FR2667697A1 - Device for attenuating the intensity of the light being propagated in an optical fibre, by application of a macro-bend in this fibre - Google Patents

Abstract

Optical attenuation device. This device comprises at least one assembly which includes an optical fibre (14) in which the light is capable of being propagated, and means (8, 10, 16, 36) for applying at least one macro-bend to the fibre, this macro-bend enabling the intensity of the light to be attenuated. Application to fibre-optic transmissions.

Description

DESCRIPTION
The present invention relates to an optical attenuation device.

 It applies in particular to the field of optical fiber transmissions.

 The known optical attenuation devices are of the opto-electronic type and / or require optical connections.

 The present invention solves the problem of achieving optical attenuation essentially mechanically and without having to make an optical connection.

 To this end, the invention uses the application of at least one macrocurvature to an optical fiber in which light is liable to propagate and which is therefore used as a transmission medium.

 By "macrocurvature" is meant a curvature whose radius is at least about 2mm.

 The macrocurvature applied to the fiber causes a weakening of the intensity of the light which propagates there.

 This attenuation is a function of the radius of curvature of the fiber and the wavelength of light.

 We can go as far as the total extinction of light, hence an application of the invention to the production of optical switches.

 In addition, if lights of different wavelengths propagate in the fiber, the lights corresponding to certain wavelengths can be attenuated or even extinguished, but not the other lights, hence an application of the invention to the production of optical filters.

 Various articles have already been published on the curvature of optical fibers and formulas giving the attenuation values as a function of the radius of curvature and of the wavelength have been established.

See for example the article by
SB ANDREASEN published in Electronics Letters, vol.

23, No. 21, October 8, 1987, p. 1138-1139.

 Specifically, the subject of the present invention is an optical attenuation device, characterized in that it comprises at least one assembly comprising an optical fiber, in which light is liable to be propagated, and means of application at least one fiber macrocurve, this macrocurve making it possible to attenuate the intensity of the light.

 Preferably, the application means are capable of varying the length of fiber subjected to the mac curl.

 The light transmitted by the fiber is thus more or less attenuated according to the length of fiber subjected to macrocurvature and the wavelength of the light.

 The application means may be capable of varying this length of fiber continuously or, on the contrary, discontinuous (in leaps and bounds).

 According to a first particular embodiment of the device which is the subject of the invention, the application means are means which act by rotation.

In this case, the means of application may include:
- a set of two pulleys integral with one another, the fiber passing between and on the pulleys,
means of rotation of the set of pulleys, and
- means for tensioning the fiber.

 According to a second particular embodiment, the application means are means which act by translation.

In this case, the means of application may include:
- a first and a second pulley against which the fiber rests,
a third pulley provided for pressing on the fiber along the perpendicular bisector of the segment joining the centers of the first and second pulleys, the latter being sufficiently spaced apart from one another for this purpose,
means for translating the third pulley along this perpendicular bisector, and
- means for tensioning the fiber.

 It should be noted, on the one hand, that radii of curvature which exceed 2.5 cm cause almost no additional weakening and, on the other hand, that the fibers with adapted sheath ("matched cladding fibers") are much more sensitive to this weakening phenomenon than the depressed cladding fibers.

 The present invention is therefore more particularly usable with fibers having a suitable sheath.

 Finally, the device which is the subject of the invention may comprise a plurality of assemblies and an optical coupler which connects an optical fiber to the optical fibers of the assemblies.

The present invention will be better understood on reading the description of exemplary embodiments given below, by way of purely indicative and in no way limiting, with reference to the appended drawings in which
FIGS. 1A, 1B and 1C schematically represent states of a device according to the invention, this device comprising application means which act by rotation,
FIG. 2 is a diagram making it possible to calculate the length of optical fiber subjected to macrocurvature as a function of the angle of rotation of the assembly of two pulleys that the device represented in FIG. 1 comprises,
FIG. 3 is a schematic view of a particular embodiment of the invention, comprising application means which act by rotation,
FIG. 4 is a schematic view of another particular embodiment of the invention, comprising application means which act by translation, and
- Figures 5 and 6 schematically illustrate other devices according to the invention.

 In Figures 1A, 16 and 1C are shown three states of a device according to the invention.

 This device acts by rotation and for this purpose comprises two identical pulleys 2, 4, of radius R, which are fixed on an axis 5, the respective centers O and 01 of the pulleys 2 and 4 being respectively located at the ends of the axis 5 , the latter being able to pivot in its middle A.

 In the idle state, an optical fiber 6, in which is likely to propagate the light that we want to attenuate, passes between the two pulleys without undergoing macrocurvature, as seen in Figure 1A.

 The points B and E in this FIG. 1A are symmetrical to one another with respect to A and represent points to which the fiber 6 is fixed but which are movable in translation on a straight line passing through A when the assembly constituted by the pulleys 2 and 4 and the axis 5 pivots around A, the fiber 6 being continuously in tension.

