JP6077084B1 - Communication network time synchronization method - Google Patents

Abstract

A communication network time synchronization method is provided. The present invention relates to a time synchronization method for a communication network, which calculates a time difference between an OLT and an ONU forming a passive optical network (PON) and corrects the time, thereby correcting the time. PON) time synchronization can be efficiently performed. [Selection] Figure 1

Description

  The present invention relates to a time synchronization technique, and more particularly to a time synchronization method for a communication network.

  Patent Document 1 proposes a time synchronization technique using GPS information.

  This technology extracts 1 PPS (1 Pulse Per Second), TOD (Time Of Day), 1 PPS_en, and 10 MHz clock using a GPS signal at a grand master node equipped with a GPS receiver, stabilizes the extracted signal, and A synchronization message for time synchronization is generated using the stabilized signal and transmitted to the slave node.

  As a result, the slave node receives the synchronization message, and the time synchronization block of the slave node performs time synchronization operation using OFCC (Offset & Frequency Compensation Clock) synchronization technology that supports time offset and frequency separation compensation. Modify the TOD information of the block.

  Then, using the TOD information corrected in the time synchronization block, the 1PPS, TOD, and 1PPS_en signals are extracted and transmitted to the stabilization block of the slave node to stabilize the signal.

Then, the stabilized signal is transmitted again to the time synchronization block, the TOD information of the time synchronization block is updated, and the updated TOD information is used for time synchronization of other slave nodes. Generate a synchronization message.
The inventor has conducted research on a time synchronization technique between a master and a slave of a communication system.

Korean Registered Patent No. 10-087776 (2008.12.23)

  The present invention has been invented to solve the above-mentioned problems, and an object thereof is to provide a time synchronization technique between a master and a slave of a communication system.

  In particular, an object of the present invention is to provide a time synchronization method capable of efficiently performing time synchronization between an OLT (Optical Line Terminal) and an ONU (Optical Network Unit) forming a passive optical network (PON: Passive Optical Network). .

  According to one aspect of the present invention for achieving the above object, a time synchronization method for a communication network is a time information acquisition step in which an OLT acquires initial time information from an NTP (Network Time Protocol) or an RTC (Real Time Clock). The time information transmission stage for transmitting the initial time information obtained by the OLT to the ONU, the initial time information received by the ONU from the OLT, and the reference time information obtained from the GM (Grand Master) A time difference calculation stage for calculating the difference, a time difference transmission stage for transmitting the time difference calculated by the ONU to the OLT, a time correction based on the time difference received from the ONU by the OLT, and time synchronization with the ONU And performing a time synchronization stage.

  According to an additional aspect of the present invention, a time synchronization method of a communication network uses the corrected time information after the time correction, the time information transmission stage, the time difference calculation stage, and the time difference transmission stage. And the time synchronization stage are repeated to continuously synchronize the time of the OLT and the ONU.

  According to an additional aspect of the present invention, the time synchronization method of the communication network compares the corrected time information received from the OLT with the reference time information acquired from the GM, and an acceptable time range. In this case, the method further includes an ONU lock phase in which the ONU is locked.

  According to an additional aspect of the present invention, the communication network time synchronization method further comprises a time synchronization information transmission step in which, if the ONU is locked, the ONU then transmits clock information to a slave device connected to the ONU. It is characterized by including.

  According to still another aspect of the present invention, a time synchronization method for a communication network includes a time information acquisition stage in which an OLT acquires initial time information from an NTP or an RTC, and transmits the initial time information from which the OLT has been acquired to the ONU. The time information transmission stage, the initial time information received by the ONU from the OLT, and the reference time information acquired from the GPS reception module, and the time difference calculation stage for calculating the time difference, and the time when the ONU was calculated A time difference transmission stage for transmitting the difference to the OLT; and a time synchronization stage for correcting the time based on the time difference received by the OLT from the ONU and performing time synchronization with the ONU. .

  According to an additional aspect of the present invention, a time synchronization method of a communication network uses the corrected time information after the time correction, the time information transmission stage, the time difference calculation stage, and the time difference transmission stage. And the time synchronization stage are repeated to continuously synchronize the time of the OLT and the ONU.

