JP6012259B2 - Optical terminal device and optical transmission system - Google Patents

Description

  The present invention provides an optical terminal device that transmits an optical signal to and from a communication station that is connected to another optical terminal device so as to be capable of transmitting an optical signal bidirectionally via a single optical transmission line, and The present invention relates to an optical transmission system.

  Like a PON (Passive Optical Network) system in which a plurality of optical terminal devices transmit optical signals to and from a communication station connected so as to be able to transmit optical signals bidirectionally via a single optical transmission line An optical transmission system has been operated conventionally. In such an optical transmission system, a termination device is installed in a communication station, and a plurality of optical terminal devices communicate with the termination device in synchronization. Further, the transmission distances between the plurality of optical terminal devices and the communication station vary, and the transmission path loss between the optical terminal device and the communication station differs depending on the distance.

  In order to equalize the optical input level from a plurality of optical terminal devices on the communication station side, for example, in the optical transmission method described in Patent Document 1, a fixed optical attenuator is inserted into the optical output of the optical terminal device, The light output level is adjusted individually.

Japanese Unexamined Patent Publication No. 7-231298

  In addition, an Internet service using a cable modem is operated in a CATV system using a coaxial cable as a transmission path. In recent years, it has been studied to convert the transmission line into an optical fiber using a system using this cable modem to form a PON system.

  However, when the transmission path is made into an optical fiber in a system using a cable modem and a PON system is used, when a burst optical signal is output from different optical terminal devices, the terminating device transmits optical signals in the same wavelength band. There is a case of receiving simultaneously. In this case, there is a problem that optical beat noise is generated in the optical receiver of the terminating device, and transmission quality is significantly deteriorated.

  Thus, transmission quality degradation due to optical beat noise becomes a problem, but as described above, transmission quality degradation occurs when the optical input levels transmitted simultaneously from a plurality of optical terminal devices and input to the terminating device are substantially the same. Tend to be less. Also, the lower the optical input level input to the terminating device, the smaller the degradation of transmission quality due to the optical beat noise described above.

  For this reason, it is desirable for the optical terminal device to transmit an optical signal so that the optical input level input to the terminating device is accurately uniform in the vicinity of the lower limit value.

  According to the optical transmission method of Patent Document 1, the optical output level can be individually adjusted on the optical terminal device side. However, since the transmission path has temperature characteristics and the like, the optical reception level at the termination device is based on the temperature and the like. Change. Therefore, it is necessary to always detect the optical input level in the optical receiver of the terminating device and control the optical output level of the optical terminal device.

  The present invention has been proposed in view of such circumstances, and is installed in a communication station connected to be capable of transmitting optical signals in both directions via a single optical transmission line together with a plurality of optical terminal devices. The present invention is applied to a transmission system that transmits an optical signal in the same wavelength band with an asynchronous termination device. The present invention provides an optical terminal device capable of reducing optical beat noise by accurately equalizing the optical input level input to the terminating device in the vicinity of the lower limit in such a transmission system, and the optical An object is to provide a transmission system.

  An optical terminal device according to the present invention receives an optical signal output from a communication station that is connected to another optical terminal device so as to be able to transmit an optical signal bidirectionally via a single optical transmission line. And a burst-like optical signal in the same wavelength band as other optical terminal devices via the optical transmission line based on transmission timing controlled by each of the transmission terminals and asynchronous terminal devices installed in the communication station An optical transmitter that transmits to the communication station, an optical input level detector that detects an optical input level of the optical signal received by the optical receiver, and a target of the optical signal that the communication station receives via the optical transmission line Calculates the transmission loss of the optical transmission line based on the storage unit that stores the optical input level, the station-side optical output level stored in the storage unit, and the optical input level detected by the optical input level detection unit Calculated by the transmission loss calculator and the transmission loss calculator Control that controls the optical output level output from the optical transmission unit to the transmission line so that the optical input level received by the communication station is the target optical input level stored in the storage unit based on the transmission loss A part.

  An optical transmission system according to the present invention includes a communication station in which a plurality of asynchronous termination devices are installed, and the above-described optical terminal device.

  The present invention is based on the transmission loss calculated from the optical output level of the optical signal output from the communication station to the optical transmission line and the optical input level of the optical signal input from the optical transmission line. The optical output level output from the optical transmitter is controlled so that the communication station receives the optical signal at the input level.

