JPWO2007083384A1 - Unidirectional transmission signal distribution method, station side apparatus and subscriber premises side apparatus in passive optical network system - Google Patents

Abstract

With respect to a one-way transmission signal distribution method, a station side device, and a subscriber premises side device in a passive optical network system, it is possible to easily design a signal-to-noise (S / N) ratio, and an expensive optical amplifier is unnecessary, Provided is a unidirectional transmission signal distribution method that can be easily distributed by an electric signal. The bit multiplexing unit 1-11 of the station side apparatus (OLT) 1-1 bit-multiplexes and transmits the digital signal of the unidirectional transmission signal only in the downlink direction and the main signal data of the passive optical network system. The bit separation unit 1-21 of the home-side apparatus 1-2 bit-separates the digital signal of the unidirectional transmission signal only in the downlink direction and the main signal data of the passive optical network system, and unidirectionally transmits the signal only in the downlink direction. And the video signal processing unit 1-22 processes the video signal of the one-way transmission signal.

Description

  The present invention relates to a one-way transmission signal distribution method, a station side apparatus, and a subscriber premises apparatus in a passive optical network system, and is conventionally performed in a passive optical network (PON) system using a wavelength multiplexing method for analog signals. The present invention relates to a technique for distributing and distributing video signals and the like by a simple bit multiplexing method using digital signals.

  A passive optical network (PON) system is a transmission method in which an optical signal transmitted through a single optical fiber is branched by an optical splitter, and a single optical fiber is shared by a plurality of users. : Optical Line Terminator) and optical fiber laying costs can be kept low. 983 series B-PON, G. It is recommended and standardized as 984 series G-PON.

  In addition, with the spread of high-speed Internet services, the IEEE 802.3 Working Group has been recommended as IEEE 802.3ah for fiber-to-the-home data communication services (FTTH: Fiber To The Home), and GE-PON (Gigabit Ethernet As a means for providing a more economical and faster FTTH system as a trademark (trademark) -PON), it has been introduced in the Japanese market from the end of 2004.

  However, passive optical network (PON) systems have absolute signal level losses due to the optical star coupler / splitter at the branch point. This increases as the number of branches increases. For example, in the case of 32 branches, the fixed loss is about 17 dB. In this case, the telecommunications carrier must design the device in consideration of this fixed loss.

  In particular, ITU-T G.I. If an attempt is made to perform frequency multiplexing analog transmission of an existing CATV (Community Antenna TeleVision) signal or the like by the wavelength multiplexing method defined in 983.3, the signal-to-noise (S / N) ratio with respect to noise superposition or When it is required to ensure a carrier-to-noise (C / N) ratio and to distribute and deliver a beautiful video signal, a high-power laser having excellent distortion characteristics is required.

  For this reason, an inexpensive and simple transmission means is required as an alternative means for analog transmission means for video signals by the wavelength multiplexing method or the like. In recent years, the flow of digitization has become a major trend in all fields, but there is a need for a technique that can distribute and distribute video signals easily and with high quality.

  In a passive optical network (PON) (hereinafter simply referred to as “PON”) system, the ITU-T G. As described in 983.3, a unidirectional transmission signal such as a video signal or the like only in the downstream direction is obtained by analog light by a wavelength multiplexing method in a wavelength band (for example, C band 1550 nm band) in which an analog optical amplifier can be used. Transmission has been used. This is because the set top box (STB) used for receiving broadcast waves, receiving coaxial CATV, and the like is effectively used and inexpensive.

  FIG. 11 shows an example of distribution / distribution of video signals and the like by analog optical transmission in a general PON system. As shown to (a) of the figure, the subscriber side communication devices (ONU # 1 to #n) 11-2 of a plurality of users are connected to the station side communication device (OLT) 11-1, and the optical star coupler / splitter 11 is provided. 3 is connected by an optical fiber branched by the -3, between the station side communication device (OLT) 11-1 and each subscriber home side communication device (ONU # 1 to #n) 11-2. Signal data (# 1, # 2, #n) is transmitted and received.

  The station side communication device (OLT) 11-1 receives the upstream burst optical signal transmitted in a time division manner from the plurality of subscriber home side communication devices (ONU # 1 to #n) 11-2 without collision. A transmission timing control instruction is issued to each of the subscriber premises communication devices (ONUs # 1 to #n) 11-2. Also, the downstream optical signal with the respective destination address is distributed to each subscriber premises communication device (ONU # 1 to #n) 11-2.

  ITU-T G. As a wavelength arrangement in wavelength division multiplexing (WDM) according to 983.3, as shown in FIG. 5B, for the main signal data of PON, a wavelength band of 1260 nm to 1360 nm for the upstream signal, The wavelength range of 1480-1500 nm is standardized for G-PON and GE-PON for downstream signals. The 1550 nm wavelength band can be overlaid for video signal distribution. For this reason, a signal such as a video signal is wavelength-multiplexed at a wavelength different from the transmission wavelength of the main signal data of the PON system and transmitted as an analog signal.

