JP2013197830A - Onu - Google Patents

Abstract

PROBLEM TO BE SOLVED: To allow for efficient migration work in system switching from EPON to GE-PON, without changing the configuration of an OLT.SOLUTION: The ONU includes an optical divider 101 which outputs a downlink signal from an OLT2 while branching to a downlink signal of a wavelength band assigned by an EPON, and a downlink signal of a wavelength band assigned by a GE-PON, an EPON termination circuit 103 which terminates the downlink signal of a wavelength band assigned by the EPON from the optical divider 101, and a GE-PON termination circuit 106 which terminates the downlink signal of a wavelength band assigned by the GE-PON from the optical divider 101.

Description

  The present invention enables the efficiency of migration work when system switching from EPON (Ethernet (registered trademark) Passive Optical Network) to GE-PON (Gigabit Ethernet (registered trademark) -Passive Optical Network) is performed. It is related to ONU (Optional Network Unit).

  The EPON is a PON having a transmission rate of 100 Mbps, and communicates by connecting one OLT (Optical Line Terminal) and a plurality of ONUs via a coupler. Here, the OLT is installed on the communication network provider station side (hereinafter referred to as the “station side”), and the ONU is installed in each subscriber's home or outdoors (hereinafter referred to as the “user home side”). On the other hand, GE-PON defined in IEEE 802.3-2005 is a PON having a transmission rate of 1 Gbps, and system switching from EPON is performed.

  Here, EPON and GE-PON have the same network topology, and a transmission path having the same specification can be used. However, as shown in FIG. 12A, EPON OLT and GE-PON ONU are not compatible and cannot be connected for the following reason.

The first reason is that the wavelength band of the downstream signal is different between EPON and GE-PON. That is, as shown in FIG. 13, in EPON, a wavelength band of 1540 to 1570 nm is assigned as a downlink signal, whereas in GE-PON, a wavelength band of 1480 to 1500 nm is assigned as a downlink signal. Therefore, the GE-PON ONU cannot receive a downstream signal from the EPON OLT. In addition, as shown in FIG. 13, in the upstream signals of EPON and GE-PON, a wavelength band of 1260 to 1360 nm is assigned.
The second reason is that the communication protocol is different between EPON and GE-PON. Therefore, data does not conduct between EPON OLT and GE-PON ONU.

  Therefore, when system switching from EPON to GE-PON is performed, if the EPON ONUs on the user's home side are sequentially replaced with GE-PON ONUs, the station-side EPON OLT is finally replaced with the GE-PON OLT. Until it is exchanged, communication cannot be performed at the user home exchanged with the GE-PON ONU. Therefore, when system switching is performed, it is necessary to exchange all EPON ONUs on the user's home side with GE-PON ONUs at the same time, and exchange the EPON OLT on the station side with GE-PON OLT.

  Note that as shown in FIG. 12B, GE-PON OLT and EPON ONU are similarly incompatible and cannot be connected.

JP 2011-77798 A

As described above, conventionally, when system switching from EPON to GE-PON is performed, it is necessary to simultaneously replace all EPON ONUs on the user's home side with GE-PON ONUs. However, there is a problem that simultaneous exchange of ONUs at all user homes is difficult.
As a conventional technique, there is an ONU in which the power is turned on when a downlink signal addressed to itself is received, and the power is turned off when a downlink signal destined for another is received (see, for example, Patent Document 1). In this prior art, ON / OFF of the ONU power is controlled based on a signal from the OLT. Then, it may be possible to use this conventional technology to improve the efficiency of migration work for system switching from EPON to GE-PON. However, in the technique disclosed in Patent Document 1, it is necessary to change the configuration of the OLT on the station side, which causes a problem that the system configuration becomes complicated.

  The present invention has been made to solve the above problems, and provides an ONU capable of improving the efficiency of migration work in system switching from EPON to GE-PON without changing the OLT configuration. The purpose is to do.

  The ONU according to the present invention branches an output signal from the OLT into a downlink signal in a wavelength band assigned by EPON and a downlink signal in a wavelength band assigned by GE-PON, and outputs an optical branching unit, An EPON termination unit that terminates a downstream signal in the wavelength band assigned by EPON from the optical branching unit, and a G-PON termination unit that terminates a downstream signal in the wavelength band allocated by GE-PON from the optical branching unit. It is provided.

  According to the present invention, since it is configured as described above, it is possible to improve the efficiency of migration work in system switching from EPON to GE-PON without changing the configuration of the OLT.

