WO2016106599A1 - 一种应用于多波长无源光网络的通信方法、装置及系统 - Google Patents
一种应用于多波长无源光网络的通信方法、装置及系统 Download PDFInfo
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Definitions
- the present invention relates to the field of communications, and in particular, to a communication method, apparatus, and system for a multi-wavelength passive optical network system.
- Passive Optical Network (PON) technology is currently a major broadband access technology.
- TDM Time Division Multiplexing
- WDM Wave Division Multiplexing
- TWDM Time Wave Division Multiplexing
- the TWDM PON system is a point-to-multipoint communication system, in which an optical line terminal (OLT) at the central office and an optical network unit ("ONU")/optical network terminal at the user end (“Optical Network Unit”)
- the optical network terminal uses multiple wavelength channels for data transmission and reception.
- Each ONU operates in one of the wavelength channels.
- the ONU can be used to refer to the ONU and/or the ONT.
- the OLT broadcasts downlink data to multiple ONUs working in the wavelength channel by using corresponding downlink wavelengths of each wavelength channel.
- the ONU of each wavelength channel can adopt the time slot allocated by the OLT.
- the upstream wavelength of the wavelength channel sends uplink data to the OLT.
- the downlink wavelength and the uplink wavelength used by the ONU can be dynamically adjusted.
- the OLT finds that the load of a certain wavelength channel is too large, it can send a wavelength switching instruction to the ONU working in the wavelength channel, instructing the ONU to switch to the lighter wavelength channel by adjusting its upstream wavelength and/or downlink wavelength.
- the OLT needs to first send a wavelength switching command to the ONU, and the ONU starts to perform wavelength switching after receiving the wavelength switching instruction. While waiting for the ONU to complete the wavelength switching, the OLT continuously sends an inquiry command to the ONU to complete the handover. After the ONU completes the wavelength switching, the message that the wavelength switching has been completed is sent to the OLT. After receiving the message that the ONU has completed the wavelength switching, the OLT starts to send information such as downlink data and time slot authorization of the uplink data to the ONU, so that the OLT and the ONU can resume normal service communication.
- the wavelength switching time is long, and the OLT and the ONU need to repeatedly confirm the information exchange to restore normal data communication. Therefore, the wavelength switching causes the service interruption time to be long, which may reduce the user experience of real-time transmission services such as voice and video.
- traffic congestion or bursts of data traffic occurs, data loss may occur, which affects service quality.
- the embodiments of the present invention provide a communication method, an optical network terminal, an optical line terminal, and a passive optical network system, which are applied to a multi-wavelength passive optical network system, and are used to solve the problem that the service interruption is long due to wavelength switching in the prior art.
- Technical problem .
- a communication method is applied to a multi-wavelength passive optical network system, where the multi-wavelength PON includes an optical line terminal OLT and at least one optical network unit ONU, and the ONU includes at least a first port and a second port.
- the method includes the ONU receiving, by using the first port or the second port, a wavelength switch request message sent by the OLT, where the wavelength switch request message carries second wavelength channel information and port information of the second port.
- the ONU switches the working wavelength channel of the optical module connected to the second port from the first wavelength channel to the second wavelength channel; the ONU sends a wavelength switch to the OLT through the first port Complete the message.
- the method further includes: switching, by the ONU, an operating wavelength channel of an optical module connected to the second port from the first wavelength channel During the process of the second wavelength channel, the ONU sends the current state information of the ONU to the OLT through the first port.
- the method further includes the ONU receiving the OLT sending by using the second port a wavelength confirmation command; and the ONU transmits a wavelength confirmation response message on the second wavelength channel through the second port.
- the ONU receives, by using the first port or the second port, a service switching message, the service switching message is used to indicate that the port that the ONU receives the service packet is switched from the first port to the second port, where the service switching message carries the second port information .
- the method further includes that the ONU sends a service switching confirmation message to the OLT by using the first port
- the ONU turns off the laser corresponding to the first port, and the ONU turns on the laser corresponding to the second port; the ONU uses the second port to perform service packets with the OLT at the second wavelength.
- the ONU receives the second wavelength that is sent by the OLT by using the first port a switching request message, configured to indicate that an operating wavelength of the optical module connected to the first port of the ONU is switched from a first wavelength to a second wavelength, where the second wavelength switching request message carries second wavelength information; Transmitting, by the second port, the second wavelength switching confirmation message to the OLT by using the second wavelength; the ONU switching an operating wavelength of the optical module connected to the first port from the first wavelength to the second a wavelength; the ONU sends a second wavelength switching complete message to the OLT by the second port by using the second port.
- the ONU by using the second port, receives the OLT by using the second wavelength
- the service sharing request message is sent by the ONU, and the ONU receives the service sharing request message sent by the OLT by using the first port, where the service sharing request message is used to indicate that the ONU is enabled.
- the optical module corresponding to the two ports works normally.
- the method further includes the ONU transmitting, by the first port, the first wavelength channel to the OLT Sending a service sharing confirmation message; the ONU opens a laser corresponding to the second port; and the ONU performs service packet exchange with the OLT by using the first port and the second port.
- the wavelength switching request message carries a start time of the second port to perform wavelength switching.
- the second wavelength channel is an uplink wavelength, and/or a downlink wavelength.
- the first wavelength channel is an uplink wavelength, and/or a downlink wavelength.
- a communication method for a multi-wavelength passive optical network includes an optical line terminal OLT and at least one optical network unit ONU, the ONU including a first port and a second port,
- the method includes the OLT transmitting a wavelength switching request message to the ONU, where the wavelength switching request message carries second wavelength information and port information of the second port; and the OLT receives the first port sent from the ONU. Wavelength switching completion message.
- the OLT sends a wavelength switch confirmation message to the first port of the ONU by using the first wavelength channel.
- the OLT receives the first wavelength channel from the first port of the ONU Current status information of the ONU.
- the OLT sends the second port to the second port of the ONU The authorization message of the uplink illuminating time slot; the OLT receives the uplink light sent by the second port of the ONU by the second wavelength.
- the OLT sends a service switching message to the first port of the ONU, where the service is The switching message is used to indicate that the ONU replaces the first port that receives the service packet with the second port, where the service switching message carries the second port information.
- the OLT receives a service switching confirmation message sent from a first port of the ONU, and the OLT Transmitting a service packet to the second port of the ONU by using the second wavelength channel.
- the OLT sends a second wavelength switching request message to the first port of the ONU, The first port for indicating the ONU switches the working wavelength from the first wavelength to the second wavelength, wherein the second wavelength switching request message carries the second wavelength information; the OLT receives the second wavelength from the a second wavelength switch confirmation message sent by the first port of the ONU; the OLT receives a wavelength switch complete message sent from the second port of the ONU at the second wavelength.
- the OLT sends a service sharing to the second port of the ONU by using the second wavelength channel And sending a service sharing request message to the first port of the ONU by using the first wavelength channel, where the service sharing request message is used to instruct the ONU to enable the optical module corresponding to the second port to work normally.
- the OLT receives the service sharing sent from the first port of the ONU by using the first wavelength channel.
- a confirmation message the OLT receives a message from the first port and the second port of the ONU through the first wavelength channel and the second wavelength channel, respectively.
- the wavelength switching request message carries a start time t0 of wavelength switching performed by the second port .
- the second wavelength channel is an uplink wavelength, and/or a downlink wavelength.
- the first wavelength channel is an uplink wavelength, and/or a downlink wavelength.
- the third aspect is an optical network unit ONU, where the ONU includes at least a first port and a second port, where the ONU includes a first port, which is used to receive a service packet from the OLT, or is used to receive an OLT. a wavelength switching request message, the wavelength switching request message carrying the second wavelength channel information and the port information of the second port, and transmitting the wavelength switching request message to the processor; the second port, when the first And receiving, by the receiver, a wavelength switch request message sent by the OLT, where the wavelength switch request message carries the second wavelength information and the port information of the second port; or
- the first receiver is configured to receive a wavelength switch request message sent by the OLT, where the wavelength switch request message carries the second wavelength channel information and the port information of the second port, and is used for redundancy backup of the ONU a processor connected to the first port and the second port, configured to switch an operating wavelength of the optical module corresponding to the second port of the ONU from the first wavelength channel to the first Wavelength channel information corresponding to the second wavelength
- the first port of the ONU is further configured to: when the second port of the ONU performs wavelength switching, feed back a state of the current ONU through the first wavelength channel.
- the second port of the ONU is further configured to receive, by the second wavelength channel, an OLT from the OLT. Wavelength confirmation command.
- the second port of the ONU is further configured to use the target wavelength channel feedback after receiving the wavelength confirmation command Confirm the response message.
- the second port of the ONU is further configured to receive, by the second wavelength channel, an OLT from the OLT. Wavelength switching success instruction.
- the first port of the ONU is further configured to receive a service switching instruction from the OLT, where the service is The switching instruction is used to indicate that the port on which the ONU receives the service packet is changed from the first port to the second port, where the service switching instruction carries the second port information of the ONU.
- the first port of the ONU is further configured to feed back a service switching confirmation message to the OLT.
- the processor of the ONU is further configured to turn off the first laser corresponding to the first port, and enable The second laser corresponding to the second port.
- the first port of the ONU is further configured to receive a second wavelength switching request message from the OLT,
- the second wavelength switching request message is used to indicate that the laser or receiver corresponding to the first port of the ONU is switched from the first wavelength channel to the second wavelength channel, where the second wavelength switching request message carries the port of the first port.
- Information second wavelength channel information.
- the processor of the ONU is further configured to control the laser or receiver corresponding to the first port by A wavelength channel is adjusted to the second wavelength channel.
- the second port of the ONU is further configured to use the second downlink wavelength corresponding to the second wavelength channel Receiving an uplink time slot grant message from the OLT.
- the first port of the ONU is further configured to receive the wavelength from the OLT through the second wavelength channel. Switch the confirmation message.
- the second wavelength channel includes an uplink wavelength and/or a downlink wavelength.
- an optical line terminal OLT is applied to a time division wavelength division multiplexing passive optical network multi-wavelength PON, the multi-wavelength PON includes the OLT and at least one optical network unit ONU, and the ONU includes a first port.