  FIG. 12 shows a transmission / reception circuit configuration example of a station side communication device (OLT) and a subscriber premises side communication device (ONU / ONT) of a conventional PON system. (A) of the figure is a transmission / reception circuit configuration in GE-PON conforming to IEEE 802.3ah, and (b) of FIG. 984. 2 shows a transmission / reception circuit configuration in G-PON conforming to x.

  In the figure, 12-1 is an interface unit with Ethernet (registered trademark), 12-2 is a priority class (QoS) control unit in the MAC layer, 12-3 is a PON processing unit that performs address processing of the PON layer, and the like. 12-4 is a laser diode, 12-5 is a photo detector or avalanche photo detector, 12-6 is a wavelength multiplexing / demultiplexing unit for wavelength multiplexing / demultiplexing optical signals in the upstream wavelength band and downstream wavelength band, and 12-7 is a video signal extraction. The circuit, 12-8 is a distributed feedback laser diode, 12-9 is an interface unit with Ethernet (registered trademark) ATM / TDM, and 12-10 is a priority class (QoS) control unit.

  As shown in the figure, the video delivery signal is delivered by overlaying the main signal of PON output from the wavelength multiplexing / separating unit 12-6 of the station side communication device (OLT) by wavelength multiplexing. In the home-side communication device (ONU / ONT), it is separated by the wavelength multiplexing / separation unit 12-6, extracted by the video signal extraction circuit 12-7, and output as a video signal.

  On the other hand, there is a form of video signal distribution by multicast type data distribution (Video on Demand, etc.) as distribution / distribution of video signals. The video signal in this form is transmitted in a format multiplexed with the main signal data signal in response to a request from a distribution requester. FIG. 13 shows an example of spectrum arrangement of signals such as analog video to be multiplexed. 13-1 is an upstream channel by QPSK, 13-2 is a downstream channel by AM VSB or QAM, and 13-3 is an additional channel for video signal distribution by VOD or the like.

As prior art documents related to the present invention, Ethernet (registered trademark) passive optical subscriber networks for broadcasting and communication fusion are described in the following Patent Documents 1 to 3.
Japanese Patent Laying-Open No. 2005-210715 JP 2005-110247 A JP-A-2005-27302

  As described above, in the distribution / distribution of video signals and the like by analog optical transmission in the PON system, it is necessary to design a troublesome signal-to-noise (S / N) ratio with respect to the loss of optical branching peculiar to PON. There is also a need for expensive optical amplifiers for the distribution of analog optical signals. Also, in multicast type data distribution in which a video signal is distributed by being multiplexed with main signal data upon request, the video signal is transmitted in a unidirectional transmission format only in the downlink direction as in a broadcast service, that is, with the main signal and Is not transmitted as a separate signal, the band of the main signal data is used.

  The present invention employs a digital transmission system for distribution and distribution of video signals and the like in a PON system, thereby making it possible to easily design a signal-to-noise (S / N) ratio compared to an analog transmission system. Another object of the present invention is to provide a one-way transmission signal distribution method that eliminates the need for expensive optical amplifiers and facilitates distribution using electrical signals.

  The unidirectional transmission signal distribution method in the passive optical network system of the present invention comprises (1) a subscriber premises apparatus and a station premises apparatus connected to the subscriber premises apparatus by an optical fiber via an optical splitter. The station side device includes means for instructing transmission timing control of the subscriber home side device for receiving, without collision, an upstream burst optical signal transmitted in a time division manner from a plurality of subscriber home side devices; In a passive optical network system comprising means for distributing a downstream optical signal with a destination address for each side device, the station side device includes a digital signal of a unidirectional transmission signal only in the downstream direction, and the passive optical network system The main signal data is bit-multiplexed and transmitted, and at the subscriber premises equipment, the digital signal of the one-way transmission signal only in the downlink direction and the main signal data of the passive optical network system are bit-separated, and the downlink direction And extracting the Mino unidirectional transmission signal.

  (2) The passive optical network system is a bi-directional transmission system for an uplink signal / downstream signal 1 Gbps, which is a standardized system defined in IEEE 802.3ah, and only in the downlink direction where the bit multiplexing and demultiplexing is performed. The unidirectional transmission signal is a signal having the same information rate and code conversion format as the bidirectional transmission system.

  (3) The passive optical network system is an ITU-T G. 984.3, an uplink signal / downstream signal 1.2448 Gbps bidirectional transmission system, wherein the downlink multiplexed and unidirectional transmission signal only in the downstream direction is the same as the bidirectional transmission system. It is a signal of an information rate and a code conversion format.

  (4) The passive optical network system is an ITU-T G. 984.3, an upstream signal / downstream signal 1.2448 Gbps bidirectional method, wherein the bit-multiplexed and demultiplexed unidirectional transmission signal only in the downstream direction has the same information as the bidirectional transmission method. It is characterized by being a signal in a code conversion format that differs from the bidirectional transmission system in terms of speed.