It is a figure which shows the structure of ONU which concerns on Embodiment 1 of this invention. It is a figure which shows the compatibility with ONU which concerns on Embodiment 1 of this invention, and OLT (EPON, GE-PON). It is a flowchart which shows operation | movement of ONU which concerns on Embodiment 1 of this invention. It is a figure explaining the migration method using ONU which concerns on Embodiment 1 of this invention. It is a figure which shows another structure of ONU which concerns on Embodiment 1 of this invention. It is a figure which shows the structure of ONU which concerns on Embodiment 2 of this invention. It is a flowchart which shows operation | movement of ONU which concerns on Embodiment 2 of this invention. It is a figure which shows the structure of ONU which concerns on Embodiment 3 of this invention. It is a figure which shows the structure of ONU which concerns on Embodiment 4 of this invention. It is a flowchart which shows operation | movement of ONU which concerns on Embodiment 4 of this invention. It is a figure which shows the signal state in each function part of ONU which concerns on Embodiment 4 of this invention. It is a figure which shows the incompatibility with the conventional ONU and OLT (EPON, GE-PON). It is a figure which shows the use wavelength range of EPON and GE-PON.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
Embodiment 1 FIG.
FIG. 1 is a diagram showing the configuration of the ONU 1 according to Embodiment 1 of the present invention.
The ONU (EPON / GE-PON integrated ONU) 1 is used at each user's home when switching the system from EPON to GE-PON, and between the OLT 2 installed at the station side Communication is performed via a coupler 3 (see FIG. 2).

As shown in FIG. 1, the OUN 1 includes an optical branching unit (optical branching unit) 101, a first O / E circuit 102, an EPON termination circuit (EPON termination unit) 103, an optical multiplexer / demultiplexer 104, and a second O / E circuit 102. / E circuit 105, GE-PON termination circuit (GE-PON termination unit) 106, first determination selection circuit (determination unit, second selection unit) 107, second determination selection circuit (determination unit, first (Selection unit) 108, user-side port 109, switching selection circuit (switching selection unit) 110, and E / O circuit 111.
The OLT 2 is EPON OLT before system switching and GE-PON OLT after system switching.

  The optical branching device 101 branches a downstream signal (optical signal) from the OLT 2 at a predetermined wavelength and outputs the branched signal to the corresponding termination circuit (EPON termination circuit 103 or GE-PON termination circuit 106). Here, as shown in FIG. 13, in EPON, a wavelength band of 1540 to 1570 nm is assigned as a downlink signal, and in GE-PON, a wavelength band of 1480 to 1500 nm is assigned as a downlink signal. Then, the optical branching device 101 branches the downstream signal from the OLT 2 at a predetermined wavelength between 1500 and 1540 nm, and the downstream signal with the wavelength band of 1540 to 1570 nm is on the EPON termination circuit 103 side (first O / E circuit 102). And a downstream signal having a wavelength band of 1480 to 1500 nm is output to the GE-PON termination circuit 106 side (optical multiplexer / demultiplexer 104).

  The first O / E circuit 102 is an O / E circuit corresponding to a signal in a wavelength band assigned by EPON, and converts a downstream signal (optical signal) from the optical splitter 101 into an electrical signal. . The downstream signal converted into the electrical signal by the first O / E circuit 102 is output to the EPON termination circuit 103.

The EPON termination circuit 103 is a termination circuit that operates according to the EPON communication protocol, and terminates a downstream signal from the first O / E circuit 102 to perform various processes. The signal processed by the EPON termination circuit 103 is output to the second determination / selection circuit 108. Further, the EPON termination circuit 103 outputs a signal (reception presence / absence signal) indicating whether or not a downlink signal is received to the first determination / selection circuit 107.
The EPON termination circuit 103 also has a function of generating an upstream signal to the OLT 2 based on a signal output from the user side port 109 via the second determination selection circuit 108. In the uplink signal in this EPON, as shown in FIG. 13, a wavelength band of 1260 to 1360 nm is assigned. The upstream signal generated by the EPON termination circuit 103 is output to the switching selection circuit 110.

  The optical multiplexer / demultiplexer 104 outputs the downstream signal from the optical branching device 101 to the second O / E circuit 105, and outputs the upstream signal from the E / O circuit 111 to the OLT 2 via the optical branching device 101. It is.

  The second O / E circuit 105 is an O / E circuit corresponding to a signal in a wavelength band assigned by GE-PON, and converts a downstream signal (optical signal) from the optical multiplexer / demultiplexer 104 into an electrical signal. Is. The downstream signal converted into the electrical signal by the second O / E circuit 105 is output to the GE-PON termination circuit 106.

