WO2016121341A1 - 光送信器、光通信システム、および光通信方法 - Google Patents
光送信器、光通信システム、および光通信方法 Download PDFInfo
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03M—CODING; DECODING; CODE CONVERSION IN GENERAL
- H03M13/00—Coding, decoding or code conversion, for error detection or error correction; Coding theory basic assumptions; Coding bounds; Error probability evaluation methods; Channel models; Simulation or testing of codes
- H03M13/03—Error detection or forward error correction by redundancy in data representation, i.e. code words containing more digits than the source words
- H03M13/23—Error detection or forward error correction by redundancy in data representation, i.e. code words containing more digits than the source words using convolutional codes, e.g. unit memory codes
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B10/00—Transmission systems employing electromagnetic waves other than radio-waves, e.g. infrared, visible or ultraviolet light, or employing corpuscular radiation, e.g. quantum communication
- H04B10/50—Transmitters
- H04B10/516—Details of coding or modulation
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03M—CODING; DECODING; CODE CONVERSION IN GENERAL
- H03M13/00—Coding, decoding or code conversion, for error detection or error correction; Coding theory basic assumptions; Coding bounds; Error probability evaluation methods; Channel models; Simulation or testing of codes
- H03M13/25—Error detection or forward error correction by signal space coding, i.e. adding redundancy in the signal constellation, e.g. Trellis Coded Modulation [TCM]
- H03M13/256—Error detection or forward error correction by signal space coding, i.e. adding redundancy in the signal constellation, e.g. Trellis Coded Modulation [TCM] with trellis coding, e.g. with convolutional codes and TCM
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04J—MULTIPLEX COMMUNICATION
- H04J11/00—Orthogonal multiplex systems, e.g. using WALSH codes
Definitions
- the present invention relates to an optical transmitter, an optical communication system, and an optical communication method, and more particularly to an optical transmitter, an optical communication system, and an optical communication method that perform optical encoding modulation using a digital signal.
- the related variable bit rate optical transmitter described in Patent Document 1 includes a digital signal processing unit (DSP) and an accompanying DA converter circuit (DAC), and various programmable M-value quadrature amplitude modulation (M-QAM). ) Drive method.
- DSP digital signal processing unit
- DAC DA converter circuit
- M-QAM programmable M-value quadrature amplitude modulation
- the DSP is programmed to apply a control algorithm and select an appropriate QAM method from among a plurality of QAM methods for signal modulation of the optical transmitter. With such a configuration, a desired transmission performance level can be maintained or transmission performance can be optimized without having to replace the optical transmitter.
- the related variable bit rate optical transmitter there is a problem that the granularity when switching the modulation method is coarse, and there is a surplus in the frequency utilization efficiency depending on conditions. Also, when switching between multiple modulation systems such as BPSK, QPSK, 8QAM, 16QAM, etc. with a single optical transceiver, multiple algorithms corresponding to multiple modulation systems and digital signal processing circuits with bit accuracy are installed. There is a need to. Therefore, there are problems that the power consumption of the optical transmitter and the optical receiver is increased and the control is complicated.
- Non-Patent Document 1 discloses a technique for obtaining a coding gain by multi-dimensional optical code modulation SP (set-partitioning) -32-4D (dimensions) -16QAM or SP-128-4D-16QAM. .
- Non-Patent Document 2 discloses a trellis encoding method combining a convolutional code and a set division method as a method for realizing a transmission distance exceeding the expected transmission distance from the trade-off relationship between the transmission distance and the frequency utilization efficiency.
- An optical modulation scheme is disclosed.
- trellis coded modulation the least square free distance between code sequences can be expanded by convolutional coding to the square distance of the distance between signals in the state divided by the set division method. Therefore, a coding gain exceeding the set division method can be obtained.
- the above-described trellis coded modulation has a limited range of application because there are fewer options for redundancy than the set division method. For this reason, there are limitations on obtaining the effects of both the finer switching of frequency utilization efficiency by the set division method and the extension of the transmission distance by trellis coded modulation. As a result, there is a problem that it is difficult to effectively use frequency resources.
- the object of the present invention is to enable frequency resources to be used without increasing power consumption and complicating control when the modulation system used in an optical communication system, which is the problem described above, can be switched according to transmission conditions.
- An object of the present invention is to provide an optical transmitter, an optical communication system, and an optical communication method that solve the problem of being difficult to utilize.
