JP2004048583A - Optical multiplex transmission equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide optical multiplex transmission equipment simultaneously performing data transmission by use of wavelength routing and multicast transmission of a carrier-wave modulation signal with a low cost. <P>SOLUTION: A data optical transmitter 101 converts each digital data signal D1, D2 into an optical packet having the wavelength corresponding to each transmission destination. An RF optical transmitter 102 converts a carrier-wave modulation signal DX into an RF optical signal of wide spectrum. A multiplexer 103 multiplexes the optical packet and the RF optical signal. The optical packet having a first wavelength and a portion of RF optical signal are output from an output terminal P1 of an optical routing section 105, and these optical signals are branched into a plurality of signals after being amplified. A first optical receiver 1061 converts the optical signal after branched into an electric signal again, and demultiplexes the electric signal into a signal D1 and a signal DX. A DG detector 10613 detects a time variation (DG amount) of the amplitude of the signal D1. The data optical transmitter 101 and the RF optical transmitter 102 control the output optical signal power, based on the detected DG amount. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an optical multiplex transmission apparatus for multiplexing a digital data signal and a carrier modulation signal and optically transmitting the multiplexed signal, and more particularly to an apparatus for multiplexing digital information generated in a burst such as a packet signal.
[0002]
[Prior art]
FIG. 11 is a block diagram showing an example of a configuration of a conventional optical multiplex transmission device. In FIG. 11, the optical multiplex transmission apparatus includes a data optical transmission unit 1001, an RF optical transmission unit 1002, a multiplexing unit 1003, an optical transmission unit 1004, an optical routing unit 1005, and a first optical reception unit 10061. And a second optical receiver 10062. The data light transmission unit 1001 includes an address extraction unit 10011, a wavelength tunable light source 10012, and a light modulation unit 10013. The RF light transmitter 1002 includes a broad spectrum light source 10021. The first optical receiving unit 10061 includes a first optical detecting unit 100611 and a first separating unit 100612, and the second optical receiving unit 10061 includes a second optical detecting unit 100621 and a second separating unit 100612. Unit 100622. FIG. 12 is a diagram for explaining signals of respective units in the optical multiplex transmission device. FIG. 13 is a diagram for explaining the relationship between the transmission characteristics (wavelength dependence) of the optical routing unit 1005 and the wavelengths set in the data optical transmission unit 1001 and the RF optical transmission unit 1002.
[0003]
The operation of the conventional optical multiplex transmission apparatus configured as described above will be described. As shown in FIG. 12A, a digital data signal divided into packet units is input to the data optical transmission unit 1001. Each packet includes address information (AD1 or AD2) indicating the destination of the packet. Hereinafter, the digital data signal corresponding to the address information AD1 is called D1, and the digital data signal corresponding to the address information AD2 is called D2. The address extracting unit 10011 extracts address information of each packet from the input digital data signals D1 and D2. As shown in FIG. 12B, the variable wavelength light source 10012 outputs light having a wavelength (L1 or L2) uniquely corresponding to the address information output from the address extraction unit 10011. The light modulation unit 10013 modulates the intensity of the light output from the variable wavelength light source 10012 based on the digital data signals D1 and D2, and outputs a data optical signal. Hereinafter, the data optical signal output from the data optical transmission unit 1001 is referred to as an optical packet.
[0004]
The RF light transmitting unit 1002 outputs an RF light signal by modulating the output light of the broad spectrum light source 10021 based on the input carrier modulation signal DX. The multiplexing unit 1003 multiplexes the optical packet output from the data optical transmission unit 1001 and the RF optical signal output from the RF optical transmission unit 1002, and outputs the multiplexed signal. The optical transmission unit 1004 transmits the optical signal output from the multiplexing unit 1003.
[0005]
The optical routing unit 1005 has a plurality of (two in FIG. 11) output terminals, and outputs the input light while switching the output terminals according to the wavelength of the input light. Further, as shown in FIG. 13B, the optical routing unit 1005 has a transmission characteristic having periodicity with respect to the wavelength of light. That is, the optical routing unit 1005 has a property of transmitting light at predetermined wavelength intervals when the wavelength of light is sequentially changed. This wavelength interval is generally referred to as FSR (Free Spectral Range).
[0006]
The relationship between the FSR and the optical routing when the optical routing unit 1005 has two output terminals P1 and P2 will be described. As shown in FIG. 13B, in the transmission characteristics of the first output terminal P1 of the optical routing unit 1005, the first dominant wavelength L1 and the first dominant wavelength L1 separated from the first dominant wavelength L1 by an interval of FSR. At the sub-wavelength L1 ′, the transmittance increases. In the transmission characteristics of the second output terminal P2, at the second main wavelength L2 different from the first main wavelength L1, and at the second sub-wavelength L2 ′ separated from the second main wavelength L2 by an interval of FSR, The permeability increases. The wavelengths of the optical packets transmitted from the data optical transmitter 1001 to the first optical receiver 10061 and the second optical receiver 10062 are the first main wavelength L1 and the second main wavelength L1 of the optical routing unit 1005, respectively. It is set so as to coincide with the main wavelength L2. Further, as shown in FIGS. 13A and 13B, the optical spectrum width of the broad spectrum light source 10021 in the RF light transmitting unit 1002 is changed by the first sub-wavelength L1 ′ and the second sub-wavelength L1 ′ of the optical routing unit 1005. The wavelength is set so as to include the wavelength L2 ′ and not include the first main wavelength L1 and the second main wavelength L2. Further, the entire wavelength bandwidth of the optical packet output from the data optical transmission unit 1001 and the wavelength bandwidth of the RF optical signal output from the RF optical transmission unit 1002 substantially match the FSR of the optical routing unit 1005. Is set to
[0007]
As a result, the first output terminal P1 outputs an optical packet going to the first optical receiving unit 10061 and a part of the RF optical signal (see FIG. 12C and FIG. 13C). From the second output terminal P2, an optical packet going to the second optical receiver 10062 and a part of the RF optical signal are output (see FIG. 12D and FIG. 13C). The optical signal output from the first output terminal P1 of the optical routing unit 1005 is input to the first optical receiving unit 10061. In the first optical receiving section 10061, the first optical detecting section 100611 re-converts the input optical signal into an electric signal, and the first separating section 100612 converts the obtained electric signal into a digital data signal D1. It separates and outputs the carrier modulation signal DX. Similarly, the optical signal output from the second output terminal P2 of the optical routing unit 1005 is input to the second optical receiving unit 10062. In the second optical receiving unit 10062, the second optical detection unit 100621 reconverts the input optical signal into an electric signal, and the second separating unit 100622 converts the obtained electric signal into a digital data signal D2. It separates and outputs the carrier modulation signal DX.
[0008]
Regarding the optical multiplex transmission apparatus as described above, P. Iannone, N.M. J. Frigo, K .; C. Richmann, "A repeated region / WDM local access network for delivery of broadcastcast digital TV", OFC'99 Technical Digest, 1999, p. 324-325. And other documents provide a detailed explanation. This optical multiplex transmission apparatus uses the wavelength of an optical packet for digital data signal transmission as an address indicating a packet transmission destination, and performs optical routing for switching an output destination according to the wavelength of input light, thereby achieving optical routing. High-speed and autonomous route switching. Further, this optical multiplex transmission apparatus modulates light having a broadband spectrum based on a carrier modulation signal and performs multiplex transmission, thereby transmitting the same optical signal to all transmission destinations from all output terminals of the optical routing unit. Output to This makes it possible to provide a high-speed data communication service and a broadcasting service such as a video signal or a broadcast service in one system.
[0009]
[Problems to be solved by the invention]
However, the conventional optical multiplex transmission apparatus as described above has the following specific problem regarding the number of optical subscribers that can be accommodated (corresponding to the number of optical receiving units in FIG. 11). That is, in an optical transmission system, the wavelength bandwidth that can be handled is limited due to the performance of an optical fiber or an optical device used, particularly an active device such as an optical amplifier. For example, the operating wavelength bandwidth of a general erbium-doped fiber amplifier (EDFA: Erbium Doped Fiber Amplifier) is about 30 to 40 nm. On the other hand, the number of wavelengths that can be multiplexed by a wavelength division multiplexing (WDM) technique within a certain wavelength band is finite due to the manufacturing accuracy of a WDM coupler or an optical filter. Therefore, in the optical multiplex transmission apparatus using the wavelength routing shown in FIG. 11, the number of optical receivers that can be connected to the optical router is equal to the number of wavelengths that can be handled by the apparatus and is limited to a predetermined value or less. On the other hand, from the economical point of view of the optical subscriber system, as the number of subscribers accommodated in the system increases, the cost dividing effect by sharing the station equipment and the installed fiber increases, which is advantageous. However, in an optical subscriber system using wavelength routing, the number of wavelengths that can be handled by the system is limited, so that the number of optical subscribers that can be accommodated is limited, and the cost-cutting effect is not sufficiently exhibited.
[0010]
As described above, the conventional optical multiplex transmission apparatus has a unique feature that, when realizing a high-speed data communication service by wavelength routing, the number of optical subscribers is limited, and the cost reduction of the system is limited. There's a problem.
[0011]
Therefore, an object of the present invention is to provide a high-speed data communication service by wavelength routing and a broadcasting service (or a broadcast service) to more subscribers, thereby realizing an economical optical subscriber system. That is.
