DE3821438A1 - Polarisation diversity receiver - Google Patents

Abstract

Optical heterodyne receivers generally require very expensive polarisation control for the received light or the light of the local laser. In polarisation diversity receivers, no optical polarisation control is required if the heterodyne wave is split into two polarisation directions which are orthogonal in relation to one another, the two generated signals are demodulated separately and the baseband signals are then added. In a known solution, following an input-side 2.2 coupler, a division is carried out by means of two polarisation beam splitters to form four light beams which are in each case fed separately to a photodiode. To reduce cost, a polarisation beam splitter whose two output terminals are in each case connected to input terminals of 2.2 couplers is inserted according to the invention into the connection between the input terminal for the received light and an input terminal of a 2.2 coupler. The output terminals of the second 2.2 coupler and one output terminal of the first 2.2 coupler are connected to assigned photodiodes, and diversity currents which are to be demodulated separately are obtained through difference formation of the generated photocurrents. <IMAGE>

Description

The invention relates to an optical heterodyne receiver according to the preamble of claim 1.

Optical superimposition receivers of the type mentioned are from Electronics Letters 22 (1986) April, No. 8, pages 413-415 and EP-A2 01 94 786.

The known optical superimposition receivers point out an optical 2 × 2 coupler on the side, which is also available as a 50/50 Rich tion coupler is referred to and whose one input with the Receiving light source and its other input with a local one Lasers are connected. To the two outputs of the 2 × 2 coupler optical photodiodes are directly coupled. The Photodi oden can be electrically connected in push-pull, so that on the connection of the two photodiodes ent a differential current is acceptable, which is fed to a photocurrent amplifier, it each of the photodiodes can also be supplied with a photocurrent amplifier be arranged so that the difference formation only with the help of ver strong photo currents. The further electrical signal ver work depends on the type of modulation of the transmitted light with from the electrical transmission tech nik known for these signals detectors.

In the training as a polarization diversity receiver, Tzeng, LD, Emkey, WL, Jack, C. A., Burrus, CA in Electronics Letters 23 (1987), 22, pp. 1195-1196 are coupled to the two outputs of the 2 × 2 coupler polarization beam splitter, the outputs of which are each connected to a diode of a diode pair switched in clocked mode, where the light of a polarization type is supplied to each pair. This design eliminates the very complex polarization control for the received light or the light generated by the local laser, but the use of two polarization beam splitters, in particular, still requires a considerable amount of effort in the optical part of the receiver.

The object of the present invention is therefore the effort with optical overlay receivers of the beginning to further reduce the type mentioned, but the suitability for the usual modulation methods, for use in hetero dyn and homodyne receivers should be maintained and by further application of the push-pull principle the laser noise elimi remains nated.

According to the invention the object is achieved in that the one Optical overlay receiver mentioned above by the im Characteristic of claim 1 specified measures further is formed. It is advantageous in the solution according to the invention the use of only one polarization beam splitter and only three photodiodes and correspondingly only three assigned Photocurrent amplifiers taking full advantage of the light output of the local laser.

With regard to the frequently used ASK modulation method and DPSK is in claim 2 in conjunction with the patents sayings 3 and 4 an advantageous development of the electri specified receiver part.

With a view to easy implementation of the 2 × 2- used Coupler in claim 5 is a possibility for the use balanced 2 × 2 couplers, an alternative to this represents the solution described in claim 6, in which unbalanced couplers can also be used. At the in Claim 7 advantageous development described an asymmetrical 2 × 2 coupler is used as the first coupler, where the energy at the output terminals is in proportion  1: 2 is present, while the second 2 × 2 coupler is symmetrical. This results in the same light on all three photodiodes energies. To compensate for production-related deviation The ideal conditions are set out in claims 8 and 9 expedient developments of the opti according to the invention described overlay receiver.

The invention is intended to be described in the following with the aid of illustrated embodiment are explained in more detail.

