DE102005050747A1 - Multiplex transmitter for polymer fiber transfer and process for its production - Google Patents

Abstract

The invention relates to a multiplex transmitter for polymer fiber transmission and a method for its production. DOLLAR A According to the invention, the multiplex transmitter has a base body with recesses, in which waveguides of the input channels and waveguides of the output channel or channels are arranged, both the base body with recesses and the waveguide being injection molded parts. DOLLAR A In the process for producing a multiplex transmitter for polymer fiber transmission, the base body with the cutouts are produced as an injection molded part in a first process step, while in a second process step the waveguides are also introduced into cutouts in the base body by injection molding.

Description

The The invention relates to a multiplex transmitter for polymer fiber transmission with one or more output channels for connecting one or more polymer optical fibers, one or more input channels for connection of photo-transmitters and a method for its production

modern optical communication systems use a high bit rate transmission channels high bandwidth of optical fibers. To the possibility of transmission of information about to be able to use the fiber, are sender-side transmitter modules and receiver side receiver modules necessary.

applications The optical technologies of communication technology have a very broad Of applications. From big ones Share the existing telecommunications network via multimedia transmission in the automobile right through to data transmission in the office- and in the home area. Optical data transmission offers high transmission capacity, is little sensitive to electromagnetic interference while providing electrical isolation between transmitter and Receiver. Also, optical fibers, especially plastic fibers, are cheaper and much lighter than copper cables with the same capacity and cover also a larger distance range from.

The Mid-90s emerged wavelength division multiplexing technique (Wavelength Division Multiplex, WDM) allowed the transmission capacity of the then mainly significantly increase the glass fibers used. With this procedure the individual will be transferred Data no longer in a temporal arrangement in a row transferred to the fiber medium, but at the same time guided on the optical fiber. Currently work is being done on the optical far-field (wavelength λ = 1.3 ... 1.7 μm) successful WDM technology in the field of short-distance networks with transmission lengths below 2000 m.

Here one works with light in the visible wavelength range and uses as transmission medium Polymer fibers (POF), since in this application level, the components as possible economical for the End users must be made.

Special Meaning receives the field of mobile multimedia applications. In addition to the higher data rate and the resulting improved integration of multimedia applications in buses or automobiles are also significant weight reductions be expected of the wiring harness.

Around considering a complex optical data transmission system To come to the aforementioned aspects, several individual tasks solved become. Which also includes including the merger wavelength-coded Individual signals to a multiplexed overall signal.

For example, there is a solution of the Fraunhofer IIS in Erlangen: In the patent application DE000010240057A1 An arrangement is proposed which, with the aid of wavelength-dependent mirrors, can split both light into its color components and distribute them spatially separated to individual polymer fibers or else combine them in the sense of a multiplexer. However, the mechanical structure of this solution is very demanding and therefore expensive, so that such a structure for the low-cost range of the consumer market (home - and automobile) is not suitable.

A simplification of the production of modules of optical data technology in the sense of cheaper mass production is achieved by the application of the injection molding technique. Here exist solutions of DE 41 09 651 A1 , of the DE 100 43 324 A1 of the DE 600 05 018 as well as the already mentioned DE 102 40 057 A1 Instructions for using this technology. However, injection molding is proposed only for the production of individual parts of the optical modules, whereby the effort-minimizing effect of the application of injection molding is limited.

The Main disadvantages of the known prior art, for a Summary in Daum et al: "POF Optical polymer fibers for the data communication ", Springer-Verlag, 2001, exist in the size and in the elaborate one Production method not for a consistent mass production really cheaper Module is suitable.

The The object of the invention is therefore to produce a cost Multiplex transmitter for Polymer fiber transmission to develop without sacrificing at transmission and signal processing quality allows the simple and cost-minimized design of complex optical transmission systems. Furthermore aims to make a manufacturing process easy and inexpensive Production of optical modules according to the claims are found.

These objects are achieved by the design of a polymer fiber transmission multiplex transmitter according to the features of the main device claim, and by a method of manufacturing Position of a multiplex transmitter for polymer fiber transmission according to the features of the method claim, wherein in dependent claims further, particularly advantageous embodiments of the inventions claimed.

The Essence of the arrangement invention lies in the surprisingly simple and advantageous combination the known radiation combining by a system of branched or merging Waveguides, the signal feed by photoelectronic elements at Input of the multiplex transmitter according to the invention for polymer fiber transfer, the inventively new provided passive or self-adjusting of the multiplex transmitter for polymer fiber transmission addition leading Polymer fibers and the invention consistently applied arrangement all sub-elements in an injection-molded body as a base recording.

The Nature of the method according to the invention for the production of the multiplex transmitter for polymer fiber transfer shows up in the extremely advantageous two-fold application of the injection molding technique in the process steps for the production of the basic body of the multiplex transmitter for Polymer fiber transmission as well as the storage of essential elements of the multiplex transmitter for polymer fiber transfer into the main body also by injection molding technology.

It is even possible the inventive method with regard to the sequence of its procedural steps to let that waveguide first be made by injection molding, then in a following Process step also enclosed by injection molding of a body to become.

The Inventions are explained in more detail below using an exemplary embodiment, in FIG both the arrangement features of the invention Multiplex transmitter for Polymer fiber transmission as also the process steps for its production can be clarified.

there shows the associated Drawing a schematic diagram of the multiplex transmitter according to the invention for polymer laser transmission.

As shown in the drawing, an inventive multiplex transmitter for polymer fiber transfer has the constituents basic body 1 , Recesses 2 , self-adjusting fiber guide 3 with polymer fiber 7 as output channel, waveguide 4 , Lenses 5 and photo-transmitting diodes 6 as input channels.

