Classifications

• • G—PHYSICS
  • G02—OPTICS
  • G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
  • G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
  • G02B6/24—Coupling light guides
  • G02B6/26—Optical coupling means
  • G02B6/27—Optical coupling means with polarisation selective and adjusting means
  • G02B6/2753—Optical coupling means with polarisation selective and adjusting means characterised by their function or use, i.e. of the complete device
  • G02B6/2766—Manipulating the plane of polarisation from one input polarisation to another output polarisation, e.g. polarisation rotators, linear to circular polarisation converters
• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01C—MEASURING DISTANCES, LEVELS OR BEARINGS; SURVEYING; NAVIGATION; GYROSCOPIC INSTRUMENTS; PHOTOGRAMMETRY OR VIDEOGRAMMETRY
  • G01C19/00—Gyroscopes; Turn-sensitive devices using vibrating masses; Turn-sensitive devices without moving masses; Measuring angular rate using gyroscopic effects
  • G01C19/58—Turn-sensitive devices without moving masses
  • G01C19/64—Gyrometers using the Sagnac effect, i.e. rotation-induced shifts between counter-rotating electromagnetic beams
  • G01C19/72—Gyrometers using the Sagnac effect, i.e. rotation-induced shifts between counter-rotating electromagnetic beams with counter-rotating light beams in a passive ring, e.g. fibre laser gyrometers
  • G01C19/721—Details
• • G—PHYSICS
  • G02—OPTICS
  • G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
  • G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
  • G02B6/24—Coupling light guides
  • G02B6/26—Optical coupling means
  • G02B6/27—Optical coupling means with polarisation selective and adjusting means
  • G02B6/2726—Optical coupling means with polarisation selective and adjusting means in or on light guides, e.g. polarisation means assembled in a light guide
  • G02B6/274—Optical coupling means with polarisation selective and adjusting means in or on light guides, e.g. polarisation means assembled in a light guide based on light guide birefringence, e.g. due to coupling between light guides

Definitions

• the present invention generally relates to the polarization filtering of light signals in devices using guided optics.
• a fiber-optic filtering and polarization orientation device comprising a first SMI monomode fiber and a PZ polarizing optical fiber.
• the invention finds an application in many fields involving guided optics, such as telecommunications, lasers, sensors or even interferometry.
• the manipulation of the polarization is often carried out by the use in the free field of non-fibered polarizing optical components, for example, polarizers, prisms or even waveplates.
• FIG. 1 illustrates an optical bench using such light signals coupled to non-fibered polarizing optical components.
• the optical bench is illuminated by an input light signal propagating through an input fiber FE.
• a lens Li collimates the input light signal, then the collimated light signal passes through a polarizer P.
• a second lens L2 refocuses the light signal towards an output fiber Fs, producing an output light signal.
• fiber components such as polarization-maintaining fibers or even polarizing fibers, or even other complex fiber components which integrate all the optical collimation or coupling components.
• the present invention proposes using fiber-based polarizing components in order to work in an "all-fibre" configuration and thus facilitate manipulation of the polarization of signals originating from guided optics components, especially fiber optics.
• the invention provides a fiber optic device filtering and orientation in polarization comprising:
• polarizing optical fiber having a first end and a second end, characterized in that the device further comprises:
• the first rigid opto-mechanical connection zone is formed by welding.
• the first rigid opto-mechanical connection zone can be covered by splice protection.
• the polarizing optical fiber has birefringence and a main signal loss rate along a main polarization axis A p and a transverse signal loss rate along a transverse polarization axis A t , where the loss rate transverse signal loss is at least 20 dB higher than the main signal loss rate.
• the device further comprises:
• the orientation adjustment system is also adapted to adjust the angular position of the second connecting zone around the second connecting axis.
• the polarizing optical fiber is arranged in the form of a loop.
• the polarizing optical fiber has a length of between 1 and 30 meters.
• the orientation adjustment system is motorized.
• the device according to the invention further comprises a servo system configured to slave the orientation adjustment of at least one of the first rigid opto-mechanical connection zone and the second connection zone opto-mechanical rigid to a setpoint.
• the fiber optic device further comprises a housing, a first connection opening and a second connection opening.
• first connection opening and the second connection opening may respectively comprise a first optical bulkhead feedthrough and a second bulkhead feedthrough.
• the first connection opening comprises an optical bulkhead bushing and the second connection opening comprises a collimator for optical fiber.