In the drawing, the figure shows a polarization diversity receiver which can be used either for the heterodyne reception of DPSK and ASK-modulated light. The receiver has an input S for the reception light, to which the primary connection of a polarization beam splitter POLS is connected. The secondary connections of this polarization beam splitter are each connected to the first connections of a first and a second 2 × 2 coupler K 1 , K 2 . The second input connection of the first 2 × 2 coupler K 1 is optically connected to the local laser L 0 , while the second input connection of the second 2 × 2 coupler K 2 is connected to the second output connection of the first 2 × 2 coupler K 1 . The first output connection of this coupler is optically connected to a first photodiode D 1 , the two output connections of the second coupler K 2 are also optically connected to a second or third photodiode D 2 , D 3 . The first 2 × 2 coupler K 1 is designed as an asymmetrical coupler in such a way that at its second output connection there is twice the light output compared to that at the first output connection. The second 2 × 2 coupler K 2 is designed as a symmetrical coupler, so that the double light power coming from the first coupler K 1 at its second input connection is uniformly applied to the two output connections of the second 2 × 2 coupler K 2 and thus evenly the second and the third photodiode D 2 , D 3 can be divided. All three photodiodes thus have approximately the same light outputs.

A first, second or third photocurrent amplifier V 1 , V 2 , V 3 is connected directly to each of the photodiodes D 1 , D 2 , D 3 . The photocurrent amplifiers have adjustable gain factors so that deviations of the couplers and the photodiodes from the desired setpoints can be compensated for. The photocurrent amplifiers also each contain an adjustable delay element, with which in particular runtime differences of the optical signals supplied to the photodiodes, which are caused by manufacturing asymmetries, can be compensated. Currents are present at the outputs of the photo current amplifiers which contain the transmission signal in an intermediate frequency position and from which the diversity currents i _x and i _y corresponding to their polarizations are generated by differentiation.

To generate the diversity currents, the output of the first photocurrent amplifier V 1 is connected to the negative input of a first analog subtractor SUB 1 , the two positive inputs of this subtractor are connected to the output connections of the second and third photocurrent amplifiers V 2 , V 3 . At the output of the first subtractor SUB 1 , the first diversity current i _{x is present} . With the output of the second Photostromver amplifier V 2 , the positive input of a second Analogsub trahierers SUB 2 is connected, the negative input of which is connected to the output of the third photocurrent amplifier V 3 . At the output of this second subtractor SUB 2 is a second Di versitätsstrom i _y . The first diversity current i _x is fed to the first input of a first analog multiplier M 1 and the second input thereof via a first delay element VG 1 . In a corresponding manner, the second diversity current i _{y is} fed directly to the first input of a second analog multiplier M 2 and the second input thereof via a second delay element VGL 2 . The outputs of the two analog multipliers are each connected separately to assigned inputs of an analog adder AD , the output of which is connected via a low-pass filter TPF to the output DA for the transmitted data signal in the baseband position. The analog adder can also perform a weighted addition to compensate for different attenuations in the analog multipliers. This also then follows, when the light output of the local laser LD due to a different angle of 45 ° between the polarizations at the output of the polarization beam splitter POLS and the polarization of the light of the local laser LD is not divided evenly on both diversity streams.

When the data signals are transmitted by means of DPSK modulation, the delay time of the two delay elements VGL 1 , VGL 2 corresponds approximately to a bit duration of the digital signals transmitted. In the transmission of ASK-modulated signals, the two delay elements can theoretically be replaced by a short circuit, so that in this case the multipliers act as squarers. In practice, however, a runtime compensation or a compensation of asymmetries of the two multipliers may be necessary, so that the delay elements VGL 1 , VGL 2 with delays which are substantially less than a period of the transmitted digital signals are to be provided. A defined polarization state of these signals is a prerequisite for reproducible linking of optical signals. In the exemplary embodiment, the connection between the outputs of the polarization steel splitter POLS and the local laser LD takes place on the one hand and the inputs of the 2 × 2 couplers K 1 , K 2 by means of polarization-maintaining elements. However, the inputs of the 2 × 2 couplers K 1 , K 2 can also be directly connected upstream of the polarization control elements.

