RU2814686C1 - Method of routing in communication network with high probability of failure of its elements - Google Patents

Abstract

FIELD: communication equipment.

SUBSTANCE: invention relates to communication networks. Technical result is achieved due to periodic measurement of the state of communication channels and evaluation of the states of logical structures of the communication network, storing in the formed memory the entire plurality of logical structures formed during the operation of the communication network, and optimal routes determined for them, their extraction from memory and use instead of recalculation in case of repetition of logical structures during further operation of communication network.

EFFECT: high stability of the communication network due to shorter time for finding optimal routes in the communication network with a high probability of failure of its elements.

4 cl, 5 dwg

Description

The invention relates to the field of functioning of communication networks and can be used to improve their performance.

A communication network is an infrastructure that ensures the transfer of information between various consumers (subscribers). The most widely used communication networks are those operating using datagram transmission technology (packet switching communication network).

A packet switched communication network consists of many communication nodes (routers) connected by communication lines. Each router (router port) has a unique identifier (IP address) and operates in accordance with the accepted methods (protocols) of interaction on the network.

The ways in which the elements of a communication network interact make up its architecture. The architecture of packet-switched communication networks assumes the preservation of communication (continuity of the information exchange process) between correspondents in the event of failures of network elements, provided that physical connectivity (working physical path) between correspondents remains [D.D. Clark, “The Design Philosophy of the DARPA Internet Protocols,” ACM SIGCOMM Computer Communication Review, vol. 18, no. 4, 1988, pp. 106–114].

The process of finding a path to transport packets is called routing. The routing task is to find the optimal path (route) between correspondents.

If we assume that the structure of the communication network and its parameters are unchanged, then the routing process only needs to be completed once. However, since the structure of the communication network and its parameters are dynamic, in order to adapt routes to changes, the routing process must be repeated and repeated.

If the routing process is not completed after each change in the communication network, the previously found routes are no longer optimal, which negatively affects the performance of the communication network.

The time spent searching for optimal routes is important, since from the moment a change occurs in the network until new optimal routes are found, the network operates with a decrease in performance indicators or is even in an inoperable state.

The main factor influencing changes in the structure of a communication network is failures of its elements, which can manifest themselves at the physical level and at the logical level. The presence of two failure levels is due to the fact that almost all active elements of the communication network are software and hardware.

A failure at the physical level implies the failure of an element, for example, due to reaching the mean time between failures, and a failure at the logical level implies a violation of the correct functioning of the software part, for example, due to cyber attacks.

Thus, the urgent task is to reduce the time it takes to find optimal routes in a communication network with a high probability of failures of its elements.

There is a known method for routing data packets between multiple switching devices [RF patent No. 2598322, H04L 12/28, publ. 09/20/2016 Bulletin. No. 26], which consists in the fact that between a plurality of network packet switching devices, the first network device, after checking the data message, compares the priority values of the current and second network devices and, for a network device with a lower priority, blocks the response through the port of the first network device associated with the specified network device devices, and the value of the priority of a network device is the reciprocal of the distance from the network device to the host device, expressed in the number of intermediate network devices located between the network device and the host device, and the calculation of distance values for each of the network devices is carried out using remote control vector algorithm.

The method is aimed at ensuring minimal delay in data transmission and uniform load distribution between network switching devices.

The disadvantage of this method is a long time when the communication network is inoperative, associated with repeating the processes of optimizing routes to the same parameters of the communication network, as well as the low energy efficiency of network elements associated with the irrational use of the computing capabilities of its elements.

There is a known method for multidimensional dynamic routing in a communication network with packet message transmission [RF patent No. 2765810, H04L 12/64, publ. 02/03/2022 Bulletin. No. 4], which consists in the fact that in communication nodes, they monitor the quality of the communication channels included in them, the results of this control are transmitted to other available communication nodes, form one-dimensional transmission routes, which are combined into multidimensional transmission routes, and determine the target functions of multidimensional transmission routes, while managing multidimensional dynamic routing designate methods for separating adjacent communication channels between communication nodes, involving the use of various physical fields, signal propagation media and methods of time, frequency, polarization, and code separation; as well as separation by power, by spatial coding, by modulation, by transmission speed, by signal shape, by exchange protocols, for each communication channel in each communication node and in each route.

The method is aimed at increasing the performance of a communication network with packet messaging by expanding the spectrum and optimizing methods.

The disadvantage of this method is the long time that the communication network is inoperative, associated with repeating the processes of optimizing routes to the same parameters of the communication network, as well as the low energy efficiency of network elements associated with the irrational use of the computing capabilities of its elements.

