JP3740537B2 - Clock synchronization signal transmission system, data transmission system, and methods thereof - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a clock synchronization signal transmission system for transmitting a clock synchronization signal in optical time division multiplexing (OTDM) transmission, a data transmission system capable of transmitting a clock synchronization signal and channel attribute information, and methods thereof.
[0002]
[Prior art]
In an optical fiber transmission system, a bit rate of 160 Gb / s or more is about to be realized at a single wavelength. However, since the response speed of the electric receiver is at most 50 to 60 GHz, clock extraction for establishing synchronization is impossible even if an optical pulse signal of 160 Gb / s or more is directly received.
[0003]
Therefore, an optical circuit for extracting a clock has been devised. For example, a method of realizing a phase locked loop (PLL) by causing an ultrafast optical gate circuit to function as an optical pulse phase shifter, and a two-stage cascade connection of an electroabsorption modulator (EA modulator) used as an optical gate modulator The optical pulse signal is down-converted to a low bit rate by the separation device having the above structure, and then the clock is extracted by the PLL at the electric signal stage, and the optical clock by injection locking to the mode-locked semiconductor laser or self-oscillation semiconductor laser The method of reproducing | regenerating has been examined.
[0004]
An apparatus and method for regenerating an optical clock by extracting a clock component from an optical pulse signal is described in JP-A-2002-353901. By using an electrical resonator having a resonance frequency 1 / n of the clock frequency of the input optical pulse signal and a semiconductor mode-locked laser driven by the output, a frequency 1 / n of the clock frequency of the input optical pulse signal A configuration for generating the optical clock is described.
[0005]
Japanese Patent Laid-Open No. 10-173634 discloses a configuration in which a low frequency signal having a frequency unique to each channel is superimposed on an optical signal of each channel by weak intensity modulation in optical time division multiplex transmission. On the receiving side, a low frequency signal is detected to identify the channel.
[0006]
[Problems to be solved by the invention]
Ultrafast optical gates and multistage optical gates for clock extraction are complicated in construction and are not economical.
[0007]
In an OTDM transmission system, there is still no method for efficiently transmitting attribute information (channel identification information, transfer information or routing information, network management information (such as failure occurrence notification)) of each multiplexed channel. Examples of such attribute information include channel identification information, transfer information (routing information), network management information, and the like. The network management information includes a failure occurrence notification. Such attribute information can only be transmitted by pulse-modulating an optical carrier in the same way as conventional main information data. Therefore, in the receiving apparatus and the router, there is only a method for demodulating the data signal and the attribute information into an electric signal and then demodulating it with an existing electric processing system.
[0008]
A method of transmitting a monitoring signal for monitoring an optical transmission line, a control signal for controlling an optical repeater on the optical transmission line, and a response signal thereof by modulating the amplitude of a pulse signal is well known.
[0009]
An object of the present invention is to provide a clock synchronization signal transmission system and method that can eliminate such inconvenience and that can efficiently transmit a clock synchronization signal and that can be easily extracted.
[0010]
It is another object of the present invention to provide a data system and method that enables transmission of attribute information of each channel with a simple configuration.
[0014]
[Means for Solving the Problems]
A data transmission system according to the present invention generates a pulse signal light generator for generating pulse signal light of n (integer) channels of a base rate (B) carrying data, and the pulse signal light generator outputs the pulse signal light. An amplitude adjusting device that adjusts the pulse amplitude of pulse signal light of one predetermined channel among n channel pulse signal lights to a level relatively different from the pulse amplitude of other pulse signals, and the amplitude adjustment A multiplexing device that time-division-multiplexes the pulse signal light of each channel output from the device and outputs the OTDM signal light to an optical transmission line; and a duplexer that divides the OTDM signal light input from the optical transmission line into two parts A clock recovery device for recovering a clock synchronization signal having a frequency corresponding to the base rate (B) from one output signal light of the duplexer, wherein one output signal of the duplexer A photoelectric conversion device that converts a signal into an electrical signal, a clock recovery device that includes a clock generation circuit that generates a clock synchronization signal having a frequency corresponding to the base rate (B) according to the output of the photoelectric converter, and a plurality of An output port is provided, and the other output signal light of the demultiplexer is separated into the signal light of each channel according to the clock synchronization signal regenerated by the clock recovery device, and the signal light of each channel is output from a different output port The optical separation device , the identification device for identifying whether the pulse signal light output from the predetermined output port of the optical separation device is the signal light of the predetermined channel, and the clock according to the identification result of the identification device And a phase adjuster for adjusting the phase of the clock synchronization signal supplied from the reproducing device to the optical separation device .
