The present invention relates to a three-dimensional position measurement system for measuring a three-dimensional position of a cable or pipe by utilizing the phenomena of Brillouin frequency shift, and/or Rayleigh frequency shift or Rayleigh scattering phase shift in a plurality of optical fibers wound around the cable or pipe.
In order to prevent collapse and ensure safety during excavation of a tunnel, there has been disclosed a system that includes a plurality of optical fibers straightly installed to an extremely long steel pipe in its longitudinal direction, to monitor movement of the ground during the excavation by measuring strain behavior of the steel pipe by utilizing Brillouin frequency shifts caused by a strain applied to these optical fibers (see Non-Patent Document 1 for example).
There has also been disclosed a distributed optical fiber pressure sensor cable for measuring accurately a pressure value that is constituted with a middle core formed of a flexible tube; pressure measuring optical fibers helically wound around the middle core; axial strain compensating optical fibers embedded in the thickness of the middle core; temperature compensating optical fibers with an extra length, loosely fitted inside the middle core together with a tensile resistance body; and a flexible outermost layer covering the outside of the middle core (see Patent Document 1 for example).
The system of Non-Patent Document 1 for measuring strain behavior of the steel pipe using optical fibers during excavation of a tunnel, since it uses a plurality of optical fibers, can measure a strain caused by a plurality of factors accompanied by axial stretch and bend of the steep pipe, but cannot measure a strain caused by axial torsion of the steel pipe because the optical fibers are installed straight.
In the pressure measurement with the pressure sensor cable of Patent Document 1 using the pressure measurement optical fibers wound helically around the core, a strain detected by the pressure measurement optical fibers contains a strain component caused by temperature change and a strain component in the axial direction. In order to eliminate these components, a plurality of optical fibers are used to obtain accurately the amount of strain due to pressure by subtracting the amounts of strains obtained by the temperature compensating optical fibers and the axial strain compensating optical fibers from the amount of strain detected by the pressure measuring optical fibers. Furthermore, in order to measure correct pressure, the effect of bending is eliminated by shortening the helical pitch, i.e., shortening the width of one complete helix turn less than the spatial resolution of the measuring instrument. However, the effect of torsional deformation is not taken into account.
The present invention is made in light of the above problems and aims at providing a three-dimensional position measurement system that is capable of accurately measuring a three-dimensional position of a deformed connecting body such as a cable connecting a target object to a strain measurement unit, by utilizing Brillouin frequency shifts, and/or Rayleigh frequency shifts or Rayleigh scattering phase shifts occurring in a plurality of optical fibers, which are helically installed in a plurality of tubular installation layers covering the outer surface of the connecting body, deformed by a strain produced in the connecting body by bend, torsion, and/or stretch such as due to external force.
A three-dimensional position measurement system according to the present invention comprises a connecting body including:
According to the present invention, a pressure, a temperature and respective strains produced by bend, stretch, and torsion due to effects of the pressure and temperature can be simultaneously measured with accuracy at given three-dimensional positions of a cable or pipe, i.e., a connecting body by utilizing phenomena of Brillouin frequency shifts and/or Rayleigh frequency shifts, or Brillouin frequency shifts and/or Rayleigh scattering phase shifts occurring in optical fibers installed in the cable or pipe, i.e., the connecting body, thereby bringing about a significant effect of enabling measurement of each three-dimensional position of the connecting body after deformed.
When light is incident into an optical fiber and its scattered light is frequency-analyzed, there is observed scattered light such as Rayleigh scattered light having a frequency approximately the same as that of the incident light and Brillouin scattered light having a frequency different from that of the incident light by the order of a few to several tens GHz. The frequency difference between the incident light and the scattered light is, for example, a Brillouin frequency. By utilizing the characteristics that the Brillouin frequency varies with stain, temperature, and/or pressure applied to the optical fiber, stain, temperature, and/or pressure applied to the optical fiber can conversely be determined from Brillouin frequency shifts (see, for example, JP2011-053146A for the measurement principle). In particular, measurement utilizing both Brillouin frequency shifts and Rayleigh frequency shifts is referred to as hybrid measurement (the same applies hereinafter). In addition, a phenomenon that the phase of Rayleigh scattered light varies with strain applied to an optical fiber can be used instead of the measurement of Rayleigh frequency shifts (see Patent Document 2 for the measurement principle). In the following, a description is firstly made of a case to which the hybrid measurement is applicable, then a description is made of a case of a solitary measurement using Brillouin frequency shifts only, for a case necessary to take pressure and temperature effects into account; and finally a description is made of measurement for a case unnecessary to take pressure and temperature effects into account.
