arctangent calculator 28, A continuous point compensation calculator 29 and the like are provided.

  Next, the propagation path of pulsed light in the interference type optical fiber sensor of the prior art 1 will be described. First, each path point in the propagation path will be described. The path point A indicates a path point located in the propagation path of the pulse waveform between the pulse light source 2 and the optical coupler 3. The path point B indicates a path point located in the propagation path of the pulse waveform between the optical coupler 3 and the optical frequency shifter 4. A path point C indicates a path point located in the propagation path of the pulse waveform between the optical coupler 3 and the delay compensation fiber 5. A path point D indicates a path point located in a propagation path of a pulse waveform between the optical amplifier 7 and the optical coupler 8. A path point E indicates a path point of a pulse waveform located on the mirror 10. A path point F indicates a path point of a pulse waveform located on the mirror 11. A path point G indicates a path point located in a propagation path of a pulse waveform between the optical coupler 8 and the O / E converter 12.

The pulsed light having the optical frequency ν output from the pulsed light source 2 is branched into two by the optical coupler 3. Of the pulsed light branched into two by the optical coupler 3, one pulsed light passes through the optical frequency shifter 4 and the optical coupler 6. The pulsed light that has passed through the optical coupler 6 is amplified by the optical amplifier 7. At this time, the pulsed light has propagated along the path ABD. Here, the optical frequency shifter 4 shifts the frequency of light by f _α when receiving a signal of frequency f _α from the oscillator 1. Therefore, pulsed light having an optical frequency ν + f _α is input to the optical coupler 6.

  Of the pulse light branched into two by the optical coupler 3, the other pulse light passes through the delay compensation fiber 5. For this reason, the pulsed light that has passed through the delay compensation fiber 5 passes through the optical coupler 6 with a delay from the pulsed light that has passed through the path ABD. The pulsed light that has passed through the optical coupler 6 is amplified by the optical amplifier 7. At this time, the pulsed light has propagated along the path ACD.

  The pulsed light that has passed through the path point D is branched into two by the optical coupler 8. One of the pulse lights branched by the optical coupler 8 is reflected by the mirror 10. The pulsed light reflected by the mirror 10 passes through the optical coupler 8 again. Then, the pulsed light that has passed through the optical coupler 8 again is input to the O / E converter 12. At this time, the pulsed light has propagated through the path DEG.

  Of the pulsed light branched by the optical coupler 8, the other pulsed light passes through the sensing fiber 9. Next, the pulsed light that has passed through the sensing fiber 9 is reflected by the mirror 11. The pulsed light reflected by the mirror 11 passes through the sensing fiber 9 and the optical coupler 8 again. Then, the pulsed light that has passed through the optical coupler 8 again is input to the O / E converter 12. At this time, the pulsed light has propagated through the path DFG. Here, when the pulsed light reciprocates through the sensing fiber 9, the phase of the light is modulated by the signal φ (t).

  Next, the pulse waveform of the pulsed light propagating through the interference type optical fiber sensor of the prior art 1 will be described. A pulse waveform A shown in FIG. 16 shows a pulse waveform passing through the position of the path point A. The numbers shown in the pulse waveform A indicate the order of output from the pulse light source 2. For example, numbers are assigned in ascending order like 1, 2, 3,...

  A pulse waveform ABDEG shown in FIG. 16 shows a pulse waveform illustrating the component of the pulsed light that has propagated through the path ABDEG among the pulsed light input to the O / E converter 12. The numbers given adjacent to the respective symbols shown in the pulse waveform ABDEG indicate the order of arrival at the O / E converter 12, for example, a1, a2, a3,. Numbers are assigned to the symbols in ascending order. In this way, a combination of symbols and numbers is given to each pulsed light. Similarly, the pulse waveform ABDFG, the pulse waveform ACDEG, and the pulse waveform ACDFG shown in FIG. 16 show the pulse waveforms illustrating the components of the pulse light propagated through the path ABDFG, the path ACDEG, and the path ACDFG, respectively. Further, the same light as the pulse waveform ABDEG is given to each pulse light of the pulse waveform ABDFG, the pulse waveform ACDEG, and the pulse waveform ACDFG.

  Here, the round-trip propagation time of the sensing fiber 9 is defined as a propagation delay τ. If the propagation delay τ is equal to the round-trip propagation time of the delay compensation fiber, the period of each pulsed light of the pulse waveform ABDFG is equal to the period of each pulsed light of the pulse waveform ACDEG. That is, since the pulse light bi (i = 1, 2, 3,...) And the pulse light ci (i = 1, 2, 3,...) Have the same period, the pulse light bi and the pulse light The light ci overlaps at the same timing. Thereby, the interference pulse light bi + ci (i = 1, 2, 3,...) Is generated at the path point G.

Further, there is a difference in frequency f _α between the frequency of the pulsed light that has passed through the optical frequency shifter 4 and the frequency of the pulsed light that has passed through the delay compensation fiber 5. Therefore, the interference pulse light bi + ci is, when the output O / E converter 12, the center frequency is the frequency f _alpha. At this time, a beat that is phase-modulated by the signal φ (t) detected by the sensing fiber 9 is generated.

  The demodulator 13 samples the interference pulse light bi + ci output from the O / E converter 12 in accordance with the timing, thereby obtaining an output represented by Expression (1). Next, the demodulator 13 demodulates the signal φ (t) detected by the sensing fiber 9. Δ (t) shown in FIG. 16 is a function represented by Expression (2) meaning sampling.

Here, δ in the equation (2) means Dirac's δ function. Therefore, the interference pulse light bi + ci is sampled by multiplying the δ function and the interference pulse light bi + ci at a predetermined cycle interval. Further, the cutoff frequencies of the LPF 26 and LPF 27 of the demodulator 13 are set to the same f _α as the beat frequency. By doing in this way, the widest signal band is ensured in the range in which folding does not overlap.

  FIG. 17 is a diagram showing an example (hereinafter referred to as Conventional Technology 2) configured to demodulate by the method of Conventional Technology 1 using the time division multiplexing configuration shown in Non-Patent Document 2. The propagation path of the pulse light from the pulse light source 2 to the optical amplifier 7 is the same. In that section, the oscillator 1, the pulse light source 2, the optical coupler 3, the optical frequency shifter 4, the delay compensation fiber 5, the optical coupler 6, and the optical amplifier 7 operate in the same manner as in the prior art 1. The difference from the prior art 1 is the configuration and operation after the optical amplifier 7.

  Specifically, the pulsed light output from the optical amplifier 7 is branched by the optical coupler 41. One pulse light branched by the optical coupler 41 is sent to the sensing fiber 71 after passing through the optical coupler 31. The other pulse light branched by the optical coupler 41 is branched by the optical coupler 42 after the timing is shifted by the delay fiber 81. One pulsed light branched by the optical coupler 42 is sent to the sensing fiber 72 after passing through the optical coupler 32. The other pulse light branched by the optical coupler 42 is shifted in timing by the delay fiber 82, passes through the optical coupler 33, and is sent to the sensing fiber 73. Thereafter, the pulsed light is coupled to one optical fiber by the optical coupler 52 and the optical coupler 51. Thereby, the signals 1 to 3 are transmitted by time division multiplexing.

The demodulator 13 shown in FIG. 17 generates pulsed light including the signal φ ₁ (t), the signal φ ₂ (t), and the signal φ ₃ (t) from the pulse train output from the O / E converter 12. And sampling separately, and phase-demodulating based on the sampling result. 17, the multiplication of the reference become _sin2πf β t or _cos2πf β t phase demodulation, an example of performing the sampling at the same time represented by formula (3) to (5) are shown.

As shown in FIG. 17, the conventional technique 2 has the same functions as the multiplier 24, multiplication 25, LPF 26, LPF 27, arctangent calculator 28, and discontinuity compensation calculator 29 shown in the conventional technique 1. The signal φ ₁ (t), the signal φ ₂ (t), and the signal φ ₃ (t) are demodulated by using three sets. Specifically, the conventional technique 2 uses the multipliers 101 to 106, the LPFs 111 to 116, the arc tangent calculators 121 to 123, and the discontinuous point compensation calculator 131, so that the signal φ ₁ (t) and the signal φ ₂ (t) and the signal φ ₃ (t) are demodulated.

FIG. 18 is a diagram illustrating an example of a pulse waveform of the pulsed light propagating through the interference type optical fiber sensor of the related art 2. It is assumed that the round-trip propagation times of the sensing fiber 71, the sensing fiber 72, and the sensing fiber 73 are τ. At this time, it is assumed that the one-way propagation time of the delay compensation fiber 5, the delay compensation fiber 81, and the delay compensation fiber 82 is 3τ. Further, it is assumed that the pulse repetition period of the pulse light source 2 is 9τ. When the parameters are assumed in this way, at the path point G, a pulse train including the signal φ ₁ (t), the signal φ ₂ (t), and the signal φ ₃ (t) is obtained.