The closest in technical essence and functions performed to the declared one (prototype) is the routing method using the OSPF protocol (Open Shortest Path First, open the shortest path first).

OSPF is a dynamic routing protocol based on link state tracking technology and uses Dijkstra's algorithm to find the shortest path [J. Moy RFC 2328 "OSPF Version 2", ISOC, 1998 244 p., https://www.ietf.org/rfc/rfc2328.txt.pdf].

The essence of the prototype method is that they measure the state of communication channels between adjacent nodes of the communication network, using the flooding method to distribute information about the state of adjacent communication channels between all nodes of the communication network. At each communication node, a graph is built that reflects the logical structure of the communication network (the current state of the communication network), and the shortest paths to the remaining nodes of the communication network are calculated using Dijkstra’s algorithm. During the operation of a communication network, the state of communication channels between adjacent nodes of the communication network is measured with a given period; when the state of communication channels changes, information about the appeared or disappeared communication channels is disseminated using the flooding method; after which, at each communication node, the graph is rebuilt, reflecting the logical structure of the communication network (the current state of the communication network) and, using Dijkstra's algorithm, the shortest paths to the remaining nodes of the communication network are calculated.

The disadvantage of this method is a long time when the communication network is inoperative, associated with repeating the processes of optimizing routes to the same parameters of the communication network, as well as the low energy efficiency of network elements associated with the irrational use of the computing capabilities of its elements.

A technical problem is the long time that the communication network remains inoperative, due to the high total duration of route search processes caused by failures of its elements.

The technical result of the invention is to increase the stability of the communication network by reducing the time it takes to find optimal routes in a communication network with a high probability of failure of its elements, and consequently, reducing the time the communication network is in an inoperative state, as well as increasing the energy efficiency of its elements.

The technical problem is achieved through periodic measurement of the state of communication channels and assessment of the states of logical structures of the communication network, storing in the generated memory the entire set of logical structures formed during the operation of the communication network, and optimal routes determined for them, retrieving them from memory and using them instead of repeating them. calculations in case of repetition of logical structures in the process of further operation of the communication network.

The technical result is achieved by the fact that in the method of routing in a communication network with a high probability of failures of its elements, the state of communication channels between adjacent nodes of the communication network is measured, information about the state of adjacent communication channels is distributed using the flooding method between all nodes of the communication network, a graph is built at each communication node , reflecting the logical structure of the communication network, during the operation of the communication network with a given period, the state of communication channels between adjacent nodes of the communication network is measured, when the state of communication channels changes, information about the appeared or disappeared communication channels is disseminated using the flooding method, the graph is rebuilt at each communication node, reflecting the logical structure of the communication network, according to the invention, additionally, at each communication node, a memory area is formed, structured to store matched records about the state of the logical structure of the network, lists of optimal routes and counters of the state of its logical structure; when the logical structure of the communication network changes, the records in the generated memory area, if there is a record for the current state of the logical structure, then as the searched routes, select routes from the list of optimal routes stored in memory corresponding to the current state of the logical structure of the communication network, increase the logical structure state counter by one, sort the records in the memory area in descending order state counter of the logical structure of the communication network, if there is no record for the current state of the logical structure, then determine the optimal routes for the current logical structure of the communication network, add to the memory area a record about the current state of the logical structure of the communication network and a list of determined optimal routes, set the value of the state counter logical structure to zero, certain routes are selected as the required routes.

The analysis of the state of the art made it possible to establish that there are no analogues characterized by sets of features identical to all the features of the claimed method. Consequently, the claimed invention meets the patentability condition of “novelty”.

The listed new set of essential features ensures a reduction in the time it takes to find optimal routes in a communication network with a high probability of failure of its elements, as well as an increase in the energy efficiency of its elements by storing certain optimal routes in memory, retrieving them from memory and using them, instead of re-computing, in case of repetition logical structures in the process of further operation of the communication network.

The results of a search for known solutions in this and related fields of technology in order to identify features that coincide with the features of the claimed invention that are distinctive from the prototypes, showed that they do not follow explicitly from the prior art. The prior art determined by the applicant does not reveal the impact of the essential features of the claimed invention on achieving the specified technical result. Therefore, the claimed invention meets the patentability requirement of “inventive step”.

The “industrial applicability” of the method is due to the presence of an elemental base on the basis of which devices that implement this method can be made to achieve the result specified in the invention.

1. A method of routing in a communication network with a high probability of failure of its elements.

The claimed method is illustrated by drawings:

fig. 1 – block diagram of a routing method in a communication network with a high probability of failure of its elements;

fig. 2 – structure of the memory area;

fig. 3 – example of a table of the current state of the logical structure of a communication network after measurements;

fig. 4 – example of a table of the current state of the logical structure of a communication network after receiving information from all communication nodes;

fig. 5 – chronological diagram of changes in the state of the communication network.