  As described above, the present invention controls the optical output level output from the optical transmission unit, thereby making it possible to uniformly equalize the optical input level input to the communication station side in the vicinity of the lower limit value. As a result, optical beat noise can be reduced.

FIG. 1 is a diagram for explaining a specific example of an optical transmission system to which the present invention is applied. FIG. 2 is a diagram for explaining the configuration of the optical terminal apparatus according to the first embodiment to which the present invention is applied. FIG. 3 is a diagram for explaining the configuration of the optical terminal apparatus according to the second embodiment to which the present invention is applied.

  The present invention provides an optical transmission system that transmits optical signals to and from a communication station in which a plurality of optical terminal devices are connected so as to be capable of transmitting optical signals bidirectionally via a single optical transmission line, and The present invention relates to an optical terminal device incorporated in the optical transmission system. An optical transmission system to which the present invention is applied is configured, for example, as shown in FIG.

  That is, the optical transmission system 1 is a PON that transmits optical signals to and from a communication station where a plurality of optical terminal devices are connected to transmit optical signals bidirectionally via a single optical transmission line. (Passive Optical Network) system. Specifically, as shown in FIG. 1, the optical transmission system 1 includes a plurality of cable modems (CMs) 211a, 211b,. , 212n (hereinafter also collectively referred to as CM 212), and a plurality of cable modems (CM: Cable Modem) 212a, 212b,. , 2n (hereinafter also collectively referred to as the optical terminal device 2), the optical transmission line 3, and the optical terminal devices 2 via the optical transmission line 3. It is comprised from the communication station 4 which communicates by an optical signal.

  The optical terminal devices 2a, 2b,..., 2n are respectively connected to the CMs 211a, 211b via the multiplexers / demultiplexers 22a, 22b,. ,..., 211n and CMs 212a, 212b,.

  The CMs 211 and 212 demodulate the RF signal (hereinafter also referred to as RF downlink signal) supplied from the optical terminal device 2. Further, the CM 211 and the CM 212 transmit a burst-like RF signal obtained by modulating the signal to the transmission destination based on the data transmission timing included in the demodulated RF downlink signal via the optical terminal device 2 to the communication station 4 side. Output to. In addition, the CM 211 controls the transmission period and transmission timing of the burst-like RF signal in synchronization with the destination CMTS 41. In addition, the CM 212 controls the transmission period and transmission timing of the burst-like RF signal in synchronization with the destination CMTS 42.

  The optical terminal device 2 converts the optical signal transmitted from the optical transmission path 3 into an RF signal and supplies it to the CM 211 and CM 212 via the multiplexer / demultiplexer 22. Further, the optical terminal device 2 converts the burst RF signal output from the CM 211 and CM 212 into a burst optical signal and outputs the burst optical signal to the optical transmission line 3.

  The optical transmission line 3 connects the plurality of optical terminal devices 2 and the communication station 4 so that an optical signal can be transmitted. The optical transmission line 3 is connected to the optical branching unit 3a and the optical terminal devices 2a, 2b,..., 2n and the optical branching unit 3a so that an optical signal can be transmitted bidirectionally. ,... 31n (hereinafter collectively referred to as an optical transmission line 31) and a single optical transmission that connects the optical branching unit 3a and the communication station 4 so that an optical signal can be transmitted bidirectionally. And a path 32.

  The optical branching unit 3a is a passive optical element such as an optical coupler that demultiplexes and combines optical signals. The optical branching unit 3 a multiplexes the optical signals transmitted from the respective optical terminal devices 2 via the optical transmission path 31 and transmits them to the communication station 4 via the optical transmission path 32. The optical branching unit 3 a demultiplexes the optical signal transmitted from the communication station 4 via the optical transmission path 32 and transmits the demultiplexed signal to each optical terminal device 2 via the optical transmission path 31.

  The optical branching device 3a is roughly classified into a fusion type and a waveguide type, and any type of optical element can be used as long as it is a passive optical element that performs multiplexing and demultiplexing as described above. May be.

  Also, an optical signal (hereinafter also referred to as upstream optical signal) transmitted from the optical terminal device 2 to the communication station 4 and an optical signal (hereinafter referred to as downstream optical signal) transmitted from the communication station 4 to the optical terminal device 2. Also, optical signals having different wavelength bands are used. In the present embodiment, as a specific example, an optical signal in the 1610 nm wavelength band is used as the upstream optical signal, and an optical signal in the 1555 nm wavelength band is used as the downstream optical signal.