G. A. Cranch et al. , “Acoustic performance of a large-aperture, seabed, fiber-optical hydrophone array,” Journal of the Acoustical Society of America, Amer. 115, no. 6, pp. 2848-2858 (2004) Ryozawa Sato, 3 others, “Development of optical fiber hydrophone”, IEICE Technical Report, May 1995, OPE95-2, p. 7-12 Ryotaku SATO et al. , “Design of Fiber-Optic Magnetometer Utilizing Magnetostriction,” Japan Journal of Applied Physics, pp. 817-820 (2007)

  FIG. 19 is a conceptual diagram showing an example of a power spectrum after A / D conversion is performed by the A / D converter 21 of the prior arts 1 and 2. The power spectrum shown in FIG. 19 is obtained by A / D converting the output result of the O / E converter 12 by the A / D converter 21. The O / E converter 12 needs to have a pass band in which the received pulsed light can be separated. For example, in the O / E converter 12 of the prior art 1, the sampling frequency 1 / (3τ) needs to be lower than the upper limit of the passband. Further, in the O / E converter 12 of the conventional technique 2, the sampling frequency 1 / (9τ) needs to be lower than the upper limit of the passband.

  Here, when pulsed light is sampled, a folding phenomenon may occur due to sampling. For this reason, beats and sidebands (upper sideband and lower sideband), noise generated in the optical amplifier 7 and the like are generated in large numbers throughout the passband of the O / E converter 12. At this time, beats and sidebands generated by folding are limited by the frequency characteristics of the optical fiber coil and hardly affect the band to be demodulated. In contrast, noise generated by the optical amplifier 7 or the like has a wide frequency band. Therefore, a large number of turns are overlapped over the entire pass band of the O / E converter 12. Thereby, the noise of the band to demodulate was increased.

  In addition, when time-division multiplexing is performed as shown in Prior Art 2, the sampling frequency is lowered as the number of signals to be multiplexed increases. Therefore, aliasing noise increases as the sampling frequency is lowered. In such a case, the number of multiplexing is limited so as not to exceed a noise level that is acceptable for use, and the noise of the band to be demodulated is also increased.

  From the above, the prior arts 1 and 2 have a problem that the noise of the band to be demodulated cannot be reduced by reducing the aliasing noise.

  The present invention has been made to solve the above-described problems, and provides an interference type optical fiber sensor that can reduce noise in a demodulated band by reducing aliasing noise. .

The interference type optical fiber sensor of the present invention includes a light source that outputs pulsed light, a modulation signal generator that generates a signal of a specific frequency, and the pulsed light output from the light source, to which the modulation signal generator is connected. and an optical frequency shifter for shifting the specific frequency, and a first optical coupler for inputting a plurality of pulsed light is shifted by the optical frequency shifter in the same optical fiber, a plurality of sensing fiber for detecting the measurement signal, a plurality A plurality of second optical couplers connected to each of the sensing fibers and generating beats including signals detected by the connected sensing fibers; and signals output from the plurality of sensing fibers, and the measurement signal and a demodulator for detecting the said modulation signal generator, the signal detected by one of the sensing fiber, frequency different of The optical frequency shifter shifts the pulsed light by the specific frequency based on the different frequencies output from the modulation signal generator so as to be included in each of a plurality of beats. The second optical coupler generates a plurality of beats having different frequencies at the same time, and the sensing fiber has a pulse that has passed through the first optical coupler and any one of the second optical couplers. The measurement signal is detected by modulating and outputting the phase of light based on the measurement signal.

  The present invention has an effect that noise in a demodulated band can be reduced by reducing aliasing noise.

It is a block diagram which shows an example of a structure of the interference type optical fiber sensor in Embodiment 1 of this invention. It is a figure explaining an example of the optical frequency of the pulsed light in Embodiment 1 of this invention, and its timing. It is a figure which shows the pulse waveform explaining operation | movement of the interference type optical fiber sensor in Embodiment 1 of this invention. I _A in the first embodiment of the present invention, I _B, is a conceptual view of the power spectrum after the I _C was converted A / D. It is a block diagram which shows an example of a structure of the interference type optical fiber sensor in Embodiment 2 of this invention. It is a block diagram which shows an example of a structure of the interference type optical fiber sensor in Embodiment 3 of this invention. It is a figure explaining an example of the optical frequency of the pulsed light in Embodiment 3 of this invention, and its timing. It is a figure which shows the pulse waveform explaining operation | movement of the interference type optical fiber sensor in Embodiment 3 of this invention. I _A in the third embodiment of the present invention, I _B, is a conceptual view of the power spectrum after the I _C was converted A / D. It is a block diagram which shows an example of a structure of the interference type optical fiber sensor in Embodiment 4 of this invention. It is a figure explaining an example of the optical frequency of the pulsed light in Embodiment 4 of this invention, and its timing. It is a figure which shows the pulse waveform explaining operation | movement of the interference type optical fiber sensor in Embodiment 4 of this invention. It is a block diagram which shows an example of a structure of the interference type optical fiber sensor in Embodiment 5 of this invention. It is a figure explaining an example of the optical frequency of the pulsed light in Embodiment 5 of this invention, and its timing. It is a figure which shows the pulse waveform explaining operation | movement of the interference type optical fiber sensor in Embodiment 5 of this invention. It is explanatory drawing of the system (henceforth the prior art 1) shown by the nonpatent literature 1. FIG. It is a figure which shows the system (henceforth the prior art 2) shown by the nonpatent literature 2. FIG. It is a figure which shows an example of the pulse waveform of the pulsed light which propagates the inside of the interference type optical fiber sensor of the prior art 2. FIG. It is a conceptual diagram which shows an example of the power spectrum after A / D-converting with the A / D converter 21 of the prior art 1,2.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

Embodiment 1 FIG.
(Description of configuration)
FIG. 1 is a block diagram showing an example of the configuration of the interference optical fiber sensor according to Embodiment 1 of the present invention. First, the configuration of the interference type optical fiber sensor will be described. The interference type optical fiber sensor includes a pulse light source 2, an optical coupler 3, a modulation signal generator 201, a modulation signal generator 202, an optical frequency shifter 211, an optical frequency shifter 212, a delay compensation fiber 5, an optical coupler 6, an optical amplifier 7, An optical coupler 8, a sensing fiber 9, a mirror 10, a mirror 11, an O / E (Opto / Electronics) converter 12, a demodulator 13, and the like are provided. The demodulator 13 includes an A / D converter 21, a reference signal generator 91, a reference signal generator 92, a reference signal generator 93, a reference signal generator 94, a reference signal generator 95, a reference signal generator 96, and a multiplier. 101, multiplier 102, multiplier 103, multiplier 104, multiplier 105, multiplier 106, LPF (Low Pass Filter) 111, LPF 112, LPF 113, LPF 114, LPF 115, LPF 116, arc tangent calculator 121, arc tangent calculator 121 122, an arctangent calculator 123, a discontinuous point compensation calculator 131, a discontinuous point compensation calculator 132, a discontinuous point compensation calculator 133, and an adder 221.

  The pulsed light source 2 generates pulsed light having a constant wavelength and makes it incident on the optical coupler 3. The optical couplers 3, 6, and 8 branch incident light beams or superimpose them into one. The modulation signal generators 201 and 202 generate signals having a specific frequency. The optical frequency shifters 211 and 212 shift the frequency based on a signal having a specific frequency input from the modulation signal generators 201 and 202. The delay compensation fiber 5 compensates for the delay time difference.

  The optical amplifier 7 amplifies the input pulsed light and inputs it to the optical coupler 8. The sensing fiber 9 is distorted by the added physical quantity, and thereby the light passing through the sensing fiber is phase-modulated. For this reason, the sensing fiber 9 can detect the change of the physical quantity according to the physical quantity to be measured. The mirrors 10 and 11 reflect incident light. The O / E converter 12 generates an electric signal by photoelectrically converting a pulsed light signal. The demodulator 13 demodulates based on the input electric signal and calculates the phase φ (t). That is, the demodulator 13 detects the measurement signal corresponding to the physical quantity based on the interference light from the sensing fiber 9.

The A / D converter 21 converts an analog signal into a digital signal. The reference signal generators 91 to 96 generate a timing signal for sampling an A / D converted digital signal at a predetermined interval and a reference signal for phase demodulation based on the δ function. The multipliers 101 to 106 multiply the output signal of the A / D converter 21 and the output signals of the reference signal generators 91 to 96, thereby sampling a necessary signal and simultaneously generating a reference signal for phase demodulation. Multiply. The LPFs 111 to 116 cut high frequency components of the output signals of the multipliers 101 to 106. The arc tangent calculators 121 to 123 determine the phase. The discontinuous point compensation calculators 131 to 133 interpolate discontinuous points generated by arctangent calculation. The adder 221 outputs [Δ _A (t) + Δ _B (t) + Δ _C (t)] Φ (t) by adding the discontinuous point compensation calculators 131 to 133.

  Next, the propagation path of pulsed light in the interference type optical fiber sensor will be described. First, each path point in the propagation path will be described. The path point A indicates a path point located in the propagation path of the pulse waveform between the pulse light source 2 and the optical coupler 3. The path point B indicates a path point located in the propagation path of the pulse waveform between the optical coupler 6 and the optical frequency shifter 211. A path point C indicates a path point located in the propagation path of the pulse waveform between the optical coupler 6 and the delay compensation fiber 5. A path point D indicates a path point located in a propagation path of a pulse waveform between the optical amplifier 7 and the optical coupler 8. A path point E indicates a path point of a pulse waveform located on the mirror 10. A path point F indicates a path point of a pulse waveform located on the mirror 11. A path point G indicates a path point located in a propagation path of a pulse waveform between the optical coupler 8 and the O / E converter 12.

