DE19625817A1 - Optical transmitter for a hybrid fiber-radio system - Google Patents

Abstract

The invention relates to an optical transmission device for a hybrid fibre-radio system in which optical signals are transmitted to transposers which generate therefrom radio signals in the GHz band. The optical transmission device has a first laser (1) which can emit light of a first optical frequency (n1), a second laser (2) which can emit light of a second optical frequency (n2), a coupler (6), to which the light emitted by the lasers (1, 2) can be supplied, and a photodetector (5), to which the light emerging at a connection (8) of the coupler (6) can be supplied. Between the photodetector (5) and the connection (8) of the coupler (6) there is provided an optical filter (4) having specified free spectral ranges. A control mechanism (3) controls the two lasers (1, 2) in dependence on a photocurrent generated by the photodetector (5).

Description

The invention relates to an optical transmission device according to the Preamble of claim 1. The invention relates also an optical transmission system according to the preamble of claim 3.

An optical transmitter with the in the preamble of Claim 1 specified features is known, for. B. from J. J. O'Reilly et al, "RACE R2005: microwave optical duplex antenna link ", IEE PROCEEDINGS-J, Vol. 140, No. 6, December 1993, pages 385 to 391. Features are also from this publication an optical transmission system known, the preamble of claim 2 form.

The optical transmission device shown there ( FIG. 2) is part of an optical transmission system shown in FIG. 1, in which an antenna is provided on the receiving side in addition to an optical receiver which has an optoelectric converter. Between this antenna and that of a remote radio station (transposer) radio signals are transmitted which, for. B. have a carrier frequency of 30 GHz; the wavelength of these radio signals is therefore in the range of a few millimeters.

The optical transmission device shown generates light one Nominal 1550 nm wavelength; the light has two optical ones Spectral lines that have a frequency spacing equal to that desired carrier frequency of 30 GHz. The light is from generated two frequency-locked lasers. Every laser is one Part of the light generated by it is fed to a coupler other part of the light generated by the laser becomes an output (O / P1, O / P2) fed. Light emerging from the coupler fed to a photodetector that generates a photocurrent (30 GHz Signal). A mixer mixes the photocurrent with one of a signal generated by a local oscillator; the generated 2 GHz Mixed signal is fed to a frequency control device (AFC) which controls one of the two lasers. The aim of this frequency control is to keep the frequency spacing constant. Disadvantageous this optical transmitter is that the mixer and the Frequency control device for very high frequencies in the GHz range must be designed.

The invention has for its object an optical Specify transmission device at which the frequency control on another kind is done. An optical solution to the task Sending device is the subject of claim 1. A optical transmission system with such an optical Sending device is the subject of claim 3. A Design of the optical transmitter is in Claim 2 specified.  

The invention is illustrated below with reference to drawings explained in more detail. Show it:

Fig. 1 shows an embodiment of an optical transmitter, and

Fig. 2 shows another embodiment of an optical transmitter.

The optical transmission device shown in FIG. 1 has two lasers 1 , 2 , a coupler 6 , an optical filter 4 , a photodetector 5 , a control device 3 and a modulator 9 . The laser 1 emits light of an optical frequency ν₁, which is fed to a terminal 10 of the coupler 6 . The laser 2 emits light of an optical frequency ν₂, which is fed to a terminal 11 of the coupler 6 . The two optical frequencies ν₁, ν₂ have a frequency spacing, the z. B. is 30 GHz. The nominal wavelength corresponding to the two optical frequencies ν₁, ν₂ is z. B. 1550 nm. Between the laser 2 and the connector 11 of the coupler 6 , a modulator 12 is inserted into the light path, whereby a modulation of the light by a data signal Data is possible.

Through the coupler 6 , the light from the two lasers 1 , 2 is coupled into an optical waveguide 7 , which is connected to a connector 9 of the coupler 6 . At a connection 8 of the coupler 6 , part of the light emitted by the two lasers 1 , 2 emerges and is fed to the optical filter 4 . Light transmitted by the optical filter 4 strikes the photodetector 5 , which converts the light into a photocurrent. The photocurrent is fed to the control device 3 , which controls the two lasers 1 , 2 as a function of the photocurrent.

The optical filter 4 has a periodic transmission characteristic. An optical filter 4 with such a periodic transmission characteristic is e.g. B a Fabry-Perot filter or a Mach-Zehnder interferometer. The parameters of this periodic transmission characteristic are the distance between the defined passband (free spectral range, FSR), which occur at regular frequency intervals, and the half-width of a passband. According to the invention, the optical filter 4 with its fixed FSR serves as the frequency standard. The parameters mentioned depend e.g. B. with the Fabry-Perot filter from the mirror distance and can be chosen almost freely. For the described embodiment of the optical transmitter, the FSR is z. B. 30 to 60 GHz.

