• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
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    • 专利摘要:
    An aircraft data network that may include a first remote data concentrator (RDC), a network switch, and a second RDC. The first RDC may receive one or more signal / input signals including data from a transmission system, and translate the data through a network protocol to generate translated data having a format consistent with the network protocol. The network switch may receive the translated data of the first RDC, determine a destination for at least a portion of the translated data, and route at least a portion of the translated data to a first receiving system. The second RDC may receive at least a portion of the translated data of the network switch, converting at least a portion of the translated data to generate converted data having a format adapted for use by the first receiving system, and communicating the converted data to the first reception system.
    公开号:FR3034596A1
    申请号:FR1652657
    申请日:2016-03-29
    公开日:2016-10-07
    发明作者:Charles Michaels
    申请人:Gulfstream Aerospace Corp;
    IPC主号:
    专利说明:

    [0001] BACKGROUND OF THE INVENTION TECHNICAL FIELD [1] Embodiments of the present invention generally relate to an aircraft, and more particularly to data network architectures for an aircraft. BACKGROUND OF THE INVENTION [2] A modern aircraft can include a data network that includes multiple transmission systems that transmit data over the data network to a plurality of different receiving systems that consume the data. Typically, each transmission system is coupled directly to one or more receiving systems via direct wired connections to each of the receiving systems so that each transmission system can transmit data by cable to the receiving systems. receipt to which it is coupled. As such, any receiving system that wants to receive data from one of the transmission systems must be wired directly to that transmission system to receive data from that transmission system. [3] A disadvantage of using direct cable connections between each transmission system and each receiving system is that transmission systems and receiving systems can be located anywhere in the aircraft. For example, some of the transmission systems may be located relatively far from the receiving systems to which they are coupled (eg one system may be located at the front of the aircraft and the other may be located at the rear of the aircraft). of the aircraft). When a receiving system is far away from the transmission systems (and vice versa), the cable runs necessary to wire the receiving system to each transmission system can be significantly long. This not only adds costs and weight to the aircraft but also significantly increases the complexity of manufacturing and maintenance. [4] For safety reasons, an aircraft is usually designed to include one or more redundant version (s) of each transmission system and one or more redundant version (s) of the primary data network that is used to couple each of the redundant transmission systems to the corresponding receiving systems. When redundant data networks are used, the cabling task is further increased. Further, since each data network is generally identical to the primary data network, the presence of redundant data networks does not necessarily guarantee that they will always be available as backup. For example, common failure modes may impact both the primary data network and the redundant data network (s) so that both may have the same (s) operating problem (s) and not working as expected (eg a software bug that impacts both networks).
    [0002] 10051 It is necessary to have an aircraft that includes an improved data network to communicate critical data to different receiving systems placed throughout the aircraft. It would be desirable to eliminate at least a portion of the necessary cabling in such a data network. For example, it would be desirable to reduce the amount and length of cables required to communicately couple each of the different transmission systems to each of the different receiving systems. It would also be desirable to provide alternative paths for the communication of critical data between the different transmission systems and the different reception systems. In addition, other desirable attributes and features of the present invention will become apparent with the following detailed description, as well as the appended claims, taken in conjunction with the accompanying drawings, the foregoing technical field and context.
    [0003] SUMMARY 10061 The disclosed embodiments relate to an aircraft that includes an aircraft data network. The aircraft data network may include a first remote data concentrator (RDC), a network switch, and a second RDC. The first RDC may receive one or more signal / input signals including data from a transmission system, and translate the data through a network protocol to generate translated data having a format consistent with the network protocol. The network switch may receive the translated data of the first RDC, determine a destination for at least a portion of the translated data, and route at least a portion of the translated data to a first receiving system. The second RDC may receive at least a portion of the translated data of the network switch, convert at least a portion of the translated data to generate converted data having a format adapted for use by the first reception system, and communicate the converted data to the translated data. first reception system.