The pulsed light having the optical frequency ν output from the pulsed light source 2 is branched into two by the optical coupler 3. One of the pulse lights branched into two by the optical coupler 3 passes through the optical frequency shifter 211 and the optical coupler 6. The pulsed light that has passed through the optical coupler 6 is amplified by the optical amplifier 7. At this time, the pulsed light has propagated along the path ABD. Here, the optical frequency shifter 211 shifts the frequency of light by f _f (t) when receiving a signal of frequency f _f (t) from the modulation signal generator 201. Therefore, pulsed light having an optical frequency ν + f _f (t) is input to the optical coupler 6.

Of the pulse light branched into two by the optical coupler 3, the other pulse light passes through the optical frequency shifter 212 and the delay compensation fiber 5 in order. The pulsed light that has passed through the optical coupler 6 is amplified by the optical amplifier 7. At this time, the pulsed light has propagated through the path ACD. Here, the optical frequency shifter 212 shifts the frequency of light by f _b (t) when receiving a signal of frequency f _b (t) from the modulation signal generator 202. Therefore, pulsed light having an optical frequency ν + f _b (t) is input to the optical coupler 6.

  The pulsed light that has passed through the path point D is branched into two by the optical coupler 8. One of the pulse lights branched by the optical coupler 8 is reflected by the mirror 10. The pulsed light reflected by the mirror 10 passes through the optical coupler 8 again. Then, the pulsed light that has passed through the optical coupler 8 again is input to the O / E converter 12. At this time, the pulsed light has propagated through the path DEG.

  Of the pulsed light branched by the optical coupler 8, the other pulsed light passes through the sensing fiber 9. Next, the pulsed light that has passed through the sensing fiber 9 is reflected by the mirror 11. The pulsed light reflected by the mirror 11 passes through the sensing fiber 9 and the optical coupler 8 again. Then, the pulsed light that has passed through the optical coupler 8 again is input to the O / E converter 12. At this time, the pulsed light has propagated through the path DFG. Here, when the pulsed light reciprocates through the sensing fiber 9, the phase of the light is modulated by the signal φ (t). In FIG. 1, (t) of the signal φ (t) is omitted from the illustration.

  Next, the configuration of the main part of the interference type optical fiber sensor will be described with reference to FIG. As shown in FIG. 1, the interference optical fiber sensor according to Embodiment 1 of the present invention has a configuration in which both of the pulsed light branched by the optical coupler 3 can be shifted in frequency. Specifically, one of the pulse lights branched by the optical coupler 3 is input to the optical frequency shifter 211. Of the pulsed light branched by the optical coupler 3, the other pulsed light is input to the optical frequency shifter 212.

A modulation signal generator 201 is connected to the optical frequency shifter 211. The optical frequency shifter 211 shifts the input pulsed light by a predetermined frequency. The frequency to be shifted is input from the modulation signal generator 201 to the optical frequency shifter 211. For example, it is assumed that the frequency f _f (t) is input from the modulation signal generator 201 to the optical frequency shifter 211. At this time, pulsed light having an optical frequency ν is input from the pulsed light source 2 to the optical frequency shifter 211 via the optical coupler 3. Therefore, the pulsed light input to the optical frequency shifter 211 is output with its frequency shifted by the frequency ν + f _f (t).

On the other hand, a modulation signal generator 202 is connected to the optical frequency 212. The optical frequency shifter 212 shifts the input pulsed light by a predetermined frequency. The frequency to be shifted is input from the modulation signal generator 202 to the optical frequency shifter 212. For example, it is assumed that the frequency f _b (t) is input from the modulation signal generator 202 to the optical frequency shifter 212. At this time, pulsed light having an optical frequency ν is input from the pulsed light source 2 to the optical frequency shifter 212 via the optical coupler 3. Therefore, the pulsed light input to the optical frequency shifter 212 is output with its frequency shifted by the frequency ν + f _b (t).

  For one sensing fiber 9, reference signal generators 91 to 96, multipliers 101 to 106, LPFs 111 to 116, arc tangent calculators 121 to 123, and discontinuous point compensation calculators 131 to 133 are used. ing. Then, the outputs of the discontinuous point compensation calculators 131 to 133 are added by the adder 221.

  That is, the reference signal generators 91 and 92, the multipliers 101 and 102, the LPFs 111 and 112, the arc tangent calculator 121, and the discontinuous point compensation calculator 131 form one set. The reference signal generators 93 and 94, the multipliers 103 and 104, the LPFs 113 and 114, the arc tangent calculator 122, and the discontinuous point compensation calculator 132 form one set. Further, the reference signal generators 95 and 96, the multipliers 105 and 106, the LPFs 115 and 116, the arctangent calculator 123, and the discontinuous point compensation calculator 133 form one set. Therefore, the signal φ sensed by one sensing fiber 9 is calculated by each of these sets, whereby the signal φ is sensed.

  Next, the correlation between the pulse waveform of the pulsed light propagating through the interference type optical fiber sensor and the frequency of the pulsed light shifted in frequency by the optical frequency shifters 211 and 212 will be described. FIG. 2 is a diagram for explaining an example of the optical frequency of pulsed light and its timing in Embodiment 1 of the present invention. The pulsed light that is the output waveform of the pulsed light source 2 and the substantially rectangular waves of the optical frequency shifters 211 and 212 are synchronized. That is, the frequency of the pulsed light output from the optical frequency shifters 211 and 212 is changed stepwise in accordance with the pulsed light output timing of the pulsed light source 2.

  As shown in FIG. 2, the horizontal axis is time, and the vertical axis is optical frequency. Then, the step-like frequency fluctuation is restored every 3τ. That is, the period of the substantially rectangular wave of the optical frequency shifters 211 and 212 is 3τ, and the frequency is 1 / (3τ). The pulse light output from the pulse light source 2 is given a number in the order of arrival at the optical frequency shifters 211 and 212. For example, numbers are assigned in ascending order such as 1, 2, 3, 4, 5, 6, 7, 8, 9,.

Here, the difference of f _f1 −f _b1 is set to 1. That is, the difference of (ν + f _b1 ) − (ν + f _f1 ) is assumed to be 1. Next, the difference of f _f2 −f _b2 is set to 3. That is, the difference of (ν + f _f2 ) − (ν + f _b2 ) is set to 3. Further, the difference of f _f3 −f _b3 is set to 5. That is, a difference of (ν + f _f3 ) − (ν + f _b3 ) is set to 5. The difference between f _b3 −f _{f2 and} the difference between f _b2 −f _f1 are 7 respectively. That is, a difference of (ν + f _b3 ) − (ν + f _f2 ) is set to 7, and a difference of (ν + f _b2 ) − (ν + f _f1 ) is set to 7. Further, f _f1 −f _b1 is 1/30 of the frequency 1 / (3τ). That is, the difference of (ν + f _f1 ) − (ν + f _b1 ) is 1/30 of 1 / (3τ). The reason why the ratio of the magnitude of the output frequency is set by the discrete values 1, 3, 5, 7 is to reduce aliasing noise. That is, a discrete value is set so as not to cause aliasing. Numbers such as 1, 3, 5, and 7 are examples, and are not limited thereto.

  In FIG. 2, description of the frequency parameter t is omitted.

Next, the bandwidth of the O / E converter 12 is set to a range in which the received pulse train can be separated, a range in which leakage from other pulses does not cause a problem, and a bandwidth having a narrow bandwidth is used. Here, Δ _A (t) of the reference signal generators 91 and 92 of the demodulator 13, Δ _B (t) of the reference signal generators 93 and 94 of the demodulator 13, and the reference signal generator 95 of the demodulator 13, Δ _C (t) of 96 is expressed by the following equations (6) to (8).

(Description of operation)
FIG. 3 is a diagram showing a pulse waveform for explaining the operation of the interference optical fiber sensor according to Embodiment 1 of the present invention. As shown in FIG. 3, for the pulsed light that passes through the path point A, the numbers are given in ascending order as 1, 2, 3, 4,. The optical frequency of each pulsed light is also given as ν.

For the pulsed light passing through the path point AB, numbers are assigned to the pulsed light passing through the path point AB in ascending order of 1, 2, 3, 4,. Also, the optical frequencies of the pulsed light passing through the path point AB are given as ν + f _f1 , ν + f _f2 , ν + f _f3,.

For the pulsed light that passes through the path point AC, numbers are assigned to the pulsed light that passes through the path point AC in ascending order of 1, 2, 3, 4,. Also, the optical frequencies of the pulsed light passing through the path point AC are given as ν + f _b1 , ν + f _b2 , ν + f _b3,. Note that the pulsed light is input to the path point AC with a delay of τ compared to the path point AB. This is because the pulsed light passes through the delay compensation fiber 5 at the path point AC.

For the pulsed light that passes through the path point ABDEG, numbers are assigned to the pulsed light that passes through the path point ABDEG in ascending order of 1, 2, 3, 4,. Further, the frequency of the pulsed light passing through the path point ABDEG is also given as ν + f _f1 , ν + f _f2 , ν + f _f3 ,.