Claims (9)

1. Optical superimposed receiver according to the polarization diversity push-pull receiver principle with an optical 2 × 2 coupler, the inputs of which are connected to a receiving light source and to a local oscillator and the outputs of which are connected to photodiodes, each of which is followed by a photocurrent amplifier is, and with an electronic detector for converting the amplified photocurrents into the transmission signal in the baseband position,
characterized,
that a polarization beam splitter (POLS) is inserted into the connection between the receiving light source ( S ) and the first input of the first 2 × 2 coupler ( K 1 ),
that the first output of this polarization beam splitter (POLS) is connected to the first input of the first 2 × 2 coupler ( K 1 ) and the second output of the polarization beam splitter (POLS) to the first input of a second 2 × 2 coupler ( K 2 ) ,
that the second input of the first 2 × 2 coupler ( K 1 ) is connected to the local laser (LD) ,
that the first output of the first 2 x 2 coupler (K 1) is connected to a most he photodiode (D 1) directly optically,
that the second output of the first 2 × 2 coupler ( K 1 ) is connected to the second input of the second 2 × 2 coupler ( K 2 ),
that the first output of the second 2 x 2 coupler (K 2) is directly connected optically with a second photodiode (D 2) and
that the second output of the second 2 × 2 coupler ( K 2 ) is directly optically connected to a third photodiode ( D 3 ) and that the photodiodes each have a first to third photocurrent amplifier ( V 1 , V 2 , V 3 ) connected downstream . 2. Optical overlay receiver according to claim 1, characterized in that
that the output of the first photocurrent amplifier (V 1 ) is connected to the input (-) for the signal to be subtracted from a first subtractor (SUB 1 ),
that the output of the second photocurrent amplifier ( V 2 ) is connected to the positive inputs (+) of the first and a second subtractor (SUB 1 , SUB 2 ),
that the output of the third photocurrent amplifier ( V 3 ) is connected to a further positive input (+) of the first subtractor (SUB 1 ) and to the input for the signal (-) to be subtracted from the second subtractor (SUB 2 ),
that the output of the first subtractor (SUB 1 ) is connected directly to the first input of a first analog multiplier ( M 1 ) and via a first delay element (VGL 1 ) to the second input of this multiplier ( M 1 ),
that the output of the second subtractor (SUB 2 ) is connected directly to the first input of a second analog multiplier ( M 2 ) and also via a second delay element (VGL 2 ) to the second input of this analog multiplier ( M 2 ),
that the outputs of the two analog multipliers ( M 1 , M 2 ) are connected to associated inputs of an adder (AD) , whose output is connected to the data output (DA) via a low-pass filter (TPF) . 3. Optical overlay receiver according to claim 2, characterized in that when receiving DPSK-modulated light, the first and the second delay element (VGL 1 , VGL 2 ) have a delay of 1 bit each because of the received signal. 4. Optical overlay receiver according to claim 2, characterized, that when receiving ASK-modulated light the first and that second delay element compared to a bit duration of the Emp catch signal comparatively very little delay to the off have asymmetrical terms.   5. Optical heterodyne receiver according to claims 1 or 2, characterized in that the first and the second 2 × 2 coupler ( K 1 , K 2 ) are constructed symmetrically and thus pending signals at their output connections. 6. Optical superimposed receiver according to claims 1 or 2, characterized in that at least one of the 2 × 2 couplers ( K 1 , K 2 ) is asymmetrical and at least one of the photocurrent amplifiers ( V 1 , V 2 , V 3 ) has an adjustable gain . 7. Optical superimposed receiver according to claim 6, characterized in that by the first 2 × 2 coupler ( K 1 ) the light energy in the ratio 1: 2 is divided on its output connections and that to the higher light energy output connection of the second coupler ( K 2 ) is connected with a symmetrical structure. 8. Optical superimposed receiver according to one or more of the preceding claims, characterized in that in at least one of the signal paths from the photodiodes ( D 1 , D 2 , D 3 ) to the assigned inputs of the first or two-th subtractor (SUB 1 , SUB 2 ) an adjustable delay element is included. 9. Optical superposition receiver according to claim 8, characterized in that at least the first and the third photocurrent amplifier ( V 1 , V 3 ) contain the delay element.