JP4541053B2 - Optical transmission system - Google Patents

Description

  The present invention relates to an optical transmission system applied to a plurality of service multiplexes using wavelength division multiplexing (WDM) technology.

  With the widespread use of high-speed lines such as ADSL and FTTH, various Internet services such as video distribution and 3D chat are provided. In the future, it is expected to provide a wide variety of services that require higher-speed lines. One means of network configuration that provides such a high-speed line is a time division multiplexing (TDMA) multi-access passive optical network (PON) represented by ITU-compliant B-PON (Broadband Passive Optical Network). In this B-PON, the accommodation efficiency of the service node is increased by branching the optical power with an optical splitter. A time slot is assigned to each subscriber terminal (ONU), and one-to-multipoint communication is realized by a time division multiplexing method.

  FIG. 7 shows a configuration example of the B-PON. Here, a service multiplexing system for multi-channel video distribution conforming to the wavelength arrangement of G.983.3 is assumed (Non-Patent Document 1).

  In the figure, the station apparatus 100 and a plurality of user apparatuses 201 to 204 are connected one-to-many via optical fiber transmission lines 301 to 304. The station apparatus 100 includes an optical subscriber service unit (OSU) 101 that performs data service, an OSU 105 that performs broadcast-type video service, a wavelength multiplexer / demultiplexer 151, and an optical splitter 161. The OSU 101 includes a light source 171 that transmits a downlink signal of a data service and a light receiver 141 that receives an uplink signal of the data service. The OSU 105 includes a light source 175 that transmits a broadcast-type video service signal. The user apparatus 201 includes an ONU 221 that receives a data service, an ONU 225 that receives a broadcast-type video service, and a wavelength multiplexer / demultiplexer 215. The ONU 221 includes a light receiver 231 that receives a downstream signal of a data service and a light source 251 that transmits an upstream signal of the data service. The ONU 225 includes a light receiver 235 that receives a broadcast-type video service signal.

  The downlink signal of the data service transmitted from the light source 171 of the OSU 101 of the station apparatus 100 and the video service signal transmitted from the light source 175 of the OSU 105 are wavelength-multiplexed by the wavelength multiplexer / demultiplexer 151 and branched by the optical splitter 161. It is sent to the optical fiber transmission line 301. The data service downlink signal and video service signal transmitted via the optical fiber transmission line 301 are demultiplexed by the wavelength multiplexer / demultiplexer 215 of the user apparatus 201, and the data service downlink signal is received by the optical receiver 231 of the ONU 221. Then, the video service signal is received by the light receiver 235 of the ONU 225. On the other hand, the upstream signal of the data service transmitted from the light source 251 of the ONU 221 passes through the wavelength multiplexer / demultiplexer 215 and is transmitted to the optical fiber transmission line 301. The upstream signal of the data service transmitted via the optical fiber transmission line 301 and the optical splitter 161 is demultiplexed by the wavelength multiplexer / demultiplexer 151 of the station apparatus 100 and received by the light receiver 141 of the OSU 101.

  Here, the downlink signal or the uplink signal of the data service corresponding to each user apparatus is assigned a predetermined time slot for each user apparatus and is time-division multiplexed. The video service signal is one-way communication only in the downlink direction and can be received simultaneously by the ONU 225 of each user apparatus.

  Further, there is a WDM-PON as a network configuration that provides a high-speed line. Since WDM-PON performs communication by assigning a wavelength to each user apparatus, it is logically equivalent to a point-to-point configuration, and an access line for occupying and using a wavelength for each user apparatus. The speed at is guaranteed.

  FIG. 8 shows a configuration example of WDM-PON (Patent Document 1). In the figure, a station apparatus 100 and a plurality of user apparatuses 201 are connected one-to-many via an optical fiber transmission line 301 and a wavelength multiplexer / demultiplexer 152. The station apparatus 100 includes an OSU 101 and a wavelength multiplexer / demultiplexer 151. The OSU 101 includes a light source 171 that transmits a downlink signal of a data service and a light receiver 141 that receives an uplink signal of the data service. The user device 201 includes an ONU 221. The ONU 221 includes a light receiver 231 that receives a downlink signal of a data service and a light source 251 that transmits an uplink signal of the data service.