  According to an additional aspect of the present invention, the time synchronization method of the communication network can accept a time difference comparing the corrected time information received from the OLT with the reference time information acquired from the GPS receiving module. The method further includes an ONU lock stage in which the ONU is locked when the time range is reached.

  According to an additional aspect of the present invention, the time synchronization method of the communication network further includes a time synchronization information transmission step in which the OLT subsequently transmits the time synchronization information to the GM if the ONU is locked. To do.

  According to an additional aspect of the present invention, the GM transmits time synchronization information to another OLT.

According to an additional aspect of the present invention, the communication network time synchronization method further includes a time synchronization information transmission step in which, if the ONU is locked, the OLT then transmits the time synchronization information to other ONUs under its control. It is characterized by including.
According to an additional aspect of the present invention, the time synchronization information received from the OLT by another subordinate ONU is transmitted to a slave device connected to itself.

  The present invention can efficiently perform time synchronization between a master and a slave of a communication system. In particular, time synchronization between the OLT and the ONU forming the passive optical network (PON) can be efficiently performed.

It is a flowchart which shows the structure of one Embodiment of the time synchronization method of the communication network by this invention. It is a block diagram which shows the passive optical network structure which performs the time synchronization method of the communication network shown in FIG. It is a flowchart which shows the structure of other embodiment of the time synchronization method of the communication network by this invention. It is a block diagram which shows the passive optical network structure which performs the time synchronization method of the communication network shown in FIG. 6 is a flowchart illustrating a configuration of a further embodiment of a time synchronization method for a communication network according to the present invention. It is a block diagram which shows the passive optical network structure which performs the time synchronization method of the communication network shown in FIG.

  Hereinafter, the present invention will be described in detail so that those skilled in the art can easily understand and reproduce the present invention through preferred embodiments described with reference to the accompanying drawings.

  In describing the present invention, when it is determined that a specific description related to a known function or configuration may be different from the gist of the embodiment of the present invention, the detailed description is omitted. To do.

  The terms used throughout the specification of the present invention are defined in consideration of the functions in the embodiments of the present invention, and can be sufficiently modified according to the intention or custom of the user or operator. Therefore, the definition of the term should be made based on the contents throughout this specification.

  FIG. 1 is a flowchart showing a configuration of an embodiment of a time synchronization method for a communication network according to the present invention.

  First, in the time information acquisition stage (110), the OLT acquires initial time information from NTP or RTC. For example, the acquired initial time information includes a frequency, 1 PPS, and TOD.

  Next, in the time information transmission step (120), the initial time information obtained by the OLT is transmitted to the ONU. For example, the initial time information is transmitted through the Ethernet (registered trademark) standard IEEE 802.1as precise time protocol.

  Next, in the time difference calculation step (130), the ONU compares the initial time information received from the OLT with the reference time information acquired from the GM, and calculates the time difference. The GM is a device that supplies a global clock defined in the Ethernet standard IEEE 802.1as.

  For example, the ONU extracts and restores the frequency, 1PPS, and TOD from the Ethernet standard IEEE802.1as precise time protocol data received from the OLT, and the GM receives a 1588 PTP (Precision Time Protocol) packet, thereby obtaining the reference time information can do.

  Next, in the time difference transmission step (140), the time difference calculated by the ONU is transmitted to the OLT. At this time, the time difference is transmitted from the ONU to the OLT with the highest priority (Highest Priority).

  For example, a time difference is transmitted through a time correction protocol, and the time correction protocol is ITU-TG. It is possible to take a format in which time difference information is added to information based on SF (Selection Factor) of BMC 5.1.

  Next, in the time synchronization step (150), the time is corrected based on the time difference received from the ONU by the OLT, and time synchronization with the ONU is performed. For example, if the current OLT time is T, the time difference received from the ONU is ΔT, and the time corrected time is T ′, then T ′ = T ± ΔT.

  After the time correction is performed as described above, the time information transmission stage (120), the time difference calculation stage (130), and the time difference transmission stage are performed using the corrected time information instead of the initial time information. (140) and the time synchronization step (150) are repeated to continuously synchronize the time between the OLT and the ONU.