For the pulsed light passing through the path point ABDFG, numbers are assigned to the pulsed light passing through the path point ABDFG in ascending order of 1, 2, 3, 4,. Further, the frequencies of the pulsed light passing through the path point ABDFG are also given as ν + f _f1 , ν + f _f2 , ν + f _f3 ,. Note that the pulsed light is input to the path point ABDFG with a delay of τ compared to the path point ABDEG. This is because the pulsed light passes through the sensing fiber 9 at the path point ABDFG.

For the pulsed light that passes through the path point ACDEG, numbers are assigned to the pulsed light that passes through the path point ACDEG in ascending order of 1, 2, 3, 4,. Further, the frequencies of the pulsed light passing through the path point ACDEG are also given as ν + f _b1 , ν + f _b2 , ν + f _b3 ,. Note that the pulsed light is input to the path point ACDEG with a delay of τ compared to the path point ABDEG. This is because the pulse light passes through the delay compensation fiber 5 at the path point ACDEG.

For the pulsed light that passes through the path point ACDFG, numbers are assigned to the pulsed light that passes through the path point ACDFG in ascending order of 1, 2, 3, 4,. Also, the frequencies of the pulsed light passing through the path point ACDFG are given as ν + f _b1 , ν + f _b2 , ν + f _b3 ,. Note that the pulsed light is input to the path point ACDFG with a delay of 2τ compared to the path point ABDFG and the path point ACDEG. This is because the pulse light passes through the delay compensation fiber 5 and the sensing fiber 9 at the path point ACDFG.

Here, it is assumed that the delay time by the delay compensation fiber 5 and the delay time by the sensing fiber 9 are the same. For example, the delay time is τ. As a result, ν + f _f1 , ν + f _f2 , ν + f _f3 ,... _Are synchronized with ν + f _b1 , ν + f _b2 , ν + f _b3,. Therefore, (ν + f _f1 ) − (ν + f _b1 ), (ν + f _f2 ) − (ν + f _b2 ), (ν + f _f3 ) − (ν + f _b3 ), etc. can be obtained accurately. Therefore, at the path point G, except for the four pulse lights immediately after the start, there are three kinds of pulse lights I _A , I _B , I _C , and I _A , I _B , I _C , I _A , I _B , ... and will continue.

FIG. 4 is a conceptual diagram of a power spectrum after A / D conversion is performed on I _A , I _B , and I _{C according} to Embodiment 1 of the present invention. For I _A, the center frequency of the beat and sidebands containing the signal detected by the sensing fiber 9 is a f _f1 -f _b1. That is, in I _A , the signal φ (t) is modulated to the beat having the center frequency f _f1 −f _b1 . Also, in the case of I _B, the center frequency of the beat and sidebands containing the signal detected by the sensing fiber 9 is a f _f2 -f _b2. That is, in I _B , the signal φ (t) is modulated to the beat having the center frequency f _f2 −f _b2 . In the case of I _C , the center frequency of the beat and the sideband including the signal detected by the sensing fiber 9 is f _f3 −f _b3 . That is, in I _C , the signal φ (t) is modulated to the beat having the center frequency f _f3 −f _b3 . The demodulator 13 demodulates the signal φ (t) from each of I _A , I _B , and I _C and outputs the result after addition by the adder 221.

(Explanation of effect)
By generating a plurality of beats having different frequencies and combining them by increasing the number of samplings, aliasing noise can be reduced. This is an effect obtained because the signals to be combined are correlated and the noise is uncorrelated. Specifically, signals to be combined with correlation have a large degree of signal reinforcement. On the other hand, uncorrelated noise has a small degree of signal reinforcement. Therefore, a relatively large difference occurs between the signal to be synthesized and the noise depending on the presence or absence of the correlation. That is, noise is reduced.

  In the output waveform, the noise reduction effect can be confirmed by passing the filter through the filter having the same bandwidth as that of the prior art 1. Further, by making the sampling finer, for example, in an application where the timing of the signal needs to be measured precisely, it can be measured more finely than in the past.

In the first embodiment, many pulse lights having different paths interfere with each other. However, as shown in FIG. 4, f _f1 -f _b1 occurs only at I _A. f _f2 −f _b2 occurs only at I _B. f _f3 −f _b3 occurs only at I _C. Therefore, even if other pulse light components leak into the pulse light to be demodulated to some extent due to the band limitation of the O / E converter, the influence on the demodulated output can be reduced.

In order to restore all the generated beats, 1 / (3τ) ≧ 2 × 24 (f _f1 −f _b1 ) according to the sampling theorem. In the first embodiment, as shown in FIG. 4, the three frequencies to be demodulated are three in order from the lowest side. Further, the lowest frequency of beats generated by folding is seven times the limit f _f1 −f _b1 that does not overlap the band to be demodulated. In other words, when folding occurs, beats and sidebands generated by folding are not used for demodulation and beats and sidebands, so that beats and sidebands generated by folding do not enter the band used for demodulation. Make sure the bands overlap. As a result, the sampling frequency is lowered, and the bandwidth of the O / E converter is reduced accordingly. If the bandwidth is narrow, a large number of aliasing does not overlap, so that aliasing noise can be suppressed.

Embodiment 2. FIG.
FIG. 5 is a block diagram showing an example of the configuration of the interference optical fiber sensor according to Embodiment 2 of the present invention.
In the second embodiment, items not particularly described are the same as those in the first embodiment of the present invention, and the same functions and configurations are described using the same reference numerals.

(Description of configuration)
The difference from the first embodiment is that the outputs of the reference signal generators 97 and 98 are different, the processing of the multipliers 101 and 102, the LPFs 111 and 112, the arctangent calculator 121, and the discontinuous point compensation calculator 131. That is, only one set of unit configurations is used, and the adder 221 is not used. The output of the reference signal generator 97 according to the second embodiment of the present invention is a waveform obtained by adding the outputs of the reference signal generator 91, the reference signal generator 93, and the reference signal generator 95 according to the first embodiment of the present invention. It is said. The output of the reference signal generator 98 according to the second embodiment of the present invention is the sum of the outputs of the reference signal generator 92, the reference signal generator 94, and the reference signal generator 96 according to the first embodiment of the present invention. It has a waveform. Therefore, the adder 221 is not necessary.

(Description of operation)
From the output of the pulse light source 2 to the output of the A / D converter of the demodulator 13, the same operation as in the first embodiment of the present invention is performed. On the other hand, the waveforms output from the reference signal generator 97 and the reference signal generator 98 are different from those in the first embodiment of the present invention. Specifically, the waveforms output from the reference signal generator 97 are Δ _A (t) sin 2π (f _1f −f _1b ) t, Δ _B (t) sin 2π (f _2f −f _2b ) t, and Δ _C. (T) Since three waveforms of sin 2π (f _3f −f _3b ) are superimposed, a discontinuous waveform is obtained instead of a sine wave. The waveforms output from the reference signal generator 98 are Δ _A (t) cos 2π (f _1f −f _1b ) t, Δ _B (t) cos 2π (f _2f −f _2b ) t, and Δ _C (t). Since the three waveforms of cos 2π (f _3f −f _3b ) are superimposed, the waveform is not a sine wave but a discontinuous waveform.

Here, according to the equations (6) to (8), the difference between Δ _A (t) and Δ _B (t) is τ, and the difference between Δ _B (t) and Δ _C (t) is τ, and the difference between Δ _C (t) and Δ _A (t) is τ. Therefore, three waveforms, Δ _A (t) sin 2π (f _1f −f _1b ) t, Δ _B (t) sin 2π (f _2f −f _2b ) t, and Δ _C (t) sin 2π (f _3f −f _3b ). The period is changed from 3τ to 1τ. Similarly, Δ _A (t) cos 2π (f _1f −f _1b ) t, Δ _B (t) cos 2π (f _2f −f _2b ) t, and Δ _C (t) cos 2π (f _3f −f _3b ) By superimposing the waveforms, the period is changed from 3τ to 1τ. Therefore, after multiplying the output of the A / D converter 21 and the outputs of the reference signal generators 97 and 98 and passing through the LPFs 111 and 112, the sampling is performed at a frequency three times that of the prior art 1. A waveform is formed. Next, the waveform output from the discontinuous point compensation calculator 131 through the arctangent calculator 121 is the same as the waveform output from the adder 221 according to the first embodiment of the present invention.

(Explanation of effect)
Although the demodulator 16 has a simpler functional configuration than the demodulator 15 of the first embodiment, the same effects as those of the first embodiment can be obtained. That is, three waveforms, Δ _A (t) sin 2π (f _1f −f _1b ) t, Δ _B (t) sin 2π (f _2f −f _2b ) t, and Δ _C (t) sin 2π (f _3f −f _3b ). And a reference signal generator 97 that outputs a waveform obtained by superimposing the waveforms, Δ _A (t) cos 2π (f _1f −f _1b ) t, Δ _B (t) cos 2π (f _2f −f _2b ) t, and Δ _C (t ) Other functions of the demodulator 16 can be simplified by using the reference signal generator 98 that outputs a waveform obtained by superposing the three waveforms of cos 2π (f _3f −f _3b ). Thereby, although it is low-cost, aliasing noise can be reduced by generating a plurality of beats having different frequencies and combining them by increasing the number of samplings.

Embodiment 3 FIG.
FIG. 6 is a block diagram showing an example of the configuration of the interference optical fiber sensor according to Embodiment 3 of the present invention.
In the third embodiment, items not particularly described are the same as those in the first and second embodiments, and the same functions and configurations are described using the same reference numerals.