b) is an enlarged cross-sectional view of the connecting body. Two sets of two optical fibers split from the four optical fibers 2 are arranged in layers at radial positions different from each other, and the two fibers of each set are arranged at angle positions different from each other by 180 degrees (see
Next, a description is made of the reason why each three-dimensional position of the connecting body after deformed can be measured accurately with the three-dimensional position measurement system thus configured. The connecting body is subject to deformation due to bend, stretch, and torsion, which are mechanically loaded to a cylindrical shaped body, assuming that the connecting body is placed under a constant temperature and pressure, and subject to additional deformation due to temperature and pressure changes when the connecting body is placed under such a changing condition. Accordingly, it is necessary to evaluate effects of all the above parameters on the Brillouin frequency shifts and the Rayleigh frequency shifts. Hence, the evaluation of these effects is explained below in turn. First of all, strains produced by basic loads shown in
A beam (a cylindrical round bar) shown in
First, strains produced by the axial force F applied to the round bar are expressed by Eq. (1) using stresses σr (=0), σθ(=0), and σz(=F/As):
where As is a cross-sectional area of the round bar, E is its Young's modulus, and V is its Poisson's ratio.
Next, the bending moment is considered. A curvature k of the cable is expressed by Eq. (2) using a second moment of area I and the bending moment M:
Furthermore, assuming either one of Mx and My to be M and a distance from the neutral plane as η, strains produced by the bending moment is expressed by Eq. (3) using stresses σr(=0), σθ(=0), and σz(=−Mη/I) due to the bending moment:
Next, a torsion rate (specific twist angle) Y due to the torsional moment Mz is given by Eq. (4):
And a stain is expressed by Eq. (5) using a stress σz(=Mz r/J):
where J is a second polar moment and G is a shearing modulus of elasticity. Furthermore, considering effects of pressure and temperature on stretch, strains caused by pressure and temperature can be evaluated using the following Eqs. (6) and (7) under the condition of no constraint on the axial displacement. Specifically, strains caused by pressure can be expressed by Eq. (6) using stresses σr(=−P), σθ(=−P), and σz(=−P) (when an external pressure P is applied):
And strains caused by a temperature change ΔT can be expressed by Eq. (7):
where α is a coefficient of thermal expansion.
Letting ΔεF, ΔεM
where Cij are sensitivity coefficients specific to each optical fiber; C′ij are sensitivity coefficients that directly correlate ΔP, ΔT with the Brillouin frequency shift; ΔεP, ΔεT denote strain changes caused by stretches due to pressure change and temperature change, respectively; and ΔεP
Replacing the sensitivity coefficients C11, C12, C13 in Eq. (8) with respective sensitivity coefficients C21, C22, and C23 correlating these changes with the Rayleigh frequency shifts, a similar equation holds true also for a case with the Rayleigh frequency shifts. That is, letting Δε1, Δε2, Δε3, Δε4 be respective strains of the four optical fibers, the first-layer optical fibers 2a1, 2a2 and the second-layer optical fibers 2b1, 2b2, the following Eq. (9) holds true for a 2×2 system in which two sets of two optical fibers are installed (embedded) in two layers having different optical fiber installation radii with the two optical fibers in each layer being wound around a cable or pipe, or the like in a double helix (two different initial circumferential positions).
In the 2×2 system, because there are eight measurement quantities (ΔvB
First, a technique of calculating the basic loads from measured strains is described below. The installation angle φ of the optical fibers installed helically around the inner tube (its radius is r) of the connecting body is determined as shown in
In Eq. (10), assuming the coordinate of the optical fiber at z=0 to be θ0 (initial circumferential position), a coordinate θ of the optical fiber at the position of z=z is expressed by Eq. (11) using the installation angle φ:
Note that the pitch actually needs to be set, depending on the distance between measurement points, to have a length of four times longer than the distance.
Here, a directional vector v of an optical fiber at an arbitrary position is expressed by Eq. (12) in the cylindrical coordinate:
A strain measured at the position with the optical fiber is expressed by the following Eq. (13) using a strain tensor ε:
Thus, when the basic loads are applied to the beam (round bar) as shown in
Since there are four basic loads F, Mx, My, Mx in the equation, strain measurement with four optical fibers allows the four basic loads to be conversely determined from these four measured strain values.