• the invention also relates to a method for filtering and orientation in polarization of an input light signal, implemented by a fiber-optic device for filtering and orientation in polarization according to the invention, comprising the following steps:
• the polarization filtering and orientation method can be implemented in a fiber optic gyrometer, said fiber gyrometer comprising:
• the optical system comprises said optical coupler and the light source
• the first monomode fiber is connected to the downstream monomode fiber of the optical neck
• the polarizing fiber of the fiber optic filtering and polarization orientation device is connected to the input/output port.
• the invention also relates to a method for filtering in polarization an input light signal and orientation in polarization of an output light signal, implemented by a fiber optic device for filtering and orientation in polarization according to the invention, comprising the following steps:
• FIG. 2 is a schematic view of an embodiment of the fiber optic device for filtering and orientation in polarization according to an exemplary embodiment
• Figure 3 illustrates the operation of a polarizing fiber
• Figure 4 illustrates the principle of welding two optical fibers and setting up a splice protection around the rigid opto-mechanical connection zone obtained by this welding.
• Figure 5 illustrates the principle of linear polarization orientation according to the present disclosure in the embodiment of Figure 2.
• Figure 6 illustrates an embodiment of an adjustment system according to the invention.
• Figure 7 illustrates a principle of mounting the rigid opto-mechanical connection of Figure 4 in the embodiment of the adjustment system of Figure 6.
• FIG. 8 is a schematic view of an embodiment of the fiber optic device for filtering and orientation in polarization according to an exemplary embodiment.
• Figure 9 illustrates a step of the principle of linear polarization orientation according to the present disclosure in the embodiment of Figure 8.
• Figure 10 illustrates an embodiment of inserting the assembly formed by the rigid opto-mechanical connection zone of Figure 4 and the embodiment of the adjustment system of Figure 7 in a holding system .
• Figure 11 shows an embodiment of fixing the assembly formed by the rigid opto-mechanical connection zone of Figure 4, the embodiment of the adjustment system of Figure 7, the system for holding the figure 10 in the embodiment of the fiber optic filtering and polarization orientation device of figure 8.
• Figure 12 illustrates an example of abutment of an embodiment of the system for adjusting a rigid opto-mechanical connection zone according to the invention.
• Figure 13 and Figure 14 illustrate alternative embodiments of the device optical fiber for filtering and orientation in polarization according to the embodiment of FIG. 8.
• FIG. 15 illustrates a use of the fiber-optic filtering and polarization orientation device according to the embodiment of FIG. 2 in a fiber gyroscope.
• FIG. 8 represents a three-dimensional view of a fiber optic device 1 according to the invention.
• a fiber optic device 1 is intended to filter, from an input light signal, a signal having any polarization to produce at the output a signal having a linear polarization with a determined orientation.
• single-mode optical fiber means a transverse single-mode fiber, denoted SM, that is to say which can include two types of polarization without distinguishing them from each other through of the structure of the fiber, and differing from a polarization-maintaining fiber, denoted PM (i.e. fiber arranged to separate two transverse polarization modes of a light signal and maintain the two transverse polarization modes), or fiber polarizing optics, denoted PZ, as mentioned above.
• SM transverse single-mode fiber
• PM i.e. fiber arranged to separate two transverse polarization modes of a light signal and maintain the two transverse polarization modes
• PZ fiber polarizing optics
• the device comprises a first SMI monomode optical fiber having an upstream end 41 and a downstream end 42.
• the device 1 further comprises a PZ polarizing fiber having a first end 81 and a second end 82.
• the PZ polarizing fiber has a structure inducing birefringence in the heart, which determines a main polarization axis A p and a transverse polarization axis A t orthogonal to each other.
• the birefringence and the optical guidance in the fiber result from a profile of index and birefringence determined inside the fiber, originating respectively from the concentrations of dopants introduced into the silica and from the stress field voluntarily generated when pulling the preform.
• the index and birefringence profiles of the fiber induce therein a main signal loss rate for a light signal having a linear polarization along the main polarization axis Ap and a transverse signal loss rate for a signal luminous having a linear polarization along the transverse polarization axis At.
• the rate of loss of transverse signal is higher than the rate of loss of main signal.
• the difference between the main and transverse signal loss rates is 20 dB.
• the difference between the main and transverse signal loss rates is between 20 dB and a value which may be greater than 90 dB.
• the difference between the main and transverse signal loss rates depends on the length of the polarizing fiber PZ, but also, if necessary, on a wound configuration of the fiber PZ and in particular the radius of curvature of the coiled configuration.