  Next, in the ONU lock stage (160), if the time difference between the corrected time information received from the OLT and the reference time information acquired from the GM reaches an allowable time range, the ONU is locked. The

  Next, if the ONU is locked in the time synchronization information transmission stage (170), the ONU then transmits the clock information to the slave device (not shown) connected to the ONU. For example, the clock information can be transmitted to the slave device in the form of 1588 PTP packet or 1PPS + TOD.

  FIG. 2 is a block diagram showing a passive optical network configuration that performs the time synchronization method of the communication network shown in FIG. The passive optical network shown in FIG. 2 includes an OLT 210, an ONU 220, and a GM 230.

  An SFU (Switching Fabric Unit) 211 of the OLT 210 acquires initial time information from the NTP or RTC after power input, and synchronizes the time based on the initial time information. For example, the acquired initial time information includes a frequency, 1 PPS, and TOD.

  The SFU 211 transmits initial time information to a SIU (Service Interface Unit) 212. The PON MAC of the SIU 212 transmits initial time information to the ONU 220. For example, the initial time information is transmitted through the Ethernet standard IEEE 802.1as precise time protocol.

  Thereby, the PON MAC 221 of the ONU 220 acquires the initial time information from the OLT 210, and the L2 switch 222 of the ONU 220 acquires the reference time information from the GM 230.

  Then, the L2 switch 222 of the ONU 220 compares the initial time information received from the OLT 210 with the reference time information acquired from the GM 230, and calculates a time difference.

  For example, the ONU 220 can extract and restore the frequency, 1 PPS, and TOD from the Ethernet standard IEEE802.1as precise time protocol data received from the OLT 210, and can transmit the 1588 PTP packet from the GM 230, thereby obtaining the reference time information.

  Next, the ONU 220 transmits the time difference calculated through the PON MAC 221 to the OLT 210. At this time, the time difference is transmitted from the ONU to the OLT with the highest priority.

  For example, a time difference is transmitted through a time correction protocol, and the time correction protocol is ITU-TG. It is possible to adopt a format in which time difference information is added to information based on SF of 8285.1 BMCCA.

  Thereafter, the SFU 211 of the OLT 210 corrects the time based on the time difference received from the ONU 220 and performs time synchronization with the ONU 220. For example, if the current OLT time is T, the time difference received from the ONU is ΔT, and the time corrected time is T ′, then T ′ = T ± ΔT.

  After the time correction is performed as described above, the above operation is continuously repeated using the corrected time information instead of the initial time information to synchronize the time between the OLT and the ONU. If the time difference between the corrected time information received from the OLT 210 and the reference time information acquired from the GM 230 reaches an allowable time range, the ONU 220 is locked.

  If the ONU 220 is locked, then the ONU 220 transmits clock information to a slave device (not shown) connected to the ONU. For example, the clock information can be transmitted to the slave device in the form of 1588 PTP packet or 1PPS + TOD.

  By mounting in this way, the present invention can efficiently perform time synchronization between the OLT and the ONU forming the passive optical network (PON).

  FIG. 3 is a flowchart showing a configuration of still another embodiment of a time synchronization method for a communication network according to the present invention.

  First, in the time information acquisition step (310), the OLT acquires initial time information from NTP or RTC. For example, the acquired initial time information includes a frequency, 1 PPS, and TOD.

  Next, in the time information transmission step (320), the initial time information obtained by the OLT is transmitted to the ONU. For example, the initial time information is transmitted through the Ethernet standard IEEE 802.1as precise time protocol.

  Next, in the time difference calculation step (330), the initial time information received by the ONU from the OLT and the reference time information acquired from the GPS receiving module are compared to calculate a time difference.

  For example, it is possible to extract and restore the frequency, 1 PPS, and TOD from the Ethernet standard IEEE 802.1as precise time protocol data received by the ONU from the OLT, and obtain 1 PPS + TOD information synchronized with the GPS satellite from the GPS receiving module.

  Next, in the time difference transmission stage (340), the time difference for which the ONU is calculated is transmitted to the OLT. At this time, the time difference is transmitted from the ONU to the OLT with the highest priority.