  The downlink signal of the data service transmitted from the light source 171 of the OSU 101 of the station apparatus 100 is wavelength-multiplexed with downlink signals from other OSUs by the wavelength multiplexer / demultiplexer 151 and is transmitted to the optical fiber transmission line 301. The data service downlink signal transmitted through the optical fiber transmission line 301 is demultiplexed for each ONU by the wavelength multiplexer / demultiplexer 152 and received by the light receiver 231 of the ONU 221. On the other hand, the upstream signal of the data service transmitted from the light source 251 of the ONU 221 is combined with the upstream signal from another ONU by the wavelength multiplexer / demultiplexer 152 and transmitted to the station apparatus 100 via the optical fiber transmission line 301. The signal is demultiplexed by the wavelength multiplexer / demultiplexer 151 of the station apparatus 100 and received by the light receiver 141 of the OSU 101.

Here, in the B-PON shown in FIG. 7, the optical splitters 161 and 162 are used for branching, whereas in the WDM-PON shown in FIG. 8, the branching loss can be reduced by using the wavelength multiplexer / demultiplexer 152. There are benefits. Therefore, a large allowable loss between the station apparatus 100 and the user apparatus 200 can be ensured.
JP 2000-196536 A Standardization trend of B-PON system and future technical issues, IEICE Transactions B, Vol.J85-B, No.4, pp.438-452, April 2002

  In B-PON, since an optical splitter is used for branching, the branching loss increases as the number of branches increases, and the allowable loss assigned to the optical fiber transmission line decreases. In addition, in the service multiplexing configuration, as shown in FIG. 7, it is necessary to insert the wavelength multiplexer / demultiplexer 151 of the station apparatus 100 and the wavelength multiplexer / demultiplexer 215 of the user apparatus 201, and flexibly cope with the addition of services. Can not do it.

  On the other hand, in WDM-PON, since it is necessary to assign and set individual wavelengths to all the ONUs, the user apparatus that accommodates each ONU becomes an individual article, which increases operational restrictions. In addition, when a plurality of services are multiplexed in the WDM-PON configuration, the network configuration becomes complicated for transmission through a single optical fiber transmission line.

  An object of the present invention is to provide an optical transmission system that can increase the number of branches by reducing the total loss of components between transmission and reception, and further eliminate the wavelength dependency of user equipment and facilitate expansion.

The present invention relates to an optical transmission system in which a station apparatus and a plurality of user apparatuses are connected via an optical fiber transmission line, and a plurality of downlink signals corresponding to a plurality of services are transmitted from the station apparatus to each user apparatus. Corresponds to a plurality of services, and transmits a plurality of optical subscriber service devices (OSUs) of wideband optical spectrum in different wavelength bands at intervals of a predetermined cycle, and a cycle of an interval of a routing cycle equal to the predetermined cycle. Transmission characteristics, and a wideband optical spectrum downstream signal input from a plurality of station-side ports is spectrally sliced, and a single narrowband optical spectrum downstream signal is combined for all wavelength bands to a plurality of users. respectively output to the side port, and an AWG which sends to each user equipment from each of the user-side port, the user device passes A wavelength demultiplexer that frequency is present at equivalent period and intervals of the routing cycle of AWG, demultiplexed by the wavelength demultiplexer, each one wave narrow spectrally sliced from each downlink signal of the broadband light spectrum and a plurality of optical terminal apparatus for receiving respectively a downlink signal band light spectrum (ONU).

Further, the user apparatus includes means for transmitting upstream signals of broadband optical spectrums in different wavelength bands at intervals of the AWG routing period, unlike the wavelength band of downstream signals, and transmitted from the plurality of ONUs. Ru configuration der to transmit the uplink signal through a wavelength division multiplexer. Here, the uplink signal corresponding to each user apparatus is transmitted by the time division multiplexing method, and the corresponding user apparatus is identified by the assigned time slot.
Further, the station apparatus inputs the uplink signal transmitted from each user apparatus to each of the user side ports of the AWG, and obtains the required signal from the uplink signal of the spectrum-sliced narrowband optical spectrum output from each of the station side ports. In this configuration, each OSU receives the signal via an optical bandpass filter that passes only an upstream signal. (Claim 1 ).