  (5) The passive optical network system regenerates the one-way transmission signal, and a subscriber premises apparatus that does not include a receiving unit that reproduces the bit-multiplexed one-way transmission signal only in the downlink direction. It is a passive optical network system in which a subscriber premises apparatus having a receiving unit is mixed.

  (6) The station side device transmits the bit-multiplexed unidirectional transmission signal only in the downlink direction with an identifier indicating that the signal is a unidirectional transmission signal only in the downlink direction. The subscriber premises apparatus determines whether the identifier is normally received and controls the bit separation position according to the determination result.

  (7) When the main signal data of the bit-separated passive optical network system is normally received in the subscriber premises apparatus, and the main signal data is not normally received for a predetermined time. The bit separation position is controlled to be changed.

  Further, (8) the unidirectional transmission only in the downlink direction from the station side device is a signal obtained by bit-multiplexing a plurality of transmission signals, and the subscriber premises device has a unidirectional transmission only in the downlink direction. The transmission signal is bit-separated into a plurality of transmission signals.

  (9) The passive optical network system includes a subscriber premises apparatus that does not include a receiving unit that reproduces a unidirectional transmission signal only in the downlink direction in which the plurality of transmission signals are bit-multiplexed, and the unidirectional It is a passive optical network system in which a plurality of types of subscriber premises apparatuses having different numbers of receiving units for reproducing transmission signals are mixed.

  (10) The station-side device transmits a wavelength-multiplexed digital signal of a unidirectional transmission signal only in the downlink direction obtained by bit-multiplexing a plurality of transmission signals and main signal data of the passive optical network system. In the subscriber premises apparatus, the digital signal of the one-way transmission signal only in the downlink direction and the main signal data of the passive optical network system are wavelength-separated, and the one-way transmission signal only in the downlink direction is bit-separated And extracting.

  (11) The downstream signal of the passive optical network system is a downstream signal 1 Gbps transmission signal, which is a standardized method defined in IEEE 802.3ah, and is only one-way in the downstream direction where the bit multiplexing and demultiplexing is performed. The transmission signal is a signal having the same information rate and code conversion format as the transmission signal.

  (12) The downstream signal of the passive optical network system is ITU-T G.264. A downlink signal 1.2448 Gbps transmission signal defined in 984.3, wherein the downlink unidirectional transmission signal to be multiplexed and separated is a signal having the same information rate and code conversion format as the transmission signal. It is characterized by being.

  (13) The downstream signal of the passive optical network system is ITU-T G.264. 984.3 Downstream signal 1.2448 Gbps transmission signal defined in 984.3, where the bit-multiplexed and demultiplexed unidirectional transmission signal only in the downstream direction has the same information rate as the transmission signal and the transmission signal It is a signal of a different code conversion format.

  (14) The station side apparatus transmits the bit-multiplexed downlink only one-way transmission signal with an identifier indicating that the signal is a downlink only one-way transmission signal. The subscriber premises apparatus determines whether the identifier is normally received and controls the bit separation position according to the determination result.

  (15) The passive optical network system includes a subscriber premises apparatus that does not include a receiving unit that reproduces only a unidirectional transmission signal in a downlink direction in which a plurality of transmission signals are bit-multiplexed, and the unidirectional transmission. It is a passive optical network system in which a plurality of types of subscriber premises apparatuses with different numbers of receiving units for reproducing signals are mixed.

  (16) In the station side apparatus, an identifier is added to each transmission signal to the unidirectional transmission signal only in the downlink direction in which a plurality of transmission signals are bit-multiplexed, and transmitted to the subscriber premises apparatus. Then, it is determined whether the identifier of the specific transmission signal is normally received, and the bit separation position is controlled according to the determination result.

  The station side device of the passive optical network system of the present invention is (17) connected to a plurality of subscriber premises devices via optical splitters and transmitted from a plurality of subscriber premises devices in a time division manner. Means for instructing transmission timing control of the subscriber premises equipment for receiving the upstream burst optical signal without collision, and means for distributing the downstream optical signal with the destination address for each subscriber premises equipment, passively In a station side apparatus constituting an optical network system, a bit multiplexing means for bit-multiplexing a digital signal of a unidirectional transmission signal only in the downlink direction and main signal data of the passive optical network system, and multiplexing by the bit multiplexing means Means for transmitting the converted downlink signal to the subscriber premises apparatus.

  Further, the subscriber premises apparatus of the passive optical network system of the present invention is (18) connected to the station side apparatus by an optical fiber via an optical splitter, and according to a transmission timing control instruction from the station side apparatus, an upstream burst optical signal In a time division manner without collision and means for receiving a downstream optical signal with a destination address from the station side device, in the subscriber premises side device constituting the passive optical network system, from the downstream signal A bit-separated bit-separated digital signal of a unidirectional transmission signal only in the downstream direction and main signal data of the passive optical network system, and a downstream direction separated by the bit-separating unit. Means for extracting only one-way transmission signals.