  For example, a time difference is transmitted through a time correction protocol, and the time correction protocol is ITU-TG. It is possible to adopt a format in which time difference information is added to information based on SF of 8285.1 BMCCA.

  Next, in the time synchronization step (350), the OLT corrects the time based on the time difference received from the ONU and performs time synchronization with the ONU. For example, if the current OLT time is T, the time difference received from the ONU is ΔT, and the time corrected time is T ′, then T ′ = T ± ΔT.

  After the time correction is performed as described above, the time information transmission step (320), the time difference calculation step (330), and the time difference transmission are performed using the corrected time information instead of the initial time information. The time of the OLT and the ONU is continuously synchronized by repeating the step (340) and the time synchronization step (350).

  Next, in the ONU lock phase (360), if the time difference between the corrected time information received from the OLT and the reference time information acquired from the GPS receiving module reaches an allowable time range, the ONU Locked.

  Next, if the ONU is locked in the time synchronization information transmission stage (370), the OLT then transmits the time synchronization information to the GM. Then, the GM transmits time synchronization information to another OLT (not shown). For example, time synchronization information is transmitted through a 1588 PTP packet.

  FIG. 4 is a block diagram showing a passive optical network configuration that performs the time synchronization method of the communication network shown in FIG. The passive optical network shown in FIG. 4 includes an OLT 410, an ONU 420, and a GM 430.

  After the power is input, the SFU 411 of the OLT 410 acquires initial time information from the NTP or RTC, and performs time synchronization based on the initial time information. For example, the acquired initial time information includes a frequency, 1 PPS, and TOD.

  The SFU 411 transmits initial time information to the SIU 412. The PON MAC of the SIU 412 transmits initial time information to the ONU 420. For example, the initial time information is transmitted through the Ethernet standard IEEE 802.1as precise time protocol.

  Thereby, the PON MAC 421 of the ONU 420 acquires the initial time information from the OLT 410, and the GPS reception module 422 of the ONU 420 acquires the reference time information from the GPS satellite (not shown).

  Then, the L2 switch 423 of the ONU 420 compares the initial time information received from the OLT 410 with the reference time information acquired from the GPS receiving module 422, and calculates a time difference.

  For example, the ONU 420 can extract and restore the frequency, 1 PPS, and TOD from the Ethernet standard IEEE 802.1as precise time protocol data received from the OLT 410, and obtain 1 PPS + TOD information synchronized with the GPS satellite from the GPS receiving module 422.

  Next, the ONU 420 transmits the time difference calculated through the PON MAC 421 to the OLT 410. At this time, the time difference is transmitted from the ONU to the OLT with the highest priority.

  For example, a time difference is transmitted through a time correction protocol, and the time correction protocol is ITU-TG. It is possible to adopt a format in which time difference information is added to information based on SF of 8285.1 BMCCA.

  Accordingly, the time is corrected based on the time difference received from the ONU 420 by the SFU 411 of the OLT 410 and time synchronization with the ONU 420 is performed. For example, if the current OLT time is T, the time difference received from the ONU is ΔT, and the time corrected time is T ′, then T ′ = T ± ΔT.

  After the time correction is performed as described above, the above operation is continuously repeated using the corrected time information instead of the initial time information to synchronize the time between the OLT and the ONU. When the time difference between the corrected time information received from the OLT 410 and the reference time information acquired from the GPS reception module 422 reaches an allowable time range, the ONU 420 is locked.

  If the ONU 420 is locked, then the OLT 410 transmits time synchronization information to the GM 430. Then, the GM 430 transmits time synchronization information to another OLT (not shown). For example, time synchronization information is transmitted through a 1588 PTP packet.

  By mounting in this way, the present invention can efficiently perform time synchronization between the OLT and the ONU forming the passive optical network (PON).

  FIG. 5 is a flowchart showing a configuration of a further embodiment of a time synchronization method for a communication network according to the present invention.

  First, in the time information acquisition step (510), the OLT acquires initial time information from NTP or RTC. For example, the acquired initial time information includes a frequency, 1 PPS, and TOD.