[0015]
With such a configuration, a base-rate clock synchronization signal can be reproduced with a simple configuration on the optical receiver side without reproducing and dividing the clock having a frequency corresponding to the bit rate of OTDM. Further, it is possible to control so that pulse signal light of a predetermined channel is output from a predetermined output port of the optical separation device. By changing the predetermined channel adjusted to a different level, the channel output from each output port of the light separation device can be changed.
[0016]
Preferably, the amplitude adjusting device includes n variable level adjusters capable of adjusting the pulse amplitude of the signal light of each channel and a control device that controls the n variable level adjusters. Thereby, the channel for adjusting the pulse amplitude can be selected.
[0017]
Preferably, the control device varies the level adjustment amount of the n variable level adjusters according to the attribute information of each channel. Thereby, the attribute information of each channel can be transmitted without restricting the transmission of data and the band of each channel.
[0018]
The attribute information is, for example, channel identification information, transfer information, network management information, and the like.
[0020]
Preferably, the amplitude adjusting device adjusts the variable level according to n variable level adjusters capable of adjusting the level of signal light of each channel and tone signals having different frequencies for each channel carrying attribute information of each channel. And a control device for controlling the level adjustment amount of the device. Thereby, channel identification becomes easy and attribute information other than channel identification can be transmitted simultaneously.
[0021]
For example, the pulse signal light generator includes a pulse light source that generates an optical pulse having a frequency corresponding to the base rate (B), a duplexer that divides output light of the pulse light source into n, and the demultiplexing And n data modulators for modulating each output of the device according to transmission data.
[0024]
A data transmission method according to the present invention generates pulse signal light of n (integer) channels of base rate (B) carrying data by a pulse signal light generator, and generates the pulse signal light by an amplitude adjuster. Of the n channel pulse signal lights output from the device, the pulse amplitude of a predetermined one channel pulse signal light is adjusted to a level relatively different from the pulse amplitudes of the other pulse signals. The signal light of each channel outputted from the adjusting device is time-division multiplexed, the obtained OTDM signal light is outputted to the optical transmission line, and the OTDM signal light inputted from the optical transmission line is divided into two by a demultiplexer. The output signal light of one of the duplexers is converted into an electrical signal, and a clock synchronization signal having a frequency corresponding to the base rate (B) is generated by a PLL circuit according to the electrical signal. According to the clock synchronization signals, by the light separation unit separates the other output signal light of the demultiplexer the signal light of each channel, the pulse signal light output from the predetermined output port of the beam splitter is of the predetermined channel It is characterized by discriminating whether it is signal light or not, and adjusting the phase of the clock synchronization signal supplied to the optical separator according to the identification result .
[0025]
With this configuration, the optical receiver reproduces a clock synchronization signal having a frequency corresponding to the base rate with a simple configuration without having to divide the frequency after reproducing the clock having a frequency corresponding to the OTDM bit rate. This makes it easy to separate the OTDM optical signal into individual channels. Further, it is possible to control so that pulse signal light of a predetermined channel is output from a predetermined output port of the optical separation device. By changing the predetermined channel adjusted to a different level, the channel output from each output port of the light separation device can be changed.
[0026]
Preferably, further, when adjusting the pulse amplitude of the pulse signal light of one predetermined channel to a level relatively different from the pulse amplitudes of the other pulse signals, the signal light of each channel according to the attribute information of each channel The pulse amplitude is varied. Thereby, the attribute information of each channel can be superimposed on the data and transmitted without restricting the transmission and band of the data of each channel.
[0027]
Preferably, the pulse amplitude of the signal light of each channel is varied according to a tone signal having a different frequency for each channel carrying attribute information of each channel. This facilitates identification of each channel.
[0028]
The attribute information is, for example, any of channel identification information, transfer information, or network management information.