(Description of configuration)
The differences from the first and second embodiments are that the ratios of the magnitudes of the output frequencies of the modulation signal generators 201 and 202 are different and the output waveforms of the reference signal generators 231 and 232 are different. FIG. 7 is a diagram illustrating an example of the optical frequency and timing of pulsed light according to Embodiment 3 of the present invention. As shown in FIG. 7, the pulse light that is the output waveform of the pulse light source 2 and the substantially rectangular waves of the optical frequency shifters 211 and 212 are synchronized. That is, the frequency of the pulsed light output from the optical frequency shifters 211 and 212 is changed stepwise in accordance with the pulsed light output timing of the pulsed light source 2.

  As shown in FIG. 7, the horizontal axis is time, and the vertical axis is optical frequency. Then, the step-like frequency fluctuation is restored every 2τ. That is, the period of the substantially rectangular wave of the optical frequency shifters 211 and 212 is 2τ, and the frequency is 1 / (2τ). The pulse light output from the pulse light source 2 is given a number in the order of arrival at the optical frequency shifters 211 and 212. For example, numbers are assigned in ascending order such as 1, 2, 3, 4, 5, 6, 7, 8, 9,.

Here, the difference of f _f1 −f _b1 is set to 1. That is, the difference of (ν + f _b1 ) − (ν + f _f1 ) is assumed to be 1. Next, the difference of f _f2 −f _b2 is set to 3. That is, the difference of (ν + f _f2 ) − (ν + f _b2 ) is set to 3. Further, the difference of f _b2 −f _f1 is set to 5. That is, the difference of (ν + f _b2 ) − (ν + f _f1 ) is set to 5. Further, f _f1 −f _b1 is assumed to be 1/14 of the frequency 1 / (3τ). That is, the difference of (ν + f _f1 ) − (ν + f _b1 ) is 1/14 of 1 / (3τ). The reason why the ratio of the magnitude of the output frequency is set by the discrete values of 1, 3, 5 is to reduce aliasing noise. That is, a discrete value is set so as not to cause aliasing. Numbers such as 1, 3, and 5 are examples, and are not limited thereto.

  In other words, the difference between the frequencies is set to a ratio of 1, 3, and 5. In FIG. 7, the description of the frequency parameter t is omitted.

Here, Δ _A (t) and Δ _B (t) of the reference signal generators 231 and 232 of the demodulator 13 are expressed by the following equations (9) and (10).

  As shown in equations (9) and (10), the period is 2τ. That is, the sampling interval is narrower than when the period is 3τ.

(Description of operation)
FIG. 8 is a diagram showing a pulse waveform for explaining the operation of the interference optical fiber sensor according to the third embodiment. As shown in FIG. 8, the numbers of the pulsed light passing through the path point A are given in ascending order of 1, 2, 3, 4,. The optical frequency of each pulsed light is also given as ν.

For the pulsed light passing through the path point AB, numbers are assigned to the pulsed light passing through the path point AB in ascending order of 1, 2, 3, 4,. Also, the optical frequency of the pulsed light passing through the path point AB is given as ν + f _f1 , ν + f _f2,.

For the pulsed light that passes through the path point AC, numbers are assigned to the pulsed light that passes through the path point AC in ascending order of 1, 2, 3, 4,. Also, the optical frequencies of the pulsed light passing through the path point AC are given as ν + f _b1 , ν + f _b2,. Note that the pulsed light is input to the path point AC with a delay of τ compared to the path point AB. This is because the pulsed light passes through the delay compensation fiber 5 at the path point AC.

For the pulsed light that passes through the path point ABDEG, numbers are assigned to the pulsed light that passes through the path point ABDEG in ascending order of 1, 2, 3, 4,. Further, the frequency of the pulsed light passing through the path point ABDEG is given as ν + f _f1 , ν + f _f2 ,...

For the pulsed light passing through the path point ABDFG, numbers are assigned to the pulsed light passing through the path point ABDFG in ascending order of 1, 2, 3, 4,. Further, the frequency of the pulsed light passing through the path point ABDFG is given as ν + f _f1 , ν + f _f2 ,... Note that the pulsed light is input to the path point ABDFG with a delay of τ compared to the path point ABDEG. This is because the pulsed light passes through the sensing fiber 9 at the path point ABDFG.

For the pulsed light that passes through the path point ACDEG, numbers are assigned to the pulsed light that passes through the path point ACDEG in ascending order of 1, 2, 3, 4,. Also, the frequency of the pulsed light passing through the path point ACDEG is given as ν + f _b1 , ν + f _b2 ,. Note that the pulsed light is input to the path point ACDEG with a delay of τ compared to the path point ABDEG. This is because the pulse light passes through the delay compensation fiber 5 at the path point ACDEG.

For the pulsed light that passes through the path point ACDFG, numbers are assigned to the pulsed light that passes through the path point ACDFG in ascending order of 1, 2, 3, 4,. Further, the frequency of the pulsed light passing through the path point ACDFG is also given as ν + f _b1 , ν + f _b2 ,. Note that the pulsed light is input to the path point ACDFG with a delay of 2τ compared to the path point ABDFG and the path point ACDEG. This is because the pulse light passes through the delay compensation fiber 5 and the sensing fiber 9 at the path point ACDFG.

Here, it is assumed that the delay time by the delay compensation fiber 5 and the delay time by the sensing fiber 9 are the same. For example, the delay time is τ. As a result, ν + f _f1 , ν + f _f2 ,... _Are synchronized with ν + f _b1 , ν + f _b2,. Therefore, (ν + f _f1 ) − (ν + f _b1 ), (ν + f _f2 ) − (ν + f _b2 ), etc. can be obtained accurately. Thus, the route point G, except four pulsed light immediately after starting, the pulse light becomes a two _{I A, I B, I A} , I B, I A, I B, followed with ... Will go.

FIG. 9 is a conceptual diagram of a power spectrum after A / D conversion of I _A and I _B in Embodiment 3 of the present invention. For I _A, the center frequency of the beat and sidebands containing the signal detected by the sensing fiber 9 is a f _f1 -f _b1. That is, in I _A , the signal φ (t) is modulated to the beat having the center frequency f _f1 −f _b1 . Also, in the case of I _B, the center frequency of the beat and sidebands containing the signal detected by the sensing fiber 9 is a f _f2 -f _b2. That is, in I _B , the signal φ (t) is modulated to the beat having the center frequency f _f2 −f _b2 . The demodulator 17 demodulates the signal φ (t) from each of I _A and I _B and outputs the demodulated signal.

(Explanation of effect)
Similar to the first embodiment, aliasing noise can be reduced by generating a plurality of beats having different frequencies and increasing the number of samplings. Further, as shown in the equations (9) and (10), by making the sampling interval finer, in applications where it is necessary to measure the timing of the signal precisely, it can be measured more finely than in the past. .

Further, since the sampling frequency can be made lower than that in the first embodiment, the bandwidth of the O / E converter 12 can be made narrower than that in the first embodiment. Thereby, aliasing noise can be suppressed. However, in Embodiment 3 of the present invention, a beat having the same frequency as the frequency of the pulsed light to be demodulated is generated in both I _A and I _B. Specifically, as shown in FIG. 9, the I _A, f _f1 -f _b1 and f _f2 -f _b2 occurs. Of these, in I _A , f _f1 −f _b1 is the beat and sideband frequency including the signal detected by the sensing fiber 9. Further, the I _B, f _f1 -f _b1 and f _f2 -f _b2 occurs. Among these, in I _B , f _f2 −f _b2 is the beat and sideband frequencies including the signal detected by the sensing fiber 9. Therefore, due to the band limitation by the O / E converter 12, another noise may be easily generated due to leakage of the previous pulse light into the pulse light to be demodulated.

Embodiment 4 FIG.
FIG. 10 is a block diagram showing an example of the configuration of the interference optical fiber sensor according to Embodiment 4 of the present invention.
In the fourth embodiment, items that are not particularly described are the same as those in the first to third embodiments, and the same functions and configurations are described using the same reference numerals.

(Description of configuration)
The difference from the first to third embodiments of the present invention is that the output timing of the frequency signal output from the modulation signal generator 205, the output timing of the frequency signal output from the modulation signal generator 206, and the reference signal generator 233 to 238 are output waveforms.

  FIG. 11 is a diagram illustrating an example of the optical frequency and timing of pulsed light according to Embodiment 4 of the present invention. As shown in FIG. 11, the frequency signals output from the modulation signal generators 205 and 206 are output with a period of 3τ. For this reason, the interval is three times longer than that in the case of the period τ of the modulation signal generators 201 to 204 according to the first to third embodiments of the present invention. Further, the pulsed light that is the output waveform of the pulsed light source 2 and the substantially rectangular waves of the optical frequency shifters 211 and 212 are synchronized. That is, the frequency of the pulsed light output from the optical frequency shifters 211 and 212 is changed stepwise in accordance with the pulsed light output timing of the pulsed light source 2. As shown in FIG. 11, the horizontal axis is time, and the vertical axis is optical frequency. And the fluctuation of the stepped frequency returns to the original every 9τ. That is, the period of the substantially rectangular wave of the optical frequency shifters 211 and 212 is 9τ, and the frequency is 1 / (9τ). The pulse light output from the pulse light source 2 is given a number in the order of arrival at the optical frequency shifters 211 and 212. For example, numbers are assigned in ascending order such as 1, 2, 3, 4, 5, 6, 7, 8, 9,.

