FR3003108A1 - REDUNDANT COMMUNICATION NETWORK FOR AIRCRAFT - Google Patents

Abstract

The internal communication network (10) of an aircraft between several entities (11, 12, 21, 22) grouped into at least two channels, the entities of the same channel being fed by the same power supply network (31, 32) comprises a set of network switches (41, 42) through which the entities are connected to communicate with each other, two entities of the same channel being interconnected through at least two different network switches. The same network switch (41, 42) provides the connection between two entities of the same channel and the connection between them of two entities of another path.

Description

The present invention relates to an internal communication network of an aircraft between several entities grouped into at least two channels, the entities of the same channel being fed by the same power supply network, comprising a set of network switches through which the entities are connected to communicate with each other, two entities of the same channel being interconnected through at least two different network switches. Some Integrated Modular Avionic (IMA) integrated avionics platforms use a network compliant with the ARINC 664 Part 7 standard.

These networks allow communication between the connected entities that respect constraints in terms of transit time, segregation, static routing of the various information flows and availability. This availability is ensured in particular by several power supply paths of the equipment connected to the network and by a complete redundancy of the information transmission channels. In order to ensure complete redundancy of the network, each entity has two network connection interfaces which are connected to two distinct subnetworks. Each subnet providing redundancy has its own network switches, commonly referred to as "switch" in English. These network switches allow routing of the exchanges between the connected entities. The redundancy as applied in the state of the art allows a high level of network availability, since the loss of a network switch causes no loss of communication, since the entities connected to the lost network switch are also connected. to another network switch, which ensures the communication of information. Similarly, the loss of one power path has no impact on the other entities powered from another power path, these entities being always connected through at least two network switches. The disadvantage of the existing solution is to require a large number of network switches. In particular, the proportion between the number of network switches and the number of connected entities increases as the number of entities is reduced. The presence of two separate network switches to provide the redundant connection of two entities has a negative impact on the mass and volume required for the installation of an integrated modular avionics platform based on an ARINC 664 Part 7 network.

The object of the invention is to propose an internal communication network of an aircraft whose mass and volume resulting from the use of redundant network switches is reduced while preserving the expected levels in terms of performance and safety, know the transit time and segregation of information flows, as well as in terms of availability, namely the robustness to the loss of a network switch or a power path. For this purpose, the subject of the invention is an internal communication network of an aircraft between several entities grouped into at least two channels of the aforementioned type, characterized in that at least one and the same network switch ensures the connection between them of two entities of the same channel as well as the connection between them of two entities of another way. According to particular embodiments, the network comprises one or more of the following characteristics: the network is capable of ensuring routing of the information flows by virtual links, ensuring segregation making it possible to isolate the information flows circulating on the network. - the network complies with the ARINC 664 Part 7 standard; - from the same switch, the entities of the same channel are connected only between them; at least one network switch is connected for its power supply to the supply network to which the entities of the corresponding channel are connected; - At least one network switch is connected for its power supply, through a switching member to one or more other power networks; the network switches are interconnected by a single inter-channel link; the network switches are interconnected by inter-channel links; the or each inter-channel link connects parts of the switches to which different channel entities are connected; said network comprises entities grouped into two pairs of channels, the entities of the same channel being fed by the same power supply network, the same network switch ensures the connection between them of two entities of the same channel as well as the connection between them of two entities of the other channel of the same channel pair, and inter-pair links ensuring the connection between them of network switches to which are connected entities of different channel pairs; and said network comprises entities grouped in n channels, n being strictly greater than 2, the same network switch ensures, for the n channels, the connection between them of two entities of the same channel.

The invention will be better understood on reading the description which follows, given solely by way of example and with reference to the drawings, in which: FIG. 1 is a diagrammatic view of an embodiment of a communication network according to the invention; FIG. 2 is a schematic view of the connection of entities of a network according to the invention to the same network switch; Figure 3 is a schematic view of another embodiment of a communication network according to the invention; and FIG. 4 is a schematic view of yet another embodiment of a communication network according to the invention. The network 10 illustrated in FIG. 1 is a network that complies with the ARINC 664 Part 7 standard. In particular, this network implements a segregation of information flows circulating on the network making it possible to isolate these flows from each other.

