RU2653242C1 - Method of distributing packets in digital communication network with heterogeneous toroidal topological structure - Google Patents

Abstract

FIELD: information technology; communication.

SUBSTANCE: invention relates to communication and can be used for the construction of packet switched digital communication networks (DCN), in switching systems for constructing switching fields of automatic telephone exchanges, computer networks, microprocessor systems, supercomputers. Method comprises steps of receiving a packet by the current switching node from the communication channel, extracting from the packet header overhead information, verifying in the extracted overhead information that there is a requirement to facilitate transmission of the packet with a minimum delay, calculating the distance from the current node to the destination node and transmitting the packet to subnet L, for which the distance between neighbouring nodes will be the longest among all subnets and will not exceed the calculated distance between the current node and the destination node for each measurement.

EFFECT: technical result is reduced delay in the transmission of packets to the DCN with a heterogeneous toroidal topological structure and higher efficiency of using the bandwidth of communication channels of homogeneous DCN when servicing heterogeneous traffic.

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Description

The invention relates to the field of communication and can be used to build digital communication networks (DSS) with packet switching, in switching systems for constructing switching fields of automatic telephone exchanges, computer networks, microprocessor systems, supercomputers, etc.

Known packet distribution methods implemented in the routing protocols RIP and OSPF and using the Bellman-Ford and Dijkstra algorithms, respectively [Olifer V., Olifer N. Computer networks. Principles, technologies, protocols: Textbook for universities. 5th ed. - St. Petersburg: Peter, 2016. - 992 s]. These methods involve the determination of transmission routes based on the results of determining the shortest paths, taking into account the number of transit sections (RIP) and the state of communications, of which information on the bandwidth of communication channels is primarily used. The disadvantages of these protocols is the need for regular exchange of routing information between nodes, the lack of consideration in determining routes of requirements for delaying packet transmission, which leads to the irrational use of the bandwidth of the DSS communication channels.

This drawback is absent in packet distribution methods in networks with homogeneous topological structures, in which the exchange of service information is completely absent.

The closest in technical essence to the claimed method is a method of packet distribution in networks with a toroidal topological structure ([Baransel, C. Routing in Multihop Packet Swithing networks: Gb / s Challenge / C. Baransel, W. Dobosiewicz, P. Grurzynski // IEEE Network. -1995. - May / June. - P. 38-61], based on one of the routing methods in regular topologies - orthogonal or diagonal. When using orthogonal routing for the packet being processed, the distance between the current node and the destination node is determined one by one (main) measurement; compares e value with zero, if it is not equal to zero, then the packet is transmitted through the output port of this measurement; otherwise, the distance between the current node and the destination node in the second dimension is calculated; if the received distance is not equal to zero, then the transmission packet through the port of the second dimension.With the use of diagonal routing, the processed packet is first transmitted through the nodes in one direction until the distances between the current node and the destination node on the first and second of measures; then the packet is routed in turn through the ports of the first and second dimensions, preserving the equality of the distances between the current node and the destination node in the first and second dimensions, until it is accepted by the destination node. A significant disadvantage of such methods are the large delay values in the transmission of heterogeneous traffic.

The technical result of the invention is to reduce the delay time of packet transmission in a DSS with an inhomogeneous toroidal topological structure and to increase the efficiency of using the bandwidth of communication channels of homogeneous DSS when serving heterogeneous traffic.

The indicated result is achieved by the known method of packet distribution in switching nodes of a digital communication network with a heterogeneous toroidal topological structure, which consists in receiving the current switching node from the communication channel of the packet, extracting service information from the packet header, calculating the distance from the current node to the destination node and the packet is transmitted by the current node in the communication channel of the subnet L, according to the invention, the presence of the requirement to ensure packet transmission with a minimum second delay, if such a requirement packet is transmitted to subnet L, for which the distance between adjacent nodes will be the greatest of all the subnets, and not to exceed the calculated distance between the current node and the destination node along each dimension.

The essence of the invention lies in the fact that in the extracted service information there is a requirement to ensure the transmission of a packet with a minimum delay, if there is such a requirement, the packet being processed is transmitted to the subnets L, for which the distance between neighboring nodes will be the largest of all subnets and not exceed the calculated distance between the current node and destination node for each dimension.

The method can be implemented in switching nodes with a heterogeneous toroidal topological structure of the DSS. In FIG. Figure 1 shows a three-level inhomogeneous toroidal structure of a DSS, consisting of three interconnected (embedded) toroidal homogeneous structures formed by switching nodes (UK) of various types. The type of CC depends on the composition of the communication equipment used and the throughput of the communication channels (CS) formed by it. In turn, the type of asset is determined by the position in the structure and the degree of the peak (the number of communication lines of the incident asset). In FIG. 2a, the topological structure of the first subnet is presented, which includes all CC connected by low-speed CS, and it is characterized by the distance between neighboring nodes Δ ¹ ₁ = Δ ¹ ₂ = 1. In FIG. 2b, the topological structure of the second subnet is presented, which has a structure width of six, is formed by ACs connected by CS with a higher throughput than in the first subnet, and is characterized by the distance between adjacent nodes Δ ² ₁ = Δ ² ₂ = 2. In FIG. 2c, the topological structure of the third subnet is presented, which has a structure width of three, is formed by nine CCs connected by the SC with the maximum possible throughputs, and is characterized by the distance between adjacent nodes Δ ³ ₁ = Δ ³ ₂ = 4.