• the propagation of a light signal having a linear polarization along the main polarization axis in the PZ polarizing fiber is privileged, while a light signal having a linear polarization along the transverse polarization axis is attenuated. and extinguished during its propagation in the polarizing fiber PZ.
• a light signal having a linear polarization along the main polarization axis is called slow mode.
• a light signal having linear polarization along the transverse polarization axis is called fast mode. Any optical signal is therefore filtered by the polarizing optical fiber PZ over a determined range of wavelengths.
• the polarizing fiber PZ is arranged to transmit a linear polarization mode, preferably a polarization mode oriented along the main polarization axis A p of the light signal.
• the polarizing fiber PZ is also arranged to extinguish or suppress another linear polarization mode, preferably a transverse polarization mode At t to the main polarization axis of the light signal.
• the PZ polarizing optical fiber is arranged to filter the polarization of the light signal which propagates along the PZ polarizing fiber.
• Figure 3 illustrates the mode of operation of the PZ polarizing optical fiber. It shows the evolution of the powers of the slow mode (in dashed line) and respectively of the fast mode (in solid line) according to the wavelength.
• the polarizing optical fiber PZ behaves like a polarization-maintaining fiber, where the slow and fast modes propagate simultaneously.
• Fast mode power attenuation begins for wavelengths greater than Z f.
• the ZPZ zone is delimited between the wavelength for which the PZ polarizing optical fiber filters the slow mode and where the power difference between the slow mode and the fast mode is greater than 20dB, i.e. l oR -Ol / 2, and the wavelength at which slow mode power attenuation begins, ie ⁇ oP +DA/2.
• the wavelength l oR can be equal to 1550 nm
• Ol can be of the order of a few tens of nanometers, for example of the order of 50 nm.
• O1 is of the order of 150 nm. Indeed, the quantity O1 depends on the length of the polarizing fiber PZ, and if necessary, on the radius of curvature in the wound configuration of the polarizing fiber PZ.
• the polarizing fiber can achieve much better filtering characteristics than more conventional devices.
• PZ polarizing fiber can exhibit an extinction rate greater than 90 dB, while extinction rates of around 40 dB are achieved by conventional devices. siques.
• the ZNP zone corresponding to wavelengths greater than 1 oR + ⁇ l/2 is a zone where the two slow and fast modes are leaky and where there is no propagation in the polarizing optical fiber PZ.
• the PZ polarizing fiber can be of the so-called "elliptical" type and include, from the inside outwards: a single-mode core with index n core, a circular sheath with refractive index n ga me less than n core , a sheath of elliptical section and of refractive index n e iii P tick greater than n ga me.
• a configuration is for example: a single-mode germano-silicate core, with an index of 7.10 3 above the refractive index of silica for a wavelength of 633 nm; a circular sheath (called buffer sheath) made of silica; a cladding of elliptical section in silica co-doped with boron, phosphorus and fluorine (ie in boro-phospho-fluoro-silicate) and with an index of 10.10 3 below the refractive index of silica for a length wave of 633 nm.
• the PZ polarizing optical fiber is arranged to retain one polarization mode (oriented along the main polarization axis A p of the light signal) and extinguish the other (transverse to the main polarization axis A p ).
• the PZ polarizing fiber can be of any other type, provided that it allows single-mode guidance of the light signal and the selection of only one of the two orthogonal polarizations (which is preferably the polarization mode which is oriented the along the main axis of polarization A p ).
• the single-mode optical fiber is arranged to transmit or transport in an identical manner two transverse polarization modes of the light signal.
• the monomode fiber according to the present disclosure does not affect the state of polarization of the light signal propagating in the monomode fiber. It is therefore not a PZ polarizing fiber within the meaning of the present disclosure.
• the monomode fiber according to the present disclosure can be a so-called “apolarized” fiber, unlike the PZ polarizing fiber as described in the present disclosure.
• the downstream end 42 of the first SMI single-mode fiber is connected to the first end 81 of the polarizing optical fiber PZ, forming a first rigid opto-mechanical connection zone ZL1 along a first connecting axis DI.
• the downstream end 42 of the first monomode fiber SMI and the first end 81 of the polarizing optical fiber PZ are connected by soldering.
• the connection is equivalent to a polarizer - free field connection, with the difference of being completely fibred.
• Figure 4 shows a welding step between, for example, the end 42 of the first SMI single-mode fiber and the first end 81 of the polarizing optical fiber PZ, on an optical welder, not shown.
