DE10209825A1 - Optical transmitter device for data transmission has source encoders to supply source-encoded data streams and channel encoders to encode the source- encoded data streams into channels - Google Patents

Abstract

Source encoders (101-103) each make available source-encoded data streams (SEDS) (104-106) at each of their outputs (113-115). Each SEDS has numerous items of useful data split into data packets, e.g. as video data, text data or audio data, as well as additional pieces of control information each designed according to an implanted communications protocol. The source-encoded data streams are each channel- encoded in channel encoders (107-109) to form channel-encoded data streams (110- 112). An Independent claim is also included for an optical receiver device for data transmission.

Description

The invention relates to an optical transmitter and an optical receiving device.

With today's optical data transmission system with an optical transmitter and with an optical The receiving device is a data rate of up to 40 GBit / s accessible per wavelength channel. This high data rate will expected to be increased further and further in the future.

The structure of a conventional optical transmission device is shown in FIG. 2.

The optical transmission device 200 has a multiplicity of source encoders 201 , 202 , 203 , which each source-code and provide data for a source-encoded data stream 204 , 205 , 206 , with the data being grouped into data packets for each source-encoded data stream 204 , 205 , 206 .

As part of the communication protocol used the data packets with suitable control information provided according to the used Communication protocol, for example according to the Ethernet Protocol, ATM (Asynchronous Transfer Mode) protocol or the FDDI (Fiber-Distributed Data Interface) protocol.

Each source encoder 201 , 202 , 203 is coupled to a channel encoder 207 , 208 , 209 , to which the source-encoded data stream 204 , 205 , 206 is fed for channel coding.

The respective source-encoded data stream 204 , 205 , 206 is channel-encoded in the channel encoder 207 , 208 , 209 , in particular provided with error protection information (for example error protection information for forward error correction or only for error detection). The channel-coded data stream 210 , 211 , 212 formed by the respective channel encoder 207 , 208 , 209 is fed to a multiplexer 213 , an output of a channel encoder 207 , 208 , 209 being coupled to an input 214 , 215 , 216 of the multiplexer 213 .

The channel-coded data streams 210 , 211 , 212 are combined to form a channel-coded total data stream 217 in the time domain, that is to say multiplexed, by means of the multiplexer 213 .

The channel-coded total data stream 217 is finally modulated, for example with the aid of a suitable external optical modulator 218, onto a light wave of constant frequency, which is provided by a light source 219 via an optical fiber 220 , or it is used to directly modulate the optical fiber 220 .

In this context, today is usually the Modulation of the amplitudes of the respective signals, for example a BPSK process (Binary Phase Shift Keying- Procedure) or an on-off keying procedure.

While the protocol generation and the channel coding can be parallelized very easily, the multiplexer 213 and the optical modulator 218 operate with the bit clock of the optical data transmission system 200 . Therefore, the multiplexer 213 and the optical modulator 218 represent a significant bottleneck in increasing the data rate of the optical data transmission system 200 .

The problems occur in a corresponding manner on the receiver side on.

It is also known from [1], [2], in the area of Modulation encoding for hard drives, that is in the field the storage of by means of the modulation encoding encoded data on hard drives, so-called (d, k) - To use modulation codes with d> 0.

An overview of the maximum achievable code rates different (d, k) modulation codes is in [3] and in To find.

Furthermore, the so-called ( 1 , 7 ) modulation code is described in [5].

The problem underlying the invention is an optical one Transmitting device and an optical receiving device to indicate with which the achievable data rate of the optical data transmission system is increased.

The problem is solved by an optical transmitter as well by an optical receiving device with the features solved according to the independent claims.

An optical transmission device according to the invention has one (d, k) modulation encoder on which a channel encoded Data stream can be fed or is fed.

A (d, k) modulation encoder is an encoder that has a any binary data sequence into a binary data sequence converts that between two first binary symbols for example between two "1" symbols at least d and a maximum of k second binary symbols (for example "0" symbols) having. The number of bits generated increases by so-called rate R of the modulation code.

The (d, k) modulation encoder, also as an RLL encoder (run Length-Limited-Encoder), converts it supplied channel-coded data stream corresponding to the used (d, k) modulation code into a modulation-encoded data stream around, which at the output of the (d, k) modulation encoder is provided.

With the output of the (d, k) modulation encoder is a Coupled input of an optical modulator, which the modulation-encoded data stream can be supplied or supplied becomes. The modulation-encoded data stream is according to the type of modulation used, preferably one Amplitude modulation, for example according to the BPSK method or the on-off keying method, on the physical Channel, for example, more constant on a light wave Frequency provided by a light source modulated. Alternatively, the optical fiber is directly from modulated the optical modulator.