Or, the station apparatus, between each OSU and AWG, each passband AWG two wavelengths demultiplexer present in equivalent period and intervals of the routing cycle and the two-wavelength division multiplexer each e further Bei an optical fiber transmission line connecting together the single-port side port, the two ports of one multi-port side of the wavelength division multiplexer is connected to each of the station-side ports of the AWG, broadband Each downstream signal of the optical spectrum is input to each of the other multi-port side ports of the two wavelength multiplexers / demultiplexers, and the upstream signal transmitted from each user apparatus is input to each of the AWG user side ports, Each of the OSUs receives a required upstream signal of a spectrum-sliced narrowband optical spectrum output from each of the other multi-port ports of the two wavelength multiplexers / demultiplexers. (Claim 2 ).

Also, in place of at least one broadband light source that generates a broadband optical spectrum downstream signal corresponding to each service, multiple downstream optical spectrum multiple signals are generated in different wavelength bands at intervals of the AWG routing period. A wavelength light source may be used (Claim 3 ).

  The present invention connects a station apparatus and a plurality of user apparatuses via a periodic filter (AWG), and spectrum-slices downstream signals of broadband optical spectrums in different wavelength bands corresponding to a plurality of services to each user apparatus. It can be transmitted and received by the ONU of each user device. In addition, upstream signals of broadband optical spectrums in different wavelength bands are wavelength-multiplexed and transmitted from each ONU of the user apparatus, and the upstream signal from each user apparatus is transmitted by a wavelength multiplexer / demultiplexer (AWG) having a periodicity of the transmission wavelength. Can be spectrally sliced and received by each OSU of the station apparatus. As a result, each user apparatus can cope with a common configuration that includes a wavelength multiplexer / demultiplexer, a light receiver, and a transmission unit corresponding to the wavelength band of the broadband optical spectrum in advance, thereby eliminating the wavelength dependence of the user apparatus. Can be expanded easily.

(First embodiment)
FIG. 1 shows a first embodiment of the optical transmission system of the present invention. In the figure, a station apparatus 100 and a plurality of user apparatuses 201 to 204 are connected via optical fiber transmission lines 301 to 304, respectively. The station apparatus 100 includes a plurality of OSUs 101 to 104 and a periodic filter (arrayed waveguide diffraction grating: AWG) 120. The OSUs 101 to 104 include broadband light sources 111 to 114 that transmit downlink signals of services 1 to 4 to be provided, respectively. The downstream signal of the broadband optical spectrum λ1 transmitted from the broadband light source 111 is input to the station side port 1 of the AWG 120, and the downstream signals of the narrowband optical spectra λ11, λ12, λ13, and λ14 spectrum-sliced from the user side ports 1-4. Is output as Similarly, the downstream signals of the broadband optical spectrums λ2 to λ4 transmitted from the broadband light sources 112 to 114 are input to the station side ports 2 to 4 of the AWG 120, respectively, and the narrowband optical spectrum is spectrally sliced from the user side ports 1 to 4. Output as downstream signals of λ21 to λ24, λ31 to λ34, and λ41 to λ44.

  Here, as shown in FIG. 2 (1), the wavelength bands of the broadband optical spectra λ1 to λ4 are arranged at intervals of the routing period (FSR) of the AWG 120, and the narrowband optical spectra λ11 to λ14, λ21 to λ24, respectively. Including λ31 to λ34 and λ41 to λ44. FIG. 3 shows the relationship between each port of the AWG 120 and the wavelength.

  Downstream signals of the narrowband optical spectra λ 11, λ 21, λ 31, λ 41 output from the user side port 1 of the AWG 120 are input to the user apparatus 201 via the optical fiber transmission line 301. The user apparatus 201 includes a wavelength multiplexer / demultiplexer 210 and a plurality of ONUs 221 to 224. As shown in FIG. 2 (2), the pass band of the wavelength multiplexer / demultiplexer 210 is equivalent to the FSR interval (wavelength band of the broadband optical spectrum λ1 to λ4) of the AWG 120, and the narrowband optical spectrum λ11, λ21, λ31. , Λ41 downstream signals are demultiplexed and input to the ONUs 221 to 224, respectively. The ONUs 221 to 224 include light receivers 231 to 234 corresponding to the wavelength bands of the broadband optical spectra λ1 to λ4, respectively, and receive downstream signals of the narrowband optical spectra λ11, λ21, λ31, and λ41 corresponding to the services 1 to 4. .