For this purpose, it implements, as known per se, virtual links acting for a given information flow, such as the virtualization of a physical link on the ARINC 664 Part 7 shared network. These virtual links are known under the following conditions: naming "virtual links" in English. The network 10 comprises four entities or subscribers 11, 12; 21, 22. These entities are sensors, actuators or computers used for the operation of the aircraft. The entities 11, 12 belong to a first channel, that is to say that they are supplied with electrical energy from a first power supply network 31. The entities 21, 22 belong to a second channel powered by a power supply network. 32. The supply networks 31 and 32 are independent. The network 10 includes two network switches 41, 42 for providing a physical connection in pairs between entities of the network to ensure communication of information between these entities. As known per se, a network switch is a device that connects several segments (cables or fibers) that can create virtual circuits. This is most often a case having several ports, for example 24 in number as shown in Figure 2. The network switch is able to determine the destination port of information according to the address to which information is intended. The network switch 41 is considered to be part of the first channel. It is connected for its power supply to the network 31. The network switch 42 is connected to the supply network 32.

To ensure redundancy of the power supply, the network switch 41 is also connected to the supply network 32 by a contactor 51 or any other switching element and symmetrically, the network switch 42 is connected for its supply to the supply network 31 by a contactor 52 or any other switching member. The contactors 51 and 52 are normally open and are adapted to be closed in case of breakage of the supply network 31, 32 normally supplying power to the network switch 41, 42 respectively. Thus, the network switch 51 may be closed in case the network switch 52 may be closed in the event of power failure of the network 32. As a variant, the contactors 51 and 52 are physically integrated with the switches 41 and 42. In accordance with the ARINC standard 664 Part 7, each entity 11, 12, 21, 22 has two communication interfaces. Each entity is connected by one of these interfaces to the network switch 41 and through its other interface to the network switch 42. Each entity of a channel is thus connected to another entity of the same channel both through the switch. network 41 and the network switch 42. More precisely, the entities 11 and 12 are connected to each other through a first portion 41A, 42B of the network switch 41 and the network switch 42 respectively. entities 21 and 22 are connected to each other, on the one hand, through a second portion 41B of the network switch 41, and on the other hand, through a second portion 42A of the network switch 42. Under these conditions, each network switch provides the connection between two entities of the same channel and the connection between them of two entities of the other channel. Preferably, in a portion 41A, 41B, 42A, 42B of a network switch, the entities of the same channel are connected only between them. Advantageously, the entities 11, 12 of the first channel on the one hand and the entities 21, 22 of the second channel on the other hand, are not interconnected through the network switches 41, 42. The ports forming each part of the switch are for example assigned to one or the other of the parts according to their proximity to each other so as to facilitate the wiring of each part of the switch. Each part of the switch may have a different number of ports from the other party depending on the nature and number of entities in each channel.

With such an arrangement, it is conceivable that each entity is connected to another entity through two separate network switches, but the network switches are all shared to ensure in their first part 41A, 42B links between the entities of the channel 1 and in their second part 42A, 418 of the links between the entities of the channel 2. As a result, the number of network switches, and therefore the volume occupied by them, as well as the mass of the set of network switches are reduced compared to the state of the art where four network switches are implemented, while maintaining the same robustness to the loss of a network switch, since the communication between two entities is always provided by the other network switch. Likewise, in case of loss of a supply channel, the entities of the always-fed channel can communicate, even in the absence of the additional supply lines via the contactors 51 and 52. The additional supply lines via contactors 51 and 52 make it possible to keep two network switches fully functional for communication if the other channel has lost power. Alternatively, inter-channel links 63, 64 are provided between the network switches 41 and 42 to provide communication between the entities of the two channels if necessary. The first and second corresponding portions, 41A, 42A on the one hand, and 41B, 42B on the other hand, of the two network switches are connected together to provide redundancy for inter-channel communications. As a variant, only a single inter-channel link for example 63 is provided and the flows between the first parts of the two network switches on the one hand, and the second parts of the two network switches on the other hand, are conveyed on the same single link by being routed over different virtual links according to the parts of the network switches concerned. The existence of two inter-channel links 63, 64 physically connected each to the ports corresponding to them has the advantage of facilitating the certification of the device and can also prevent the inter-channel link becomes a bottleneck. In Figure 2 is illustrated an example of a network switch 41 having 24 input channels. As known per se, the network switch comprises a supply circuit 65, a processing unit 66 and a memory 67, in which are stored the connections provided between the different ports. The processing unit 66, as known per se, is able to ensure the routing of the information between the entities, following a connection table stored in the memory 67, this table containing the addresses of the entities with the corresponding ports.

In the example illustrated in FIG. 2, the network comprises, in addition to the entities 11, 12, 21 and 22 illustrated in FIG. 1, additional entities 71, 72 belonging to the channel 1 and additional entities 81, 82 belonging to In this figure, virtual links segregating between these links are illustrated by way of example. A first virtual link 91 provides the connection between the entities 11, 12 and 71. A second virtual link 92 provides a link between the entities 71, 72. Thus, the entity 71, connected to a single port, participates through this entity. port to two segregated virtual links 91 and 92.