[0012]
Means for Solving the Problems and Effects of the Invention
A first invention is an optical multiplex transmission apparatus for transmitting a digital data signal to a selected destination and transmitting a carrier modulation signal to all destinations,
A data light for selecting a wavelength corresponding to each transmission destination from a predetermined first wavelength band, modulating light having the selected wavelength based on a digital data signal to be transmitted to the transmission destination, and outputting as a data optical signal A transmission unit;
An RF light transmitting unit that modulates light occupying a predetermined second wavelength band that does not overlap with the first wavelength band based on a carrier modulation signal, and outputs the modulated light as an RF light signal;
A multiplexing unit that combines and outputs the data optical signal output from the data optical transmission unit and the RF optical signal output from the RF optical transmission unit;
An optical transmission unit that transmits an optical signal output from the multiplexing unit,
In the transmission characteristics of each output terminal, a periodicity (FSR: Free Spectral Range) substantially matching the difference between the center wavelength of the first wavelength band and the center wavelength of the second wavelength band is provided in the transmission characteristics of each output terminal. Appears and separates the data optical signal transmitted by the optical transmission unit for each wavelength corresponding to each destination, splits the RF optical signal transmitted by the optical transmission unit into a plurality, and outputs the optical signal from each output terminal. A routing unit,
An optical amplification unit that amplifies the optical signal output from the optical routing unit,
An optical branching unit that further branches the optical signal amplified by the optical amplifying unit into a plurality,
An optical receiving unit that receives the optical signal branched by the optical branching unit, and separates and outputs a digital data signal and a carrier modulation signal based on the received optical signal,
The relative magnitude of the power of the data optical signal and the power of the RF optical signal input to the optical amplifier is determined based on the reception quality in the optical receiver.
According to the first aspect, by performing optical routing using the wavelength of the data optical signal as an address, the digital data signal is transmitted to only predetermined optical subscribers, and at the same time, the light source of a wide spectrum band is used. By distributing the same RF optical signal to all optical subscribers and amplifying and branching the optical signal after optical routing, a super multi-branch optical subscriber network can be realized. . Also, by determining the relative magnitudes of the powers of the data optical signal and the RF optical signal input to the optical amplifying unit based on the reception quality in the optical receiving unit, the digital data signal and the carrier wave output from the optical receiving unit are determined. The quality of the modulated signal can be suitably controlled. Therefore, even when an optical signal is amplified and branched after optical routing, high-quality optical signal transmission can be performed, so that the number of optical subscribers that can be accommodated is increased and a low-cost optical subscriber system is provided. Can be.
[0013]
According to a second aspect of the present invention, in the first aspect, the RF input to the optical amplifying section is set such that a temporal change (DG: Differential Gain) of the amplitude of the digital data signal output from the optical receiving section becomes smaller than a predetermined value. The power of the optical signal is controlled to be high and / or the power of the data optical signal input to the optical amplifier is controlled to be low.
[0014]
In a third aspect based on the second aspect, a DG detecting section for detecting a DG amount of the digital data signal output from the optical receiving section;
A quality information transmission unit that transmits the DG amount detected by the DG detection unit to at least one of the data light transmission unit and the RF light transmission unit;
At least one of the data light transmitting unit and the RF light transmitting unit controls the power of the output optical signal based on the DG amount transmitted by the quality information transmitting unit.
According to the second and third aspects, the DG of the digital data signal output from the optical receiver is detected, and the level of the optical signal output from each optical transmitter is adjusted based on the detected DG amount. By doing so, it is possible to control the power of the RF optical signal input to each optical amplifying unit to be large and / or the power of the data optical signal to be small so that the DG of the digital data signal becomes smaller than a predetermined value. As a result, high-quality optical signals can be transmitted even when the optical signals are amplified and branched after optical routing, so that the number of optical subscribers that can be accommodated is increased, and a low-cost optical subscriber system is provided. be able to.
[0015]
In a fourth aspect based on the first aspect, the power of the RF optical signal input to the optical amplifying section is large so that the waveform distortion of the carrier modulation signal output from the optical receiving section is smaller than a predetermined value, and / or Alternatively, the power of the data optical signal input to the optical amplifier is controlled to be small.
[0016]
In a fifth aspect based on the fourth aspect, a distortion detector for detecting a waveform distortion amount of the carrier modulation signal output from the optical receiver,
A quality information transmission unit that transmits the waveform distortion amount detected by the distortion detection unit to at least one of the data light transmission unit and the RF light transmission unit;
At least one of the data light transmitter and the RF light transmitter controls the power of the output optical signal based on the waveform distortion transmitted by the quality information transmitter.
According to the fourth and fifth aspects, the waveform distortion of the carrier modulation signal output from the optical receiver is detected, and the optical signal output from each optical transmitter is detected based on the detected waveform distortion. By adjusting the level, the power of the RF optical signal input to each optical amplifier is increased and / or the power of the data optical signal is reduced so that the waveform distortion amount of the carrier modulation signal becomes smaller than a predetermined value. can do. As a result, high-quality optical signals can be transmitted even when the optical signals are amplified and branched after optical routing, so that the number of optical subscribers that can be accommodated is increased, and a low-cost optical subscriber system is provided. be able to.
[0017]
In a sixth aspect based on the first aspect, the DG of the digital data signal output from the optical receiving section is smaller than a first predetermined value, and the waveform distortion of the carrier modulation signal output from the optical receiving section is the second level. The power of the RF optical signal input to the optical amplifier and / or the power of the data optical signal input to the optical amplifier are controlled so as to be smaller than the predetermined value of 2.
[0018]
In a seventh aspect based on the sixth aspect, the reception quality detection section detects a DG amount of the digital data signal output from the optical reception section and a waveform distortion amount of the carrier modulation signal output from the optical reception section. ,
A quality information transmission unit that transmits the DG amount and the waveform distortion amount detected by the reception quality detection unit to at least one of the data light transmission unit and the RF light transmission unit;
At least one of the data light transmission unit and the RF light transmission unit controls the power of the output optical signal based on the DG amount and the waveform distortion amount transmitted by the quality information transmission unit.
According to the sixth and seventh aspects, the DG of the digital data signal output from the optical receiving unit and the waveform distortion amount of the carrier modulation signal output from the optical receiving unit are detected, and the detected DG is detected. By adjusting the level of the optical signal output from each optical transmission unit based on the amount and the waveform distortion amount, each of the DG of the digital data signal and the waveform distortion of the carrier modulation signal becomes smaller than a predetermined value. The power of the RF optical signal input to the optical amplifier can be controlled to be large and / or the power of the data optical signal can be controlled to be small. As a result, high-quality optical signals can be transmitted even when the optical signals are amplified and branched after optical routing, so that the number of optical subscribers that can be accommodated is increased, and a low-cost optical subscriber system is provided. be able to.
[0019]
In an eighth aspect based on the first aspect, the signal is input to the optical amplifier such that the signal-to-noise level ratio (SNR) of the digital data signal output from the optical receiver is greater than a predetermined value. The power of the RF optical signal to be transmitted is controlled to be small, and / or the power of the data optical signal input to the optical amplifier is controlled to be large.
[0020]
In a ninth aspect based on the eighth aspect, the SNR detecting section detects an SNR amount of the digital data signal output from the optical receiving section;
A quality information transmission unit that transmits the SNR amount detected by the SNR detection unit to at least one of the data light transmission unit and the RF light transmission unit;
At least one of the data light transmitting unit and the RF light transmitting unit controls the power of the output optical signal based on the SNR amount transmitted by the quality information transmitting unit.
According to the eighth and ninth aspects, the SNR of the digital data signal output from the optical receiver is detected, and the level of the optical signal output from each optical transmitter is adjusted based on the detected SNR amount. By doing so, it is possible to control the power of the RF optical signal input to each optical amplifying unit to be small and / or to increase the power of the data optical signal so that the SNR of the digital data signal becomes larger than a predetermined value. As a result, high-quality optical signals can be transmitted even when the optical signals are amplified and branched after optical routing, so that the number of optical subscribers that can be accommodated is increased, and a low-cost optical subscriber system is provided. be able to.
[0021]
In a tenth aspect based on the first aspect, the SNR of the digital data signal output from the optical receiver is greater than a first predetermined value, and the DG of the digital data signal is smaller than a second predetermined value. As described above, the power of the data optical signal input to the optical amplifier and / or the power of the RF optical signal input to the optical amplifier is controlled.
[0022]
According to an eleventh aspect based on the tenth aspect, the digital signal quality detection unit detects an SNR amount and a DG amount of the digital data signal output from the optical receiving unit;
A quality information transmission unit that transmits the SNR amount and the DG amount detected by the digital signal quality detection unit to at least one of the data light transmission unit and the RF light transmission unit;
At least one of the data light transmission unit and the RF light transmission unit controls the power of the output optical signal based on the SNR amount and the DG amount transmitted by the quality information transmission unit.
According to the tenth and eleventh aspects, the SNR and DG of the digital data signal output from the optical receiving unit are detected, and the digital data signal is output from each optical transmitting unit based on the detected SNR amount and DG amount. By adjusting the level of the optical signal, the signal is input to each optical amplifying unit such that the SNR of the digital data signal is larger than the first predetermined value and the DG of the digital data signal is smaller than the second predetermined value. The power of the RF optical signal and / or the power of the RF optical signal input to the optical amplifier can be controlled to be small. As a result, high-quality optical signals can be transmitted even when the optical signals are amplified and branched after optical routing, so that the number of optical subscribers that can be accommodated is increased, and a low-cost optical subscriber system is provided. be able to.
[0023]
In a twelfth aspect based on the first aspect, the power of the RF optical signal input to the optical amplifying unit is small so that the power of the data optical signal received by the optical receiving unit is larger than a predetermined value, and / or It is characterized in that the power of the data optical signal input to the optical amplifier is largely controlled.
