WO2013075307A1 - 监测网络节点的输出时间方法、装置和系统 - Google Patents
监测网络节点的输出时间方法、装置和系统 Download PDFInfo
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- WO2013075307A1 WO2013075307A1 PCT/CN2011/082834 CN2011082834W WO2013075307A1 WO 2013075307 A1 WO2013075307 A1 WO 2013075307A1 CN 2011082834 W CN2011082834 W CN 2011082834W WO 2013075307 A1 WO2013075307 A1 WO 2013075307A1
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L43/00—Arrangements for monitoring or testing data switching networks
- H04L43/08—Monitoring or testing based on specific metrics, e.g. QoS, energy consumption or environmental parameters
- H04L43/0805—Monitoring or testing based on specific metrics, e.g. QoS, energy consumption or environmental parameters by checking availability
- H04L43/0817—Monitoring or testing based on specific metrics, e.g. QoS, energy consumption or environmental parameters by checking availability by checking functioning
Definitions
- the present invention relates to the field of communication networks, and in particular, to a method, device and system for monitoring output time of a network node. Background technique
- the IEEE1588 V2 protocol is a frequency time synchronization protocol, referred to as PTP (Precision Time Protocol), which is a precision time synchronization protocol standard for network measurement and control systems.
- PTP Precision Time Protocol
- time accuracy can reach microseconds in the case of frequency synchronization. This standard is able to accurately disperse, book
- the time of independent operation is synchronized.
- the current maintenance method can only monitor the status of a single node, and the node monitoring is only based on the ⁇ negotiation.
- the function determines the port state and tracking state of the node or the logically connected upper and lower nodes, which can only reflect whether the time of each node is in the tracking state, and cannot timely sense the time error of the node and network output in the tracking state. Once the time error of a node or a few nodes is large, the time for the external output of the network may be unavailable.
- the tracking state is normal, even if there is a large error in the time when the meter is used to measure the external output of the network, the current maintenance means cannot indicate which nodes in the current tracking path have introduced an abnormality. Summary of the invention
- Embodiments of the present invention provide a method, apparatus, and system for monitoring an output time of a network node.
- the technical solution is as follows:
- a method of monitoring an output time of a network node comprising:
- the time offset obtained by the processor is vector-accumulated to obtain a time deviation cumulative vector
- a monitoring device is configured to monitor an output time of a network node, where the monitoring device comprises:
- a time synchronization module configured to perform time synchronization with other network nodes
- a time deviation obtaining module configured to acquire a time deviation generated during the time synchronization process
- the accumulating module is configured to perform vector summation of the acquired time deviation to obtain a time deviation cumulative vector; and a determining module, configured to determine whether an absolute value of the time deviation cumulative vector is greater than a first threshold; When the determining module determines that the absolute value of the time deviation cumulative vector is greater than the first threshold, determining that the output time is unavailable;
- a sending module configured to send the information that the output time is unavailable to the monitoring server.
- a time synchronization system the system includes a first node, a second node, and a monitoring server, and the first node tracks an output time of the second node;
- the first node and the second node both include the monitoring device described above;
- the monitoring server is configured to receive information that the output time sent by the first node and the second node is unavailable, and output an alarm according to the information that the output time is unavailable.
- a time synchronization system the system includes a first node, a second node, and a monitoring server, wherein the first node and the second node perform time synchronization, and the first node tracks the output time of the second node;
- the time deviation in each time synchronization is obtained by the node, and the long-term cumulative monitoring of the time deviation can reflect the trend and amplitude of the time adjustment of the node, and the output time quality of the node is evaluated in the tracking state, and the time offset of the monitoring node is monitored. It has a positive significance for enhancing the availability and maintainability of the ground carrying network through PTP delivery.
- FIG. 1 is a flowchart of a method for monitoring an output time of a network node according to an embodiment of the present invention
- FIG. 2 is a schematic diagram of a node connection according to an embodiment of the present invention.
- FIG. 3 is a flowchart of a method for monitoring an output time of a network node according to an embodiment of the present invention
- FIG. 4 is a schematic structural diagram of a monitoring apparatus according to an embodiment of the present invention.
- FIG. 5 is a schematic structural diagram of a time synchronization system according to an embodiment of the present invention.
- FIG. 6 is a schematic structural diagram of a time synchronization system according to an embodiment of the present invention. detailed description
- FIG. 1 is a flowchart of a method for monitoring an output time of a network node according to an embodiment of the present invention.
- the execution body of the embodiment is a first node in a time synchronization system, the time synchronization system includes at least a first node and a second node, and the first node and the second node are directly connected in the time synchronization system.
- the embodiment specifically includes:
- the first node and the second node in the communication network are network elements, and the first node and the second node are connected by more than one physical link.
- the PTP is started, and the first node and the second node perform port negotiation according to the configuration, and select an optimal physical link.
- Time synchronization is completed as a trace path. Among them, time synchronization is a known process in ⁇ , and will not be described here.
- the first node When time synchronization is performed, the first node is a slave node of the second node, the first node tracks the second node, and the first node adjusts the local time to synchronize with the time of the second node, so that the local time and the time of the second node are synchronized. Same or similar.
- the time offset obtained by the processor is vector-accumulated to obtain a time offset cumulative vector
- the first node and the second node perform a time synchronization every first preset time period, and each time synchronization process records a time deviation and performs vector accumulation on the time deviation to obtain a time deviation accumulation vector;
- the method further includes: transmitting the obtained time offset accumulation vector to the monitoring server.
- the second time duration is obtained, and the time deviation cumulative vector obtained before the time point is sent to the monitoring server, so that the monitoring server monitors the output time quality of the node according to the time deviation cumulative vector obtained within the preset time length. This is the time to send The accumulated value before the interval, instead of the accumulated value over a period of time, the monitoring server can see the offset trend of the node time by the accumulated value of each time period received.