The main body 1 is made as an injection molded part of polymethyl methacrylate (PMMA). PMMA is a scratch-resistant and transparent material with very high rigidity, whose light transmission is approx. 92% at 1 mm thickness and whose refractive index according to ISO 489 is 1.492.

The named basic body 1 has recesses 2 which are designed so that in them preferably consisting of polyvinyl chloride PVC waveguide 4 as well as the lenses 5 Can find recording. PVC is a transparent material with a refractive index> 1.5 in the wavelength range of 300 ... 800 nm. The lenses 5 form an input optics for the generation of parallel beam bundles of the photo-transmitting diodes 6 exiting input beams.

After passing through the lenses 5 become the wavelength-coded single optical signals of the transmitting diodes 6 in respective gradually merging waveguides 4 summarized in a single multiplexed signal, that over the polymer fiber 7 is led out of the multiplexer transmitter. The polymer fiber 7 is within the output range of the multiplexer transmitter by a self-adjusting fiber guide 3 aligned so that the optical output signal is coupled out optimally.

According to the method invention, the production of the multiplex transmitter for polymer fiber transfer takes place in a special injection molding technique. In the first process step, the main body 1 with the recesses 2 for receiving the self-adjusting fiber guide 3 , for the waveguides 4 , for the lenses 5 and the photo-transmitting diodes 6 injected. In the second process step, the waveguides become with another micro-spraying process 4 and the lenses 5 inserted in optically high-quality with smooth surfaces.

As already shown earlier, is also very possible, the just reverse the order of the procedural steps and first through Injection molded waveguide then by injection molding with a body wrap. This flexibility the procedures the method according to the invention represents an important and novel advantage in the implementation of the invention in a mass production process.

The implementation described in the embodiment of the multiplex transmitter for polymer fiber transmission is only one of several possible - the selected arrangement of the embodiment is to be understood as an advantageous embodiment of the invention. Other implementations of the multiplex transmitter for polymer fiber transmission are conceivable and possible, without that of the claim Area of the invention is left.

For example, more than one polymer fiber 7 be led out of the multiplex transmitter for polymer fiber transmission. Similarly, a three-dimensional Anord tion of photo-transmitting diodes 6 (indicated in the drawing) possible, whose signals are then combined via a three-dimensional array of waveguides (not further explained in the figure) to form a multiplexed signal.

As special advantages of the invention can apply:
The described fabrication of the polymer fiber transmission multiplex transmitter allows cost-effective mass production of this important component of complex optical communication systems, laying the groundwork for their mass and cost-minimized adoption in a wide variety of applications such as enterprise, residential and automotive data communications, as well as capital goods machinery and equipment ,

With leave the present integrated-optical multiplexer transmitter optical fibers with high numerical aperture at low Damping and high crosstalk attenuation as a transmission medium deploy. The massive in the aforementioned application areas usable polymer fibers in turn contribute to cost reduction and Weight saving in the transmission systems at.

The Polymer fiber transmitter coupling of the inventive polymer fiber transmission multiplex transmitter can be adjusted without adjustment thanks to the integrated optical production method fully automatic and replaces previous elaborate adjustment procedures for multiplexer output fibers. The adjustment accuracy by the injection-molded self-adjusting fiber guide allows one Fiber alignment in the range better 10 microns and better 1 °.

1

body

2

recess

3

fiber guide

4

waveguides

5

lens

6

Photo transmitting diode

7

polymer fiber

Claims (9)

Multiplex transmitter for polymer fiber transmission 1.1. with one or more output channels for the connection of polymer optical fibers ( 7 1.2. one or more input channels for the connection of photo senders ( 6 1.3. wherein the multiplex transmitter comprises a base body ( 1 1.4. with recesses ( 2 ), 1.5. in which waveguides ( 4 ) of the input channels and waveguides ( 4 ) of the output channels or are arranged 1.6. and where both the main body ( 1 ) with recesses ( 2 ) as well as the waveguides ( 4 ) Injection molded parts are. Multiplex transmitter for polymer fiber transmission according to claim 1, 2.1. in which the one or more output channels self-adjusting fiber guides ( 3 ) exhibit. Multiplex transmitter for polymer fiber transmission according to claim 1, 3.1. in which the one or more waveguides of the input channels one or more lenses ( 5 ) are arranged upstream. Multiplex transmitter for polymer fiber transmission according to claim 1, 4.1. where the lenses ( 5 ) Injection molded parts are. Multiplex transmitter for polymer fiber transmission according to claim 3, 5.1. in which the one or more waveguides ( 4 ) of the input channels upstream lenses ( 5 ) Injection molded parts are. Method of manufacturing a multiplex transmitter for polymer laser transmission, 6.1. the one or more input and output channels with optical waveguides ( 4 ), 6.2. which in a basic body ( 1 ) within recesses ( 2 ), 6.3. wherein in one method step the main body ( 1 ) with the recesses ( 2 ) produced as an injection molded part and 6.4. in another process step, the waveguides ( 4 ) by injection molding in recesses ( 2 ) of the basic body ( 1 ) are introduced. Method for producing a multiplex transmitter for polymer laser transmission according to claim 6, 7.1. in which the method step for producing the main body ( 1 ) the first process step and the introduction of waveguides ( 4 ) in recesses ( 2 ) of the basic body ( 1 ) form the second process step. Method for producing a multiplex transmitter for polymer laser transmission according to claim 6, 8.1. in which the production of waveguides ( 4 ) by injection molding the first process step and the production of the main body ( 1 ) around the already injection-molded waveguides ( 4 ) also by Injection molding form the second process step. A method of manufacturing a polymer fiber transmission multiplex transmitter according to claim 6, 9.1. in which by injection molding one or more lenses ( 5 ) in recesses ( 2 ) of the basic body ( 1 ) are introduced.