[0024]
According to a thirteenth aspect, in the twelfth aspect, an optical power detection unit that detects an amount of power of the data optical signal received by the optical reception unit,
A quality information transmission unit that transmits the amount of power detected by the optical power detection unit to at least one of the data light transmission unit and the RF light transmission unit;
At least one of the data light transmitting unit and the RF light transmitting unit controls the power of the output optical signal based on the amount of power transmitted by the quality information transmitting unit.
According to the twelfth and thirteenth aspects, the power of the data optical signal received by the optical receiving unit is detected, and the level of the optical signal output from each optical transmitting unit is adjusted based on the detected amount of power. This makes it possible to control the power of the RF optical signal input to each optical amplifying unit to be smaller and / or to increase the power of the data optical signal so that the output of the data optical signal becomes larger than a predetermined value. As a result, high-quality optical signals can be transmitted even when the optical signals are amplified and branched after optical routing, so that the number of optical subscribers that can be accommodated is increased, and a low-cost optical subscriber system is provided. be able to.
[0025]
In a fourteenth aspect based on the first aspect, the power of the data optical signal received by the optical receiver is greater than a first predetermined value, and the DG of the digital data signal output from the optical receiver is equal to the second power. The power of the data optical signal input to the optical amplifier and / or the power of the RF optical signal input to the optical amplifier are controlled so as to be smaller than the predetermined value.
[0026]
In a fifteenth aspect based on the fourteenth aspect, an optical power detection unit that detects the power amount of the data optical signal received by the optical reception unit,
A DG detection unit that detects a DG amount of the digital data signal output from the optical reception unit;
A quality information transmission unit that transmits the power amount detected by the optical power detection unit and the DG amount detected by the DG detection unit to at least one of the data light transmission unit and the RF light transmission unit;
At least one of the data light transmitting unit and the RF light transmitting unit controls the power of the output optical signal based on the amount of power and the amount of DG transmitted by the quality information transmitting unit.
According to the fourteenth and fifteenth aspects, the power of the data optical signal received by the optical receiver and the DG of the digital data signal output from the optical receiver are detected, and the detected power amount and DG By adjusting the level of the optical signal output from each optical transmission unit based on the amount, the power of the data optical signal received by the optical reception unit is larger than the first predetermined value, and the power output from the optical reception unit Controlling the power of the data optical signal input to the optical amplifier and / or the power of the RF optical signal input to the optical amplifier so that the DG of the digital data signal becomes smaller than the second predetermined value. it can. As a result, high-quality optical signals can be transmitted even when the optical signals are amplified and branched after optical routing, so that the number of optical subscribers that can be accommodated is increased, and a low-cost optical subscriber system is provided. be able to.
[0027]
In a sixteenth aspect based on the first aspect, the data light input to the optical amplifying section is set so that a bit error rate (BER) of the digital data signal output from the optical receiving section becomes smaller than a predetermined value. The power of the signal and / or the power of the RF optical signal to be input to the optical amplifier are controlled.
[0028]
In a seventeenth aspect based on the sixteenth aspect, a BER detecting section for detecting a BER amount of the digital data signal output from the optical receiving section;
A quality information transmission unit that transmits the BER amount detected by the BER detection unit to at least one of the data light transmission unit and the RF light transmission unit;
At least one of the data light transmitting unit and the RF light transmitting unit controls the power of the output optical signal based on the BER amount transmitted by the quality information transmitting unit.
According to the sixteenth and seventeenth aspects, the BER of the digital data signal output from the optical receiver is detected, and the level of the optical signal output from the optical transmitter is adjusted based on the detected BER amount. Thus, the power of the data optical signal input to the optical amplifier and / or the power of the RF optical signal input to the optical amplifier can be controlled so that the BER of the digital data signal becomes smaller than a predetermined value. . As a result, high-quality optical signals can be transmitted even when the optical signals are amplified and branched after optical routing, so that the number of optical subscribers that can be accommodated is increased, and a low-cost optical subscriber system is provided. be able to.
[0029]
An eighteenth invention is characterized in that, in the first invention, the data optical signal is an optical signal having an intermittently generated burst property.
According to the eighteenth aspect, a large-capacity digital data signal can be transmitted more efficiently.
[0030]
In a nineteenth aspect based on the first aspect, the carrier modulation signal is obtained by modulating a plurality of carriers having predetermined different frequencies based on data corresponding to each carrier to obtain a plurality of modulation signals. It is a frequency multiplexed signal obtained by frequency multiplexing a signal.
According to the nineteenth aspect, a carrier modulation signal having a larger capacity can be transmitted.
[0031]
In a twentieth aspect based on the first aspect, the data optical signal is an optical signal having an intermittently generated burst property, and the carrier modulation signal includes a plurality of carrier waves having predetermined different frequencies. Is modulated based on data corresponding to each carrier to obtain a plurality of modulation signals, and is a frequency multiplexed signal obtained by frequency multiplexing the modulation signals.
According to the twentieth aspect, a large-capacity digital data signal can be transmitted more efficiently, and a larger-capacity carrier-modulated signal can be transmitted.
[0032]
According to a twenty-first aspect, in the first aspect, the bandwidth of the first wavelength band substantially matches the bandwidth of the second wavelength band.
According to the twenty-first aspect, it is possible to efficiently use an optical wavelength band and realize optical signal transmission to a large number of receiving terminals.
[0033]
According to a twenty-second aspect, in the first aspect, the bandwidth of the first wavelength band and / or the bandwidth of the second wavelength band is smaller than the FSR of the optical routing unit.
According to the twenty-second aspect, it is possible to avoid interference between the data optical signal and the RF optical signal, and realize higher quality optical signal transmission.
[0034]
According to a twenty-third aspect, in the first aspect, the bandwidth of the first wavelength band, the bandwidth of the second wavelength band, and the FSR of the optical routing unit substantially match.
According to the twenty-third aspect, by using the optical wavelength band efficiently and avoiding the interference between the data optical signal and the RF optical signal, a higher quality can be provided for a large number of receiving terminals. Optical signal transmission can be realized.
[0035]
In a twenty-fourth aspect based on the first aspect, the data light transmitting section includes, as a light source, a DBR (Distributed Bragg Reflector) laser, an SSG (Super Structure Grating) -DBR laser, an SG (Sampled-Grating) -DBR laser, And a GCSR (Grating Coupler Sampled Reflector) laser.
According to the twenty-fourth aspect, the entire wavelength bandwidth used for transmitting the data optical signal can be expanded, and the digital data signal can be transmitted to a greater number of receiving terminals.
[0036]
In a twenty-fifth aspect based on the first aspect, the RF light transmitting section uses a super luminescent diode as a light source.
According to a twenty-sixth aspect, in the first aspect, the RF light transmitting unit uses a light emitting diode as a light source.
According to a twenty-seventh aspect, in the first aspect, the RF light transmitting unit uses spontaneous emission light of an erbium-doped optical fiber amplifier as a light source.
According to the twenty-fifth to twenty-seventh aspects, the wavelength bandwidth used for transmitting the RF optical signal can be expanded, and the carrier modulation signal can be distributed to a greater number of receiving terminals.
[0037]
In a twenty-eighth aspect based on the first aspect, the RF light transmitting section includes a plurality of light sources, and multiplexes and outputs the output lights of the light sources.
According to the twenty-eighth aspect, it is possible to increase the power of the RF optical signal and distribute the carrier modulation signal to a greater number of receiving terminals.
[0038]
In a twenty-ninth aspect based on the first aspect, the optical routing unit includes an AWG (Arrayed Waveguide Grating).
According to the twenty-ninth aspect, it is possible to more efficiently use the optical wavelength band and realize optical signal transmission to a greater number of receiving terminals.
[0039]
BEST MODE FOR CARRYING OUT THE INVENTION
(1st Embodiment)
FIG. 1 is a block diagram showing a configuration of the optical multiplex transmission device according to the first embodiment of the present invention. In FIG. 1, the optical multiplex transmission apparatus according to the present embodiment includes a data optical transmission unit 101, an RF optical transmission unit 102, a multiplexing unit 103, an optical transmission unit 104, an optical routing unit 105, a first The optical amplifier 1071, the second optical amplifier 1072, the first optical splitter 1081, the second optical splitter 1082, the first optical receiver 1061, and the second optical receiver 1062 , And a quality information transmission unit 109. In addition, the data light transmission unit 101 includes an address extraction unit 1011, a variable wavelength light source 1012, and a light modulation unit 1013. The RF light transmitter 102 includes a broad spectrum light source 1021.
[0040]
The optical multiplex transmission apparatus shown in FIG. 1 includes a plurality of first optical receiving units 1061 and a plurality of second optical receiving units 1062. Each of the first optical receiving units 1061 and each of the second optical receiving units 1062 include an optical detecting unit and a separating unit. Further, at least one of the first optical receiving unit 1061 and the second optical receiving unit 1062 further includes a DG detecting unit. FIG. 1 shows an example in which one of the first optical receiving units 1061 includes an optical detection unit 10611, a separation unit 10612, and a DG detection unit 10613. However, in FIG. 1, for simplification of the drawing, one first optical receiving unit 1061 showing the internal configuration and one second optical receiving unit 1062 omitting the internal configuration are shown one by one, and other optical receiving units 1062 are shown. The description of the receiving unit is omitted.
[0041]
The signals of each section in the optical multiplex transmission device according to the present embodiment are the same as those in the conventional optical multiplex transmission device. Also, the relationship between the transmission characteristics (wavelength dependence) of the optical routing unit 105 and the set wavelengths of the data light transmitting unit 101 and the RF light transmitting unit 102 is the same as in the conventional optical multiplex transmission device. Therefore, hereinafter, the optical multiplex transmission apparatus according to the present embodiment will be described with reference to FIGS. 12 and 13 again.