An optical receiving device provided on the receiver side has an optical demodulator corresponding to that of the optical channel, for example an optical channel Glass fiber network, an optical data stream can be fed or is supplied, and demodulated by the optical demodulator becomes.

The optically demodulated data stream is at the output of the optical demodulator provided. With the exit of the optical demodulator is a (d, k) modulation decoder coupled, which via the input of the optical demodulated data stream can be supplied or is supplied.

The (d, k) used in the receiver device - Modulation code is the same one used in the optical Transmitting device is used.

Modulation according to the (d, k) - Modulation code enables and the modulation decoded Data stream is at an output of the (d, k) - Modulation decoders provided.

The invention can clearly be seen in the fact that a itself in the area of storing data on a Hard disk known coding method, namely a (d, k) - Modulation code, as part of an optical Data transmission system is used to there on very inexpensive and very simple way even without one Change the optical hardware components, the data rate to increase the optical data transmission system.

It should be noted that the (d, k) modulation codes without more with the commonly used Amplitude modulation methods can be combined what maintaining a significant increase in data rate of the currently available optical components. The switching frequency of the optical modulator or the required bandwidth of a receiver diode used significantly increased while maintaining the same data rate.

According to an embodiment of the optical transmission device a plurality of source encoders are provided, each a source encoder is coupled to a channel encoder and the one encoded by the respective source encoder Data stream is supplied to the respective channel encoder and there with corresponding additional information, the Error protection information is provided.

The plurality of channel coded thus formed Data streams are fed to a multiplexer, which in the Time range the multitude of channel-coded data streams merges a channel-coded total data stream.

The output of the multiplexer is in accordance with this embodiment coupled to an input of the (d, k) modulation encoder.

A corresponding architecture is according to one embodiment of the invention in the optical receiving device provided, according to this embodiment in the optical Receiving device a demultiplexer is provided with an output of the (d, k) modulation decoder is coupled and which of the modulation-decoded total data stream can be supplied or is supplied.

The modulation is decoded using the demultiplexer Total data stream in the time domain in a variety of modulation-decoded data streams, which essentially correspond to the channel-coded data streams, split and the respective channel decoders, of which a large number in the optical receiving device is provided.

Each channel decoder decodes the one supplied to it modulation-decoded data stream to a channel-decoded Data stream which can be fed to a source decoder or is supplied in which source decoder the respective Data stream is source-decoded.

The (d, k) modulation encoder is preferably designed as a ( 1 , 7 ) modulation encoder or as a ( 2 , 7 ) modulation encoder.

According to an embodiment of the invention, the respective (d, k) modulation decoder is designed as a ( 1 , 7 ) modulation decoder or as a ( 2 , 7 ) modulation decoder on the receiver side.

Embodiments of the invention are in the figures are shown and explained in more detail below.

Show it

Figure 1 is a sketch of an optical transmitter according to an embodiment of the invention.

Fig. 2 shows a diagram of an optical transmission device according to the prior art;

Fig. 3 is a structural diagram of a (d, k) -Modulationsencoders;

FIGS. 4a and 4b intensity characteristics of a format in accordance with the NRZI-coded bit string (FIG. 4a) and a according to the (1, 7) modulation and NRZI format encoded bit sequence (Fig. 4b);

Fig. 5 is a sketch of an optical receiving device according to an embodiment of the invention.

An embodiment of an optical according to the invention Data transmission system is explained in more detail below.

Fig. 1 shows a plurality of source encoders 101, 102, 103 which at their respective output 113, 114, 115 each have a quellenencodierten data stream 104, providing 105, 106.

Each source-coded data stream 104 , 105 , 106 has a multiplicity of useful data divided into data packets, for example in the form of video data, textual data or audio data, as well as additional control information which is designed in accordance with the communication protocol used in each case.

According to this embodiment, the Ethernet protocol alternatively, the ATM (Asynchronous Transfer Mode) protocol or the FDDI (Fiber-Distributed Data Interface) protocol can be used.

An input 116 , 117 , 118 of a channel encoder 107 , 108 , 109 assigned to the respective source encoder 101 , 102 , 103 is connected to an output 113 , 114 , 115 of a source encoder 101 , 102 , 103 , via which input 116 , 117 , 118, the respective source-coded data stream 104 , 105 , 106 can be or is fed to the channel encoder 107 , 108 , 109 .