- the OLT includes a sending module, configured to send a wavelength switching request message to the ONU, where the wavelength switching request message carries second wavelength information and port information of the second port, where the wavelength The switching request message is used to identify that the working wavelength of the optical module corresponding to the second port of the ONU is switched from the first wavelength channel to the second wavelength channel; and the receiving module is configured to receive the first one from the ONU on the first wavelength channel The wavelength switch completion message sent by the port, where the wavelength switch completion message is used to identify that the optical module corresponding to the second port of the ONU completes wavelength switching.
- the receiving module is further configured to receive, in the first wavelength channel, a current state of the ONU sent from a first port of the ONU information.
- the OLT further includes a processing module, where the processing module is configured to generate the wavelength switching request message And transmitted to the transmitting module.
- the sending module is further configured to send a service switching message to the first port of the ONU.
- the service switching message is used to indicate that the ONU replaces the first port that receives the service packet with the second port, where the service switching message carries the second port information.
- the receiving module is further configured to receive a service switching confirmation message from the first port of the ONU, where the service switching confirmation message is used to identify whether the ONU performs service switching.
- the sending module is further configured to use the first wavelength channel to the first of the ONUs
- the port or the second wavelength channel sends a service sharing request message to the second port of the ONU, where the service sharing request message is used to instruct the ONU to enable the optical module corresponding to the second port to work normally, and the service sharing request message carries the first Two port port information.
- the sending module is further configured to use the first wavelength channel to the first of the ONUs
- the port or the second wavelength channel sends a service sharing request message to the second port of the ONU, where the service sharing request message is used to instruct the ONU to enable the optical module corresponding to the second port to work normally, and the service sharing request message carries the first Two port port information.
- the wavelength switching request message carries a start time of the second port to perform wavelength switching.
- the second wavelength channel is an uplink wavelength, and/or a downlink wavelength.
- the first wavelength channel is an uplink wavelength, and/or a downlink wavelength.
- a fifth aspect is a time division wavelength division multiplexing passive optical network multi-wavelength PON system, the multi-wavelength PON comprising an optical line terminal OLT and at least one optical network unit ONU, the ONU comprising at least a first port and a second port The first port and the second port operate at a first wavelength, and the ONU includes the ONU of any one of the third aspects.
- the method provided by the embodiment of the present invention achieves a better user experience in the process of wavelength switching without interrupting the service by rapidly switching the wavelength based on the second port.
- FIG. 1 is a schematic structural diagram of a multi-wavelength PON network according to an embodiment of the present invention
- FIG. 2 is a schematic diagram of another multi-wavelength PON network architecture according to an embodiment of the present invention.
- FIG. 3 is a schematic flowchart of a communication method applied to a multi-wavelength PON system according to an embodiment of the present invention
- 4A is a schematic flowchart of another communication method applied to a multi-wavelength PON system according to an embodiment of the present invention
- 4B is a schematic flowchart of another communication method applied to a multi-wavelength PON system according to an embodiment of the present invention.
- 4C is a schematic flowchart of another communication method applied to a multi-wavelength PON system according to an embodiment of the present invention.
- FIG. 5 is a schematic diagram of a PLOAM message frame format according to an embodiment of the present disclosure.
- FIG. 6 is a schematic flowchart of a specific implementation manner of a communication method applied to a multi-wavelength PON system according to an embodiment of the present disclosure
- FIG. 7A is a schematic flowchart of a method for load sharing according to an embodiment of the present invention.
- FIG. 7B is a schematic flowchart of a specific load sharing implementation manner according to an embodiment of the present disclosure.
- FIG. 8 is a schematic flowchart of another method for applying a communication method to a multi-wavelength PON system according to an embodiment of the present invention.
- FIG. 9 is a schematic structural diagram of an optical network unit ONU according to an embodiment of the present disclosure.
- FIG. 10 is a schematic structural diagram of an optical line terminal OLT according to an embodiment of the present invention.
- FIG. 1 and FIG. 2 are schematic diagrams showing different application scenarios of an embodiment of the present invention.
- the ONUs/ONTs mentioned below are all referred to as ONUs.
- the ONUs/ONTs mentioned below are all referred to as ONUs.
- the ONUs/ONTs mentioned below are all referred to as ONUs.
- the ONUs/ONTs mentioned below are all referred to as ONUs.
- the ONUs/ONTs mentioned below are all referred to as ONUs.
- the ONU is hereinafter referred to as a multi-port ONU.
- Figure 1 shows an example of a multi-port ONU including two ports.
- An Optical Line Terminal (OLT) is connected to multiple ONUs through an Optical Distribution Network (ODN).
- ONT Optical Distribution Network
- Each multi-port ONU occupies two branch fibers, and the two branch fibers are respectively connected to two ports of the ONU.
- FIG. 2 also takes a multi
- the multi-wavelength PON system 100 includes an OLT 110, a plurality of ONUs 120, and an ODN 130.
- the OLT 110 is connected to the plurality of ONUs 120 in a Point to Multi-Point (P2MP) manner through the ODN 130. More than one OLT may also be included in the multi-wavelength PON system 100.
- the plurality of ONUs 120 share the optical transmission medium of the ODN 130.
- the ODN 130 may include a backbone fiber 131, an optical power split module 132, and a plurality of branch fibers 133.
- the optical power splitting module 132 may be disposed at a remote node (RN), which is connected to the OLT 110 through the trunk optical fiber 131 on the one hand, and connected to the plurality of ONUs 120 through the plurality of branch optical fibers 133 on the other hand.
- the communication link between the OLT 110 and the plurality of ONUs 120 may include a plurality of wavelength channels that share the optical transmission medium of the ODN 130 by WDM.
- Each ONU 120 can operate in one of the wavelength channels of the multi-wavelength PON system 100, and each wavelength channel can carry the traffic of one or more ONUs 120.
- a plurality of ONUs 120 operating in the same wavelength channel can share the wavelength channel by TDM.
- the multi-wavelength PON system 100 has four wavelength channels as an example. It should be understood that, in practical applications, the number of wavelength channels of the multi-wavelength PON system 100 may also be determined according to network requirements.
- the four wavelength channels of the multi-wavelength PON system 100 are named as wavelength channel 1, wavelength channel 2, wavelength channel 3, and wavelength channel 4, respectively, in FIG.
- Each of the wavelength channels adopts a pair of uplink and downlink wavelengths respectively.
- the upstream wavelength and the downstream wavelength of the wavelength channel 1 may be ⁇ u1 and ⁇ d1, respectively
- the upstream wavelength and the downstream wavelength of the wavelength channel 2 may be ⁇ u2 and ⁇ d2, respectively
- the upstream wavelength and the downstream wavelength may be ⁇ u3 and ⁇ d3, respectively
- the upstream wavelength and the downstream wavelength of the wavelength channel 4 may be ⁇ u4 and ⁇ d4, respectively.
- Each wavelength channel can have a corresponding wavelength channel identifier (for example, the channel numbers of the four wavelength channels can be 1, 2, 3, and 4 respectively), that is, the wavelength channel identifier matches the uplink and downlink wavelengths of the wavelength channel identified by the wavelength channel. Relationships, OLT 110 and ONU 120 can learn the upstream and downstream wavelengths of the wavelength channel based on the wavelength channel identification.
- the OLT 110 may include an optical coupler 111, a first wavelength division multiplexer 112, and a second wavelength division multiplexing The device 113, the plurality of downlink optical transmitters Tx1 to Tx4, the plurality of upstream optical receivers Rx1 to Rx4, and the processing module 114.
- the plurality of downstream optical transmitters Tx1 to Tx4 are connected to the optical coupler 111 through the first wavelength division multiplexer 112, and the plurality of upstream optical receivers Rx1 to Rx4 are connected to the optical coupler through the second wavelength division multiplexer 113.
- the coupler 111 is further connected to the trunk fiber 131 of the ODN 130.
- the emission wavelengths of the plurality of downlink optical transmitters Tx1 to Tx4 are different.
- Each of the downstream optical transmitters Tx1 to Tx4 may respectively correspond to one of the wavelength channels of the multi-wavelength PON system 100, such as multiple downlink optical transmitters Tx1 ⁇ .
- the emission wavelength of Tx4 can be ⁇ d1 to ⁇ d4, respectively.
- the downstream optical transmitters Tx1 to Tx4 can respectively transmit downlink data to corresponding wavelength channels by using their emission wavelengths ⁇ d1 ⁇ ⁇ d4 to be received by the ONUs 120 operating in the corresponding wavelength channels.
- the receiving wavelengths of the plurality of upstream optical receivers Rx1 to Rx4 may be different, and each of the upstream optical receivers Rx1 to Rx4 also respectively correspond to one of the wavelength channels of the multi-wavelength PON system 100, for example, multiple uplinks.
- the receiving wavelengths of the optical receivers Rx1 to Rx4 may be ⁇ u1 to ⁇ u4, respectively.
- the upstream optical receivers Rx1 to Rx4 can receive the uplink data transmitted by the ONU 120 operating in the corresponding wavelength channel by using the reception wavelengths ⁇ u1 to ⁇ u4, respectively.
- the first wavelength division multiplexer 112 is configured to perform wavelength division multiplexing processing on the downlink data of the plurality of downlink optical transmitters Tx1 to Tx4 and having wavelengths of ⁇ d1 to ⁇ d4, respectively, and transmit the same to the backbone of the ODN 130 through the optical coupler 111.
- the optical fiber 131 is to provide downlink data to the ONU 120 through the ODN 130.
- the optical coupler 111 can also be used to provide uplink data from the plurality of ONUs 120 and having wavelengths of ⁇ u1 to ⁇ u4, respectively, to the second wavelength division multiplexer 113, and the second wavelength division multiplexer 113 can respectively set the wavelength to ⁇ u1.
- the uplink data of ⁇ u4 is demultiplexed to the upstream optical receivers Rx1 to Rx4 for data reception.
- the processing module 114 may be a Media Access Control (MAC) module, which may specify a working wavelength channel for the plurality of ONUs 120 by wavelength negotiation, and send the signal to the ONU 120 according to the working wavelength channel of the ONU 120.
- the downlink data is supplied to the downstream optical transmitters Tx1 to Tx4 corresponding to the wavelength channels, so that the downstream optical transmitters Tx1 to Tx4 transmit the downlink data to the corresponding wavelength channels.