• the first rigid opto-mechanical connection zone ZL1 can be covered by splice protection. This splice protection ensures the mechanical holding of the first rigid opto-mechanical connection zone ZL1.
• the first rigid opto-mechanical connection zone ZL1 is defined as a region including a portion of the first SMI monomode fiber containing the downstream end 42 and a portion of the PZ polarizing fiber containing the first end 81, the two portions being interconnected.
• the device 1 also comprises an adjustment system 13 making it possible to respectively orient the first rigid opto-mechanical connection zone ZL1.
• the adjustment system 13 makes it possible to adjust the angular position of the first connection zone ZL1 around the first connection axis DI.
• the angular position of the latter determines that of the first end PZ1 of the polarizing optical fiber PZ.
• the adjustment in angular position of the first connection zone ZL1 makes it possible to choose the orientation of the linear polarization filtered by the polarizing fiber PZ at its first end 81. Therefore , according to the present disclosure, the light signal has a linear polarization with an orientation that can be modulated as a function of the adjustment in angular position of the first connection zone ZL1.
• FIG 5 it is illustrated how a light signal SE having a polarization P propagating in the first single-mode optical fiber SMI is transformed into a light signal SZ propagating in the polarizing optical fiber PZ and having a polarization PR1 with a different orientation following a rotation RI of the first rigid opto-mechanical connection zone ZL1.
• the P polarization at the input has been represented as linear, of which only the projection on the slow axis of the PZ fiber is filtered.
• the P polarization at the input can be any polarization which will retain in guided mode in the PZ fiber only its linear part aligned with the slow axis, this axis being driven by the mechanical rotation of the opto-mechanical link. rigid ZL1.
• the adjustment system 13 may consist of a first knob 131 surrounding the first rigid optical-mechanical connection zone ZL1.
• the first monomode fiber SMI, the polarizing optical fiber PZ as well as the first rigid opto-mechanical connection zone ZL1 and the second rigid opto-mechanical connection zone ZL2 can be inserted into the first knob 131.
• the first wheel 131 is a wheel with a first central hole 231, a first pin 331 and a first thin slot 431 as shown in Figure 6.
• a user inserts the part of the polarizing optical fiber PZ located on one side of the first rigid opto-mechanical connection zone ZL1 into the first central orifice 231 of the first wheel 131, as illustrated in FIG. 7.
• the inside diameter of the first central orifice 231 is adjusted to the outside diameter of the connection zone ZL1.
• the first rigid opto-mechanical connection zone ZL1 is pushed into the first central orifice 231 to be fixed there, for example by gluing.
• the first pin 331 makes it possible to turn the first knob 131.
• the adjustment system 13 makes it possible to continuously adjust the angular position of the first connection zone ZL1.
• the only torsional stresses undergone by the first SMI monomode optical fiber are located respectively at the level of the first rigid opto-mechanical connection zone ZL1.
• the adjustment system 13 can be motorized.
• the adjustment system 13 comprises a first wheel 131, this can be driven by a first motor.
• the device 1 may in this case comprise a servo system 21 (not shown) making it possible to slave the orientation adjustment of the first rigid opto-mechanical connection zone ZL1 to a first setpoint.
• the servo system then comprises a control unit 23 (not shown) capable of controlling the actuation of the motorized adjustment system 3.
• the fiber optic device 1 for filtering and orientation in polarization further comprises a second monomode optical fiber SM2 having an upstream end 61 and a downstream end 62.
• a second monomode optical fiber SM2 having an upstream end 61 and a downstream end 62.
• An implementation of this embodiment is shown in Figure 8.
• the second end 82 of the polarizing fiber PZ is connected to the upstream end 61 of the second monomode fiber SM2, forming a second rigid opto-mechanical connection zone ZL2 along a second connection axis D2.
• the second end 82 of the polarizing optical fiber PZ and the upstream end 61 of the second single-mode fiber SM2 are connected by hard welding, in a manner similar to that illustrated in FIG. 4 for the first opto-mechanical connection zone. rigid ZL1.
• the bond is equivalent to a polarizer - free field connection, with the difference of being completely fiber-reinforced and allowing alignment problems to be overcome.
• the second rigid opto-mechanical connection zone ZL2 is defined as a region including a portion of the second monomode fiber SM2 containing the upstream end 61 and a portion of the polarizing fiber PZ containing the second end 82, the two portions being interconnected.