- the optical transmitter includes an interface unit that converts a digital signal transmitted under a predetermined transmission condition by an optical carrier wave into a parallel signal having a predetermined number of bits at a predetermined transmission rate, and a redundant parallel signal.
- An encoding unit that encodes one of a plurality of convolutional encoding methods of different degrees, a mapping unit that associates an output bit signal output from the encoding unit with a modulation symbol, and a symbol that is output from the mapping unit
- An optical modulation unit that modulates an optical carrier wave based on a signal and a predetermined encoding method corresponding to a predetermined transmission condition are selected from a plurality of convolutional encoding methods, and operates according to the predetermined encoding method As described above, an encoding unit that controls the interface unit, the encoding unit, the mapping unit, and the optical modulation unit.
- An optical communication system of the present invention includes an optical transmitter that transmits an optical modulation signal to an optical transmission medium, and an optical receiver that receives the optical modulation signal propagated through the optical transmission medium.
- the optical transmitter includes an optical carrier wave.
- An interface unit that converts a digital signal transmitted under a predetermined transmission condition into a parallel signal having a predetermined number of bits at a predetermined transmission rate and outputs the parallel signal with a plurality of convolutional coding schemes having different redundancy levels.
- An encoding unit that encodes using one of the encoding methods, a mapping unit that associates an output bit signal output from the encoding unit with a modulation symbol, and light that modulates an optical carrier based on the symbol signal output from the mapping unit
- a predetermined encoding method corresponding to a predetermined transmission condition is selected from the modulation unit and a plurality of convolutional encoding methods, and the interface is configured to operate according to the predetermined encoding method.
- an encoding control unit for controlling each of the source unit, the encoding unit, the mapping unit, and the optical modulation unit.
- the optical receiver receives the optical modulation signal, converts the optical modulation signal into an electric signal, and outputs the received signal.
- a predetermined conversion method is selected from the photoelectric conversion unit, the decoding unit that receives the received signal and decodes the received signal using one of the decoding methods, and the plurality of decoding methods.
- a decoding control unit that causes the decoding unit to operate according to a predetermined decoding method.
- the optical communication method of the present invention converts a digital signal transmitted under a predetermined transmission condition using an optical carrier wave into a parallel signal having a predetermined number of bits at a predetermined transmission rate, and the parallel signal is convolved with a plurality of different degrees of redundancy.
- Encoding is performed with a predetermined encoding method corresponding to a predetermined transmission condition among the encoding methods, a symbol signal is generated by associating the encoded bit signal with a modulation symbol, and an optical carrier wave is modulated based on the symbol signal An optical modulation signal is generated.
- the optical transmitter, the optical communication system, and the optical communication method of the present invention even when the modulation scheme used in the optical communication system can be switched according to the transmission conditions, the power consumption can be increased. It is possible to effectively use frequency resources without causing complicated control.
- FIG. 1 is a block diagram showing a configuration of an optical transmitter 100 according to the first embodiment of the present invention.
- the optical transmitter 100 includes an interface unit 110, an encoding unit 120, a mapping unit 130, an optical modulation unit 140, and an encoding control unit 150.
- the interface unit 110 converts a digital signal transmitted under a predetermined transmission condition using an optical carrier wave into a parallel signal having a predetermined number of bits at a predetermined transmission rate and outputs the parallel signal.
- the encoding unit 120 encodes the parallel signal using one of a plurality of convolutional encoding schemes having different redundancy.
- the mapping unit 130 associates the output bit signal output from the encoding unit 120 with the modulation symbol.
- the optical modulator 140 modulates the optical carrier based on the symbol signal output from the mapping unit 130.
- the encoding control unit 150 selects a predetermined encoding method corresponding to a predetermined transmission condition from a plurality of convolutional encoding methods. Then, the interface unit 110, the encoding unit 120, the mapping unit 130, and the light modulation unit 140 are controlled so as to operate according to the predetermined encoding method at this time.
- At least one of transmission capacity, transmission distance, error rate, and optical signal-to-noise ratio can be used.
- the encoding control unit 150 selects an optimal encoding method from encoding method 1 to encoding method k according to predetermined transmission conditions such as a transmission distance and a transmission capacity required for communication. Then, the operation modes of the interface unit 110, the encoding unit 120, the mapping unit 130, and the optical modulation unit 140 are set according to the selected encoding method.
- the interface unit 110 performs serial / parallel conversion on the input signal and outputs an m-bit parallel signal.
- Encoding section 120 receives information bits converted into m bits in parallel, encodes them based on the encoding scheme set by encoding control section 150, and outputs n-bit bit strings b 1 to b n .