 In FIG. 1B, corresponding to a rotation of 900 of the axis 5 around A, it can be seen that the fiber is subjected to two macrocurvings of the same length l (MN) = l (PQ).

 FIG. 1C corresponds to a rotation of 1800 of the axis 5 around A, which gives rise to two macrocurvatures of the same length l (RS) = l (TU).

We see that a continuous rotation will vary the length of fiber subjected to the macrocurvature of radius R, and therefore The weakening
There will therefore be a relationship between the angle of rotation and the weakening of the light.

 To determine this relationship, the length of fiber subjected to macrobending is calculated below as a function of the angle of rotation.

 The device being symmetrical, the calculation is made for a single pulley, for example the pulley of center O (FIG. 2).

The lengths AB, OA and OI (= OJ) are respectively noted L, d and R, the length of the arc
IJ is noted 1/2 and the angle al is known (see these notations in Figure 2).

We can write :
sin a2 = R / d
tg bl = OH / BH = (d.sin a1) / (Ld.cos a1)
sin b2 = OJ / OB = (R.sin b1) / (d.sin al).

 The angles g and w are additional and the angles g and (al + a2 + bl + b2) are also; therefore, the angles w and (al + a2 + bl + b2) are equal.

 The length I of fiber subjected to macrobending is then easily determined with: I = 2w.R.

 The curve of the variations of the contact length (l) can be plotted as a function of the angle of rotation (ai), for different values of L, the quantities d and R being fixed and equal to 5mm and 6mm respectively, for example.

 We note that the curve is all the more linear as L is important.

 Depending on the desired attenuation range, the diameter of the pulleys can be determined.

 In practice, it is advantageous to choose a distance OA close to R, which improves the linearity.

 In Figure 3, there is shown schematically a device according to the invention comprising two identical pulleys 8 and 10 whose axes are parallel.

 The device shown in FIG. 3 also includes an optical fiber 14 in which light is flowing, the intensity of which is to be attenuated, this fiber passing over and between the pulleys.

 The pulleys 8 and 10 are mounted on an orientable disc 16, the axis 18 of which is parallel to and equidistant from the axes of the pulleys.

 The pulleys 8 and 10 are free to rotate on the disc.

 Two "points" of the fiber, which are located on either side of the disc 16 and are symmetrical to each other with respect to the axis 18 of this disc 16, are respectively "fixed" by clamps 20 and 22 which make it possible to block the protective sheath of the fiber while leaving the latter free inside this sheath.

 The clamps 20 and 22 are made movable in relation to a straight line dl which passes through the axis 18 of the disc 16.

 To do this, the clamps 20 and 22 are respectively mounted on carriages 24 and 26 and the latter are movable in translation parallel to the straight line dl, by means of ball bearings (not shown), respectively on raceways 28 and 30.

 The fiber 14 is set and kept in tension by return springs 32 and 34, each of these being fixed, by one end, to the corresponding carriage and by the other end, to one end of the raceway.

 The disk 16 makes it possible to rotate the pulleys 8 and 10 around a axis 18 around a axis, rotation being possible in one direction and in the opposite direction.

 We see in Figure 3 a means 36 for controlling the rotation of the disc 16 to the desired angular position and to maintain the disc 16 at this position.

For information only and not at all
limitative, a notch switch is used on which the set of pulleys is mounted as indicated above and which allows this set of pulleys to rotate.

 It is thus possible to impose on the fiber 14 a determined macrocurvature, at the level of each pulley, and therefore a determined attenuation.

 Another device according to the invention, which acts by translation, is schematically represented in FIG. 4 and also comprises the two pulleys 8 and 10.

 In the case of FIG. 4, these pulleys 8 and 10 are mounted to rotate respectively around two axes which are fixed and parallel.

 The device shown in Figure 4 also includes another pulley 38 whose axis is parallel to those of the pulleys 8 and 10 and which is movable in translation along the perpendicular bisector m of the segment joining the centers of the pulleys 8 and 10, the latter being sufficiently spaced from each other to allow passage of the pulley 38 between them.

 This pulley 38 can be identical to the pulleys 8 and 10.

 The device shown in FIG. 4 also includes the fiber 14 which transports the light which it is desired to attenuate.

 Initially, the fiber 14 passes over the pulleys 8 and 10 but not between them and the light is not attenuated by the device.

 The fiber then extends along a straight line D1 and the pulley 38 is located on one side of this straight line D1 and does not press on the fiber 14, while the two pulleys 8 and 10 are located on the other side of this right.

 The device shown in FIG. 4 also includes means 40 and 42 for tensioning the fiber 14, means which have been described with reference to FIG. 3 and which include the members bearing the references 20, 24, 28, 32 and 22, 26, 30, 34.

 In the case of FIG. 4, the "points" of the fiber 14, which are respectively "fixed" by the clamps 20 and 22, are placed on the line D1, symmetrically to one another with respect to the perpendicular bisector m, and on either side of the set of pulleys 8 and 10.