Further, the reference signal generators 233 to 238 have different definitions of Δ _A (t), Δ _B (t), and Δ _C (t). Specifically, the sampling intervals are different as represented by equations (11) to (13).

That is, since the intervals of f _1f −f _1b , f _2f −f _2b , and f _3f −f _3b are 3τ, the intervals of Δ _A (t), Δ _B (t), and Δ _C (t) are also 3τ. Is defined to be In short, the output timings of the modulation signal generators 205 and 206 and the sampling intervals of the reference signal generators 233 to 238 are set to be the same. Here, the difference of f _f1 −f _b1 is set to 1. That is, the difference of (ν + f _b1 ) − (ν + f _f1 ) is assumed to be 1. Next, the difference of f _f2 −f _b2 is set to 3. That is, the difference of (ν + f _f2 ) − (ν + f _b2 ) is set to 3. Further, the difference of f _f3 −f _b3 is set to 5. That is, a difference of (ν + f _f3 ) − (ν + f _b3 ) is set to 5. The reason why the ratio of the magnitude of the output frequency is set by the discrete values of 1, 3, 5 is to reduce aliasing noise. That is, a discrete value is set so as not to cause aliasing. Numbers such as 1, 3, and 5 are examples, and are not limited thereto.

(Description of operation)
FIG. 12 is a diagram showing pulse waveforms for explaining the operation of the interference optical fiber sensor according to the fourth embodiment of the present invention. As shown in FIG. 12, for the pulsed light passing through the path point A, the numbers are given in ascending order as 1, 2, 3, 4,.

For the pulsed light that passes through the path point ABDE1G, numbers are assigned to the pulsed light that passes through the path point ABDE1G in ascending order of 1a1, 2a1, 3a1, 4a1,. Further, the frequencies of the pulsed light passing through the path point ABDE1G are given as ν + f _f1 , ν + f _f2 , ν + f _f3 ,.

For the pulsed light that passes through the path point ABDF1G, numbers are assigned to the pulsed light that passes through the path point ABDF1G in ascending order as 1b1, 2b1, 3b1, 4b1,. Further, the frequencies of the pulsed light passing through the path point ABDF1G are also given as ν + f _f1 , ν + f _f2 , ν + f _f3 ,. The pulsed light is input to the path point ABDF1G with a delay of τ compared to the path point ABDE1G. This is because the pulsed light passes through the sensing fiber 71 at the path point ABDF1G.

For the pulsed light passing through the path point ACDE1G, numbers are assigned to the pulsed light passing through the path point ACDE1G in ascending order of 1c1, 2c1, 3c1, 4c1,. Further, the frequency of the pulsed light passing through the path point ACDE1G is given as ν + f _b1 , ν + f _b2 , ν + f _b3 ,. The pulsed light is input to the path point ACDE1G with a delay of τ compared to the path point ABDE1G. This is because the pulse light passes through the delay compensation fiber 5 at the path point ACDE1G.

In addition, for the pulsed light passing through the path point ACDF1G, numbers are sequentially assigned to the pulsed light passing through the path point ACDF1G in ascending order of 1d1, 2d1, 3d1, 4d1,. Further, the frequencies of the pulsed light passing through the path point ACDF1G are given as ν + f _b1 , ν + f _b2 , ν + f _b3 ,. Note that the pulsed light is input to the path point ACDF1G with a delay of 2τ compared to the path point ABDE1G. This is because the pulse light passes through the delay compensation fiber 5 and the sensing fiber 71 at the path point ACDF1G.

For the pulsed light that passes through the path point ABDE2G, numbers are assigned to the pulsed light that passes through the path point ABDE2G in ascending order of 1a2, 2a2, 3a2, 4a2,. Further, the frequencies of the pulsed light passing through the path point ABDE2G are given as ν + f _f1 , ν + f _f2 , ν + f _f3 ,.

For the pulsed light that passes through the path point ABDF2G, numbers are assigned to the pulsed light that passes through the path point ABDF2G in ascending order as 1b2, 2b2, 3b2, 4b2,. Further, the frequencies of the pulsed light passing through the path point ABDF2G are given as ν + f _f1 , ν + f _f2 , ν + f _f3 ,. The pulsed light is input to the path point ABDF2G with a delay of τ compared to the path point ABDE2G. This is because the pulsed light passes through the sensing fiber 72 at the path point ABDF2G.

For the pulsed light that passes through the path point ACDE2G, numbers are assigned to the pulsed light that passes through the path point ACDE2G in ascending order of 1c2, 2c2, 3c2, 4c2,. Also, the frequencies of the pulsed light passing through the path point ACDE2G are given as ν + f _b1 , ν + f _b2 , ν + f _b3 ,. Note that the pulsed light is input to the path point ACDE2G with a delay of τ compared to the path point ABDE2G. This is because pulse light passes through the delay compensation fiber 5 at the path point ACDE2G.

Further, for the pulsed light passing through the path point ACDF2G, numbers are sequentially assigned to the pulsed light passing through the path point ACDF2G in ascending order as 1d2, 2d2, 3d2, 4d2,. Also, the frequencies of the pulsed light passing through the path point ACDF2G are given as ν + f _b1 , ν + f _b2 , ν + f _b3 ,. Note that the pulsed light is input to the path point ACDF2G with a delay of 2τ as compared with the path point ABDE2G. This is because the pulse light passes through the delay compensation fiber 5 and the sensing fiber 72 at the path point ACDF2G.

In addition, for the pulsed light that passes through the path point ABDE3G, numbers are assigned to the pulsed light that passes through the path point ABDE3G in ascending order as 1a3, 2a3, 3a3, 4a3,. Also, the frequencies of the pulsed light passing through the path point ABDE3G are given as ν + f _f1 , ν + f _f2 , ν + f _f3 ,.

For the pulsed light that passes through the path point ABDF3G, numbers are assigned to the pulsed light that passes through the path point ABDF3G in ascending order as 1b3, 2b3, 3b3, 4b3,. Further, the frequencies of the pulsed light passing through the path point ABDF3G are given as ν + f _f1 , ν + f _f2 , ν + f _f3 ,. The pulsed light is input to the path point ABDF3G with a delay of τ compared to the path point ABDE3G. This is because the pulsed light passes through the sensing fiber 73 at the path point ABDF3G.

For the pulsed light that passes through the path point ACDE3G, numbers are assigned to the pulsed light that passes through the path point ACDE3G in ascending order of 1c3, 2c3, 3c3, 4c3,. Further, the frequencies of the pulsed light passing through the path point ACDE3G are given as ν + f _b1 , ν + f _b2 , ν + f _b3 ,. Note that the pulsed light is input to the path point ACDE3G with a delay of τ compared to the path point ABDE3G. This is because the pulse light passes through the delay compensation fiber 5 at the path point ACDE3G.

For the pulsed light that passes through the path point ACDF3G, numbers are assigned to the pulsed light that passes through the path point ACDF3G in ascending order of 1d3, 2d3, 3d3, 4d3,. Further, the frequency of the pulsed light passing through the path point ACDF3G is given as ν + f _b1 , ν + f _b2 , ν + f _b3 ,. Note that the pulsed light is input to the path point ACDF3G with a delay of 2τ compared to the path point ABDE3G. This is because the pulse light passes through the delay compensation fiber 5 and the sensing fiber 73 at the path point ACDF3G.

  A time difference of 3τ is set between the pulsed light passing through the path point ABDE1G and the pulsed light passing through the path point ABDE2G. In addition, a time difference of 3τ is set between the pulsed light passing through the path point ABDE2G and the pulsed light passing through the path point ABDE3G.

Here, it is assumed that the delay time due to the delay compensation fibers 5, 81, and 82 and the delay time due to the sensing fibers 71, 72, and 73 are the same. For example, the delay time is τ. As a result, ν + f _f1 , ν + f _f2 , ν + f _f3 ,... _Are synchronized with ν + f _b1 , ν + f _b2 , ν + f _b3,. Therefore, (ν + f _f1 ) − (ν + f _b1 ), (ν + f _f2 ) − (ν + f _b2 ), (ν + f _f3 ) − (ν + f _b3 ), etc. can be obtained accurately. Therefore, at the path point G, except for 10 pulse lights immediately after the start, there are three kinds of pulse lights I _A , I _B , I _c , and I _A , I _B , I _c , I _A , I _B, so that I _c, go on with .... The demodulator 18 demodulates the signals φ ₁ (t), φ ₂ (t), and φ ₃ (t) from I _A , I _B , and I _c .

(Explanation of effect)
In the fourth embodiment of the present invention, three signals are obtained from one pulsed light by using the sensing fibers 71, 72, 73 and shifting the timing of each pulsed light. That is, the time difference between f _f1 and f _f2 is set to 3τ, the time difference between f _f2 and f _f3 is set to 3τ, the time difference between f _f3 and f _f1 is set to 3τ, and f _b1 and f _b2 Is set to 3τ, the time difference between f _b2 and f _b3 is set to 3τ, and the time difference between f _b3 and f _b1 is set to 3τ, so that f _f1 −f _b1 and f _f2 −f _b2 , F _f3 −f _b3 appear at the same time. A plurality of signals detected by a plurality of sensing fibers are alternately included in one frequency beat. For example, of the beats having a frequency of f _f1 −f _b1, the signal φ ₁ (t) is used for the pulse light of I _A , the signal φ ₂ (t) is used for the pulse light of I _B , and the signal φ is the signal of the pulse light of I _C. φ ₃ (t) is included. By demodulating beats of three frequencies simultaneously, three signals can be obtained simultaneously.