- Mapping unit 130 a bit sequence b 1 ⁇ b n to After symbol mapping in d-dimensional symbol space, S 1, S 2, ⁇ ⁇ ⁇ , to the light modulation unit 140 as a data string of d pieces (dimensions) of S d Output.
- the optical modulation unit 140 performs optical modulation based on each data of S 1 , S 2 ,..., S d and outputs a transmission optical signal that has been optically encoded and modulated.
- the light modulator 140 includes a digital-to-analog converter (not shown), a modulator driver, an optical modulator, a light source, and the like.
- the interface unit 110 operates at a predetermined transmission rate determined according to a predetermined encoding method, converts the parallel signal into a parallel signal having a predetermined number of bits determined according to a predetermined encoding method, and outputs the parallel signal. That is, the interface unit 110 operates at different transmission rates according to the encoding scheme set by the encoding control unit 150, and serial / parallel converts the transmission bit string input at the set transmission rate into an m-bit parallel signal. .
- the encoding unit 120 is configured to be able to select and set from k encoding schemes of encoding scheme 1 to encoding scheme k having different output redundant bit numbers.
- the encoding method at this time is determined by the encoding control unit 150, and an m-bit parallel signal is input and an n-bit output bit signal is output.
- the mapping unit 130 assigns the n-bit output signal of the encoding unit 120 to the d-dimensional symbol space so as to obtain a coding gain by trellis coding modulation.
- the symbol signal for driving the optical modulator the optical modulator 140 is provided, i.e. the data sequence S 1, S 2, is converted to ⁇ ⁇ ⁇ S d.
- the optical phase of the optical carrier (I component and Q component), polarization (X polarization component and Y polarization component), Signals according to at least one of the wavelength and time dimensions can be used. Further, by combining these multiple dimensions, it is possible to perform higher-dimensional optical encoding modulation.
- the light modulator provided in the light modulation unit 140 includes any one of a ferroelectric material such as lithium niobate (LiNbO 3 ) and a semiconductor material.
- a ferroelectric material such as lithium niobate (LiNbO 3 )
- a semiconductor material such as silicon niobate (LiNbO 3 )
- a digital signal transmitted under a predetermined transmission condition by an optical carrier is converted into a parallel signal having a predetermined number of bits at a predetermined transmission rate.
- the parallel signal is encoded by a predetermined encoding method corresponding to a predetermined transmission condition among a plurality of convolutional encoding methods having different redundancy.
- the symbol signal is generated by associating the encoded bit signal with the modulation symbol.
- an optical modulation signal is generated by modulating the optical carrier based on this symbol signal.
- the parallel signal described above When converting to the parallel signal described above, it can be configured to convert the signal into a parallel signal having a predetermined number of bits determined according to a predetermined encoding method at a predetermined transmission rate determined according to a predetermined encoding method. .
- a predetermined encoding method corresponding to a predetermined transmission condition is selected from a plurality of convolutional encoding methods having different degrees of redundancy.
- the encoding is performed.
- FIG. 2 is a block diagram showing a configuration of an optical transmitter 200 according to the second embodiment of the present invention.
- the optical transmitter 200 includes an interface unit 110, an encoding unit 220, a mapping unit 230, an optical modulation unit 140, and an encoding control unit 150. Since the configuration of the optical transmitter 200 according to the present embodiment other than the encoding unit 220 and the mapping unit 230 is the same as that of the optical transmitter 100 according to the first embodiment, detailed description thereof is omitted.
- FIG. 3 shows an example of the configuration of the encoding unit 220 included in the optical transmitter 200 of the present embodiment.
- the encoding unit 220 can configure a plurality of encoder structures with different numbers of redundant bits in the convolutional encoding scheme and equal constraint lengths. Then, the encoding control unit 150 controls the encoding unit 220 to operate by selecting one encoder structure from a plurality of encoder structures.
- the encoding unit 220 has a structure that can be configured by switching between the first encoder structure 221 and the second encoder structure 222.
- the number of input bits is m bits
- the number of output bits is n bits
- the number of input bits is m ′ bits
- the number of output bits is n bits
- the logic circuit is switched using only one encoder. It is possible to select two types of encoding schemes only.
- FIG. 4 shows an example of the configuration of the mapping unit 230 provided in the optical transmitter 200 of the present embodiment.
- the mapping unit 230 includes a set selection unit 231 and a symbol selection unit 232.