[0030]
【Example】
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0031]
FIG. 1 shows a schematic welfare block diagram of one embodiment of the present invention. The system according to this embodiment includes an optical transmission device 10, an optical transmission line 12, and an optical reception device 14. In this embodiment, the optical transmitter 10 time-division multiplexes 40 Gb / s optical signals for 4 channels and outputs the optical signals to the optical transmission line 12. Accordingly, an optical signal of 160 Gb / s propagates through the optical transmission line 12. By adopting the configuration of the optical transmitter 10 and the optical receiver 14 shown in FIG. 1 for each wavelength of the wavelength division multiplexing transmission system, the present invention can be applied to the wavelength division multiplexing system.
[0032]
The configuration and operation of the optical transmitter 10 will be described. The pulse light source 20 outputs an optical pulse train having a base rate (basic repetition frequency) B having a single wavelength λs. Here, the base rate B is 40 GHz. The optical demultiplexer 22 divides the output pulse of the pulse light source 20 into four and supplies each to the data modulators 24-1 to 24-4. The data modulator 24-1 binary modulates the amplitude of the optical pulse train from the optical demultiplexer 22 according to the data D1. Similarly, the data modulators 24-2 to 24-4 each perform binary modulation on the amplitude of the optical pulse train from the optical demultiplexer 22 according to the data D2 to D4. Thereby, the data modulators 24-1 to 24-4 output optical pulse signals of 40 Gb / s carrying the data D1 to D4, respectively.
[0033]
The variable attenuators 26-1 to 26-4 attenuate the output signal light of the data modulators 24-1 to 24-4 at an attenuation rate according to the control signal from the control device 28. As will be described in detail later, the control device 28 varies the attenuation rate of the attenuators 26-1 to 26-4 so as to carry the attribute information PR1 to PR4 of each channel ch1 to ch4, and the optical receiver 14 The time average attenuation rate (DC component) of the attenuators 26-2 to 26-4 is controlled to the same value so that a clock having a frequency corresponding to the base rate B can be reproduced, and the attenuation rate of the attenuator 26-1 is It controls so that it may become larger than the time average attenuation factor (DC component) of the other attenuators 26-2 to 26-4.
[0034]
The output signal light from the attenuators 26-1 to 26-4 is input to the multiplexer 34 via the phase modulators 30-1 to 30-4 and the delay units 32-1 to 32-4. The delay units 32-1 to 32-4 are provided to arrange the signal lights of the respective channels ch1 to ch4 in different time slots, and the delays of the delay units 32-1 to 32-4 are realized in order to realize this. Times τ1 to τ4 are adjusted. The delay time τ1 of the delay device 32-1 may be zero. That is, the delay device 32-1 can be omitted. The delay units 32-1 to 32-4 and the multiplexer 34 correspond to an OTDM multiplexer. The bit rate of the output signal light from the multiplexer 34 is 160 Gb / s. The output signal light from the multiplexer 34 propagates through the optical transmission line 12 and enters the optical receiver 14.
[0035]
As described above, the control device 28 varies the attenuation rate of the attenuators 26-1 to 26-4 so as to convey the attribute information PR1 to PR4 of the channels ch1 to ch4. More specifically, the control device 28 attenuates 26-1 to 26-4 according to a signal obtained by digitally modulating the amplitude of the sine wave of the frequencies W1 to W4 inherent to the channels ch1 to ch4 with the attribute information PR1 to PR4. Varying the attenuation factor. In other words, this is AC control of the attenuation rate of the attenuators 26-1 to 26-4. As digital modulation, FSK, PSK, DPSK or DQPSK can be used. The frequencies W1 to W4 are, for example, about 100 kHz to 10 MHz which is sufficiently smaller than the base rate (40 GHz) of the data D1 to D4. Since the data amount of attribute information is generally small, such a rate is sufficient. Also, at such a rate, neither transmission of data D1 to D4 nor clock extraction of the base rate B of OTDM is adversely affected.
[0036]
In this manner, the attribute information PR1 to PR4 of each channel ch1 to ch4 can be transmitted by being superimposed on the data D1 to D4 without consuming the band for the data D1 to D4. The attribute information PR1 to PR4 is, for example, channel identification information, transfer information (or routing information), network management information, and the like. The network management information includes a failure occurrence notification.