The GE-PON termination circuit 106 is a termination circuit that operates according to the GE-PON communication protocol, and terminates the downstream signal from the second O / E circuit 105 to perform various processes. The signal processed by the GE-PON termination circuit 106 is output to the second determination / selection circuit 108. Further, the GE-PON termination circuit 106 outputs a signal (reception presence / absence signal) indicating whether or not a downlink signal is received to the first determination selection circuit 107.
The GE-PON termination circuit 106 also has a function of generating an upstream signal to the OLT 2 based on a signal output from the user side port 109 via the second determination selection circuit 108. Note that, in the upstream signal in this GE-PON, as shown in FIG. 13, the wavelength band of 1260 to 1360 nm is assigned as in the upstream signal in EPON. The upstream signal generated by the GE-PON termination circuit 106 is output to the switching selection circuit 110.

  Based on the reception presence / absence signals from the EPON termination circuit 103 and the GE-PON termination circuit 106, the first determination selection circuit 107 sends a downstream signal to any termination circuit of the EPON termination circuit 103 and the GE-PON termination circuit 106. Is determined. A signal (reception circuit determination signal) indicating the determination result by the first determination selection circuit 107 is output to the second determination selection circuit 108. The first determination selection circuit 107 also has a function of controlling the switching selection circuit 110 based on the determination result.

  Based on the determination result (reception circuit determination signal) by the first determination selection circuit 107, the second determination selection circuit 108 determines to which terminal circuit the downlink signal has been output, and the downlink signal is output. Only a signal that has been terminated and processed by the termination circuit is selected and output to the user-side port 109. Further, the second determination selection circuit 108 outputs a signal output from the user-side port 109 to the termination circuit based on the determination result.

  The user-side port 109 outputs a signal output from one terminal circuit via the second determination / selection circuit 108 to a lower-order user terminal (not shown). Further, the user-side port 109 outputs a signal from the user terminal to the second determination / selection circuit 108. It is assumed that the user-side port 109 has a function (auto-negotiation function) that autonomously sets an optimal link speed according to an input signal.

  The switching selection circuit 110 outputs only an upstream signal from one of the EPON termination circuit 103 and the GE-PON termination circuit 106 to the E / O circuit 111 according to the control of the first determination selection circuit 107. The switching is performed as described above.

  The E / O circuit 111 is an O / E circuit corresponding to a signal in a wavelength band assigned by EPON and GE-PON, and converts an upstream signal (electric signal) from the switching selection circuit 110 into an optical signal. is there. The upstream signal converted into the optical signal by the E / O circuit 111 is output to the optical multiplexer / demultiplexer 104.

  As described above, the ONU 1 includes both the EPON termination circuit 103 that operates according to the EPON communication protocol and the GE-PON termination circuit 106 that operates according to the GE-PON communication protocol. Therefore, as shown in FIG. 2, the ONU 1 is compatible and connectable with both the GE-PON OLT and the EPON OLT.

Next, the operation of the ONU 1 configured as described above will be described with reference to FIG.
In the operation of the ONU 1, as shown in FIG. 3, first, the optical branching device 101 branches the downstream signal (optical signal) from the OLT 2 at a predetermined wavelength (a wavelength between 1500 to 1540 nm) and the downstream signal of 1540 to 1570 nm. Is output to the EPON termination circuit 103 side (first O / E circuit 102), and a downstream signal of 1480 to 1500 nm is output to the GE-PON termination circuit 106 side (optical multiplexer / demultiplexer 104) (step ST31).

Next, the termination circuit to which the downlink signal is output from the optical branching unit 101 terminates the downlink signal according to its own communication protocol (step ST32).
When a downstream signal is output to the EPON termination circuit 103, the downstream signal is terminated by the EPON termination circuit 103 according to the EPON communication protocol. That is, the first O / E circuit 102 converts the downstream signal (optical signal) from the optical branching device 101 into an electrical signal, and the EPON termination circuit 103 terminates the downstream signal and performs various processes. The signal processed by the EPON termination circuit 103 is output to the second determination / selection circuit 108. Further, the EPON termination circuit 103 outputs a signal (reception presence / absence signal) indicating whether or not a downlink signal is received to the first determination / selection circuit 107.

  When a downstream signal is output to the GE-PON termination circuit 106 side, the downstream signal is terminated by the GE-PON termination circuit 106 according to the GE-PON communication protocol. That is, the second O / E circuit 105 converts the downstream signal (optical signal) received via the optical multiplexer / demultiplexer 104 into an electrical signal, and the GE-PON termination circuit 106 terminates the downstream signal. Perform various processes. The signal processed by the GE-PON termination circuit 106 is output to the second determination / selection circuit 108. Further, the GE-PON termination circuit 106 outputs a signal (reception presence / absence signal) indicating whether or not a downlink signal is received to the first determination selection circuit 107.