• the second rigid opto-mechanical connection zone ZL2 can be covered by splice protection. This splice protection ensures the mechanical hold of the second ZL2 rigid opto-mechanical connection zone.
• a cylindrical rigid protection bar can be used as splice protection for each of the first rigid opto-mechanical connection zone ZL1 and the second rigid opto-mechanical connection zone ZL2.
• Figure 4 shows the placement of a rigid cylindrical protective bar surrounding the first rigid opto-mechanical connection zone ZL1.
• the fiber optic device 1 for filtering and orientation in polarization further comprises a second single-mode optical fiber SM2.
• the PZ polarizing optical fiber is arranged in the form of a loop.
• the radius of curvature of the loop is of the order of ten centimeters.
• the number of turns is defined by the length of the polarizing optical fiber PZ. For example, for a fiber 10 meters long and with a loop diameter of 7 cm, the number of turns is around 50.
• PZ the polarization filtering effect varies in response to the stress on the PZ polarizing optical fiber caused by its curvature.
• the device 1 when the polarizing optical fiber PZ is arranged in the form of a loop, the device 1 is more compact.
• the polarizing optical fiber PZ has a length of between 1 and 30 meters.
• the polarizing optical fiber PZ has a length of between 5 and 15 meters.
• the first monomode fiber SMI and the second monomode fiber SM2 are arranged so as to minimize the stresses to which they are subjected.
• stress we mean any force exerted on the SMI and SM2 fibers and tending to deform them mechanically.
• the first SMI single-mode fiber and the second SM2 single-mode fiber are advantageously positioned in a straight line, in order to avoid the constraints due to curvatures and to minimize the effect of these curvatures on the birefringence of the SMI and SM2 fibers.
• the only mechanical pressures on the first monomode fiber SMI and the second monomode fiber SM2 are located at the level of the first rigid opto-mechanical connection zone ZL1 and the second rigid opto-mechanical connection zone ZL2.
• the adjustment system 13 is also configured to orient the second rigid opto-mechanical connection zone ZL2. The adjustment system 13 then also makes it possible to adjust the angular position of the second connection zone ZL2 around the second connection axis D2.
• the angular position of the second rigid opto-mechanical connection zone ZL2 determines that of the second end PZ2 of the polarizing optical fiber PZ .
• the adjustment in angular position of the second connection zone ZL2 makes it possible to choose the orientation of the linear polarization at the output of the polarizing optical fiber PZ and therefore propagating in the second fiber SM2 singlemode optic.
• FIG. 9 it is illustrated how a light signal SZ having a PRI polarization propagating in the polarizing optical fiber PZ is transformed into a light signal SS propagating in the second monomode optical fiber SM2 and having a linear polarization P R 2 with a different orientation following a rotation R2 of the second rigid opto-mechanical connection zone ZL2.
• the device 1 is integrated into a housing 3.
• the housing 3 has a base 5, a cover 7, a first connection opening 9 and a second connection opening 11.
• the upstream end 41 of the pre first single-mode optical fiber SMI is aligned with the first connection opening 9.
• the downstream end 62 of the second single-mode optical fiber SM2 is aligned with the second connection opening 11.
• the adjustment system 13 is mounted on the casing 3.
• the adjustment system 13 may comprise a first knob 131 and a second knob 132 respectively surrounding the first rigid opto-mechanical connection zone ZL1 and the second rigid opto-mechanical connection zone ZL2.
• the rotation of the knobs 131 and 132 respectively allows the rotation of the first rigid opto-mechanical connection zone ZL1 and of the second rigid opto-mechanical connection zone ZL2. It thus allows the adjustment of their angular position around, respectively, the first connecting axis DI and the second connecting axis D2.
• first monomode fiber SMI, the polarizing optical fiber PZ and the second monomode fiber SM2 as well as the first rigid opto-mechanical connection zone ZL1 and the second rigid opto-mechanical connection zone ZL2 can be inserted into the first knob 131 and the second knob 132, how the first knob 131 and the second knob 132 can be fixed to the housing 3, and how to rotate the first and second rigid opto-mechanical connection zones ZL1 and ZL2 by using the first wheel 131 and the second wheel 132.
• the first knob 131 (respectively the second knob 132) can be a roller with a first central orifice 231 (respectively a second central orifice 232), a first lug 331 (respectively a second lug 332 ) and a first thin slot 431 (respectively a second thin slot 432) as shown in Figure 6.
• the insertion of the first rigid opto-mechanical connection zone ZL1 in the first wheel 131 can be carried out as described previously, in fi gure 7, that is to say in the case where the device 1 does not does not include the second monomode fiber SM2 and that the adjustment system 13 includes a first wheel 131.