    [0004] BRIEF DESCRIPTION OF THE DRAWINGS [7] Embodiments of the present invention will be described hereinafter with reference to the following figures, in which like numerals denote similar elements, and wherein [8] FIG. 1 is a perspective view of an aircraft in which the disclosed embodiments can be implemented according to a non-limiting implementation. [9] FIG. 2 is a simplified block diagram of an aircraft data network according to one implementation of the disclosed embodiments. [0010] FIG. 3 is a simplified block diagram of an aircraft data network according to another embodiment of the disclosed embodiments. 10011] FIG. 4 is a simplified block diagram of an aircraft data network according to still another implementation of the disclosed embodiments. [0012] FIG. 5 is a simplified block diagram of an aircraft data network 15 according to another embodiment of the disclosed embodiments. DESCRIPTION OF EXEMPLARY EMBODIMENTS [0013] As used herein, the term "exemplary" means "exemplary or illustrative." The following detailed description is purely by way of example and is not intended to limit the invention or the application and uses of the invention. Any embodiment described herein as "exemplary" need not be construed as being preferred to, or advantageous on, other embodiments. All the embodiments described in this Detailed Description are exemplary embodiments provided to enable those skilled in the art to make or use the invention and not to limit the scope of the invention which is defined by the revendications. Furthermore, the intention is not to be constrained by any expressed or insinuated theory presented in the technical field, context, brief preceding summary or the detailed description that follows. [0014] Overview [0015] The disclosed embodiments relate to different aircraft data network architectures that employ double dissimilar networks. These architectures comprise at least one transmission system which is the source of the critical data, and a plurality of reception systems which are the consumers of these critical data. As used herein, the term "critical data" refers to any data used by a receiving system to enable this receiving system 5 to perform communication, navigation or aviation functions. For example, the critical data may be communication data that is used by a receiving system to perform a communication function, navigation data that is used by a receiving system to perform a navigation function; or aviation data that is used by a receiving system to perform an aviation function. For example, critical data may be data provided by a transmission system such as an attitude heading and reference system (AHRS), an inertial reference system (IRS). and / or an air data system (ADS) to a flight computer for providing assistance to aviation functions performed by the flight computer. Alternatively, the critical data may be data provided by a navigation system such as a GPS system to provide assistance to aviation functions performed by a display in the cockpit of the aircraft. Another example would be the VHF radios and HF radios used to perform the communication function between the flight crew and the air traffic control. The critical data is "critical" because if it is absent or erroneous, it may prevent the receiving system from performing its intended communication, navigation or aviation functions. According to the disclosed embodiments, the disclosed aircraft data network architectures also include remote data hubs as well as network switches to help reduce the cabling load in an aircraft data network. Remote data hubs can be distributed in different locations throughout the aircraft. Remote data hubs serve as locations where data from multiple transmission systems can be concentrated to be distributed to the different receiving systems that consume the data. Each of the different receiving systems may be communicatively coupled to one or more of the remote data hubs, so that the receiving system can receive data from both the primary transmission system and any redundant version. of this transmission system. Thus, the same data can be shared by multiple receiving systems (each connected to one of the RDCs) without having to directly wire each individual receiving system to each particular transmission system. In some embodiments, each primary transmission system 5 has one or more redundant transmission system (s) which is another source of critical data and each of the receiving systems that consumes the critical data can receive these critical data of the primary transmission system and each redundant transmission system. When the network includes multiple transmission systems (and thus redundant multiple transmission systems) and a receiving system needs to receive data from each of the multiple transmission systems, the benefits of implementing RDC work becomes even more obvious since the receiving system can receive data from each of the multiple transmission systems and each of the redundant multiple transmission systems through a single RDC. In other words, the receiving system can be communicatively coupled to a RDC and simply receive the data it needs from each of the transmission systems and each of the redundant transmission systems. The receiving system can then compare the data received from one of the transmission systems and its corresponding redundant transmission system to validate the data received from each to ensure that the data is valid. An advantage of the disclosed aircraft data network architectures is that they can eliminate the need to directly interface the transmission systems of an aircraft and each of the receiving systems of the aircraft, and can therefore greatly reduce the wiring that would otherwise be required. This not only reduces manufacturing costs but also reduces the weight of the aircraft. Another advantage of the disclosed aircraft data network architectures is that they can provide dissimilar paths for the same critical data across the aircraft data network. This can reduce / eliminate the possibility of common failure modes. The aircraft receiving systems (which consume the critical data) will have at least two sources for these critical data, and each of the two sources will carry these critical data over dissimilar dissimilar paths. [0023] FIG. 1 is a perspective view of an aircraft 110 in which the disclosed embodiments may be implemented in an exemplary non-limiting manner. Although not shown in FIG. 1, the aircraft 110 also includes various onboard computers, aircraft instrumentation and various control systems which will now be described with reference to FIG. 2-5. The aircraft includes various primary flight control surfaces and secondary flight control surfaces. Each flight control surface typically has one or more actuators for controlling its movements. An actuator control unit transmits control signals to the actuators. The actuators generate signals that control the movement of the different flight control surfaces of the aircraft according to the control signals.