- the first preset duration is an interval for performing synchronization
- the second preset duration is an interval for transmitting a time offset accumulation vector, where the first preset duration and the second preset duration are set by the technician at the initial time of the system.
- the absolute value of the time offset is the amplitude of the first node time adjustment in the time synchronization
- the absolute value of the time offset cumulative vector is the total amplitude of the first node's time adjustment within the preset duration.
- the direction according to the time deviation and the time deviation accumulation vector is used to indicate whether the tendency of the first node to perform time adjustment is forward adjustment or backward adjustment.
- the step 104 specifically includes: determining whether an absolute value of the time offset cumulative vector is greater than a first threshold, and if yes, determining that an output time of the first node is unavailable, and if not, It is determined that the output time of the first node is available. It can be known by those skilled in the art that the time of the first node and the time of the second node should be the same or similar each time time synchronization is performed, but if any one of the first node or the second node has an output time failure or frequency When the time synchronization is performed again, the time deviation occurs.
- the first threshold is a preset value in the time synchronization system and is set by a technician.
- the first node may monitor, according to the time offset accumulation vector, a time quality that the time synchronization system outputs to the outside through the end node.
- the information that the output time is unavailable is sent to the monitoring server.
- the present invention can be implemented based on the condition that the network has completed time tracking.
- the time deviation in each time synchronization is obtained by the node, and the long-term cumulative monitoring of the time deviation can reflect the trend and amplitude of the time adjustment of the node, and the output time quality of the node is evaluated in the tracking state, and the time offset of the monitoring node is monitored. It has a positive significance for enhancing the availability and maintainability of the ground carrying network through PTP delivery.
- FIG. 2 is a schematic diagram of a node connection according to an embodiment of the present invention.
- the connection relationship between the nodes is as shown in Figure 2.
- NE1, NE2, NE3, NE4, NE5, and B NE6 are physically connected through optical fibers 1 ⁇ 5, BITS is used as the time source input, and NE1 ⁇ NE6 are used to start PTP.
- PTP can synchronize NE1, NE2 NE3 NE4 NE6 and NE5.
- the NE6 tracking path is NE5-NE4-NE6.
- the time tracking status of each network element in the network is normal, and the NE6 output time can be use.
- FIG. 3 is a flowchart of a method for monitoring an output time of a network node according to an embodiment of the present invention.
- the nodes NE5 and NE4 in the architecture shown in FIG. 2 are used as an example.
- the NE5 and the NE4 are directly connected in the network.
- the embodiment specifically includes:
- NE4 and NE5 After determining the physical link, NE4 and NE5 perform port negotiation.
- NE4 is a slave port and NE5 is a master port, NE4 and NE5 start time synchronization.
- the NE4 acquires a time stamp according to the protocol information that interacts with the NE5 during the time synchronization process.
- the time stamp is obtained by the protocol information exchanged when the NE4 and the NE5 are synchronized; the specific process description is as follows:
- NE5 sends Sync information to NE4 at time tl, NE5 records the time point T1 at that moment, and transmits the time stamp T1 to NE4 through Sync information (or Follow_up information);
- NE4 sends Delay_Req information to NE5 at time t3, and the time point T3 is recorded by NE4;
- 304 and NE4 calculate the time deviation according to the time scales T1, ⁇ 2, ⁇ 3, and ⁇ 4, and adjust the local time according to the time deviation to complete the tracking of ⁇ 4 to ⁇ 5;
- time delay of information from ⁇ 5 to ⁇ 4 is equal to the time delay of information from ⁇ 4 to NE5e and both are
- the time-scale on NE4 at the same time is Offset with respect to the time-scale deviation on NE5 (ie, the time deviation of NE4 from NE5), then the T1 obtained by NE4 according to the recorded T2, ⁇ 3 and the protocol information. , T4, the following one-dimensional equation is established:
- T2 - T1 Delay + Offset
- T4 - T3 Delay - Offset
- NE4 can calculate the delay Delay on the path between NE5 and NE4, and the time offset of NE4 relative to NE5 Offset:
- the time deviation with respect to NE5 can be eliminated, and the precise time of synchronization is synchronized with NE5. 305.
- the NE4 performs vector accumulation on the obtained time offset to obtain a time deviation cumulative vector, and performs step 306 and
- the time deviation recorded here is a vector, and the vector is accumulated to know the adjustment range and the adjustment trend of the time in a period of time.
- NE4 and NE5 are time synchronized. If the time synchronization is performed on the N+1th time, there is still a time deviation.
- the time deviation direction between the NE4 and the NE5 is known, if the vector is the same. As the direction grows, it indicates that NE4 or NE5 has a shift in time after the Nth synchronization.
- the accumulation process in step 305 can be performed by a processor internal to the node.
- NE4 determines whether an absolute value of the time deviation cumulative vector is greater than a first threshold.
- the absolute value of the time deviation accumulation vector is greater than the first threshold value, whether the vector direction changes or not, it indicates that the time of NE4 or NE5 is abnormal, and the abnormality may be due to (1) the local clock has a fixed frequency offset or ( 2)
- the optical transceiver link is asymmetric (that is, the time delay of the protocol information from the master port master to the slave port slave is equal to the time delay from the slave to the master).
- the asymmetry of the optical transceiver link between the Master and the Slave changes by lm, which causes the calculated time offset Offset to increase by about 5 ns.
- the error of lus only needs to introduce the asymmetry of the 200 m fiber. Yes.
- the time offset Offset calculated by the node will continue to shift in the same direction, and the time of the external output will also be offset incorrectly.
- the error of the time stamp of the node in processing the protocol information will also cause the time offset Offset calculation to be incorrect.
- the monitoring server in this embodiment refers to the server that has the data collection function module.
- the monitoring server is not necessarily a separate server, but it can also be a functional module of other servers.
- the monitoring server receives the information that the output time sent by the NE4 is unavailable, and outputs an alarm that the output time of the NE4 is abnormal, and ends.
- the monitoring server can output or prompt the available node and the unavailable node to the monitoring server user so that the user can perform maintenance according to the output or prompt.