  Next, in the time information transmission step (520), the initial time information obtained by the OLT is transmitted to the ONU. For example, the initial time information is transmitted through the Ethernet standard IEEE 802.1as precise time protocol.

  Next, in the time difference calculation stage (530), the initial time information received by the ONU from the OLT is compared with the reference time information acquired from the GPS receiving module, and the time difference is calculated.

  For example, it is possible to extract and restore the frequency, 1 PPS, and TOD from the Ethernet standard IEEE 802.1as precise time protocol data received by the ONU from the OLT, and obtain 1 PPS + TOD information synchronized with the GPS satellite from the GPS receiving module.

  Next, in the time difference transmission stage (540), the time difference calculated by the ONU is transmitted to the OLT. At this time, the time difference is transmitted from the ONU to the OLT with the highest priority.

  For example, a time difference is transmitted through a time correction protocol, and the time correction protocol is ITU-TG. It is possible to adopt a format in which time difference information is added to information based on SF of 8285.1 BMCCA.

  Next, in the time synchronization step (550), the time is corrected based on the time difference received from the ONU by the OLT, and time synchronization with the ONU is performed. For example, if the current OLT time is T, the time difference received from the ONU is ΔT, and the time corrected time is T ′, then T ′ = T ± ΔT.

  After the time correction is performed as described above, the time information transmission stage (520), the time difference calculation stage (530), and the time difference transmission are performed using the corrected time information instead of the initial time information. The time of the OLT and the ONU is continuously synchronized by repeating the step (540) and the time synchronization step (550).

  Next, in the ONU lock phase (560), if the time difference between the corrected time information received from the OLT and the reference time information acquired from the GPS receiving module reaches an allowable time range, the ONU Locked.

  Next, if the ONU is locked in the time synchronization information transmission step (570), then the OLT transmits the time synchronization information to other ONUs under its control. For example, the time synchronization information is transmitted to other ONUs under the control using the 802.1as precise time protocol.

  Then, the time synchronization information received from the OLT by other ONUs under its control is transmitted to the slave device (not shown) connected to itself. For example, the time synchronization information can be transmitted to the slave device through a 1588 PTP packet.

  FIG. 6 is a block diagram showing a passive optical network configuration that performs the time synchronization method of the communication network shown in FIG. The passive optical network shown in FIG. 6 includes an OLT 610, an ONU 620, and another ONU 630.

  After the power is input, the SFU 611 of the OLT 610 acquires initial time information from the NTP or RTC, and synchronizes the time based on the initial time information. For example, the acquired initial time information includes a frequency, 1 PPS, and TOD.

  The SFU 611 transmits initial time information to the SIU 612. The PON MAC of SIU 612 transmits initial time information to ONU 620. For example, the initial time information is transmitted through the Ethernet standard IEEE 802.1as precise time protocol.

  Then, the PON MAC 621 of the ONU 620 acquires initial time information from the OLT 610, and the GPS reception module 622 of the ONU 620 acquires reference time information from a GPS satellite (not shown).

  Then, the L2 switch 623 of the ONU 620 compares the initial time information received from the OLT 610 with the reference time information acquired from the GPS reception module 622, and calculates a time difference.

  For example, the ONU 620 can extract and restore the frequency, 1 PPS, and TOD from the Ethernet standard IEEE 802.1as precise time protocol data received from the OLT 610, and obtain 1 PPS + TOD information synchronized with the GPS satellite from the GPS receiving module 622.

  Next, the ONU 620 transmits the time difference calculated through the PON MAC 621 to the OLT 610. At this time, the time difference is transmitted from the ONU to the OLT with the highest priority.

  For example, a time difference is transmitted through a time correction protocol, and the time correction protocol is ITU-TG. It is possible to adopt a format in which time difference information is added to information based on SF of 8285.1 BMCCA.

  Then, the SFU 611 of the OLT 610 corrects the time based on the time difference received from the ONU 620, and performs time synchronization with the ONU 620. For example, if the current OLT time is T, the time difference received from the ONU is ΔT, and the time corrected time is T ′, then T ′ = T ± ΔT.