    [0005] 100241 FIG. 2 is a simplified block diagram of an aircraft data network 200 according to an implementation of the disclosed embodiments. The aircraft data network 200 includes a transmission system 220-1, a redundant transmission system 220-2, a first remote data concentrator (RDC) 240-1, a second RDC 240-2, a third RDC 240 3, a network switch 250, a first reception system 280-1, a second reception system 280-2, a third reception system 280-3 and a fourth reception system 280-4. In a non-limiting implementation, it can be assumed that the first RDC 240-1 is placed relatively far from the second RDC 240-2 and the third RDC 240-3. For example, in one implementation, it can be assumed that the first RDC 240-1 is placed at the front of the aircraft and that the second RDC 240-2 and the third RDC 240-3 are placed at the rear of the aircraft.
    [0006] It should be noted that FIG. 2 is a simplified representation of an implementation of the aircraft data network 200 and that in other implementations additional transmission systems, receiving systems, RDCs and network switches may be included. In this regard, in some embodiments, each of the transmission systems 220-1, 220-2 may be different multiple transmission systems. For example, in one embodiment, the transmission system 220-1 may represent transmission systems including, for example, a heading and attitude reference system (AHRS), an inertial center (IRS), and / or an aerodynamic data system (ADS), a communication system, etc. Likewise, in some embodiments, each of the receiving systems 280 may represent multiple, distinct receiving systems. In addition, in some embodiments, each of the RDCs may represent distinct multiple RDCs.
    [0007] In some embodiments, the aircraft data network 200 may include additional transmission systems (not illustrated for simplicity reasons) and the first RDC 240-1 may be coupled to these additional transmission systems. Similarly, the second RDC 240-2 and the third RDC 240-3 can each be coupled to additional receiving systems (not shown for simplicity). In some embodiments, the aircraft data network 200 may include additional RDCs and additional network switches (not shown for simplicity). For example, the network switch 250 may be coupled to additional RDCs (not shown for simplicity). In FIG. 2, the transmission systems 220-1, 220-2 are communicatively coupled to the first RDC 240-1 by a first connection 230-1 and a second connection 230-2, respectively. The receiving systems 280-1, 280-2 are communicatively coupled to the RDC 240-2 via 230-3, 230-4 connections, and the receiving systems 280-3, 280-4 are communicatively coupled to the RDC 240. In one embodiment, the connections 230 may be direct wired connections, and in another embodiment, the RDCs 240 and the network switch 250 may communicate wirelessly, the connections 230 may be wireless communication links. The first RDC 240-1 is communicatively coupled to the network switch 250 by a data bus 245. The network switch 250 is coupled to the second RDC 240-2 by a data bus 245-2 and the third RDC 240-3 by a data bus 245-3. The two transmission systems 220-1, 220-2 send data to the first RDC 240-1. Although illustrated as using a single block in FIG. 2, the transmission system 220-1 may represent several different systems and therefore, the first RDC 240-1 receives different incoming signals from each transmission system. In other words, the incoming signals received by the RDC 240-1 may be different signals from the different transmission systems which are represented by the transmission system 220-1. These different incoming signals can be discrete, analog or digital. As used herein, the term "remote data concentrator (RDC)" may refer to a microprocessor-based control that converts input data from one form to another before they are processed. issue. In one embodiment, a RDC may receive input data (discrete, analog, or digital) from a number of different transmission systems. The RDC can process and reformat the input data into a common digital data format so that it can be communicated over a network. For example, a RDC is a protocol converter that can convert incoming input signals through a network protocol such as EIA / TIA-232, EIA / TIA-422, EIA / TIA-485, ARINC 429, USB 2.0, ARINC-664, MIL-STD1553, CAN bus and Ethernet. In addition, a RDC may receive data that has been converted through the network protocol and convert the converted data back to a form that can be used by the many receiving systems before communicating them to the many receiving systems. In one embodiment, the first RDC 240-1 translates the input data (e.g., converts the data through a network