Next, a typical installation configuration of and corresponding specifications for the four optical fibers are described with reference to
Next, a description is made of a procedure of calculating the four basic loads from four strain values measured with the four optical fibers. Relationships of the following Eqs. (15) to (18) hold true between the four strain values and the basic loads A strain value of the optical fiber a1 is expressed by Eq. (15):
εf1=AαF+Bα sin θαMx+Bα cos θαMy+CαMz (15)
Likewise, respective strain values of the optical fibers a2, b1, b2 are expressed by Eqs. (16), (17), and (18):
εf2=AαF−Bα sin θαMx−Bα cos θαMy+CαMz (16),
εf3=AβF+Bβ sin θβMx+Bβcos θβMy+CβMz (17), and
εf4=AβF−Bβ sin θβMx−Bβ cos θβMy+CβMz (18).
In Eqs. (15) to (18), the coefficients Aα, Aβ, Bα, Bβ, Cα, Cβ are expressed by the following Eqs. (19) to (24):
By solving Eqs. (15) to (18), the basic loads can be derived as expressed by Eqs. (25) to (28);
In the above, each equation are derived by assuming the connecting body to be made of an isotropic material for simplicity; however, the connecting body has multi-layer structure in practice, so that it needs to be treated as a complex material each of which layer has a different elastic modulus. Hence, constants, such as E, v, and a, need to be actually measured. In the present invention, the basic loads are calculated from strain of each optical fiber determined with the analyzer from frequency shifts of both Brillouin scattered light and Rayleigh scattered light measured with the hybrid backscattering measuring module. Since the connecting body is assumed in the derivation of the equations to be an isotropic material for simplicity as described above, constants and the like associated with the basic loads need to be calibrated for each cable to be used when the basic loads are calculated.
Next, a description is made below of a method of determining a three-dimensional position at a desired point of the cable or pipe from the basic loads determined above. The three-dimensional position can be estimated in principle by integrating the strains with respect to the basic loads calculated using the above-described relational expressions between the strains and the basic loads (see
In the following, the method is described sequentially along data processing flow shown in
Because of different installation paths of the first-layer optical fibers and the second-layer optical fibers, the Eq. (29) can be written as sum of two terms as shown in Eq. (30):
The three-dimensional position of the straight beam is thereby calculated as 1+uz. When temperature and pressure changes need to be taken into account, strains caused by these changes may be added to εz.
As for bending of the cable or pipe, although it can be calculated by directly integrating the strains expressed by Eq. (3) and (5), there is a method of determining a three-dimensional position by integrating a curvature k and a torsion rate (specific twist angle) Y obtained by measurement with the optical fibers, assuming the cable or the like as a smooth curve (see Non-Patent Document 2). The method is described below by taking a cable as a representative of a cable and the like.
Regarding the cable as a smooth curve and designating its arc-length parameter at s, the curve in the three-dimensional space is expressed as r(s); 0≦s≦L. The curve is assumed to have an infinitesimal thickness and its intrinsic direction is assumed to be defined on the plane orthogonal to the curve. The unit vector in this direction is referred to as “x normal”, and a local coordinate (ez, ex, ey) fixed to each point of the curve is defined below as shown in
Letting Y(s) be the torsion rate (specific twist angle) of the x normal of the curve along s, the following Eq. (31) holds true:
Combining the above equations, a differential equation for (ez ex, ey), i.e., Eq. (32) holds true:
The matrix A in Eq. (32) is expressed as the following Eq. (33):
While the arc-length parameter s, which is the argument, is abbreviated in Eqs. (32) and (33), it should be noted that the coordinate system, kx, ky, Y, and A all are functions of s.
Next, a method of estimating using Eq. (32) the position of the cable from measurement values obtained by the optical fibers is described below. In the measurement with the optical fibers, measurement values of the curvatures kx, ky and the torsion rate Y are assumed to be obtained in the local coordinate system fixed to the cable. Using these values, an equation for the curve with respect to the local coordinate system (ez ex, ey) is obtained as Eq. (34):
where A is the following Eq. (35):
While the argument is also abbreviated here, the coordinate system, kx, ky, Y, and A all are functions of s.