- MAC Media Access Control
- the processing module 114 can also perform Dynamic Bandwidth Allocation (DBA) for uplink transmission on each wavelength channel, and allocate an uplink transmission time slot to the ONU 120 multiplexed to the same wavelength channel by TDM to authorize The ONU 120 transmits uplink data through its corresponding wavelength channel in a designated time slot.
- DBA Dynamic Bandwidth Allocation
- the uplink transmit wavelength and the downlink receive wavelength of each ONU 120 are adjustable, and the ONU 120 can adjust its own uplink transmit wavelength and downlink receive wavelength to the uplink wavelength and downlink corresponding to the wavelength channel according to the wavelength channel specified by the OLT 110, respectively.
- the wavelength thereby enabling transmission and reception of uplink and downlink data through the wavelength channel.
- the ONU 120 can include at least two ports 121, an optical module, and a processing module, wherein each port 121 corresponds to a set of optical modules.
- the optical module includes a light emitter 123 and a light receiver 122.
- multiple ports 121 of the ONU can work at the same wavelength or can work at different wavelengths.
- the downlink receiving wavelengths of the first port and the second port of the ONU are both ⁇ d1
- the uplink transmitting wavelengths are both ⁇ u1.
- the first port and the second port of the ONU operate on the first wavelength channel.
- the downlink receiving wavelength of the first port of the ONU is ⁇ d1 and the downlink receiving wavelength of the second port is ⁇ d2, it can be understood that the first port and the second port of the ONU operate on different wavelength channels.
- multiple ports of an ONU work in the same wavelength.
- the ONU may be in load balancing mode or in the wavelength channel backup mode of the OLT.
- the ONU is working normally, only the laser corresponding to one port is working normally, and the other port is used as the second port.
- the laser is in the state of being shut down, sleeping, or stopped, but the optical receiver corresponding to the second port can work normally.
- Receiving the downlink optical signal of course, the optical receiver corresponding to the second port of the ONU can also be in a closed or sleep state, and only the optical module corresponding to the first port is working normally.
- the processing module 124 may be a Media Access Control (MAC) module, which may perform wavelength negotiation with the OLT 110, and adjust the receiving wavelength of the downstream optical receiver 122 and the upstream optical transmitter 123 according to the wavelength channel specified by the OLT 110.
- the transmitting wavelength ie, adjusting the downlink receiving wavelength and the uplink transmitting wavelength of the ONU 120
- the processing module 124 can also control the upstream optical transmitter 123 to be specified according to the dynamic bandwidth allocation result of the OLT 110.
- the time slot transmits uplink data.
- the splitter splitter 132 is connected to the two ports of the ONU through an optical coupler 125.
- the optical coupler 125 can couple the uplink data sent by the uplink optical transmitter 123 corresponding to the first port 121 and the uplink data sent by the uplink optical transmitter 123 corresponding to the second port 121 to provide the branch fiber to the ODN 130.
- 133 to send to the OLT 110 through the ODN 130; on the other hand, the optical coupler 125 can also provide downlink data sent by the OLT 110 through the ODN 130 to the downlink optical receiver corresponding to the first port and the second port, respectively.
- 122 performs data reception.
- the multi-wavelength PON system 100 or 200 (which is distinguished from FIG. 1 and the PON system in FIG. 2 is marked as 200) is operated, if the number of ONUs 120 on the line is large, an ideal situation is preferred.
- the number of ONUs 120 per wavelength channel may be different due to the user moving up and down, etc., for example, there may be a large number of ONUs 120 of one wavelength channel, and the number of ONUs 120 of one or more wavelength channels.
- the load of the wavelength channel is unbalanced.
- the load of the wavelength channel used by the more ONUs is heavy.
- the ONUs 120 operating in the same wavelength channel use TDM to perform service multiplexing. When the load of a certain wavelength channel is too heavy, bandwidth may be insufficient. The normal service of the ONU 120 is affected.
- the OLT may switch the ONU to the same wavelength channel and turn off the other three wavelength channels to save resources.
- the direction in which the data or the optical signal carrying the data is transmitted from the OLT to the ONU is referred to as a downlink direction.
- the channel through which the OLT transmits the optical signal to the ONU is also referred to as a downlink wavelength channel.
- the bearer for carrying the information or data sent by the OLT to the ONU may also be referred to as a downlink frame; similarly, the transmission direction of the data or the optical signal carrying the data from the ONU to the OLT is referred to as an uplink direction; accordingly, the ONU
- the channel that transmits the optical signal to the OLT is also referred to as an upstream wavelength channel; accordingly, the carrier used to carry the information or data transmitted by the ONU to the OLT may also be referred to as an upstream frame.
- the method provided by the embodiment of the present invention can solve the problem that the OLT wavelength channel is unbalanced and energy-saving, and the method provided by the embodiment of the present invention can make the service not interrupt during the wavelength switching process.
- the method provided by the embodiment of the present invention can make the service not interrupt during the wavelength switching process.
- FIG. 3 is a schematic diagram of a communication applied to a multi-wavelength passive optical network system according to an embodiment of the present invention;
- the interaction flow chart of the method, wherein the architecture of the multi-wavelength PON can be as shown in FIG. 1 or FIG. 2, or other multi-wavelength PON architecture.
- the embodiment of the present invention does not limit the architecture of the multi-wavelength PON. As long as the PON system has at least two or more wavelength channels, it should be protected by the present invention.
- the multi-wavelength PON network includes an OLT and at least one ONU, and the ONU includes at least two ports, which are referred to as a first port and a second port for convenience of explanation.
- the first port and the second port work in the first wavelength channel, and the laser and the optical transceiver corresponding to the first port work normally, that is, the first port can be called the primary port.
- the laser corresponding to the second port is in the state of being shut down, sleeping, or stopped.
- the optical receiver corresponding to the second port may be in an on or off state, that is, the second port may be referred to as an alternate port for redundancy backup of the wavelength channel. . It should be understood that when the receiver corresponding to the second port is turned on, it can normally receive the downlink optical signal, and does not work when turned off or when sleeping.
- the method in this embodiment includes:
- Step 301 The ONU receives, by using the first port or the second port, a wavelength switch request message sent by the OLT, where the wavelength switch request message carries the second wavelength channel information and the port information of the second port.
- the ONU receives the wavelength switching request message sent by the OLT through the first port, and the second port of the ONU can be in the state of redundant backup.
- the first wavelength channel may also be referred to as a source wavelength channel
- the second wavelength channel may also be referred to as a target wavelength channel.
- the present invention examples are unified terms, referred to as a first wavelength channel and a second wavelength channel.
- the wavelength switching request message sent by the OLT to the ONU is used to indicate that the second port of the ONU performs wavelength switching, and the current working wavelength is switched from the first wavelength channel to the second wavelength channel; wherein the wavelength switching request message further carries a starting time t0, The t0 is used to indicate that the second port of the ONU starts to switch from the first wavelength channel to the second wavelength channel at time t0.
- the first wavelength channel and the second wavelength channel herein merely indicate any two channels that can work in the multi-wavelength PON system
- the first wavelength channel represents the current wavelength channel in which the ONU is working
- the second wavelength channel represents The OLT indicates the target wavelength channel to which the ONU switches.
- the upstream and downstream wavelength pairs do not need to be uniquely paired, that is, the upstream wavelengths of the first wavelength channel and the second wavelength channel may be the same wavelength, and the first wavelength is the same.
- the downstream wavelengths of the channel and the second wavelength channel can also be the same. That is to say, in this embodiment, the OLT may only instruct the ONU to perform uplink wavelength switching, or only perform downlink wavelength switching, or simultaneously perform uplink wavelength and downlink wavelength switching.
- the OLT allocates a target wavelength channel to the ONU before sending the wavelength switch request message to the ONU.
- the OLT may need to instruct the ONU to perform wavelength switching during the operation of the ONU, for example, when the wavelength channel A
- the OLT can control a part of the ONUs that are working in the wavelength channel A to switch to the wavelength channel by adjusting the uplink transmit wavelength and/or the downlink receive wavelength by using a wavelength switching command.
- LB load balancing
- the OLT allocates a target wavelength channel to the ONU, and assigns any one of the plurality of idle wavelength channels to the ONU; or selects an optimal one of the wavelength channels to allocate to the ONU; Or, according to an algorithm, a certain wavelength channel is selected and allocated to the ONU, and the embodiment of the present invention does not limit how to select the target wavelength channel.
- adjusting the optical module of the ONU to the second wavelength channel is understood to adjust both the upstream wavelength and the downstream wavelength.
- only the uplink wavelength or only the downlink wavelength may be switched.
- the embodiment of the present invention should also include a scenario in which only the uplink wavelength is adjusted or only the downlink wavelength is adjusted.
- the wavelength switching request message instructs the ONU to adjust the uplink wavelength and the downlink wavelength
- the wavelength switching request message further carries the uplink wavelength identifier and the downlink wavelength identifier; if the wavelength switching request message indicates that the ONU only adjusts the uplink wavelength, the wavelength switching request message And further, if the wavelength switching request message indicates that the ONU only adjusts the downlink wavelength, the wavelength switching request message further carries the downlink wavelength identifier; the uplink wavelength identifier and the downlink wavelength identifier may be 0, 1 To identify.
- the field is identified by 2 bits
- the uplink wavelength is identified by 00
- the downlink wavelength is identified by 01
- the uplink wavelength and the downlink wavelength are used by 10, which may of course be identified by other means provided in the prior art.
- the representation manner of the second wavelength channel information may be a wavelength channel number, a wavelength length value, and may also be a representation adopted by other prior art.
- the ONU sends a wavelength switch request response message to the OLT through the first port of the ONU.
- the ONU feeds back the wavelength switching request response message to the OLT through the first port of the ONU, because the ONU The laser corresponding to the second port is off or hibernated or is in a stopped state, and cannot send uplink light, so the laser corresponding to the first port responds to the wavelength switching request message.
- the wavelength switching request response message sent by the ONU carries information indicating that the ONU cannot be switched, if the tuning of the ONU optical module is not exceeded.