  According to the present invention, in the distribution / distribution of the unidirectional transmission signal only in the downstream direction such as the video signal in the passive optical network system, the main signal data of the passive optical network system and the digital signal of the unidirectional transmission signal are converted into bits. Multiplexed by multiplexing and transmitted by digital transmission method, it is possible to distribute and distribute unidirectional transmission signals such as video signals only in the downlink direction using inexpensive passive optical network systems And cost reduction.

  In addition, by simple bit multiplexing and demultiplexing, the main signal system can distribute and distribute only one-way transmission signals such as video signals as separate signals from the main signal data of the passive optical network system. It is possible to distribute a unidirectional transmission signal only in the downlink direction such as a video signal without affecting the bandwidth of the data signal.

It is a figure which shows the structure of the 1st thru | or 5th embodiment of this invention. It is a figure which shows the 6th Embodiment of this invention. It is a figure which shows the 7th Embodiment of this invention. It is a figure which shows the 8th Embodiment of this invention. It is a figure which shows the 9th Embodiment of this invention. It is a figure which shows the 10th and 11th embodiment of this invention. It is a figure which shows the 12th Embodiment of this invention. It is a figure which shows the 13th Embodiment of this invention. It is a figure which shows the 14th Embodiment of this invention. It is a figure which shows 15th and 16th embodiment of this invention. It is a figure which shows an example of delivery and distribution of a video signal etc. by the analog optical transmission in a general PON system. It is a figure which shows the example of a transmission / reception circuit structure of the station side communication apparatus (OLT) of a conventional PON system, and a subscriber home side communication apparatus (ONU / ONT). It is a figure which shows the spectrum arrangement | positioning example of signals, such as an analog image | video multiplexed.

Explanation of symbols

1-1 Station side equipment (OLT)
1-2 Subscriber premises equipment (ONU)
1-3 Optical splitter 1-11 Bit multiplexing unit 1-21 Bit separation unit 1-22 Video signal processing unit 12-5 Avalanche photodetector 12-6 Wavelength multiplexing / separation unit 12-8 Distributed feedback laser diode (DFB-LD)
12-9 Interface unit with Ethernet (registered trademark) ATM / TDM 12-10 Priority class (QoS) control unit

  FIG. 1 shows the configuration of the first embodiment of the present invention. As shown in the figure, the PON system is connected to a plurality of customer premises equipment (ONU: Optical Network Unit / ONT: 1-2) via an optical fiber via an optical splitter 1-3. It is comprised with the station side apparatus (OLT: Optical Line Terminator) 1-1.

  The station side device (OLT) 1-1 is a subscriber home side device (ONT) for receiving uplink burst optical signals transmitted in a time division manner from a plurality of subscriber home side devices (ONU) 1-2 without collision. / ONU) 1-2 for sending transmission timing control instruction (not shown) and means for distributing a downstream optical signal with a destination address for each subscriber premises equipment (ONT / ONU) 1-2 (not shown) ). In the subscriber premises equipment (ONT / ONU) 1-2 and the station equipment (OLT) 1-1, the same components as those in the conventional configuration shown in FIG. The explanations made are omitted.

  In the above PON system, the digital signal of the unidirectional transmission signal only in the downstream direction such as the video signal is bit-multiplexed with the main signal data of the PON by the bit multiplexing unit 1-11 of the station side apparatus (OLT) 1-1. Then, it is converted into an optical signal by a distributed feedback laser diode (DFB-LD) 12-8 and transmitted.

  In the subscriber premises equipment (ONT / ONU) 1-2, the received optical signal is converted into an electric signal by the photo detector or the avalanche photo detector 12-5, and the bit separation unit 1-21 performs only the down direction of the video signal or the like. By separating the digital signal of the unidirectional transmission signal and the main signal data of the PON into bits, and demodulating the digital signal of the unidirectional transmission signal only in the downstream direction by the video signal processing unit 1-22 Distribute

  As a second embodiment of the present invention, the above-described PON system is an uplink signal / downstream signal 1 Gbps bidirectional transmission system (the optical transmission speed is 1.25 Gbps after 8B10B code conversion), which is a standardized system defined in IEEE 802.3ah. And a unidirectional transmission signal only in the downlink direction that is bit-multiplexed / separated is a signal having the same information rate and the same code conversion format as the bidirectional transmission method (the optical transmission rate is 8B10B). Converted to 1.25 Gbps).

  As a third embodiment of the present invention, the PON system described above is an ITU-T G. Upstream signal / downstream signal 1.2448 Gbps bidirectional transmission system (optical transmission rate is 155.52 × N (N: integer); in this case, N = 8), which is defined in a recommendation document such as 984.3, and bit multiplexing The unidirectional transmission signal only in the downlink direction to be converted / separated is a signal having the same information rate as the bidirectional transmission method (the optical transmission rate is the downlink signal 1.2448 Gbps) and the same code conversion format. Can do.

