DE10139673A1 - Optical signal transmission medium has foil-like signal transmission layer, foil-like boundary layer(s) bounding on signal transmission layer with lower refractive index - Google Patents

Abstract

The optical signal transmission medium has a foil-like signal transmission layer (11) and at least one foil-like boundary layer (12,13) bounding on the signal transmission layer whose refractive index is lower than that of the signal transmission layer. Foil-like boundary layers can be arranged on both sides of the signal transmission layer. AN Independent claim is also included for the following: an optical coupler, especially for a medium for optical signal transmission.

Description

The invention relates to a medium for optical signal transmission according to the The preamble of claim 1 and 8 and an optical coupler according to the preamble of claim 10.

In optical signal transmission technology or optical Communication technology are connections between communication devices that Exchange data with each other with the help of optical cables, so-called Optical fiber cables, manufactured. In this case, the optical serves Cable as a medium for optical signal transmission.

Should be in a building, e.g. B. in an office, communication facilities be connected with fiber optic cables, especially if the wall connections of a flush-mounted fiber optic cable in the Close planning of the communication facilities, precise planning required. A subsequent move of the communication facilities must then with long connecting cables between the wall connection of the Optical fiber cable and the communication device or through subsequent laying work can be carried out under plaster. Providing too as many wall connections as possible or laying the fiber optic cables with excess length in empty pipes or below the floor accordingly provided cavities can only remedy this to a limited extent. The The flexibility of previous optical cable networks is therefore limited.

Furthermore, when using an optical cable as a medium for optical signal transmission due to the small dimensions of the optical Suitable optical sockets are installed in the fibers in the area of the wall connections that have a corresponding connector to within a few micrometers to lead. This is the only way to create a low-loss connector between the optical cable and the communication device to be connected be guaranteed. Because of these high accuracy requirements both the plugs and the sockets have to be made with great effort and with the help of special tools.

Proceeding from this, the present invention is based on the problem a new medium for optical signal transmission and one to create appropriate optical coupler.

This problem is addressed by a medium for optical signal transmission and with the features of claims 1 and 8 and by an optical coupler solved the features of claim 10.

Preferred developments of the invention result from the Subclaims and the following description. Based on Drawing is a preferred embodiment of the invention closer explained. The drawing shows:

Fig. 1 shows an inventive medium for optical signal transmission in cross-section,

Fig. 2, the medium for optical signal transmission of Fig. 1 together with an optical coupler according to the invention also in cross section.

Fig. 1 shows an embodiment of a medium 10 of the invention for optical signal transmission. The medium 10 has a film-like and multilayer structure.

Referring to FIG. 1, the medium 10 according to the invention comprises for optical signal transmission, a sheet-shaped signal transmission layer 11. The signal transmission layer 11 consists of transparent material and has a refractive index n1. In order to keep transmission losses low, the signal transmission layer 11 is made of a material with low light attenuation.

An adjacent film-shaped boundary layer 12 or 13 is arranged on each side of the signal transmission layer 11 . Which is arranged on the upper surface of the signal transmission layer 11 barrier layer 12 protects the signal transmission layer 11 from dirt and damage. It is made of transparent material, the refractive index n2 of the material of the boundary layer 12 being smaller than the refractive index n1 of the signal transmission layer 11 . The boundary layer 13 arranged on the underside of the signal transmission layer 11 is likewise made of a material whose refractive index n3 is smaller than the refractive index n1 of the signal transmission layer 11 . Because the refractive indices n2 and n3 of the boundary layers 12 and 13 are smaller than the refractive index n1 of the signal transmission layer 11 is to ensure that the run in the signal transmission layer 11 is reflected at the boundary layers 12 and 13 in the direction of the signal transmission layer. 11 As a result, the light is guided in the signal transmission layer 11 .

The signal transmission layer 11 and the boundary layers 12 , 13 are arranged on a film-shaped carrier layer 14 . About the carrier layer 14 , the medium 10 according to the invention for optical signal transmission z. B. attachable to a wall 15 . The carrier layer 14 is made of elastic material and can compensate for unevenness in the wall 15 or another surface on which the medium 10 according to the invention is to be fastened. It thus prevents the unwanted coupling out of light from the film by pressing unevenness into the signal transmission layer 11 .