  In the optical transmission system 1 having such a configuration, by using the optical branching unit 3a, a plurality of optical terminal devices 2 and the communication station 4 are bidirectionally connected via a single optical transmission line 32. Transmission is possible by an optical signal. In the optical transmission system to which the present invention is applied, a plurality of optical branching units can be used to enable transmission between a plurality of optical terminal devices 2 and the communication station 4 using an optical signal.

  Next, a specific configuration of the communication station 4 will be described. The communication station 4 includes two cable modem termination systems (CMTS) 41, 42, an optical receiver 43, a multiplexer 44, an optical transmitter 45, a WDM filter 46, and a management. A device 47 and a control signal adder 48 are provided.

  The CMTS 41 is a termination device according to the present invention, and modulates and demodulates a signal for communication with the CM 211 connected to each optical terminal device 2. Specifically, the CMTS 41 modulates a signal to be transmitted to the CM 211 connected to each optical terminal device 2, and supplies the modulated RF signal to the multiplexer 44 from the uplink port 411. Further, the CMTS 41 demodulates the RF signal supplied from the optical receiver 43 to the downstream port 412 via the duplexer 43a.

  The CMTS 42 is a termination device according to the present invention, and modulates and demodulates a signal to be communicated with the CM 212 connected to each optical terminal device 2. The modulated RF signal is supplied to the multiplexer 44, and the RF signal supplied from the optical receiver 43 to the downstream port 422 via the duplexer 43a is demodulated.

  The communication station 4 may be provided with more CMTSs. The CMTS may use any modulation scheme such as frequency modulation and phase modulation as long as the modulation scheme can be distinguished from other terminal devices.

  The optical receiver 43 receives a downstream optical signal demultiplexed from a WDM filter 46 described later, and supplies the received RF signal to the CMTSs 41 and 42 via the demultiplexer 43a.

  The multiplexer 44 combines the RF signals supplied from the CMTSs 41 and 42 and supplies the combined RF signal to the optical transmitter 45.

  The optical transmitter 45 converts the RF signal supplied from the multiplexer 44 into a downstream optical signal and outputs it to the WDM filter 46.

  The WDM filter 46 is a filter that multiplexes and demultiplexes light of different optical wavelengths, demultiplexes the upstream optical signal from the optical transmission path 32 and outputs it to the optical receiver 43, and optically transmits the downstream optical signal. The signal is multiplexed to the path 32 and output to the optical terminal device 2 side.

  The management device 47 controls the operation of each unit provided in the communication station 4. In addition, the management device 47 transmits control information to be described later to the control information adder 48.

  The control information adder 48 includes a CPU 481 and a modulation unit 482, modulates the control information transmitted from the management device 47 by the modulation unit 482, and supplies the modulated RF signal to the multiplexer 44.

  In the optical transmission system 1 having such a configuration, the downstream optical signal transmitted from the optical transmitter 45 on the communication station 4 side reaches all the optical terminal devices 2, and the optical terminal device 2 and the CMs 211 and 212 are necessary. Information will be received.

  On the other hand, the CM 211 is a burst obtained by modulating the uplink data to the cable modem termination device CMTS 41 installed in the communication station 4 based on the data transmission timing information included in the downstream optical signal transmitted from the communication station 4 side. The RF signal is supplied to the optical terminal device 2. Then, the optical terminal device 2 transmits a burst-like optical signal corresponding to the RF signal supplied from the CM 211 to the communication station 4 side.

  Also, the CM 212 modulates the uplink data to the cable modem termination device CMTS 42 installed in the communication station 4 based on the data transmission timing information included in the downstream optical signal transmitted from the communication station 4 side. The RF signal is supplied to the optical terminal device 2. Then, the optical terminal device 2 transmits a burst-like optical signal corresponding to the RF signal supplied from the CM 212 to the communication station 4 side.

  In this way, in the optical transmission system 1, data transmission by time division multiplexing is performed so that the upstream optical signal output from each optical terminal apparatus 2 is not simultaneously input to the communication station 4 side.

  Even if data transmission is performed by such time division multiplexing, since the CMTSs 41 and 42 installed in the communication station 4 operate asynchronously with each other, a plurality of optical terminal devices 2 simultaneously output upstream optical signals. There is a case. This is because the CMTSs 41 and 42 asynchronously control the timings of requesting the CMs 211 and 212 to transmit burst optical signals.