• the insertion of the second rigid opto-mechanical connection zone ZL2 can be performed in a similar manner.
• the first wheel 131 and the first rigid opto-mechanical connection zone ZL1 are inserted into a first holding structure in the form of a double
• V has fixing lugs capable of being fixed on an internal face of the cover 7 of the box 3 using screws or any other fixing means, as well as a low bar connecting the fixing lugs.
• the two V-shapes are designed to respectively provide two points of contact with the cover 7 and a friction zone with the first rigid opto-mechanical connection zone ZL1. This design provides low-cost mechanical strength that stabilizes positions.
• the second wheel 132 and the second rigid opto-mechanical connection zone ZL2 are inserted into a second holding structure in the shape of a double V.
• the first wheel 131 provided with the rigid opto-mechanical connection zone ZL1 inserted into the first double V-shaped holding structure is then fixed under the cover 7 of the box 3 via the fixing lugs 531 as illustrated in Figure 11.
• a first opening 151 is provided in the cover 7 of the housing 3 to allow the first wheel 131 and its first lug 331 to pass through the cover 7 and to cause it with a finger for example.
• the second wheel 132 provided with the rigid opto-mechanical connection zone ZL2 inserted into the second double V-shaped holding structure is then fixed under the cover 7 of the box 3 via mounting brackets.
• a second opening 152 is provided in the cover 7 of the case 3 to allow the second knob 132 and its second pin 332 to pass through the cover 7 and to drive it with a finger, for example.
• the first pin 331 of the first wheel 131 is used as a stop to control the rotation of the first wheel 131.
• the first opening 151 is wide enough to allow the first pin 331 to pass during a rotation of the first wheel 131
• the rotation is restrained by the presence of the low bar which blocks the first knob 131 when the first lug 331 comes into contact with the low bar, as illustrated in FIG. 12.
• the first lug 331 can also serve as a reference and can, for example, to coincide with the orientation of the slow axis of the PZ polarizing fiber.
• the second lug 332 of the second wheel 132 is used as a stop to control the rotation of the second wheel 132.
• the second opening 152 is wide enough to allow the lug to pass during a rotation of the second wheel 132.
• the rotation is restrained by the presence of the low bar which blocks the second wheel 132 when the second lug 332 comes into contact with the low bar.
• the second lug 332 can also serve as referencing and can, for example, coincide with the orientation of the slow axis of the polarizing fiber PZ.
• the adjustment system 13 makes it possible to continuously adjust the angular position respectively of the first connection zone ZL1 and of the second connection zone ZL2.
• the only torsional stresses undergone by the first monomode optical fiber SMI and the second optical fiber SM2 are located respectively at the level of the first rigid opto-mechanical connection zone ZL1 and of the second opto-mechanical connection zone. ZL2 rigid mechanics.
• this circular birefringence causes only an overall rotation of the orientation of the input polarization P without loss on the degree of polarization of the signal.
• this circular birefringence does not change either the ability to rotate the output polarization with the rotation of the rigid opto-mechanical connection zone ZL2. The torsional stresses therefore do not disturb the operation of the device 1.
• the device 1 being symmetrical, it is thus possible to connect one or the other of the first single-mode optical fiber SMI and the second single-mode optical fiber SM2 to an input light signal in order to obtain at the end from the other SM2 or SMI monomode optical fiber an output light signal having a linear polarization of determined orientation.
• the adjustment system 13 can be motorized.
• the adjustment system 13 comprises a first knob 131 and a second knob 132, these can be driven by a first motor and a second motor.
• the device 1 may in this case comprise a servo system 21 making it possible to slave the orientation adjustment of the first rigid opto-mechanical connection zone ZL1 to a first setpoint, and of the second opto-mechanical connection zone rigid mechanical ZL2 at a second setpoint.
• the servo system then comprises a control unit 23 capable of controlling the actuation of the motorized adjustment system 3. This slaving allows control of the filtering and of the orientation in polarization according to the use made of the device 1 by the user, for example, of the desired output polarization, or of the measurement of a parameter of a light source S performed.
• first connection opening 9 and the second connection or connection 11 respectively comprise a first optical partition crossing 171 and a second optical partition crossing 172, to which the upstream end 41 of the first single-mode optical fiber SMI and the downstream end 62 of the second single-mode optical fiber SM2.