1.1 Before operating the communication network, a memory area is formed, structured to store matched records about the state of the logical structure of the network, lists of optimal routes and counters of the state of its logical structure (Fig. 1, block 1).

Memory structuring involves allocating the required number of memory cells from the general pool of device memory cells, grouping them and naming them.

What is important is the limit on the number of stored records (memory capacity), which should be no more than m log n , where m is the number of communication lines, and n is the number of communication nodes. An explanation of this limitation is provided below, in the part of the description devoted to the evaluation of effectiveness.

The general view of the formed memory is presented in the form of a table in Fig. 2, where the lines contain the corresponding entries “Logical structure”, “List of optimal routes” and “Counter”.

The memory area can be formed on the basis of random access memory (RAM) or permanent memory (NVRAM) of the router. For example, a Cisco 1941 router can have from 512 MB to 2 GB of permanent memory [Cisco 1941 Series Integrated Services Routers Data sheet, 14 p. – 2017, www.cisco.com].

Also, additional memory modules can be installed on the communication node, for example, “MEM3800-256U1024D” or “MEM-C6K-CPTFL2GB”.

1.2 Further actions are carried out during the operation of the communication network, which is shown in the block diagram as a cycle (Fig. 1, block 2-16), in which: the service variable t is reset to zero - the current operating time (Fig. 1, block 2), in the body cycle (Fig. 1, blocks 3-15), the variable t is increased by the value Δ t corresponding to the specified period (Fig. 1, block 3), the condition for exiting the cycle is checked, corresponding to the end of the operating time T (Fig. 1, block 16).

Perform the following actions with a given period.

1.3 Measure the state of communication channels between adjacent nodes of the communication network (Fig. 1, block 4).

The action is carried out in relation to each communication line by communication nodes adjacent to it (routers).

One of the options for measuring the state of communication channels is the exchange of service messages over these channels according to the request-response scheme. The channel is considered operational if a response is received within a specified time and inoperative otherwise [J. Moy RFC 2328 “OSPF Version 2”, ISOC, 1998 244 p., https://www.ietf.org/rfc/rfc2328.txt.pdf; Olifer V., Olifer N. Computer networks. Principles, technologies, protocols: Anniversary edition. – St. Petersburg: Peter, 2020. – 1008 p.: ill.].

In addition, measurements of the state of communication channels can be carried out using methods in accordance with communication network measurement protocols [RFC-2544; RFC-5357; Y.1564], using hardware and software systems that implement the specified techniques, for example, MAKS-EMK [Official website of the manufacturer: https://kometeh.ru/], M716-10G [Official website of the manufacturer: https://stc. metrotek.ru/] or ShinewayTech SWT-DTA-100D-ETH-SDH [Official website of the manufacturer: https://shinewaytech.com/].

In the case of an accurate assessment of the quality of communication channels, their state (operability/inoperability) can be determined based on the compliance of the measured indicators with the required values.

As a result of the action, information about operational (list) communication channels appears at each communication node. Communication channels are determined by pairs of identifiers (IP addresses) of the communication nodes that form it.

The measurement results are recorded in the table of the current state of the logical structure (Fig. 3).

1.4 Disseminate information about emerging or disappearing communication channels (Fig. 1, block 5) [J. Moy RFC 2328 “OSPF Version 2”, ISOC, 1998 244 p., https://www.ietf.org/rfc/rfc2328.txt.pdf; Olifer V., Olifer N. Computer networks. Principles, technologies, protocols: Anniversary edition. – St. Petersburg: Peter, 2020. – 1008 p.: ill.].

Information is distributed in accordance with accepted network methods, for example, via the TCP/IP protocol, for which appropriate packets are generated and sent through router ports connected by a communication line.

The formation of communication channels can be carried out, for example, using optical “MOXA SFP-1GLHLC-T”, radio “Ruggedcom WiN7225” and “MAXBridge CPE 50 SME” and other modules installed at communication nodes.

Each communication node sends to other nodes of the communication network a list of adjacent operational communication channels (data from the table of the current state of the logical structure).

When a communication node receives information about appeared or disappeared communication channels (a list of adjacent operational communication channels presented in the table of the current state of the logical structure of the neighboring communication node), this data is entered into its own table of the current state of the logical structure (Fig. 4).

Thus, each router of the communication network knows the state of the channels of the entire communication network.

