EP0602158A1 - Device for optical transmission of data between different electronic circuits - Google Patents

Abstract

This device for transmitting information by optical means between different electronic circuits arranged on auxiliary boards (11) extending from a main board (12) of an electronic circuit box, in which at least each auxiliary board (11) comprises optical connection means fitted with means for transmitting and receiving information beams, and comprising means for transmitting the information beams optically between the cards, fitted with complementary connection means opposite card connection means, is characterized in that the means for transmitting the beams comprise a flat optical guide (10) made of light-conducting dielectric material extending approximately parallel to the main card (12), facing means for transmitting and receiving each card to connect them together.

Description

 Device for transmitting information optically between different electronic circuits

The present invention relates to a device for transmitting information by optical means between different electronic circuits arranged on auxiliary cards extending from a main card of an electronic circuit box.

There are already known in the prior art various transmission devices of this type, in which at least each auxiliary card comprises optical connection means provided with means for transmitting and receiving optical beams of information. These devices also include means for transmitting information beams by optical means provided with complementary connection means opposite the card connection means, to ensure the transmission of optical beams between cards.

The housings used to support the electronic circuits of any assembly generally comprise a rigid carcass and most often metallic. The part opposite to the front of this box is often used for fixing connectors for connecting the circuits of this box with the other components of the assembly in question. The lower part of this box is constituted by a main printed circuit board also called "motherboard", on which are arranged connectors which allow to interconnect sub-assemblies of electronic circuits arranged in the box on printed circuit boards. auxiliary cards also called "daughter cards". Different means of exchanging information between the different daughter cards have been devised in the state of the art.

Thus, for example, these exchanges are made by means of connectors and printed circuits fixed on the motherboard. However, in complex assemblies, the speed and capacity of information exchanges are such that the means described above are insufficient to ensure the proper functioning of the assembly. This is the case in particular for the assemblies used in the aeronautical industry but also in any industry where the acquisition and exchange of a very large number of information must be done very quickly and at very high speed. Means have also been developed in the prior art for transmitting information by optical means in the air.

In this case, each daughter card has one or more means for transmitting optical information beams and one or more means for receiving beams. Information is then distributed either from one daughter card to all the other daughter cards, or in series from card to card.

However, the drawbacks of exchanging information in the air are manifold, since unforeseen obstacles such as smoke can hinder or prevent the propagation of optical beams.

Furthermore, unwanted reflections can also introduce spurious information into the whole.

Also known in the prior art are information exchange means which use optical fibers and optical couplers, star, or individual, for each input-output interface of the daughter cards.

In this case, each coupler is connected to an optical fiber arranged for example in a loop.

However, this structure has a large footprint below the motherboard, which is not always compatible with the space available, in particular for on-board assemblies.

The object of the invention is therefore to solve these problems by proposing an information transmission device which is simple, reliable, as small as possible and whose cost price is as low as possible.

To this end, the invention relates to a device for transmitting information by optical means between different electronic circuits arranged on auxiliary cards extending from a main card of an electronic circuit box. , in which at least each auxiliary card comprises optical connection means provided with means for transmitting and receiving information beams, and comprising means for transmitting information beams between the cards, provided additional connection means opposite the card connection means, characterized in that the beam transmission means comprise a flat optical guide made of light-conducting dielectric material extending approximately parallel to the main card, opposite the transmission and reception means of each card to connect them together. The invention will be better understood with the aid of the description which follows, given solely by way of example and made with reference to the appended drawings, in which:

- Fig.l, 2 and 3 show devices for transmitting information by optical means of the prior art;

- Fig.4 schematically illustrates the operation of information transmission means according to the invention; - Fig.5, δ and 7 show different embodiments of an information transmission device according to the invention; and

- Fig.8,9 and 10 show different embodiments of an optical guide forming part of a transmission device according to the invention.

As can be seen in FIG. 1, there already exist in the state of the art, devices for transmitting information by optical means between daughter cards designated by the general reference 1. These cards include for example means 2 for transmitting an optical information beam in the direction of means 3 for receiving it, provided on the other daughter cards.

These different means make it possible to transmit different signals between the cards and therefore ensure the exchange of information between these cards. These daughter boards extend approximately perpendicularly from a mother board 4 and are connected to the circuits thereof, for example by means of electrical connectors 5. These means are described, for example, in the review "l ' Onde Electrique "vol.70, No. 6. November, December 1990. As the ^r previously described, these means of transmission by optical means 1 in air have a number of disadvantages.

In FIGS. 2 and 3, another embodiment of means for transmitting information by optical means is shown, of the state of the art. This figure shows an information transmission device using optical fibers. for example 6, making it possible to connect daughter cards 7 to each other using an optical coupler 8, for example in a star shape. Each means of transmitting or receiving information from each daughter card is connected to an optical fiber and all the optical fibers are connected at the optical coupler to ensure the transmission of information between the different cards. These different elements are fixed on a motherboard 9.

The various drawbacks of this type of device have also been described above.