  The configurations of the user devices 202 to 204 connected to the user side ports 2 to 4 of the AWG 120 via the optical fiber transmission lines 302 to 304 are the same, and the wavelength multiplexer / demultiplexer 210 having the same passband as the user device 201 , ONUs 221 to 224 are provided with light receivers 231 to 234 corresponding to the wavelength bands of the broadband optical spectrum λ1 to λ4. Thereby, the user apparatus 202 receives downstream signals of the narrowband optical spectra λ12, λ22, λ32, and λ42 corresponding to the services 1 to 4, and the user apparatus 203 receives the narrowband optical spectra λ13 and λ23 corresponding to the services 1 to 4. , Λ33, λ43, and the user apparatus 204 receives the narrowband optical spectra λ14, λ24, λ34, λ44 corresponding to services 1 to 4.

  Thus, the broadband optical spectrum λ1 for transmitting the downlink signal of service 1 from the station apparatus 100 is spectrally sliced by the AWG 120 as downlink signals of the narrowband optical spectra λ11, λ12, λ13, and λ14, and the optical fiber transmission line 301 Are distributed to the user apparatuses 201 to 204 via the .about.304 and received by the light receiver 231 of the ONU 221 via the wavelength multiplexer / demultiplexer 210 having the same configuration. That is, the downlink signals of the narrow-band optical spectra λ11, λ12, λ13, and λ14 all have service 1 information, and the user apparatuses 201 to 204 can receive the service 1 downlink signals at the same time. The same applies to services 2-4.

(Second Embodiment)
FIG. 4 shows a second embodiment of the optical transmission system of the present invention. The feature of this embodiment is that the configuration of the first embodiment is extended to two-way communication. However, two optical fiber transmission lines, downstream and upstream, are used for bidirectional communication.

  In the figure, transmission of a downlink signal from the station apparatus 100 to each of the user apparatuses 201 to 204 is the same as that in the first embodiment, and the corresponding components are denoted by the same reference numerals. However, here, the station apparatus 100 includes the OSUs 101 and 102 that transmit the downstream signals of the services 1 and 2, and the ONUs 221 and 222 corresponding to the user apparatuses 201 to 204, respectively.

  In order to transmit an upstream signal from the user apparatus 201 to the station apparatus 100, broadband light sources 241 and 242 that transmit the upstream signal to the ONUs 221 and 222 are provided. The upstream signals of the broadband optical spectra λ 1 and λ 2 transmitted from the broadband light sources 241 and 242 are combined by the wavelength multiplexer / demultiplexer 211 and transmitted to the station apparatus 100 via the optical fiber transmission line 311. The pass bands of the wavelength multiplexers / demultiplexers 210 and 211 are the same.

  The upstream signals of the broadband optical spectra λ1 and λ2 transmitted from the user apparatuses 201 to 204 are respectively input to the user side ports of the AWG 121 of the station apparatus 100. At this time, uplink signals of the spectrum-sliced narrowband optical spectra λ11 to λ14 and λ21 to λ24 are output to the station side ports 1 and 2 of the AWG 121, respectively. The optical bandpass filter 131 connected to the station side port 1 of the AWG 121 selects the narrowband optical spectrums λ11 to λ14 that are spectrally sliced from the upstream signals of the broadband optical spectrum λ1 transmitted from the user apparatuses 201 to 204, respectively. The signal is input to the OSU 101 and received by the light receiver 141. Also, the optical bandpass filter 132 connected to the station side port 2 of the AWG 121 selects the narrowband optical spectrums λ21 to λ24 that are spectrally sliced from the upstream signals of the broadband optical spectrum λ2 transmitted from the user devices 201 to 204, respectively. The signal is input to the OSU 102 and received by the light receiver 142.

  In addition, the downstream signal and the upstream signal of the narrowband optical spectrum λ11 to λ14 corresponding to the ONU 221 of each user apparatus 201 to 204, or the downstream signal and the upstream signal of the narrowband optical spectrum λ21 to λ24 corresponding to the ONU 222 are time-division respectively. Each user is identified by the time slot allocated by the multiplexing method.

(Third embodiment)
FIG. 5 shows a third embodiment of the optical transmission system of the present invention. The feature of this embodiment is that the configuration of the first embodiment is extended to two-way communication. However, one optical fiber transmission line is used for bidirectional communication.

