JP4786720B2 - PON system and PON connection method - Google Patents

Abstract

A PON system incorporating a new PON having an up-link transmission rate and a down-link transmission rate different from respective those of the existing PON in an optical access network used by an existing PON. In the PON system, a new PON2X transmits/receives a down-link signal having a wavelength ?3 different from that of the existing PON1 and an up-link signal having the same wavelength ?1 as that of the existing PON1. A 1G-OLT (10) of the existing PON1 has a PON control section (17) performs band control so that it opens a predetermined time of the up-link band of the existing PON1 when controlling the up-link band of the existing PON1 as a band for the new PON2X and it does not assign the open time to the up-link band of the existing PON1. A 10G-OLT (20X) of the new PON has a no-signal section detecting section (29) for detecting the open time and a PON control section (27) for assigning the detected open time to the up-link band of the new PON2X.

Description

  The present invention relates to a PON system and a PON connection method for accommodating a new PON having a transmission rate different from that of an existing PON in an optical access network used by the existing PON.

  2. Description of the Related Art In recent years, a technology related to PON (Passive Optical Network) in which a branching device (splitter) is inserted in the middle of an optical fiber network and a single optical fiber is drawn into a plurality of subscriber side devices has been developed. In this PON, a PON system that performs data transfer at a signal speed of 1 Gbps (Giga Bit Per Second) for both upstream and downstream is now widespread. However, when the transmission capacity required by the user is insufficient, a PON system (for example, a 10G-PON system that transmits at a signal speed of 10 Gbps upstream / downstream) in which the upstream / downstream speed is higher than the current transmission speed is introduced. Is required. Since the required bandwidth of the user depends on the usage status of each user, the transition to a new PON (for example, transition from 1G-PON to 10G-PON) proceeds on a subscriber basis.

  In an asymmetric PON system in which uplink and downlink transmission rates are different, there is a technique of accommodating (entering) a subscriber-side device having a higher uplink direction in an existing PON system. In the passive optical network PON described in Patent Document 1, the low-speed signal and the high-speed signal are time-divided because the station side device has two types of the bit synchronization circuit for low speed and the bit synchronization circuit for high speed in the upstream direction. An upstream signal can be received. Then, the new subscriber-side device whose speed is increased is transmitting an uplink signal at a signal rate that is a constant multiple of the uplink transmission rate of the existing subscriber-side device in the allocated uplink time zone. As a result, the control signal multiplexed on the downlink signal has a common format for the existing subscriber side device and the new subscriber side device. In the PON system described in Patent Document 2, spare fibers are laid in advance, and service upgrades in PON are provided at different wavelengths.

JP 2005-33537 A US Pat. No. 7,095,958

  However, in the former and the latter prior arts, a plurality of (for example, 32) subscriber-side devices are cascade-connected to one station-side device in the PON. Therefore, only one of the plurality of subscriber-side devices is used. Cannot be replaced by a subscriber-side device of a new PON system. For this reason, in order to change all the subscriber side equipment belonging to the PON at the same time, there has been a problem that the construction in all the subscriber homes must be performed simultaneously.

  In addition, the former prior art has a problem that it is not possible for a subscriber-side device that has increased the speed in the downstream direction as well as the speed in the upstream direction to enter the existing PON system. Further, in the latter prior art, since a device cannot be replaced in units of subscriber side devices unless a spare fiber network is laid in advance, the configuration of the PON system is complicated and the fiber network is laid. There was a problem of cost and time.

  The present invention has been made in view of the above, and it is an object of the present invention to provide a PON system and a PON connection method that can easily replace a subscriber-side device with a new PON system with a simple configuration.

In order to solve the above-described problems and achieve the object, the present invention uses a new new PON which is different from the existing PON which is an existing PON and has different transmission rates in the downlink and uplink directions. The PON system accommodated in the optical access network has a pseudo pseudo subscriber side device connected to the optical access network on the subscriber side, and the new PON is different from the existing PON in a downstream signal. While transmitting / receiving at a different wavelength, an upstream signal is transmitted / received at the same wavelength as that of the existing PON, and the station side device of the existing PON performs upstream control of the existing PON when performing bandwidth control in the upstream direction of the existing PON. A predetermined time zone is released as a new PON zone and bandwidth control is performed so that the opened time zone is not allocated to the upstream band of the existing PON. A first band control unit, wherein the new PON station side device detects a release time zone opened by the first band control unit, and the open time zone detected by the detection unit A second bandwidth control unit that allocates a bandwidth in the upstream direction of the PON, and the pseudo subscriber side device transmits release information regarding the release time zone to be transmitted to the station side device of the new PON, to the existing PON An information generator configured to generate a downlink signal transmitted from a station-side device and a downlink signal transmitted from the new-PON station-side device; and the detection unit included in the new-PON station-side device Detecting the release time zone based on the release information generated by the information generation unit, the downlink signal transmitted from the own device to the pseudo subscriber side device, and the timing at which the release information is received. And butterflies.

  According to the present invention, a predetermined time zone in the upstream band of the existing PON is released as a new PON zone, and the released time zone is allocated to the upstream zone of the new PON, so the transmission speeds are different. There is an effect that the new PON can be easily accommodated in the optical access network used by the existing PON with a simple configuration.

FIG. 1 is a block diagram showing the configuration of the PON system according to the first embodiment. FIG. 2 is a diagram illustrating a configuration of a PON system when only an existing PON system exists. FIG. 3 is a diagram illustrating a configuration of a PON system when an existing PON system and a new PON system exist. FIG. 4 is a diagram illustrating a configuration of a PON system when only a new PON system exists. FIG. 5 is a timing chart showing the operation timing of the PON system shown in FIG. FIG. 6 is a diagram for explaining a time zone in which data transmission assigned to the existing PON system by the PON system shown in FIG. 3 is permitted. FIG. 7 is a timing chart showing the operation timing of the PON system shown in FIG. FIG. 8 is a timing chart showing the operation timing of the existing PON system shown in FIG. FIG. 9 is a timing chart showing the operation timing of the new PON system shown in FIG. FIG. 10 is a block diagram illustrating a configuration of the PON system according to the second embodiment. FIG. 11 is a block diagram illustrating a configuration of the PON system according to the third embodiment. FIG. 12 is a timing chart showing the operation timing of the PON system shown in FIG. FIG. 13 is a timing chart showing a discovery procedure of the PON system shown in FIG. FIG. 14 is a timing chart showing the timing of the transmission permission signal transmitted by the PON system shown in FIG. FIG. 15 is a timing chart showing a discovery procedure of the PON system shown in FIG.

Explanation of symbols

1 Existing PON system 2X, 2Y, 2Z New PON system 5X, 5Y, 5Z PON system 10 1G-OLT
11, 21, 31, 41, 61 WDM
12, 22, 32, 42, 62 E / O conversion unit 13, 23, 33, 43, 63a, 63b, 71 O / E conversion unit 14, 24 Burst synchronization unit 15, 25, 35, 45 MUX unit 16, 26 , 36, 46 DMUX section 17, 27, 37, 47 PON control section 18, 28 Network interface section 20X, 20Y, 20Z 10G-OLT
29 No signal section detection unit 30 1G-ONU
38, 48 User interface unit 40 10G-ONU
50 Optical branch network 51 Optical fiber 60 Pseudo ONU
67 10G-PON control unit 69 1G-PON control unit 70 No signal section detection unit

  Embodiments of a PON system and a PON connection method according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

Embodiment 1 FIG.
FIG. 1 is a block diagram showing the configuration of the PON system according to the first embodiment. The PON system 5X includes an existing PON system 1 that is an existing PON system and a new PON system 2X that is a new PON system. Here, a case where the existing PON system 1 is a bidirectional 1 Gbps 1G-PON system and the new PON system 2X is a bidirectional 10 Gbps 10G-PON system will be described.