  After the time correction is performed as described above, the above operation is continuously repeated using the corrected time information instead of the initial time information to synchronize the time between the OLT and the ONU. If the time difference between the corrected time information received from the OLT 610 and the reference time information acquired from the GPS reception module 622 reaches an allowable time range, the ONU 620 is locked.

  If the ONU 620 is locked, then the OLT 610 transmits time synchronization information to other ONUs 630 under its control. For example, the time synchronization information is transmitted to other ONUs under the control using the 802.1as precise time protocol.

  Then, the time synchronization information received from the OLT by other subordinate ONUs 630 is transmitted to the slave device (not shown) connected to itself. For example, the time synchronization information can be transmitted to the slave device through a 1588 PTP packet.

By mounting in this way, the present invention can efficiently perform time synchronization between the OLT and the ONU forming the passive optical network (PON).
The present invention has been described with reference to the preferred embodiments referred to by the accompanying drawings. However, it should be understood that various changes and modifications may be made without departing from the scope of the present invention within the scope of the following claims. Obviously, variations are possible.

  The present invention is industrially applicable in the time synchronization technical field and its application technical field.

210, 410, 610: OLT
220, 420, 620: ONU
230, 430: GM
630: Other ONU

Claims (11)

A time information acquisition stage in which the OLT acquires initial time information from NTP or RTC;
A time information transmission stage for transmitting the initial time information obtained by the OLT to the ONU;
A time difference calculation step of calculating a time difference by comparing the initial time information received by the ONU from the OLT and the reference time information acquired from the GM;
A time difference transmission stage for transmitting the time difference calculated by the ONU to the OLT;
A time synchronization stage in which the OLT corrects the time based on the time difference received from the ONU and performs time synchronization with the ONU;
A time synchronization method for a communication network, comprising: The communication network time synchronization method is
After the time correction, using the corrected time information, the time information transmission stage, the time difference calculation stage, the time difference transmission stage, and the time synchronization stage are repeated to continuously set the times of the OLT and the ONU. The communication network time synchronization method according to claim 1, wherein synchronization is performed. The communication network time synchronization method is
It further includes an ONU lock stage in which the ONU is locked when the time difference obtained by comparing the corrected time information received from the OLT and the reference time information acquired from the GM reaches an allowable time range. The time synchronization method for a communication network according to claim 2. The communication network time synchronization method is
The method of claim 3, further comprising a time synchronization information transmission step of transmitting the clock information to a slave device connected to the ONU after the ONU is locked. A time information acquisition stage in which the OLT acquires initial time information from NTP or RTC;
A time information transmission stage for transmitting the initial time information obtained by the OLT to the ONU;
A time difference calculation step of calculating a time difference by comparing the initial time information received by the ONU from the OLT and the reference time information acquired from the GPS receiving module;
A time difference transmission stage for transmitting the time difference calculated by the ONU to the OLT;
A time synchronization stage that corrects the time based on the time difference received by the OLT from the ONU and performs time synchronization with the ONU;
A time synchronization method for a communication network, comprising: The communication network time synchronization method is
After the time correction, using the corrected time information, the time information transmission stage, the time difference calculation stage, the time difference transmission stage, and the time synchronization stage are repeated to continuously set the times of the OLT and the ONU. The communication network time synchronization method according to claim 5, wherein synchronization is performed. The communication network time synchronization method is
If the time difference obtained by comparing the corrected time information received from the OLT and the reference time information acquired from the GPS receiving module reaches an allowable time range, an ONU lock stage is further included in which the ONU is locked. The time synchronization method for a communication network according to claim 6. The communication network time synchronization method is
The method of claim 7, further comprising a time synchronization information transmission step in which the OLT transmits time synchronization information to the GM after the ONU is locked. The GM is
The time synchronization method for a communication network according to claim 8, wherein the time synchronization information is transmitted to another OLT. The communication network time synchronization method is
The method according to claim 7, further comprising a time synchronization information transmission step in which the OLT transmits the time synchronization information to another ONU under its control after the ONU is locked.   The time synchronization method for a communication network according to claim 10, wherein time synchronization information received from the OLT by another subordinate ONU is transmitted to a slave device connected to the ONU.

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