[0037]
The control device 28 also controls the time average attenuation rate (DC component) of the attenuators 26-2 to 26-4 to the same value so that the optical receiver 14 can regenerate a clock having a frequency corresponding to the base rate B. At the same time, the attenuation rate of the attenuator 26-1 is controlled to be larger than the time average attenuation rate (DC component) of the other attenuators 26-2 to 26-4. For example, the same offset is set for the attenuation rates of the attenuators 26-2 to 26-4, and an offset larger than the offset of the attenuators 26-2 to 26-4 is set for the attenuation rate of the attenuator 26-1. Set. By this DC control, the pulse amplitude of the output signal light of the attenuator 26-1 becomes smaller than the pulse amplitude of the output signal light of the attenuators 26-2 to 26-4.
[0038]
In this way, when a plurality of signal lights having the same bit rate B (for example, 40 Gb / s) are time-division multiplexed, if the pulse amplitude of one channel is sufficiently different from the pulse amplitude of the other channel, Fourier As can be easily understood by recalling the conversion, the spectrum of the OTDM signal light includes a tone component having a frequency corresponding to the bit rate B. By extracting this tone component, the optical receiver 14 can reproduce the clock corresponding to the base rate B. For example, just by making the attenuation rate of the attenuator 26-1 larger by 0.13 dB than the attenuation rate of the other attenuators 26-2 to 26-4, as described later, a 40 GHz clock is generated in the optical receiver 14. I was able to extract.
[0039]
This effect can be extended to clock extraction at an intermediate frequency between the base rate B and the bit rate B × n of the time division multiplexed optical signal composed of n channels. For example, when n channels of the same base rate B are time-division multiplexed, the optical pulse amplitudes of a plurality of appropriate channels in the n channel are attenuated at the same rate, so that from the n-channel time-division multiplexed optical signal, A clock having a frequency B × k (where k is an integer from 2 to n−1) can be extracted.
[0040]
The OTDM optical signal propagated through the optical transmission line 12 is input to the optical receiver 14. The configuration and operation of the optical receiver 14 will be described. The OTDM optical signal propagated through the optical transmission line 12 is divided into two by a demultiplexer 40, one of which is input to an optical amplifier (for example, an erbium-doped optical fiber amplifier (EDFA)) 42, and the other is a clock recovery device. 44.
[0041]
The clock regeneration device 44 includes a light receiver 46 that converts an optical signal of 160 Gb / s input to the optical transmission line 12 into an electric signal, an amplifier 48 that amplifies the output of the light receiver 46, and a clock synchronized with 40 GHz from the output of the amplifier 48. A phase lock loop (PLL) circuit 50 that extracts and generates the signal, an amplifier 52 that amplifies the output of the PLL circuit 50, a band-pass filter (BPF) 54 that extracts only a 40 GHz component from the output of the amplifier 52, and an output of the BPF 54 And a delay circuit 56 for timing adjustment. The configuration itself of the clock recovery device 44 is known for clock recovery. It is characteristic that a 40 GHz clock corresponding to the bit rate B of one channel is reproduced from 160 Gb / s signal light without adding a special circuit. This is possible because, as described above, the output of the light receiver 46 includes a tone component having a frequency corresponding to the base rate B of time division multiplexing. Therefore, the delay circuit 56 outputs a 40 GHz clock signal.
[0042]
A 40 GHz clock signal output from the clock recovery device 44 (delay circuit 56) is amplified by an amplifier 58 and applied to a mode-locked laser (MLLD) 60 as a drive signal. As a result, the MLLD 60 oscillates a laser pulse at 40 GHz and outputs a control pulse light of 40 GHz.
[0043]
The control pulse light output from the MLLD 60 is input to the control terminal C of the light separation device 66 via the optical amplifier (for example, erbium-doped optical fiber amplifier (EDFA)) 62 and the phase adjuster 64. The output signal light of the optical amplifier 42 is input to the data input terminal D of the light separation device 66. The optical demultiplexer 66 applies the OTDM optical signal input to the data input terminal D to each channel ch1, ch2, ch3. Separated into ch4 signal light and output from output ports 1-4. The light separation device 66 includes, for example, a light control optical switch. An optical switch that can be used for separating the OTDM signal light is, for example, I.D. Shaket et al. "160 Gbit / s full OTDM demultiplexing based FWM of SOA-array integrated on planar lightwave circuit," Proc. 27th, European Conference on Optical Communication (ECOC'01), Tul. 2.2, pp. 182-183, 2001.