 The clamps 20 and 22 are movable in translation parallel to the straight line D1.

 The pulley 38 is free to rotate at one end 44 of a slide 46 which extends along the perpendicular bisector m and which is displaceable in translation in a groove 48 parallel to the perpendicular bisector m.

 Means 50 are provided for controlling the movement of the slide 46 to the desired position and for locking this slide 46 in this position.

 By moving the pulley 38 towards the pulleys 8 and 10, this pulley 38 presses on the fiber 14, induces on it a macrocurvature and therefore causes an attenuation of the light transmitted by the fiber 14.

 The present invention makes it possible to produce continuously variable attenuators with different attenuation ranges and with a resolution as fine as desired.

 The change of range or resolution can be effected by a change of pulleys in the devices of the kind of those represented in FIGS. 3 and 4.

An attenuation device in accordance with
The invention has important advantages over those which are currently commercially available:
- it does not require any connection and, in the idle state, there is therefore no loss of insertion,
- it does not generate any reflection,
- it acts on the fiber itself, its use does not require cutting it,
- It can be carried out in a simple manner and therefore inexpensive.

 The invention makes it possible to produce selective attenuation devices, switches and optical switches (wavelength filtering).

For example, with a judicious choice of pulley diameters, a device can be produced in three positions:
(a) - transparent at 1300nm and 1550nm,
(b) - transparent at 1300nm and opaque at
1550nm,
(c) - opaque at 1300nm and 1550nm.

We see in Figure 5 a set of eight devices according to the invention 500, 502, 504, 506, ..., 512 and 514 which are mounted in parallel and whose
The associated fibers receive from the same fiber 58 lights of respective wavelengths 1300 nm and 1550nm, via an appropriate coupler 60.

 The devices 500, 502, 504 are for example respectively in positions (a), (b), (c) while the other devices are all in position (a).

This allows, in a fiber optic transmission network:
- to have a minimum basic service at 1300nm and an optional service at 1550nm,
- to cut a subscriber without disconnecting,
- to use reflectometry without limitation for the commissioning and maintenance of the network by putting, for example, your devices 502 to 514 of FIG. 5 in position (b) and the device 500 in position (a).

 We can characterize at 1550nm the branch relating to this device 500 and in particular make a continuity test up to the subscriber in reflectometry.

 It can be seen that with positions (a) and (c) an optical switch is produced.

 It can also be seen that the present invention makes it possible to produce devices having optical switching functions; the choice of a light emitter will be done by cutting the others.

 This is schematically illustrated in FIG. 6 where we see eight devices 602, 604, 606, ..., 616 in accordance with the invention which are mounted in parallel and whose associated fibers send the lights which they transport in a same optical fiber 70 via an appropriate optical coupler 72.

 In the case of FIG. 6, the choice of a light emitter (not shown), associated with one of the eight fibers of the eight devices, will be done by "cutting" the other seven devices, that is to say by putting them in an opaque state).

 The devices according to the invention are easily remotely controllable by electromechanisms (motors, relays, ...).

 The devices described use the fiber used as a support, but it is also possible to produce characterized independent devices, which can be inserted into links in the same way as the conventional attenuators currently available on the market.

Claims (8)

 1. Optical attenuation device, characterized in that it comprises at least one assembly comprising an optical fiber (14), in which light is liable to propagate, and means (8, 10, 16, 36; 8, 10, 38, 46, 48, 50) of applying at least one macrocurvature to the fiber (14), this macrocurvature making it possible to attenuate the intensity of the light.  2. Device according to claim 1, characterized in that the application means (8, 10, 16, 36; 8, 10, 38, 46, 48, 50) are capable of varying the length of fiber subjected to the macro curvature.  3. Device according to any one of claims 1 and 2, characterized in that the application means (8, 10, 16, 36) are means which act by rotation.  4. Device according to claim 3, characterized in that the application means comprise:  - a set of two pulleys (8, 10) integral with each other, the fiber (14) passing between and on the pulleys,  means (16, 36) for rotating the pulley assembly, and  - Means (40, 42) for tensioning the fiber (14).  5. Device according to any one of claims 1 and 2, characterized in that the application means (8, 10, 38, 46, 48, 50) are means which act by translation.  6. Device according to claim 5, characterized in that the application means comprise:  - a first (8) and a second (10) pulleys against which the fiber (14) rests,  - A third pulley (38) provided to press on the fiber along the perpendicular bisector (m) of the segment joining the centers of the first (8> and second (10) pulleys, these being sufficiently spaced from each other to this effect,  means (46, 48, 50) for translating the third pulley along this perpendicular bisector (m), and  - Means (40, 42) for tensioning your fiber.  7. Device according to any one of claims 1 to 6, characterized in that the optical fiber (14) is a suitable sheath fiber.  8. Device according to any one of claims 1 to 7, characterized in that it comprises a plurality of assemblies (500, ..., 514; 602, 616) and an optical coupler (60; 72) which connects an optical fiber (58; 70) to the optical fibers of the assemblies.