[0042]
First, the operation of the optical multiplex transmission device shown in FIG. 1 will be described. As shown in FIG. 12A, a digital data signal divided into packet units is input to the data optical transmission unit 101. Each packet includes address information (AD1 or AD2) indicating the destination of the packet. Hereinafter, the digital data signal corresponding to the address information AD1 is called D1, and the digital data signal corresponding to the address information AD2 is called D2. The address extracting unit 1011 extracts address information of each packet from the input digital data signals D1 and D2. As shown in FIG. 12B, the variable wavelength light source 1012 outputs light having a wavelength (L1 or L2) uniquely corresponding to the address information output from the address extraction unit 1011. The light modulation unit 1013 modulates the intensity of the light output from the wavelength variable light source 1012 based on the digital data signals D1 and D2, and outputs a data optical signal. Hereinafter, the data optical signal output from the data optical transmission unit 101 is referred to as an optical packet.
[0043]
The RF light transmitter 102 outputs an RF light signal by modulating the output light of the broad spectrum light source 1021 based on the input carrier modulation signal DX. The multiplexing unit 103 multiplexes the optical packet output from the data optical transmission unit 101 and the RF optical signal output from the RF optical transmission unit 102 and outputs the multiplexed signal. The optical transmission unit 104 transmits the optical signal output from the multiplexing unit 103.
[0044]
The optical routing unit 105 has a plurality of (two in FIG. 1) output terminals, and outputs the input light while switching the output terminals according to the wavelength of the input light. Further, as shown in FIG. 13B, the optical routing unit 105 has a transmission characteristic having periodicity with respect to the optical wavelength. That is, the optical routing unit 105 has a property of transmitting light at predetermined wavelength intervals (FSR).
[0045]
The transmission characteristics of the first output terminal P1 of the optical routing unit 105 indicate that the first main wavelength L1 and the first sub-wavelength L1 ′ separated from the first main wavelength L1 by an interval of FSR are transparent. Get higher. In the transmission characteristics of the second output terminal P2, at the second main wavelength L2 different from the first main wavelength L1, and at the second sub-wavelength L2 ′ separated from the second main wavelength L2 by an interval of FSR, The permeability increases. The wavelengths of the optical packets transmitted from the data optical transmission unit 101 to the first optical reception unit 1061 and the second optical reception unit 1062 are the first main wavelength L1 and the second main wavelength L1 of the optical routing unit 105, respectively. It is set so as to coincide with the main wavelength L2. Also, as shown in FIGS. 13A and 13B, the optical spectrum width of the broad spectrum light source 1021 in the RF light transmission unit 102 is changed by the first sub-wavelength L1 ′ and the second sub-wavelength L1 ′ of the optical routing unit 105. The wavelength is set so as to include the wavelength L2 ′ and not include the first main wavelength L1 and the second main wavelength L2. Further, the entire wavelength bandwidth of the optical packet output from the data optical transmission unit 101 and the wavelength bandwidth of the RF optical signal output from the RF optical transmission unit 102 are smaller than the FSR of the optical routing unit 105 or the FSR Is set to substantially match From the above, the optical routing unit 105 indicates that the transmission characteristic of each output terminal is substantially equal to the difference between the center wavelength of the first wavelength band occupied by the optical packet and the center wavelength of the second wavelength band occupied by the RF optical signal. It has the characteristic that coincident periodicity (FSR) appears.
[0046]
As a result, the first output terminal P1 outputs an optical packet going to the first optical receiving unit 1061 and a part of the RF optical signal (see FIGS. 12C and 13C). From the second output terminal P2, an optical packet heading for the second optical receiver 1062 and a part of the RF optical signal are output (see FIGS. 12D and 13C). The first optical amplifier 1071 and the second optical amplifier 1072 are provided corresponding to the first output terminal P1 and the second output terminal P2 of the optical routing unit 105, respectively, and output from each output terminal. The amplified optical signals are amplified and output. The first optical splitter 1081 and the second optical splitter 1082 are provided corresponding to the first optical amplifier 1071 and the second optical amplifier 1072, respectively, and the light output from each optical amplifier is provided. The signal is branched into a plurality of signals and output. Note that the optical multiplex transmission apparatus shown in FIG. 1 does not need to include the first optical amplifier 1071 and the second optical amplifier 1072 unless it is necessary to amplify an optical signal.
[0047]
A plurality of first optical receiving units 1061 are provided corresponding to each of the plurality of optical signals branched by the first optical branching unit 1081 (FIG. 1 shows only one first optical receiving unit 1061). Shown). Each first optical receiving unit 1061 includes an optical detection unit and a separation unit, as described above. The first optical receiver 1061 shown in FIG. 1 will be described. The optical detector 10611 reconverts the optical signal output from the first optical splitter 1081 into an electric signal. Separating section 10612 separates digital data signal D1 and carrier modulation signal DX from the electric signal output from optical detection section 10611, and outputs the separated signal. The optical detection unit and the separation unit included in the first optical reception unit 1061 omitted in FIG. 1 operate similarly.
[0048]
Similarly, a plurality of second optical receiving units 1062 are provided for each of the plurality of optical signals branched by the second optical branching unit 1082 (in FIG. 1, the second optical receiving unit 1062 is one Only one is shown). Each second optical receiving unit 1062 includes an optical detection unit and a separation unit as described above. Each second optical receiving unit 1062 reconverts the optical signal output from the second optical branching unit 1082 into an electric signal similarly to the first optical receiving unit 1061, and converts the digital data signal D2 and the carrier modulation signal. And DX.
[0049]
The DG detection unit 10613 included in the first optical reception unit 1061 detects the amount of waveform distortion of the digital data signal D1 output from the separation unit 10612, that is, the amount of DG (Differential Gain). The quality information transmission unit 109 transmits the DG amount detected by the DG detection unit 10613 to the data light transmission unit 101 and / or the RF light transmission unit 102. The data light transmitting unit 101 and / or the RF light transmitting unit 102, having received the DG amount transmitted by the quality information transmitting unit 109, adjust the transmission level of the optical signal output from each of them based on the received DG amount. In other words, the quality information transmission unit 109 transmits the DG amount detected by the DG detection unit 10613 to at least one of the data light transmission unit 101 and the RF light transmission unit 102, and transmits the data light transmission unit 101 and the RF light transmission unit At least one of 102 controls the power of the output optical signal based on the received DG amount.
[0050]
In FIG. 1, the DG detecting unit is included in one of the first optical receiving units 1061. However, one of the first optical receiving unit 1061 and the second optical receiving unit 1062 has one DG detecting unit. It is sufficient if at least one is included. The DG detection unit included in the second optical reception unit 1062 detects the DG amount of the digital data signal D2 output from the separation unit included in the second optical reception unit 1062. When two or more DG detection units are included in the optical multiplex transmission device, the quality information transmission unit 109 transmits the detected plurality of DG amounts to the data light transmission unit 101 and / or the RF light transmission unit. Transmit to 102. In this case, the data light transmitting unit 101 and / or the RF light transmitting unit 102 that has received the plurality of DG amounts adjusts the transmission level of the optical signal output from each, based on the received plurality of DG amounts. For example, the data light transmitting unit 101 and / or the RF light transmitting unit 102 calculates an average value, a maximum value, and the like of a plurality of received DG amounts, and adjusts a transmission level of an output optical signal based on the obtained values. Is also good.
[0051]
Next, transmission quality of optical signals input to the first optical receiving unit 1061 and the second optical receiving unit 1062 will be described. The optical packets output from the two output terminals P1 and P2 of the optical routing unit 105 become intermittently generated bursty optical signals as a result of the wavelength routing, and the first optical amplifier 1071 and the second optical amplifier 1072 To the optical amplifying unit 1072. On the other hand, the RF optical signal created based on the broad spectrum light source 1021 is always output from all the output terminals of the optical routing unit 105, and becomes a continuous optical signal as the first optical amplifier 1071 and the second optical amplifier. 1072.
[0052]
The first optical amplifier 1071 and the second optical amplifier 1072 are typically configured by an optical fiber amplifier. However, when each optical amplifying unit is configured using an optical fiber amplifier, distortion occurs in the output signal of each optical amplifying unit as described below. With reference to FIG. 2, a description will be given of distortion generated in an output signal of an optical amplifier configured using an optical fiber amplifier. FIG. 2A is a diagram illustrating a waveform of an optical packet output from the optical fiber amplifier, and FIG. 2B is a diagram illustrating a waveform of the optical packet and the RF optical signal output from the optical fiber amplifier. is there.
[0053]
When an intermittent optical signal such as an optical packet is input to the optical fiber amplifier, the transient response characteristic of the optical fiber amplifier is moderate (on the order of microseconds). As described above, the amplitude of the output optical signal changes with time, and the waveform of the optical packet deteriorates. Further, when a plurality of optical signals having different wavelengths are simultaneously input to the optical fiber amplifier, a competition phenomenon of the gain of the optical fiber amplifier occurs between the plurality of optical signals. For this reason, when an optical packet that is an intermittent optical signal and an RF optical signal that is a continuous optical signal are simultaneously input to the optical fiber amplifier, as shown in FIG. At the same time, the amplitude of the output RF optical signal fluctuates, and the signal quality deteriorates. In order to prevent such signal quality deterioration, a predetermined optical power difference is set between an optical packet input to the first optical amplifier 1071 and the second optical amplifier 1072 and an RF optical signal. Is required.
[0054]
FIG. 3A shows the RF light based on the waveform distortion DG (vertical axis) of the optical packet (digital data signal) output from the optical fiber amplifier and the optical power of the optical packet input to the optical fiber amplifier. FIG. 4 is a diagram illustrating a relationship between a signal and a relative optical power (horizontal axis). When the amplitude of the optical signal at the head position of the optical packet is A and the attenuation of the amplitude of the optical signal is B (see FIG. 3B), the waveform distortion DG is defined by the following equation (1). Is done.