- the embodiment further includes:
- the NE4 sends the first time offset cumulative vector obtained before the sending time point to the monitoring server every second preset duration.
- NE4 and NE5 in the architecture shown in FIG. 2 are taken as an example, and NE4 and NE5 are in the network.
- the logic in the network is directly connected, and NE4 tracks the output time of NE5.
- NE4 and NE5 respectively monitor their output time, and send the time deviation accumulation vector to the monitoring server.
- NE5 is the second node, and the time deviation accumulation vector sent by NE5 is sent.
- NE4 is the first node
- the time offset accumulation vector sent by NE4 is the first time offset accumulation vector.
- the monitoring server receives the first time offset cumulative vector and the second time offset cumulative vector.
- the monitoring server can receive the time offset accumulation vector sent by more than two nodes, and monitor the output time quality of the node according to the time deviation accumulation vector.
- the monitoring server calculates a vector difference between the first time offset cumulative vector and the second time offset cumulative vector, and determines whether an absolute value of the vector difference is greater than a second threshold.
- the second threshold is a preset value in the time synchronization system and is set by a technician.
- NE5 is in the tracking path of NE4, NE5 is the master port, NE4 is the slave port, and NE4 is time synchronized according to the time of NE5.
- NE4 abnormality after synchronization, NE4 and NE5 should be kept close to each other or synchronized.
- the amplitude of the next synchronization adjustment may be large, and a large time deviation occurs, so that the absolute value of the vector difference of the NE5 and NE4 time deviation accumulation vectors is greater than the second threshold.
- all abnormal nodes on the tracking path can be obtained by judging the absolute values of the inter-node vector differences that are directly connected on the same tracking path. Further, the monitoring server can also follow the nodes on the same tracking path. The pairwise judgment is performed in the order from the back to the front to obtain the first node that introduces the abnormality on the tracking path.
- the system shown in FIG. 2 is taken as an example.
- the absolute value of the difference between the received time deviation cumulative vectors of NE4 and NE6 is less than the second threshold, the absolute value of the difference of the time offset cumulative vectors of NE4 and NE5 may be determined, when the absolute value is greater than The second threshold value indicates that the first node that introduces an abnormality on the tracking path is NE4.
- the time deviation in each time synchronization is obtained by the node, and the long-term cumulative monitoring of the time deviation can reflect the trend and amplitude of the time adjustment of the node, and the output time quality of the node is evaluated in the tracking state, and the time offset of the monitoring node is monitored. It has a positive significance for enhancing the availability and maintainability of the ground carrying network through PTP delivery. Further, based on the PTP principle, as long as the time offset Offset of a node on the tracking path of the network output node is offset, the output time of the network output node is also tracked, and the first path on the tracking path can be determined accordingly. A node with a large offset of the time offset accumulation vector is a node that may introduce an offset.
- FIG. 4 is a monitoring apparatus for monitoring an output time of a network node according to an embodiment of the present invention. See Figure 4, The monitoring device includes:
- a time synchronization module 401 configured to perform time synchronization with other network nodes
- the time deviation obtaining module 402 is configured to acquire a time deviation generated during the time synchronization process
- the accumulating module 403 is configured to perform vector summation on the acquired time offset to obtain a time offset cumulative vector.
- the determining module 404 is configured to determine whether an absolute value of the time offset cumulative vector is greater than a first threshold; When the determining module determines that the absolute value of the time offset accumulation vector is greater than the first threshold, determining that the output time is unavailable;
- the sending module 406 is configured to send the information that the output time is unavailable to the monitoring server.
- the sending module 406 is further configured to send the time offset cumulative vector obtained by the accumulating module 403 to the monitoring server.
- the device provided in this embodiment may be a function module on a node, which is the same as the method embodiment.
- the device provided in this embodiment may be a function module on a node, which is the same as the method embodiment.
- a function module on a node which is the same as the method embodiment.
- FIG. 5 is a schematic structural diagram of a time synchronization system according to an embodiment of the present invention.
- the system includes: the system includes a first node A1, a second node B1, and a monitoring server Cl, and the first node A1 tracks an output time of the second node B1;
- the first node A1 and the second node B1 both include the monitoring device described in the above embodiments;
- the monitoring server C1 is configured to receive information that the output time sent by the first node A1 and the second node B1 is unavailable, and output an alarm according to the information that the output time is unavailable.
- the first node A1 is further configured to send a first time offset accumulation vector to the monitoring server C1, where the second node Bl is further configured to send a second time offset accumulation vector to the monitoring server;
- the monitoring server C1 includes:
- a receiving unit C11 configured to receive the first time offset cumulative vector and the second time offset cumulative vector
- a calculating unit C12 configured to calculate the first time offset cumulative vector and the second time offset cumulative vector
- a determining unit C13 configured to determine whether an absolute value of the vector difference is greater than a second threshold, and determining, when the absolute value of the vector difference acquired by the acquiring unit is greater than a second threshold An output of the node is abnormal.
- the output unit C14 is configured to output an alarm that the output time of the first node is abnormal.
- FIG. 6 is a schematic structural diagram of a time synchronization system according to an embodiment of the present invention.
- the system includes: a first node A2, a second node B2, and a monitoring server C2.
- the time between the first node A2 and the second node B2 is the same. Step, and the first node A2 tracks the output time of the second node B2;
- the first node A2 acquires a time offset generated in the time synchronization process, and performs vector integration on the acquired time offset to obtain a first time offset accumulation vector, and sends the first time offset accumulation vector to the monitoring server;
- the second node B2 is configured to acquire a time offset generated during the time synchronization process, perform vector integration on the acquired time offset to obtain a second time offset accumulation vector, and send the second time offset accumulation vector to the monitoring server;
- the monitoring server C2 calculates a vector difference between the first time offset cumulative vector and the second time offset cumulative vector, and determines whether the absolute value of the vector difference is greater than a second threshold value, when the acquiring unit acquires When the absolute value of the vector difference is greater than the second threshold, an alarm that an abnormality occurs in the output time of the first node is output.