In practice, since the local coordinate system (ez, ex, ey) is necessary to be transformed to the external three-dimensional coordinate system, the external coordinate system is expressed as Eq. (36) by regarding its components as three-dimensional column vectors:
Then, the differential equation is rewritten as Eq. (37):
Among solutions obtained by solving Eq. (37), ez and an estimated value of the position r(s) satisfy the relationship r′(s)=ez as described above. Hence, the estimated value of the tree-dimensional position can be calculated by integrating this equation (see the following Eq. (38)):
r(s)=r(0)+∫0sez(u)du (38)
The above is a method of calculating a three-dimensional position through the procedures along Route 1 shown in
Since the three-dimensional position that can be calculated from Eq. (38) is an estimated value, it involves an error. The error is the difference between the true position of the cable and the estimated value. Evaluation of the error is described below. As a specific example, a case of accurate estimation of the position of an in-water target object connected to the head of a cable is conceived. Defining as an origin point the above-water position of one end of the cable and as a terminal point the position of the other end of the cable, i.e., the position of the in-water target object, an accurate three-dimensional calculation of the terminal point is described below.
Letting Lc be the length from the origin point to the head of the cable, assuming the cable to be a smooth curve, and employing the arc-length parameter s as with the above, s=0 denotes the origin point and s=Lc denotes the terminal point. Expressing the position of each point on the curve as a three-dimensional vector x(s) and the curvature vector at each point as k(s), the equation of the curve is given as x″(s)=k(s), where the double prime mark “″” denotes second derivative. An elementary arc length is defined at a position s on the curve, and a curvature vector k0(s) is assumed to be given in the local coordinate system at the position. Since k(s) is rotated from k0(s) in the three-dimensional space, an orthogonal matrix M(s) exists and is expressed as x″(s)=M(s) k(s). Then, utilizing the fact that a curvature in the local coordinate system can be determined using the four optical fibers wound helically around the surface of the cable, k0(s) can be expressed using as the following strains (εf1, . . . ) measured with the four optical fibers: k0(s)=A(s) εf(s), where εf(s)=(εf1(s), εf2(s), εf3(s), εf4(s))T, A(s) are coefficient matrices that are expressed using θα, θβ and the like.
According to the above, the estimated value xk(s) of the position of the cable can be calculated by solving the differential equation: xk″(s)=Mk(s) k0k(s)=Mk(s) A(s) εfk(s), where Mk is an estimated matrix for the orthogonal matrix M(s). The true position of the cable is the solution of x″(s)=M(s) k0(s) and the position error Δx(s)=xk(s)−x(s) obeys the flowing Eq. (39):
Δx″(s)=M(s)Δk0(s)+(Mk(s)−M(s))k0(s) (39).
Then, the error is evaluated on the basis of the Eq. (38): For ease of the evaluation, a case where the cable is hung down perpendicularly in the water is discussed here to estimate an error at the head of the cable. In this case, the orthogonal matrix is assumed to be the unit matrix: M(s)≡I3. Further assuming the estimated matrix to be equal to the orthogonal matrix: Mk(s)≡I3, the error Δx(s) of the cable position is expressed as a differential equation: x″(s)=A(s) εf(s). It is also assumed that φα=φβ, rα=rβ, and θβ=θα+(π/2) in A(s). In this case, the coefficient matrix A(s) is expressed as Eq. (40):
And a correlation coefficient Pk0(s) of the error Δk0(s) of the curvature vector in the local coordinate system is expressed as the Eq. (41):
Therefore, an estimated error at the head of the cable is expressed by Eq. (42):
Δx(Lc)=∫0L
Calculation of the covariance matrix derives Eq. (43):
The equation (43) shows that the error in the z-direction (perpendicular direction) is zero and the standard deviation of error in distance on the xy-plane is expressed as Eq. (44):
Assuming, for example, φα=φβ=π/4, V=0.5, rα=rβ(aα?)=2.5 cm, Δs=1 cm, Lc=1 km, and σεf=0.1με, the distance error σxy on the horizontal plane is calculated to be 65.3 mm.