DG = B / A × 100 [%] (1)
[0055]
According to FIG. 3A, the waveform distortion amount DG decreases as the relative optical power of the RF optical signal increases. Therefore, the waveform distortion DG can be reduced by increasing the relative power of the RF optical signal. In other words, in order to make the waveform distortion amount DG smaller than the predetermined reference value, the relative power of the RF optical signal may be set to a certain value or more. The optical multiplex transmission device according to the present embodiment controls the power of the optical signal output from the data optical transmission unit 101 and / or the RF optical transmission unit 102 based on the waveform distortion amount DG obtained by the DG detection unit 10613. Thereby, the power of the RF optical signal input to each optical amplifier is controlled to be large and / or the power of the optical packet input to each optical amplifier is controlled to be small so that the waveform distortion amount DG becomes smaller than a predetermined value. be able to.
[0056]
As described above, according to the optical multiplex transmission apparatus according to the present embodiment, by performing path switching (optical routing) in the optical domain using the wavelength of the data optical signal as an address, an optical packet can be transmitted only to a predetermined optical subscriber. At the same time, the same RF optical signal is distributed to all optical subscribers by using a light source of a broad spectrum band, and the optical signal after optical routing is amplified and branched, so that the A multi-branch optical subscriber network can be realized. Furthermore, according to the optical multiplex transmission apparatus according to the present embodiment, the optical receiving unit detects the waveform distortion amount DG of the digital data signal, and based on the detected DG amount, changes the level of the optical signal output from each optical transmitting unit. By performing the adjustment, the power of the RF optical signal input to each optical amplifier and / or the power of the optical packet can be controlled so that the DG of the digital data signal becomes smaller than a predetermined value. As a result, high-quality optical signals can be transmitted even when the optical signals are amplified and branched after optical routing, so that the number of optical subscribers that can be accommodated is increased, and a low-cost optical subscriber system is provided. be able to.
[0057]
(Second embodiment)
FIG. 4 is a block diagram showing the configuration of the optical multiplex transmission device according to the second embodiment of the present invention. In FIG. 4, the optical multiplex transmission apparatus according to the present embodiment includes a data light transmission unit 101, an RF light transmission unit 102, a multiplexing unit 103, an optical transmission unit 104, an optical routing unit 105, a first The optical amplifier 1071, the second optical amplifier 1072, the first optical splitter 1081, the second optical splitter 1082, the first optical receiver 4061, and the second optical receiver 4062 , And a quality information transmission unit 109. This optical multiplex transmission apparatus is different from the optical multiplex transmission apparatus according to the first embodiment in that the first optical receiving unit 1061 and the second optical receiving unit 1062 are respectively replaced with the first optical receiving unit 4061 and the second optical receiving unit 4061. The light receiving unit 4062 is replaced.
[0058]
The optical multiplex transmission device illustrated in FIG. 4 includes a plurality of first optical receiving units 4061 and a plurality of second optical receiving units 4062. Each of the first optical receiving units 4061 and each of the second optical receiving units 4062 include an optical detection unit and a separation unit. Further, at least one of the first optical receiving unit 4061 and the second optical receiving unit 4062 further includes a distortion detecting unit. FIG. 4 illustrates an example in which one of the first optical receiving units 4061 includes an optical detection unit 10611, a separation unit 10612, and a distortion detection unit 40614. In FIG. 4, the same omission as in FIG. 1 is performed. In the following, among the components of the present embodiment, the components having the same functions as those of the first embodiment will be denoted by the same reference numerals and the description thereof will be simplified, and the differences from the first embodiment will be described. This will be mainly described.
[0059]
In the first embodiment, the power of the optical packet and the RF optical signal input to the first optical amplifier 1071 and the second optical amplifier 1072 is determined based on the waveform distortion DG detected by the DG detector 10613. By controlling so as to satisfy a predetermined condition, the quality degradation of the optical signal generated at the time of optical amplification is suppressed. On the other hand, in the present embodiment, instead of the waveform distortion amount DG of the digital data signal D1, the waveform distortion amount DUR (Desired / Undesired Ratio) of the carrier modulation signal is used as an amount representing the waveform distortion of the carrier modulation signal DX. The power of the optical signal is controlled based on the detected DUR amount. More specifically, distortion detecting section 40614 included in first optical receiving section 4061 detects the DUR amount of the carrier modulation signal output from demultiplexing section 10612. The quality information transmission unit 109 transmits the DUR amount detected by the distortion detection unit 40614 to at least one of the data light transmission unit 101 and the RF light transmission unit 102. At least one of the data light transmitter 101 and the RF light transmitter 102 controls the power of the output optical signal based on the received DUR amount. Note that the first optical receiving unit 4061 and the second optical receiving unit 4062 that do not include the distortion detecting unit operate in the same manner as the optical receiving unit that includes the distortion detecting unit except that the amount of waveform distortion DUR is not detected.
[0060]
FIG. 5 shows the waveform distortion DUR (vertical axis) of the RF optical signal (carrier modulated signal) output from the optical fiber amplifier and the optical power of the RF packet based on the optical power of the optical packet input to the optical fiber amplifier. It is a figure which shows the relationship with relative optical power (horizontal axis). The waveform distortion amount DUR is defined by a relative power value [dBc] of an unnecessary component with reference to a carrier level of a carrier modulation signal reproduced by optical detection (square detection) of an RF optical signal.
[0061]
According to FIG. 5, the waveform distortion amount DUR decreases as the relative optical power of the RF optical signal increases. Therefore, if the relative power of the RF optical signal is increased, the amount of waveform distortion DUR can be reduced. In other words, in order to make the waveform distortion amount DUR smaller than the predetermined reference value, the relative power of the RF optical signal may be set to a certain value or more. The optical multiplex transmission apparatus according to the present embodiment controls the power of the optical signal output from the data optical transmission unit 101 and / or the RF optical transmission unit 102 based on the waveform distortion amount DUR obtained by the distortion detection unit 40614. Thereby, the power of the RF optical signal input to each optical amplifier is controlled to be large and / or the power of the optical packet input to each optical amplifier is controlled to be small so that the waveform distortion amount DUR becomes smaller than a predetermined value. be able to.
[0062]
As described above, according to the optical multiplex transmission apparatus according to the present embodiment, the optical receiving unit detects the waveform distortion amount DUR of the carrier modulation signal, and outputs the optical signal output from each optical transmitting unit based on the detected DUR amount. By controlling the level of the RF signal, the power of the RF optical signal input to each optical amplifier and / or the power of the optical packet can be controlled so that the DUR of the carrier modulation signal becomes smaller than a predetermined value. it can. As a result, high-quality optical signals can be transmitted even when the optical signals are amplified and branched after optical routing, so that the number of optical subscribers that can be accommodated is increased, and a low-cost optical subscriber system is provided. be able to.
[0063]
In the present embodiment, the level of the optical signal output from each optical transmitter is adjusted based on the detected DUR amount. However, the waveform distortion DG of the digital data signal and the waveform distortion DUR of the carrier modulation signal are adjusted. May be detected, and the level of the optical signal output from each optical transmission unit may be adjusted based on the detected DG amount and DUR amount. The optical multiplex transmission apparatus according to the modification of the present embodiment is configured such that the DG of the digital data signal is smaller than the first predetermined value and the DUR of the carrier modulation signal is smaller than the second predetermined value. The power of the RF optical signal input to each optical amplifier is controlled to be large and / or the power of the optical packet is controlled to be small.
[0064]
(Third embodiment)
FIG. 6 is a block diagram illustrating a configuration of an optical multiplex transmission device according to the third embodiment of the present invention. In FIG. 6, the optical multiplex transmission apparatus according to the present embodiment includes a data optical transmission unit 101, an RF optical transmission unit 102, a multiplexing unit 103, an optical transmission unit 104, an optical routing unit 105, a first The optical amplifier 1071, the second optical amplifier 1072, the first optical splitter 1081, the second optical splitter 1082, the first optical receiver 5061, and the second optical receiver 5062 , And a quality information transmission unit 109. This optical multiplex transmission apparatus is different from the optical multiplex transmission apparatus according to the first embodiment in that a first optical receiving unit 1061 and a second optical receiving unit 1062 are respectively replaced by a first optical receiving unit 5061 and a second optical receiving unit 5061. The optical receiver 5062 is replaced.
[0065]
The optical multiplex transmission apparatus shown in FIG. 6 includes a plurality of first optical receiving units 5061 and a plurality of second optical receiving units 5062. Each of the first optical receiving units 5061 and each of the second optical receiving units 5062 include an optical detection unit and a separation unit. At least one of the first optical receiving unit 5061 and the second optical receiving unit 5062 further includes an overall quality detecting unit. FIG. 6 shows an example in which one of the first optical receiving units 5061 includes an optical detecting unit 10611, a separating unit 10612, and an overall quality detecting unit 50615. FIG. 6 is omitted from FIG. In the following, among the components of the present embodiment, the components having the same functions as those of the first embodiment will be denoted by the same reference numerals and the description thereof will be simplified, and the differences from the first embodiment will be described. This will be mainly described.
[0066]
In the first embodiment, the power of the optical packet and the RF optical signal input to the first optical amplifier 1071 and the second optical amplifier 1072 is determined based on the waveform distortion DG detected by the DG detector 10613. By controlling so as to satisfy a predetermined condition, the quality degradation of the optical signal generated at the time of optical amplification is suppressed. However, as shown in FIG. 7, when the power of the RF optical signal input to the optical fiber amplifier is increased (relative to the power of the optical packet), the DG of the digital data signal is improved, while the digital data signal is improved. The signal-to-noise level ratio SNR (Signal to Noise Ratio) deteriorates. Since the bit error rate (BER), which is the overall quality of a digital data signal, is determined by both DG and SNR, a good BER can be obtained in an environment where the SNR is excessively deteriorated even if the DG is improved. Can not.