  Next, based on the reception presence / absence signal from the EPON termination circuit 103 and the GE-PON termination circuit 106, the first determination selection circuit 107 selects which termination circuit out of the EPON termination circuit 103 and the GE-PON termination circuit 106. It is determined whether a downlink signal has been output (step ST33). A signal (reception circuit determination signal) indicating the determination result by the first determination selection circuit 107 is output to the second determination selection circuit 108.

The first determination selection circuit 107 controls the switching selection circuit 110 based on the determination result (step ST34). In other words, when a downstream signal is output to the EPON termination circuit 103 side with respect to the switching selection circuit 110, the first determination selection circuit 107 outputs only the upstream signal from the EPON termination circuit 103 to the E / O circuit 111. When the downstream signal is output to the GE-PON termination circuit 106 side, only the upstream signal from the GE-PON termination circuit 106 is output to the E / O circuit 111. Let the switch occur.
Here, the ONU 1 generates and transmits an upstream signal by receiving the downstream signal from the OLT 2. Therefore, by knowing which of the EPON and GE-PON corresponds to the downstream signal from the OLT 2, it is possible to grasp the termination circuit that generates the upstream signal.

Next, the second determination selection circuit 108 determines to which terminal circuit the downstream signal is output based on the determination result (reception circuit determination signal) by the first determination selection circuit 107, and the downstream signal is output. Only the signal that has been terminated and processed by the terminated circuit is selected and output to the user-side port 109 (step ST35). That is, when a downstream signal is output to the EPON termination circuit 103 side, only the signal terminated and processed by the EPON termination circuit 103 is selected and output to the user side port 109. On the other hand, when a downstream signal is output to the GE-PON termination circuit 106 side, only the signal terminated and processed by the GE-PON termination circuit 106 is selected and output to the user side port 109.
Even if a signal is erroneously output from the unnecessary termination circuit by the second determination selection circuit 108, the signal does not flow to the user side port 109 side, and malfunction can be prevented.

  Further, the second determination selection circuit 108 outputs a signal output from the user-side port 109 thereafter to the termination circuit from which the downlink signal was output immediately before based on the determination result by the first determination selection circuit 107. (Step ST36).

Next, the termination circuit to which a signal is output from the user-side port 109 via the second determination / selection circuit 108 generates and transmits an uplink signal to the OLT 2 according to its own communication protocol (step ST37).
Here, when a signal is output to the EPON termination circuit 103, the EPON termination circuit 103 generates and transmits an uplink signal according to the EPON communication protocol. That is, the EPON termination circuit 103 generates an upstream signal based on the signal from the user side port 109, and the E / O circuit 111 converts the upstream signal (electric signal) received via the switching selection circuit 110 into an optical signal. The signal is converted and output to the OLT 2 via the optical multiplexer / demultiplexer 104 and the optical branching unit 101.

When a signal is output to the GE-PON termination circuit 106, the GE-PON termination circuit 106 generates and transmits an upstream signal according to the GE-PON communication protocol. That is, the GE-PON termination circuit 106 generates an upstream signal based on the signal from the user-side port 109, and the E / O circuit 111 outputs the upstream signal (electric signal) received via the switching selection circuit 110 as an optical signal. The signal is converted into a signal and output to the OLT 2 via the optical multiplexer / demultiplexer 104 and the optical branching unit 101.
In step ST37, the switching selection circuit 110 selects an upstream signal to be output to the OLT 2 side in accordance with the control by the first determination selection circuit 107. Therefore, even when an uplink signal is generated by mistake in an unnecessary termination circuit, the uplink signal does not flow before the switching selection circuit 110, and malfunction can be prevented.

Next, a migration method in the case where system switching from EPON to GE-PON is performed using the ONU 1 configured as described above will be described with reference to FIG.
In a state before the system switching, as shown in FIG. 4A, an EPON OLT is installed on the station side, and an EPON ONU is installed on each user's home side. The EPON OLT and each EPON ONU are connected via a coupler 3.

  When switching the system from EPON to GE-PON, as shown in FIG. 4B, first, as shown in FIG. 4B, the EPON ONU installed in each user's house is replaced with the ONU (EPON / GE-PON integrated type) of the present invention. ONU) 1 in order. At this time, since the replaced ONU 1 has the EPON termination circuit 103 and can receive the downstream signal from the EPON OLT, it can be operated normally even during the system switching. .