As can be seen in FIGS. 4,5 and 6, the information transmission device according to the invention comprises means for transmitting optical beams between cards, which are in the form of a flat optical guide , designated by the general reference

10, extending roughly parallel to the main card opposite transmission and reception means for connection of each auxiliary card for example

11, to connect them together and allow the transmission of the optical beams between these different cards. More particularly, the planar optical guide is formed from dielectric material which conducts light, such as for example polymer. This optical guide comprises, opposite means for transmitting and receiving beams from each card, connection means comprising a portion of the input and output surface of the optical beams and a portion of deflection of these beams for deflecting the beams emanating from the transmission means of each card in the general direction of the guide and the beams propagating in the guide, towards the reception means of each card.

Thus, the beams passing through the guide propagate in a direction parallel to the axis thereof between the different cards and at the level of each card and more particularly of the connection means of each of these, these beams are deviated at 90 ° in the example illustrated, to be directed to means for receiving these cards. The beams emitted by the emission means of each card are also deflected at 90 ° to propagate in a direction roughly parallel to the axis of the guide in the direction of the other cards.

In the various embodiments shown in these figures, the deflection means consist of inclined planes, for example 10a and 10b, at 45 °, arranged opposite the means for transmitting and receiving each card as can be see it in Fig. 4.

This allows the transmission and reception means of each card to transmit and receive optical beams in and from the guide in order to ensure an exchange of information between the various cards.

These inclined planes can be formed by the edges of notches or V-shaped grooves, or else of conical recesses with a circular or other base or pyramids with any polygonal base.

The use of these recesses has a certain number of advantages compared to the notches and the grooves, because it makes it possible to improve the quality of the coupling in particular in reception. In Figs. 5,6 and 7, different positions of the guide 10 have been illustrated relative to a motherboard 12. In Fig. 5, the guide 10 is arranged under the motherboard 12 and this guide has portions 10c passing through this motherboard 12, a part of this guide projecting beyond this card to allow the optical connection of the guide and of means for transmitting and receiving bundles of cards.

It can also be seen in this figure that the guide comprises, facing the map, an inclined plane lOd used to deflect the optical beams emitted and received by this card, in order to connect it to other cards.

In Fig. 6 and 7, the optical guide 10 is arranged above the motherboard 12 and includes connection means opposite each card. These connection means can be constituted by inclined planes for example at 45 ° formed by the lateral sides of V-grooves whose tip is directed towards the cards, to connect these cards to each other. According to a particular embodiment, the surface portion of the guide facing the issuing and receiving means of each card can be curved to improve the transmission of the beams.

In FIGS. 8, 9 and 10, various forms of guide have been shown and it can be seen that this can have a star shape as shown in FIG. 8, that is to say that this guide comprises different branches to connect the different cards together, a loop shape as shown in Fig.9 or a straight shape as shown in Fig.10.

It will also be noted that the depths of the grooves or recesses may be different depending on their position in the guide to improve the transmission of information. Thus, for example, these grooves or these recesses may have a decreasing depth the closer we get to the central part of the guide.

This guide can for example be produced by molding and can be fixed on the motherboard, for example by gluing or integrated into the latter during its manufacture.

Claims

 CLAIMS 1. Device for transmitting information optically between different electronic circuits arranged on auxiliary cards (11) extending from a main card (12) of an electronic circuit box, in which at least each auxiliary card (11) comprises optical connection means provided with means for transmitting and receiving information beams, and comprising means for transmitting information beams by optical means between the cards, provided with means complementary connection opposite the card connection means, characterized in that the beam transmission means comprise a flat optical guide (10) made of dielectric material conducting light, extending approximately parallel to the main card (12), opposite the transmission and reception means of each card to connect them together. 2. Device according to claim 1, characterized in that the guide is made of polymer. 3. Device according to claim 1 or 2, characterized in that the means for transmitting and receiving the optical beams of the auxiliary cards extend in a plane approximately perpendicular to the plane of the guide (10) and in that the complementary connection means of the guide comprise, opposite these connection means of each card, a portion of the beam entry and exit surface and a portion (10a, 10b, 10d) of beam deflection to deflect the beams from the beam emitting means of each card in the general direction of the guide and the beams propagating in the guide, towards the receiving means of each card. 4. Device according to any one of the preceding reven¬ dications, characterized in that the guide has a star shape. 5. Device according to claims 1 to 3, characterized in that the guide has a loop shape. 6. Device according to claims 1 to 3, characterized in that the guide is straight. 7. Device according to any one of the preceding claims, characterized in that the guide (10) is arranged under the main card (12). 8. Device according to claim 1 to 6, characterized in that the guide (10) is arranged on the main card (12). 9. Device according to any one of reven¬ dications 3 to 8, characterized in that the beam deflection portion comprises inclined planes. 10. Device according to claim 9, carac¬ terized in that the inclined planes are formed by the edges of V-grooves. 11. Device according to claim 9, carac¬ terized in that the inclined planes are formed by the edges of recesses of gradually decreasing health section. 12. Device according to claim 11, characterized in that the recesses are conical. 13. Device according to claim 11, characterized in that the recesses are pyramidal. 14. Device according to any one of claims 10 to 13, characterized in that the depths of the grooves or recesses are different according to their position in the guide.