- the input of the set selection unit 231 is ⁇ bits
- the set selection unit 231 divides the modulation symbol into a plurality of subsets (small sets), and selects one of the plurality of subsets (small sets) based on the output bit signal. That is, the set selection unit 231 selects one small set from among a plurality of small sets based on the ⁇ -bit input signal.
- the symbol selection unit 232 selects one modulation symbol based on the output bit signal from the modulation symbols included in the selected subset selected by the set selection unit 231 and associates the output bit signal with the selected modulation symbol. That is, the symbol selection unit 232 selects one symbol out of 2 ⁇ symbols included in the small set selected by the set selection unit 231 based on the ⁇ -bit input signal, and outputs the selected symbol to the optical modulation unit 140. To do. Here, it is assumed that the selected symbol belongs to the four-dimensional symbol space. In this embodiment, the optical phase (I component and Q component) and polarization (X polarization component and Y polarization component) of the optical carrier wave are used as the four-dimensional signal space.
- the set selection unit 231 divides the four-dimensional QAM modulation constellation into eight small sets S0 to S7 shown in FIG. 5 based on the set division method. Then, one of the small sets is selected using the encoded ⁇ bits.
- the symbol selection unit 232 selects one of a plurality of symbols belonging to the small set selected by the set selection unit 231 using the uncoded ⁇ bits, and outputs the selected four-dimensional signal.
- the set selection unit 231 divides the four-dimensional QAM modulation constellation into 32 small sets R0 to R31 based on the set division method. Then, one of the small sets is selected using the encoded ⁇ bits.
- the symbol selection unit 232 selects one of a plurality of symbols belonging to the small set selected by the set selection unit 231 using the uncoded ⁇ bits, and outputs the selected four-dimensional signal.
- Non-Patent Document 1 discloses SP-128-16QAM modulation in which symbol division by set division is performed on symbols mapped in a four-dimensional signal space of phase information and polarization information. Since the inter-symbol distance is expanded by the set division, the reception sensitivity can be improved.
- the set division will be described in more detail.
- FIG. 6 shows an example of set division for a two-dimensional 16QAM constellation.
- a two-dimensional 16QAM symbol is divided into two sets P0 and P1 thinned out by half. This doubles the minimum squared Euclidean distance (MSED) between symbols in each set.
- the set division can be repeated, and as shown in the figure, P0 can be further divided into Q0 and Q1, and P1 can be further divided into Q2 and Q3. It goes without saying that the set division can be further repeated according to the original symbol set. Note that the same set division is possible for a two-dimensional 2 n QAM signal.
- FIG. 5 is an example of set partitioning for four-dimensional 2 n QAM.
- the set division in 4 dimensions can be configured from the set division in 2 dimensions.
- R0 indicates a union of a small set of X polarization P0 and Y polarization P0 and a small set of X polarization P1 and Y polarization P1.
- R0 and R1 can be further divided into eight small sets S0 to S7. It goes without saying that the set division can be further repeated by the original symbol set in the four-dimensional symbol space as in the case of the two-dimensional symbol space.
- the first encoder structure 221 and the second encoder structure 222 make a state transition by 2 bits of the input bits and have exactly the same state transition structure.
- FIG. 7 shows a trellis diagram corresponding to the state transition.
- the redundant bit is 1 bit, and at this time, one of a plurality of symbols in one small set among the small sets S0 to S7 corresponding to the transition is sent,
- the least square Euclidean distance (MSED) between the symbols is 4d 0 2 .
- the second encoder structure 222 when the second encoder structure 222 is used and the redundant bit is 3 bits, one of a plurality of symbols of the small sets T0 to T31 corresponding to the transition is sent, and the least square between the symbols is sent.
- the Euclidean distance (MSED) is 8d 0 2 .
- the above-described plurality of encoding methods can have different settings for receiving sensitivity and encoding rate. Therefore, it becomes possible to select a modulation method using a suitable encoding method according to the required transmission distance and transmission capacity.
- the base constellation does not change, so that it is possible to minimize changes in digital signal processing.
- the modulation system used in the optical communication system can be switched according to the transmission conditions, the effect of extending the transmission distance without increasing the power consumption or complicating the control is achieved. Obtainable.
- the physical interface such as an optical modulator can be shared in each encoding method, the number of parts can be reduced. Thereby, the cost of an optical transmitter can be reduced and control can be facilitated.
- a digital signal transmitted under a predetermined transmission condition by an optical carrier is converted into a parallel signal having a predetermined number of bits at a predetermined transmission rate.