  In the figure, transmission of a downlink signal from the station apparatus 100 to each of the user apparatuses 201 to 204 is the same as that in the first embodiment, and the corresponding components are denoted by the same reference numerals. However, here, the station apparatus 100 includes the OSUs 101 and 102 that transmit the downstream signals of the services 1 and 2, and the ONUs 221 and 222 corresponding to the user apparatuses 201 to 204, respectively. Further, broadband optical spectra λ1 and λ2 are assigned to downstream signals of services 1 and 2, and broadband optical spectra λ3 and λ4 are assigned to corresponding upstream signals, respectively.

  In order to transmit an upstream signal from the user apparatus 201 to the station apparatus 100, broadband light sources 241 and 242 that transmit the upstream signal to the ONUs 221 and 222 are provided. The upstream signals of the broadband optical spectra λ 3 and λ 4 transmitted from the broadband light sources 241 and 242 are combined by the wavelength multiplexer / demultiplexer 210 and transmitted to the station apparatus 100 via the optical fiber transmission line 301. The pass band of the wavelength multiplexer / demultiplexer 210 is equivalent to the FSR interval (wavelength band of the broadband optical spectrum λ1 to λ4) of the AWG 120, as shown in FIG.

  The upstream signals of the broadband optical spectra λ3 and λ4 transmitted from the user apparatuses 201 to 204 are respectively input to the user side ports of the AWG 120 of the station apparatus 100. At this time, uplink signals of spectrum-sliced narrowband optical spectra λ31 to λ34 and λ41 to λ44 are output to the station side ports 3 and 4 of the AWG 121, respectively. The optical bandpass filter 131 connected to the station side port 3 of the AWG 121 selects the narrowband optical spectrums λ31 to λ34 that are spectrally sliced from the upstream signals of the broadband optical spectrum λ3 transmitted from the user apparatuses 201 to 204, respectively. The signal is input to the OSU 101 and received by the light receiver 141. Further, the optical bandpass filter 132 connected to the station side port 4 of the AWG 121 selects the narrowband optical spectrums λ41 to λ44 that are spectrally sliced from the upstream signals of the broadband optical spectrum λ4 transmitted from the user devices 201 to 204, respectively. The signal is input to the OSU 102 and received by the light receiver 142.

  In addition, the downstream signal of the narrowband optical spectrum λ11 to λ14 and the upstream signal of the narrowband optical spectrum λ31 to λ34 corresponding to the ONU 221 of each user apparatus 201 to 204, or the downstream signal of the narrowband optical spectrum λ21 to λ24 corresponding to the ONU 222. The uplink signals in the narrow-band optical spectrum λ41 to λ44 identify each user by a time slot assigned by the time division multiplexing method.

  Further, the upstream signals of the narrowband optical spectra λ31 to λ34 and λ41 to λ44, which are spectrum-sliced, are output to the station side ports 1 and 2 of the AWG 121 and are incident on the broadband light sources 111 and 112, respectively. Therefore, when the required reflection resistance cannot be obtained for the broadband light sources 111 and 112, an optical isolator is disposed to block the upstream signal.

(Fourth embodiment)
FIG. 6 shows a fourth embodiment of the optical transmission system of the present invention. The feature of this embodiment is that WDM transmission is performed between the OSUs 101 and 102 of the station apparatus 100 and the AWG 120 in the configuration of the third embodiment.

  In the figure, the downstream signals of the broadband optical spectrums λ 1 and λ 2 transmitted from the broadband light sources 111 and 112 of the OSUs 101 and 102 of the station apparatus 100 are combined by the wavelength multiplexer / demultiplexer 151 and passed through the optical fiber transmission line 321. Are transmitted to the wavelength multiplexer / demultiplexer 152, demultiplexed, and input to the station side ports 1 and 2 of the AWG 120, respectively. The pass bands of the wavelength multiplexer / demultiplexers 151 and 152 are the same as the wavelength multiplexer / demultiplexer 210 of the user apparatuses 201 to 204, and are equivalent to the FSR interval of the AWG 120. At this time, downlink signals of the spectrum-sliced narrowband optical spectra λ11 to λ14 and λ21 to λ24 are output to the user side ports 1 to 4 of the AWG 120.