  When a plurality of optical terminal devices 2 simultaneously output upstream optical signals in this way, the optical receiver 43 in the communication station 4 simultaneously receives light in the same wavelength band, so that optical beat noise is generated and transmission quality is increased. Is damaged. Such optical beat noise is reduced when the optical input level of the optical receiver 43 is made uniform with high accuracy near the lower limit value.

  Therefore, in the optical transmission system 1 to which the present invention is applied, in order to equalize the optical input level of the upstream optical signal transmitted to the communication station 4 with high accuracy near the lower limit, The first embodiment has a configuration as shown in FIG.

  That is, as shown in FIG. 2, the optical terminal device 2 includes a multiplexing / demultiplexing unit 22, an RF detection unit 23, a variable attenuator 24, an optical transmission unit 25, a WDM filter 26, and an optical reception unit 27. The optical input level detection unit 28 and the optical transmission control unit 29 are provided.

  The multiplexing / demultiplexing unit 22 supplies the RF signal supplied from the CMs 211 and 212 to the variable attenuator 24 via the demultiplexing unit 231 provided in the RF detection unit 23.

  The RF detection unit 23 detects whether or not the CMs 211 and 212 output burst-like RF signals according to the RF signal transmission period and transmission timing via the demultiplexing unit 231, and the detection result is obtained. The optical transmission control unit 29 is notified.

  The variable attenuator 24 variably attenuates the RF signal supplied via the demultiplexing unit 231 of the RF detection unit 23 to adjust the signal amplitude ratio, and the RF signal adjusted in the signal amplitude ratio is supplied to the optical transmission unit 25. Supply. As will be described later, the variable attenuator 24 is controlled by the optical transmission controller 29. The optical terminal device 2 may adjust the signal amplitude ratio of the RF signal by connecting a variable gain amplifier instead of the variable attenuator 24 in front of the optical transmission unit 25.

  The optical transmitter 25 converts the RF signal supplied from the variable attenuator 24 into an upstream optical signal, and outputs the converted upstream optical signal to the WDM filter 26, and thus has the following configuration. That is, the optical transmission unit 25 includes an amplifier 251, a laser diode 252, a monitor photodiode 253, a resistance element 254, and an AD converter 255.

  The optical transmission unit 25 causes the RF signal amplified by the amplifier 251 to flow through the laser diode 252 to emit light, converts the RF signal into an upstream optical signal, and outputs the upstream optical signal to the WDM filter 26.

  The optical transmitter 25 receives the back light of the laser diode 252 with the monitor photodiode 253, converts the received current into a voltage with the resistance element 254, and digitizes this voltage with the AD converter 255. The optical transmission unit 25 notifies the optical transmission control unit 29 of the digitized voltage value as a value indicating the optical output level of the laser diode 252.

  In the optical transmission unit 25, as will be described later, the operating point of the laser diode 252, that is, the bias current for setting the output level of the laser is controlled by the optical transmission control unit 29.

  The WDM filter 26 is a filter that combines and demultiplexes light of different optical wavelengths, and combines the upstream optical signal output from the optical transmission unit 25 to the optical transmission line 3 and outputs it to the communication station 4. . The WDM filter 26 demultiplexes the downstream optical signal transmitted from the optical transmission path 3 and outputs the demultiplexed optical signal to the optical receiving unit 27.

  The optical receiver 27 includes a photodiode 271 that receives the downstream optical signal output from the WDM filter 26 and two amplifiers 272 and 273 that amplify the electrical signal received by the photodiode 271. The optical receiving unit 27 amplifies the electrical signal received by the photodiode 271 by the two amplifiers 272 and 273 and supplies the amplified signal to the multiplexing / demultiplexing unit 22.

  The optical input level detection unit 28 detects the optical input level of the downstream optical signal input to the optical reception unit 27 and notifies the optical transmission control unit 29 of the detected optical input level. Specifically, the optical input level detection unit 28 converts the current received by the photodiode 271 into a voltage by the resistance element 281, digitizes this voltage by the AD converter 282, and converts this voltage value into the optical input of the optical reception unit 27. The level is notified to the optical transmission control unit 29.

  The optical transmission control unit 29 includes a CPU 291, a memory 292, a temperature sensor 293, a DA converter 294, and an Ib control unit 295.