- the capability range the wavelength switching request response message sent by the ONU carries information for instructing the ONU to confirm the handover.
- the ONU can pass the Physical Layer Operations Administration and Maintenance (PLOAM) message, the Optical Network Terminal Management and Control Interface (OMCI) message, and the Multi-Point Control Protocol (Multi-Point).
- PLOAM Physical Layer Operations Administration and Maintenance
- OMCI Optical Network Terminal Management and Control Interface
- Multi-Point Multi-Point Control Protocol
- Control Protocols (MPCP) messages or any of the Operation Management and Maintenance (OAM) messages carry the wavelength switch request response message sent by the ONU to the OLT.
- the ONU may also carry the wavelength switching time information sent to the OLT through the newly defined message.
- FIG. 5 is a schematic diagram of the PLOAM message format.
- the PLOAM message typically includes an Optical Network Unit Identity (ONU ID) field, a Message ID field, a Sequence Number field, a Data field, and an Integrity Check field.
- ONU ID Optical Network Unit Identity
- Message ID field a Message ID field
- Sequence Number field a Sequence Number field
- Data field a Data field
- Integrity Check field an Integrity Check field.
- the information indicating that the ONU confirms the handover or cannot be switched carried in the wavelength switching request response message sent by the ONU may be carried in the data field of the PLOAM message.
- the wavelength switching request response message may be in the format shown in Table 1.
- Step 302 The ONU switches the working wavelength channel of the optical module connected to the second port from the current first wavelength channel to the second wavelength channel.
- the MAC module of the ONU is configured to switch the working wavelength channel of the optical module corresponding to the second port from the current first wavelength channel to the second wavelength channel.
- the wavelength switching request message indicates that the ONU switches the uplink wavelength and the downlink wavelength, and the ONU needs to adjust the optical receiver and the optical transmitter corresponding to the second port to align the uplink wavelength and the downlink wavelength of the target wavelength channel; if the wavelength switching command is used Instructing the ONU to switch the upstream wavelength, the ONU only needs to adjust the optical transmitter corresponding to the second port to align the upstream wavelength; similarly, if the wavelength switching command instructs the ONU to switch the downstream wavelength, the ONU only needs to adjust The second port corresponds to the optical receiver to align the downstream wavelength.
- Step 303 When the second port wavelength switching of the ONU is completed, the ONU sends a wavelength switching complete message to the OLT through its first port.
- the ONU reports the handover completion message to the OLT through the first port or the second port on the first wavelength channel.
- the PLOAM Physical Layer Operation Administration Maintenance
- OMCI ONU Management and Control Interface
- MPCP Multi-Point Control Protocol
- OAM Operaation Administration and Maintenance
- the MAC module of the ONU can know whether the laser or the receiver of the second port is adjusted to the target wavelength by means of temperature, experience value, table, or the like. For example, the MAC module of the ONU obtains the current uplink wave of the laser corresponding to the second port by reading the temperature value of the laser corresponding to the second port. If it is determined that the laser has been adjusted into position, the first port is instructed to report a handover completion message to the OLT.
- the first and second ports are set on the ONU, so that when the ONU performs wavelength switching, one port performs wavelength switching, and the other port can still perform normal service packet interaction with the OLT, and switches in wavelength. There is no need to interrupt the business during the process.
- FIG. 4A is an interaction flowchart of a second embodiment of a communication method according to an embodiment of the present invention. As shown in FIG. 4A, the method in this embodiment includes:
- Step 401 The OLT sends a wavelength switch request message to the first port or the second port of the ONU, where the wavelength switch request message carries the second port information and the second wavelength channel information of the ONU.
- the wavelength switching request message may further include a start time t0 for indicating that the ONU performs wavelength switching.
- the OLT can pass the Physical Layer Operations Administration and Maintenance (PLOAM) message, the Optical Network Terminal Management and Control Interface (OMCI) message, and the Multi-Point Control Protocol (Multi-Point).
- PLOAM Physical Layer Operations Administration and Maintenance
- OMCI Optical Network Terminal Management and Control Interface
- Multi-Point Multi-Point Control Protocol
- Control Protocols (MPCP) messages or any of the Operation Management and Maintenance (OAM) messages carry the wavelength switch request message sent by the OLT to the ONU.
- the OLT may also carry the wavelength switch request message sent to the ONU through the newly defined message.
- FIG. 5 is a schematic diagram of the PLOAM message format.
- the PLOAM message typically includes an Optical Network Unit Identity (ONU ID) field, a Message ID field, a Sequence Number field, a Data field, and an Integrity Check field.
- ONU ID Optical Network Unit Identity
- Message ID field a Message ID field
- Sequence Number field a Sequence Number field
- Data field a Data field
- Integrity Check field an Integrity Check field
- the port information and the second wavelength channel information of the ONU may be carried in a data field of the PLOAM message.
- the wavelength switching request response message may be in the format shown in Table 1.
- the wavelength switching request message may use a Tuning_Contorl message (a type of MPCP message) in an existing standard, where the Tuning_Control message carries a start adjustment time Start_time, port information Port, and a second wavelength.
- Tuning_Contorl message a type of MPCP message
- the Tuning_Control message carries a start adjustment time Start_time, port information Port, and a second wavelength.
- Channel information Tuning_target Specifically, as shown in Figure 6.
- step 401 is also applicable, and details are not described herein again.
- the ONU feeds back a wavelength switch confirmation message to the OLT through its first port.
- the ONU can pass the Physical Layer Operations Administration and Maintenance (PLOAM) message, the Optical Network Terminal Management and Control Interface (OMCI) message, and the Multi-Point Control Protocol (Multi-Point).
- PLOAM Physical Layer Operations Administration and Maintenance
- OMCI Optical Network Terminal Management and Control Interface
- Multi-Point Multi-Point Control Protocol
- Control Protocols (MPCP) messages or any of the Operation Management and Maintenance (OAM) messages carry the wavelength switch request message sent by the OLT to the ONU.
- the ONU may also carry the wavelength switching time information sent to the OLT through the newly defined message.
- the wavelength switch confirmation message may use a Tuning_Response message (a type of MPCP message) in the existing standard, where the Tuning_Response message carries a flag bit, where the flag bit is used to identify whether the ONU agrees to switch. . For example, if the flag bit is equal to 0, the ONU does not agree to switch the wavelength, and the flag bit equals 1 to indicate that the ONU agrees to switch, as shown in FIG. 6.
- step 402 is also applicable, and details are not described herein again.
- Step 403 The ONU adjusts the laser and/or the receiver corresponding to the second port of the ONU to the second wavelength channel according to the indication of the OLT.
- the ONU when the ONU receives the wavelength switching request message from the OLT, the data field in the message is read, and the second port that the OLT instructs the ONU to adjust the current uplink and downlink wavelengths to the second wavelength channel is obtained.
- the ONU processor controls the optical receiver and the optical transmitter corresponding to the second port of the ONU, so that the optical receiver and the optical transmitter are aligned with the uplink wavelength and the downlink wavelength of the target wavelength channel; if the wavelength switching command is to indicate that the ONU switches the upstream wavelength The ONU only needs to adjust the optical transmitter corresponding to the second port to align the uplink wavelength. Similarly, if the wavelength switching command instructs the ONU to switch the downlink wavelength, the ONU only needs to adjust the optical reception corresponding to the second port. Machine to align the downstream wavelength.
- step 404 the OLT sends an uplink time slot grant message to the ONU.
- the uplink time slot grant message sent by the OLT is used to indicate that the first port of the ONU sends the uplink light in the time slot.
- the first port of the ONU can feed back the state of the current ONU through the first wavelength channel during the wavelength switching process.
- the status of the current ONU may be that the wavelength is being adjusted, the rollback, the fault, and the adjustment are completed.
- the status information may be reported to the OLT through the first port of the ONU.
- Step 406 When the second port of the ONU completes the wavelength switch, the ONU feeds back the wavelength switch completion message to the OLT through the first port.
- the wavelength switch completion message is used to identify that the second port wavelength of the ONU is switched.
- the ONU can pass the Physical Layer Operations Administration and Maintenance (PLOAM) message, the Optical Network Terminal Management and Control Interface (OMCI) message, and the Multi-Point Control Protocol (Multi-Point).
- PLOAM Physical Layer Operations Administration and Maintenance
- OMCI Optical Network Terminal Management and Control Interface
- Multi-Point Multi-Point Control Protocol
- MPCP Physical Layer Operations Administration and Maintenance
- OAM Operation Management and Maintenance
- ONU may also carry the wavelength switch completion information sent to the OLT through the newly defined message.
- the wavelength switching completion message may also use an existing Tuning_Response message, where the flag of the Tuning_Response Flags is set to 1 to indicate that the ONU has completed wavelength switching, and set to 0 represents ONU uncompleted wavelength switching. Specifically, as shown in Figure 6.
- the OLT sends a wavelength confirmation command to the second port of the ONU through the second wavelength channel.
- the wavelength confirmation command may use an existing Tuning_Control message, where the Flags Flags of the Tuning_Control is set to 1 to indicate that the OLT confirms that the ONU has completed wavelength switching.
- step 408 after receiving the wavelength confirmation command, the second port of the ONU feeds back the wavelength confirmation response message through the second wavelength channel.
- the OLT sends a wavelength switching success command to the ONU.
- step 401 to step 409 the working wavelength of the second port of the ONU is switched from the first wavelength channel to the second wavelength channel.
- steps 401 to 409 are based on the initial state of the plurality of ports of the ONU to operate in the same wavelength channel.
- multiple ports of the ONU may be in the initial state, and the multiple ports of the ONU are working on different wavelength channels.
- the service switching or load balancing of the ONU may be performed through steps 410 to 423 or step 511. Step 514 is implemented.
- the OLT sends a service switching request message, where the service switching request message is used to change the port on which the ONU interacts with the OLT to change the service port from the first port to the second port, where the The service switching request message carries the second port information of the ONU.
- the service switching request message further carries a start time, where the start time is used to identify a start time that the OLT instructs the ONU to start port switching.
- the service switching request message may be sent to the first port of the ONU on the first wavelength channel, or may be sent to the second port of the ONU on the second wavelength channel.