  In the present embodiment, a new PON system 5X is configured by adding a new PON system 2X to the existing PON system 1 configuring the PON system 5X. Here, a case will be described in which the first PON system 5X is configured by only the existing PON system 1, the new PON system 2X is added, and finally the PON system 5X is configured by only the new PON system 2X.

  FIG. 1 shows a configuration of the PON system 5X in a state where a new PON system 2X is added to the PON system 5X configured only by the existing PON system 1. The existing PON system 1 includes a 1G-OLT 10, 1G-ONU 30 (2) to 1 G-ONU 30 (n) (n is a natural number), and an optical branch network (optical access network) 50. The new PON system 2X includes a 10G-OLT 20X, a 10G-ONU 40 (1), and an optical branch network 50. The optical branch network 50 is a 2-input n-output optical branch network, and connects the new PON system 2X and the existing PON system 1.

  First, the configuration of the 1G-OLT 10 will be described. The 1G-OLT 10 is a station-side device of the existing PON system 1, and includes a WDM (optical transmission / reception unit) 11, an E / O conversion unit 12, an O / E conversion unit 13, a burst synchronization unit 14, a MUX unit 15, and a DMUX unit 16. , A PON control unit 17 and a network interface unit 18.

  A WDM (Wavelength Division Multiplexing) 11 is connected to the optical branching network 50 and is also connected to the E / O conversion unit 12 and the O / E conversion unit 13. The E / O conversion unit 12 is connected to the MUX unit 15, and the O / E conversion unit 13 is connected to the DMUX unit 16 via the burst synchronization unit 14.

  The MUX unit 15 and the DMUX unit 16 are connected to the PON control unit 17 and the network interface unit 18, respectively. The WDM 11 multiplexes the optical signal in the upstream direction (direction from the ONU to the OLT) (optical demultiplexing), and multiplexes the optical signal in the downstream direction (the direction from the OLT to the ONU) (optical multiplexing).

  The E / O conversion unit (λ2Tx) 12 performs E / O (Electric to Optical) conversion of the signal from the MUX unit 15 into a downlink signal having the wavelength λ2, and transmits the downlink signal via the WDM 11. The O / E conversion unit (λ1Rx) 13 performs O / E (Optical to Electric) conversion on the upstream signal (burst optical signal) of the wavelength λ1 received by the WDM 11 and inputs it to the burst synchronization unit 14.

  The burst synchronization unit 14 takes bit synchronization of the upstream signal O / E converted by the O / E conversion unit 13 and inputs the bit synchronization to the DMUX unit 16. The DMUX unit 16 separates the uplink signal from the burst synchronization unit 14 into an uplink PON control signal and user data. The DMUX unit 16 inputs the separated PON control signal to the PON control unit 17 and inputs the separated user data to the network interface unit 18. The MUX unit 15 multiplexes the downlink PON control signal (signal for controlling the PON system 5X) from the PON control unit 17 and the user data from the network interface unit 18 and inputs the multiplexed data to the E / O conversion unit 12 .

  The PON control unit 17 generates a PON control signal to be sent to the 1G-ONU and inputs it to the MUX unit 15. The PON control unit 17 receives the PON control signal sent from the 1G-ONU via the MUX unit 15. The PON control unit 17 controls the operation of the 1G-OLT 10 based on the PON control signal generated by itself and the PON control signal from the 1G-ONU.

  The network interface unit 18 is a communication interface that connects to an external device (not shown). The network interface unit 18 inputs user data sent from the external device to the MUX unit 15 and sends user data sent from the DMUX unit 16 to the external device.

  Next, the configuration of the 1G-ONU 30 (2) will be described. The 1G-ONU 30 (2) is a subscriber side device of the existing PON system 1, and includes a WDM 31, an E / O conversion unit 32, an O / E conversion unit 33, a MUX unit 35, a DMUX unit 36, a PON control unit 37, and a user. An interface unit 38 is provided.

  The WDM 31 is connected to the optical branch network 50 and to the E / O conversion unit 32 and the O / E conversion unit 33. The E / O conversion unit 32 is connected to the MUX unit 35, and the O / E conversion unit 33 is connected to the DMUX unit 36. The MUX unit 35 and the DMUX unit 36 are connected to a PON control unit 37 and a user interface unit 38, respectively.

  The WDM 31, the E / O conversion unit 32, the O / E conversion unit 33, the MUX unit 35, the DMUX unit 36, the PON control unit 37, and the user interface unit 38 are the WDM 11, the E / O conversion unit 12, and the O / E conversion unit, respectively. 13, the MUX unit 15, the DMUX unit 16, the PON control unit 17, and the network interface unit 18 have the same functions.

  That is, the WDM 31 multiplexes the optical signal in the upstream direction (optical multiplexing) and multiplexes the optical signal in the downstream direction (optical demultiplexing). The E / O conversion unit (λ1Tx) 32 performs E / O conversion of the signal from the MUX unit 35 into an upstream signal having the wavelength λ1, and transmits the upstream signal via the WDM 31. The O / E converter (λ2Rx) 33 performs O / E conversion on the downstream signal (burst optical signal) having the wavelength λ2 received by the WDM 31 and inputs the signal to the DMUX unit 36.

  The MUX unit 35 multiplexes the upstream PON control signal from the PON control unit 37 and the user data from the user interface unit 38 and inputs the multiplexed data to the E / O conversion unit 32. The DMUX unit 36 separates the downlink signal from the O / E conversion unit 33 into a downlink PON control signal and user data. The DMUX unit 36 inputs the separated PON control signal to the PON control unit 37 and inputs the separated user data to the user interface unit 38.

  The PON control unit 37 generates a PON control signal to be sent to the 1G-OLT 10 and inputs it to the MUX unit 35. The PON control unit 37 receives the PON control signal transmitted from the 1G-OLT 10 via the DMUX unit 36, and analyzes the received PON control signal. The PON control unit 37 controls the operation of the 1G-ONU 30 (2) based on the PON control signal generated by itself and the PON control signal from the 1G-OLT 10.

  The user interface unit 38 is a communication interface that connects to an external device (not shown). The user interface unit 38 inputs user data sent from the external device to the MUX unit 35 and transmits user data sent from the DMUX unit 36 to the external device. Note that 1G-ONU 30 (3) to 1G-ONU 30 (n) and 1G-ONU 30 (1), which will be described later, also have the same configuration as 1G-ONU 30 (2).

  Next, the configuration of the 10G-OLT 20X will be described. The 10G-OLT 20X is a station device of the new PON system 2X, and includes a WDM 21, an E / O conversion unit 22, an O / E conversion unit 23, a burst synchronization unit 24, a MUX unit 25, a DMUX unit 26, a PON control unit 27, A network interface unit 28 and a no-signal section detection unit 29 are provided.