- the first node A2 further determines whether the absolute value of the first time offset cumulative vector is greater than a first threshold, and when the absolute value of the first time offset cumulative vector is greater than the first threshold, determining The output time of the first node is unavailable, and the information that the output time is unavailable is sent to the monitoring server;
- the monitoring server C2 also outputs an alarm according to the information that the output time sent by the first node is unavailable.
- the second node B2 further determines whether an absolute value of the second time offset cumulative vector is greater than a first threshold, and when the absolute value of the second time offset cumulative vector is greater than a first threshold, determining The output time of the second node is unavailable, and the information that the output time is unavailable is sent to the monitoring server;
- the monitoring server C2 further outputs an alarm according to the information that the output time sent by the second node is unavailable.
- a person skilled in the art may understand that all or part of the steps of implementing the above embodiments may be completed by hardware, or may be instructed by a program to execute related hardware, and the program may be stored in a computer readable storage medium.
- the storage medium mentioned may be a read only memory, a magnetic disk or an optical disk or the like. The above is only the preferred embodiment of the present invention, and is not intended to limit the present invention. Any modifications, equivalent substitutions, improvements, etc., which are within the spirit and scope of the present invention, should be included in the protection of the present invention. Within the scope.
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Abstract
本发明公开了一种监测网络节点的输出时间方法、装置和系统,属于通信网络领域。该方法包括:在节点之间进行时间同步;获取所述时间同步过程中产生的时间偏差;由处理器将获取的时间偏差进行矢量累计,得到时间偏差累计矢量;确定所述时间偏差累计矢量的绝对值大于第一门限值时,则确定输出时间不可用;将所述输出时间不可用的信息发送给监测服务器。该装置包括:时间同步模块、时间偏差获取模块、累计模块、发送模块、判断模块和确定模块。本发明可以反映该节点时间调整的趋势和幅度,在跟踪状态下评估节点的输出时间质量,监测节点的时间偏移,对增强地面承载网通过PTP传递精确时间的可用性和可维护性有积极的意义。
Description
监测网络节点的输出时间方法、 装置和系统 技术领域
本发明涉及通信网络领域, 特别涉及一种监测网络节点的输出时间方法、 装置和系统。 背景技术
在现代通信网络中, 实时性要求说较高的业务对于整个通信网络时钟频率同步甚至时间 同步提出了很高的要求。 IEEE1588 V2协议就是一种频率时间同步协议,简称 PTP ( Precision Time Protocol, 精密时间协议), 该 PTP是网络测量和控制系统的精密时间同步协议标准。 采用 PTP, 在频率同步的情况下, 时间精度可以达到微秒级。 此标准能够精确地把分散、 书
独立运行的时间同步起来。
在对现有技术进行分析后, 发明人发现现有技术至少具有如下缺点:
现有的通信网络通过 ΡΤΡ传递时间时, 输出时间精度易受网络拓扑或网络内部软硬件 环境变化等因素影响, 目前的维护手段只能对单节点的状态进行监测, 且节点监测只是基 于 ΡΤΡ协商功能来判决本节点或者逻辑直连的上下节点的端口状态和跟踪状态, 只能反映 各节点的时间是否处于跟踪状态, 而无法及时感知跟踪状态下节点和网络输出的时间误差 大小。 一旦某一节点或某几个节点输出的时间误差较大, 就可能导致网络对外输出的时间 不可用。 另外, 当跟踪状态正常时, 即使使用仪表测量到网络对外输出的时间存在较大的 误差, 目前维护手段也无法指示当前跟踪路径上是哪些节点引入了异常。 发明内容
本发明实施例提供了一种监测网络节点的输出时间方法、 装置和系统。 所述技术方案 如下:
一种监测网络节点的输出时间的方法, 所述方法包括:
在节点之间进行时间同步;
获取所述时间同步过程中产生的时间偏差;
由处理器将获取的时间偏差进行矢量累计, 得到时间偏差累计矢量;
确定所述时间偏差累计矢量的绝对值大于第一门限值时, 则确定输出时间不可用; 将所述输出时间不可用的信息发送给监测服务器。
一种监测装置, 用于监测网络节点的输出时间, 所述监测装置包括:
时间同步模块, 用于与其他网络节点进行时间同步;
时间偏差获取模块, 用于获取所述时间同步过程中产生的时间偏差;
累计模块, 用于将获取的时间偏差进行矢量累计, 得到时间偏差累计矢量; 判断模块, 用于判断所述时间偏差累计矢量的绝对值是否大于第一门限值; 确定模块, 用于当所述判断模块确定所述时间偏差累计矢量的绝对值大于第一门限值 时, 则确定输出时间不可用;
发送模块, 用于将所述输出时间不可用的信息发送给监测服务器。
一种时间同步系统, 所述系统包括第一节点、 第二节点和监测服务器, 第一节点跟踪 第二节点的输出时间;
所述第一节点和第二节点都包括上述的监测装置;
所述监测服务器用于接收第一节点和第二节点发送的输出时间不可用的信息, 并根据 所述输出时间不可用的信息输出告警。
一种时间同步系统, 所述系统包括第一节点、 第二节点和监测服务器, 第一节点与第 二节点之间进行时间同步, 且第一节点跟踪第二节点的输出时间;
所述第一节点, 获取所述时间同步过程中产生的时间偏差, 将获取的时间偏差进行矢 量累计得到第一时间偏差累计矢量, 将第一时间偏差累计矢量发送给所述监测服务器; 所述第二节点, 获取所述时间同步过程中产生的时间偏差, 将获取的时间偏差进行矢 量累计得到第二时间偏差累计矢量, 将第二时间偏差累计矢量发送给所述监测服务器; 所述监测服务器, 计算所述第一时间偏差累计矢量与所述第二时间偏差累计矢量的矢 量差, 判断所述矢量差的绝对值是否大于第二门限值, 当所述获取单元获取的所述矢量差 的绝对值大于第二门限值时, 输出所述第一节点的输出时间出现异常的告警。 本发明实施例提供的技术方案的有益效果是:
通过节点获取每次时间同步中的时间偏差, 并对该时间偏差进行长期累积监测, 可以 反映该节点时间调整的趋势和幅度, 在跟踪状态下评估节点的输出时间质量, 监测节点的 时间偏移, 对增强地面承载网通过 PTP传递精确时间的可用性和可维护性有积极的意义。 附图说明
为了更清楚地说明本发明实施例中的技术方案, 下面将对实施例描述中所需要使用的 附图作简单地介绍, 显而易见地, 下面描述中的附图仅仅是本发明的一些实施例, 对于本
领域普通技术人员来讲, 在不付出创造性劳动的前提下, 还可以根据这些附图获得其他的 附图。
图 1是本发明实施例提供的一种监测网络节点的输出时间的方法的流程图;
图 2是本发明实施例提供的节点连接示意图;
图 3是本发明实施例提供的一种监测网络节点的输出时间的方法的流程图;
图 4是本发明实施例提供的一种监测装置的结构示意图;
图 5是本发明实施例提供的一种时间同步系统的结构示意图
图 6是本发明实施例提供的一种时间同步系统的结构示意图。 具体实施方式
为使本发明的目的、 技术方案和优点更加清楚, 下面将结合附图对本发明实施方式作 进一步地详细描述。
图 1 是本发明实施例提供的一种监测网络节点的输出时间的方法的流程图。 该实施例 的执行主体为时间同步系统中的第一节点, 该时间同步系统中至少包括第一节点和第二节 点,且该第一节点和第二节点在该时间同步系统中逻辑直连,参见图 1,该实施例具体包括:
101、 在节点之间进行时间同步;
本领域技术人员可以获知, 通信网络中的第一节点和第二节点均为网元, 该第一节点 和第二节点通过一条以上物理链路相连。 第一节点和第二节点之间确定了传输的物理链路 和时间组网配置时, 启动 PTP, 该第一节点和第二节点根据配置情况自行进行端口协商, 选取一条最优的物理链路作为跟踪路径完成时间同步。 其中, 时间同步是 ΡΤΡ中的已知过 程, 在此暂不赘述。
102、 获取所述时间同步过程中产生的时间偏差;
在进行时间同步时, 第一节点为第二节点的从节点, 该第一节点跟踪第二节点, 第一 节点调整本地时间与第二节点的时间进行同步, 使得本地时间与第二节点的时间相同或相 近。
103、 由处理器将获取的时间偏差进行矢量累计, 得到时间偏差累计矢量;
在本实施例中, 每隔第一预设时长, 第一节点和第二节点进行一次时间同步, 每次时 间同步过程记录时间偏差并对该时间偏差进行矢量累计, 得到时间偏差累计矢量;
进一步地, 所述方法还包括: 将得到的时间偏差累计矢量发送给监测服务器。 每隔第 二预设时长, 将该时间点之前得到该时间偏差累计矢量发送给监测服务器, 使得监测服务 器根据预设时长内得到的时间偏差累计矢量监测节点的输出时间质量。 这个发送的是该时
间点之前的累计值, 而不是一段时间内的累计值, 监测服务器通过收到的每个时间段的累 计值, 可以看出该节点时间的偏移趋势。 其中, 第一预设时长是进行同步的间隔, 第二预 设时长是发送时间偏差累计矢量的间隔, 该第一预设时长和第二预设时长为技术人员在系 统初始时进行设置。
其中, 该时间偏差的绝对值为该次时间同步中第一节点时间调整的幅度, 而该时间偏 差累计矢量的绝对值为该第一节点在预设时长内时间调整的总幅度。
另外, 根据时间偏差和时间偏差累计矢量的方向用于指示第一节点进行时间调整的趋 势是向前调整还是向后调整。