  The optical transmission controller 29 is based on information stored in the memory 292 by the CPU 291, the optical output level of the optical transmitter 25, the optical input level of the optical receiver 27, the temperature detected by the temperature sensor 293, and the like. The bias current of the laser diode 252 included in the optical transmitter 25 is controlled. The optical transmission control unit 29 converts the bias current control signal into a DA converter 294, and the Ib control unit 295 controls the bias current of the laser diode 252 using the bias current control signal. Further, as will be described later, the optical transmission control unit 29 controls the operation of the variable attenuator 24 according to the optical output level of the optical transmission unit 25 so that the optical output level of the upstream optical signal changes. The degree of light modulation can be adjusted to be constant.

  The optical transmission control unit 29 configured as described above has the upstream optical signal at the target optical input level based on the transmission loss of the optical signal transmitted by the CPU 291 between the optical terminal device 2 and the communication station 4. Is input to the communication station 4 to control the optical output level of the laser diode 252.

  In order to perform such control, the memory 292 inputs the downstream optical signal output level Pcf of the downstream optical signal output from the communication station 4 to the optical transmission line 3 and inputs from each optical terminal device 2 to the communication station 4. The target optical input level Pci of the upstream optical signal to be stored is stored in advance. The station-side light output level Pcf and the target light input level Pci are not limited to being stored in the same memory 292, and may be stored in different storage media.

  The CPU 291 performs transmission loss based on the station-side optical output level Pcf stored in the memory 292 and the optical input level detected by the optical input level detection unit 28 (hereinafter also referred to as the terminal-side optical input level Phi). calculate.

  As a specific example, assuming that the station-side optical output level Pcf = + 14 dBm and the terminal-side optical input level Phi = −8 dBm, the CPU 291 calculates 22 dB, which is the transmission loss of the downstream optical signal in the optical transmission path 3, from Pcf-Phi. To do. Since the downstream optical signal and the upstream optical signal are transmitted through the same transmission path 3, it is assumed that the transmission loss of both is equal. When the target station-side optical input level Pci = −20 dBm, the CPU 291 causes the optical transmitter 25 to input an optical signal to the communication station 4 at the target optical input level Pci according to the following equation. The terminal-side optical output level Phf output from can be calculated with high accuracy.

Phf = Pci + 22 = −20 + 22 = + 2 dBm
The uplink signal and the downlink signal have the same transmission loss but have different frequency bands. Therefore, the optical transmission control unit 29 may use the value obtained by correcting the transmission loss of the downstream optical signal based on the wavelength dependence of the transmission loss by the CPU 291 as the transmission loss of the upstream optical signal. Thereby, the optical signal of the target light input level Pci can be input to the communication station 4 with higher accuracy.

  In this way, the optical transmission control unit 29 controls the optical output level output from the optical transmission unit 25, so that the optical input level of the upstream optical signal input to the communication station 4 is near its lower limit value. Therefore, the optical beat noise can be reduced.

  Further, the optical transmission control unit 29 detects the environmental temperature of the laser diode 252 included in the optical transmission unit 25 by the temperature sensor 293, and the CPU 291 controls the optical output level of the laser diode 252 according to the environmental temperature. In order to perform such control, the memory 292 stores the following temperature characteristic information. That is, the memory 292 stores in advance a function or look-up table that indicates the correspondence between the environmental temperature and the light output level calculated from the bias current value of the laser diode 252.

  The CPU 291 reads temperature characteristic information corresponding to the environmental temperature detected by the temperature sensor 293 from the memory 292 and calculates a bias current value that obtains the optical output level Phf output from the optical transmitter 25. In this way, the optical transmission control unit 29 controls the optical output level Phf output from the optical transmission unit 25 with higher accuracy in consideration of the optical output characteristics that change according to the temperature of the laser diode 252. Can do.

  Further, the CPU 291 may correct the temperature characteristic information stored in the memory 292 based on the light output level of the monitor photodiode 253 notified from the light transmitter 25. In this way, the CPU 291 can correct the temperature characteristic of the laser diode 252 that changes over time, for example.

  Further, the CPU 291 controls the optical output level of the laser diode 252 of the optical transmission unit 25, and from the variable attenuator 24 so that the optical modulation degree of the optical signal transmitted by the optical transmission unit 25 becomes a predetermined value. The signal amplitude value of the output RF signal is changed. This is because the degree of modulation of the optical signal changes according to the optical output level, and when this change increases, the distortion characteristics deteriorate, and when this change decreases, the CNR deteriorates. In either case, the transmission characteristics deteriorate. It is. That is, the CPU 291 can prevent the optical modulation degree from changing by appropriately changing the signal amplitude level of the RF signal by the variable attenuator 24.