  The WDM 21 is connected to the optical branch network 50 and to the E / O conversion unit 22 and the O / E conversion unit 23. The E / O conversion unit 22 is connected to the MUX unit 25, and the O / E conversion unit 23 is connected to the DMUX unit 26 via the burst synchronization unit 24. The MUX unit 25 and the DMUX unit 26 are connected to the PON control unit 27 and the network interface unit 28, respectively. Further, the no-signal section detection unit 29 which is the main feature of the present invention is connected to the PON control unit 27 and the O / E conversion unit 23.

  The no-signal section detection unit 29 detects the no-signal section from the upstream signal from the O / E conversion unit 23 and notifies the PON control unit 27 of it. That is, the WDM 21 multiplexes the optical signal in the upstream direction (optical demultiplexing) and multiplexes the optical signal in the downstream direction (optical multiplexing).

  The WDM 21, the E / O conversion unit 22, the O / E conversion unit 23, the burst synchronization unit 24, the MUX unit 25, the DMUX unit 26, the PON control unit 27, and the network interface unit 28 are the WDM 11, the E / O conversion unit 12, The O / E conversion unit 13, the burst synchronization unit 14, the MUX unit 15, the DMUX unit 16, the PON control unit 17, and the network interface unit 18 have the same functions.

  The E / O conversion unit (λ3Tx) 22 performs E / O conversion of the signal from the MUX unit 25 into a downlink signal having the wavelength λ3 and transmits the downlink signal via the WDM 21. The O / E conversion unit (λ1Rx) 23 performs O / E conversion on the upstream signal (burst optical signal) of the wavelength λ1 received by the WDM 21 and inputs it to the burst synchronization unit 24 and the no-signal section detection unit 29.

  The burst synchronization unit 24 takes bit synchronization of the upstream signal O / E converted by the O / E conversion unit 23 and inputs the bit synchronization to the DMUX unit 26. The DMUX unit 26 separates the upstream burst signal from the burst synchronization unit 24 into an upstream PON control signal and user data. The DMUX unit 26 inputs the separated PON control signal to the PON control unit 27 and inputs the separated user data to the network interface unit 28. The MUX unit 25 multiplexes the downstream PON control signal from the PON control unit 27 and the user data from the network interface unit 28 and inputs the multiplexed data to the E / O conversion unit 22.

  The PON control unit 27 generates a PON control signal to be sent to the 10G-ONU 40 (1) and inputs it to the MUX unit 25. The PON control unit 27 receives the PON control signal sent from the 10G-ONU 40 (1) via the MUX unit 25, and analyzes the received PON control signal. The PON control unit 27 operates the 10G-OLT 20X based on the no-signal section of the upstream signal detected by the no-signal section detection unit 29, the PON control signal generated by itself, and the PON control signal from the 10G-ONU 40 (1). To control.

  The network interface unit 28 is a communication interface connected to an external device (not shown). The network interface unit 28 inputs user data sent from the external device to the MUX unit 25 and transmits user data sent from the DMUX unit 26 to the external device.

  Next, the configuration of the 10G-ONU 40 (1) will be described. 10G-ONU 40 (1) is a subscriber-side device of the new PON system 2X, and includes WDM 41, E / O conversion unit 32, O / E conversion unit 43, MUX unit 45, DMUX unit 46, PON control unit 47, user An interface unit 48 is provided.

  The WDM 41 is connected to the optical branch network 50 and is also connected to the E / O conversion unit 42 and the O / E conversion unit 43. The E / O conversion unit 42 is connected to the MUX unit 45, and the O / E conversion unit 43 is connected to the DMUX unit 46. The MUX unit 45 and the DMUX unit 46 are connected to the PON control unit 47 and the user interface unit 48, respectively.

  The WDM 41, E / O conversion unit 42, O / E conversion unit 43, MUX unit 45, DMUX unit 46, PON control unit 47, user interface unit 48 are WDM 11, E / O conversion unit 12, O / E conversion unit, respectively. 13, the MUX unit 15, the DMUX unit 16, the PON control unit 17, and the network interface unit 18 have the same functions.

  That is, the WDM 41 multiplexes the optical signal in the upstream direction (optical multiplexing) and multiplexes the optical signal in the downstream direction (optical demultiplexing). The E / O conversion unit (λ1Tx) 42 performs E / O conversion of the signal from the MUX unit 45 into a signal of wavelength λ1, and transmits the signal in the upstream direction via the WDM 31. The O / E converter (λ3Rx) 43 performs O / E conversion on the downstream signal (burst optical signal) having the wavelength λ3 received by the WDM 41 and inputs the signal to the DMUX unit 46.

  The MUX unit 45 multiplexes the uplink PON control signal from the PON control unit 47 and the user data from the user interface unit 48 and inputs the multiplexed data to the E / O conversion unit 42. The DMUX unit 46 separates the downlink signal from the O / E conversion unit 43 into a downlink PON control signal and user data. The DMUX unit 46 inputs the separated PON control signal to the PON control unit 47 and inputs the separated user data to the user interface unit 48.

  The PON control unit 47 generates a PON control signal to be sent to the 10G-OLT 20X and inputs it to the MUX unit 45. The PON control unit 47 receives the PON control signal sent from the 10G-OLT 20X via the DMUX unit 46, and analyzes the received PON control signal. The PON control unit 47 controls the operation of the 10G-ONU 40 (1) based on the PON control signal generated by itself and the PON control signal from the 10G-OLT 20X.

  The user interface unit 48 is a communication interface that connects to an external device (not shown). The user interface unit 48 inputs user data sent from the external device to the MUX unit 45 and transmits user data sent from the DMUX unit 46 to the external device. Note that 10G-ONU 40 (2) to 10G-ONU 40 (n), which will be described later, also have the same configuration as 10G-ONU 40 (1).

  In the following description, 1G-ONU 30 (1) to 30 (n) may be referred to as 1G-ONU 30 or 1G-ONU for convenience of description. In addition, the 10G-ONU 40 (1) to 40 (n) may be referred to as 10G-ONU 40 or 10G-ONU for convenience of explanation.

  Next, a change in the configuration of the PON system 5X will be described. For example, the first PON system 5 </ b> X has an existing PON system 1 including a 1G-OLT 10, 1G-ONU 30 (1) to 1 G-ONU 30 (n), and an optical branching network 50. Thereafter, the new PON system 2X is added to the PON system 5X by adding the 10G-OLT 20X and replacing the 1G-ONU 30 (1) with the 10G-ONU 40 (1). Thereafter, each 1G-ONU 30 (2) to 1G-ONU 30 (n) is sequentially replaced with 10G-ONU 40 (2) to 10G-ONU 40 (n). The final PON system 5X is configured by 10G-OLT 20X, 10G-ONU 40 (1) to 1G-ONU 30 (n).

  Here, the configuration of the PON system 5X when only the existing PON system 1 exists, the configuration of the PON system 5X when the existing PON system 1 and the new PON system 2X exist, only the new PON system 2X exists The configuration of the PON system 5X in the case where it is in operation will be described.

  FIG. 2 is a diagram illustrating a configuration of a PON system when only an existing PON system exists. In the PON system 5X in the case where only the existing PON system 1 exists, each 1G-ONU 30 (1) to 30 (n) is connected to the 1G-OLT 10 via the optical branching network 50. The upstream direction transmits data using the wavelength λ1, and the downstream direction transmits data using the wavelength λ2.