104、确定所述时间偏差累计矢量的绝对值大于第一门限值时,则确定输出时间不可用。 在本实施例中, 该步骤 104 具体包括: 判断所述时间偏差累计矢量的绝对值是否大于 第一门限值, 如果是, 则确定所述第一节点的输出时间不可用, 如果否, 则确定所述第一 节点的输出时间可用。 本领域技术人员可以获知, 每次进行时间同步后, 第一节点的时间 与第二节点的时间应是相同或相近, 但是如果第一节点或第二节点中有任一个的输出时间 故障或频率差, 则再进行一次时间同步时, 还会出现时间偏差, 因此当第一节点确定该时 间偏差累计矢量的绝对值大于第一门限值, 则说明该第一节点或第二节点的时间出现问题, 该第一节点的输出时间不可用。 其中, 该第一门限值为时间同步系统中的预设值, 由技术 人员设置。
进一步地, 当所述第一节点为时间同步系统中的末节点时, 第一节点可以根据所述时 间偏差累计矢量监测该时间同步系统通过所述末节点对外输出的时间质量。
105、 将所述输出时间不可用的信息发送给监测服务器。
在本实施例中, 为了向监测服务器告警该节点的输出时间不可用, 将输出时间不可用 的信息发送给监测服务器。
需要说明的是, 为了使所监测的输出时间偏移具有实际参考意义, 本发明可基于网络 已经完成时间跟踪的条件下实施。
通过节点获取每次时间同步中的时间偏差, 并对该时间偏差进行长期累积监测, 可以 反映该节点时间调整的趋势和幅度, 在跟踪状态下评估节点的输出时间质量, 监测节点的 时间偏移对增强地面承载网通过 PTP传递精确时间的可用性和可维护性有积极的意义。
图 2是本发明实施例提供的节点连接示意图。 节点之间的连接关系如图 2所示, NE1、 NE2、 NE3、 NE4、 NE5禾 B NE6分别通过光纤 1~5物理连接, BITS作为时间源输入, NE1〜 NE6启动 PTP, 贝 U丰艮据 PTP, 可以实现 NE1、 NE2 NE3 NE4 NE6禾口 NE5的同步, NE6 跟踪路径为: NE5-NE4-NE6。 另外, 该网络中各网元时间跟踪状态正常, NE6输出时间可
用。
图 3 是本发明实施例提供的一种监测网络节点的输出时间的方法的流程图。 本实施例 仅以图 2所示的架构中的节点 NE5和 NE4为例进行说明, NE5和 NE4在网络中逻辑直连, 该实施例具体包括:
301、 NE4和 NE5确定物理链路后, 进行端口协商;
本领域技术人员可以获知, NE4和 NE5之间根据时间同步协议进行端口协商, 其具体 协商过程在 PTP标准中有明确描述, 在此不再赘述。
302、 当 NE4为从端口, NE5为主端口时, NE4与 NE5开始时间同步;
303、 NE4根据时间同步过程中与 NE5交互的协议信息获取时标;
其中, 时标通过 NE4和 NE5之间进行同步时交互的协议信息获得; 其具体过程说明如 下:
( 1 ) NE5在 tl时刻发送 Sync信息给 NE4, NE5记录该时刻点时标 Tl, 并将该时标 T1通过 Sync信息 (或者 Follow_up信息) 传递到 NE4;
(2) Sync信息到达 NE4的时刻为 t2, 由 NE4记录该时刻点的时标 T2;
(3 ) NE4在时刻 t3发送 Delay_Req信息给 NE5, 由 NE4记录该时刻点时标 T3;
(4) Delay Req信息到达 NE5的时刻为 t4, 由 NE5记录该时刻点的时标 T4, 并将该 时标通过 Delay_Resp信息传递到 NE4。
304、 NE4根据时标 Tl、 Τ2、 Τ3和 Τ4计算时间偏差, 并根据该时间偏差调整本地时 间, 以完成 ΝΕ4对 ΝΕ5的跟踪;
假设信息从 ΝΕ5 到 ΝΕ4 的时间延迟与信息从 ΝΕ4 到 NE5e 的时间延迟相等且都为
Delay, 另外, 同一时刻在 NE4上的时标相对于在 NE5上的时标偏差 (即 NE4相对于 NE5 的时间偏差) 为 Offset, 则在 NE4根据记录的 T2、 Τ3和通过协议信息得到的 Tl、 T4, 如 下一元一次方程式成立:
T2 - T1 = Delay + Offset
T4 - T3 = Delay - Offset
通过解上述方程, NE4就可以计算出 NE5与 NE4间路径上的延迟 Delay, 以及 NE4相 对于 NE5的时间偏差 Offset:
Delay = [(T2 - Τ1) + (Τ4 - Τ3)] 12
Offset = [(Τ2 - Τ1) - (Τ4 - Τ3)] 12
ΝΕ4根据计算得出的时间偏差 Offset调整 NE4本地精确时间, 就可以消除相对于 NE5 的时间偏差, 同步精确时间到与 NE5—致。
305、 NE4将获取的时间偏差进行矢量累计, 得到时间偏差累计矢量, 执行步骤 306和
309;
需要说明的是, 这里记录的时间偏差为矢量, 对该矢量进行累计, 可以获知在一段时 间内时间的调整幅度和调整趋势。 当第 N次进行时间同步后, NE4和 NE5时间同步, 如果 第 N+1次进行时间同步时, 还存在时间偏差, 通过累计可知该 NE4和 NE5之间的时间偏 差方向, 如果该矢量向同一方向不断增长, 则说明 NE4或 NE5在第 N次同步后, 时间又出 现偏移现象。
该步骤 305中的累计过程可以由节点内部的处理器进行。
306、 NE4判断该时间偏差累计矢量的绝对值是否大于第一门限值,
如果是, 则执行步骤 307;
如果否, 则确定该 NE4的输出时间可用, 结束。
当该时间偏差累计矢量的绝对值大于第一门限值, 不论该矢量方向是否改变, 都说明 NE4或 NE5的时间出现异常, 该异常可能是由于 (1 ) 本地时钟有固定频偏或是 (2) 光纤 收发链路不对称(即协议信息从主端口 Master到从端口 Slave的时间延迟与从 Slave到 Master 的时间延迟相等) 造成的。 以 SDH光承载网为例, Master和 Slave间光纤收发链路不对称 性变化 lm, 导致计算出的时间偏差 Offset就增加约为 5ns的误差, lus的误差只需要引入 200m光纤不对称性为就可以了。 同样的如果跟踪路径上某节点时钟存在固定频偏, 则该节 点计算出的时间偏差 Offset就会不断向同一个方向偏移, 最终对外输出的时间也会随之错 误的偏移。 另外, 节点在处理协议信息的时标出现误差也会导致时间偏差 Offset计算有误。