  Thereafter, as shown in FIG. 4C, after all the EPON ONUs on the user's home side are replaced with the ONU 1 of the present invention, the EPON OLT on the station side is replaced with the GE-PON OLT. As a result, the GE-PON termination circuit 106 functions thereafter in the ONU 1 of the present invention. Thereby, the system switching from EPON to GE-PON can be completed.

As described above, according to the first embodiment, the optical branching device that branches the downlink signal from the OLT 2 into the downlink signal in the wavelength band assigned by EPON and the downlink signal in the wavelength band assigned by GE-PON. 101, an EPON termination circuit 103 that terminates a downlink signal in the wavelength band assigned by EPON, and a GE-PON termination circuit 106 that terminates a downlink signal in the wavelength band assigned by GE-PON. Therefore, in changing the system from EPON to GE-PON without changing the configuration of the OLT 2, it is not necessary to exchange all the ONUs on the user's home side at the same time, and it is possible to exchange them sequentially. Therefore, the efficiency of the migration work can be improved.
In addition, when it is necessary to exchange ONUs all at once as in the prior art, a construction contractor needs to perform work. However, when the ONUs can be sequentially replaced, for example, the ONU 1 of the present invention can be sent to the user's home and the user can perform the ONU replacement. Reduction can be achieved.

  In the first embodiment, switching from EPON to GE-PON is shown as system switching. Normally, as the system switching, switching from the old EPON to the new GE-PON is assumed, but if the system switching from GE-PON to EPON is necessary, the ONU 1 of the present invention is used. The same effect can be obtained.

  Further, the description has been given assuming that the user-side port 109 in the first embodiment has an auto-negotiation function and can set the link speed to an optimum value autonomously according to an input signal. However, when the user side port 109b not having the above function is used, the link speed of the user side port 109b is set to the first determination selection circuit 107 based on the determination result, for example, as shown in FIG. You may make it add the function (setting part) set to an optimal value. In this case, if the first determination / selection circuit 107 determines that a downlink signal has been output to the EPON termination circuit 103 side, the first determination / selection circuit 107 sets the link speed of the user-side port 109 to a maximum of 100 Mbps. On the other hand, if it is determined that a downstream signal has been output to the GE-PON termination circuit 106 side, the link speed of the user side port 109 is set to a maximum of 1 Gbps.

  In the first embodiment, the case where the second determination selection circuit 108 and the switching selection circuit 110 are provided in order to reliably prevent malfunction due to a signal erroneously output from an unnecessary termination circuit has been described. Instead of these circuits, for example, a switch that can physically switch the signal path may be used to realize the same operation. Further, the second determination selection circuit 108 and the switching selection circuit 110 are not essential components and may be deleted.

Embodiment 2. FIG.
FIG. 6 is a diagram showing the configuration of the ONU 1 according to Embodiment 2 of the present invention. The ONU 1 according to the second embodiment shown in FIG. 6 is obtained by adding a circuit stop control circuit (stop control unit) 112 to the ONU 1 according to the first embodiment shown in FIG. Other configurations are the same, and the same reference numerals are given and description thereof is omitted.
Note that the first determination selection circuit 107 performs a second determination on a signal (reception circuit determination signal) indicating which of the EPON termination circuit 103 and the GE-PON termination circuit 106 the downlink signal is output to. The data is output to the selection circuit 108 and the circuit stop control circuit 112.

Based on the determination result (reception circuit determination signal) by the first determination selection circuit 107, the circuit stop control circuit 112 is a signal (stop) that instructs an unnecessary termination circuit to which no downlink signal is output. Signal). The circuit stop control circuit 112 instructs the termination circuit to start operation when the content of the determination result by the first determination selection circuit 107 is switched after stopping the operation of the termination circuit. Output a start signal.
The EPON termination circuit 103 and the GE-PON termination circuit 106 have a function of stopping / starting their own operations in response to signals (stop signal, start signal) from the circuit stop control circuit 112.

Next, the unnecessary circuit determination / stop operation by the ONU 1 configured as described above will be described with reference to FIG.
In the unnecessary circuit determination / stop operation by the ONU 1, as shown in FIG. 7, first, when the downstream signal from the OLT 2 is received by the ONU 1, the termination circuit corresponding to the wavelength band via the optical branching unit 101. A downstream signal is output to (EPON termination circuit 103 or GE-PON termination circuit 106) (step ST71).

