RU2673404C2 - System and method for processing distributed ssm protocols based on complex packet exchange system - Google Patents

Abstract

FIELD: computer equipment.SUBSTANCE: invention relates to computer engineering. System for processing a distributed SSM protocol based on an integrated packet exchange system is described, which is characterized by the following: includes the main control panel, the system exchange unit and at least one operating panel, while the system exchange unit is responsible for the communication between the main data processing unit and the operational data processing unit; main control panel includes the main processing unit and the main processing unit, aforementioned data processing logic is responsible for collecting the inbound SSM messages of each port of each operating panel and packaging the output messages of the main data processing unit, as well as sending to each operational processing logic, the aforementioned main processing unit is responsible for processing the above-mentioned incoming SSM messages and sending outgoing messages to each operational processing unit, each operation panel includes an operation unit for data processing and an operation logic unit for data processing, aforementioned data processing unit is responsible for calculating the outgoing SSM messages of each port of the operation panel, packing them into ESMC messages and sending them to the operation logic processing unit, aforementioned data processing logic is responsible for providing SSM inbound messages for each port of this operation panel to the main data processing logic and sending the above ESMC messages to each port.EFFECT: technical result is to provide processing of the distributed SSM protocol based on an integrated packet exchange system.9 cl, 3 dwg

Description

Technical field

The present invention relates to the technical field of synchronous transmission systems, in particular, to a system and method for processing a distributed SSM protocol (Synchronous Status Message) based on an integrated packet exchange system.

Prior art

Currently, SSM is widely used in synchronous digital transmission systems. For synchronization systems, time synchronization is crucial, and the main goal in terms of the time topology of synchronization systems is to avoid the synchronization loop.

The implementation of the SSM protocol is an important tool in solving the problem of avoiding the formation of a synchronization loop. Implementation of the SSM protocol not only includes the implementation of SSM rules, stringent requirements are also imposed by the time SSM messages are processed. In accordance with the requirements of the G.8262 standard and the international standard YD / T 1267, in the absence of switching, the delay Tnsm (delay of non-sequential information) of SSM processing is <200 ms, in the presence of switching, the delay Tsm (delay of alternating information) of SSM processing is <500 ms , and in terms of maintaining the delay Tnm (delay in maintaining information) SSM processing is <2000 ms.

As the sophistication of modern communications equipment continues to grow, there are more supported ports for operational processing. Each port must support time synchronization and SSM information transfer. Suppose there are N operating panels in total, each of which has M ports. In accordance with the traditional algorithm, the main microprocessor needs to read SSM information from N * M ports. Complex systems can have extremely many ports for processing the SSM protocol stack. In this case, the system needs to process a large number of operations, operations of various types, the microprocessor load on the main panel becomes extremely large, at the same time, when processing SSM messages of many ports, the SSM delay ceases to satisfy the protocol requirements. If the processing time of the SSM protocol is too long, if the time source switches, and as a result of this, a synchronization loop forms (the synchronization loop is a phenomenon when the network’s own synchronization signal is monitored from the timer. When the timer goes directly to the output or directly through the network, it returns to the input , then a synchronization loop occurs), which leads to instability of the entire time channel and to oscillations in it.

The essence of the invention

To overcome the disadvantages of existing technologies, the aim of the present invention is to provide a system and method for processing a distributed SSM protocol based on an integrated packet exchange system; In the present invention, the corresponding SSM delay is improved and the SSM processing time is effectively reduced, which avoids the formation of a synchronization loop in the time cycle.

To achieve the goal described above, the following technical solutions are used in the present invention: a system and method for processing distributed SSM protocols based on an integrated packet exchange system, including a main control panel, a system exchange unit and at least one operating panel, while the system exchange unit is responsible for communication between the main data processing unit and the operational data processing unit. The main control panel includes a main data processing unit and a main data processing logic unit, while the aforementioned main data processing logic unit is responsible for collecting incoming SSM messages of each port of each operating panel, packing outgoing messages of the main data processing unit, and sending them to each operating room logical data processing unit. Each operation panel includes an operational data processing unit and an operational logical data processing unit; the aforementioned operational data processing unit is responsible for calculating the outgoing SSM messages of each port of the operating panel, packaging them in an ESMC message and sending it to the operational logical data processing unit. The aforementioned operational data processing logic unit is responsible for providing incoming SSM messages of each port of a given operating panel to the main data processing logic unit and sending the aforementioned ESMC messages to each port.