In an actual measurement situation such that, for example, the cable exists in water, if the depth at each point of the cable is obtained using pressure sensors, higher accuracy is expected by replacing estimated position values with the depth values obtained by the pressure sensor. To be more specific, from the relationship between pressure or temperature change measured with the optical fibers installed to the cable and frequency shifts measured by the hybrid measurement, a continuous distribution of pressure or temperature is calculated, and depth correction may be performed by converting the distribution into depth. The conversion is performed by utilizing the fact that the depth z(s) can be calculated using the relationship P(s)=ρgz(s) between pressure P(s) and depth z(s) (s is the arc-length parameter of the cable), where ρ is the density of water and g is the gravitational acceleration (see Route 2 in
Then, the three-dimensional position of the cable calculated using the three-dimensional calculation method through the procedures along Route 1 shown in
When an independent pressure gage is additionally mounted at some midpoint on the path to the measurement point of the cable or mounted to the towed object connected with the cable, depth can also be calibrated by converting a pressure value measured with such a pressure gage into a depth value (see Route 3 in
As described above, the present invention shows that a three-dimensional position of the cable can be accurately determined by the hybrid measurement method using four optical fibers. An example of accurate strain measurement performed even in an actual field test using the present measurement method is described here.
As has been described above, Embodiment 1 shows that in the 2×2 system in which four optical fibers, i.e., two sets of two optical fibers are installed (embedded) in two layers having different radii with the two optical fibers in each layer being wound around a cable or pipe, or the like in a double helix (two different initial circumferential positions), the three-dimensional position at a given point of the cable can be determined with significant accuracy even under loads by external force using the hybrid measurement method, which utilizes both Brillouin frequency shifts and Rayleigh frequency shifts.
While Embodiment 1 shows the case of the 2×2 system, in which the four optical fibers, i.e., the two sets of two optical fibers are installed (embedded) two layers having different radii with the two optical fibers in each layer being wound around a cable or pipe, or the like in a double helix (two different initial circumferential positions), employing such the installation configuration, it happens that values of Mx, My cannot be calculated, as can be seen from Eqs (27) or (28), owing to occurrence of zero denominator if θα and θβ are set to be the same value, for example. Therefore, it is necessary to be careful for the installation not to be in such the configuration in the 2×2 system. In a 3×2 system, in which two sets of three optical fibers are installed in two layers having different radii with the three optical fibers in each layer being wound around a cable or pipe, or the like with a triple helix (three initial circumferential positions different from each other by, for example, 120 degrees), it does not happen that values of Mx, My cannot be calculated. In the present embodiment, therefore, a method for three-dimensional position measurement such as of a cable using the 3×2 system is described focusing on differences from the 2×2 system.
In the present embodiment, six optical fibers are used as a 3×2 system. A specification for the optical fibers in the 3×2 system is shown in
Applicability of the 3×2 system to three-dimensional position measurement is described first. The number of equations for, i.e., the number of measurement quantities of the frequency shift changes measured by the hybrid measurement using the six optical fibers increases to twelve in total compared to eight in the foregoing 2×2 system because the number of relational expressions for strain changes Δε5 and Δε6 of the fifth and sixth optical fibers increments by two per layer (see Eq. (9) and the specific relational expressions of Δε5 and Δε6 are omitted). Because there are total eight unknown quantities ΔP, ΔT, Δε1, Δε2, Δε3, Δε4, Δε5, Δε6 in this case, a pressure and a temperature applied to, and strains produced in each optical fibers can be calculated separately from frequency shift changes measured by the hybrid measurement and by solving the twelve simultaneous equations using the least squares method, as with the foregoing 2×2 system.
Derivation of relationships between the basic loads and strains (εfi, . . . ) obtained from Δε1 (i=1, . . . , 6) to be measured with the six optical fibers a1, a2, a3, b1, b2, b3 shown in
Since the coefficients Aα, Aβ, Bα, Bβ, Cα, Cβ in the above equations are the same as with the 2×2 system, expressions of them are omitted here. By measuring six strain values by the hybrid measurement and by solving the above equations, the basic loads F, Mx, My, Mz are obtained as below.
First, the axial force and the torsional moment can be calculated by adding respective strains of the first-layer optical fibers and the second-layer optical fibers as shown in the following Eqs. (51) and (52), respectively:
Next, the bending moment can be calculated by solving the following Eq. (53) using the least squares method:
where the axial force and the torsional moment are eliminated. Since more optical fibers are used in Embodiment 2 than in Embodiment 1, measurement error can be more reduced than Embodiment 1 accordingly, thus bringing about an effect of improvement in accuracy of the three-dimensional position measurement.
