FR2714740A1 - Set of optical isolators comprising transverse Faraday rotators - Google Patents

Abstract

A substrate (2) supports a number of channels (V1, V2, V3, V4) placed side by side in a transverse direction. Each channel has an upper section comprising a diode laser (L) and a lens (B1). This is followed by an isolating section in the form of a bar comprising an upper polariser (PM), a rotating element (R) and a lower polariser (PV) forming bars across the isolating region. The lower section has an optical fibre (F1). A magnet, adapted to all the rotating elements in the isolating bar, turns the plane of polarisation anticlockwise (14) through 45 degrees. The substrate has a transverse groove (18) to support the bar across the entire width of the isolating region. Longitudinal seatings (HB1-HB4, HF1-HF4) on the substrate support the upper and lower sections.

Description

Optical isolation assembly and optical transmission module comprising this assembly.

 The present invention relates in particular to an optical isolation assembly. It finds application in fiber optic telecommunication networks.

 Such a network conventionally comprises optical transmission modules. Such a module receives a sheet of optical fibers in which the fibers are parallel to the same longitudinal direction and are juxtaposed in a transverse direction. This sheet is connected to a laser strip comprising laser emitters each emitting in this longitudinal direction in an associated optical fiber, these emitters therefore being juxtaposed in this transverse direction. It is usual for each laser emitter to be protected against return of light by an optical isolator with Faraday effect interposed between this emitter and the associated fiber.

 Such an insulator comprises optical elements through which light passes. These elements include a polarizing rotator element with a high Verdet constant, and most often one or two polarizers. The insulator further includes a magnet for subjecting the rotator element to a magnetic field.

 The costs of producing and positioning these optical elements of the isolator constitute an appreciable fraction of the total cost of producing an optical transmission module of this kind.

 The object of the present invention is in particular to enable the isolators of such a transmission module and more generally of an optical isolation assembly comprising a row of such isolators to be produced and positioned in a simple and inexpensive manner.

 For these purposes it has in particular for object an optical isolation assembly comprising rotator elements with Faraday effect arranged in a transverse direction. According to this invention, these rotator elements consist of successive segments of the same bar extending continuously in this direction.

 Using the attached diagrammatic figures, a more specific description will now be given below, by way of nonlimiting example, how the present invention can be implemented. When the same element is represented in several figures, it is designated therein by the same reference sign.

 FIG. 1 represents a perspective view of an optical transmission module according to this invention.

 Figure 2 shows a top view of this module.

 Figure 3 shows a side view of this module.

 We will first describe the components of an optical isolation assembly included in this transmission module.

Among these elements some are known. These are the following
- A substrate 2. A main face 4 of this substrate has a longitudinal direction extending between an upstream side 6 and a downstream side 8 of this substrate. A direct longitudinal direction OX going from this upstream side to this downstream side and a reverse longitudinal direction XO opposite this direct direction is defined in this direction. This face 4 also has a transverse direction OY crossed with this longitudinal direction and, more precisely, typically perpendicular to the latter.

Optical elements are carried by this substrate. They constitute at least partially a plurality of channels
V1, V2, V3, V4 each designated by the letter V followed by a number for this channel. These channels transmit respectively and separately a plurality of useful light waves propagating generally in the direct longitudinal direction. They are juxtaposed in the transverse direction OY.

Each of these channels, for example channel V1, has sections extending and succeeding one another in the direct longitudinal direction and each consisting of at least one optical element. These sections include
an upstream section TA consisting of at least one upstream optical element L1, B1 carried by the substrate,
an isolation section TB consisting of at least one optical isolation element PM1, Ri, PV1 also carried by the substrate,
- And a downstream section TC consisting of at least one downstream optical element F1 still carried by the substrate.

 The optical elements corresponding in the various channels V1 ... V4 are designated by reference signs made up of the same letters, but ending with the number 1 ... 4 of the channel in question. The isolation sections of the plurality of these paths follow one another in the transverse direction OY in an isolation area 12 having a width 13 in this direction.

 Each of the channels such as V1 is provided with an optical isolator 10. In general, this isolator must perform the following functions: it must allow a useful light wave transmitted by this channel to pass in the direct longitudinal direction from the upstream section to the section downstream to produce a useful effect. At the same time it must prevent any parasitic light wave traversing the downstream section in the opposite longitudinal direction from producing a damaging effect in the upstream section.

The insulator 10 first comprises for this a rotator element R1 with Faraday effect constituting a said optical insulation element carried by the substrate. This rotator element is such that a magnetic field adapted to this element makes the latter able to rotate 45 degrees in a direct angular direction 14 the direction of polarization of a useful light wave having a linear polarization, this direct angular direction being defined by rotation around the longitudinal direction. This insulator also includes a magnet 16 creating this suitable magnetic field.

 We will now recall how such an insulator performs its functions, starting with what concerns the useful light wave. This wave first has upstream of the rotator element a linear polarization in a direction which will be called hereinafter "normal upstream polarization direction". Polarization directions of light waves will be defined by their angular offsets measured from this normal upstream polarization direction in the direct angular direction.