  Downstream signals of the narrowband optical spectrums λ11 and λ21 output from the user side port 1 of the AWG 120 are input to the user apparatus 201 via the optical fiber transmission line 301, and are demultiplexed by the wavelength multiplexer / demultiplexer 210, and each ONU 221 is demultiplexed. Are received by the optical receivers 231 of .about.222. Downstream signals of narrowband optical spectra λ12 and λ22, downstream signals of narrowband optical spectra λ13 and λ23, which are input from user-side ports 2 to 4 of the AWG 120 to user apparatuses 202 to 204 via optical fiber transmission lines 302 to 304, Downstream signals of narrowband optical spectra λ14 and λ24 are also received.

  The upstream signals of the broadband optical spectra λ 3 and λ 4 transmitted from the broadband light sources 241 and 242 of the user apparatus 201 are combined by the wavelength multiplexer / demultiplexer 210 and input to the user side port 1 of the AWG 120 via the optical fiber transmission line 301. Is done. Similarly, the upstream signals of the broadband optical spectra λ3 and λ4 transmitted from the user devices 202 to 204 are input to the user side ports 2 to 4 of the AWG 120, respectively. At this time, the uplink signals of the narrowband optical spectrums λ31 to λ34 and λ41 to λ44, which are spectrum-sliced, are output to the station side ports 1 to 4 of the AWG 120, respectively, via the wavelength multiplexers / demultiplexers 151 and 152. The upstream signals of the narrowband optical spectra λ31 to λ34 and λ41 to λ44 are separated and received by the light receivers 141 and 142 of the corresponding OSUs 101 and 102, respectively.

  The uplink signals of the narrowband optical spectrum λ31 to λ34 or the uplink signals of the narrowband optical spectrum λ41 to λ44 corresponding to the user apparatuses 201 to 204 are assigned to each user in the time slot assigned by the time division multiplexing method. Identify.

(Other embodiments)
In the station apparatus 100 of the embodiment described above, a broadband light source corresponding to at least one service may be replaced with a multi-wavelength light source corresponding to a broadcast type service. The multi-wavelength light source generates a downstream signal having an optical spectrum corresponding to the transmission wavelength of the AWG 120 in advance. For example, in the configuration of the third embodiment shown in FIG. 5, when the narrowband optical spectrums λ21 and λ22 corresponding to the broadband optical spectrum λ2 are generated by the multi-wavelength light source of the OSU 102, the user devices 201 to 201 are demultiplexed by the AWG 120, respectively. 204 is transmitted to each ONU 222 of 204, and a broadcast type service is provided.

  Further, in the embodiment described above, an optical splitter may be used to branch an optical fiber transmission line so that a plurality of user devices can be accommodated like B-PON. However, in this configuration, the user is identified by a time slot assigned by the time division multiplexing method.

The figure which shows 1st Embodiment of the optical transmission system of this invention. The figure which shows the wavelength arrangement | positioning of a broadband optical spectrum, and the pass band of a wavelength multiplexer / demultiplexer. The figure which shows the relationship between each port of AWG, and a wavelength. The figure which shows 2nd Embodiment of the optical transmission system of this invention. The figure which shows 3rd Embodiment of the optical transmission system of this invention. The figure which shows 4th Embodiment of the optical transmission system of this invention. The figure which shows the structural example of B-PON. The figure which shows the structural example of WDM-PON.

Explanation of symbols

100 station equipment 101, 102, 103, 104, 105 optical subscriber service equipment (OSU)
111, 112, 113, 114 Broadband light source 120, 121 Periodic filter (AWG)
131,132 Optical bandpass filter (BPF)
141, 142 Light receiver 151, 152 Wavelength multiplexer / demultiplexer 161 Optical splitter 171, 175 Light source 201, 202, 203, 204 User equipment 210, 211, 215 Wavelength multiplexer / demultiplexer 221, 222, 223, 224, 225 Optical termination Equipment (ONU)
231, 232, 233, 234, 235 Light receiver 241, 242 Broadband light source 251 Light source 301, 302, 303, 304, 311, 312, 313, 314, 321 Optical fiber transmission line

Claims (3)