- the parallel signal is encoded by a predetermined encoding method corresponding to a predetermined transmission condition among a plurality of convolutional encoding methods having different redundancy.
- the symbol signal is generated by associating the encoded bit signal with the modulation symbol.
- an optical modulation signal is generated by modulating the optical carrier based on this symbol signal.
- the modulation symbol is divided into a plurality of subsets, and one of the plurality of subsets is selected based on the bit signal. Then, one modulation symbol can be selected from the modulation symbols included in the selected selected subset based on the bit signal, and the bit signal can be associated with the selected modulation symbol.
- a predetermined encoding method corresponding to a predetermined transmission condition is selected from a plurality of convolutional encoding methods having different degrees of redundancy.
- the encoding is performed.
- FIG. 8 is a block diagram showing a configuration of an optical transmitter 300 according to the third embodiment of the present invention.
- the optical transmitter 300 includes an interface unit 110, an encoding unit 320, a mapping unit 330, a parallel / serial conversion unit 335, an optical modulation unit 140, and an encoding control unit 150. Since the configuration of the optical transmitter 300 according to the present embodiment other than the encoding unit 320, the mapping unit 330, and the parallel / serial conversion unit 335 is the same as that of the optical transmitter 100 according to the first embodiment, detailed description thereof is omitted. Description is omitted.
- FIG. 9 shows an example of the configuration of the encoding unit 320 included in the optical transmitter 300 of the present embodiment.
- the encoder 320 is a structure that can be configured by switching between the first encoder structure 321 and the second encoder structure 322.
- the number of input bits is m bits
- the number of output bits is n bits
- the number of input bits is m ′ bits
- the number of output bits is n bits
- the logic circuit is switched using only one encoder. It is possible to select two types of encoding schemes only.
- FIG. 10 shows an example of the configuration of the mapping unit 330 included in the optical transmitter 300 of the present embodiment.
- the mapping unit 330 includes a set selection unit 331 and a symbol selection unit 332.
- the input of the set selection unit 331 is ⁇ bits
- the set selection unit 331 divides the modulation symbol into a plurality of subsets (small sets), and selects one of the plurality of subsets (small sets) based on the output bit signal. That is, the set selection unit 331 selects one small set from among a plurality of small sets based on the ⁇ -bit input signal.
- the symbol selection unit 332 selects one modulation symbol based on the output bit signal from the modulation symbols included in the selected subset selected by the set selection unit 331, and associates the output bit signal with the selected modulation symbol. That is, the symbol selection unit 332 selects one symbol out of 2 ⁇ symbols included in the small set selected by the set selection unit 331 based on the ⁇ -bit input signal, and the parallel / serial conversion unit 335. Output to.
- the selected symbol belongs to the 8-dimensional symbol space.
- an optical phase of an optical carrier (I component and Q component), polarization (X polarization component and Y polarization component), and two continuous time slots are used as an 8-dimensional signal space. It was.
- the parallel / serial conversion unit 335 assigns the 8-dimensional signal output from the mapping unit 330 to each of the two time slots as a 4-dimensional signal, and outputs the 4-dimensional signal to the optical modulation unit 140.
- the set selection unit 331 divides the 8-dimensional QAM modulation constellation into 16 small sets V0 to V15 shown in FIG. 11 based on the set division method. Then, one of the small sets is selected using the encoded ⁇ bits.
- the symbol selection unit 332 selects one of a plurality of symbols belonging to the small set selected by the set selection unit 331, and outputs the selected 8-dimensional signal.
- the set selection unit 331 divides the 8-dimensional QAM modulation constellation into 256 small sets W0 to W255 shown in FIG. 11 based on the set division method. Then, one of the small sets is selected using the encoded ⁇ bits.
- the symbol selection unit 332 selects one of a plurality of symbols belonging to the small set selected by the set selection unit 331, and outputs the selected 8-dimensional signal.
- the minimum free distance is 4d 0 2 .
- the transmission bit rate is (n-1) / (2n), but the reception sensitivity is improved.
- the redundant bits are 4 bits, the minimum free distance is 8d 0 2 .
- the transmission bit rate is (n ⁇ 4) / (2n), but the reception sensitivity is further improved.
- the above-described plurality of encoding methods can have different settings for receiving sensitivity and encoding rate. Therefore, it becomes possible to select a modulation method using a suitable encoding method according to the required transmission distance and transmission capacity.