307、 确定该 NE4的输出时间不可用, 将输出时间不可用的信息发送给监测服务器; 本领域技术人员可以获知, 本实施例所述的监测服务器是指具有数据收集功能模块的 服务器, 这里所说监测服务器不一定是一个单独的服务器, 也可以是其他服务器的一个功 能模块。
308、 监测服务器接收 NE4发送的输出时间不可用的信息, 输出 NE4的输出时间出现 异常的告警, 结束。
监测服务器可以将该可用节点和不可用节点输出或提示给监测服务器用户, 以使得用 户能够根据输出或提示进行维护。
进一步地, 该实施例还包括:
309、 NE4每隔第二预设时长, 将该发送时间点之前得到的第一时间偏差累计矢量发送 给监测服务器;
本实施例仅以图 2所示的架构中的节点 NE4和 NE5为例进行说明, NE4和 NE5在网
络中逻辑直连, 且 NE4跟踪 NE5的输出时间, NE4和 NE5分别对自身的输出时间进行监 测, 并将时间偏差累计矢量发送给监测服务器, NE5为第二节点, NE5发送的时间偏差累 计矢量为第二时间偏差累计矢量, NE4为第一节点, NE4发送的时间偏差累计矢量为第一 时间偏差累计矢量。
310、 监测服务器接收第一时间偏差累计矢量和第二时间偏差累计矢量;
在实际中, 监测服务器可以接收两个以上的节点发送的时间偏差累计矢量, 并根据该 时间偏差累计矢量对节点的输出时间质量进行监测。
311、 监测服务器计算所述第一时间偏差累计矢量与所述第二时间偏差累计矢量的矢量 差, 并判断所述矢量差的绝对值是否大于第二门限值,
如果是, 则执行步骤 312;
如果否, 则确定 NE4未出现异常, 结束;
其中, 该第二门限值为时间同步系统中的预设值, 由技术人员设置。
312、 确定 NE4出现异常, 输出所述第一节点的输出时间出现异常的告警。
由于 NE5处于 NE4的跟踪路径上, NE5为主端口, NE4为从端口, 该 NE4根据 NE5 的时间进行时间同步, 在 NE4异常的情况下, 经过同步, NE4与 NE5之间应该保持时间相 近或同步, 而由于 NE4异常, 其下一次同步需要调整的幅度可能会很大, 出现很大的时间 偏差, 从而造成 NE5和 NE4时间偏差累计矢量的矢量差绝对值大于第二门限值。
需要说明的是, 通过对在同一跟踪路径上逻辑直连的节点间矢量差的绝对值的判断, 可获知跟踪路径上所有异常节点, 进一步地, 监测服务器还可以根据同一跟踪路径上的节 点按照从后向前的顺序进行两两判断, 以便获知该跟踪路径上首个引入异常的节点, 以图 2 所示的系统为例,对于 NE6的跟踪路径 NE5-NE4-NE6来说,如果监测服务器接收到的 NE4 和 NE6的时间偏差累计矢量的差值的绝对值小于第二门限值, 则可对 NE4和 NE5的时间 偏差累计矢量的差值的绝对值进行判断, 当该绝对值大于第二门限值, 则可获知该跟踪路 径上首个引入异常的节点为 NE4。
通过节点获取每次时间同步中的时间偏差, 并对该时间偏差进行长期累积监测, 可以 反映该节点时间调整的趋势和幅度, 在跟踪状态下评估节点的输出时间质量, 监测节点的 时间偏移, 对增强地面承载网通过 PTP传递精确时间的可用性和可维护性有积极的意义。 进一步地, 基于 PTP原理, 只要网络输出节点跟踪路径上的某节点的时间偏差 Offset出现 偏移, 则说明该网络输出节点的输出时间也会跟踪偏移, 并且可据此判断该跟踪路径上首 个时间偏差累计矢量出现较大偏移的节点为可能引入偏移的节点。
图 4是本发明实施例提供的一种监测装置, 用于监测网络节点的输出时间,。参见图 4,
该监测装置包括:
时间同步模块 401, 用于与其他网络节点进行时间同步;
时间偏差获取模块 402, 用于获取所述时间同步过程中产生的时间偏差;
累计模块 403, 用于将获取的时间偏差进行矢量累计, 得到时间偏差累计矢量; 判断模块 404, 用于判断所述时间偏差累计矢量的绝对值是否大于第一门限值; 确定模块 405,用于当所述判断模块确定所述时间偏差累计矢量的绝对值大于第一门限 值时, 则确定输出时间不可用;
发送模块 406, 用于将所述输出时间不可用的信息发送给监测服务器。
所述发送模块 406还用于将所述累计模块 403得到的时间偏差累计矢量发送给监测服 务器。
本实施例提供的装置, 具体可以为节点上的功能模块, 与方法实施例属于同一构思, 其具体实现过程详见方法实施例, 这里不再赘述。
图 5是本发明实施例提供的一种时间同步系统的结构示意图。 参见图 5, 该系统包括: 所述系统包括第一节点 Al、 第二节点 B1和监测服务器 Cl, 第一节点 A1跟踪第二节 点 B1的输出时间;
所述第一节点 A1和第二节点 B1都包括上述实施例所述的监测装置;
所述监测服务器 C1用于接收第一节点 A1和第二节点 B1发送的输出时间不可用的信 息, 并根据所述输出时间不可用的信息输出告警。
其中, 所述第一节点 Al, 还用于向所述监测服务器 C1发送第一时间偏差累计矢量; 所述第二节点 Bl, 还用于向所述监测服务器发送第二时间偏差累计矢量;
所述监测服务器 C1包括:
接收单元 Cll, 用于接收所述第一时间偏差累计矢量和所述第二时间偏差累计矢量; 计算单元 C12,用于计算所述第一时间偏差累计矢量与所述第二时间偏差累计矢量的矢 判断单元 C13,用于判断所述矢量差的绝对值是否大于第二门限值,并当所述获取单元 获取的所述矢量差的绝对值大于第二门限值时, 确定所述第一节点的输出时间出现异常; 输出单元 C14, 用于输出所述第一节点的输出时间出现异常的告警。
本实施例提供的系统, 与方法实施例属于同一构思, 其具体实现过程详见方法实施例, 这里不再赘述。