In the channel encoder 107 , 108 , 109 , the respective source-coded data stream 104 , 105 , 106 is channel-coded to a respective channel-coded data stream 110 , 111 , 112 , which is provided at the output 119 , 120 , 121 of the respective channel encoder 107 , 108 , 109 .

As part of the channel coding, error protection information is added to the data packets of the source-coded data stream 104 , 105 , 106 in order to enable error detection and optionally even error correction on the receiver side.

In each case an output 119 , 120 , 121 of a channel encoder 107 , 108 , 109 is coupled to an input 122 , 123 , 124 of a time multiplexer 125 .

From the time division multiplexer 125, the plurality of channel coded data streams 110, 111, 112 a provided at the output 126 of the time division multiplexer 125 channel coded data stream 135 total combined in the time domain, that is multiplexed.

An output 127 of a (d, k) modulation encoder 128 , configured according to this exemplary embodiment as a ( 1 , 7 ) modulation encoder, is connected to the output 126 of the time multiplexer 125 .

In a (d, k) modulation encoder with d> 0, the binary input data sequence (a _i ) supplied to the (d, k) modulation encoder is converted into a binary output data sequence (x _i ), which is between two first binary symbols , according to this embodiment between two "1" symbols at least d and a maximum of k second binary symbols, according to this embodiment at least d and a maximum of k "0" symbols. The number of bits of the output data sequence (x _i ) generated increases reciprocally to the so-called rate R of the (d, k) modulation code due to the (d, k) modulation coding.

The ( 1 , 7 ) modulation code known per se and described in [5] has a fixed rate R = 2/3. Since the modulation frequency can be doubled with this modulation code, the input bit rate can be increased by 33.3%.

Furthermore, the output data sequences formed according to the ( 1 , 7 ) modulation code in the ( 1 , 7 ) modulation encoder 128 are shown by the input data sequences supplied to the ( 1 , 7 ) modulation encoder 128 :

The modulation-coded data stream 136 formed in this way by means of the ( 1 , 7 ) modulation encoder 128 and provided at its output 131 is provided to an optical modulator 133 , which is coupled via an input 132 to the output 131 of the ( 1 , 7 ) modulation encoder 128 is.

Fig. 3300 (d k) are presented to illustrate a structure diagram of a -Modulationsencoders 301, with an input Bitdatenfolge (a _i) 302 in accordance with (d, k) to the respectively used - modulation code to an output Bitdatenfolge (x _i) 303 is mapped.

With the optical modulator 133 , a light wave fed from a light source 129 to an optical fiber 130 with constant frequency is modulated by means of amplitude modulation, the information of the modulation-encoded data stream 136 and fed to a second optical fiber 134 .

The amplitude modulation according to this embodiment takes place according to the on-off keying procedure, alternatively according to the BPSK procedure.

According to this exemplary embodiment, the NRZI standard (non-return-to-zero interleaved standard) as Data format used.

Fig. 4a shows a intensity profile 400 of a according to the NRZI-standard encoded bit sequence 401 over time, wherein the first binary symbol, that is, the "1" symbol, a change of the nominal signal amplitude corresponds to, while in a second binary symbol, means with a "0" symbol, no change in signal amplitude occurs.

According to this embodiment, the maximum switching frequency of the optical modulator 133 f _max .

The maximum (gross) data rate to be transmitted during use a (d, k) modulation code is larger by a factor (d + 1) than in the uncoded case.

At the same time, the (net) data rate decreases by the rate of the (d, k) modulation code R used in each case, so that the (net) data rate overall at (d + 1) × R × f _max bits / s (compared to f _max Bits / s in the uncoded case).

FIG. 4b shows the intensity profile 410 of the modulationsencodierten data sequence 411 for an inventive (1, 7) -Modulationsencodierung which is combined with a coding according to the NRZI format according to the invention.

After transmission of the optically modulated data stream 137 formed by the optical modulator 133 and supplied to the second optical fiber 134 , the optically modulated data stream 137 is received by an optical receiver device 500 (cf. FIG. 5).

The second optical fiber 134 connected to the optical receiving device 500 and feeding the optically modulated data stream 137 to the optical receiving device 500 is coupled to an optical demodulator 501 , at the output 502 of which the optically demodulated data stream 503 is provided, which essentially corresponds to the modulation-encoded data stream 136 .

An input 504 of a ( 1 , 7 ) modulation decoder 505 is coupled to the output 502 of the optical demodulator 501 , via which input 504 the optically demodulated data stream 503 is supplied.