Next, based on the reception presence / absence signal from the GE-PON termination circuit 106, the first determination selection circuit 107 determines whether a downstream signal has been output to the GE-PON termination circuit 106 side (step ST72).
In step ST72, when the first determination selection circuit 107 determines that a downstream signal is output to the GE-PON termination circuit 106 side, the circuit stop control circuit 112 stops the operation with respect to the EPON termination circuit 103. Is output (stop signal) (step ST73). Thereafter, the EPON termination circuit 103 that has received the stop signal stops its own operation. Then, the GE-PON termination circuit 106 terminates the downstream signal.

On the other hand, when the first determination selection circuit 107 determines in step ST72 that no downlink signal is output to the GE-PON termination circuit 106 side, based on the reception presence / absence signal from the EPON termination circuit 103, It is determined whether a downstream signal has been output to the EPON termination circuit 103 side (step ST74).
In step ST74, when the first determination selection circuit 107 determines that a downstream signal is output to the EPON termination circuit 103, the circuit stop control circuit 112 stops the operation with respect to the GE-PON termination circuit 106. Is output (step ST75). Thereafter, the GE-PON termination circuit 106 that has received the stop signal stops its own operation. The EPON termination circuit 103 terminates the downstream signal.

  If the downstream signal is not output to the termination circuit in use thereafter, the first determination / selection circuit 107 determines that there is no termination circuit to which the downstream signal is output. Then, according to the determination result, the circuit stop control circuit 112 outputs a signal (start signal) instructing the operation start to the termination circuit whose operation has been stopped. Thereafter, the termination circuit that has received the activation signal starts operation.

  As described above, according to the second embodiment, the configuration is such that it is determined to which termination circuit the downlink signal has been output and the operation of the unnecessary termination circuit is stopped. In addition, it is possible to save power.

Embodiment 3 FIG.
FIG. 8 is a diagram showing the configuration of the ONU 1 according to Embodiment 3 of the present invention. The ONU 1 according to the third embodiment shown in FIG. 8 is obtained by adding a state monitoring circuit (state monitoring unit, notification instruction unit) 113 to the ONU 1 according to the first embodiment shown in FIG. Other configurations are the same, and the same reference numerals are given and description thereof is omitted.

The state monitoring circuit 113 monitors the state of the unused termination circuit in which no downstream signal is output (for example, whether the circuit starts normally or the clock operates normally). At this time, the state monitoring circuit 113 notifies a signal (state request signal) requesting state notification to the unused termination circuit, and performs state monitoring by latching a response (state signal) from the termination circuit. .
Further, the state monitoring circuit 113 also has a function of instructing the termination circuit in the used state from which the downlink signal is output to notify the OLT 2 of the monitoring result (state notification signal). For example, when the unused GE-PON state is monitored, the monitoring result is notified to the OLT 2 by using the used EPON termination circuit 103 (the EPON termination circuit 103 notifies the OLT 2 with an upstream signal). .

  As described above, according to the third embodiment, the state of the unused termination circuit is monitored and notified to the OLT 2 using the used termination circuit. In addition to the effect, it is possible to prevent the occurrence of a failure at the time of system switching.

Embodiment 4 FIG.
FIG. 9 is a diagram showing the configuration of the ONU 1 according to Embodiment 4 of the present invention. The ONU 1 according to the fourth embodiment shown in FIG. 9 changes the circuit stop control circuit 112 of the ONU 1 according to the second embodiment shown in FIG. 6 to a circuit stop control circuit (stop control circuit) 112b, and a state monitoring circuit (state A monitoring unit, a notification instruction unit) 113b and a timer circuit 114 are added. Other configurations are the same, and the same reference numerals are given and description thereof is omitted.
Note that the first determination selection circuit 107 performs a second determination on a signal (reception circuit determination signal) indicating which of the EPON termination circuit 103 and the GE-PON termination circuit 106 the downlink signal is output to. The data is output to the selection circuit 108, the circuit stop control circuit 112b, and the timer circuit 114.

Based on the determination result (reception circuit determination signal) by the first determination selection circuit 107, the circuit stop control circuit 112b is a signal (stop) for instructing an unnecessary termination circuit to which no downstream signal is output. Signal). The circuit stop control circuit 112b instructs the termination circuit to start operation when the content of the determination result by the first determination selection circuit 107 is switched after stopping the operation of the termination circuit. Output a start signal. Further, the circuit stop control circuit 112b also has a function of outputting a signal (start signal, stop signal) for temporarily operating the terminal circuit whose operation has been stopped in response to the timer signal from the timer circuit 114. doing.
The EPON termination circuit 103 and the GE-PON termination circuit 106 have a function of stopping / starting their own operations in response to signals (stop signal, start signal) from the circuit stop control circuit 112b.