图 6是本发明实施例提供的一种时间同步系统的结构示意图。 参见图 6, 该系统包括: 第一节点 A2、第二节点 B2和监测服务器 C2,第一节点 A2与第二节点 B2之间进行时间同
步, 且第一节点 A2跟踪第二节点 B2的输出时间;
所述第一节点 A2, 获取所述时间同步过程中产生的时间偏差, 将获取的时间偏差进行 矢量累计得到第一时间偏差累计矢量, 将第一时间偏差累计矢量发送给所述监测服务器; 所述第二节点 B2, 获取所述时间同步过程中产生的时间偏差, 将获取的时间偏差进行 矢量累计得到第二时间偏差累计矢量, 将第二时间偏差累计矢量发送给所述监测服务器; 所述监测服务器 C2, 计算所述第一时间偏差累计矢量与所述第二时间偏差累计矢量的 矢量差, 判断所述矢量差的绝对值是否大于第二门限值, 当所述获取单元获取的所述矢量 差的绝对值大于第二门限值时, 输出所述第一节点的输出时间出现异常的告警。
所述第一节点 A2, 还判断所述第一时间偏差累计矢量的绝对值是否大于第一门限值, 当所述第一时间偏差累计矢量的绝对值大于第一门限值时, 则确定第一节点的输出时间不 可用, 并将所述输出时间不可用的信息发送给监测服务器;
所述监测服务器 C2, 还根据所述第一节点发送的输出时间不可用的信息输出告警。 所述第二节点 B2, 还判断所述第二时间偏差累计矢量的绝对值是否大于第一门限值, 当所述第二时间偏差累计矢量的绝对值大于第一门限值时, 则确定第二节点的输出时间不 可用, 并将所述输出时间不可用的信息发送给监测服务器;
所述监测服务器 C2, 还根据所述第二节点发送的输出时间不可用的信息输出告警。 本领域普通技术人员可以理解实现上述实施例的全部或部分步骤可以通过硬件来完 成, 也可以通过程序来指令相关的硬件完成, 所述的程序可以存储于一种计算机可读存储 介质中, 上述提到的存储介质可以是只读存储器, 磁盘或光盘等。 以上所述仅为本发明的较佳实施例, 并不用以限制本发明, 凡在本发明的精神和原则 之内, 所作的任何修改、 等同替换、 改进等, 均应包含在本发明的保护范围之内。
Claims
1、 一种监测网络节点的输出时间的方法, 其特征在于, 所述方法包括:
在节点之间进行时间同步;
获取所述时间同步过程中产生的时间偏差;
由处理器将获取的时间偏差进行矢量累计, 得到时间偏差累计矢量;
确定所述时间偏差累计矢量的绝对值大于第一门限值时, 则确定输出时间不可用; 将所述输出时间不可用的信息发送给监测服务器。
2、 根据权利要求 1所述的方法, 其特征在于, 所述方法还包括: 将得到的时间偏差累计 矢量发送给监测服务器。
3、 一种监测装置, 用于监测网络节点的输出时间, 其特征在于, 所述监测装置包括: 时间同步模块, 用于与其他网络节点进行时间同步;
时间偏差获取模块, 用于获取所述时间同步过程中产生的时间偏差;
累计模块, 用于将获取的时间偏差进行矢量累计, 得到时间偏差累计矢量;
判断模块, 用于判断所述时间偏差累计矢量的绝对值是否大于第一门限值;
确定模块,用于当所述判断模块确定所述时间偏差累计矢量的绝对值大于第一门限值时, 则确定输出时间不可用;
发送模块, 用于将所述输出时间不可用的信息发送给监测服务器。
4、根据权利要求 3所述的监测装置, 其特征在于, 所述发送模块还用于将所述累计模块 得到的时间偏差累计矢量发送给监测服务器。
5、 一种时间同步系统, 其特征在于, 所述系统包括第一节点、 第二节点和监测服务器, 第一节点跟踪第二节点的输出时间;
所述第一节点和第二节点都包括权利要求 3所述的监测装置;
所述监测服务器用于接收第一节点和第二节点发送的输出时间不可用的信息, 并根据所 述输出时间不可用的信息输出告警。
6、 根据权利要求 5所述的系统, 其特征在于,
所述第一节点, 还用于向所述监测服务器发送第一时间偏差累计矢量;
所述第二节点, 还用于向所述监测服务器发送第二时间偏差累计矢量;
所述监测服务器包括:
接收单元, 用于接收所述第一时间偏差累计矢量和所述第二时间偏差累计矢量;
计算单元,用于计算所述第一时间偏差累计矢量与所述第二时间偏差累计矢量的矢量差; 判断单元, 用于判断所述矢量差的绝对值是否大于第二门限值, 并当所述获取单元获取 的所述矢量差的绝对值大于第二门限值时, 确定所述第一节点的输出时间出现异常;
输出单元, 用于输出所述第一节点的输出时间出现异常的告警。
7、 一种时间同步系统, 其特征在于, 所述系统包括第一节点、 第二节点和监测服务器, 第一节点与第二节点之间进行时间同步, 且第一节点跟踪第二节点的输出时间;
所述第一节点, 获取所述时间同步过程中产生的时间偏差, 将获取的时间偏差进行矢量 累计得到第一时间偏差累计矢量, 将第一时间偏差累计矢量发送给所述监测服务器;
所述第二节点, 获取所述时间同步过程中产生的时间偏差, 将获取的时间偏差进行矢量 累计得到第二时间偏差累计矢量, 将第二时间偏差累计矢量发送给所述监测服务器;
所述监测服务器, 计算所述第一时间偏差累计矢量与所述第二时间偏差累计矢量的矢量 差, 判断所述矢量差的绝对值是否大于第二门限值, 当所述获取单元获取的所述矢量差的绝 对值大于第二门限值时, 输出所述第一节点的输出时间出现异常的告警。
8、 根据权利要求 7所述的系统, 其特征在于,
所述第一节点, 还判断所述第一时间偏差累计矢量的绝对值是否大于第一门限值, 当所 述第一时间偏差累计矢量的绝对值大于第一门限值时, 则确定第一节点的输出时间不可用, 并将所述输出时间不可用的信息发送给监测服务器;
所述监测服务器, 还根据所述第一节点发送的输出时间不可用的信息输出告警。
9、 根据权利要求 7所述的系统, 其特征在于,
所述第二节点, 还判断所述第二时间偏差累计矢量的绝对值是否大于第一门限值, 当所 述第二时间偏差累计矢量的绝对值大于第一门限值时, 则确定第二节点的输出时间不可用, 并将所述输出时间不可用的信息发送给监测服务器;
所述监测服务器, 还根据所述第二节点发送的输出时间不可用的信息输出告警。
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