- the OLT can pass the Physical Layer Operations Administration and Maintenance (PLOAM) message, the Optical Network Terminal Management and Control Interface (OMCI) message, and the Multi-Point Control Protocol. Protocols, MPCP) messages or any of the Operation Administration and Maintenance (OAM) messages To carry the above service switching request message.
- PLOAM Physical Layer Operations Administration and Maintenance
- OMCI Optical Network Terminal Management and Control Interface
- MPCP Multi-Point Control Protocol. Protocols
- OAM Operation Administration and Maintenance
- the OLT may also carry the above service switching request message through a newly defined message.
- FIG. 5 is a schematic diagram of the PLOAM message format.
- the PLOAM message typically includes an Optical Network Unit Identity (ONU ID) field, a Message ID field, a Sequence Number field, a Data field, and an Integrity Check field.
- ONU ID Optical Network Unit Identity
- Message ID field a Message ID field
- Sequence Number field a Sequence Number field
- Data field a Data field
- Integrity Check field an Integrity Check field.
- the second port information carried in the service switching request message sent by the OLT may be carried in a data field.
- step 411 the ONU feeds back the service switching confirmation message to the OLT through the first port on the first wavelength channel, or feeds the service switching confirmation message to the OLT through the second port on the second wavelength channel.
- the OLT refreshes the configuration, and switches the service flow from the first wavelength channel to the second wavelength channel.
- step 412 the ONU turns off the laser corresponding to the first port.
- the ONU closes the first wavelength channel corresponding to the first port, and can also be understood as the first port performs a sleep or false state, and the ONU wakes up the second port.
- Step 413 The OLT sends a service packet to the OLT through the second wavelength channel, and the ONU receives the service packet delivered by the OLT through the second port on the second wavelength channel.
- the OLT establishes service communication with the second port of the ONU, and the service is from the first The port was successfully switched to the second port.
- the various interaction messages mentioned in steps 410 to 413 may use existing message formats, such as Tuning_Control and Tuning_Response messages.
- the specific content is shown in Figure 6.
- the OLT and the second port of the ONU establish a service communication channel through the second wavelength channel.
- the original second port becomes the new primary port
- the original first port becomes the first port.
- the new alternate port the original first wavelength channel is stopped, and the communication between the OLT and the ONU uses the second wavelength channel.
- the ONU can further adjust the working wavelength of the first port from the first wavelength channel to the second wavelength channel.
- This process is the same as the working wavelength of the second port mentioned in the foregoing steps 401 to 409.
- the adjustment from the first wavelength channel to the second wavelength channel is the same, as shown in FIG. 4C:
- the OLT sends a second wavelength switching request message to the ONU, where the second wavelength switching request message is used to instruct the original first port of the ONU to switch from the first wavelength channel to the second wavelength channel.
- the second wavelength switching request message carries port information of the original first port and information of the second wavelength channel.
- the ONU may receive the second wavelength switching request message by using the first port in the first wavelength channel, and may also receive the second wavelength switching request message by using the second port in the second wavelength channel.
- the second wavelength switching request message further carries a start time of the wavelength switching.
- step 415 the ONU feeds back the wavelength switching confirmation message on the second wavelength channel through its second port.
- Step 416 The ONU switches the working wavelength channel of the optical module connected to the first port from the first wavelength channel to the second wavelength channel.
- the OLT sends an uplink time slot grant message to the ONU through the second wavelength channel.
- step 418 when the original first port of the ONU is performing wavelength switching, the ONU feeds back the state of the current ONU through the second port.
- Step 419 When the original first port of the ONU completes the wavelength switching, the ONU feeds back the second wavelength switching completion message to the OLT through the second port in the second wavelength channel.
- Step 420 The OLT sends a wavelength switch completion response message through the second wavelength channel.
- step 421 the ONU feeds back the acknowledgement message with the second wavelength channel through its first port.
- steps 414 to 421 are used to adjust the first port of the ONU from the first wavelength channel to the second wavelength channel.
- the steps 414 to 421 are based on the same principle as the steps 401 to 409. The descriptions described in steps 401 to 409 also apply to steps 414 to 421.
- the size of the sequence numbers of the above processes does not mean the order of execution, and the order of execution of each process should be determined by its function and internal logic, and should not be taken to the embodiments of the present invention.
- the implementation process constitutes any limitation.
- all the foregoing messages that the OLT interacts with the ONU may adopt the MPCP protocol or the OAM protocol, and implement fast wavelength switching or load switching function by extending the MPC PDU or the OAMDU frame structure.
- the wavelength switching request message may be implemented by extending the TUNING_CONTROL frame structure in the MPCP or the OAM protocol, for example, by adding a target Ports target port domain and expanding the Flags domain to add a target wavelength to send a confirmation message. As shown in table 2:
- the current port state message is fed back through the first port, and the TUNING_RESPONSE frame structure is extended in the MPCP or OAM protocol, and the flag field (corresponding to the flag bit of Table 3) is newly added, including the switching. , fault, wavelength is rolling back, completed switching, wavelength confirmation feedback, etc.
- Table 3 is as follows:
- the two ports of the ONU are switched from the first wavelength channel to the second wavelength channel through steps 401 to 421, and normal communication of the service is ensured during the handover.
- FIG. 7A is a wavelength switching method according to an embodiment of the present invention.
- the interaction flowchart of the third embodiment is as shown in FIG. 7A.
- the method in this embodiment includes:
- Steps 501 to 509 refer to steps 401 to 409 in the second embodiment, and the two are the same.
- the second port of the ONU is switched from the first wavelength channel to the second wavelength channel through steps 501 to 509.
- Step 510 The OLT sends a load sharing request message to the ONU, where the load sharing request message includes an identifier of the ONU and second port information, where the load sharing request message is used to instruct the ONU to enable the optical module corresponding to the second port to be normal.
- the optical module corresponding to the first port bears all the services together; or it is understood to reduce the burden of the optical module corresponding to the first port.
- the ONU receives the service sharing request message sent by the OLT by using the second port by using the second port; or the ONU receives the first wavelength channel by using the first port.
- the service delivered by the OLT shares the request message.
- the OLT can pass the Physical Layer Operations Administration and Maintenance (PLOAM) message, the Optical Network Terminal Management and Control Interface (OMCI) message, and the Multi-Point Control Protocol. Any one of the Protocols, MPCP, or Operation Management and Maintenance (OAM) messages carries the load sharing request message. In other alternative embodiments, the OLT may also carry the load sharing request message through a newly defined message.
- PLOAM Physical Layer Operations Administration and Maintenance
- OMCI Optical Network Terminal Management and Control Interface
- Multi-Point Control Protocol Multi-Point Control Protocol.
- Any one of the Protocols, MPCP, or Operation Management and Maintenance (OAM) messages carries the load sharing request message.
- the OLT may also carry the load sharing request message through a newly defined message.
- FIG. 5 is a schematic diagram of the format of the PLOAM message.
- the PLOAM message typically includes an Optical Network Unit Identity (ONU ID) field, a Message ID field, a Sequence Number field, a Data field, and an Integrity Check field.
- ONU ID Optical Network Unit Identity
- Message ID field a Message ID field
- Sequence Number field a Sequence Number field
- Data field a Data field
- Integrity Check field an Integrity Check field.
- the second port information carried in the service switching request message sent by the OLT may be carried in a data field.
- the load sharing request message may also adopt a Load_Control message, where the Load_Control message carries a flag bit, a start time, and port information. Specifically, as shown in FIG. 7B.
- Step 511 The ONU feeds back a service sharing confirmation message to the OLT in the first wavelength channel by using the first port.
- Step 512 The ONU establishes a new service channel for the second port, and starts the laser corresponding to the second port, and communicates with the OLT through the second wavelength channel. At this time, the two ports of the ONU can work normally, and the load is implemented. Sharing.
- the MAC module of the ONU establishes a new service channel for the second port of the ONU, and turns off the redundancy backup.
- Step 513 The OLT sends a service packet by using the first wavelength channel and the second wavelength channel, and the ONU receives the service packet delivered by the OLT through the first port and the second port.
- the size of the sequence numbers of the above processes does not mean the order of execution, and the order of execution of each process should be determined by its function and internal logic, and should not be taken to the embodiments of the present invention.
- the implementation process constitutes any limitation.
- the load sharing message can also be implemented by using an MPC PDU or an OAMDU, and can be implemented by a person skilled in the art by customizing a new frame structure or extending a frame structure in an existing standard.
- Table 4 shows the load balancing request message by customizing a new LOAD_CONTROL frame structure, as shown in Table 4:
- the OLT can perform service communication with the first and second ports of the ONU through the first wavelength channel and the second wavelength channel respectively, thereby implementing load sharing and increasing the bandwidth capacity of the ONU.
- FIG. 8 is an interaction flowchart of a wavelength switching method according to an embodiment of the present invention. As shown in FIG. 8, the method in this embodiment includes:
- Step 801 The OLT sends a wavelength switching request message to the ONU, where the wavelength switching request message carries the second wavelength channel information and the port information of the second port.
- the OLT sends a wavelength switching request message to the first port of the ONU.
- the OLT receives a wavelength switch confirmation message sent from the first port of the ONU in the first wavelength channel;
- Step 802 The OLT receives a wavelength switching complete message sent from the first port of the ONU in the first wavelength channel.
- the OLT sends a wavelength switch confirmation message to the ONU on the second wavelength channel.
- the method further includes the OLT receiving the The first port of the ONU is the current state information of the ONU sent by the first wavelength channel.
- the method further includes: the OLT transmitting, to the second port of the ONU, an authorization message of an uplink illuminating time slot allocated for the second port;
- the wavelength channel receives the upstream light transmitted from the second port of the ONU.
- the method further includes the OLT sending a service switching message to the first port of the ONU, where the service switching message is used to indicate that the ONU performs a service packet with the OLT.
- the exchanged port is replaced by the first port to the second port, where the service switching message carries the ONU identifier and the second port information.
- the service switching message may further carry the service switching start time t0. ;
- the OLT sends a service packet to the second port of the ONU through the second wavelength channel.
- the method further includes the OLT sending a second wavelength switching request message to the ONU, where the first port of the ONU is configured to switch the working wavelength from the first wavelength channel.