  As a fourth embodiment of the present invention, the PON system described above is an ITU-T G. Upstream signal / downstream signal 1.2448 Gbps bidirectional transmission system (optical transmission rate is 155.52 × N (N: integer); in this case, N = 8), which is defined in a recommendation document such as 984.3, and bit multiplexing A single-directional transmission signal only in the downlink direction to be converted / separated is a signal having the same transmission speed as that of the bidirectional transmission method but having a different code conversion format (8B10B code conversion usually used in Ethernet (registered trademark)). (The optical transmission rate can be a downlink signal of 1.2448 Gbps).

  As a fifth embodiment of the present invention, in the above-described PON system, a subscriber premises apparatus (ONT / ONU) 1-2 including a video signal processing unit 1-22, and a bit-multiplexed downlink direction only Although there is a means up to a bit separation unit 1-21 for separating the bit of the unidirectional transmission signal and the main signal data of the PON, the subscription does not include a reception unit for reproducing the video signal of the unidirectional transmission only in the downstream direction. The present invention can be applied to a PON system in which a customer premises device (ONT / ONU) (not shown) is mixed. The subscriber premises equipment (ONT / ONU) that does not include the video signal processing unit 1-22 receives only the data service in the PON system without receiving the distribution distribution of the downstream video.

  FIG. 2 shows a sixth embodiment of the present invention. In the sixth embodiment, an identifier indicating that a unidirectional transmission signal only in the downlink direction such as a video signal is a special packet signal in a unidirectional transmission signal only in the downlink direction such as a video signal to be bit-multiplexed. First, the subscriber premises equipment (ONT / ONU) 1-2 inputs the signal separated by the bit separation unit 1-21 to the video signal processing unit 1-22, and the video signal processing unit 1 In −22, it is determined whether the identifier is normally received from the input signal, and the video signal processing unit 1-22 generates a bit separation control signal corresponding to the determination result, and the bit separation control signal The bit separation position of the bit separation unit 1-21 is controlled.

  That is, when the above-mentioned identifier is normally received by the video signal processing unit 1-22, the bit separation control signal that leaves the bit extraction position of the unidirectional transmission signal only in the downlink direction in the bit separation unit 1-21 as it is. Is not received normally, the bit separation control for exchanging the bit extraction position of the unidirectional transmission signal only in the downlink direction and the bit extraction position of the PON main signal data in the bit separation unit 1-21 Generate a signal.

  A seventh embodiment of the present invention is shown in FIG. In the seventh embodiment, the subscriber premises equipment (ONT / ONU) 1-2 inputs the signal separated by the bit separation unit 1-21 to the PON processing unit 12-3, and the PON processing unit 12 -3 determines whether or not the input PON signal is normally received, generates a bit separation control signal corresponding to the determination result in the PON processing unit 12-3, and performs bit separation by the bit separation control signal The bit separation position of the conversion unit 1-21 is controlled.

  When the PON signal is normally received by the PON processing unit 12-3, a bit separation control signal is generated that leaves the bit extraction position of the unidirectional transmission signal only in the downlink direction in the bit separation unit 1-21 as it is, If not normally received, a bit separation control signal is generated for switching the bit extraction position of the unidirectional transmission signal only in the downlink direction and the bit extraction position of the PON main signal data in the bit separation unit 1-21. .

  FIG. 4 shows an eighth embodiment of the present invention. In the eighth embodiment, a unidirectional transmission signal only in the downlink direction, such as a bit-multiplexed video signal, is obtained by bit-multiplexing a plurality of transmission signals in the bit multiplexing unit 4-1, and a station side device (OLT) ) The downlink PON signal from 1-1 is bit-multiplexed by the bit multiplexer 1-11 with a downlink only unidirectional transmission signal obtained by bit-multiplexing the plurality of transmission signals, and a distributed feedback laser diode (DFB). -LD) It is converted into an optical signal by 12-8 and transmitted.

  In the subscriber premises equipment (ONT / ONU) 1-2, the received optical signal is converted into an electric signal by the photo detector or the avalanche photo detector 12-5, and the bit separation unit 1-21 performs only the down direction of the video signal or the like. The digital signal of the unidirectional transmission signal and the main signal data of the PON are separated into bits, and further, the unidirectional transmission signal only in the downstream direction is separated into a plurality of transmission signals by the bit separation unit 4-2. Is demodulated by the video signal processing unit 1-22 so that a plurality of video signals and the like can be distributed and received. In FIG. 4, video signals and the like that have undergone 1 to 4 bit multiplexing are further subjected to 1 to 2 bit multiplexing, and in the customer premises equipment (ONT / ONU) 1-2, the reverse bit separation is performed. The example which performs is shown.