• the first connecting opening 9 comprises an optical bulkhead crossing 173 to which is connected the upstream end 41 of the first SMI monomode optical fiber
• the second opening connection 11 comprises a collimator for tick optic fiber 192 to which is connected the downstream end 62 of the second single-mode optical fiber SM2.
• the second connection opening 11 comprises an optical bulkhead crossing 174 to which the downstream end 62 of the second optical fiber is connected.
• the first connection opening 9 comprises a collimator 191 for optical fiber to which is connected the upstream end 41 of the first SMI monomode optical fiber.
• the fiber collimator can be of the SELFOC® brand. These variants make it possible to obtain a free field output signal and to integrate the device 1 directly into a free field type optical bench.
• the device 1 comprises the first SMI monomode fiber and the second SM2 monomode fiber and that the upstream end 41 of the first SMI monomode optical fiber is used as the input of the device 1 and the downstream end 62 of the second single-mode optical fiber SM2 as the output of device 1.
• the symmetrical configurations for using device 1 are obtained by using the downstream end 62 of the second single-mode optical fiber SM2 as the input of device 1 and the upstream end 41 of the first SMI monomode optical fiber as the output of device 1.
• a light source S having a light flux is positioned at the input of the device 1.
• the light source S comes from an optical fiber. It can be polarized or unpolarized. At least a portion of the luminous flux penetrates through the upstream end 41 of the first SMI monomode fiber, forming an input signal SE propagating in the first SMI monomode fiber.
• the input signal SE has the same degree of polarization and the same nature of polarization as the light source S.
• a method for filtering and polarization orientation of a light signal using the device 1 described above and used by a user is described below.
• the user adjusts the polarization of the signal SZ filtered by the PZ polarizing optical fiber.
• the user uses the adjustment system 13 to adjust the angular orientation of the first rigid opto-mechanical connection zone ZL1 around the first connection axis D1.
• the user can for example use a control portion of the light signal SS to carry out this adjustment, to adjust the illumination thereof as desired, by adjusting the angular orientation of the first rigid opto-mechanical connection zone ZL1 around the first axis link D1.
• the user adjusts the orientation of the linear polarization of the light signal SS coming from the second monomode optical fiber SM2 by using the adjustment system 13 to define the angular orientation of the second zone of rigid opto-mechanical link ZL2 around the second link axis D2.
• Any polarization control system can be used to assist this adjustment, such as an analyzer associated with a means of determining the light intensity downstream of the analyzer (screen, sensor).
• the signal SS is used as an input signal of an application device, the user can for example use the signal at the output of the application device to control the orientation adjustment of the polarization of the light signal SS.
• a service for adjusting the angular orientation of the first rigid opto-mechanical link zone ZL1 and/or of the second opto-mechanical link zone ZL2 rigid mechanics can be realized.
• the fiber optic device 1 then comprises a servo system 5 making it possible to slave the adjustment in orientation of the first rigid opto-mechanical connection zone ZL1 to a first setpoint, and/or to slave the adjustment in orientation of the second rigid opto-mechanical connection zone ZL2 at a second set point.
• the user wishes to optimize the transmission of the light signals SE, SZ and SS through the device 1.
• the user collects a control portion of the light signal SS of which he measures for example the illumination received by a sensor 2 (the sensor can be a photodiode or any other optical sensor).
• the servo system 21 comprises a control unit 23 which drives the adjustment system 13 and a processing unit 25 which receives the signal measured by the sensor 2.
• the control unit 23 triggers the rotation of the knob 131, which rotates the first rigid opto-mechanical connection zone ZL1 over a range of 180°.
• the processing unit 13 identifies the position P max of the wheel 131 for which the signal measured by the sensor 2 is maximum and controls the rotation of the wheel 131 to this position P max.
• the user may wish to set the power of the signal at the output of the device to any other value, for example, to minimum power, or any other target value.
• the signal SS serves as an input signal to a user device
• the user wishes to maintain the polarization of the light signal SS in line with the function of the user device.
• the light signal SS serves as an input signal to a Mach-Zehnder type interferometer, or even to an atomic interferometer system.
• such devices preferentially use linearly polarized waves.
• the output signal SS serves as an input signal to the downstream device considered.
• the rotation of the second opto-mechanical connection zone ZL2 can be slaved to the contrast of the fringes of the interferometric system.
• Another example is the efficiency measurement of polarizers.
• the rotation of the second opto-mechanical connection zone ZL2 can be slaved to the power transmitted by the polarizer tested.