[0067]
Therefore, the present embodiment is characterized in that the power of an optical signal is controlled based on both DG and SNR. More specifically, the total quality detection unit 50615 included in the first optical reception unit 5061 includes a signal-to-noise ratio of the digital data signal D1 in addition to the waveform distortion amount DG of the digital data signal D1 output from the separation unit 10612. The level ratio SNR is detected. The quality information transmitting unit 109 transmits the DG amount and the SNR amount detected by the total quality detecting unit 50615 to at least one of the data light transmitting unit 101 and the RF light transmitting unit 102. At least one of the data light transmitter 101 and the RF light transmitter 102 adjusts the SNR of the digital data signal D1 from the first predetermined value based on the received DG amount and the SNR amount in order to improve the BER of the digital data signal. The power of the output optical signal is controlled so as to be large and the DG of the digital data signal becomes smaller than the second predetermined value. Note that the first optical receiving unit 5061 and the second optical receiving unit 5062 that do not include the overall quality detecting unit are the same as the optical receiving unit that includes the overall quality detecting unit except that they do not detect the DG amount and the SNR amount. Operate.
[0068]
As described above, according to the optical multiplex transmission apparatus of the present embodiment, the optical receiver detects the waveform distortion amount DG of the digital data signal and the signal-to-noise level ratio SNR of the digital data signal, and detects the detected DG amount. By adjusting the level of the optical signal output from each optical transmission unit based on the SNR and the SNR amount, the power of the optical packet input to each optical amplification unit and / or the RF optical signal input to each optical amplification unit Can be appropriately controlled. As a result, high-quality optical signals can be transmitted even when the optical signals are amplified and branched after optical routing, so that the number of optical subscribers that can be accommodated is increased, and a low-cost optical subscriber system is provided. be able to.
[0069]
In the present embodiment, the level of the optical signal output from each optical transmitter is adjusted based on the detected DG amount and SNR amount. However, only the SNR of the digital data signal is detected and the detected SNR is adjusted. The level of the optical signal output from each optical transmitter may be adjusted based on the amount. The optical multiplex transmission apparatus according to the modified example of the present embodiment reduces the power of the RF optical signal input to each optical amplifying unit so that the SNR of the digital data signal becomes larger than a predetermined value, and / or The power of the optical packet is largely controlled.
[0070]
(Fourth embodiment)
FIG. 8 is a block diagram illustrating a configuration of an optical multiplex transmission apparatus according to the fourth embodiment of the present invention. 8, the optical multiplex transmission apparatus according to the present embodiment includes a data light transmission unit 101, an RF light transmission unit 102, a multiplexing unit 103, an optical transmission unit 104, an optical routing unit 105, a first The optical amplifier 1071, the second optical amplifier 1072, the first optical splitter 1081, the second optical splitter 1082, the first optical receiver 7061, and the second optical receiver 7062 , And a quality information transmission unit 109. This optical multiplex transmission apparatus is different from the optical multiplex transmission apparatus according to the first embodiment in that the first optical receiving section 1061 and the second optical receiving section 1062 are respectively replaced with the first optical receiving section 7061 and the second optical receiving section 1062. The light receiving unit 7062 is replaced.
[0071]
The optical multiplex transmission apparatus illustrated in FIG. 8 includes a plurality of first optical receiving units 7061 and a plurality of second optical receiving units 7062. Each of the first optical receiving section 7061 and each of the second optical receiving sections 7062 includes a wavelength separating section, a BB (Base Band) optical detecting section, and an RF optical detecting section. Further, at least one of the first optical receiving unit 7061 and the second optical receiving unit 7062 further includes a DG detecting unit and a light receiving level detecting unit. FIG. 8 shows that one of the first optical receiving units 7061 includes a wavelength separating unit 70616, a BB optical detecting unit 70611, an RF optical detecting unit 70612, a DG detecting unit 10613, and a light receiving level detecting unit 70617. This is an example of the case where there is. In FIG. 8, the same omission as in FIG. 1 is performed. In the following, among the components of the present embodiment, the components having the same functions as those of the first embodiment will be denoted by the same reference numerals and the description thereof will be simplified, and the differences from the first embodiment will be described. This will be mainly described.
[0072]
In the first embodiment, the power of the optical packet and the RF optical signal input to the first optical amplifier 1071 and the second optical amplifier 1072 is determined based on the waveform distortion DG detected by the DG detector 10613. By controlling so as to satisfy a predetermined condition, the quality degradation of the optical signal generated at the time of optical amplification is suppressed. However, as shown in FIG. 9, when the power of the RF optical signal input to the optical fiber amplifier is increased (relative to the power of the optical packet), the DG of the digital data signal is improved, while the digital data signal is improved. Degrades the signal-to-noise level ratio SNR. Since the BER, which is the overall quality of the digital data signal, is determined by both the DG and the SNR, a good BER cannot be obtained in an environment where the SNR is excessively deteriorated even if the DG is improved.
[0073]
Therefore, the present embodiment is characterized in that the power of the optical signal is controlled based on the received power of the DG and the optical packet. The reason why the received power of the optical packet is used in the present embodiment is that when the power of the RF optical signal input to the optical amplifier changes, the received power of the optical packet and the SNR of the digital data signal D1 change in substantially the same manner. This is because the received power of the optical packet can be used for controlling the power of the optical signal instead of the SNR (see FIG. 9).
[0074]
A wavelength separating unit 70616 included in the first optical receiving unit 7061 separates the wavelength of the optical signal input to the first optical receiving unit 7061 into an optical packet and an RF optical signal, and outputs the optical packet and the RF optical signal. The BB optical detection unit 70611 reconverts the optical packet output from the wavelength separation unit 70616 into a digital data signal D1, and outputs the digital data signal D1. The RF light detection unit 70612 reconverts the RF light signal output from the wavelength separation unit 70616 into a carrier modulation signal DX and outputs the signal. The DG detection unit 10613 detects a waveform distortion amount DG of the digital data signal D1. The light reception level detection unit 70617 detects the reception power of the optical packet. The quality information transmission unit 109 transmits the DG amount detected by the DG detection unit 10613 and the reception power amount detected by the light reception level detection unit 70617 to at least one of the data light transmission unit 101 and the RF light transmission unit 102. I do. At least one of the data light transmitting unit 101 and the RF light transmitting unit 102 determines that the received power of the optical packet is larger than the first predetermined value and the DG of the digital data signal is based on the received DG amount and the received power amount. The power of the output optical signal is controlled so as to be smaller than the second predetermined value. Note that the first optical receiving unit 7061 and the second optical receiving unit 7062, which do not include the DG detection unit and the light reception level detection unit, do not detect the DG amount and the reception power amount, except for the DG detection unit and the light reception level. The operation is similar to that of the optical receiving unit including the detecting unit.
[0075]
As described above, according to the optical multiplex transmission apparatus according to the present embodiment, the optical receiving unit detects the waveform distortion amount DG of the digital data signal and the reception power of the optical packet, and detects the detected DG amount and reception power amount. By adjusting the level of the optical signal output from each optical transmission unit based on the above, the power of the optical packet input to each optical amplification unit and / or the power of the RF optical signal input to each optical amplification unit can be appropriately adjusted. Can be controlled. As a result, high-quality optical signals can be transmitted even when the optical signals are amplified and branched after optical routing, so that the number of optical subscribers that can be accommodated is increased, and a low-cost optical subscriber system is provided. be able to.
[0076]
In the present embodiment, the level of the optical signal output from each optical transmission unit is adjusted based on the detected DG amount and the received power amount. However, only the received power amount of the optical packet is detected and the detection is performed. The level of the optical signal output from each optical transmitter may be adjusted based on the received power amount obtained. The optical multiplex transmission apparatus according to the modification of the present embodiment reduces the power of the RF optical signal input to each optical amplifying unit and / or reduces the optical packet so that the received power amount becomes larger than a predetermined value. Control the power of
[0077]
(Fifth embodiment)
FIG. 10 is a block diagram illustrating a configuration of an optical multiplex transmission apparatus according to the fifth embodiment of the present invention. In FIG. 10, the optical multiplex transmission apparatus according to the present embodiment includes a data light transmission unit 101, an RF light transmission unit 102, a multiplexing unit 103, an optical transmission unit 104, an optical routing unit 105, a first The optical amplifier 1071, the second optical amplifier 1072, the first optical splitter 1081, the second optical splitter 1082, the first optical receiver 9061, and the second optical receiver 9062 , And a quality information transmission unit 109. This optical multiplex transmission apparatus is different from the optical multiplex transmission apparatus according to the first embodiment in that the first optical receiver 1061 and the second optical receiver 1062 are respectively replaced by the first optical receiver 9061 and the second optical receiver 1061. The light receiving unit 9062 is replaced.
[0078]
The optical multiplex transmission apparatus illustrated in FIG. 10 includes a plurality of first optical receiving units 9061 and a plurality of second optical receiving units 9062. Each of the first optical receiving units 9061 and each of the second optical receiving units 9062 include an optical detection unit and a separation unit. Further, at least one of the first optical receiving unit 9061 and the second optical receiving unit 9062 further includes a BER detecting unit. FIG. 10 illustrates an example in which one of the first optical receiving units 9061 includes an optical detection unit 10611, a separation unit 10612, and a BER detection unit 90618. FIG. 10 is omitted from FIG. 1. In the following, among the components of the present embodiment, the components having the same functions as those of the first embodiment will be denoted by the same reference numerals and the description thereof will be simplified, and the differences from the first embodiment will be described. This will be mainly described.