[0044]
The light separation device 66 outputs the signal light of each channel ch1 to ch4 from separate output ports 1 to 4. If the transmission error on the optical transmission line 12 is ignored, the outputs of the ch1 to ch4 of the optical demultiplexer 66 correspond to the outputs of the attenuators 26-1 to 26-4. Are attribute information PR1 to PR4.
[0045]
In the configuration so far, there is no guarantee that the signal light of the channel ch1 is output from the output port 1 of the light separation device 66. However, by controlling the phase adjuster 64 by the frequency discriminating circuit 82 and the phase control device 84 described later, it can be guaranteed that the signal light of the channel ch1 is output from the output port 1 of the light separation device 66. Details thereof will be described later.
[0046]
The demultiplexers 68-1 to 68-4 each divide the output signal light of the corresponding channel of the optical separation device 66 into two, output one as a payload signal of the corresponding channel, and the other as the attribute demodulator 70- 1 to 70-4.
[0047]
In the attribute demodulator 70-1, the light receiver 72 converts the output signal light from the duplexer 68-1 into an electrical signal. The output of the light receiver 72 is amplified by the amplifier 74 and applied to the multiplier 76. The output of the multiplier 76 is applied to the control terminal of the local oscillator 80 via the loop filter 78. The local oscillator 80 oscillates at a frequency and phase corresponding to the output voltage of the loop filter 78. The output of the oscillator 80 is applied to the multiplier 76. Multiplier 76 multiplies the output of amplifier 74 by the output of oscillator 80. The attribute information PR1 is demodulated by square detection in the multiplier 76.
[0048]
When the signal light output from the output port 1 of the light separation device 66 is ch1 signal light, the oscillator 80 oscillates at the frequency W1. When the signal light output from the output port 1 of the optical separation device 66 is not the ch1 signal light, the oscillator 80 oscillates at a frequency other than the frequency W1. Therefore, by examining the oscillation frequency of the oscillator 80, it is possible to determine whether or not the signal light output from the output port 1 of the light separation device 66 is the ch1 signal light.
[0049]
The frequency identification circuit 82 checks whether or not the frequency of the output signal of the oscillator 80 is equal to the frequency W1, and outputs a coincidence signal to the phase controller 84 if they match, or a mismatch signal if they do not match. When the frequency of the output signal of the oscillator 80 is not equal to the frequency W 1, the phase controller 84 sweeps the phase adjustment amount in the phase adjuster 64, that is, when the frequency identification circuit 82 outputs a coincidence signal, that is, the oscillator 80. In the state where the frequency of the output signal is equal to the frequency W1, the phase adjustment amount of the phase adjuster 64 is fixed. As a result of this phase control, the signal light output from the output port 1 of the light separation device 66 becomes ch1 signal light.
[0050]
The separation order of the light separation device 66 is generally constant. That is, the ch2 signal light is output from the output port 2 of the optical separation device 66, the ch3 signal light is output from the output port 3, and the ch4 signal light is output from the output port 4.
[0051]
By changing the comparison frequency in the frequency identification circuit 82, the correspondence between each output port of the optical separation device 66 and the channel can be changed. For example, when the comparison frequency in the frequency identification circuit 82 is changed to the frequency W2, the optical separation device 66 outputs the signal light of the channel ch2 from the output port 1, and outputs the signal light of the channel ch3 from the output port 2, The signal light of channel ch4 is output from the output port 3, and the signal light of channel ch1 is output from the output port 4.
[0052]
In the present embodiment, in optical time division multiplexing transmission, the optical pulse amplitude of one or a plurality of channels is set to a level different from the pulse amplitude of the remaining channel, and the optical transmission line is transmitted in the optical receiver. A clock having a frequency corresponding to the bit rate of the channel or an integral multiple thereof can be reproduced. This means that one of the clock synchronization signals having a plurality of discrete frequencies can be selectively transmitted.