From the ( 1 , 7 ) modulation decoder 505 , according to the ( 1 , 7 ) modulation code used, the optically demodulated data stream 503 is converted into a modulation-decoded total data stream 506 using the correspondingly inverted mapping table shown above, which modulation-decoded total data stream 506 is provided at an output 507 of the ( 1 , 7 ) modulation decoder 505 .

The output 507 of the ( 1 , 7 ) modulation decoder 505 is coupled to an input 508 of a time demultiplexer 509 .

The modulation-decoded total data stream 506 is supplied to the input 508 of the time demultiplexer 509 . The time demultiplexer 509 divides the modulation-decoded total data stream 506 into a plurality of modulation-decoded data streams 510 , 511 , 512 demultiplexed in the time domain, which are provided at a respective output 513 , 514 , 515 of the time demultiplexer 509 .

An output 513 , 514 , 515 of the time demultiplexer 509 is each coupled to an input 516 , 517 , 518 of a channel decoder 519 , 520 , 521 .

Via the respective input 516 , 517 , 518 of the channel decoder 519 , 520 , 521 , the respective demultiplexed, modulation-decoded data stream 510 , 511 , 512 is fed to it. In the channel decoder 519 , 520 , 521 , among other things, an error detection or an error correction is carried out in accordance with the error protection mechanism used.

Each channel decoder 519 , 520 , 521 forms a channel-decoded data stream 525 , 526 , 527 provided at its output 522 , 523 , 524 .

The respective output 522 , 523 , 524 of a channel decoder 519 , 520 , 521 is coupled to a corresponding input 528 , 529 , 530 of a source decoder 531 , 532 , 533 as a data sink and the respective channel-decoded data stream 525 , 526 , 527 becomes the respective source decoder 531 , 532 , 533 and source-decoded by the respective source decoder 531 , 532 , 533 .

Is assumed from optical components that in uncoded case, i.e. without using a (d, k) - Modulation coding with a maximum rate of 40 GBit / s can work, the transmitted over the optical channel According to the invention, the data rate can be increased to 80 Gbit / s. This is also the necessary output side Processing speed of the (d, k) used - Modulation encoder.

When using the ( 1 , 7 ) modulation code with a code rate of R = 2/3, that is, to put it graphically, two input bits are converted into three output bits, the available net data rate is 2/3 × 80 GBit / s = 53.333 Gbps. This data throughput must be supported by the respective multiplexer and on the input side by the (d, k) modulation encoder.

In this context, it should be noted that a data rate of 80 GBit / s on the receiver side as well must be implemented.

Accordingly, the receiver components are on the required Adapt processing speed. However, this only has little influence on the quality of the received signal, since the corresponding edges in the input signal are relative to the Bit clock and are more separated by a factor of 2.

Some alternative embodiments of the The embodiment described above is explained.

As an alternative to the ( 1 , 7 ) modulation code, the ( 2 , 7 ) modulation code can be used, in which case the respective modulation encoder as ( 2 , 7 ) modulation encoder and the associated (d, k) modulation decoder as ( 2 , 7 ) - Modulation decoders are designed.

The ( 2 , 7 ) modulation code has a fixed rate of R = 1/2. In this case, since the modulation frequency can be increased three times with the ( 2 , 7 ) modulation code, the input bit rate can be increased by 50%.

The mapping table used by the ( 2 , 7 ) modulation encoder or ( 2 , 7 ) modulation decoder is described below:

Alternatively, many other (d, k) modulation codes can be used, the modulation encoder or modulation decoder used in each case of course being adapted in accordance with the (d, k) modulation code used, e.g. B. the ( 1 , 3 ) modulation code (ie the so-called Miller code).

Furthermore, generally everyone in [1], [2], [3] or [4] described (d, k) modulation code can be used.

In an alternative embodiment, the respective optical modulator not a light wave constant frequency, but the light carrier itself is modulated directly.

Furthermore, it is of course possible to have different Use coding formats instead of the NRZI format, for example the RZ format.

In this context it should be noted that the individual Components of the optical transmitter and / or optical receiving device partially or completely can be implemented either in hardware or in software can.