- the optical transmitter 300 of the present embodiment a configuration in which a predetermined encoding method corresponding to a predetermined transmission condition is selected and encoded from among a plurality of convolutional encoding methods having different redundancy levels. It is said.
- the modulation scheme used in the optical communication system can be switched according to the transmission conditions, the frequency resource is not increased without increasing the power consumption or complicating the control. Can be used effectively.
- the present invention is not limited to this, and any modulation method based on a convolutional encoder and a trellis diagram can apply the present invention even when using turbo trellis coded modulation or bit interleaved coded modulation. Needless to say.
- FIG. 12 is a block diagram showing a configuration of an optical communication system 1000 according to the fourth embodiment of the present invention.
- the optical communication system 1000 includes an optical transmitter 100 that transmits an optical modulation signal to a communication path (optical transmission medium) 600, and an optical receiver 400 that receives the optical modulation signal propagated through the communication path 600.
- the optical transmitter 100 includes an interface unit 110, an encoding unit 120, a mapping unit 130, an optical modulation unit 140, and an encoding control unit 150. Since the configuration and operation of the optical transmitter 100 are the same as those of the optical transmitter according to the first embodiment, detailed description thereof is omitted.
- the optical receiver 400 includes a photoelectric conversion unit 410, a decoding unit 420, and a decoding control unit 430.
- the photoelectric conversion unit 410 receives the light modulation signal, converts it into an electrical signal, and outputs a reception signal.
- Decoding section 420 receives the received signal and decodes it using one of a plurality of decoding schemes. Then, the decoding control unit 430 selects a predetermined decoding method from a plurality of decoding methods, and causes the decoding unit 420 to operate according to the predetermined decoding method.
- the operation of the optical communication system 1000 according to the present embodiment will be described. Note that the operation of the optical transmitter 100 for outputting the optical signal that has been optically encoded and modulated is the same as that in the first embodiment, and a description thereof will be omitted.
- the optical signal output from the optical modulation unit 140 included in the optical transmitter 100 is received by the photoelectric conversion unit 410 included in the optical receiver 400 through the communication path 600.
- the photoelectric conversion unit 410 converts the received optical signal into an electrical signal, and outputs the received signal as a digital signal in each XI-ch, XQ-ch, YI-ch, and YQ-ch lane.
- the photoelectric conversion unit includes a 90 ° hybrid, a photodiode, a transimpedance amplifier, an A / D converter (analog-to-digital converter), and the like (not shown).
- the decoding unit 420 selects one decoding method among a plurality of decoding methods according to the setting of the decoding control unit 430.
- a decoding method as described above a soft-decision Viterbi decoding method that outputs a probability that a bit is 1 in each bit, a Viterbi decoding method that makes a hard decision on a maximum likelihood sequence, and a convolutional code with a longer constraint length
- a sequential decoding method can be used.
- the optical communication system 1000 may further include an optical network control unit 500.
- the optical network control unit 500 determines a predetermined encoding method and a predetermined decoding method corresponding to a predetermined transmission condition, and notifies the encoding control unit 150 and the decoding control unit 430 in synchronization.
- optical network control unit 500 Next, the operation of the optical network control unit 500 will be described in more detail.
- the optical network control unit 500 selects a suitable encoding method and decoding method based on communication quality information such as transmission distance and transmission capacity, which are transmission conditions required from the system operation side. Then, the selection result is notified in synchronization with the encoding control unit 150 and the decoding control unit 430. Specifically, the optical network control unit 500 instructs the encoding control unit 150 to set the coding redundancy such as the coding rate, and instructs the decoding control unit 430 to set the decoding scheme. At this time, a suitable reception state can be maintained by performing the setting change of the encoding control unit 150 and the decoding control unit 430 in synchronization.
- the optical network control unit 500 does not necessarily need to acquire communication quality information used for the above-described control from the system operation side. For example, it is possible to select a suitable encoding method and decoding method using information such as an optical signal-to-noise ratio and an error rate.
- a digital signal transmitted under a predetermined transmission condition by an optical carrier is converted into a parallel signal having a predetermined number of bits at a predetermined transmission rate.
- the parallel signal is encoded by a predetermined encoding method corresponding to a predetermined transmission condition among a plurality of convolutional encoding methods having different redundancy.
- the symbol signal is generated by associating the encoded bit signal with the modulation symbol.
- an optical modulation signal is generated by modulating the optical carrier based on this symbol signal.
- the optical modulation signal is received and a reception signal converted into an electric signal is generated.
- the received signal is decoded by selecting a predetermined decoding method from among a plurality of decoding methods.