  A ninth embodiment of the present invention is shown in FIG. In this embodiment, as in the eighth embodiment, a unidirectional transmission signal only in the downlink direction such as a video signal to be bit-multiplexed is obtained by bit-multiplexing a plurality of transmission signals. (ONT / ONU) 1-2 includes a bit separation unit 1-21 that performs bit separation on a double-bit multiplexed downlink signal, but receives a unidirectional transmission signal only in the downlink direction and receives a video signal. As a video signal processing unit 1-22 for reproducing (a) one having three receiving / reproducing units, (b) having two receiving / reproducing units, and (c) having one receiving / reproducing unit. Multiple types of customer premises equipment (ONT / ONU) 1-2 with different numbers of receiving / playback units, such as (d) those without video signal processing unit 1-22 This is applied to the PON system.

  A tenth embodiment of the present invention is shown in FIG. In FIG. 6, the PON system is a PON system similar to that shown in FIG. This embodiment is an embodiment in which a unidirectional transmission digital signal only in the downstream direction such as a video signal is multiplexed with a downstream PON signal from the station side apparatus (OLT) 1-1 by a wavelength multiplexing method. As a unidirectional transmission digital signal only in the downstream direction, a plurality of transmission signals are bit-multiplexed by the bit multiplexer 6-1 and transmitted, and the video signal extraction circuit 6 of the subscriber premises equipment (ONT / ONU) 1-2 is transmitted. -2, by separating the plurality of transmission signals into bits, it is possible to distribute and receive one-way transmission digital signals such as video signals only in the downstream direction.

  In the eleventh embodiment of the present invention, the downlink one-way transmission digital signal such as the video signal of the tenth embodiment is a downlink signal 1 Gbps transmission method (optical) which is a standardized method defined in IEEE 802.3ah. The transmission speed is 8B10B code-converted and is 1.25 Gbps), and the unidirectional transmission digital signal only in the downlink direction that is bit-multiplexed / separated also has the same information speed and the same code conversion format. (The optical transmission speed is 1.25 Gbps after 8B10B conversion).

  A twelfth embodiment of the present invention is shown in FIG. In this embodiment, a unidirectional transmission digital signal only in the downlink direction, such as a video signal in the tenth embodiment, is converted into an ITU-T G. Downstream signal 1.2448 Gbps transmission system (optical transmission rate is 155.52 × N (N: integer); N = 8 in this case) defined in the recommendation of 984.3, etc., and bit multiplexed / separated The unidirectional transmission digital signal only in the downlink direction has the same information speed and the same code conversion format (the optical transmission speed is the downlink 1.2448 Gbps system).

  A thirteenth embodiment of the present invention is shown in FIG. In this embodiment, a unidirectional transmission digital signal only in the downlink direction, such as a video signal in the tenth embodiment described above, is transmitted as a TU-TG. Downlink signal 1.2448 Gbps transmission system (optical transmission rate is 155.52 × N (N integer); N = 8 in this case) defined in the recommendation of 984.3, etc. Unidirectional transmission digital signals with only one direction have the same transmission rate, but signals of different code conversion formats (signals of the 8B10B code format normally used in Ethernet (registered trademark) (the optical transmission rate is the 1.2448 Gbps downlink)) ).

  A fourteenth embodiment of the present invention is shown in FIG. In this embodiment, an identifier indicating that the signal is a unidirectional transmission signal only in the downlink direction such as a video signal is added as a special packet signal to the bit-multiplexed digital signal in the tenth embodiment. In the subscriber premises equipment (ONT / ONU) 1-2, the signal separated by the bit separation unit 1-21 is input to the video signal processing unit 1-22, and the video signal processing unit 1- 22 determines whether or not the above-mentioned identifier has been normally received from the signal input at 22, generates a bit separation control signal according to the determination result at the video signal processing unit 1-22, and performs bit separation by the bit separation control signal The bit separation position of the conversion unit 1-21 is controlled.

  A fifteenth embodiment of the present invention is shown in FIG. In this embodiment, a unidirectional transmission digital signal only in the downlink direction such as a video signal is wavelength-multiplexed, and a unidirectional transmission signal only in the downlink direction such as a bit multiplexed video signal is a plurality of transmission signals. In the PON system that distributes the bit multiplexed signal, as the subscriber premises equipment (ONT / ONU) 1-2, the bit separation unit 1-21 that performs bit separation of the double bit multiplexed downlink signal is performed. The video signal processing unit 1-22 that receives a unidirectional transmission signal only in the downstream direction and reproduces the video signal includes (a) three reception / reproduction units, and (b) a reception / reproduction unit. Plurality in which the number of reception / reproduction units included is different, such as two provided, (c) one reception / reproduction unit, and (d) one not provided with the video signal processing unit 1-22. Type of subscriber premises equipment (ON / ONU) 1-2 is applied to a PON system coexist.