  FIG. 3 is a diagram illustrating a configuration of a PON system when an existing PON system and a new PON system exist. In FIG. 3, in the PON system 5X, the optical branch network 50 is shared between the existing PON system 1 and the new PON system 2X, and the 10G-compatible OLT (10G-OLT10) and 10G-ONU 30 (1) are installed. Show.

  In the PON system 5X when the existing PON system 2X and the new PON system 1 exist, the existing PON system 1 and the new PON system 2X use different wavelengths in the downstream direction, and use the same wavelength in the upstream direction. Share. Specifically, in the 1G-PON 30 (2) to 30 (n) of the existing PON system 1, the wavelength λ1 is used for the upstream wavelength and the wavelength λ2 is used for the downstream wavelength. On the other hand, the 10G-PON 40 (1) of the new PON system 2X uses the wavelength λ1 for the upstream wavelength and uses the wavelength λ3 for the downstream wavelength.

  FIG. 4 is a diagram illustrating a configuration of a PON system when only a new PON system exists. In FIG. 4, in the PON system 5X, the state where all the subscriber side devices have shifted to 10G-PON (10G-ONUs 30 (1) to 30 (n)) is shown.

  In the PON system 5X in which only the new PON system 2X exists, each 10G-ONU 40 (1) to 40 (n) is connected to the 10G-OLT 20X via the optical branching network 50. In the upstream direction, data is transmitted using the wavelength λ1, and in the downstream direction, data is transmitted using the wavelength λ3.

  In each PON system 5X shown in FIGS. 2 to 4, the transmission timing in the upstream direction is indicated by a multiplexed PON control signal transmitted from the downstream direction. That is, the 1G-PON subscriber side apparatus is instructed to transmit in the upstream direction by the PON control signal multiplexed with the downstream signal of wavelength λ2. On the other hand, the subscriber side device of 10G-PON is instructed in the uplink transmission timing by the PON control signal multiplexed on the downlink signal of wavelength λ2.

  Next, the operation timing of each PON system 5X shown in FIGS. 2 and 3 will be described. FIG. 5 is a timing chart showing the operation timing of the PON system shown in FIG. In the PON system 5X, the 1G-OLT 10 periodically performs grant allocation to the 1G-ONU 30 at a predetermined bandwidth update period T. The 1G-OLT 10 (Tx) here assigns all the band update periods T only to the 1G-ONU 30 (1G region). Specifically, the PON control unit 17 of the 1G-OLT 10 assigns a bandwidth update period T to each 1G-ONU 30, thereby giving each 1G-ONU 30 a transmission permission (transmission permission information). Then, each 1G-ONU 30 performs uplink data transmission based on the transmission permission assigned to itself. In the 1G-OLT 10, user data is extracted from a signal sent from the 1G-ONU 30 and transmitted to an external device via the network interface unit 18.

  FIG. 6 is a diagram for explaining a time zone in which data transmission assigned to the existing PON system by the PON system shown in FIG. 3 is permitted. Also in the PON system 5X shown in FIG. 3, the 1G-OLT 10 periodically performs grant allocation to the 1G-ONU 30 with a predetermined bandwidth update period T. The 1G-OLT 10 (Tx) here releases a part of the time in each band update period T so that the new PON system 2X can use it, and the remaining part of the time in the band update period T is 1G-ONU30. Assign to (1G area). Each 1G-ONU 30 performs uplink data transmission only during a part of the time within the bandwidth update period T (a time zone in which data transmission is permitted) based on the transmission permission assigned to itself.

  FIG. 7 is a timing chart showing the operation timing of the PON system shown in FIG. The 1G-OLT 10 (Tx) assigns to each 1G-ONU 30 a time zone (remaining time zone) excluding an open time zone (open time zone) in the bandwidth update period T. The 10G-OLT 20X (Tx) assigns to the 10G-ONU 40 a time zone released by the 1G-OLT 10 (Tx) (part of the time within each band update period T).

  Specifically, the PON control unit 17 of the 1G-OLT 10 allocates a time zone (1G region) excluding an open time zone (10G region) within the bandwidth update period T to each 1G-ONU 30. Then, the PON control unit 27 of the 10G-OLT 20X allocates an open time zone (10G region) within the bandwidth update period T to the 10G-ONU 40.

  The ratio of the time allocated to the 1G-ONU 30 and the time allocated to the 10G-ONU 40 in each band update period T is, for example, the ratio of the number of 1G-ONUs 30 connected to the optical branching network 50 to the number of 10G-ONUs 40. Set accordingly.

  The 1G-ONU 30 performs uplink data transmission based on the transmission permission assigned to the own device, and the 10G-ONU 40 performs uplink data transmission based on the transmission permission assigned to the own device. In the 1G-OLT 10, user data is extracted from a signal sent from the 1G-ONU 30 and transmitted to an external device via the network interface unit 18. In the 10G-OLT 20X, user data is extracted from a signal sent from the 10G-ONU 40 and transmitted to an external device via the network interface unit 18.

  Next, detailed operation timing of the PON system 5X shown in FIG. 3 will be described. FIG. 8 is a timing chart showing the operation timing of the existing PON system shown in FIG. Here, as an example of the operation timing of the existing PON system 1 shown in FIG. 3, a case where the 1G-OLT 10 grants transmission permission to two 1G-ONUs (#A) and 1G-ONUs (#B) will be described. Here, 1G-ONU (#A) and 1G-ONU (#B) are any of 1G-ONUs 30 (2) to 30 (n).

  In the 1G-OLT 10 (station side device) of the existing PON system 1 (1G-PON system), the PON control unit 17 has a counter inside, and includes a counter value (time stamp) in the downstream PON control signal. Thus, each 1G-ONU 30 (subscriber side device) is synchronized.

  The PON control unit 17 calculates the transmission timing of each 1G-ONU 30 at the band update cycle T (a time zone in which transmission permission is given). As shown in FIG. 8, the PON control unit 17 sets (releases) the time of TN in the band update period T in the area for the new PON system 2X. In addition, the PON control unit 17 sets the area (T-TN) time in the area for the existing PON system 1 and allocates it to the 1G-ONU. That is, TN is assigned to the time zone for 10G-PON, and the region (T-TN) is assigned to the time zone for 1G-PON.

  Here, the PON control unit 17 assigns the time zone from t1 (0) to t1 (a) to the 1G-ONU (#A) in the time of the region (T-TN), and also from t1 (a) to The time zone up to t1 (b) is assigned to 1G-ONU (#B).

  In addition, since the time zone (TN) from t1 (b) to T2 (0) is an area for the new PON system 2X, the PON control unit 17 sets the time zone from t1 (b) to T2 (0). Then, a non-existing subscriber side device is specified and transmission is permitted, or a time zone in which transmission permission is not given to any subscriber side device is set.

  The transmission permission signal (PON control signal) from the PON control unit 17 is from the time point when reception of the uplink direction is first started every band update period T (when the uplink signal from 1G-ONU (#A) is received). Also, it is transmitted to 1G-ONU (#A) and 1G-ONU (#B) just before RTT (Round Trip Time).