- the second wavelength switching request message carries the second wavelength channel information and the port information of the first port;
- the OLT receives a wavelength switching complete message sent from a second port of the ONU through a second wavelength channel.
- the method further includes: the OLT sending a service sharing request message to the first port of the ONU through the first wavelength channel, or the second wavelength channel to the ONU
- the second port sends a service sharing request message, where the service sharing request message is used to instruct the ONU to enable the optical module corresponding to the second port to work normally;
- the OLT receives a test message from the first port and the second port of the ONU through the first wavelength channel and the second wavelength channel, where the test message is used to test whether the first port and the second port of the OLT and the ONU are established.
- the business channel is a test message from the first port and the second port of the ONU through the first wavelength channel and the second wavelength channel, where the test message is used to test whether the first port and the second port of the OLT and the ONU are established.
- the fourth embodiment is based on the description of the second and third embodiments on the OLT side, and the frame structure mentioned in the second and third embodiments is also applicable to the embodiment of the present invention.
- the first and second ports are set on the ONU, so that when the ONU performs wavelength switching, one port is switched, and the other port can still perform normal service packet interaction with the OLT. There is no need to interrupt the business.
- FIG. 9 is a schematic structural diagram of an ONU of an optical network unit according to an embodiment of the present invention.
- the optical network unit ONU 90 includes a first port 901, a second port 902, and a processor 903.
- the first port 901 is connected to the first laser 904 and the first receiver 905, and the first laser 904 and the first receiver 905 are collectively referred to as a first optical module.
- the second port 902 is coupled to the second laser 906 and the second receiver 907, and the second laser 906 and the second receiver 907 are collectively referred to as a second optical module.
- the first laser 904, the first receiver 905, the second laser 906, and the second receiver 907 are each coupled to a processor 903, the first port and the second port operating in a first wavelength channel.
- the ONU specifically includes:
- the first port 901 is configured to receive a service packet from the OLT, or to receive a wavelength switch request message sent by the OLT, where the wavelength switch request message carries the second wavelength channel information and the port information of the second port, The wavelength switch request message is transmitted to the processor 903.
- the second port 902 when the first receiver is configured to receive a service packet from the OLT, to receive a wavelength switch request message sent by the OLT, where the wavelength switch request message carries the second wavelength information and the Port information of the second port; or when the first receiver is configured to receive a wavelength switching request message sent by the OLT, where the wavelength switching request message carries the second wavelength channel information and the port information of the second port, Redundant backup for the ONU.
- the first port 901 is configured to send a wavelength switch confirmation message to the OLT, where the wavelength switch confirmation message carries information for identifying whether the ONU is handed over.
- the second port 902 is in a closed or hibernation state or is inoperable.
- the processor 903 is configured to switch the second optical module corresponding to the second port from the first wavelength channel to the second wavelength channel, and is further configured to generate a wavelength switch confirmation message and transmit the message to the first port 901.
- the first port 901 is further configured to send a wavelength switch complete message to the OLT.
- the ONU can receive the wavelength switching request message from the OLT through its first port or the second port. Therefore, when receiving through the first port of the ONU, the first port 901 needs to receive the service packet from the OLT. Receiving a wavelength switch request message from the OLT and The wavelength switch request message is reported to the processor 903 of the ONU. At this time, the second port of the ONU is used for redundancy backup. When receiving through the second port of the ONU, the first port 901 is only used to receive the service report from the OLT. The second port 902 is configured to receive a wavelength switch request message from the OLT, and report the wavelength switch request message to the processor 903 of the ONU.
- the first port 901 of the ONU is further configured to receive an uplink time slot grant message from the OLT.
- the first port 901 of the ONU is further configured to feed back the state of the current ONU through the first wavelength channel when the second port 902 of the ONU performs wavelength switching.
- the second port 902 of the ONU is further configured to receive a wavelength confirmation command from the OLT through the second wavelength channel.
- the second port 902 of the ONU is further configured to: after receiving the wavelength confirmation command, feed back a wavelength confirmation response message through the second wavelength channel.
- the second port 902 of the ONU is further configured to receive a wavelength switching success instruction from the OLT in the second wavelength channel;
- the first port 901 of the ONU is further configured to receive a wavelength switching success instruction from the OLT in the first wavelength channel.
- the first port 901 of the ONU is further configured to receive a service switching instruction from the OLT; or the second port 901 of the ONU is further configured to receive a service switching instruction from the OLT;
- the service switching instruction is used to indicate that the port on which the ONU receives the service packet is changed from the first port 901 to the second port 902, and the service switching instruction carries the second port information of the ONU.
- the service switching instruction carries a start time for instructing the ONU to switch the service.
- the first port 901 of the ONU is further used to feed back a service switching confirmation message to the OLT.
- the processor 903 of the ONU is further configured to turn off the first laser 904 corresponding to the first port and turn on the second laser 906 corresponding to the second port 902.
- the first port 901 of the ONU is further configured to receive a second wavelength switching request message from the OLT, where the second wavelength switching request message is used to indicate a laser corresponding to the first port of the ONU. And/or the receiver is switched from the first wavelength channel to the second wavelength channel, wherein the second wavelength switching request message carries port information of the first port, and the second wave Long channel information.
- the second port 902 of the ONU is further configured to send a second wavelength switch confirmation message to the OLT in the second wavelength channel.
- the processor 903 of the ONU is further configured to control the laser and/or the receiver corresponding to the first port 901 to be adjusted from the first wavelength channel to the second wavelength channel.
- the second port 902 of the ONU is further configured to receive an uplink time slot grant message from the OLT in the second wavelength channel.
- the second port 902 of the ONU is further configured to feed back the state of the current ONU through the second wavelength channel when the first port 901 of the ONU performs wavelength switching.
- the status of the current ONU may be a state of being switched, faulty, rolled back, and completed.
- the second port 902 of the ONU is further configured to send a second wavelength switching completion message to the OLT through the second wavelength channel; or the first port 901 of the ONU is further configured to pass the second wavelength.
- the channel sends a second wavelength switching completion message to the OLT, where the second wavelength switching completion message is used to identify that the working wavelength channel of the optical module corresponding to the first port 901 of the ONU is switched from the first wavelength channel to the second wavelength channel.
- the first port 901 of the ONU is further configured to receive a second wavelength switching instruction from the OLT through the second wavelength channel.
- the first port 901 of the ONU is further configured to send a second wavelength switch response message by using the second wavelength channel.
- the optical network unit of the embodiment of the present invention may correspond to the above-mentioned and other operations and/or functions of the respective modules in the present invention, respectively, in order to implement the corresponding processes of the method in FIG. 4A to FIG. 7B, for the sake of brevity, here. No longer.
- the first and second ports are set on the ONU, so that when the ONU performs the wavelength switching, one port can be switched, and the other port can still receive the downlink service packet normally, and the service is not interrupted during the wavelength switching process.
- a schematic diagram of a structure of an optical line terminal OLT according to an embodiment of the present invention is applied to a multi-wavelength PON system, where the multi-wavelength PON includes an optical line terminal OLT and at least one optical network.
- the ONU, the ONU includes a first port and a second port, wherein the first port and the second port operate in a first wavelength channel.
- the optical line terminal 100 includes:
- the sending module 1010 is configured to send a wavelength switching request message to the ONU, where the wavelength switching request message carries the second wavelength channel information and the port information of the second port, where the wavelength switching request message is used to identify the ONU
- the working wavelength of the optical module corresponding to the second port is switched from the first wavelength channel to the second wavelength channel;
- the receiving module 1020 is configured to receive, on the first wavelength channel, a wavelength switch completion message sent from the first port of the ONU, where the wavelength switch completion message is used to identify that the optical module corresponding to the second port of the ONU completes the wavelength switch.
- the receiving module 1020 is further configured to receive, on the first wavelength channel, current state information of the ONU sent from the first port of the ONU.
- the current status information of the ONU includes switching, fault, rollback, and handover completion.
- the OLT further includes a processing module 1030, where the processing module 1030 is configured to generate a wavelength switching request message, and transmit the message to the sending module 1010.
- the processing module 1030 is further configured to receive a wavelength switch confirmation message transmitted from the receiving module 1020.
- the processing module 1030 is further configured to allocate an uplink lighting time slot to the ONU.
- the sending module 1010 is further configured to send an authorization message of an uplink lighting time slot to the ONU.
- the receiving module 1020 is further configured to receive the uplink light sent from the second port of the ONU on the second wavelength channel.
- the sending module 1010 is further configured to send a service switching message to the first port of the ONU, where the service switching message is used to indicate that the ONU uses an interactive port of a service packet.
- the first port is replaced with the second port, wherein the service switching message carries the second port information.
- the service switching message further carries a service switching start time t0.
- the processing module 1030 is further configured to generate a service switching message, and transmit the service switching message to the sending module 1010.
- the receiving module 1020 is further configured to receive the first A service switching confirmation message sent by a port, where the service switching confirmation message is used to identify whether the ONU performs service switching.
- the processing module 1030 is further configured to: after receiving the service switching confirmation message sent by the ONU, refresh the configuration, and switch the service flow from the first wavelength channel to the second wavelength channel.
- the sending module 1010 is further configured to send a service packet to the second port of the ONU on the second wavelength channel.
- the sending module 1010 is further configured to send a second wavelength switching request message to the second port of the ONU, where the working wavelength of the optical module corresponding to the first port of the ONU is indicated by The one wavelength channel is switched to the second wavelength channel, wherein the second wavelength switching request message carries the second wavelength channel information and the port information of the first port.
- the receiving module 1020 is further configured to receive, on the second wavelength channel, a second wavelength switching confirmation message sent from the second port of the ONU, and receive the second wavelength channel from the second wavelength channel.
- a second wavelength switching completion message sent by the second port of the ONU where the second wavelength switching confirmation message is used to identify whether the ONU agrees to perform wavelength switching of the optical module of the first port; and the second wavelength switching completion message is used to identify that the ONU is completed.
- the wavelength of the optical module corresponding to the first port is switched.
- the sending module 1010 is further configured to send a service sharing request message to the first port of the ONU or the second wavelength channel to the second port of the ONU in the first wavelength channel.
- the service sharing request message is used to instruct the ONU to enable the optical module corresponding to the second port to work normally, and the service sharing request message carries the port information of the second port.