1.5 Rebuild the graph reflecting the logical structure of the communication network (Fig. 1, block 6).

A graph is a model of a communication network that reflects its structure at the level of mutual relations of nodes and communication lines and is traditionally used to determine optimal routes.

A graph reflecting the logical structure of a communication network is a model of a communication network that reflects not the physical connection of communication nodes, but their relationship (interaction) at the logical level.

The logical level of interaction reflects the functionality/inoperability of the software component of the communication nodes, i.e. correctness/incorrectness of their mutual configuration, correct/incorrect operation of applications, absence/presence of cyber attacks, etc.

The construction of a graph reflecting the logical structure of a communication network, based on data in the table of the current state of the logical structure, can be carried out graphically by connecting those vertices if the communication lines between the nodes reflecting them are in working condition.

1.6 Check whether the logical structure of the network has changed.

1.7 If the logical structure of the communication network has changed, then control is transferred to block 8 (Fig. 1) to perform procedures for searching for optimal routes for the new structure, otherwise control is transferred to block 3 (Fig. 1) to re-perform procedures for assessing the state of the logical structure of the communication network .

1.8 If the logical structure of the communication network changes, the records in the formed memory area are checked (Fig. 1, block 8).

At each communication node (router), during the entire operation of the network T , data about the current logical structure of the communication network, presented in the form of a graph, as well as data about past logical structures and optimal routes corresponding to them are recorded and stored in the generated memory (Fig. 2 ).

Checking the entries in the generated memory area is carried out by searching for a match between the current logical network structure and the entries in the “Logical network structure” column.

If there is a record, then control is transferred to block 9 (Fig. 1) to retrieve from memory the routes that are optimal for the current logical structure, otherwise (there is no record), control is transferred to block 12 (Fig. 1) to determine the routes that are optimal for the current logical structure .

1.9 If there is a record, then routes are selected as the required routes from the list of optimal routes stored in memory corresponding to the current state of the logical structure of the communication network (Fig. 1, block 9).

The state counter of the logical structure is increased by one (Fig. 1, block 10) and the records in the memory area are sorted in descending order (Fig. 1, block 11).

Increasing the counter and sorting records is carried out to move records about the most frequently appearing logical structures to the beginning of the table, which reduces the time of their search.

1.10 If there is no record, then the optimal routes for the current logical structure of the communication network are determined (Fig. 1, block 12). Determining routes can be carried out either by the Dijkstra algorithm traditionally used in the OSPF protocol or by any other [M. Needham, E. Hodler Graph algorithms. Practical implementation on the Apache Spark and Neo4j platforms. / lane from English V. S. Yatsenkova - M.: DMK Press, 2020. - 258 p.: ill.].

After determining the optimal routes, add a corresponding record about the current state of the logical structure of the communication network and a list of determined optimal routes to the generated memory (Fig. 1, block 13) and set the counter value to zero (Fig. 1, block 14). Saving certain routes in memory is carried out for their use during further operation of the communication network in the event of a reappearance of the logical structure of the communication network.

In this case, the least frequently occurring records (records with the lowest counter value) are deleted if their number exceeds m log n , where m is the number of communication lines, and n is the number of communication nodes.

Certain routes are used as search routes (Fig. 1, block 15).

1.11 Thus, in blocks 12, 15 (Fig. 1), routes are searched in the traditional way, which consists in determining optimal routes every time the logical structure of the communication network changes. In turn, actions directly aimed at solving a technical problem and achieving a technical result (Fig. 1, blocks 1, 4, 7, 8, 9, 10, 11, 13, 14) generally consist in storing logical structures formed during the operation of the network and optimal routes determined for them, evaluate the logical structure, use certain optimal routes stored in memory again in the event of a repetition of the logical structure of the communication network.

The effectiveness of the claimed method can be assessed as follows.

The technical problem is that the communication network remains inoperative for a long time.

In fig. Figure 5 shows a chronological diagram of changes in the state of the communication network. Thus, the time the communication network remains in an inoperative state ( Tner ) consists of the time of measuring the state of communication channels (tmeas _{. )} , the time of disseminating information about the state of communication channels ( tdisc _. ) and the time of searching for optimal routes ( tsearch _. ) for the current logical communication network structures:

Time intervals t _meas. and t _dist. both in the prototype method and in the claimed method remain unchanged. A parameter that influences the achievement of a technical result is the search time for optimal routes t _search.

Since in both cases the number of procedures for searching for optimal routes is the same, the efficiency can be assessed based on a comparison of the computational complexity of algorithms for finding Dijkstra's shortest paths, on the one hand, and searching for an entry in a list, on the other.

The fairness of this assessment is based on the direct connection between the number of operations performed in a procedure (computational complexity), the execution time of the procedure and the amount of electricity spent on it (in the case of using non-volatile memory).