- a predetermined encoding method corresponding to a predetermined transmission condition is selected from a plurality of convolutional encoding methods having different redundancy levels.
- the encoding is performed.
- Optical transmitter 110 Interface unit 120, 220, 320 Encoding unit 130, 230, 330 Mapping unit 140
- Optical modulation unit 150 Encoding control unit 221, 321 First encoder structure 222, 322 Second Encoder structure 231, 331 set selection unit 232, 332 symbol selection unit 335 parallel / serial conversion unit 400
- optical receiver 410 photoelectric conversion unit 420 decoding unit 430 decoding control unit 500 optical network control unit 600 communication path 1000 light Communications system
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Abstract
Description
図1は、本発明の第1の実施形態に係る光送信器100の構成を示すブロック図である。光送信器100は、インターフェース部110、符号化部120、マッピング部130、光変調部140、および符号化制御部150を有する。
次に、本発明の第2の実施形態について説明する。図2は、本発明の第2の実施形態に係る光送信器200の構成を示すブロック図である。
次に、本発明の第3の実施形態について説明する。図8は、本発明の第3の実施形態に係る光送信器300の構成を示すブロック図である。
次に、本発明の第4の実施形態について説明する。図12は、本発明の第4の実施形態に係る光通信システム1000の構成を示すブロック図である。
110 インターフェース部
120、220、320 符号化部
130、230、330 マッピング部
140 光変調部
150 符号化制御部
221、321 第1の符号化器構造
222、322 第2の符号化器構造
231、331 セット選択部
232、332 シンボル選択部
335 パラレル/シリアル変換部
400 光受信器
410 光電変換部
420 復号化部
430 復号化制御部
500 光ネットワーク制御部
600 通信路
1000 光通信システム
Claims (19)
- 光搬送波により所定の伝送条件で伝送するデジタル信号を、所定の伝送レートで、所定のビット数のパラレル信号に変換して出力するインターフェース手段と、
前記パラレル信号を、冗長度の異なる複数の畳み込み符号化方式のうちの一の符号化方式で符号化する符号化手段と、
前記符号化手段が出力する出力ビット信号を変調シンボルに対応付けるマッピング手段と、
前記マッピング手段が出力するシンボル信号に基づいて前記光搬送波を変調する光変調手段と、
前記複数の畳み込み符号化方式の中から、前記所定の伝送条件に対応した所定の符号化方式を選択し、前記所定の符号化方式に応じて動作するように、前記インターフェース手段、前記符号化手段、前記マッピング手段、および前記光変調手段をそれぞれ制御する符号化制御手段、とを有する
光送信器。 - 請求項1に記載した光送信器において、
前記インターフェース手段は、前記所定の符号化方式に応じて定まる前記所定の伝送レートで動作し、前記所定の符号化方式に応じて定まる前記所定のビット数のパラレル信号に変換して出力する
光送信器。 - 請求項1または2に記載した光送信器において、
前記符号化手段は、前記畳み込み符号化方式における冗長ビット数が異なり、拘束長が等しい複数の符号化器構造を構成することができ、
前記符号化制御手段は、前記複数の符号化器構造から一の符号化器構造を選択して動作するように前記符号化手段を制御する
光送信器。 - 請求項1から3のいずれか一項に記載した光送信器において、
前記マッピング手段は、セット選択手段とシンボル選択手段を備え、
前記セット選択手段は、前記変調シンボルを複数のサブセットに分割し、前記出力ビット信号に基づいて前記複数のサブセットのうちの一のサブセットを選択し、
前記シンボル選択手段は、前記セット選択手段が選択した選択サブセットに含まれる変調シンボルから、前記出力ビット信号に基づいて一の変調シンボルを選択し、選択した変調シンボルに前記出力ビット信号を対応付ける
光送信器。 - 請求項1から4のいずれか一項に記載した光送信器において、