When the useful wave crosses the rotator element, it undergoes the Faraday effect there. I1 follows that it then propagates downstream of this element with a direction of normal downstream polarization having an angular offset equal to 45 degrees and positive. The normal upstream polarization direction is such that this offset allows said useful effect.

 As a first example of the polarization mode of the useful light wave, this wave can have a linear polarization because it is generated by a semiconductor laser emitter. The orientation of this transmitter then imposes the normal upstream polarization direction. As a second example, compatible with the first, this direction of polarization can be imposed by an upstream polarizer such as PM1 disposed upstream of the rotator element such as R1. As for said useful effect, it can be constituted by the fact that this wave is modulated to carry information in the downstream section and beyond.

 As regards the parasitic light wave, this wave first presents downstream of the rotator element the normal downstream direction of polarization. After having undergone the Faraday effect in this element, it has, upstream of the latter, a direction of polarization having an angular offset equal to 90 degrees and positive. this latter angular offset prevents said harmful effect. As a first example of the stray wave polarization mode, this wave can have in the downstream section a linear polarization in the normal downstream direction of polarization because it is generated there by a stray reflection of the useful wave having this direction of polarization. As a second example compatible with the first, such a direction of polarization can be imposed by a downstream polarizer such as PV1 disposed downstream of the rotator element such as R1. As for the harmful effect of the parasitic wave, it may for example be a disturbance of the optical functioning of a semiconductor laser transmitter receiving this parasitic wave. Such a harmful effect does not occur or at least is limited if the direction of polarization of the stray wave is perpendicular to the direction of polarization of the light wave emitted by this laser.

 According to the present invention, the insulation assembly comprises a rotator bar R extending continuously in the transverse direction OY over the entire width L of the insulation area 12. This results in the isolation section TB of each channel such that V1 has a segment such as R1 of this rotator bar. This segment constitutes said rotator element of the optical isolator of this channel.

 Preferably and as shown, the isolation assembly comprises a magnet 16 creating a magnetic field constituting all of said magnetic fields adapted to the rotator elements R1 ... R4 of the optical isolators of all the channels V1 ... V4. This magnet is for example constituted by two blades magnetized in the longitudinal direction in the same direction. These two plates extend in the transverse direction, one above the other below the substrate 2.

 Preferably and as shown, an upstream polarizing bar PM is placed in the insulation area 12 upstream of the rotator bar R and constitutes a said optical insulating element carried by the substrate 2. This upstream polarizing bar extends continuously in the transverse direction OY over the entire width L of this area and it imposes the direction of upstream polarization normal to any light wave passing through it. It thus constitutes at the same time all the upstream polarizers PM1 ... PM4 previously mentioned.

 Also preferably and as shown, a downstream polarizing bar PV is disposed in the isolation area 12 downstream of the rotator bar R and constitutes a said optical insulating element carried by the substrate 2. This downstream polarizing bar s' extends like the upstream polarizing bar.

 I1 imposes the normal downstream polarization direction on any light wave passing through it. It thus constitutes at the same time all the downstream polarizers PV1 ... PV4 previously mentioned.

 More preferably and as shown, a groove 18 is dug in the main face 4 of the substrate and extends in the transverse direction OY to constitute a housing for all said bars, that is to say at least for the rotator bar R and also for the upstream PM and / or downstream PV polarizing bars if the isolation assembly includes these polarizing bars.

Again preferably and as shown, the substrate 2 further comprises housings HL, HB1 .... HB4, HF1 ... HF4 hollowed out in the main face 4 to receive the upstream optical elements L1 ... L4, B1 .. .B4 and downstream F1 ... F4 carried by this substrate. These housings align the tracks V1 ... V4 in the longitudinal direction OX:
This substrate 2 is advantageously made of monocrystalline silicon. At least some of the accommodation 18,
HL, HB1 ... HB4, HF1 ... HF4 then have faces according to privileged crystal planes of this substrate.

The components described above of the isolation assembly constitute at the same time an optical emission module. For this, the upstream optical elements carried by said substrate 2 comprise, in each channel such as V1, in succession in the direct longitudinal direction OX
a semiconductor laser emitter such as L1 emitting a said useful light wave having the normal upstream polarization direction,
- And a lens such as B1, for example in the form of a ball, focusing this wave.

The laser transmitters L1 ... L4 of all channels
V1 ... V4 are formed in the same laser strip L extending in the transverse direction OY, the lenses
B1 ... B4 being on the other hand separated.

 As for the downstream optical elements carried by the substrate, they comprise in each channel, for example in the channel V1, an optical fiber F1 receiving the useful light wave focused by the lens B1 of this channel. The substrate 2 then has, for each channel, a guide groove HF1 constituting a said housing for holding this optical fiber F1 in the longitudinal direction OX.

 A cover (not shown) keeps all the optical elements in their respective housings.