[0079]
In the first embodiment, the power of the optical packet and the RF optical signal input to the first optical amplifier 1071 and the second optical amplifier 1072 is determined based on the waveform distortion DG detected by the DG detector 10613. By controlling so as to satisfy a predetermined condition, the quality degradation of the optical signal generated at the time of optical amplification is suppressed. However, as shown in FIGS. 7 and 9, when the power of the RF optical signal input to the optical fiber amplifier is increased (relative to the power of the optical packet), the DG of the digital data signal is improved. Thus, the SNR of the digital data signal deteriorates. Since the BER, which is the overall quality of the digital data signal, is determined by both the DG and the SNR, a good BER cannot be obtained in an environment where the SNR is excessively deteriorated even if the DG is improved.
[0080]
Therefore, the present embodiment is characterized in that the power of the optical signal is controlled based on the BER of the digital data signal. More specifically, a BER detector 90618 included in the first optical receiver 9061 directly detects the BER of the digital data signal D1. The quality information transmission unit 109 transmits the BER amount detected by the BER detection unit 90618 to at least one of the data light transmission unit 101 and the RF light transmission unit 102. At least one of the data light transmitter 101 and the RF light transmitter 102 controls the power of the output optical signal based on the received BER amount so that the BER of the digital data signal becomes smaller than a predetermined value. Note that the first optical receiving unit 9061 and the second optical receiving unit 9062 that do not include the BER detecting unit operate in the same manner as the optical receiving unit that includes the BER detecting unit except that the BER amount is not detected.
[0081]
As described above, according to the optical multiplex transmission apparatus according to the present embodiment, the BER of the digital data signal is detected by the optical receiving unit, and the level of the optical signal output from each optical transmitting unit is changed based on the detected BER amount. By adjusting, the power of the optical packet input to each optical amplifier and / or the power of the RF optical signal input to each optical amplifier are appropriately set. As a result, high-quality optical signals can be transmitted even when the optical signals are amplified and branched after optical routing, so that the number of optical subscribers that can be accommodated is increased, and a low-cost optical subscriber system is provided. be able to.
[0082]
Hereinafter, matters common to the above-described embodiments (including their modifications) will be described. First, a supplementary description will be given of the relationship between the transmission characteristics (wavelength dependence) of the optical routing unit 105 and the set wavelengths of the data optical transmission unit 101 and the RF optical transmission unit 102. As described in the first embodiment, the optical routing unit 105 separates and outputs optical signals having different wavelengths for each output terminal, and has a transmission characteristic with periodicity with respect to the optical wavelength. That is, the optical routing unit 105 has a property of transmitting light at predetermined wavelength intervals (FSR) when the wavelength of light is sequentially changed. Therefore, in the optical multiplex transmission apparatus according to each embodiment, the first wavelength band occupied by the optical packet and the second wavelength band occupied by the RF optical signal are set so as not to overlap with each other. As a result, an optical packet or an RF optical signal having an unnecessary wavelength is not output from each output terminal of the optical routing unit 105, so that interference between the unnecessary optical signal and the necessary optical signal is prevented, and high-quality signal transmission is performed. It can be performed.
[0083]
In order to increase the number of optical receiving units connected to the optical routing unit 105, the first wavelength band occupied by the optical packet and the second wavelength band occupied by the RF optical signal are expanded. It is preferable that the bandwidth of the wavelength band of the second wavelength band and the bandwidth of the second wavelength band are substantially matched, and both are set so as not to exceed the FSR, or both are set so as to substantially match the FSR. . This makes it possible to more effectively utilize the transmission characteristics of the optical routing unit 105 and efficiently accommodate more optical receiving units. The optical routing unit 105 having such characteristics is configured by, for example, AWG (Arrayed Waveguide Grating).
[0084]
Next, a signal transmitted by the optical multiplex transmission device according to each embodiment will be described. As described above, the optical packet is an optical signal having a burst property that occurs intermittently. As a result, a large-capacity digital data signal can be transmitted to a large number of optical subscribers more efficiently. The carrier modulation signal is, for example, a plurality of carriers having predetermined different frequencies, a plurality of modulation signals are obtained by modulating based on data corresponding to each carrier, a frequency obtained by frequency multiplexing the modulation signal It may be a multiplex signal.
[0085]
Next, a light source used in the optical transmission device according to each embodiment will be described. The wavelength tunable light source 1012 included in the data light transmitting unit 101 is a DBR (Distributed Bragg Reflector) laser, an SSG (Super Structure Grating) -DBR laser, an SG (Sampled-Grating) -DBR laser, or a GCSR Gating (GSR). ) It is constituted by a laser or the like. Thereby, the entire wavelength bandwidth used for transmitting the data optical signal can be expanded, and the digital data signal can be transmitted to a larger number of receiving terminals.
[0086]
The broad-spectrum light source 1021 included in the RF light transmitting unit 102 includes a super luminescent diode (SLE), a light emission diode (LED), or an erbium-doped optical fiber amplifier (EDFA: Erbium Doped). It is composed of spontaneous emission light (ASE) of a fiber amplifier (Amplified Spontaneous Emission). As a result, the wavelength bandwidth used for transmitting the RF optical signal can be expanded, and the carrier modulation signal can be distributed to a greater number of receiving terminals. Alternatively, the optical multiplex transmission apparatus may include a plurality of broad-spectrum light sources 1021, modulate each light source with the same carrier modulation signal, combine the modulated optical signals, and output as an RF optical signal. Alternatively, a plurality of broad-spectrum light sources 1021 may be provided, the output light from each light source may be combined, and then the combined light may be modulated with a carrier modulation signal and output as an RF optical signal. Thereby, even after the optical routing, the RF optical signal having sufficient power can be distributed to each optical receiving unit, so that the reception quality of the RF optical signal can be maintained and the deterioration of the transmission characteristics can be prevented.
[0087]
Although the first embodiment has been described with respect to the optical multiplex transmission device having no optical amplification unit and the optical multiplex transmission device including two or more DG detection units, the other embodiments (including their modifications) ), A similar optical multiplex transmission device can be configured.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration of an optical multiplex transmission device according to a first embodiment of the present invention.
FIG. 2 is a diagram for explaining a waveform deterioration phenomenon of an optical packet and an RF optical signal in the optical multiplex transmission apparatus according to the first embodiment of the present invention.
FIG. 3 is a view for explaining the relationship between the DG of an optical packet (digital data signal) and the power of an RF optical signal input to an optical amplifier in the optical multiplex transmission apparatus according to the first embodiment of the present invention. FIG.
FIG. 4 is a block diagram illustrating a configuration of an optical multiplex transmission device according to a second embodiment of the present invention.
FIG. 5 is a diagram for explaining the relationship between the DUR of the RF optical signal and the power of the RF optical signal input to the optical amplifier in the optical multiplex transmission apparatus according to the first embodiment of the present invention.
FIG. 6 is a block diagram illustrating a configuration of an optical multiplex transmission device according to a third embodiment of the present invention.
FIG. 7 is a diagram for explaining the relationship between the signal quality of a digital data signal and the power of an RF optical signal input to an optical amplifier in an optical multiplex transmission apparatus according to a third embodiment of the present invention. .
FIG. 8 is a block diagram illustrating a configuration of an optical multiplex transmission apparatus according to a fourth embodiment of the present invention.
FIG. 9 illustrates the relationship between the signal quality of a digital data signal, the received power of an optical packet, and the power of an RF optical signal input to an optical amplifier in an optical multiplex transmission apparatus according to a fourth embodiment of the present invention. FIG.
FIG. 10 is a block diagram illustrating a configuration of an optical multiplex transmission apparatus according to a fifth embodiment of the present invention.
FIG. 11 is a block diagram showing a configuration of a conventional optical multiplex transmission device.
FIG. 12 is a diagram for explaining signals of respective units in the optical multiplex transmission device.
FIG. 13 is a diagram for explaining a relationship between transmission characteristics of an optical routing unit and set wavelengths of an optical packet and an RF optical signal in an optical multiplex transmission apparatus.
[Explanation of symbols]
101: Data light transmission unit
1011 ... Address extraction unit
1012… tunable light source
1013… light modulator
102… RF light transmitter
1021… Wide spectrum light source
103… combining part
104: Optical transmission unit
105: Optical routing unit
1061... First optical receiver
1062... Second optical receiver
10611: Optical detector
10612 ... Separation unit
10613 ... DG detection unit
1071... First optical amplifier
1072... Second optical amplifier
1081... First optical branching unit
1082... Second optical branching unit
109: Quality information transmission unit
4061... First optical receiver
4062... Second optical receiver
40614: Strain detector
5061... First optical receiver
5062... Second optical receiver
50615 ... Comprehensive quality detection unit
7061... First optical receiver
7062... Second optical receiver
70611 ... BB photodetector
70612 ... RF light detector
70616 ... wavelength separation unit
70617: Light reception level detection unit
9061... First optical receiver
9062... Second optical receiver
90618 ... BER detection unit

Claims (29)

An optical multiplex transmission device for transmitting a digital data signal to a selected destination and transmitting a carrier modulation signal to all destinations,
A data light for selecting a wavelength corresponding to each transmission destination from a predetermined first wavelength band, modulating light having the selected wavelength based on a digital data signal to be transmitted to the transmission destination, and outputting as a data optical signal A transmission unit;
An RF light transmission unit that modulates light occupying a predetermined second wavelength band that does not overlap with the first wavelength band based on the carrier modulation signal, and outputs the modulated light as an RF light signal;
A data optical signal output from the data optical transmitter, and a multiplexing unit that combines and outputs the RF optical signal output from the RF optical transmitter,
An optical transmission unit that transmits the optical signal output from the multiplexing unit,
It has a plurality of output terminals, and in the transmission characteristics at each output terminal, a periodicity (FSR: Free Spectral Range) substantially matching the difference between the center wavelength of the first wavelength band and the center wavelength of the second wavelength band. ) Appears, separates the data optical signal transmitted by the optical transmission unit for each wavelength corresponding to each transmission destination, and divides the RF optical signal transmitted by the optical transmission unit into a plurality of output optical signals. An optical routing unit that outputs from
An optical amplifier that amplifies the optical signal output from the optical routing unit,
An optical branching unit that further branches the optical signal amplified by the optical amplifying unit into a plurality of optical signals,
An optical receiving unit that receives the optical signal branched by the optical branching unit and, based on the received optical signal, separates and outputs the digital data signal and the carrier modulation signal.