The state monitoring circuit 113b does not output a downstream signal, and the state of the unused termination circuit temporarily operated by the circuit stop control circuit 112b (for example, the circuit starts normally or the clock is normal) Or the like). At this time, the state monitoring circuit 113b notifies a signal (state request signal) for requesting a state notification to the unused termination circuit, and monitors the state by latching a response (state signal) from the termination circuit. .
In addition, the state monitoring circuit 113b has a function of instructing the OLT 2 to notify the OLT 2 of the monitoring result (state notification signal) to the used termination circuit from which the downlink signal is output.

  The timer circuit 114 starts a timer based on the determination result (reception circuit determination signal) by the first determination selection circuit 107. Then, after the timer expires, a timer signal indicating that is output to the circuit stop control circuit 112b. After a predetermined period of time, the timer is started again, and a timer signal indicating that is output to the circuit stop control circuit 112b.

Next, the state monitoring operation by the ONU 1 configured as described above will be described with reference to FIGS. FIG. 11 shows a case where a downstream signal is output to the EPON termination circuit 103 and the operation of the GE-PON termination circuit 106 is stopped.
In the state monitoring operation by the ONU 1, as shown in FIG. 10, after a downstream signal is output to one of the termination circuits, the operation of the unused termination circuit is stopped by the unnecessary circuit determination / stop operation shown in FIG. (ST101) First, the timer circuit 114 starts a timer (step ST102). In the example illustrated in FIG. 11, the timer circuit 114 starts the timer after the downstream signal is output to the EPON termination circuit 103 and the operation of the GE-PON termination circuit 106 is stopped.
Next, after the timer expires, the timer circuit 114 outputs a timer signal indicating that to the circuit stop control circuit 112b and the state monitoring circuit 113b (step ST103).

  Next, in response to the timer signal from the timer circuit 114, the circuit stop control circuit 112b outputs a signal (start signal) instructing the temporary restart of the operation to the termination circuit that has stopped the operation (step ST104). . In the example shown in FIG. 11, the circuit stop control circuit 112b temporarily operates the GE-PON termination circuit 106 after the timer expiration is notified. As a result, it is possible to monitor the state of the unused GE-PON termination circuit 106.

Next, the state monitoring circuit 113b monitors the state of the unused termination circuit in accordance with the timer signal from the timer circuit 114 (step ST105). In the example illustrated in FIG. 11, the state monitoring circuit unit 113b is notified of the expiration of the timer and waits for a predetermined period (waiting for activation of the GE-PON termination circuit 106), and then requests the GE-PON termination circuit 106 to notify the state. (Status request signal) is notified and status response is monitored by latching the response (status signal).
Next, the state monitoring circuit 113b instructs the terminal circuit in use to notify the OLT 2 of the monitoring result (step ST106). In the example illustrated in FIG. 11, the state monitoring circuit 113 b notifies the OLT 2 of the monitoring result (status signal) of the GE-PON termination circuit 106 using the EPON termination circuit 103.

Thereafter, while the downstream signal continues to be output to the EPON termination circuit 103, the operations of steps ST102 to ST106 are repeated.
In step ST102 after the second order, the timer circuit 114 activates the timer again after a predetermined period (more than the time required for the state monitoring circuit 113b to perform state monitoring) after the timer expires, and notifies that effect. The timer signal shown is output to the circuit stop control circuit 112b. Upon receiving this timer signal, the circuit stop control circuit 112b outputs a signal (stop signal) instructing the operation stop to the unused termination circuit whose operation has been temporarily resumed. In the example illustrated in FIG. 11, the circuit stop control circuit 112 b stops the operation of the GE-PON termination circuit 106. Thereby, power saving can be achieved.

After that, as shown in FIG. 11, when the downlink signal is not output to the EPON termination circuit 103, the first determination / selection unit 107 determines that there is no termination circuit to which the downlink signal is output. Then, according to the determination result, the circuit stop control circuit 112b outputs a signal (start signal) instructing the GE-PON termination circuit 106 to start the operation. Thereafter, the GE-PON termination circuit 106 that has received the activation signal starts its operation. The timer circuit 114 stops the timer.
Thereafter, the process returns to the unnecessary circuit determination / stop operation shown in FIG.

  As described above, according to the fourth embodiment, it is determined to which termination circuit the downstream signal is output, operation of the unnecessary termination circuit is stopped, and the state of the unused termination circuit is monitored. Therefore, in addition to the effect in the second embodiment, it is possible to prevent the occurrence of a failure at the time of system switching.

  In the state monitoring circuits 113 and 113b in the third and fourth embodiments, the state monitoring of the unused termination circuit (EPON termination circuit 103 or GE-PON termination circuit 106) is performed. On the other hand, normally, after the system is switched from EPON to GE-PON, the EPON termination circuit 103 is not used. For this reason, only the unused GE-PON termination circuit 106 may be monitored.