  FIG. 9 is a timing chart showing the operation timing of the new PON system shown in FIG. Here, as an example of the operation timing of the new PON system 2X shown in FIG. 3, a case where the 10G-OLT 20X grants transmission permission to the 10G-ONU 40 will be described.

  The no-signal section detection unit 29 of the 10G-OLT 20X detects a no-signal section from uplink signals transmitted from 1G-ONU (#A) and 1G-ONU (#B). Here, the no-signal section detection unit 29 performs an upstream signal in the time zone of the region (T-TN) allocated to 1G-ONU (#A) and 1G-ONU (#B) in the band update period T. And a no-signal section is detected in the TN time zone when the 1G-OLT 10 is released.

  As illustrated in FIG. 9, for example, the no-signal section detection unit 29 generates a “High” detection signal during a period in which an uplink signal is received, and “Low” during a period in which no uplink signal is received. ”Is generated. That is, the no-signal section detection unit 29 generates a waveform having a rising edge at the beginning of the band update period T when the band update period T and the 10G-PON area TN in one period are set in the 1G-OLT 10. At the same time, a waveform having a falling edge at the head of the region TN is generated. The no-signal section detection unit 29 inputs the generated edge waveform (no-signal section detection signal) to the PON control unit 27.

  The PON control unit 27 sets the band update period T and the 10G-PON region TN based on the edge waveform from the no-signal section detection unit 29. And the PON control part 27 synchronizes with 1G-OLT10 based on the no signal area detection signal which the no signal area detection part 29 received. Further, the PON control unit 27 recognizes the time of the 10G-PON area TN and transmits a transmission permission signal to the 10G-ONU before the RTT of the 10G-PON area TN.

  The 10G-ONU transmits an uplink signal at a predetermined timing based on a transmission permission signal from the 10G-OLT. The upstream burst signal from the 10G-ONU is bit-synchronized by the burst synchronization unit 14 of the 10G-OLT.

  In the present embodiment, the case where the existing PON system 1 is a bidirectional 1 Gbps 1G-PON system has been described, but the existing PON system 1 may be configured by a PON system other than the 1G-PON system.

  In the present embodiment, the case where the new PON system 2X is a bidirectional 10 Gbps 10G-PON system has been described. However, the new PON system 2X may be configured by a PON system other than the 10G-PON system.

  Further, in the present embodiment, the transmission permission signal from the PON control unit 17 is 1G-ONU (#A), 1 R-ONU (#A) Although it has been transmitted to 1G-ONU (#B), it may be transmitted before RTT. In this case, the transmission permission signal includes information indicating how long before the RTT the transmission permission signal is transmitted (information indicating the timing for granting transmission permission to the 1G-ONU).

  As described above, according to the first embodiment, in the new PON system 2X, the optical branch network 50 is shared with the existing PON system 1, and a wavelength λ3 different from that of the existing PON system 1 is used for the wavelength of the downstream signal. Since the information of the time zone not used by the existing PON system 1 is autonomously detected based on the upstream signal and used, it is new in units of users (each subscriber side terminal) without affecting the operation of the existing PON system 1 It becomes possible to shift to the PON system 2X. Therefore, replacement of the subscriber side device with the new PON system 2X can be easily performed with a simple configuration.

  Further, in each bandwidth update period T, the ratio of the time allocated to the 1G-ONU 30 and the time allocated to the 10G-ONU 40 is the ratio of the number of 1G-ONUs 30 and 10G-ONUs 40 connected to the optical branching network 50. Accordingly, an appropriate time according to the number ratio can be allocated to the 1G-ONU 30 and the 10G-ONU 40, and the existing PON system 1 and the new PON system 2X can efficiently transmit and receive signals. .

Embodiment 2. FIG.
Next, a second embodiment of the present invention will be described with reference to FIGS. In the first embodiment, the new PON system monitors the upstream signal of the existing PON system 1 to detect the upstream time zone (no signal section) that can be used in the own system. However, in the second embodiment, the new PON system Monitors the downstream signal of the existing PON system 1 to detect the upstream time zone (no signal section) that can be used in the local system.

  FIG. 10 is a block diagram illustrating a configuration of the PON system according to the second embodiment. Of the constituent elements in FIG. 10, constituent elements that achieve the same functions as those of the PON system 5X of the first embodiment shown in FIG.

  The PON system 5Y has an existing PON system 1 and a new PON system 2Y. Here, the case where the new PON system 2Y is a 10G-PON system of bidirectional 10 Gbps as in the new PON system 2X of the first embodiment will be described.

  In this embodiment, a new PON system 2Y is added to the existing PON system 1 to form a new PON system 5Y. Here, a case will be described in which the first PON system 5Y is configured by only the existing PON system 1, the new PON system 2Y is added, and finally the PON system 5Y is configured by only the new PON system 2Y.

  FIG. 10 shows a configuration of the PON system 5Y in a state where a new PON system 2Y is added to the PON system 5Y configured only by the existing PON system 1. The new PON system 2Y includes a 10G-OLT 20Y, a 10G-ONU 40 (1), and an optical branching network 50. The optical branch network 50 is a 2-input n-output optical branch network, and connects the new PON system 2Y and the existing PON system 1. Further, in the present embodiment, the optical fiber 51 is routed from the subscriber side of the optical branch network 50 and connected to the 10G-OLT 20Y.

  Next, the configuration of the 10G-OLT 20Y will be described. The 10G-OLT 20Y is a station-side device of the new PON system 2Y, and includes a WDM 21, an E / O conversion unit 22, an O / E conversion unit 23, a burst synchronization unit 24, a MUX unit 25, a DMUX unit 26, a PON control unit 27, In addition to the network interface unit 28, a no-signal section detection unit 70 and an O / E conversion unit 71 are provided.

  The O / E conversion unit 71 is connected to the optical branch network 50 through the optical fiber 51, and the no-signal section detection unit 70 is connected to the O / E conversion unit 71 and the PON control unit 27. The O / E converter (λ2Rx) 71 performs O / E conversion on the downstream signal of the wavelength λ2 from the 1G-OLT 10 received via the optical fiber 51 and inputs the signal to the no-signal section detector 70.

  The no-signal section detection unit 70 analyzes a time stamp and transmission permission information (information indicating a transmission-permitted time zone) in the transmission permission signal multiplexed on the downstream signal from the 1G-OLT 10, and outputs the upstream as a result of this analysis. 10G-PON time zone (no signal section) is detected. The no-signal section detection unit 70 inputs the detected upstream time zone for 10G-PON to the PON control unit 27.

  The PON control unit 27 is based on the time zone for upstream 10G-PON detected by the no-signal section detection unit 70, the PON control signal generated by itself, and the PON control signal from the 10G-ONU 40 (1). Controls the operation of the OLT 20Y.

  Here, the time zone detection process for the upstream 10G-PON will be described with reference to FIG. The no-signal section detection unit 70 monitors a time period t1 (b) to t2 (0) that is permitted to be transmitted to the 1G-OLT 10 by designating a non-existing subscriber side device, or to all the subscriber side devices. Monitor the time periods t1 (0) to t1 (a), t1 (a) to t1 (b), t2 (0) to t2 (a), and t2 (a) to t2 (b) permitted for transmission. The time zone for 10G-PON is detected.

  When a time zone t1 (b) to t2 (0) for which transmission is permitted by specifying a non-existing subscriber side device is monitored, the monitored time zone t1 (b) to t2 (0) is for 10G-PON. Detected as a time zone.