[0053]
By modulating the pulse amplitude of each channel with a tone signal having a different frequency for each channel, each channel can be easily identified in the optical receiver.
[0054]
Furthermore, by modulating the pulse amplitude of each channel with the attribute information of each channel, the attribute information of each channel can be transmitted without affecting the main data transmission and its band. At this time, by modulating the pulse amplitude of each channel with a tone signal having a different frequency for each channel, the optical receiver can easily identify the signal light of each channel after separating the OTDM signal light.
[0055]
【The invention's effect】
As can be easily understood from the above description, according to the present invention, a clock having a frequency corresponding to the base rate of OTDM signal light or an integral multiple thereof can be transmitted. Also, the attribute information of each channel can be transmitted without affecting the main data transmission and its bandwidth. As a result, a more efficient optical transmission system can be constructed.
[Brief description of the drawings]
FIG. 1 is a schematic block diagram of an embodiment of the present invention.
[Explanation of symbols]
10: Optical transmitter 12: Optical transmission line 14: Optical receiver 20: Pulse light source 22: Optical demultiplexers 24-1-24-4: Data modulators 26-1 to 26-4: Variable attenuator 28: Control Devices 30-1 to 30-4: phase modulators 32-1 to 32-4: delay device 34: multiplexer 40: duplexer 42: optical amplifier 44: clock recovery device 46: light receiver 48: amplifier 50: PLL (phase lock loop) circuit 52: amplifier 54: band pass filter (BPF)
56: Delay circuit 58: Amplifier 60: Mode-locked laser (MLLD)
62: Optical amplifier 74: Phase adjuster 66: Optical separators 68-1 to 68-4: Demultiplexers 70-1 to 70-4: Attribute demodulator 72: Light receiver 74: Amplifier 76: Multiplier 78: Loop Filter 80: Local oscillator 82: Frequency identification circuit 84: Phase control device

Claims (17)

Pulse signal light generators (20, 22, 24-1 to 24-4) for generating pulse signal light of n (integer) channels of a base rate (B) for carrying data;
Of the pulse signal light of n channels output from the pulse signal light generator (20, 22, 24-1 to 24-4), the pulse amplitude of a predetermined one-channel pulse signal light is changed to other An amplitude adjusting device (26-1 to 26-4, 28) for adjusting to a level relatively different from the pulse amplitude of the pulse signal;
Multiplexer (32-1 ) that time-division-multiplexes the pulse signal light of each channel output from the amplitude adjusting device (26-1 to 26-4, 28) and outputs the OTDM signal light to the optical transmission line (12). ~ 32-4, 34),
A duplexer (40) for dividing the OTDM signal light input from the optical transmission line (12) into two parts;
A clock recovery device (44) for recovering a clock synchronization signal having a frequency corresponding to the base rate (B) from one output signal light of the duplexer (40), wherein one of the duplexers (40) A photoelectric converter (46) for converting the output signal light of the signal into an electric signal, and a clock generation circuit for generating a clock synchronization signal having a frequency corresponding to the base rate (B) according to the output of the photoelectric converter (46) A clock recovery device (44) comprising (50);
A plurality of output ports, and in accordance with the clock synchronization signal regenerated by the clock regenerator (44), the other output signal light of the demultiplexer (40) is separated into the signal light of each channel; A light separation device (66) for outputting signal light from different output ports ;
An identification device (82) for identifying whether or not the pulse signal light output from the predetermined output port of the light separation device (64, 66) is the signal light of the predetermined channel;
Phase adjusters (64, 84) for adjusting the phase of the clock synchronization signal supplied from the clock recovery device (44) to the light separation device (66) according to the identification result of the identification device (82).