- the receiving module 1020 is further configured to receive, in the first wavelength channel, a service sharing confirmation message sent from the first port of the ONU, and in the first wavelength channel and the first A service packet is sent on the two-wavelength channel.
- the wavelength switching request message carries a start time t0 of the second port for wavelength switching.
- optical line terminal OLT of the embodiment of the present invention may correspond to the above-mentioned and other operations and/or functions of the respective modules in the present invention, respectively, in order to implement the corresponding processes of the methods in FIGS. 4A to 7A, for the sake of brevity, This will not be repeated here.
- An embodiment of the present invention provides a multi-wavelength PON system, where the multi-wavelength PON includes an optical line terminal OLT and at least one optical network unit ONU, where the ONU includes a first port and a second port, where the first port and The second port operates at the first wavelength.
- the structure of the OLT refer to the description of the sixth embodiment.
- the structure of the ONU refer to the description of the fifth embodiment.
- the interaction process between the OLT and the ONU refer to the second embodiment or the implementation. The description of the third example will not be repeated here.
- aspects of the present invention, or possible implementations of various aspects may be embodied as a system, method, or computer program product.
- aspects of the invention, or possible implementations of various aspects may be in the form of an entirely hardware embodiment, an entirely software embodiment (including firmware, resident software, etc.), or a combination of software and hardware aspects, They are collectively referred to herein as "circuits," “modules,” or “systems.”
- aspects of the invention, or possible implementations of various aspects may take the form of a computer program product, which is a computer readable program code stored in a computer readable medium.
- the computer readable medium can be a computer readable signal medium or a computer readable storage medium.
- the computer readable storage medium includes, but is not limited to, an electronic, magnetic, optical, electromagnetic, infrared, or semiconductor system, apparatus, or device, or any suitable combination of the foregoing, such as random access memory (RAM), read only memory (ROM), Erase programmable read-only memory (EPROM or flash memory), optical fiber, portable read-only memory (CD-ROM).
- the processor in the computer reads the computer readable program code stored in the computer readable medium such that the processor is capable of performing the various functional steps specified in each step of the flowchart, or a combination of steps; A device that functions as specified in each block, or combination of blocks.
- the computer readable program code can execute entirely on the user's computer, partly on the user's computer, as a separate software package, partly on the user's computer and partly on the remote computer, or entirely on the remote computer or server.
- the functions noted in the various steps in the flowcharts or in the blocks in the block diagrams may not occur in the order noted. For example, two steps, or two blocks, shown in succession may be executed substantially concurrently or the blocks may be executed in the reverse order.
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Abstract
Description
域 | 字节 |
目的地址 | 6 |
源地址 | 6 |
长度/类型 | 2 |
操作码 | 2 |
时间戳 | 4 |
授权数目/标志位 | 2 |
目标波长通道 | 2 |
授权开始时间 | 4 |
授权长度 | 2 |
目标端口 | 2 |
同步时间 | 2 |
保留字段 | 29 |
检验位 | 4 |
域 | 字节 |
目的地址 | 6 |
源地址 | 6 |
长度/类型 | 2 |
操作码 | 2 |
时间戳 | 4 |
标志位 | 2 |
授权开始时间 | 4 |
授权长度 | 2 |
同步时间 | 2 |
保留字段 | 29 |
检验位 | 4 |
域 | 字节 |
目的地址 | 6 |
源地址 | 6 |
长度/类型 | 2 |
操作码 | 2 |
时间戳 | 4 |
授权数目/标志位 | 2 |
授权开始时间 | 4 |
授权长度 | 2 |
同步时间 | 2 |
端口信息 | 2 |
保留字段 | 29 |
检验位 | 4 |
Claims (37)
- 一种应用于多波长无源光网络系统的通信方法,所述多波长无源光网络包括光线路终端OLT和至少一个光网络单元ONU,所述ONU至少包含第一端口和第二端口,其特征在于,所述方法包括:所述ONU通过所述第一端口或第二端口接收所述OLT下发的波长切换请求消息,所述波长切换请求消息携带第二波长通道信息和所述第二端口的端口信息;所述ONU将所述第二端口连接的光模块的工作波长通道从第一波长通道切换到与所述第二波长通道信息对应的第二波长通道;和所述ONU通过所述第一端口向所述OLT发送波长切换完成消息。
- 根据权利要求1所述的方法,其特征在于,所述方法还包括:在所述ONU将所述第二端口连接的光模块的工作波长通道从所述第一波长通道切换到所述第二波长通道的过程中,所述ONU通过所述第一端口向所述OLT发送ONU当前的状态信息。
- 根据权利要求1或2所述的方法,其特征在于,所述方法还包括:所述ONU通过所述第二端口接收所述OLT发送的波长确认指令;和所述ONU通过所述第二端口在所述第二波长通道发送波长确认响应消息。
- 根据权利要求1~3任意一项所述的方法,其特征在于,所述方法还包括:所述ONU通过所述第一端口或第二端口接收所述OLT发送的业务切换消息,所述业务切换消息用于指示所述ONU将接收业务报文的端口由所述第一端口切换至所述第二端口,其中,所述业务切换消息携带第二端口信息。
- 根据权利要求1~3任意一项所述的方法,其特征在于,所述方法还包括:所述ONU通过所述第二端口以所述第二波长通道接收所述OLT下发的业务分担请求消息,或者,所述ONU通过所述第一端口以所述第一波长通道接收所述OLT下发的业务分担请求消息,其中,所述业务分担请求消息用于指示所述ONU开启第二端口对应的光模块正常工作。
- 根据权利要求5所述的方法,其特征在于,所述方法还包括:所述ONU通过所述第一端口在所述第一波长通道向所述OLT发送业务分担确认消息;所述ONU打开所述第二端口连接的激光器;和所述ONU通过所述第一端口和所述第二端口接收OLT发送的业务报文。
- 根据权利要求1~6任意一项所述的方法,其特征在于,所述波长切换请求消息携带用于指示所述第二端口进行波长切换的起始时间t0。
- 根据权利要求1~7任意一项所述的方法,其特征在于,所述第二波长通道包括上行波长和/或下行波长。
- 根据权利要求1~8任意一项所述的方法,其特征在于,所述第一波长通道包括上行波长和/或下行波长。
- 一种应用于多波长无源光网络的通信方法,所述多波长无源光网络包括光线路终端OLT和至少一个光网络单元ONU,所述ONU包含第一端口和第二端口,其特征在于,所述方法包括:所述OLT发送波长切换请求消息至所述ONU,所述波长切换请求消息携带第二波长通道信息和所述第二端口的端口信息,所述波长切换请求消息指示所述ONU从所述第一波长通道切换到与所述第二波长通道信息对应的第二波长通道;和所述OLT接收从所述ONU的所述第一端口发送的波长切换完成消息。
- 根据权利要求10所述的方法,其特征在于,所述方法还包括:所述OLT接收从所述ONU的第一端口发送的所述ONU当前的状态信息。
- 根据权利要求10或11所述的方法,其特征在于,所述方法还包括:所述OLT向所述ONU的所述第一端口发送业务切换消息,所述业务切换消息用于指示所述ONU与所述OLT进行业务报文交互的端口由所述第一端口切换至所述第二端口,其中,所述业务切换消息携带第二端口信息。
- 根据权利要求12所述的方法,其特征在于,所述方法还包括:所述OLT接收从所述ONU的第一端口发送的业务切换确认消息;和所述OLT通过第二波长通道向所述ONU的第二端口发送业务报文。
- 根据权利要求10或11所述的方法,其特征在于,所述方法还包括:所述OLT通过第二波长通道向所述ONU的第二端口发送业务分担请求消息,或者,通过第一波长通道向所述ONU的第一端口发送业务分担请求消息,其中,所述业务分担请求消息用于指示所述ONU开启第二端口对应的光模块正常工作。
- 根据权利要求14所述的方法,其特征在于,所述方法还包括:所述OLT通过第一波长通道接收从所述ONU的第一端口发送的业务分担确认消息;所述OLT分别通过第一波长通道和第二波长通道从所述ONU的第一端口和第二端口收到消息。
- 根据权利要求10~15任意一项所述的方法,其特征在于,所述波长切换请求消息携带用于指示所述第二端口进行波长切换的起始时间t0。
- 根据权利要求10~16任意一项所述的方法,其特征在于,所述第二波长通道包括上行波长和/或下行波长。
- 根据权利要求10~17任意一项所述的方法,其特征在于,所述第一波长通道包括上行波长和/或下行波长。
- 一种光网络单元ONU,所述ONU至少包含第一端口和第二端口,其特征在于,所述ONU包括:所述第一端口,用于接收OLT下发的波长切换请求消息,所述波长切换请求消息携带第二波长通道信息和所述第二端口的端口信息,以及将所述波长切换请求消息发送至处理器;所述第二端口,用于接收所述OLT下发的波长切换请求消息,该波长切换请求消息携带第二波长信息和所述第二端口的端口信息;和/或,用于所述ONU的冗余备份;与所述第一端口和所述第二端口相连的处理器,用于将所述ONU的第二端口对应的光模块的工作波长从第一波长通道切换到与所述第二波长通道信息对应的第二波长通道,以及生成波长切换完成消息,并传输至所述 第一端口;所述第一端口,还用于向所述OLT发送所述波长切换完成消息。
- 根据权利要求19所述的ONU,其特征在于,所述ONU的第一端口还用于当所述ONU的第二端口在进行波长切换时,向所述OLT发送所述ONU的当前状态信息。
- 根据权利要求19或20任意一项所述的ONU,其特征在于,所述ONU的第二端口还用于通过所述第二波长通道接收来自所述OLT的波长确认指令。