protocol) into translated data so that it can be processed and routed by the network switch 250. The first RDC 240-1 converts the incoming signals through a network protocol (eg, a particular digital bus protocol) into an outgoing composite outgoing signal (or data stream). ) which is suitable for bus 245 (eg, ARINC bus 429 and / or Ethernet data). The outgoing signal is a digital data stream formatted by a particular network protocol. Thus, the first RDC 240-1 "concentrates" the incoming data into an outbound signal that includes all the translated data. The first RDC 240-1 communicates the translated data to the network switch 250 via the bus 245-1. Some of this translated data is destined for the reception system 280-1 and some of this translated data is destined for the other reception system 280-2. In other embodiments, where the network switch 250 and one or both RDC 240-2, 240-3 are not employed, the first RDC 240-1 may be directly connected to one or both In such embodiments, the first RDC 240-1 can perform additional functionality for converting incoming signals from the transmission systems 220 so that the data received by transmission are converted to an appropriate type or signal format (eg, data word type) that is used by (or required by) the aircraft receiving systems 280 (eg, which can be read and processed by the reception systems 280 of the aircraft) before communicating them to the various reception systems. In other words, if required, the first RDC 240-1 can reformat the data received from the transmission systems 220 into a data type needed by each receiving system 280, and communicate this data directly to the receiving system. 280 appropriate. For example, in one embodiment, the first RDC 240-1 may have loaded configuration files that describe the transmission system and the receiving system for certain data and how these data are to be processed and reformatted before send them to the intended receiving system. [0032] Referring now to the specific implementation shown in FIG. 2 (which employs the network switch 250 and RDCs 240-2, 240-3), it will be appreciated that the term "network switch" may refer to a networking device that connects the aircraft systems together and performs switching functions with respect to data communicated between these devices. A network switch receives incoming data, processes it, and forwards the processed data along a path to its intended destination. In FIG. 2, the network switch 250 is configured to: read the translated data, determine their destination and a path to that destination (e.g., a particular reception system), and route the translated data along a path to the destination appropriate destination. In this embodiment, at least a portion of the translated data is routed to the second RDC 240-2 and the third RDC 240-3. The second RDC 240-2 and the third RDC 240-3 each translate (or convert) the data received from the network switch 250 into a signal type or format (e.g., data word type) which is used by the aircraft reception systems 280 (eg, which can be read and processed by the aircraft reception systems 280). The second and third RCDs 240-2, 240-3 can receive data that has been converted through the network protocol and convert the converted data back to a form that can be used by the different receiving systems before communicating them to the data carriers. different reception systems. In other words, the second RDC 240-2 and the third RDC 240-3 reformat the data received from the network switch 250 into a data type necessary for each receiving system, and communicate this data directly to the appropriate receiving system. For example, in one embodiment, the second RDC 240-2 and the third RDC 240-3 each have loaded configuration files that describe the transmission system and reception system for certain data and how these data should be. processed and reformatted before sending them to the intended receiving system. A problem with this particular architecture is that the RDCs 240 and the network switch 250 must each function properly as they are the only links along a path between a particular transmission system 220 and a particular reception system 280. . If one of the RDCs 240 or the network switch 250 malfunctions or fails for any reason, the receiving systems may not receive the data being communicated by the transmission systems. 