In an optical transmission system in which a station apparatus and a plurality of user apparatuses are connected via an optical fiber transmission line, and a plurality of downlink signals corresponding to a plurality of services are transmitted from the station apparatus to each user apparatus,
The station device is
A plurality of optical subscriber service devices (OSUs) corresponding to a plurality of services and transmitting downlink signals of broadband optical spectrums in different wavelength bands at predetermined intervals;
Downstream of each one narrowband optical spectrum obtained by spectrally slicing each downstream signal of the broadband optical spectrum having a periodic transmission characteristic at an interval of a routing period equal to the predetermined period and input from a plurality of station side ports An AWG that outputs signals to a plurality of user-side ports all together for all the wavelength bands, and sends the signals to each of the user devices from each of the user-side ports;
The user equipment is
A wavelength demultiplexer passband is present at equivalent period and intervals of the routing cycle of the AWG,
A plurality of optical termination units (ONUs) each receiving the one-wave narrowband optical spectrum downstream signals each demultiplexed by the wavelength multiplexer / demultiplexer and spectrum-sliced from the downstream optical spectrum downstream signals; equipped with a,
The user apparatus includes, in the plurality of ONUs, means for transmitting uplink signals in a wideband optical spectrum in different wavelength bands at intervals of the AWG routing period, unlike the wavelength band of the downlink signals. The transmitted upstream signal is configured to transmit via the wavelength multiplexer / demultiplexer,
The station apparatus inputs an uplink signal transmitted from each user apparatus to each of the user side ports of the AWG and outputs an uplink signal of a spectrum-sliced narrowband optical spectrum output from each of the station side ports. Is received by each OSU through an optical bandpass filter that passes only the required upstream signal from
The uplink signal corresponding to each of the user apparatuses is transmitted by a time division multiplexing method, and the corresponding user apparatus is identified by an assigned time slot . In an optical transmission system in which a station apparatus and a plurality of user apparatuses are connected via an optical fiber transmission line, and a plurality of downlink signals corresponding to a plurality of services are transmitted from the station apparatus to each user apparatus,
The station device is
A plurality of optical subscriber service devices (OSUs) corresponding to a plurality of services and transmitting downlink signals of broadband optical spectrums in different wavelength bands at predetermined intervals;
Downstream of each one narrowband optical spectrum obtained by spectrally slicing each downstream signal of the broadband optical spectrum having a periodic transmission characteristic at an interval of a routing period equal to the predetermined period and input from a plurality of station side ports An AWG that outputs signals to a plurality of user-side ports all together for all the wavelength bands, and sends the signals to each of the user devices from each of the user-side ports;
The user equipment is
A wavelength multiplexer / demultiplexer having a passband having a period equivalent to an interval of the routing period of the AWG;
A plurality of optical termination units (ONUs) each receiving the one-wave narrowband optical spectrum downstream signals each demultiplexed by the wavelength multiplexer / demultiplexer and spectrum-sliced from the downstream optical spectrum downstream signals; With
The user apparatus includes, in the plurality of ONUs, means for transmitting uplink signals in a wideband optical spectrum in different wavelength bands at intervals of the AWG routing period, unlike the wavelength band of the downlink signals. The transmitted upstream signal is configured to transmit via the wavelength multiplexer / demultiplexer,
The station apparatus, prior SL between each OSU and the AWG, two wavelength division multiplexer, each pass band is present in a comparable period and intervals of the routing cycle of the AWG and the two WDM An optical fiber transmission line that connects the ports on the single port side of each of the devices, and each of the multi-port side of each of the two wavelength multiplexers / demultiplexers is each of the station side ports of the AWG To each of the other multi-port ports of the two wavelength multiplexers / demultiplexers, and the uplink signal transmitted from each user apparatus is transmitted to the AWG. The spectrum-sliced narrowband optical spectrum is input to each of the user-side ports and output from each of the other multi-port ports of the two wavelength multiplexers / demultiplexers. The uplink signals of main and configured to receive each OSU,
The uplink signal corresponding to each of the user apparatuses is transmitted by a time division multiplexing method, and the corresponding user apparatus is identified by an assigned time slot . The optical transmission system according to claim 1 or 2,
Instead of at least one broadband light source that generates a downstream signal of the broadband optical spectrum corresponding to each service, a plurality of downstream signals of a narrowband optical spectrum are generated in different wavelength bands at intervals of the routing period of the AWG. An optical transmission system using a multi-wavelength light source.

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