An optical multiplex transmission apparatus, wherein the relative magnitudes of the powers of the data optical signal and the RF optical signal input to the optical amplifier are determined based on the reception quality of the optical receiver. The power of the RF optical signal input to the optical amplifying unit is large and / or so that the temporal change (DG: Differential {Gain}) of the amplitude of the digital data signal output from the optical receiving unit is smaller than a predetermined value. 2. The optical multiplex transmission apparatus according to claim 1, wherein the power of the data optical signal input to the optical amplifier is controlled to be small. A DG detection unit that detects a DG amount of the digital data signal output from the optical reception unit;
A quality information transmission unit that transmits the DG amount detected by the DG detection unit to at least one of the data light transmission unit and the RF light transmission unit;
The apparatus according to claim 2, wherein at least one of the data light transmitting unit and the RF light transmitting unit controls power of an output optical signal based on a DG amount transmitted by the quality information transmitting unit. Optical multiplex transmission equipment. The power of the RF optical signal input to the optical amplifying unit is large and / or the data input to the optical amplifying unit so that the waveform distortion of the carrier modulation signal output from the optical receiving unit is smaller than a predetermined value. The optical multiplex transmission apparatus according to claim 1, wherein the power of the optical signal is controlled to be small. A distortion detection unit that detects a waveform distortion amount of the carrier modulation signal output from the optical reception unit,
A quality information transmission unit that transmits the waveform distortion amount detected by the distortion detection unit to at least one of the data light transmission unit and the RF light transmission unit,
The at least one of the data light transmission unit and the RF light transmission unit controls the power of an optical signal to be output based on the amount of waveform distortion transmitted by the quality information transmission unit. An optical multiplex transmission device according to claim 1. The DG of the digital data signal output from the optical receiving unit is smaller than a first predetermined value, and the waveform distortion of the carrier modulation signal output from the optical receiving unit is smaller than a second predetermined value, The optical multiplexing device according to claim 1, wherein the power of the RF optical signal input to the optical amplifier is controlled to be large and / or the power of the data optical signal input to the optical amplifier is controlled to be small. Transmission equipment. A reception quality detection unit that detects a DG amount of the digital data signal output from the optical reception unit and a waveform distortion amount of the carrier modulation signal output from the optical reception unit;
A quality information transmission unit that transmits the DG amount and the waveform distortion amount detected by the reception quality detection unit to at least one of the data light transmission unit and the RF light transmission unit;
At least one of the data light transmitting unit and the RF light transmitting unit controls the power of the output optical signal based on the DG amount and the waveform distortion amount transmitted by the quality information transmitting unit. Item 7. An optical multiplex transmission device according to item 6. The power of the RF optical signal input to the optical amplifying unit is small so that the signal-to-noise level ratio (SNR) of the digital data signal output from the optical receiving unit is larger than a predetermined value, and 2. The optical multiplex transmission device according to claim 1, wherein power of a data optical signal input to the optical amplifying unit is largely controlled. An SNR detector for detecting an SNR amount of the digital data signal output from the optical receiver;
A quality information transmission unit that transmits the SNR amount detected by the SNR detection unit to at least one of the data light transmission unit and the RF light transmission unit;
9. The apparatus according to claim 8, wherein at least one of the data light transmitting unit and the RF light transmitting unit controls the power of the output optical signal based on the SNR amount transmitted by the quality information transmitting unit. Optical multiplex transmission equipment. Data input to the optical amplifying unit such that the SNR of the digital data signal output from the optical receiving unit is larger than a first predetermined value and the DG of the digital data signal is smaller than a second predetermined value. The optical multiplex transmission apparatus according to claim 1, wherein the power of an optical signal and / or the power of an RF optical signal input to the optical amplifier is controlled. A digital signal quality detection unit for detecting an SNR amount and a DG amount of the digital data signal output from the optical receiving unit;
A quality information transmission unit that transmits the SNR amount and the DG amount detected by the digital signal quality detection unit to at least one of the data light transmission unit and the RF light transmission unit;
At least one of the data light transmitting unit and the RF light transmitting unit controls the power of an optical signal to be output based on the SNR amount and the DG amount transmitted by the quality information transmitting unit. The optical multiplex transmission device according to claim 10. The power of the RF optical signal input to the optical amplifying unit is small and / or the data optical signal input to the optical amplifying unit so that the power of the data optical signal received by the optical receiving unit is larger than a predetermined value. 2. The optical multiplex transmission apparatus according to claim 1, wherein the power of the optical multiplex transmission is greatly controlled. An optical power detection unit that detects the power amount of the data optical signal received by the optical reception unit,
A quality information transmission unit that transmits the power amount detected by the optical power detection unit to at least one of the data light transmission unit and the RF light transmission unit,
13. The apparatus according to claim 12, wherein at least one of the data light transmitting unit and the RF light transmitting unit controls the power of the output optical signal based on the amount of power transmitted by the quality information transmitting unit. Optical multiplex transmission equipment. The optical receiver is configured such that the power of the data optical signal received by the optical receiver is greater than a first predetermined value and the DG of the digital data signal output from the optical receiver is smaller than a second predetermined value. The optical multiplex transmission apparatus according to claim 1, wherein power of a data optical signal input to an amplifier and / or power of an RF optical signal input to the optical amplifier is controlled. An optical power detection unit that detects the power amount of the data optical signal received by the optical reception unit,
A DG detection unit that detects a DG amount of the digital data signal output from the optical reception unit;
A quality information transmission unit that transmits the power amount detected by the optical power detection unit and the DG amount detected by the DG detection unit to at least one of the data light transmission unit and the RF light transmission unit,
At least one of the data light transmitting unit and the RF light transmitting unit controls the power of an output optical signal based on the amount of power and the amount of DG transmitted by the quality information transmitting unit. 15. The optical multiplex transmission device according to 14. The power of the data optical signal input to the optical amplifying unit and / or the optical signal such that the bit error rate (BER: Bit @ Error @ Rate) of the digital data signal output from the optical receiving unit is smaller than a predetermined value. The optical multiplex transmission apparatus according to claim 1, wherein the power of the RF optical signal input to the amplifier is controlled. A BER detector that detects a BER amount of the digital data signal output from the optical receiver;
A quality information transmission unit that transmits the BER amount detected by the BER detection unit to at least one of the data light transmission unit and the RF light transmission unit;
17. The apparatus according to claim 16, wherein at least one of the data light transmitting unit and the RF light transmitting unit controls power of an output optical signal based on a BER amount transmitted by the quality information transmitting unit. Optical multiplex transmission equipment. The optical multiplex transmission apparatus according to claim 1, wherein the data optical signal is an optical signal having a burst property that occurs intermittently. The carrier modulation signal, a plurality of carriers having a predetermined frequency different from each other, to obtain a plurality of modulation signals by modulating based on data corresponding to each carrier, a frequency obtained by frequency multiplexing the modulation signal 2. The optical multiplex transmission device according to claim 1, wherein the optical multiplex transmission device is a multiplex signal. The data optical signal is an optical signal having a burst property that occurs intermittently, and the carrier modulation signal is a plurality of carriers having predetermined different frequencies, based on data corresponding to each carrier. 2. The optical multiplex transmission apparatus according to claim 1, wherein the optical multiplex transmission apparatus is a frequency multiplexed signal obtained by modulating to obtain a plurality of modulation signals and frequency multiplexing the modulation signals. 2. The optical multiplex transmission apparatus according to claim 1, wherein a bandwidth of the first wavelength band substantially matches a bandwidth of the second wavelength band. The optical multiplex transmission apparatus according to claim 1, wherein a bandwidth of the first wavelength band and / or a bandwidth of the second wavelength band is smaller than an FSR of the optical routing unit. 2. The optical multiplex transmission apparatus according to claim 1, wherein the bandwidth of the first wavelength band, the bandwidth of the second wavelength band, and the FSR of the optical routing unit substantially match. The data light transmitting unit includes, as a light source, a DBR (Distributed Bragg Reflector) laser, an SSG (Super Structure Grating) -DBR laser, an SG (Sampled-Grating) Co-DBR laser, or a GCSR (Grating Scoring Laser). The optical multiplex transmission apparatus according to claim 1, wherein: The optical multiplex transmission device according to claim 1, wherein the RF light transmission unit uses a super luminescent diode as a light source. The optical multiplex transmission device according to claim 1, wherein the RF light transmission unit uses a light emitting diode as a light source. The optical multiplex transmission apparatus according to claim 1, wherein the RF light transmission unit uses spontaneous emission light of an erbium-doped optical fiber amplifier as a light source. The optical multiplex transmission apparatus according to claim 1, wherein the RF light transmission unit includes a plurality of light sources, and multiplexes and outputs output lights of the light sources. The optical multiplex transmission apparatus according to claim 1, wherein the optical routing unit includes an AWG (Arrayed Waveguide Grating).

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