The following publications are cited in this document:
[1] RL Adler, D. Coppersmith, M. Hassner, Algorithms for Sliding Block Codes, IEEE Transactions for Information Theory, Vol. 29, No. 1, pp. 5-22, 1983
[2] KA Schouhammer Immink, Coding Techniques for Digital Recorders, Proceedings of IEEE, Vol. 78, No. 11, pp. 1745-1759, 1990
[3] JG Proakis, Digital Communications, 4th edition, McGraw-Hill New York, pp. 578-588, 2001
[4] PH Siegel, JK Wolf, Modulation and Coding for Information Storage, IEEE Communications Magazine, Vol. 29, No. 12, pp. 68-86, 1991
[5] AD Weathers, JK Wolf, A New Rate 2/3 Sliding Block Code for the ( 1 , 7 ) -Runlength Constraint with the Minimal Number of Encoder States, IEEE Transactions on Information Theory, Vol. 37, No. 3, pp. 908-913, May 1991 List of reference symbols 100 Optical transmission device
101 source encoders
102 source encoders
103 source encoder
104 Source encoded data stream
105 Source encoded data stream
106 source encoded data stream
107 channel encoder
108 channel encoder
109 channel encoder
110 channel coded data stream
111 channel encoded data stream
112 channel encoded data stream
113 Source encoder output
114 Source encoder output
115 Source encoder output
116 Channel encoder input
117 Channel encoder input
118 Channel encoder input
119 Channel encoder output
120 output channel encoder
121 Channel encoder output
122 Time multiplexer input
123 Time multiplexer input
124 Time multiplexer input
125 time multiplexers
126 Time division multiplexer output
127 input ( 1 , 7 ) modulation encoder
128 ( 1 , 7 ) modulation encoder
129 light source
130 First optical fiber
131 Output ( 1 , 7 ) modulation encoder
132 input optical modulator
133 Optical modulator
134 Second optical fiber
135 channel encoded total data stream
136 modulation encoded data stream
137 Optically modulated data stream
201 source encoder
202 source encoder
203 source encoder
204 Source encoded data stream
205 Source encoded data stream
206 source encoded data stream
207 channel encoder
208 channel encoder
209 channel encoder
210 channel coded data stream
211 channel encoded data stream
212 channel encoded data stream
213 multiplexer
214 Multiplexer input
215 input multiplexer
216 input multiplexer
217 total data stream
218 Optical modulator
219 light source
220 optical fiber
300 structure image
301 (d, k) modulation encoder
302 input bit string
303 output bit string
400 intensity curve
401 bit sequence
410 intensity curve
411 bit sequence
500 optical receiving device
501 Optical demodulator
502 optical demodulator output
503 Optically demodulated data stream
504 input ( 1 , 7 ) modulation decoder
505 ( 1 , 7 ) modulation decoder
506 Modulation-decoded total data stream
507 output ( 1 , 7 ) modulation decoder
508 Time demultiplexer input
509 time demultiplexer
510 modulation decoded data stream
511 Modulation decoded data stream
512 modulation-decoded data stream
513 Time demultiplexer output
514 output time demultiplexer
515 output time demultiplexer
516 Channel decoder input
517 Channel decoder input
518 Channel decoder input
519 channel decoder
520 channel decoder
521 channel decoder
522 Channel decoder output
523 Channel decoder output
524 Channel decoder output
525 channel decoded data stream
526 channel decoded data stream
527 channel decoded data stream
528 Source decoder input
529 Source decoder input
530 Source decoder input
531 source decoder
532 source decoder
533 source decoder

Claims (8)

1. Optical transmission device
with a (d, k) modulation encoder which can be supplied with a channel-coded data stream and which provides a modulation-encoded data stream, and
with an optical modulator, which is coupled to the (d, k) modulation encoder and to which the modulation-encoded data stream can be fed. 2. Optical transmission device according to claim 1,
with a plurality of channel encoders,
with a multiplexer, which is coupled on the input side to the channel encoders and is coupled on the output side to an input of the (d, k) modulation encoder. 3. Optical transmission device according to claim 1 or 2, in which the (d, k) modulation encoder is designed as ( 1 , 7 ) modulation encoder. 4. Optical transmission device according to claim 1 or 2, in which the (d, k) modulation encoder is designed as a ( 2 , 7 ) modulation encoder. 5. Optical receiving device
with an optical demodulator, to which an optically encoded data stream can be fed and which provides an optically demodulated data stream, and
with a (d, k) modulation decoder, which is coupled to the optical demodulator and to which the optically demodulated data stream can be fed. 6. Optical receiving device according to claim 5,
with a demultiplexer which is coupled on the input side to an output of the (d, k) modulation decoder and which provides a demultiplexed modulation-decoded data stream on the output side in each case, and
with a plurality of channel decoders, one channel decoder each being coupled to one output of the demultiplexer. 7. Optical receiving device according to claim 5, or 6, wherein the (d, k) modulation decoder is designed as a ( 1 , 7 ) modulation decoder. 8. Optical receiving device according to claim 5 or 6, in which the (d, k) modulation decoder is designed as ( 2 , 7 ) modulation decoder.