  In short, pulse lights having different frequencies are gradually shifted in time and propagated in the path, so that many pulse lights are propagated in parallel at the same time. As a result, many signals can be obtained at one time. Therefore, in the prior art 2, a time interval of 9τ is necessary to obtain the signal obtained once, whereas in the fourth embodiment of the present invention, the signal obtained once is obtained again. Can now be done at 3τ time intervals. Therefore, the cycle was shortened. Therefore, the sampling frequency is increased and aliasing noise can be reduced.

Embodiment 5. FIG.
FIG. 13 is a block diagram showing an example of the configuration of the interference optical fiber sensor according to Embodiment 5 of the present invention.
In the fifth embodiment, items that are not particularly described are the same as those in the first to fourth embodiments, and the same functions and configurations are described using the same reference numerals.

(Description of configuration)
The difference from the first to fourth embodiments of the present invention is that the output timing of the frequency signal output from the modulation signal generators 207 and 208 and the magnitude of each frequency signal output from the modulation signal generators 207 and 208. , A point where a plurality of sensing fibers are grouped into N pieces, and an output waveform of a reference signal.

FIG. 14 is a diagram illustrating an example of the optical frequency and timing of pulsed light according to the fifth embodiment of the present invention. As shown in FIG. 14, the frequency signals output from the modulation signal generators 207 and 208 are output with a half cycle kMτ. For this reason, the period of the pulsed light that is the output waveform of the pulsed light source 2 is set to be kMτ. Further, the modulation signal generators 207 and 208 have a difference between ν + f _f1 and ν + f _b1 of 2i−1, a difference between ν + f _f2 and ν + f _b2 of 2i−1, and a difference between ν + f _b2 and ν + f _f1. 2N + 1. That is, the ratio of f _f1 −f _b1 , f _f2 −f _b2 , and f _b2 −f _f1 is set to 2i−1, 2i−1, and 2N + 1. However, i is assumed to be a natural number such as 1, 2,.

  Here, N is the number of beat frequencies to be demodulated, and M is the number of signals to be self-division multiplexed. In the fourth embodiment of the present invention, a case where N = 2 and M = 2 will be described. k is one of the coefficients of the pulse repetition period output from the pulse light source 2 and the sensing fiber round-trip propagation time τ, and is usually set to 2 or 3. In the fourth embodiment of the present invention, a case where k = 3 will be described. Then, when the pulsed light sequentially output from the pulsed light source 2 is branched and sent to the O / E converter through the propagation path, each path point is set so as not to overlap in the same time. Delay fibers 5, 83, 84, and 85 are attached between them.

  Under such a premise, the output of the optical amplifier 7 is branched by the optical coupler 301 and sent to N groups. Each group of mirrors, for example, the mirror 331 in the case of the group 1 and the like in the case of the group 2 Is reflected by a mirror 335 or the like. The pulse light multiplexed and transmitted through such a propagation path is received by the O / E converter 12 and input to the A / D converter of the demodulator 19.

The demodulator 19 includes reference signal generators 239 to 246. The reference signal generators 239 to 246 multiply N by multiplying the reference signal of sin 2π (f _1f −f _1b ) to sin 2π (f _Nf −f _Nb ) and the sampling function represented by the equations (14) to (19). N × M obtained by multiplying × M pairs of reference signals, a reference signal of cos 2π (f _1f −f _1b ) to cos 2π (f _Nf −f _Nb ), and a sampling function represented by equations (14) to (19) Among the pair of reference signals, a reference signal added with a reference signal corresponding to the timing of the beat frequency including the signal to be demodulated is output. Then, the demodulator 19 multiplies the reference signal corresponding to each signal by the output of the A / D converter 21 and performs phase demodulation.

(Description of operation)
FIG. 15 is a diagram showing pulse waveforms for explaining the operation of the interference optical fiber sensor according to the fifth embodiment of the present invention. As shown in FIG. 15, for the pulsed light that passes through the path point A, numbers are assigned in ascending order as 1, 2, 3, 4,.

In addition, for the pulsed light that passes through the path point ABDE11G, numbers are assigned to the pulsed light that passes through the path point ABDE11G in ascending order as 1a11, 2a11, 3a11, 4a11,. Also, the frequency of the pulsed light passing through the path point ABDE11G is given as ν + f _f1 , ν + f _f2 ,.

For the pulsed light that passes through the path point ABDF11G, numbers are assigned to the pulsed light that passes through the path point ABDF11G in ascending order as 1b11, 2b11, 3b11, 4b11,. Also, the frequency of the pulsed light passing through the path point ABDF1G is given as ν + f _f1 , ν + f _f2 ,. Note that the pulsed light is input to the route point ABDF11G with a delay of τ compared to the route point ABDE11G. This is because the pulsed light passes through the sensing fiber 321 at the path point ABDF11G.

In addition, for the pulsed light that passes through the path point ACDE11G, numbers are assigned to the pulsed light that passes through the path point ACDE11G in ascending order, such as 1c11, 2c11, 3c11, 4c11,. Further, the frequency of the pulsed light passing through the path point ACDE11G is given as ν + f _b1 , ν + f _b2 ,. Note that the pulsed light is input to the path point ACDE11G with a delay of τ compared to the path point ABDE11G. This is because the pulse light passes through the delay compensation fiber 5 at the path point ACDE11G.

Further, for the pulsed light passing through the path point ACDF11G, numbers are assigned to the pulsed light passing through the path point ACDF11G in ascending order as 1d11, 2d11, 3d11, 4d11,. Also, the frequency of the pulsed light passing through the path point ACDF11G is given as ν + f _b1 , ν + f _b2 ,. The pulsed light is input to the path point ACDF11G with a delay of 2τ compared to the path point ABDE11G. This is because the pulse light passes through the delay compensation fiber 5 and the sensing fiber 321 at the path point ACDF11G.

For the pulsed light that passes through the path point ABDE12G, numbers are assigned to the pulsed light that passes through the path point ABDE12G in ascending order as 1a12, 2a12, 3a12, 4a12,. Further, the frequency of the pulsed light passing through the path point ABDE12G is given as ν + f _f1 , ν + f _f2 ,.

Further, for the pulsed light that passes through the path point ABDF12G, numbers are sequentially assigned to the pulsed light that passes through the path point ABDF12G in ascending order of 1b12, 2b12, 3b12, 4b12,. Also, the frequency of the pulsed light passing through the path point ABDF12G is given as ν + f _f1 , ν + f _f2 ,... Note that the pulsed light is input to the path point ABDF12G with a delay of τ compared to the path point ABDE12G. This is because the pulsed light passes through the sensing fiber 322 at the path point ABDF12G.

For the pulsed light passing through the path point ACDE12G, numbers are assigned to the pulsed light passing through the path point ACDE12G in ascending order of 1c12, 2c12, 3c12, 4c12,. Also, the frequency of the pulsed light passing through the path point ACDE12G is given as ν + f _b1 , ν + f _b2 ,. Note that the pulsed light is input to the path point ACDE12G with a delay of τ compared to the path point ABDE12G. This is because the pulse light passes through the delay compensation fiber 5 at the path point ACDE12G.

Further, for the pulsed light passing through the path point ACDF12G, numbers are sequentially assigned to the pulsed light passing through the path point ACDF12G in ascending order of 1d12, 2d12, 3d12, 4d12,. Also, the frequency of the pulsed light passing through the path point ACDF12G is given as ν + f _b1 , ν + f _b2 ,. The pulsed light is input to the path point ACDF12G with a delay of 2τ compared to the path point ABDE12G. This is because the pulsed light passes through the delay compensation fiber 5 and the sensing fiber 322 at the path point ACDF12G.

In addition, for the pulsed light that passes through the path point ABDE21G, numbers are assigned to the pulsed light that passes through the path point ABDE21G in ascending order as 1a21, 2a21, 3a21, 4a21,. The frequencies of the pulsed light passing through the path point ABDE21G are ν + f _f1 , ν + f _f2 ,.

In addition, for the pulsed light that passes through the path point ABDF21G, numbers are assigned to the pulsed light that passes through the path point ABDF21G in ascending order as 1b21, 2b21, 3b21, 4b21,. Further, the frequency of the pulsed light passing through the path point ABDF21G is given as ν + f _f1 , ν + f _f2 ,. Note that the pulsed light is input to the route point ABDF21G with a delay of τ compared to the route point ABDE21G. This is because the pulsed light passes through the sensing fiber 323 at the path point ABDF21G.

Further, for the pulsed light passing through the path point ACDE21G, numbers are assigned to the pulsed light passing through the path point ACDE21G in ascending order as 1c21, 2c21, 3c21, 4c21,. Also, the frequency of the pulsed light passing through the path point ACDE21G is given as ν + f _b1 , ν + f _b2 ,. The pulsed light is input to the path point ACDE21G with a delay of τ compared to the path point ABDE21G. This is because the pulse light passes through the delay compensation fiber 5 at the path point ACDE21G.