According to Fig. 1, between the carrier layer 14 and the lower boundary layer 13 is disposed a foil-shaped reflection layer 16. The reflection layer 16 is designed as a metallic mirror. The function of the reflection layer 16 will be discussed in detail later.

The film-shaped, multilayer medium 10 for optical signal transmission can have a width of up to 200 cm and a length of up to 100 m.

Fig. 2 shows medium 10 according to the invention for optical signal transmission with an optical coupler 17. The optical coupler 17 is used to couple optical signals into and / or out of the medium 10 for optical signal transmission.

The optical coupler 17 comprises a light guide body 18 , which is made of transparent material. The light guide body 18 preferably has a cylindrical basic shape with a tip 19 at one end of the light guide body 18 . With the aid of a fastening device 20 , the optical coupler is to be fastened on the medium 10 for optical signal transmission. In the illustrated embodiment, the optical coupler is attached 17 along a mounting plane 21 which extends approximately parallel to the medium 10 on the medium 10 degrees. The attachment can be realized by an adhesive layer or adhesive layer 23 , by means of which the optical coupler 17 is glued to the medium 10 . Alternatively, the optical coupler 17 can also be attached to the medium 10 by means of a suction cup or by screwing on. The specialist is responsible for selecting the appropriate fastening method.

The light guide body 18 protrudes from the mounting plane 21 on both sides. The light guide body 18 is enclosed on one side by a housing 22 . On the opposite side, the light guide body 18 projects with the tip 19 out of the housing 22 and the fastening plane 21 .

Referring to FIG. 1 the light guide body is associated with a transmitting and receiving device 24 18. The transmitting and receiving device 24 is formed by at least one photo element. On the one hand, it absorbs light extracted from the medium 10 and converts it into an electrical signal, on the other hand it converts the electrical signals into optical signals, which are then coupled into the medium 10 . The transmission and reception device 24 can be connected to a data interface (not shown) via an electrical connection cable 25 .

To distinguish a transmission channel from a reception channel, the medium 10 according to the invention for optical signal transmission in wavelength division multiplexing can be operated simultaneously with two or more wavelengths. For this purpose, only transmitting and receiving devices that work with different wavelengths need to be present in the optical coupler 17 . The transmission channel can also be separated from the reception channel by using two film-shaped, multilayer media 10 in parallel with one another, namely one medium for the transmission channel and the other medium for the reception channel. In this case, two optical couplers are required, one for the medium forming the receive channel and one for the medium forming the transmit channel.

At this point it should be pointed out that instead of the above transmitting and receiving device 24 , at least one connecting device for an optical cable or an optical fiber can also be assigned to the light guide body 18 . Optical signals can thus be fed directly into the coupler 17 via a fiber-optic cable.

Referring to FIG. 2, the optical coupler 17 is in the fastening thereof on the medium 10 with the tip 19 of the light guide body 18 in the sheet-shaped multi-layer medium 10 pressed. The elastic carrier layer 14 yields and the other layers of the medium 10 - ie the boundary layers 12 and 13 , the signal transmission layer 11 and the reflection layer 16 - are bent accordingly. Then, according to the light guide restriction of the signal transmission layer 11 occurs when a critical bending radius of the signal transmission layer 11 is exceeded light from the signal transmission layer 11. The likewise curved reflection layer 16 acts in the region of the indentation like a focal mirror and reflects the light emerging from the signal transmission layer 11 into the coupler 17 or into the light guide body 18 thereof. The reflection layer 15 accordingly increases the coupling efficiency of the optical signal - that is, the light - between the medium 10 and the optical coupler 17 .

At this point, it should be pointed out that the coupling device and / or coupling device for optical signals can be permanently assigned to the medium 10 according to the invention on the network-side connection side of the same. This is advantageous if the connection of the medium 10 on the network side is fixed. As a rule, no coupling devices and / or coupling devices will be permanently assigned to the device-side connection side of the medium 10 .

The medium 10 according to the invention for optical signal transmission described here, in contrast to the optical fiber, is designed in the form of a film and is therefore up to several m wide, but so thin that the attachment thereof, for. B. can be done on a wall without any special tools. The medium 10 according to the invention for optical signal transmission can, for. B. stick on a wall over the carrier layer 14 and cover with a thin translucent color layer on the outside of the boundary layer 12 . After attaching the medium 10 to the wall, it will therefore hardly be visible.