  Further, the optical transmission control unit 29 controls the operation of the optical transmission control unit 29 according to the detection result by the RF detection unit 23. That is, the optical transmission control unit 29 operates only during a period in which the CMs 211 and 212 output RF signals. In this way, the optical transmission control unit 29 operates at the transmission timing synchronized with the CMTSs 41 and 42 of the communication station 4, so that the burst optical signal corresponding to the RF signal supplied by the CMs 211 and 212 is obtained. Can be output.

  Next, the optical terminal device 5 according to the second embodiment will be described. The optical terminal device 5 according to the second embodiment has the same configuration as the optical terminal device 2 according to the first embodiment described above, and is further modulated by an optical signal transmitted from the communication station 4. A control signal demodulator 51 for demodulating the control signal. In addition, about the structure similar to the optical terminal device 2 which concerns on the 1st Example mentioned above, the same code | symbol is attached | subjected and the description shall be abbreviate | omitted.

  The control signal demodulating unit 51 includes a demultiplexing unit 511 that demultiplexes the RF signal received by the optical receiving unit 27, demodulates the control signal from the RF signal demultiplexed from the demultiplexing unit 511, and demodulates the control signal. Is supplied to the optical transmission control unit 29. For example, as shown in FIG. 3, the demultiplexing unit 511 is connected between the amplifiers 272 and 273. With such connection, the optical terminal device 5 can supply the RF signal converted from the upstream optical signal to the multiplexing / demultiplexing unit 22 at a desired signal level.

  The control signal demodulated by the control signal demodulator 51 is modulated by the communication station 4 and transmitted to the optical terminal device 5 as follows. In the communication station 4, for example, when the transmission loss of the upstream optical signal is larger than the transmission loss of the downstream optical signal, the optical input level received by the optical receiver 43 becomes smaller than the target. Including such specific examples, the communication station 4 may need to change the target light input level Pci.

  Therefore, in the communication station 4, the management device 47 transmits the target light input level Pci to the control information adder 48, and the control information adder 48 modulates the target light input level Pci into the RF signal as the control signal. The downstream optical signal is transmitted to the optical terminal device 5 by the optical transmitter 45.

  In addition, the communication station 47 may set the same target light input level Pci for all the optical terminal devices 5 connected via the optical transmission path 3, and is different for each optical terminal device 5. A value may be set.

  In the optical terminal device 5, when the optical reception unit 27 receives the optical signal in which the control signal is modulated, the control information demodulation unit 51 demodulates the control signal and supplies it to the optical transmission control unit 29. In the optical transmission controller 29, the CPU 291 changes the target light input level Pci stored in the memory 292 to the target light input level Pci indicated in the control signal from the control information demodulator 51.

  In this way, the optical terminal device 5 is configured so that the upstream optical signal is input to the communication station 4 with high accuracy at the target optical input level Pci changed according to the request from the communication station 4. 25 operations can be controlled.

  Of course, the optical terminal devices 2 and 5 to which the present invention is applied are not limited to the above-described embodiments, and various modifications are possible.

  1 optical transmission system, 2, 2a, 2b,..., 2n, 5 optical terminal device, 211, 212 CM, 22 multiplexing / demultiplexing unit, 23 RF detection unit, 231, 511 demultiplexing unit, 24 variable attenuator, 25 Optical transmitter, 251, 272, 273 Amplifier, 252 Laser diode, 253 Monitor photodiode, 254, 281 Resistive element, 255, 282 AD converter, 26, 46 WDM filter, 27 Optical receiver, 271 Photodiode, 28 light Input level detection unit, 29 Optical transmission control unit, 291, 481 CPU, 292 Memory, 293 Temperature sensor, 294 DA converter, 295 Ib control unit, 3, 31, 31a, 31b, ..., 31n, 32 Optical transmission line 3a, optical branching unit, 4 communication station, 41, 42 CMTS, 411, 421 upstream port 412, 422 downlink port, 43 an optical receiver, 44 a multiplexer, 45 an optical transmitter, 47 management unit, 48 control signal adder, 482 modulation unit, 51 control signal demodulator

Claims (8)