For the pulsed light that passes through the path point ACDF21G, numbers are assigned to the pulsed light that passes through the path point ACDF21G in ascending order of 1d21, 2d21, 3d21, 4d21,. Also, the frequency of the pulsed light passing through the path point ACDF21G is given as ν + f _b1 , ν + f _b2 ,. The pulsed light is input to the path point ACDF21G with a delay of 2τ compared to the path point ABDE21G. This is because the pulse light passes through the delay compensation fiber 5 and the sensing fiber 323 at the path point ACDF21G.

For the pulsed light that passes through the path point ABDE22G, numbers are assigned to the pulsed light that passes through the path point ABDE22G in ascending order as 1a22, 2a22, 3a22, 4a22,. Also, the frequency of the pulsed light passing through the path point ABDE22G is given as ν + f _f1 , ν + f _f2 ,.

Further, for the pulsed light that passes through the path point ABDF22G, numbers are sequentially assigned to the pulsed light that passes through the path point ABDF22G in ascending order of 1b22, 2b22, 3b22, 4b22,. Also, the frequency of the pulsed light passing through the path point ABDF22G is given as ν + f _f1 , ν + f _f2 ,... The pulsed light is input to the path point ABDF22G with a delay of τ compared to the path point ABDE22G. This is because the pulsed light passes through the sensing fiber 324 at the path point ABDF22G.

For the pulsed light that passes through the path point ACDE22G, numbers are assigned to the pulsed light that passes through the path point ACDE22G in ascending order of 1c22, 2c22, 3c22, 4c22,. Also, the frequency of the pulsed light passing through the path point ACDE22G is given as ν + f _b1 , ν + f _b2 ,. The pulsed light is input to the path point ACDE22G with a delay of τ compared to the path point ABDE22G. This is because the pulse light passes through the delay compensation fiber 5 at the path point ACDE22G.

Further, for the pulsed light passing through the path point ACDF22G, numbers are assigned to the pulsed light passing through the path point ACDF22G in ascending order of 1d22, 2d22, 3d22, 4d22,. Also, the frequency of the pulsed light passing through the path point ACDF22G is given as ν + f _b1 , ν + f _b2 ,. Note that the pulsed light is input to the path point ACDF22G with a delay of 2τ compared to the path point ABDE22G. This is because the pulsed light passes through the delay compensation fiber 5 and the sensing fiber 324 at the path point ACDF22G.

  A time difference of 3τ is set between the pulsed light passing through the path point ABDE11G and the pulsed light passing through the path point ABDE12G. Further, a time difference of 3τ is set between the pulsed light passing through the path point ABDE12G and the pulsed light passing through the path point ABDE21G. A time difference of 3τ is set between the path point ABDE21G and the pulsed light passing through the ABDE22G.

Therefore, at the path point G, except for kMN + 1 pulse light immediately after the start, the pulse light is of the kMN type and continues as I ₁₁ , I ₁₂ , I ₂₁ , I ₂₂ ,. The demodulator 19 samples the signals detected by the sensing fibers 321, 322, 323, and 324 and demodulates the phase.

(Explanation of effect)
In the prior art 2, only M multiplexed transmissions that are time-division multiplexed are performed. In contrast, in the fifth embodiment of the present invention, M × N signals obtained by multiplying time-division-multiplexed M signals and N-multiplexed signals with different beat frequencies are multiplexed and transmitted. Can do.

(Explanation of usage)
(1) In all the embodiments, the method of changing the frequency of the modulation signal generator has been described as the method of changing the frequency of the light. However, the number of times the optical frequency shifter passes, and other methods such as switching the path of the multistage frequency shifter are not used. You can also change the frequency of light.
(2) In all the embodiments, the example in which the frequency of light is changed stepwise has been shown. However, even if the frequency is not stepwise, the operation can be similarly performed by changing the difference between the frequencies of the two lights. .
(3) In Embodiment 1 of the present invention, an example is shown in which the phase is demodulated for each frequency and then added. In Embodiments 2 to 5 of the present invention, examples in which a reference signal obtained by adding a plurality of frequency reference signals is used. In addition, addition can be performed at other positions in the phase demodulation process.

(4) In Embodiments 1, 2, and 4 of the present invention, an example using three beat frequencies is shown. In the third and fifth embodiments of the present invention, examples using two beat frequencies are shown. Besides this, other numbers of beat frequencies can be used. That is, the number of beat frequencies may be arbitrary and is not limited.
(5) In the fifth embodiment of the present invention, an example in which the beat frequency multiplexing number is set to 2 and the time division multiplexing number is set to 2 has been described, but the number of M and N is changed. Thus, the multiplexing number can be changed.
(6) In the first, second, and third embodiments of the present invention, an example in which a signal is included in all the pulsed light has been shown. You can get the effect of just increasing the number.

(7) In the first to fifth embodiments of the present invention, the example in which the Michelson interferometer is configured by attaching the optical coupler and the mirror to the sensing fiber has been described. However, instead of the Mach-Zehnder interferometer and the mirror, FBG (Fiber It is also possible to use an interferometer or the like using Bragg grating.
(8) In Embodiments 1 to 5 of the present invention, an example in which pulsed light is branched by an optical coupler has been shown.
(9) In the first to fifth embodiments of the present invention, the example using the reference signal obtained by multiplying the reference signal corresponding to the beat frequency and the timing signal to be sampled has been described, but the reference signal corresponding to the sampling and the beat frequency is used. Can be performed separately.
(10) In the first to fifth embodiments of the present invention, an example in which A / D conversion is performed and then demodulated by digital processing has been described. However, a part or all of the demodulator can be an analog processing demodulator.
(11) Although the same phase demodulation method is shown in the first to fifth embodiments of the present invention, other phase demodulation methods can also be used.

(12) In the fifth embodiment of the present invention, an example is shown in which an interferometer and an optical coupler that multiplex beat frequencies are connected in parallel, and an interferometer and an optical coupler that perform time division multiplexing are connected in series. May be connected in other forms, such as a combination of parallel and series.
(13) In the fifth embodiment of the present invention, an example in which the multiplexing of the beat frequency and the time division multiplexing are used is shown, but it can be used in combination with other multiplexing methods such as wavelength branch multiplexing.

  1 Oscillator 2 Pulse light source 3, 6, 8, 31, 32, 33, 41, 42, 51, 52, 301, 302, 303, 304, 305, 306, 307, 308, 309, 310 Optical coupler, 4 Optical frequency shifter 5, 81, 82, 83, 84, 85 Delay compensation fiber, 7 Optical amplifier, 9, 71, 72, 73, 321, 322, 323, 324 Sensing fiber 10, 11, 61, 62, 63 64, 65, 66, 331, 332, 333, 334, 335, 336, 337, 338 mirror, 12 O / E converter, 13, 14, 15, 16, 17, 18, 19 demodulator, 21 A / D converter, 22, 23, 91, 92, 93, 94, 95, 96, 97, 98, 231, 232, 233, 234, 235, 236, 237, 238, 23 9, 240, 241, 242, 243, 244, 245, 246 Reference signal generator, 24, 25, 101, 102, 103, 104, 105, 106, 107, 108 Multiplier, 26, 27, 111, 112, 113, 114, 115, 116, 117, 118 LPF, 28, 121, 122, 123, 124 Inverse tangent calculator, 29, 131, 132, 133, 134 Discontinuous point compensation calculator, 201, 202, 203, 204 205, 206, 207, 208 Modulation signal generator 211, 212 Optical frequency shifter, 221 Adder.

Claims (5)

A light source that outputs pulsed light;
A modulation signal generator for generating a signal of a specific frequency;
An optical frequency shifter, connected to the modulation signal generator, for shifting the pulsed light output from the light source by the specific frequency;
A first optical coupler that inputs a plurality of pulse lights shifted by the optical frequency shifter to the same optical fiber;
A plurality of sensing fibers for detecting measurement signals;
A plurality of second optical couplers connected to each of the plurality of sensing fibers and generating beats including signals detected by the connected sensing fibers;
A demodulator for detecting the measurement signal from signals output from the plurality of sensing fibers;
With
The modulation signal generator is
Generating different frequencies so that signals detected by one sensing fiber are respectively included in a plurality of beats having different frequencies;
The optical frequency shifter is
Shifting the pulsed light by the specific frequency based on the different frequencies output from the modulation signal generator;
The second optical coupler is
It generates multiple beats with different frequencies at the same time,
The sensing fiber is
The measurement signal is detected by modulating and outputting the phase of the pulsed light that has passed through the first optical coupler and any one of the second optical couplers based on the measurement signal. Interferometric optical fiber sensor. The demodulator
The interference type optical fiber sensor according to claim 1, wherein a plurality of signals calculated based on the plurality of beats are synthesized. The demodulator
A reference signal generator for sampling a signal output from the sensing fiber;
The reference signal generator is
The interference type optical fiber sensor according to claim 1 or 2, wherein a plurality of reference signals corresponding to beats of a plurality of frequencies and having different sampling intervals are generated. The interference type according to any one of claims 1 to 3, wherein a beat and a sideband generated by folding in a beat and a sideband that are not used for demodulation by the demodulator overlap each other. Optical fiber sensor. The interference type optical fiber sensor according to any one of claims 1 to 3, wherein a plurality of signals detected by the plurality of sensing fibers are alternately included in a beat of one frequency.

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