Claims (9)

 1) Optical isolation assembly comprising Faraday effect rotator elements arranged in a transverse direction, this assembly being characterized by the fact that these rotator elements are constituted by successive segments (R1 ... R4) of the same bar ( R) extending continuously in this direction (OY).  2) An assembly according to claim 1, this assembly comprising a substrate (2) having a main face (4) having  a longitudinal direction (OX) extending between an upstream side (6) and a downstream side (8) of this substrate by having a direct longitudinal direction (OX) from this upstream side to this downstream side and a reverse longitudinal direction ( XO) opposed to this direct sense,  - and a transverse direction (OY) crossed with this longitudinal direction,  this insulation assembly further comprising optical elements carried by said substrate to constitute at least partially a plurality of channels (V1, V2, V3, V4) transmitting respectively and separately a plurality of useful light waves propagating generally in said direct longitudinal direction, these channels being juxtaposed in said transverse direction,  each of these channels (V1) having sections extending and succeeding each other in said direct longitudinal direction and each consisting of at least one optical element, these sections including  - an upstream section (TA) constituted by at least one upstream optical element (L1, B1) carried by said substrate,  an isolation section (TB) consisting of at least one optical isolation element (PM1, R1, PV1) carried by this substrate,  - and a downstream section (TC) consisting of at least one downstream optical element (F1) carried by this substrate,  the isolation sections of the plurality of these paths following each other in said transverse direction (OY) in an isolation area (12) having a width (13) in this direction,  each of these channels (V1) being provided with an optical isolator (10) allowing on the one hand the useful light wave transmitted by this channel to pass in said direct longitudinal direction from said upstream section to said downstream section to produce an effect useful, this insulator on the other hand preventing any parasitic light wave traversing this downstream section in said reverse longitudinal direction from producing a damaging effect in said upstream section, this optical isolator comprising for this at least  - a Faraday effect rotator element (R1) constituting a said optical insulation element carried by said substrate, this rotator element being such that a magnetic field adapted to this element makes the latter able to rotate 45 degrees in one direction direct angular (14) the direction of polarization of a said useful light wave having a linear polarization, this direct angular direction being defined by rotation around said longitudinal direction,  - and a magnet (16) creating this adapted magnetic field,  this assembly being characterized by the fact that it comprises a rotator bar (R) extending continuously in said transverse direction (OY) over the entire said width (L) of the insulation area (12) so that the isolation section (TB) of each said channel (V1) comprises a segment (R1) of this rotator bar, this segment constituting said rotator element of the optical isolator of this channel.  3) An assembly according to claim 2, this assembly being characterized in that it comprises a magnet (16) creating a magnetic field constituting at the same time all of said magnetic fields adapted to the rotating elements (R1 ... R4) of the optical isolators of all said channels (V1 ... V4).  4) An assembly according to claim 2 characterized in that it further comprises an upstream polarizing bar (PM) disposed in said isolation area (12) upstream of said rotator bar (R) and constituting a said optical element of insulation carried by said substrate (2), this upstream polarizing bar extending continuously in said transverse direction (OY) over the entire said width (L) of this insulation area.  5) An assembly according to claim 2 characterized in that it further comprises a downstream polarizing bar (PV) disposed in said isolation area (12) downstream of said rotator bar (R) and constituting a said optical element of insulation carried by said substrate (2), this downstream polarizing bar extending continuously in said transverse direction (OY) over the entire said width (L) of this insulation area.  6) An assembly according to any one of claims 2 to 5, this assembly being characterized in that said substrate (2) has a groove (18) hollowed out in said main face (4) of this substrate and extending along said transverse direction (OY) to constitute a housing for all said bars (R, PM, PV).  7) An assembly according to claim 6 characterized in that said substrate (2) further comprises housings (HL, HB1 .... HB4, HFi ... .HF4) hollowed out in said main face (4) to receive said elements upstream (L1 ... L4, B1. .B4) and downstream (F1 ... F4) optics carried by this substrate so as to align said channels (V1 ... V4) in said longitudinal direction (OX).  8) An assembly according to claim 7 characterized in that said substrate (2) consists of monocrystalline silicon, at least some of said housings (18, HL, HB1 ... HB4, HF1 ... HF4) having faces according to privileged crystalline planes of this substrate.  9) Optical emission module characterized in that it comprises an insulation assembly according to any one of claims 2 to 8, said upstream optical elements carried by said substrate (2) comprising, in each said channel (V1 ), in succession in said direct longitudinal direction (OX)  - a semiconductor laser emitter (L1) emitting a said useful light wave having said normal upstream polarization direction,  - and a lens (B1) focusing this wave,  the laser emitters (L1 ... L4) of all said channels (V1 ... V4) being formed in the same laser strip (L) extending in said transverse direction (OY),  said downstream optical elements carried by said substrate comprising in each said channel (V1) an optical fiber (F1) receiving said useful light wave focused by said lens (B1) of this channel, said substrate (2) having for each said channel a groove guide (HF1) constituting a said housing for holding this optical fiber (F1) in said longitudinal direction (OX).