Similarly, a virtual link 93 is illustrated between the entities 21, 81 and 82, and a second virtual link 94 exists between the entities 82 and 22. In FIG. 3 is illustrated a network 100 comprising four entity channels grouped two two in two pairs of channels forming two sub-networks 101 and 102, each identical to the network 10 of Figure 1. The elements constituting the subarray 101 take the references of the corresponding elements of Figure 1 increased by 100 while the elements of the subnet 102 have the same references increased by 200. The entities of the four channels are separate entities and are not redundant entities from each other. In order to ensure communication between the entities connected to the supply networks 131, 132 on the one hand, and the entities connected to the supply networks 231, 232 on the other hand, a first inter-pair link 301 exists between the first portions 142A, 241A network switches 142 and 241, while a second link 302 exists between the second portions 141B, 242B network switches 141 and 142. It is thus conceived that to reduce the number of network switches, while ensuring a redundancy according to the ARINC 664 Part 7 standard, the network switches are advantageously shared between entities of only two channels. Thus, the same network switch provides the connection between entities of only two channels. Alternatively and to further reduce the number of network switches, for a network having n communication channels, it is possible to use each switch by operating each n-switch if the number of ports of the switch allows it. The same network switch ensures, for the n channels, the connection between them of the entities of the same channel. Preferably, the number of switches is then reduced to 2.

Thus, in the case of four channels, as illustrated in FIG. 4, two network switches denoted 441 and 442 respectively group the network switches 141 and 241 on the one hand and the network switches 142 and 242 on the other hand. The network switch 141 groups the four parts 141A, 141B, 241A, 241B of the network switches 141 and 241 while the network switch 442 groups together the four parts 142A, 142B, 242A, 242B of the network switches 142 and 242.5.

Claims (11)

CLAIMS1.- Communication network (10; 100) internal of an aircraft between several entities (11, 12, 21, 22; 111, 112, 121, 122, 211, 212, 221, 222) grouped in at least two ways , the entities of the same channel being fed by the same power supply network (31, 32; 131, 132, 231, 232), comprising a set of network switches (41, 42, 141, 142, 241, 242) through which the entities are connected to communicate with each other, two entities of the same channel being interconnected through at least two different network switches, characterized in that at least one network switch (41, 42; 141, 142, 241, 242) provides the connection between two entities of the same channel and the connection between them of two entities of another path. 2.- communication network according to claim 1, characterized in that the network is adapted to provide routing of information flows by virtual links, ensuring segregation to isolate the flow of information flowing on the network. 3.- communication network according to claim 2, characterized in that the network complies with the standard ARINC 664 Part 7. 4. Communication network according to any one of the preceding claims, characterized in that from the same switch, the entities of the same channel are connected only between them. 5. Communication network according to any one of the preceding claims, characterized in that at least one network switch (41, 42; 141, 142, 241, 242) is connected for its supply to the power supply network (31). , 32; 131, 132, 231, 232) to which the entities of the corresponding channel are connected. 6. Communication network according to claim 5, characterized in that at least one network switch (41, 42; 141, 142, 241, 242) is connected for its power supply, through a switching member (51). , 52; 151, 152; 251, 252) to one or more other supply networks (31, 32; 131, 132, 231, 232). 7. Communication network according to any one of the preceding claims, characterized in that the network switches (41, 42; 141, 142, 241, 242) are interconnected by a single inter-channel link. 8. Communication network according to any one of claims 1 to 6, characterized in that the network switches (41, 42; 141, 142, 241, 242) are interconnected by inter-channel links (63, 64, 163, 164, 263, 264). 9. Communication network according to claim 4 and claim 7 or 8 taken together, characterized in that the or each inter-channel link (63, 64; 163, 164; 263, 264) connects parts of the network switches ( 41, 42; 141, 142, 241, 242) to which entities of different paths are connected. 10 - communication network according to any one of the preceding claims, characterized in that it comprises entities (111, 112, 121, 122, 211, 212, 221, 222) grouped into two pairs of channels, the entities of the same channel being fed by the same power supply network, the same network switch ensures the connection between them of two entities of the same channel as well as the connection between them of two entities of the other channel of the same pair of channels and in that it comprises inter-pair links (301, 302) interconnecting network switches (141, 142, 241, 242) to which entities of different channel pairs are connected. 11 - communication network according to any one of claims 1 to 9, characterized in that it comprises entities (111, 112, 121, 122, 211, 212, 221, 222) grouped in n channels, n being strictly greater than 2, in that the same network switch (441, 442) provides, for the n channels, the connection between them of two entities of the same channel. 25