The method can be implemented by the following algorithm.

Step 1. Accept the packet for processing and transmission.

Step 2. Service information is extracted from the packet header.

Step 3. If it is not necessary to ensure the minimum delay, then the subnet L = 1 is assigned for transmission and go to step 5.

Step 4. If it is necessary to ensure a minimum delay, then determine the subnet for transmission in the following sequence:

Step 4.1 From the packet header, the address of the destination node x _d is determined for each dimension δ ₁ (x _d ), δ ₂ (x _d ).

Step 4.2 The distance between the current node x _c and the destination node x _{d is} calculated:

where the subtraction operation is carried out modulo K; K is the value of the width of the structure of the topology of the subnet L = 1; δ ₁ (x _d), δ ₂ (x _d) - the destination node x _d of the first and second measurements; δ ₁ (x _c ), δ ₂ (x _c ) is the address of the current node x _s in the first and second dimensions, d ₁ , d ₂ is the distance between the address of the destination node x _d and the address of the current node x _c in the first and second dimensions .

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будут наибольшими из всех подсетей, но не превышать вычисленное расстояние d₁ и d₂ между текущим узлом x_c и узлом-адресатом x_d по каждому измерению:Step 4.3 Determine the subnet L for which the distances between adjacent nodes

and

will be the largest of all subnets, but not exceed the calculated distance d ₁ and d ₂ between the current node x _c and the destination node x _d for each dimension:

where N is the set of subnets that make up the heterogeneous toroidal DSS. This operation can be implemented by comparing the distances between neighboring nodes of each subnet with the calculated distance for each dimension.

Step 5. Define a measurement for transmission on L. subnets

Step 6. Transfer the packet in the selected subnet L and according to the selected dimension.

The method can be implemented, for example, using a device, a diagram of which is shown in FIG. 3, where 1 - receiving devices are indicated, 2 - transmission devices, 3 - service information extraction unit, 4 - switching device (switching matrix), 5 - service information analysis unit, 6 - distance calculation unit to the destination node, 7 - block subnet definitions L, 8 - transmission measurement determination unit, 9 - control unit.

The subnet determination unit 7 is designed to determine the subnet L, using information about the distance between the current node and the destination node, the width of the topological structure and the presence of the requirement to ensure the minimum delay for the served packet. The transmission measurement determination unit 8 is intended to determine a measurement number by which a packet will be transmitted based on the diverting or orthogonal routing method used. The control unit 9 is designed to generate switching control signals for the switching device, based on the subnet number and the measurement number for transmission.

The device can be implemented on elements that are widely distributed in the field of electronic and electrical engineering or in software form, based on the processors used in network elements.

The implementation device operates as follows. The receiving device 1 from the communication channel receives the packet and transmits it to the service information extraction unit 3. In the service information extraction unit 3, the service part is extracted from the received packet and sent to the service information analysis unit 5. In the service information analysis unit 5, address information is extracted the recipient node δ ₁ (x _d ), δ ₂ (x _d ) and information about the need to ensure minimum packet transmission delay. This information is typical for a wide range of network protocols [Olifer V., Olifer N. Computer networks. Principles, technologies, protocols: Textbook for universities. 5th ed. - St. Petersburg: Peter, 2016. - 992 s]. The address of the destination node, δ ₁ (x _d ), δ ₂ (x _d ), is transmitted to the input of the distance calculation unit to the destination node 6, and information about the need to ensure minimum delay is transmitted to the first input of the subnet determination unit 7. In the distance calculation unit destination node 6 calculate the distance from the current node to the destination node in both directions d ₁ , d ₂ using expression (1) and transfer it to the second input of the subnet definition block 7, as well as to the input of the transmission measurement number determination block 8. In block definition subnet 7 determine the value of the subnet L, for which The distance between neighboring nodes will be the largest of all subnets and not exceed the calculated distance between the current node and the destination node for each dimension. The determination procedure is based on a sequential comparison of the distances between neighboring nodes of each subnet with the calculated distance for each dimension. Next, the obtained value of L is transmitted to the first input of block 9. In the measurement determination block for transmission 8, using diagonal routing, the measurement number for transmission k is determined based on the following expressions:

In orthogonal routing, the measurement number for transmission k is determined based on:

The obtained values of the measurement number k are transmitted to the second input of the control unit 9. In the control unit 9, on the basis of the received values of the subnet number L and the measurement number k, control signals are generated for switching the output of the i-th unit for extracting service information 3 and the input of the j-th transmission device, corresponding to the calculated values of L and k.

Studies of information exchange in the DSS using simulation models that implement the proposed method showed an increase in throughput of the DSS when transmitting heterogeneous traffic by 10-15% relative to self-routing algorithms in toroidal DSS [Golovchenko EV The routing algorithm in digital communication networks with a toroidal topology. Telecommunications, No. 10, 2012, pp. 12-18].

Claims (1)

A method for distributing packets at switching nodes of a digital communication network with an inhomogeneous toroidal topological structure, which consists in receiving a packet from the communication channel by the current switching node, extracting service information from the packet header, calculating the distance from the current node to the destination node and transmitting the packet to the current node in the communication channel subnets L, characterized in that they check in the extracted service information the presence of a requirement to ensure transmission of a packet with a minimum delay, if there is such a processing requirement yvaemy packet is transmitted on the subnet L, for which the distance between adjacent nodes will be the greatest of all the subnets, and not to exceed the calculated distance between the current node and the destination node along each dimension.

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