- 根据权利要求21所述的ONU,其特征在于,所述ONU的第二端口还用于当接收到所述波长确认指令后,通过所述第二波长通道向所述OLT发送波长确认响应消息。
- 根据权利要求19~22任意一项所述的ONU,其特征在于,所述ONU的所述第一端口还用于接收来自所述OLT的业务切换指令,所述业务切换指令用于指示所述ONU接收业务报文的端口由所述第一端口更改为所述第二端口,其中,所述业务切换指令携带所述ONU的所述第二端口信息。
- 根据权利要求23所述的ONU,其特征在于,所述ONU的所述第一端口还用于反馈业务切换确认消息至所述OLT。
- 根据权利要求23或24所述的ONU,其特征在于,所述处理器还用于关闭所述第一端口对应的第一激光器,开启所述第二端口对应的第二激光器。
- 根据权利要求19~25任意一项所述的方法,其特征在于,所述第二波长通道包括上行波长和/或下行波长。
- 根据权利要求19~26任意一项所述的方法,其特征在于,所述第一波长通道包括上行波长和/或下行波长。
- 一种光线路终端OLT,应用于多波长无源光网络系统,所述多波长无源光网络系统包括所述OLT和至少一个光网络单元ONU,所述ONU包含第一端口和第二端口,其特征在于,所述OLT包括:发送模块,用于发送波长切换请求消息至所述ONU,所述波长切换请求消息携带第二波长通道信息和所述第二端口的端口信息,其中,所述波 长切换请求消息用于标识ONU的第二端口对应的光模块工作波长由所述第一波长通道切换到第二波长通道;接收模块,用于在第一波长通道上接收从所述ONU的第一端口发送的波长切换完成消息,其中,所述波长切换完成消息用于标识所述ONU的第二端口对应的光模块完成波长切换。
- 根据权利要求28所述的OLT,其特征在于,所述接收模块还用于在所述第一波长通道接收从所述ONU的第一端口发送的所述ONU当前的状态信息。
- 根据权利要求28或29所述的OLT,其特征在于,所述OLT还包括处理模块,其中,处理模块用于生成所述波长切换请求消息,并传输至所述发送模块。
- 根据权利要求28~30任意一项所述的OLT,其特征在于,所述发送模块还用于向所述ONU的第一端口发送业务切换消息,所述业务切换消息用于指示所述ONU将接收业务报文的第一端口更换至所述第二端口,其中,所述业务切换消息携带第二端口信息。
- 根据权利要求31所述的OLT,其特征在于,所述接收模块还用于从所述ONU的第一端口接收业务切换确认消息,其中,业务切换确认消息用于标识ONU是否进行业务切换。
- 根据权利要求28~32任意一项所述的OLT,其特征在于,所述发送模块还用于在第一波长通道向所述ONU的第一端口或者在第二波长通道向ONU的第二端口发送业务分担请求消息,所述业务分担请求消息用于指示所述ONU开启第二端口对应的光模块正常工作,所述业务分担请求消息携带第二端口的端口信息。
- 根据权利要求28~33任意一项所述的OLT,其特征在于,所述波长切换请求消息携带所述第二端口进行波长切换的起始时间t0。
- 根据权利要求28~34任意一项所述的OLT,其特征在于,所述第二波长通道为上行波长,和/或下行波长。
- 根据权利要求28~35任意一项所述的OLT,其特征在于,所述第一波长通道为上行波长,和/或下行波长。
- 一种多波长无源光网络系统,所述多波长无源光网络系统包括光 线路终端OLT和至少一个光网络单元ONU,所述ONU至少包含第一端口和第二端口,其中,所述第一端口和所述第二端口工作在第一波长,其特征在于,所述ONU包括如权利要求19~27任意一项所述的ONU。
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2018026634A (ja) * | 2016-08-08 | 2018-02-15 | 日本電信電話株式会社 | 光通信システム、局側装置及び光通信方法 |
WO2019048476A1 (en) * | 2017-09-05 | 2019-03-14 | Danmarks Tekniske Universitet | OPTICAL LINE TERMINAL AND OPTICAL FIBER ACCESS SYSTEM WITH INCREASED CAPACITY |
CN112235662A (zh) * | 2019-07-15 | 2021-01-15 | 中兴通讯股份有限公司 | 一种降低无源光网络上行时延的方法及相关设备 |
Families Citing this family (11)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2017041210A1 (zh) * | 2015-09-07 | 2017-03-16 | 华为技术有限公司 | 一种无源光网络通信的方法、装置及系统 |
US10608735B2 (en) * | 2016-05-04 | 2020-03-31 | Adtran, Inc. | Systems and methods for performing optical line terminal (OLT) failover switches in optical networks |
US11039229B2 (en) * | 2017-08-29 | 2021-06-15 | Cable Television Laboratories, Inc. | Systems and methods for coherent optics ranging and sensing |
EP3836428B1 (en) | 2018-08-31 | 2022-12-28 | Huawei Technologies Co., Ltd. | Information transmission method, optical line termination, optical network unit and communication system |
CN111447036B (zh) * | 2019-01-17 | 2023-02-03 | 华为技术有限公司 | 一种通信方法、装置及系统 |
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CN110446123B (zh) * | 2019-08-19 | 2022-01-11 | 深圳市双翼科技股份有限公司 | 无源光网络中olt端口的节能控制方法和系统 |
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CN113518271B (zh) * | 2020-04-10 | 2024-02-13 | 上海诺基亚贝尔股份有限公司 | 无源光网络中用于信道管理的方法、装置和系统 |
CN113556176B (zh) * | 2021-06-29 | 2022-07-05 | 成都市联洲国际技术有限公司 | 光组件发射光控制方法、装置、光组件、光模块及收发器 |
Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102045126A (zh) * | 2011-01-10 | 2011-05-04 | 中兴通讯股份有限公司 | 波分复用无源光网络系统及其使用方法 |
CN102820943A (zh) * | 2012-08-15 | 2012-12-12 | 烽火通信科技股份有限公司 | Twdm-pon系统中olt和onu之间的波长管理方法 |
CN103548292A (zh) * | 2012-05-23 | 2014-01-29 | 华为技术有限公司 | 多波长无源光网络的波长切换方法、系统和装置 |
CN104137490A (zh) * | 2012-04-20 | 2014-11-05 | 三菱电机株式会社 | 通信系统、母站装置、子站装置、控制装置以及通信控制方法 |
Family Cites Families (12)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2001326654A (ja) * | 2000-05-17 | 2001-11-22 | Nec Corp | Ponのプロテクション切替方法および切替装置 |
JP2008028718A (ja) * | 2006-07-21 | 2008-02-07 | Hitachi Communication Technologies Ltd | 加入者装置、局装置および受動光網 |
JP4905076B2 (ja) * | 2006-11-16 | 2012-03-28 | 沖電気工業株式会社 | 局側装置 |
US8744265B2 (en) * | 2007-04-27 | 2014-06-03 | Futurewei Technologies, Inc. | Passive optical network with partially-tuned lasers |
JP5058910B2 (ja) * | 2008-07-29 | 2012-10-24 | 日本電信電話株式会社 | ポイント−マルチポイントシステムにおける冗長化伝送システム |
JP5204234B2 (ja) | 2008-08-26 | 2013-06-05 | 三菱電機株式会社 | Ponシステムおよび冗長化方法 |
CN101998191A (zh) * | 2009-08-27 | 2011-03-30 | 华为技术有限公司 | 汇聚节点联动切换方法及汇聚节点和系统 |
US8995836B2 (en) * | 2010-07-13 | 2015-03-31 | Futurewei Technologies, Inc. | Passive optical network with adaptive filters for upstream transmission management |
EP2525517B1 (en) * | 2011-05-20 | 2016-05-04 | ADVA Optical Networking SE | An optical wavelength division multiplex (WDM) transmission system, especially a WDM passive optical network |
WO2012119439A1 (zh) | 2011-09-05 | 2012-09-13 | 华为技术有限公司 | 光网络系统的数据通信方法、光网络单元及系统 |
CN103391486B (zh) * | 2012-05-09 | 2018-05-04 | 中兴通讯股份有限公司 | 一种进行波长调整的方法及光线路终端及光网络单元 |
ES2629198T3 (es) * | 2012-10-17 | 2017-08-07 | Huawei Technologies Co., Ltd. | Método, sistema y aparato de conmutación de protección para red óptica pasiva |
-
2014
- 2014-12-30 WO PCT/CN2014/095651 patent/WO2016106599A1/zh active Application Filing
- 2014-12-30 KR KR1020177021107A patent/KR102035629B1/ko active IP Right Grant
- 2014-12-30 JP JP2017535383A patent/JP6445706B2/ja not_active Expired - Fee Related
- 2014-12-30 CN CN201480075783.8A patent/CN106031064B/zh not_active Expired - Fee Related
- 2014-12-30 EP EP14909410.4A patent/EP3242424B1/en not_active Not-in-force
-
2017
- 2017-06-30 US US15/639,529 patent/US10123101B2/en not_active Expired - Fee Related
Patent Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102045126A (zh) * | 2011-01-10 | 2011-05-04 | 中兴通讯股份有限公司 | 波分复用无源光网络系统及其使用方法 |
CN104137490A (zh) * | 2012-04-20 | 2014-11-05 | 三菱电机株式会社 | 通信系统、母站装置、子站装置、控制装置以及通信控制方法 |
CN103548292A (zh) * | 2012-05-23 | 2014-01-29 | 华为技术有限公司 | 多波长无源光网络的波长切换方法、系统和装置 |
CN102820943A (zh) * | 2012-08-15 | 2012-12-12 | 烽火通信科技股份有限公司 | Twdm-pon系统中olt和onu之间的波长管理方法 |
Non-Patent Citations (1)
Title |
---|
See also references of EP3242424A4 * |
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2018026634A (ja) * | 2016-08-08 | 2018-02-15 | 日本電信電話株式会社 | 光通信システム、局側装置及び光通信方法 |
WO2019048476A1 (en) * | 2017-09-05 | 2019-03-14 | Danmarks Tekniske Universitet | OPTICAL LINE TERMINAL AND OPTICAL FIBER ACCESS SYSTEM WITH INCREASED CAPACITY |
US11444718B2 (en) | 2017-09-05 | 2022-09-13 | Danmarks Tekniske Universitet | Optical line terminal and optical fiber access system with increased capacity |
CN112235662A (zh) * | 2019-07-15 | 2021-01-15 | 中兴通讯股份有限公司 | 一种降低无源光网络上行时延的方法及相关设备 |
WO2021008224A1 (zh) * | 2019-07-15 | 2021-01-21 | 中兴通讯股份有限公司 | 一种降低无源光网络上行时延的方法及相关设备 |
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