The optical signal - that is, the light - is distributed in the entire signal transmission layer 11 of the medium 10 . The optical coupler 17 can therefore be placed on the medium 10 at any desired location.

The medium 10 according to the invention for optical signal transmission accordingly combines the advantage of easy, subsequent laying with the advantage that the positions at which the optical coupler 17 is to be applied to the medium 10 for coupling and / or decoupling the optical signal are not precisely defined have to. Rather, these positions can be freely selected within the entire area of the medium 10 . There is no need for high-precision optical plug connections.

It is also advantageous that the medium 10 according to the invention remains functional even in the event of local destruction, as long as the medium is not only completely cut through. The optical couplers 17 leave no damage on the wall or on the medium 10 . The coupler 17 is removable and reusable.

The medium 10 according to the invention can also be referred to as an optical communication film. LIST OF REFERENCE NUMERALS 10 Medium
11 signal transmission layer
12 boundary layer
13 boundary layer
14 carrier layer
15 wall
16 reflective layer
17 couplers
18 light guide
19 top
20 fastening device
21 mounting level
22 housing
23 adhesive layer
24 transmitting and receiving device
25 connection cables

Claims (15)

1. Medium for optical signal transmission characterized by a film-shaped signal transmission layer ( 11 ) and at least one adjacent film-shaped boundary layer ( 12 , 13 ), the refractive index of which is smaller than the refractive index of the signal transmission layer ( 11 ). 2. Medium according to claim 1, characterized in that a film-shaped boundary layer ( 12 , 13 ) is arranged on both sides of the signal transmission layer ( 11 ). 3. Medium according to claim 1 or 2, characterized in that the signal transmission layer ( 11 ) and the or each boundary layer ( 12 , 13 ) are arranged on a film-shaped carrier layer ( 14 ). 4. Medium according to claim 4, characterized in that the carrier layer ( 14 ) is made of elastically deformable material. 5. Medium according to one or more of claims 1 to 4, characterized in that a film-shaped reflection layer ( 15 ) is arranged between the carrier layer ( 14 ) and the boundary layer ( 13 ) adjoining the carrier layer ( 14 ). 6. Medium according to claim 5, characterized in that the reflection layer ( 15 ) is designed as a metallic mirror. 7. Medium according to one or more of claims 1 to 4, characterized in that the carrier layer ( 14 ), the or each boundary layer ( 12 , 13 ), the signal transmission layer ( 11 ) and the reflection layer ( 15 ) are made of elastically deformable materials , 8. Medium for optical signal transmission characterized by a film-shaped and multilayer structure, with a film-shaped signal transmission layer ( 11 ) and at least one adjacent film-shaped boundary layer ( 12 , 13 ), the refractive index of which is smaller than the refractive index of the signal transmission layer ( 11 ). 9. Medium according to claim 8, characterized by one or more of Features according to claims 2 to 7. 10. Optical coupler, in particular for a medium for optical signal transmission according to one or more of claims 1 to 9, characterized by a light guide body ( 18 ) for coupling and / or decoupling optical signals in and / or from a medium ( 10 ) for optical Signal transmission, and by a fastening device ( 20 ) for attaching the optical coupler ( 17 ) on the medium ( 10 ) for optical signal transmission. 11. Optical coupler according to claim 10, characterized in that the light guide body ( 18 ) is made of transparent material. 12. Optical coupler according to claim 10 or 11, characterized in that the fastening device ( 20 ) has sections extending approximately parallel to the medium ( 10 ), the sections fastening the optical coupler ( 17 ) to the medium ( 10 ). 13. Optical coupler according to one or more of claims 10 to 12, characterized in that the sections extend laterally next to the light guide body ( 18 ), the light guide body ( 18 ) protruding from a mounting plane ( 21 ) on both sides. 14. Optical coupler according to one or more of claims 10 to 13, characterized in that the light guide body ( 18 ) is assigned at least one transmitting and / or receiving device ( 24 ). 15. Optical coupler according to one or more of claims 10 to 13, characterized in that the light guide body ( 18 ) is assigned at least one connection device for an optical cable or an optical fiber.