  The sixteenth embodiment of the present invention is the same as the fifteenth embodiment described above in that bit multiplexing is performed so that the subscriber premises equipment (ONT / ONU) 1-2 can reproduce the video signal desired by the user. Is transmitted by superimposing an identifier (packet signal, etc.) of the signal on a unidirectional transmission digital signal only in the downstream direction such as a video signal to be converted, and the subscriber premises equipment (ONT / ONU) 1-2 receives a bit. The signal bit-separated by the demultiplexing unit 1-21 is input to the video signal processing unit 1-22, and the video signal identifier desired by the user is normally received from the signal input by the video signal processing unit 1-22. The bit separation control signal is generated based on the determination result, and the bit separation position of the bit separation unit 1-21 is controlled by the bit separation control signal.

  The first to sixteenth embodiments described above have IEEE 802.3ah speed of 1.25 Gbps, and ITU-T G.1. 984.3 speed is 1.2448 Gbps (= 155.52 Mbps × 8 times), but the speed combination is not limited to this, and the Ethernet (registered trademark) interface (transmission speed: 125 Mbps, information speed: 100 Mbps) ) And any combination of the SDH frame rate of 155.52 Mbps.

  In the tenth to sixteenth embodiments described above, ITU-T G. 983.3 can be configured based on the wavelength arrangement (see FIG. 11B), but the wavelength when multiplexing the unidirectional transmission digital signal only in the downstream direction such as the video signal is as follows. The present invention is applicable not only to the 1550 nm band (C band) but also to the L band of the 1600 nm band scheduled to be used in the future.

Claims (18)