The computational complexity of Dijkstra's algorithm used in the prototype method is O(n ² ) with its classical implementation and m log n with its optimized implementation, where m is the number of graph edges, and n is the number of graph vertices [V.A. Kozmidiadi, A.N. Maslov, N.V. Petri Complexity of calculations and algorithms Mir Publishing House, 1974, - 392 pp.].

The computational complexity of searching for an element in an array is O(l) , where l is the number of entries in the array [V.A. Kozmidiadi, A.N. Maslov, N.V. Petri Complexity of calculations and algorithms Mir Publishing House, 1974, - 392 pp.].

Considering the limitation on the number of records stored in memory l < m log n , the number of operations performed when searching for optimal routes in memory, and, consequently, the time spent ( t _search. ) and the energy spent will be less than when they are re-calculated, according to prototype method.

2. In the variant of the method of routing in a communication network with a high probability of failures of its elements, before operating the communication network, all possible options for its logical structure are formed, optimal routes are determined for each option of the logical structure, all possible options for the logical structure of the communication network and the optimal routes determined for them are recorded. into the formed memory areas.

Since logical relationships between communication nodes can only be based on established physical relationships, the graph of the logical structure of a communication network is always a subgraph of the physical structure, or at least identical to it.

Preliminary calculations can further reduce the time required to find optimal routes.

3. In another version of the routing method in a communication network with a high probability of failures of its elements, records in the memory area are not sorted by the counter value, and only data about the state of the logical structure of the network and optimal routes that differ from previous records is written into the formed memory area.

Since changes in the logical structure of a communication network, as a rule, occur gradually, data that includes complete information about the logical structure of a communication network after each change is redundant.

Storing the basic logical structure and features that characterize its changes makes it possible to reduce the redundancy of stored data and, consequently, the required amount of memory at communication nodes.

4. In the third version of the method of routing in a communication network with a high probability of failure of its elements, actions to determine optimal routes and store data about them are performed on a limited selection of communication nodes, and the receipt of optimal routes by the remaining communication nodes is carried out by distributing them.

Since data on the state of the logical structure of the communication network and the optimal routes corresponding to this structure, stored at communication nodes, are largely duplicated, centralizing their storage makes it possible to reduce the required total amount of memory on the communication network.

Thus, the claimed method of routing in a communication network with a high probability of failures of its elements by reducing the time it takes to find optimal routes in the communication network, and therefore reducing the time the communication network is in an inoperative state, makes it possible to increase the stability of the communication network, as well as increase the energy efficiency of its elements . The technical result has been achieved.

Claims (4)

1. A method of routing in a communication network with a high probability of failure of its elements, which consists in measuring the state of communication channels between adjacent nodes of the communication network, using the flooding method to distribute information about the state of adjacent communication channels between all nodes of the communication network, building a graph reflecting the logical structure of a communication network; during the operation of a communication network, with a given period, the state of communication channels between adjacent nodes of the communication network is measured; when the state of communication channels changes, information about the appeared or disappeared communication channels is disseminated using the flooding method; the graph is rebuilt at each communication node , reflecting the logical structure of the communication network, characterized in that at each communication node a memory area is formed, structured to store no more than m log n associated records about the state of the logical structure of the network, lists of optimal routes and counters of the state of its logical structure, in During the operation of the network, when the state of communication channels changes, they check whether the logical structure of the network has changed; when the logical structure of the communication network changes, they check the records in the generated memory area; if there is a record for the current state of the logical structure, then select routes from the list stored in memory as the required routes optimal routes corresponding to the current state of the logical structure of the communication network, increase the state counter of the logical structure by one, sort the records in the memory area in descending order of the state counter of the logical structure of the communication network; if there is no record for the current state of the logical structure, then determine the optimal routes for the current logical structure structures of the communication network, add to the memory area a record about the current state of the logical structure of the communication network and a list of certain optimal routes, set the value of the logical structure state counter to zero, and select certain routes as the required routes. 2. The method according to claim 1, characterized in that before operating the communication network, all possible options for its logical structure are formed, optimal routes are determined for each option of the logical structure, all possible options for the logical structure of the communication network and the optimal routes determined for them to the formed areas are recorded. memory. 3. The method according to claim 1, characterized in that the records in the memory area are not sorted by the counter value, and only data about the state of the logical structure of the network and optimal routes that differ from previous records is written into the formed memory area. 4. The method according to claim 1, characterized in that the actions to determine optimal routes and store data about them are performed on a limited selection of communication nodes, and the receipt of optimal routes by the remaining communication nodes is carried out by distributing them.