A data transmission system comprising: The amplitude adjusting device (26-1 to 26-4, 28)
N variable level adjusters (26-1 to 26-4) capable of adjusting the pulse amplitude of the pulse signal light of each channel;
Control device (28) for controlling the n variable level adjusters (26-1 to 26-4)
The data transmission system according to claim 1 , comprising: The data transmission system according to claim 2 , wherein the control device (28) varies the level adjustment amount of the n variable level adjusters (26-1 to 26-4) according to attribute information of each channel. The apparatus according to claim 3 , further comprising a plurality of attribute demodulating devices (70-1 to 70-4) for demodulating the attribute information from pulse signal light output from each output port of the light separating device (66). Data transmission system. The data transmission system according to claim 4 , wherein the attribute information includes at least one of channel identification information, transfer information, and network management information.   The identification device (82) follows the signal from the attribute demodulation device that demodulates the attribute information of the pulse signal light output from the predetermined output port of the light separation device (64, 66). 66. The data transmission system according to claim 4, wherein the pulse signal light output from the predetermined output port is identified as signal light of the predetermined channel. The amplitude adjusting device (26-1 to 26-4, 28)
N variable level adjusters (26-1 to 26-4) capable of adjusting the level of signal light of each channel;
A control device (28) for controlling the level adjustment amount of the variable level adjusters (26-1 to 26-4) in accordance with tone signals having different frequencies for each channel carrying attribute information of each channel.
The data transmission system according to claim 1 , comprising: 8. The apparatus according to claim 7 , further comprising a plurality of attribute demodulation devices (70-1 to 70-4) that demodulate the attribute information from pulse signal light output from each output port of the light separation device (66). Data transmission system. The data transmission system according to claim 8 , wherein the attribute information includes at least one of channel identification information, transfer information, and network management information. The identification device (82) determines the light separation device (64, 66) according to the frequency of the tone signal carrying the attribute signal of the pulse signal light output from the predetermined output port of the light separation device (64, 66). 66. The data transmission system according to claim 7, wherein the pulse signal light output from the predetermined output port is identified as signal light of the predetermined channel. The pulse signal light generator generates a pulse light source (20) that generates an optical pulse having a frequency corresponding to the base rate (B), and a duplexer that divides the output light of the pulse light source (20) into n channels ( and 22), according to any one of n data modulators (24-1 to 24-4) from the composed claims 1 to 10 for modulating the duplexer each output (22) in accordance with the transmission data Data transmission system. The pulse signal light generators (20, 22, 24-1 to 24-4) generate pulse signal light of n (integer) channels of the base rate (B) for carrying data,
Of the pulse signal light of n channels output from the pulse signal light generators (20, 22, 24-1 to 24-4) by the amplitude adjusting device (26-1 to 26-4, 28), , Adjusting the pulse amplitude of the pulse signal light of one predetermined channel to a level relatively different from the pulse amplitude of the other pulse signals,
The signal light of each channel output from the amplitude adjusting device (26-1 to 26-4, 28) is time-division multiplexed, and the obtained OTDM signal light is output to the optical transmission line (12).
The OTDM signal light input from the optical transmission line (12) is divided into two by a demultiplexer (40),
One output signal light of the duplexer (40) is converted into an electrical signal, and a clock synchronization signal having a frequency corresponding to the base rate (B) is generated by a PLL circuit according to the electrical signal,
In accordance with the generated clock synchronization signal, the optical separator (66) separates the other output signal light of the duplexer (40) into signal light of each channel ,
Identifying whether the pulse signal light output from the predetermined output port of the optical separation device (66) is the signal light of the predetermined channel;
A data transmission method characterized by adjusting the phase of the clock synchronization signal supplied to the optical separator (66) according to the identification result . When adjusting the pulse amplitude of the pulse signal light of a given channel to a level relatively different from the pulse amplitude of other pulse signals, the pulse amplitude of the signal light of each channel is varied according to the attribute information of each channel data transmission method according to claim 1 2 to. According different frequency tone signal for each channel carrying the attribute information of each channel, the data transmission method according to claim 1 2 to vary the pulse amplitude of the signal light of each channel. Data transmission method according to claim 1 2 or 1 3 from the pulse signal light output from each output port of the beam splitter (66) for demodulating the attribute information. The attribute information, channel identification information, the data transmission method according to claim 1 2 or 1 3 comprising at least one of the transfer information and network management information. The pulse signal light output from the predetermined output port of the light separation device (66) according to the frequency of the tone signal carrying the attribute information of the pulse signal light output from the predetermined output port of the light separation device (66). 15. The data transmission method according to claim 14, wherein it is identified whether or not the signal light of the predetermined channel.

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