It comprises a plurality of subscriber premises equipment, and a station side equipment connected to the subscriber premises equipment by an optical fiber via an optical splitter, and the station side equipment is time-shared from the plurality of subscriber premises equipment. Means for instructing transmission timing control of the subscriber premises equipment for receiving the upstream burst optical signal transmitted by the mobile terminal without collision, and means for distributing the downstream optical signal with the destination address for each subscriber premises equipment In the provided passive optical network system,
In the station side device, the digital signal of the unidirectional transmission signal only in the downlink direction and the main signal data of the passive optical network system are bit-multiplexed and transmitted,
In the subscriber premises equipment, the digital signal of the unidirectional transmission signal only in the downlink direction and the main signal data of the passive optical network system are bit-separated, and the unidirectional transmission signal only in the downlink direction is extracted. A unidirectional transmission signal distribution method in a passive optical network system.   The passive optical network system is a bidirectional transmission system of 1 Gbps upstream signal / downstream signal that is a standardized system defined in IEEE 802.3ah, and is a unidirectional transmission signal only in the downstream direction that is multiplexed and separated by the bit. 2. The unidirectional transmission signal distribution method in the passive optical network system according to claim 1, wherein the signal is a signal having the same information rate and code conversion format as the bidirectional transmission system.   The passive optical network system is an ITU-TG. 984.3, an uplink signal / downstream signal 1.2448 Gbps bidirectional transmission system, wherein the downlink multiplexed and unidirectional transmission signal only in the downstream direction is the same as the bidirectional transmission system. 2. The one-way transmission signal distribution method in a passive optical network system according to claim 1, wherein the signal is an information rate and code conversion type signal.   The passive optical network system is an ITU-TG. 984.3, an upstream signal / downstream signal 1.2448 Gbps bidirectional method, wherein the bit-multiplexed and demultiplexed unidirectional transmission signal only in the downstream direction has the same information as the bidirectional transmission method. The unidirectional transmission signal distribution method in the passive optical network system according to claim 1, wherein the signal is in a code conversion format different from the bidirectional transmission system at a speed.   The passive optical network system includes a subscriber premises apparatus that does not include a receiving unit that reproduces the bit-multiplexed unidirectional transmission signal only in the downlink direction, and a receiving unit that reproduces the unidirectional transmission signal. 2. The one-way transmission signal distribution method in the passive optical network system according to claim 1, wherein the one is a passive optical network system in which a subscriber premises apparatus is mixed. In the station side device, the bit-multiplexed unidirectional transmission signal only in the downlink direction is added with an identifier indicating that the signal is a unidirectional transmission signal only in the downlink direction, and transmitted.
The one-way in the passive optical network system according to claim 1, wherein the subscriber premises apparatus determines whether the identifier is normally received and controls a bit separation position according to the determination result. Transmission signal distribution method.   In the subscriber premises apparatus, it is determined whether the main signal data of the bit-separated passive optical network system has been normally received, and the bit separation position is determined when the main signal data is not normally received for a predetermined time. 2. The method of unidirectional transmission signal distribution in a passive optical network system according to claim 1, wherein control is performed so as to change.   The unidirectional transmission signal only in the downlink direction from the station side device is a signal obtained by bit-multiplexing a plurality of transmission signals, and the subscriber premises device converts the unidirectional transmission signal only in the downlink direction into a plurality of signals. 2. The unidirectional transmission signal distribution method in a passive optical network system according to claim 1, wherein bit separation is performed on the transmission signal.   The passive optical network system regenerates the unidirectional transmission signal, and a subscriber premises apparatus that does not include a receiving unit that reproduces only the unidirectional transmission signal in the downlink direction in which the plurality of transmission signals are bit-multiplexed. 9. The unidirectional transmission signal distribution method in a passive optical network system according to claim 8, wherein a plurality of types of subscriber premises apparatuses having different numbers of receiving units are mixed passive optical network systems. It comprises a plurality of subscriber premises equipment, and a station side equipment connected to the subscriber premises equipment by an optical fiber via an optical splitter, and the station side equipment is time-shared from the plurality of subscriber premises equipment. Means for instructing transmission timing control of the subscriber premises equipment for receiving the upstream burst optical signal transmitted by the mobile terminal without collision, and means for distributing the downstream optical signal with the destination address for each subscriber premises equipment In the provided passive optical network system,
In the station side device, the digital signal of the unidirectional transmission signal only in the downlink direction in which a plurality of transmission signals are bit-multiplexed, and the main signal data of the passive optical network system are wavelength-multiplexed and transmitted,
In the subscriber premises equipment, the digital signal of the unidirectional transmission signal only in the downlink direction and the main signal data of the passive optical network system are wavelength-separated, and the unidirectional transmission signal only in the downlink direction is bit-separated A method for distributing a one-way transmission signal in a passive optical network system, characterized by:   The downstream signal of the passive optical network system is a downstream signal 1 Gbps transmission signal, which is a standardized method defined in IEEE 802.3ah, and the downstream-only one-way transmission signal multiplexed and separated is the transmission signal. The unidirectional transmission signal distribution method in the passive optical network system according to claim 10, wherein the signal has the same information rate and code conversion format as the signal.   The downstream signal of the passive optical network system is ITU-T G.264. A downlink signal 1.2448 Gbps transmission signal defined in 984.3, wherein the downlink unidirectional transmission signal to be multiplexed and separated is a signal having the same information rate and code conversion format as the transmission signal. The unidirectional transmission signal distribution method in the passive optical network system according to claim 10, wherein:   The downstream signal of the passive optical network system is ITU-T G.264. 984.3 Downstream signal 1.2448 Gbps transmission signal defined in 984.3, where the bit-multiplexed and demultiplexed unidirectional transmission signal only in the downstream direction has the same information rate as the transmission signal and the transmission signal The unidirectional transmission signal distribution method in the passive optical network system according to claim 10, wherein the signals are signals of different code conversion formats. In the station side device, the bit-multiplexed unidirectional transmission signal only in the downlink direction is added with an identifier indicating that the signal is a unidirectional transmission signal only in the downlink direction, and transmitted.
The one-way in the passive optical network system according to claim 10, wherein the subscriber premises apparatus determines whether or not the identifier is normally received and controls a bit separation position according to the determination result. Transmission signal distribution method.   The passive optical network system includes a subscriber premises apparatus that does not include a receiving unit that reproduces only a unidirectional transmission signal in a downlink direction in which a plurality of transmission signals are bit-multiplexed, and a reception that reproduces the unidirectional transmission signal. 11. The one-way transmission signal distribution method in a passive optical network system according to claim 10, wherein a plurality of types of subscriber premises apparatuses having different numbers of units are mixed passive optical network systems. In the station side device, to the unidirectional transmission signal only in the downlink direction in which a plurality of transmission signals are bit-multiplexed, an identifier is added for each transmission signal, and transmitted.
The passive optical network according to claim 15, wherein the subscriber premises apparatus determines whether an identifier of a specific transmission signal is normally received and controls a bit separation position according to the determination result. A one-way transmission signal distribution method in a system. A subscriber premises apparatus for receiving uplink burst optical signals transmitted in a time division manner from a plurality of subscriber premises equipment without collision, connected to the plurality of subscriber premises equipment via an optical splitter. In the station side apparatus comprising the means for performing the transmission timing control instruction and the means for distributing the downstream optical signal with the destination address for each subscriber premises apparatus, constituting the passive optical network system,
Bit multiplexing means for bit-multiplexing the digital signal of the unidirectional transmission signal only in the downlink direction and the main signal data of the passive optical network system;
Means for transmitting a downlink signal multiplexed by the bit multiplexing means to the subscriber premises apparatus;
A station apparatus for a passive optical network system, comprising: Connected to the station side device by an optical fiber via an optical splitter, and according to a transmission timing control instruction from the station side device, means for transmitting an upstream burst optical signal in a time division manner without collision, and a destination address is attached from the station side device And a means for receiving a downstream optical signal, and a subscriber premises apparatus constituting a passive optical network system,
Bit separation means for bit-separating, from the downstream signal, bit-multiplexed digital signal of the unidirectional transmission signal only in the downstream direction and main signal data of the passive optical network system,
Means for extracting a unidirectional transmission signal only in the downlink direction separated by the bit separation means;
A subscriber-side device for a passive optical network system, comprising:

Images