  When monitoring the time zone permitted for transmission to all the subscriber side devices, the time zones t1 (b) to t2 (0) are extracted as the time zones (areas) remaining after monitoring, and the extracted time zone is It is detected as a time zone for 10G-PON.

  Next, the operation timing of the new PON system 2Y in the PON system 5Y according to the second embodiment will be described with reference to FIG. As illustrated in FIG. 9, the no-signal section detection unit 70 generates a “High” detection signal, for example, during a period in which an uplink signal is received, and “Low” during a period in which no uplink signal is received. ”Is generated. That is, the no-signal section detector 70 generates a waveform with a rising edge at the beginning of the band update period T when the band update period T and the 10G-PON area TN in one period are set in the 1G-OLT 10. At the same time, a waveform having a falling edge at the head of the region TN is generated. The no-signal section detection unit 70 inputs the generated edge waveform (no-signal section detection signal) to the PON control unit 27.

  The PON control unit 27 sets the band update period T and the 10G-PON region TN based on the edge waveform from the no-signal section detection unit 70. And the PON control part 27 synchronizes with 1G-OLT10 based on the no signal area detection signal which the no signal area detection part 70 received. Furthermore, the time of the area TN for 10G-PON is recognized, and a transmission permission signal is transmitted to the 10G-ONU before the RTT of the area TN for 10G-PON.

  The 10G-ONU 40 transmits an uplink signal at a predetermined timing based on the transmission permission signal from the 10G-OLT 20Y. The uplink signal from the 10G-ONU 40 is bit-synchronized by the burst synchronization unit 14 of the 10G-OLT 20Y.

  In the present embodiment, the optical fiber 51 is routed from the subscriber side of the optical branch network 50 and connected to the 10G-OLT 20Y. However, the optical fiber 51 is connected to the 10G-OLT 20Y from a different position from the subscriber side. The fiber 51 may be routed and connected to the 10G-OLT 20Y. In this case, the same effect as that obtained when the optical fiber 51 is routed from the subscriber side of the optical branching network 50 and connected to the 10G-OLT 20Y can be obtained.

  As described above, according to the second embodiment, in the new PON system 2Y, the optical branch network 50 is shared with the existing PON system 1, and a wavelength λ3 different from that of the existing PON system 1 is used for the wavelength of the downstream signal. Since the information of the time zone not used by the existing PON system 1 is autonomously detected based on the downlink signal and used, it is new in units of users (each subscriber side terminal) without affecting the operation of the existing PON system 1 It becomes possible to shift to the PON system 2Y. Moreover, since the information of the time slot | zone (time slot | zone for 10G-PON) which the existing PON system 1 does not use is detected based on the downstream signal sent from 1G-OLT10 of the existing PON system 1, 1G-ONU30 Even when it is stopped, it is possible to easily shift to the new PON system 2Y.

Embodiment 3 FIG.
Next, Embodiment 3 of the present invention will be described with reference to FIGS. In the third embodiment, the timing of the existing PON system and the new PON system are synchronized by connecting a pseudo subscriber side device (a pseudo ONU 60 described later) that performs timing adjustment to the optical branching network.

  FIG. 11 is a block diagram illustrating a configuration of the PON system according to the third embodiment. Among the constituent elements in FIG. 11, constituent elements that achieve the same functions as those of the PON system 5X of the first embodiment shown in FIG.

  The PON system 5Z includes an existing PON system 1, a new PON system 2Z, and a pseudo ONU (pseudo subscriber side device) 60. Here, the case where the new PON system 2Z is a bidirectional 10 Gbps 10G-PON system, similar to the new PON system 2X of the first embodiment, will be described.

  In the present embodiment, a new PON system 2Z is added to the existing PON system 1 to configure a new PON system 5Z. Here, a case will be described in which the first PON system 5Z is configured with only the existing PON system 1, and then the new PON system 2Z is added, and finally the PON system 5Z is configured with only the new PON system 2Z.

  FIG. 11 shows a configuration of the PON system 5Z in a state where the new PON system 2Z is added to the PON system 5Z configured by the existing PON system 1 and the pseudo ONU 60. The new PON system 2Z includes a 10G-OLT 20Z, a 10G-ONU 40 (1), and an optical branch network 50. The optical branch network 50 is an optical branch network with two inputs (n + 1) output, and connects the new PON system 2Z, the existing PON system 1, and the pseudo ONU 60.

  Next, the configuration of the pseudo ONU 60 will be described. The pseudo ONU 60 includes a WDM 61, O / E converters 63a and 63b, an E / O converter 62, a 10G-PON controller (information generator) 67, and a 1G-PON controller 69.

  The WDM 61 is connected to the optical branch network 50 and is also connected to the O / E converters 63 a and 63 b and the E / O converter 62. The O / E conversion unit 63a is connected to the 10G-PON control unit 67, and the O / E conversion unit 63b is connected to the 1G-PON control unit 69. The 1G-PON control unit 69 is connected to the 10G-PON control unit 67, and the 10G-PON control unit 67 is connected to the E / O conversion unit 62.

  The WDM 61, the O / E converters 63a and 63b, and the E / O converter 62 have the same functions as the WDM 11, the O / E converter 13, the E / O converter 12, and the PON controller 17, respectively. That is, the WDM 61 multiplexes (optical multiplexing) the upstream optical signal and multiplexes (optical demultiplexing) the downstream optical signal.

  The O / E converter (λ3Rx) 63a performs O / E conversion on the downstream signal (burst optical signal) having the wavelength λ3 received by the WDM 61 and inputs the signal to the 10G-PON controller 67. The O / E converter (λ2Rx) 63b performs O / E conversion on the downstream signal (burst optical signal) having the wavelength λ2 received by the WDM 61 and inputs the signal to the 1G-PON controller 69. The E / O conversion unit (λ1Tx) 62 performs E / O conversion of the signal from the 10G-PON control unit 67 into an optical signal having the wavelength λ1, and transmits the optical signal via the WDM 61 in the upstream direction.

  The 1G-PON control unit 69 receives the PON control signal of wavelength λ2 sent from the 1G-OLT 10 via the O / E conversion unit 63b, and analyzes the received PON control signal. The 1G-PON control unit 69 generates a PON control signal to be sent to the 1G-OLT 10 based on the analyzed PON signal, and inputs the PON control signal to the 10G-PON control unit 67.

  The 10G-PON control unit 67 receives the PON control signal of wavelength λ3 sent from the 10G-OLT 20Z via the O / E conversion unit 63a, and analyzes the received PON control signal. The 10G-PON control unit 67 generates a PON control signal to be sent to the 10G-OLT 20Z based on the analyzed PON signal. The 10G-PON control unit 67 inputs the generated PON control signal and the PON control signal from the 1G-PON control unit 69 to the E / O conversion unit 62.

  Next, the configuration of the 10G-OLT 20Z will be described. The 10G-OLT 20Z is a station-side device of the new PON system 2Z, and includes a WDM 21, an E / O conversion unit 22, an O / E conversion unit 23, a burst synchronization unit 24, a MUX unit 25, a DMUX unit 26, a PON control unit 27, A network interface unit 28 is provided. The PON control unit 27 controls the operation of the 10G-OLT 20Z based on the PON control signal generated by itself and the PON control signal from the pseudo ONU 60.