Based on the technical solution described above, the main protocol processing unit is installed in the aforementioned main information processing unit, which is responsible for processing the above-mentioned incoming SSM messages. In the aforementioned operational data processing unit, an operational protocol stack is installed, which is responsible for calculating the outgoing SSM messages of each port of the operating panel.

Based on the technical solution described above, the system also includes a backup main control panel, which is an additional unit and copies and archives data of the main control panel.

Based on the technical solution described above, the system also includes a communication unit between the panels, which is used to transfer load data between the main control panel and the backup main control panel.

Based on the technical solution described above, the system also includes an auxiliary command input terminal, with which the client can configure the timer function of this system. The main protocol stack converts and separates the settings information of the command input terminal and sends the necessary settings for the SSM protocol to the main data processing unit.

Based on the technical solution described above, the aforementioned command input terminal is a PC on which equipment network management software or a command line input interface is installed.

Based on the technical solution described above, a method for processing a distributed SSM protocol based on an integrated packet exchange system includes the following steps: Step S1: Each operational logical data processing unit receives incoming SSM messages from each port of this operating panel. Step S2: The main data processing unit receives the settings information entered by the user and, through the system exchange unit, notifies each operating panel of the need to provide the operating panel code for incoming SSM messages. Step S3: The operation panels notified of the need to provide incoming SSM messages via the operational data processing logic block provide their incoming SSM messages to the main data processing logic block. Step S4: In the main data processing unit, the main protocol stack is installed, which processes the user-entered settings information and incoming SSM messages of each operating panel in the main data processing logical unit using the SSM protocol, and also combines the processing results with the user-entered settings information and through the system exchange unit sends them back to the data processing operating unit of the original operating panel. Step S5: An operational protocol stack is installed in the operational data processing unit, which, in accordance with the received processing results and user input information, calculates the outgoing SSM messages of each port, and the operational data processing unit wraps these SSM outgoing messages in ESMC messages and through the operation logic block data processing sends to each port of the operating panel.

Based on the technical solution described above, in step S4, the main protocol stack, in accordance with the user-entered settings information and incoming SSM messages of each operation panel in the main data processing logical unit, calculates the current blocking source and SSM value of the current blocking source.

Based on the technical solution described above, in step S5, the format of the aforementioned ESMC message complies with the requirements of the G.8264 protocol.

A useful result of the present invention is as follows:

1. The present invention employs a distributed computing method in which SSM information is processed jointly by a main control panel and an operation panel. The sent part of the SSM rules is executed by the operation panel, the central processing of all ports of all equipment is replaced by the processing by the operating panel of its own ports, the corresponding SSM delay has been improved, and the SSM processing time has been effectively reduced, which avoids the formation of a synchronization loop in the time cycle.

2. The present invention allows, through the operating panel for data exchange (packet exchange) between the main control panel and the operating panel, to selectively send to the main control panel the necessary SSM messages for the main control, thereby reducing the amount of data transfer.

3. The data processing unit of the main control panel and the backup main control panel synchronizes through the communication unit between the panels, which ensures the unity of the received settings information of the main control panel and the backup main control panel and the unity of the status of each state received by the main control panel and the backup main control panel operating panel, which allows you to provide a protective function in case of failure of the main control panel.

Brief Description of Images

Figure 1 is a structural block diagram of a distributed protocol processing system SSM based on the integrated packet exchange system of an embodiment of the present invention;

2 is a schematic diagram of synchronization of a main control panel and a standby main control panel according to an embodiment of the present invention;

Figure 3 is a schematic representation of the main control panel receiving settings information according to an embodiment of the present invention.

Specific Embodiments

The following is a more detailed description of the present invention, accompanied by images and embodiments.