  Further, within the scope of the present invention, the invention of the present application can be freely combined with each embodiment, modified with any component in each embodiment, or omitted with any component in each embodiment. .

1 ONU, 2 OLT, 3 coupler, 101 optical branching unit (optical branching unit), 102 first O / E circuit, 103 EPON termination circuit (EPON termination unit), 104 optical multiplexer / demultiplexer,
105 second O / E circuit, 106 GE-PON termination circuit (GE-PON termination unit), 107 first determination selection circuit (determination unit, second selection unit, setting unit), 108 second determination selection Circuit (determination unit, first selection unit), 109, 109b user side port, 110 switching selection circuit (switching selection unit), 111 E / O circuit, 112, 112b circuit stop control circuit (stop control unit), 113, 113b State monitoring circuit (state monitoring unit, notification instruction unit), 114 timer circuit.

Claims (10)

An optical branching unit that branches and outputs a downlink signal from the OLT into a downlink signal in a wavelength band assigned by EPON and a downlink signal in a wavelength band assigned by GE-PON;
An EPON termination unit that terminates a downstream signal in the wavelength band assigned by the EPON from the optical branching unit;
An ONU comprising: a GE-PON termination unit that terminates a downstream signal in a wavelength band assigned by the GE-PON from the optical branching unit. A determination unit that determines which of the EPON termination unit and the GE-PON termination unit the downlink signal is output to;
2. The ONU according to claim 1, further comprising: a stop control unit configured to stop the operation of the termination unit from which the downlink signal is not output based on a determination result by the determination unit. Among the EPON termination unit and the GE-PON termination unit, a state monitoring unit that monitors the state of the termination unit that is not outputting the downlink signal;
Among the EPON termination unit and the GE-PON termination unit, a notification instruction unit is provided that instructs the termination unit to which the downlink signal is output to notify the OLT of the monitoring result by the state monitoring unit. The ONU according to claim 1. The stop control unit temporarily operates the terminal unit that stopped the operation at a predetermined timing,
Of the EPON termination unit and the GE-PON termination unit, a state monitoring unit that monitors the state of the termination unit that is not output the downlink signal and is temporarily operated by the stop control unit;
Among the EPON termination unit and the GE-PON termination unit, a notification instruction unit is provided that instructs the termination unit to which the downlink signal is output to notify the OLT of the monitoring result by the state monitoring unit. The ONU according to claim 2. A user-side port that outputs a signal that has been terminated and processed by the EPON termination unit and the GE-PON termination unit to a lower-level user terminal;
A determination unit that determines which of the EPON termination unit and the GE-PON termination unit the downlink signal is output to;
The ONU according to claim 1, further comprising: a setting unit configured to set a link speed of the user side port based on a determination result by the determination unit. A user-side port that outputs an input signal to a lower-level user terminal; and
A determination unit that determines which of the EPON termination unit and the GE-PON termination unit the downlink signal is output to;
2. The apparatus according to claim 1, further comprising: a first selection unit that outputs to the user side port a signal that has been terminated and processed by a termination unit that has determined that the downlink signal has been output by the determination unit. Alternatively, the ONU according to claim 3. The EPON termination unit and the GE-PON termination unit have a function of generating an upstream signal,
Of the EPON termination unit and the GE-PON termination unit, a switching selection unit that performs switching so as to output an upstream signal from one termination unit to the OLT;
A determination unit that determines which of the EPON termination unit and the GE-PON termination unit the downlink signal is output to;
The ONU according to claim 1, further comprising: a second selection unit that controls the switching selection unit based on a determination result by the determination unit. A user-side port that outputs a signal that has been terminated and processed by the EPON termination unit and the GE-PON termination unit to a lower-level user terminal;
The ONU according to claim 2, further comprising: a setting unit configured to set a link speed of the user side port based on a determination result by the determination unit. A user-side port that outputs an input signal to a lower-level user terminal; and
The apparatus according to claim 2, further comprising: a first selection unit that outputs to the user-side port a signal that has been terminated and processed by a termination unit that has determined that the downlink signal has been output by the determination unit. Alternatively, the ONU according to claim 4. The EPON termination unit and the GE-PON termination unit have a function of generating an upstream signal,
Of the EPON termination unit and the GE-PON termination unit, a switching selection unit that performs switching so as to output an upstream signal from one termination unit to the OLT;
The ONU according to claim 2, further comprising: a second selection unit that controls the switching selection unit based on a determination result by the determination unit.

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