  Next, an operation procedure of the PON system 5Z will be described. The pseudo ONU 60 receives the downstream signal from the 1G-OLT 10 by the WDM 61, and inputs the signal subjected to the O / E conversion by the O / E conversion unit 63 b to the 1G-PON control unit 69. The 1G-PON control unit 69 analyzes the PON control signal multiplexed on the downstream signal from the 1G-OLT 10 and detects an upstream 10G-PON area (no signal section). The area detection for 10G-PON is detected by the same processing as the no-signal section detection unit 70 of the second embodiment. The 1G-PON control unit 69 inputs the detected no-signal section information to the 10G-PON control unit 67.

  Further, the pseudo ONU 60 receives the downstream signal from the 10G-OLT 20Z by the WDM 61, and inputs the downstream signal subjected to the O / E conversion by the O / E conversion unit 63a to the 10G-PON control unit 67. The 10G-PON control unit 67 analyzes the PON control signal multiplexed on the downlink signal from the 10G-OLT 20Z, and determines the upstream 1G-PON area (T-TN) and the upstream 10G-PON area TN. To detect. The area for 10G-PON is detected by the same process as the no-signal section detector 70 of the second embodiment.

  Here, the detailed operation timing of the PON system 5Z shown in FIG. 11 will be described. FIG. 12 is a timing chart showing the operation timing of the PON system shown in FIG. The PON control unit 17 of the 1G-OLT 10 sets (releases) the time of the area TN in the band update period T to the area for the new PON system 2Z. In addition, the PON control unit 17 sets the time of the area (T-TN) in the area for the existing PON system 1 and allocates it to the 1G-ONU 30.

  The PON control unit 17 of the 1G-OLT 10 transmits a transmission permission signal to the 1G-ONU 30 and the pseudo ONU 60 every band update period T. The transmission permission signal here includes information on the timing for permitting the transmission to the 1G-ONU 30 and information on the time (T-TN) for which the transmission is permitted. The PON control unit 17 here transmits a transmission permission signal to the 1G-ONU 30 and the pseudo ONU 60 by 1G-PON (λ1). The 1G-ONU 30 transmits an uplink signal having the wavelength λ1 to the 1G-OLT 10 based on the transmission permission signal from the 1G-OLT 10.

  The pseudo ONU 60 inputs a transmission permission signal from the 1G-OLT 10 to the 1G-PON control unit 69 via the WDB 61 and the O / E changing unit 63b. The 1G-PON control unit 69 analyzes the transmission permission signal from the 1G-OLT 10 and starts the start (time p) (10G-PON transmission permission of the area where the 1G-OLT 10 is free for 10G-PON. Time). The 1G-PON control unit 69 of the pseudo ONU 60 inputs information on the time (time p) when the transmission of 10G-PON is permitted to the 10G-PON control unit 67.

  The PON control unit 27 of the 10G-OLT 20Z searches for the start position of the time zone for 10G-PON set by the PON control unit 17 of the 1G-OLT 10. First, the PON control unit 27 tentatively sets the start timing of the band update period T and the 10G-PON time zone (10G area) TN. That is, the PON control unit 27 starts the start timing (time) of the 1G-PON area (area that receives the 1G-PON signal) and the 10G-PON area (area that receives the 10G-PON signal). And tentatively set the period. Since the area (timing) for 10G-PON set by the PON control unit 27 is a provisional area, the reception position (transmission position) set at this time is actually 1G-OLT 10 free for 10G-PON. Does not necessarily coincide with the beginning of a certain area.

  The PON control unit 27 receives the upstream signal (message) from the pseudo ONU 60 with a delay of (T-TN) from the time zone for 1G-PON temporarily set by itself. A transmission permission signal is transmitted. In other words, the PON control unit 27 gives transmission permission to the pseudo ONU 60 so that the upstream message can be received at the head (time r) of the 10G-PON area that is provisionally set.

  The 10G-PON control unit 67 of the pseudo ONU 60 is the difference between the time (time p) at which 10G-PON transmission is permitted, which is input from the 1G-PON control unit 69, and the transmission timing specified by the 10-OLT 20Z. The information of (rp) is included in the upstream message (release information) and notified to the 10G-OLT 20Z. At this time, the pseudo ONU 60 transmits an uplink message to the 10G-OLT 20Z at 10 Gbps.

  The upstream message from the 10G-PON control unit 67 is received by the 10G-OLT 20Z and sent to the PON control unit 27 of the 10G-OLT 20Z. The PON control unit 27 is a time r (temporarily set time) at which an upstream message is scheduled to be received from the pseudo ONU 60, a time q at which the upstream message is actually received from the pseudo ONU 60, and an upstream message. Based on the transmission timing difference (rp) information included therein, an area (start timing) in which the 1G-OLT 10 is free for 10G-PON and the pseudo ONU 60 to 1G-OLT 10 (10G-OLT 20Z) RTT up to is calculated.

  The PON control unit 27 corrects the transmission timing in the transmission permission message to be transmitted to the pseudo ONU 60 based on the calculated information (area where 1G-OLT 10 is free for 10G-PON, RTT). Thereafter, the PON control unit 27 repeats transmission of a transmission permission signal to the pseudo ONU 60 until the synchronization with the 1G-OLT 10 is established. Then, every time an uplink message is received from the pseudo ONU 60, the 1G-OLT 10 calculates an area free for 10G-PON and the RTT, and corrects the transmission timing in the transmission permission message to be transmitted to the pseudo ONU 60.

  When the difference information in the upstream message received from the pseudo ONU 60 becomes 0, the PON control unit 27 determines that synchronization with the 1G-OLT 10 has been achieved. In the 10G-OLT 20Z, after the 10G-PON area is correctly recognized, this area is used for the 10G-ONU.

  As described above, according to the third embodiment, in the new PON system 2Z, the optical branch network 50 is shared with the existing PON system 1, and a wavelength λ3 different from that of the existing PON system 1 is used for the wavelength of the downstream signal. Since information on a time zone that is not used by the existing PON system 1 is autonomously detected and used based on the downstream signal from the pseudo ONU 60, the user unit (subscriber-side terminal) is used without affecting the operation of the existing PON system 1. It becomes possible to shift to the new PON system 2Y.

  Further, the 10G-OLT 20 determines the difference between the time r at which the uplink message is scheduled to be received from the pseudo ONU 60, the time q at which the uplink message is actually received from the pseudo ONU 60, and the transmission timing included in the uplink message (r Based on the information of -p), it is possible to calculate the area (start timing) and RTT that are free for 10G-PON, so that it is possible to shift to the new PON system 2Y with a simple configuration. .

Embodiment 4 FIG.
Next, a fourth embodiment of the present invention will be described with reference to FIGS. In the PON system 5X, in order to detect that a subscriber side device (1G-ONU 30 or 10G-ONU 40) is connected to the optical branching network 50, a discovery procedure is periodically performed.

  Here, the discovery procedure in each PON system 5X shown in FIGS. 2 and 3 of the first embodiment will be described. FIG. 13 is a timing chart for explaining the discovery procedure of the PON system shown in FIG.