As shown in FIG. 1, a system and method for processing distributed SSM protocols based on an integrated packet exchange system, including a main control panel, a system exchange unit and at least one operating panel, while the system exchange unit is responsible for communication between the main data processing unit and the operational data processing unit. The main control panel includes a main data processing unit and a main data processing logic unit, while the aforementioned main data processing logic unit is responsible for collecting incoming SSM messages of each port of each operating panel, packaging of outgoing messages of the main data processing unit (conversion to the system’s internal communication format) , as well as sending them to each operational logical data processing unit. The aforementioned main data processing unit is responsible for processing the aforementioned incoming SSM messages, as well as sending outgoing messages to each operational data processing unit. In the aforementioned main data processing unit, a main protocol stack is installed which is responsible for processing the aforementioned incoming SSM messages. Each operation panel includes an operational data processing unit and an operational logical data processing unit; the aforementioned operational data processing unit is responsible for calculating the outgoing SSM messages of each port of the operating panel, packing them into ESMC (Ethernet synchronization messaging channel) messages (the ESMC message format must comply with the international G.8264 standard) and sending it to the operational processing logic unit data. In the aforementioned operational data processing unit, an operational protocol stack is installed, which is responsible for calculating the outgoing SSM messages of each port of the operating panel. The aforementioned operational data processing logic unit is responsible for providing incoming SSM messages of each port of a given operating panel to the main data processing logic unit and sending the aforementioned ESMC messages to each port.

As shown in FIG. 2, the system also includes a backup main control panel and a communication unit between the panels, while the backup main control panel is an additional unit and copies and archives data of the main control panel. The above-mentioned communication unit between the panels is used to transfer load data between the main control panel and the redundant main control panel. It is used to ensure the unity of the settings received by the main control panel and the backup main control panel, and the information received by the main control panel and the backup main control panel of the status of each operating panel.

As shown in FIG. 3, the system also includes an auxiliary command input terminal with which the client can configure the timer function of this system, including activating / deactivating the SSM protocol, selecting timer sources for which the SSM protocol will be activated, and entering source settings. The main protocol stack converts and separates the settings information of the command input terminal and sends the necessary settings for the SSM protocol to the main data processing unit. The above command input terminal is a PC on which equipment network management software or a command line input interface is installed.

A method for processing a distributed SSM protocol based on an integrated packet exchange system based on the system described above includes the following steps:

step S1. Each operational logical unit of data processing receives incoming SSM messages of each port of this operating panel.

step S2. The main data processing unit receives the settings information entered by the user and, through the system exchange unit, notifies each operating panel of the need to provide the operating panel code of the incoming SSM messages.

step S3. Notified of the need to provide incoming SSM messages, the operation panels, through the operational data processing logic block, provide their incoming SSM messages to the main data processing logic block.

step S4. In the main data processing unit, the main protocol stack is installed, which processes the user-entered settings information and incoming SSM messages of each operating panel in the main data processing logical unit. The main protocol stack, in accordance with the user-entered settings information and incoming SSM messages of each operating panel in the main logical processing unit, calculates the current blocking source (to which operating panel the hardware timer lock originally indicated) and the SSM value of the current blocking source (SSM value corresponding to the blocked operating panel). The processing results and user-entered settings information are combined and sent back to the data processing operating unit of the original operating panel via the system exchange unit.

step S5. An operational protocol stack is installed in the operational data processing unit, which, in accordance with the received processing results and settings entered by the user, calculates the outgoing SSM messages of each port, and the operational data processing unit packs these outgoing SSM messages into ESMC messages and sends on each port of the operating panel. The format of the aforementioned ESMC messages complies with the requirements of the G.8264 protocol (Distribution of timing information through packet networks - distribution of time information through packet networks, ITU-T G.8264).

Each operating panel of the present invention receives settings information sent by the main control panel through a system exchange unit. The main control panel, through this settings information, controls one or more specific operating panels, and through a separate logical processing unit, incoming SSM messages of each port of this operating panel are provided to the main control panel. In accordance with the settings information, the main panel activates the selection part of the SSM protocol sources. Using the SSM protocol, a high priority timer source is selected as the system timer source. After the calculations are completed, the main control panel notifies the operational data processing unit of each operating panel of the selected operating panel and the port of the operating panel through communication between the panels. The general status and settings of the operational data processing unit transmitted by the main control panel trigger the part of sending the SSM protocol, and the calculated result is sent to each port of the operating panel via the operational logical data processing unit.