An optical receiver that receives an optical signal output from a communication station that is connected so as to be capable of transmitting optical signals in both directions via a single optical transmission line together with other optical terminal devices;
Based on the transmission timing controlled by the terminal devices that are asynchronous with each other installed in the communication station, burst optical signals in the same wavelength band as the other optical terminal devices are transmitted via the optical transmission line. An optical transmitter for transmitting to the communication station;
An optical input level detector that detects an optical input level of an optical signal received by the optical receiver; and
The optical output level of the optical signal output from the communication station to the optical transmission line and the target optical input level of the optical signal received by the communication station via the optical transmission line are stored. A storage unit;
A transmission loss calculation unit that calculates a transmission loss of the optical transmission line based on the optical output level stored in the storage unit and the optical input level detected by the optical input level detection unit,
Based on the transmission loss calculated by the transmission loss calculation unit, the optical transmission unit transmits the optical signal of the target optical input level stored in the storage unit to the optical transmission line so that the communication station receives the optical signal. An optical terminal device comprising: a control unit that controls an optical output level to be output. A temperature detection unit for detecting an environmental temperature of the optical transmission unit;
The storage unit further stores temperature characteristic information in which the environmental temperature of the optical transmission unit is associated with the light output level transmitted by the optical transmission unit,
The control unit is configured to input the target light input stored in the storage unit based on the transmission loss calculated by the transmission loss calculation unit and the temperature characteristic information corresponding to the environmental temperature detected by the temperature detection unit. 2. The optical terminal device according to claim 1, wherein an optical output level output from the optical transmission unit to the optical transmission line is controlled so that the communication station receives an optical signal of a level. The optical transmitter includes a laser diode that transmits an optical signal having an optical output level corresponding to a bias current, and a monitor photodiode that receives light output from the laser diode,
3. The optical terminal device according to claim 2, wherein the control unit corrects an optical output level indicated by the temperature characteristic information according to a light reception level received by the monitor photodiode. The optical terminal device further includes a transmission detection unit for detecting a transmission period for transmitting an optical signal in synchronization with each terminal device installed in the communication station,
2. The optical terminal apparatus according to claim 1, wherein the control unit controls an optical output level transmitted by the optical transmission unit only when the transmission detection unit detects that an optical signal is transmitted. A signal amplitude ratio adjusting unit for adjusting the signal amplitude ratio of the electrical signal;
The optical transmission unit converts the electrical signal adjusted by the signal amplitude ratio adjustment unit into an optical signal and transmits the optical signal,
The said control part controls the optical modulation degree of the optical signal transmitted by the said optical transmission part to become a predetermined value by changing the amplitude level of the said signal amplitude ratio adjustment part. Item 4. The optical terminal device according to Item 1. The optical signal received by the optical receiver includes information indicating the target optical input level,
The said control part demodulates the information which shows the target optical input level contained in the optical signal received by the said optical receiver, and changes the information memorize | stored in the said memory | storage part. The optical terminal device according to 1. A communication station where a plurality of asynchronous end devices are installed;
A plurality of optical terminal devices connected to the communication station so as to be able to transmit optical signals in both directions via a single optical transmission line;
The optical terminal device
An optical receiver for receiving an optical signal output from the communication station;
Based on the transmission timing controlled by each terminating device installed in the communication station, a burst-like optical signal having the same wavelength band as that of the other optical terminal device is transmitted to the communication station via the optical transmission line. An optical transmitter for transmitting to
An optical input level detector that detects an optical input level of an optical signal received by the optical receiver; and
The station-side optical output level of the optical signal output to the optical transmission line by the communication station and the target optical input level of the optical signal received by the communication station via the optical transmission line are stored. A storage unit;
A transmission loss calculation unit that calculates a transmission loss of the optical transmission line based on the optical output level stored in the storage unit and the optical input level detected by the optical input level detection unit,
Based on the transmission loss calculated by the transmission loss calculation unit, the optical transmission unit transmits the optical signal of the target optical input level stored in the storage unit to the optical transmission line so that the communication station receives the optical signal. An optical transmission system comprising: a control unit that controls an optical output level to be output. The communication station outputs an optical signal in which information indicating the target optical input level set for each optical terminal device is modulated,
The control unit of the optical terminal device demodulates information indicating the target optical input level included in the optical signal received by the optical receiving unit of the optical terminal device, and stores the demodulated information in the storage unit of the optical terminal device. 8. The optical transmission system according to claim 7, wherein the information is changed.