Depending on what value the two optical frequencies ν₁, ν₂ currently have, more or less light is passed through the optical filter 4 . This transmitted light is received by the photodetector 5 and converted into a photocurrent proportional to the light.

The control device 3 evaluates the photocurrent and derives control signals therefrom by which the lasers 1 , 2 are influenced directly or indirectly in such a way that the optical frequencies ν₁, ν₂ change. Such influencing can e.g. B. done in that the laser temperatures are changed or that the laser operating currents are changed. The optical frequency of laser light can be changed both by temperature changes and by current changes.

As a way of stabilizing the optical frequencies ν₁, ν₂ the laser 1 , 2 , the known wobble process can be used. Each laser 1 , 2 is supplied with a sinusoidal electrical signal; the electrical signals have different electrical frequencies (first and second wobble frequency), which are in the range of a few kHz. The control device 3 can thus determine the amplitude of the photocurrent at the first wobble frequency and the amplitude of the photocurrent at the second wobble frequency. This makes it possible to determine the phase position of the two photocurrents, with the knowledge of which the optical frequencies ν₁, ν₂ of the lasers 1 , 2 can be stabilized exactly to the frequency spacing specified by the FSR of the optical filter 4 .

The control device 3 influences the lasers 1 , 2 so that the amplitude of the photocurrent is at a maximum at each wobble frequency. If this is the case, the optical frequencies ν₁, ν₂ are each tuned to a desired pass band of the optical filter 4 and the required frequency interval specified by the FSR of the optical filter 4 is set. This frequency spacing is provided as an electrical carrier frequency in a remote radio station.

The phase-sensitive detection described takes place in the range of a few kHz, ie the photodetector 5 need not be suitable for frequencies in the GHz range, so that an inexpensive photodetector can be used.

A further exemplary embodiment of an optical transmission device is shown in FIG . Components already shown in FIG. 1 have the same reference numerals in FIG. 2, these components also have the same function. The optical transmission device shown in FIG. 2 differs from that shown in FIG. 1 essentially in that a portion of the light emitted by a laser 1 , 2 is coupled out by an asymmetrical coupler 13 , 14 and fed to the optical filter 4 . This feeding takes place with the aid of a coupler 15 , which brings the two out-coupled light components together and feeds them to the optical filter 4 . The coupler 13 is arranged between the laser 1 and the connection 10 of the coupler 6 , and the coupler 14 is arranged between the laser 2 and the connection 11 of the coupler 6 . The respective other part of the light emitted by a laser 1 , 2 is fed to the connection 10 of the coupler 6 or the modulator 12 , as shown in FIG. 1. The evaluation of the photocurrent generated by the photodetector 5 has already been explained in connection with FIG. 1.

The second embodiment of an optical transmitter is particularly advantageous in those applications in which the bandwidth of the optical signal with the optical frequency ν₂ is large compared to the width of the passband of the optical filter 4 . This is e.g. B. the case with subcarrier modulation methods with data signals that have a high bandwidth.

Claims (3)

1. Optical transmission device, with a first laser ( 1 ) that can emit light of a first optical frequency (ν₁), a second laser ( 2 ) that can emit light of a second optical frequency (ν₂), a photodetector ( 5 ), the light generated by the two lasers ( 1 , 2 ) can be supplied, and a control device ( 3 ) connected to the photodetector ( 5 ), characterized in that there is an optical filter ( 4 ) with defined pass bands which is in the direction of propagation of the Lasers ( 1 , 2 ) emitted light is arranged in front of the photodetector ( 5 ) in such a way that light from the first and second lasers ( 1 , 2 ) can be fed to the optical filter ( 4 ) and that the control device ( 3 ) controls the two lasers ( 1 , 2 ) as a function of a photocurrent generated by the photodetector ( 5 ). 2. Optical transmission device according to claim 1, characterized in that a first coupler ( 13 ) is present which couples out part of the light emitted by the first laser ( 1 ) and feeds the optical filter ( 4 ), and in that a second coupler ( 14 ) is present, which couples out part of the light emitted by the second laser ( 2 ) and feeds it to the optical filter ( 4 ). 3. Optical transmission system, with an optical transmitter, an optical waveguide and an optical receiver, in which the optical transmitter can emit a first laser ( 1 ), the light of a first optical frequency (ν₁), a second laser ( 2 ), the light can emit a second optical frequency (ν₂), a photodetector ( 5 ) to which light generated by the lasers ( 1 , 2 ) can be fed, and a control device ( 3 ) connected to the photodetector ( 5 ), characterized in that in the optical Transmitting device there is an optical filter ( 4 ) with defined passband, which is arranged in the direction of propagation of the light emitted by the lasers ( 1 , 2 ) in front of the photodetector ( 5 ) that light from the first and second lasers ( 1 , 2 ) Optical filter ( 4 ) can be fed, and that the control device ( 3 ) the two lasers ( 1 , 2 ) in dependence on one of the photodetector ( 5 ) e generated photocurrent controls.