  The 1G-OLT 10 performs identification number identification and distance measurement of the 1G-ONU 30 connected to the optical branching network 50 by a discovery procedure. As illustrated in FIG. 13, in the discovery procedure, the 1G-OLT 10 transmits a transmission permission signal having a window width W upstream non-signal section to the 1G-ONU 30 in the period P. The 1G-ONU 30 (subscriber side device) transmits an uplink message in the discovery window. The message from the 1G-ONU is normally received by the 1G-OLT 10.

  In the new PON system 2X, the 10G-OLT 20X detects the appearance timing of the discovery window of the existing PON system 1 by the same procedure as the no-signal section detection process described in the first embodiment.

  That is, in the case of the PON system 5X shown in FIG. 3, the 1G-OLT 10 sends a discovery message (transmission permission signal) in order to quickly complete the discovery procedure while avoiding collision of upstream messages between the 1G-ONU and the 10G-ONU. The data is sent out in the PON system 5X. For example, the 1G-OLT 10 transmits a discovery message at the timing illustrated in FIG.

  FIG. 15 is a timing chart for explaining the discovery procedure of the PON system shown in FIG. As shown in FIG. 15, in the discovery procedure here, 1G-OLT 10 transmits 1G-ONU 30 with a period P and a transmission permission signal provided with an upstream no-signal section of window width W. The transmission permission signal transmitted from the 1G-OLT 10 to the 1G-ONU 30 is thinned out at a predetermined rate. That is, the 1G-OLT 10 has a period in which discovery of the 1G-ONU 30 is not performed.

  When the no-signal section detection unit 29 of the 10G-OLT 20X detects the appearance timing of the discovery window of the existing PON system 1, the PON control unit 27 is a period in which the 1G-OLT 10 does not perform the discovery of the 1G-ONU 30 based on the appearance timing. (Open cycle) is detected.

  Then, the PON control unit 27 transmits a transmission permission signal in which an uplink no-signal section having a window width W is provided to the 10G-ONU 40 based on a period in which the 1G-OLT 10 does not discover the 1G-ONU 30. That is, 10G-OLT10 transmits a transmission permission signal to 10G-ONU40 using the timing at which the transmission permission signal was thinned out by 1G-OLT10. In other words, in the 10G-PON system, the discovery of the 10G-ONU 40 is performed in a cycle in which the 1G-ONU 30 does not perform discovery.

  The 1G-ONU 30 transmits an uplink message in the discovery window. The message from the 1G-ONU 30 is normally received by the 1G-OLT 10. Further, the 10G-ONU 40 transmits an uplink message in the discovery window. The message from the 10G-ONU 40 is normally received by the 10G-OLT 10.

  Here, the appearance timing of the discovery window of the existing PON system 1 is detected by the same procedure as the detection process of the no-signal section by the 10G-OLT 20X described in the first embodiment. , 3, the appearance timing of the discovery window of the existing PON system 1 may be detected by the same procedure as the detection processing of the no-signal section by the 10G-OLT 20Y, 20Z.

  As described above, according to the fourth embodiment, in the new PON system 2X, the optical branch network 50 is shared with the existing PON system 1, and a wavelength λ3 different from that of the existing PON system 1 is used for the wavelength of the downstream signal. Since the discovery window of the existing PON system is autonomously detected and used based on the upstream signal, it is transferred to the new PON system 2X in units of users (each subscriber side terminal) without affecting the operation of the existing PON system 1 It becomes possible to do.

  In the first embodiment, the no-signal section detection unit 29 corresponds to the detection unit described in the claims, the PON control unit 27 corresponds to the second band control unit, and the PON control unit 17 corresponds to the first band. Corresponds to the control unit. In the second embodiment, the no-signal section detection unit 70 corresponds to the detection unit described in the claims, the PON control unit 27 corresponds to the second band control unit, and the PON control unit 17 corresponds to the first band. Corresponds to the control unit. In the third embodiment, the PON control unit 27 corresponds to the detection unit and the second band control unit described in the claims, and the PON control unit 17 corresponds to the first band control unit.

  As described above, the PON system and the PON connection method according to the present invention are suitable for accommodating a new PON in an optical access network.

Claims (6)

In a PON system that accommodates a new PON that is different from the existing PON in the downlink and uplink transmission rates in the optical access network used by the existing PON,
A pseudo-pseudo subscriber side device connected to the optical access network on the subscriber side,
The new PON transmits and receives a downstream signal at a different wavelength from the existing PON, and transmits and receives an upstream signal at the same wavelength as the existing PON.
The station-side apparatus of the existing PON releases a predetermined time band as a new PON band and releases the band in the upstream direction of the existing PON when performing bandwidth control in the upstream direction of the existing PON. The band includes a first band control unit that performs band control so that the band is not allocated to the upstream band of the existing PON
The station apparatus on the new PON detects a release time zone opened by the first band control unit, and assigns the open time zone detected by the detection unit to the upstream band of the new PON. Two bandwidth control units ,
The pseudo-subscriber side device transmits release information regarding the release time zone to be transmitted to the new PON station side device, a downstream signal transmitted from the existing PON station side device, and the new PON station side device. An information generation unit that generates based on a downlink signal transmitted from
The detection unit included in the new PON station side device is based on release information generated by the information generation unit, a downlink signal transmitted from the own device to the pseudo subscriber side device, and timing when the release information is received. And detecting the open time zone.   2. The detection unit according to claim 1, wherein the detection unit detects the open time period based on an uplink signal transmitted from a subscriber-side device of the existing PON to the station-side device of the existing PON. PON system.   2. The detection unit according to claim 1, wherein the detecting unit detects the open time period based on a downlink signal transmitted from a station-side device of the existing PON to a subscriber-side device of the existing PON. PON system. The first bandwidth control unit includes the number of subscriber-side devices of the existing PON connected to the optical access network and the number of subscriber-side devices of the new PON connected to the optical access network. The PON system according to any one of claims 1 to 3 , wherein an open time period corresponding to the ratio is set. When performing discovery for accommodating and joining the new PON subscriber side device in the optical access network,
The first bandwidth control unit provided in the station device of the existing PON sets a release cycle by releasing a predetermined discovery cycle of discovery cycles when performing discovery of the existing PON,
The detection unit included in the station-side device of the new PON detects the release cycle opened by the first band control unit, and the second band control unit uses the release cycle detected by the detection unit. The PON system according to claim 1, wherein PON discovery is performed. In a PON connection method for accommodating a new PON that is different from the existing PON in the downlink and uplink transmission rates in the optical access network used by the existing PON,
When the station-side device of the existing PON performs upstream bandwidth control of the existing PON, a predetermined time zone of the bandwidth of the existing PON upstream is released as a new PON bandwidth and opened Is a first bandwidth control step for performing bandwidth control so as not to allocate to the upstream bandwidth of the existing PON;
A pseudo pseudo subscriber side device connected to the optical access network on the subscriber side transmits a downlink signal transmitted from the station side device of the existing PON and a downlink transmitted from the station side device of the new PON. A transmission step of generating release information related to the release time zone based on a direction signal and transmitting the release information to the station-side device of the new PON;
The new PON station side device detects the release time zone based on the generated release information, the downlink signal transmitted from the own device to the pseudo subscriber side device, and the timing at which the release information is received. A detection step;
A second bandwidth control step in which the station-side device of the new PON allocates the detected open time zone to an upstream bandwidth of the new PON;
PON connection method characterized by including.

Images