The present invention is not limited to the above embodiments, and if the technical personnel in this field can, without interrupting the principles of the present invention, make some adjustments and improvements, then these adjustments and improvements are also considered to be within the protection range of the present invention. The disclosure of the invention does not describe in detail the well-known existing techniques to those skilled in the art.

Claims (19)

1. The processing system of the distributed SSM protocol based on an integrated packet exchange system, which is characterized by the following: includes a main control panel, a system exchange unit and at least one operating panel, the system exchange unit is responsible for communication between the main data processing unit and the operational data processing unit; the main control panel includes a main data processing unit and a main data processing logic unit, the aforementioned data processing logic unit is responsible for collecting incoming SSM messages of each port of each operating panel and packing outgoing messages of the main data processing unit, as well as sending it to each operational data processing logic unit , the aforementioned main data processing unit is responsible for processing the aforementioned incoming SSM messages and sending outgoing messages to each operational unit to data processing, and each operating panel includes an operational data processing unit and an operational data processing logic unit, the aforementioned operational data processing unit is responsible for calculating the SSM messages of each port of the operating panel, packaging them in ESMC messages and sending to the operational data processing logical unit, the aforementioned operational data processing logical unit is responsible for providing incoming SSM messages of each port of this operating panel to the main logical processing unit and sending the aforementioned ESMC messages to each port. 2. The processing system of the distributed SSM protocol based on an integrated packet exchange system in accordance with paragraph 1, which is characterized by the following: inside the aforementioned data processing unit, a main protocol stack is installed which is responsible for processing the aforementioned incoming SSM messages; inside the aforementioned operational data processing unit, an operational protocol stack is installed, which is responsible for calculating the outgoing SSM messages of each port of the operating panel. 3. The processing system of the distributed SSM protocol based on an integrated packet exchange system in accordance with paragraph 1, which is characterized by the following: it also includes a backup main control panel, which is an additional unit and copies and archives data of the main control panel. 4. The system for processing the distributed SSM protocol based on an integrated packet exchange system in accordance with Clause 3, which is characterized by the following: it also includes a communication unit between the panels, which is used to transfer load data between the main control panel and the backup main control panel. 5. The processing system of the distributed SSM protocol based on an integrated packet exchange system in accordance with Clause 1, which is characterized by the following: it also includes an external command input terminal with which the client can configure the timer function of this system, and the main protocol stack converts and splits information about the settings of the command input terminal and sends the necessary SSM protocol settings to the main data processing unit. 6. The system for processing the distributed SSM protocol based on an integrated packet exchange system in accordance with clause 5, which is characterized by the following: the aforementioned command input terminal is a PC on which the equipment’s network management software or command line input interface is installed. 7. A method for processing a distributed SSM protocol based on an integrated packet exchange system in accordance with paragraph 1, characterized by the presence of the following steps: step S1: receiving by each operational logic processing unit of the data incoming messages SSM of each port of this operating panel; step S2: receiving by the main data processing unit the settings information entered by the user and notifying by the system exchange unit of each operating panel the need to provide the operating panel code to the incoming SSM messages; step S3: providing notified by the need to provide incoming SSM messages by the operation panels by means of the operational logical processing unit of the data of their incoming SSM messages to the main logical processing unit; step S4: implementing the main protocol stack installed in the main data processing unit for processing user-entered settings information and incoming SSM messages of each operating panel in the main data processing logical unit using the SSM protocol, as well as combining the processing results and user-entered settings information and sending them by system exchange unit back to the operational data processing unit of the original operating panel; step S5: calculating the protocol stack installed in the operational data processing unit in accordance with the received processing results and the user inputted information of the settings, the SSM messages of each port, packaging the SSM message in the ESMC message by the data processing operation unit and sending it via the operation processing logic data on each port of the operating panel. 8. A method for processing a distributed SSM protocol based on an integrated packet exchange system in accordance with clause 7, characterized by the following: in step S4, the main protocol stack, in accordance with the user-entered configuration information and incoming SSM messages, calculates each operating panel in the main data processing logical unit current lock source and SSM value of the current lock source. 9. A method for processing a distributed SSM protocol based on an integrated packet exchange system in accordance with clause 7, characterized by the following: in step S5, the format of the aforementioned ESMC message complies with the requirements of the G.8264 protocol.

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