• the user wishes to use the light signal SS at the output of device 1 as an input signal to a user device in a free field.
• a fiber collimator 192 is then connected to the downstream end 62 of the second single-mode optical fiber SM2. The light beam coming from the fiber collimator 192 is then positioned at the input of the user device in free field.
• the user wishes to measure the degree of polarization D of the light source S.
• the user places a photodiode type sensor at the output of the downstream end SM2 av of the second monomode optical fiber SM2.
• the user adjusts the angular orientation of the first rigid opto-mechanical connection zone ZL1 using the adjustment system 13 to obtain a maximum signal E max with the sensor.
• the user adjusts the angular orientation of the first rigid opto-mechanical connection zone ZL1 using the adjustment system 13 to obtain a minimum signal Emin with the sensor.
• the user wishes to linearly bias a non-polarized light signal using the device 1.
• it uses the adjustment system 3 to adjust the orientation of the second rigid opto-mechanical connection zone ZL2 around the second connection axis D2.
• the user adjusts this orientation to obtain the desired polarization direction.
• An analyzer placed downstream of the downstream end SM2 av of the second monomode optical fiber SM2 can be used to adjust this orientation.
• This embodiment can be used in particular in interferometric applications, in which it is desired to work with a determined polarization light signal.
• One of the advantages of the device 1 in this configuration, and of the polarization filtering and orientation method according to the invention, is to be able to manipulate the polarization of a light signal without component alignment problems.
• input preferentially coming from an optical fiber with an all-fibre system.
• the configuration in a box 3 with at least one optical bulkhead crossing 171 or 172 makes the device 1 compact and practical to use, also in relation to the symmetry of the latter.
• the device 1 does not include a second monomode fiber SM2.
• the second end 82 of the PZ polarizing fiber is directly integrated into a “user” device.
• the device 1 can be used for some of the applications mentioned above in the case where the device 1 also comprises a second monomode fiber SM2, where the light signal SS serves as an input signal to a Mach-Zehnder type interferometer, or even to an atom interferometer system. Indeed, such devices preferably use linearly polarized waves.
• FIG. 15 illustrates the integration of the device 1 according to the invention in the fiber gyrometer.
• a fiber gyrometer measures the phase shift between two counter-propagating light signals propagating in a Sagnac interferometer 23 and coming from a light source 21.
• the light source is a linearly polarized laser diode.
• the light source is connected to an optical coupler 27 coupling the source by an upstream optical fiber 271 to an input/output port 25 by a downstream single-mode fiber 272.
• the downstream input/output port 25 is coupled to the interferometer Sagnac interferometer 23 via an optical splitter (not shown) defining the two input arms of the Sagnac interferometer 23.
• the light wave arriving in the downstream input/output port must be linearly polarized.
• the polarization filtering and orientation device 1 can be inserted between the optical coupler 27 and the input/output port 25 in the following manner and as illustrated in FIG. 15.
• the first SMI monomode fiber is connected to the downstream monomode fiber of the optical coupler.
• the first monomode fiber SMI is welded to a first end 83 of a polarizing fiber PZ in accordance with the structure of the device 1, forming a first rigid opto-mechanical connection zone ZL1 along a first connection axis.
• the first rigid opto-mechanical connection zone ZL1 is covered by a splice protection.
• a wheel 131 in which the splice protection is inserted allows angular adjustment around the first connecting axis.
• the second end 82 of the PZ polarizing fiber is connected to the input/output port 25 (which is an integrated optical component).
• a user of the fiber optic gyroscope can adjust the angular orientation of the first rigid opto-mechanical connection zone ZL1 so as to limit the losses in the direction of the input/output port.
• the device 1 not comprising a second single-mode fiber SM2 also operates when the second end 82 of the polarizing fiber PZ is fixed by another optical device (integrated optical component as in the example of the fiber gyrometer , or polarization-maintaining fiber).
• another optical device integrated optical component as in the example of the fiber gyrometer , or polarization-maintaining fiber.
• the polarizing optical fiber PZ is not arranged in the form of a loop but in a straight line between the first rigid opto-mechanical connection zone ZL1 and the second first rigid opto-mechanical connection zone ZL2.

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• 2021
  • 2021-06-04 FR FR2105915A patent/FR3123732A1/fr active Pending
• 2022
  • 2022-06-02 EP EP22731649.4A patent/EP4348178A1/de active Pending
  • 2022-06-02 WO PCT/EP2022/065131 patent/WO2022253987A1/fr active Application Filing

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