前記シンボル信号は、前記デジタル信号を伝送する際のタイムスロット上の位置を一の次元とする信号からなり、
前記シンボル信号を、前記タイムスロット上の異なる位置に割り当てて前記光変調手段に出力するパラレル/シリアル変換手段をさらに有する
光送信器。 - 請求項1から5のいずれか一項に記載した光送信器において、
前記伝送条件は、伝送容量、伝送距離、誤り率、および光信号対雑音比のうちの少なくとも一である
光送信器。 - 請求項1から6のいずれか一項に記載した光送信器において、
前記シンボル信号は、前記光搬送波の光位相、偏波、波長、および時間の次元のうちの少なくとも一の次元による信号からなる
光送信器。 - 請求項1から7のいずれか一項に記載した光送信器において、
前記光変調手段を構成する光変調器は、強誘電体材料および半導体材料のいずれかを含んで構成されている
光送信器。 - 請求項1から8のいずれか一項に記載した光送信器において、
前記デジタル信号を、偏波多重、波長多重、および時分割多重の少なくとも一により多重して伝送する
光送信器。 - 光変調信号を光伝送媒体に送出する光送信器と、前記光伝送媒体を伝搬した前記光変調信号を受信する光受信器、を有し、
前記光送信器は、
光搬送波により所定の伝送条件で伝送するデジタル信号を、所定の伝送レートで、所定のビット数のパラレル信号に変換して出力するインターフェース手段と、
前記パラレル信号を、冗長度の異なる複数の畳み込み符号化方式のうちの一の符号化方式で符号化する符号化手段と、
前記符号化手段が出力する出力ビット信号を変調シンボルに対応付けるマッピング手段と、
前記マッピング手段が出力するシンボル信号に基づいて前記光搬送波を変調する光変調手段と、
前記複数の畳み込み符号化方式の中から、前記所定の伝送条件に対応した所定の符号化方式を選択し、前記所定の符号化方式に応じて動作するように、前記インターフェース手段、前記符号化手段、前記マッピング手段、および前記光変調手段をそれぞれ制御する符号化制御手段、とを備え、
前記光受信器は、
前記光変調信号を受信し電気信号に変換して受信信号を出力する光電変換手段と、
前記受信信号を入力し、複数の復号化方式のうちの一の復号化方式で復号化する復号化手段と、
前記複数の復号化方式の中から、所定の復号化方式を選択し、前記復号化手段を前記所定の復号化方式で動作させる復号化制御手段、とを備える
光通信システム。 - 請求項10に記載した光通信システムにおいて、
光ネットワーク制御手段をさらに有し、
前記光ネットワーク制御手段は、前記所定の伝送条件に対応した前記所定の符号化方式と前記所定の復号化方式を決定し、前記符号化制御手段と前記復号化制御手段に同期して通知する
光通信システム。 - 請求項11に記載した光通信システムにおいて、
前記光ネットワーク制御手段は、前記決定に基づいて、
前記符号化制御手段に、前記畳み込み符号化方式における符号化冗長度を通知する
光通信システム。 - 請求項10から12のいずれか一項に記載した光通信システムにおいて、
前記復号化方式は、ビタビ復号方式および逐次復号法方式のいずれかである
光通信システム。 - 請求項10から13のいずれか一項に記載した光通信システムにおいて、
前記伝送条件は、伝送容量、伝送距離、誤り率、および光信号対雑音比のうちの少なくとも一である
光通信システム。 - 請求項10から14のいずれか一項に記載した光通信システムにおいて、
前記シンボル信号は、前記光搬送波の光位相、偏波、波長、および時間の次元のうちの少なくとも一の次元による信号からなる
光通信システム。 - 光搬送波により所定の伝送条件で伝送するデジタル信号を、所定の伝送レートで、所定のビット数のパラレル信号に変換し、
前記パラレル信号を、冗長度の異なる複数の畳み込み符号化方式のうちの前記所定の伝送条件に対応した所定の符号化方式で符号化し、
前記符号化したビット信号を変調シンボルに対応付けてシンボル信号を生成し、
前記シンボル信号に基づいて前記光搬送波を変調した光変調信号を生成する
光通信方法。 - 請求項16に記載した光通信方法において、
前記パラレル信号に変換する際に、前記所定の符号化方式に応じて定まる前記所定の伝送レートで、前記所定の符号化方式に応じて定まる前記所定のビット数のパラレル信号に変換する
光通信方法。 - 請求項16または17に記載した光通信方法において、
前記変調シンボルを複数のサブセットに分割し、前記ビット信号に基づいて前記複数のサブセットのうちの一のサブセットを選択し、
選択した選択サブセットに含まれる変調シンボルから、前記ビット信号に基づいて一の前記変調シンボルを選択し、選択した前記変調シンボルに前記ビット信号を対応付ける
光通信方法。 - 請求項16から18のいずれか一項に記載した光通信方法において、
前記光変調信号を受け付け、電気信号に変換した受信信号を生成し、
前記受信信号を、複数の復号化方式の中から所定の復号化方式を選択して復号化する
光通信方法。
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