The consolidated process flow of the measurements described in Embodiments 1 and 2 is shown by Case 1 in
In addition, there is a 1×3 system other than the above, in which three sets of an optical fiber are installed in three layers having different radii with the optical fiber in each layer being wound around a cable, pipe, or the like in a single helix (one installation angle only). In this case, the system exhibits a merit of reducing the number of optical fibers to be used, however, other problem, such as of taking time in installing, i.e., embedding of the optical fibers in the cable or the like, arise in implementation of the system, in addition to the care described in the explanation of the 2×2 system. Hence, the detailed explanation is omitted in the present patent application.
Cases to which the hybrid measurement is applicable have been described in Embodiments 1 and 2. In Embodiment 3, description is made of a three-dimensional measurement of a cable position without using the hybrid measurement. The three-dimensional position measurement of a cable can be performed accurately without using the hybrid measurement by a method described below. It should be noted that in a case according to the present embodiment, a three-dimensional position of the cable can be measured by a solitary measurement using any one of Brillouin frequency shifts and Rayleigh frequency shifts although embedding work of optical fibers in a cable or the like becomes burdensome and takes time compared to cases using the hybrid measurement. The following describes that such measurement is possible.
First, a discussion is made of a case of measuring a three-dimensional position at an arbitrary position of a cable or the like under effects of pressure and temperature by employing the present embodiment. In the measurement according to the present embodiment, although embedding work of optical fibers in a cable or pipe, which is a measurement target, takes time and effort to some degrees (because the optical fibers are embedded in four or more different layers), the three-dimensional position of the cable or the like can be measured with six or more optical fibers by a solitary measurement using any one of Brillouin frequency shifts and Rayleigh frequency shifts (see Case 2 in
An installation configuration of the optical fibers for such a case is specifically described below. The installation configuration is roughly classified into three: Case a (1×6 system), Case b (2×4 or 2×2+2 system), and Case c (3×4 or 3×2+2 system). Case a is such that six optical fibers each are embedded separately in six layers having different installation radii, of a cable or the like in an independent helical configuration. While less optical fibers are needed for use than Case b and Case c, embedding of the optical fibers takes time and effort and the data processing is complicated. Case b is such that in the 2×4 system for example, eight optical fibers are installed (embedded) in four layers having different installation radii in a double helical configuration (see
In the following, description is made of Embodiment 3 taking the 2×4 system of Case b as a representative example. In this case, using the 2×4 system, i.e., using total eight optical fibers, strain changes of these eight optical fibers are determined from, for example, Brillouin frequency shifts ΔvB. Here, converting the Brillouin frequency shifts to apparent strain changes using Δεi=ΔvB/C11 for ease of data processing, the following Eq. (54) holds true for the strain changes of the eight optical fibers:
where Aα, Aβ, AY, Aδ, Bα, Bβ, BY, Bδ, Cα, Cβ, CY, Cδ, . . . are coefficients correlating these strain changes with the basic loads and the like as with Embodiment 1. Eq. (54) shows that the bending moments can easily be separated from the other unknown quantities. Specifically, by solving, using a method such as a least squares method, the following simultaneous equations (55) obtained from the above equations, the bending moments can be calculated as solutions of Eq. (55).
The unknown quantities expect for the above can be obtained by solving the following four-unknown simultaneous equations (56):
It should be noted that in a case of no need to take into account the effects of pressure and temperature in a three-dimensional position measurement of a cable or pipe, a solitary measurement using Brillouin frequency shifts or Rayleigh frequency shifts can be performed by the 2×2 system or the 3×2 system as shown by the Case 3 in
Even in a case according to any of the embodiments, since the optical fibers are embedded in the outer circumferential layers of a cable or pipe, which is a measurement target, and each layers can be peeled off layer by layer from the surface (outermost layer), there is a feature that certain-length cables are easily connectable, thus coping with the measurement without any problems even if its measurement range is a long distance (for example, one kilometer or longer) (see
Additionally, even in any of the embodiments, the three-dimensional measurement method according to the present invention is applicable to so-called on-line system (see
Furthermore, since the optical fiber itself has a communication function, it is possible to establish communication to a device mounted on the head of an unmanned probe vehicle, a towed object, or the like connected to the end of the cable, i.e., reception/transmission of signals from/to the device and an electronic instrument such as a pressure sensor and a temperature sensor provided to the device.
Number | Date | Country | Kind |
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2012-262190 | Nov 2012 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2013/079117 | 10/28/2013 | WO | 00 |