220. This can be important especially when the data being communicated by the transmission systems 220 are "critical" data. Another problem with this particular architecture is that RDCs 240 and Network Switches 5 (if many are present) may be subject to a common failure mode (eg RDC 240 could also be subject to a common software bug) where all RDCs 240 or network switches do not work as expected (eg, communicate the data to the wrong receiving system). [0035] To address these issues with the aircraft data network 200, in one embodiment, additional transmission systems, receiving systems, RDCs, and network switches are included for redundancy. In other words, a separate network is provided which includes a redundant network switch (not shown) similar or identical to the network switch 250 and redundant RDCs (not shown) similar or identical to the RDC 240-1, 240-2, 240 -3 for providing two alternative paths 15 for the data that is communicated between the transmission systems 220 and the reception systems 280. In one embodiment, a redundant network switch (not shown) is provided which is identical to the Network switch 250 and redundant RDCs (not shown) are provided, which are identical to RDC 240-1, 240-2, 240-3 to provide two alternative alternative paths for data that is communicated between transmission systems 220 and receiving systems 280. In another embodiment, a redundant network switch (not shown) is provided, which is similar to the network switch 250 and redundant RDCs. s (not shown) are provided, which are similar to RCDs 240-2, 1-240, 240-3 for providing two alternative alternative paths for data that is communicated between the transmission systems 220 and the receiving systems 280 To reduce the likelihood of common failure modes, the redundant network switch (not shown) and the redundant RDCs (not shown) function similar to the network switch 250 and RDC 2401, 240-2, 240-3 except that the Redundant network switch (not shown) and redundant RDCs (not shown) employ different hardware and / or software in comparison to network switch 250 and RDC 240-1, 240-2, 240-3, respectively. Such an implementation will be described below with reference to FIG. 4. In addition, in other embodiments which will be described with reference to FIG. 5, network switches and multiple RDCs may be implemented such that there are distinct multiple paths for the data that is communicated between the transmission systems 220 and the reception systems 280. [0036] It is desirable to provide other architectures that can provide alternative paths for communication of critical data to protect against common failure modes along the primary path between the transmission systems 220 and the receiving systems 280. According to one embodiment, these alternative paths may be provided as shown in FIG. 3. According to one embodiment, these alternative paths may be provided as shown in FIG. 4. [0037] FIG. 3 is a simplified block diagram of an aircraft data network 300 in accordance with another embodiment of the disclosed embodiments. The aircraft data network 300 of FIG. 3 comprises the same blocks, components or elements as the aircraft data network 200 of FIG. 2. In FIG. 3, the same blocks, components or elements are identified with corresponding reference numbers but with a series of numbers 300 instead of a series of numbers 200. The description of each element of FIG. 2 applies to the same blocks, components or elements of FIG. 3. For brevity, the description of each of the elements in FIG. 3 will not be repeated. This embodiment differs from FIG. 2 in that it also comprises a plurality of direct wired connections 325-1 ... 325-4 for the communication data (e.g., critical data) of the transmission systems 320 to the receiving systems 380-1, 380-2. Although not illustrated for the sake of clarity, it will be understood that additional direct wired connections may also be provided between the receiving systems 380-3, 380-4 and the transmission systems 320. The direct wired connections 325-1. .225-4 provide alternative paths for data that are not subject to the same failure modes as the paths illustrated in FIG. 2. For example, if one of the 25 RDC 340-1 or 340-2 is not operating as expected, then the data that was supposed to be routed by these RDCs to the receiving systems 380-1, 380-2 can still be provided via one of the direct cable connections 325-1 ... 325-4 between the transmission systems 320 and the receiving systems 380-1, 380-2. A disadvantage of this approach is that because of the locations of the transmission systems 320 and the reception systems 380 on the aircraft, the lengths of some of the cables or all the cables used to implement the cable connections. Direct 325-1 ... 325-4 between the transmission systems 320 and the reception systems 380 may be important. For example, the direct cable connections 325-1 and 325-4 may be used to communicate data of the transmission systems 320-1, 320-2 directly to the receiving system 380-1, but need to be routed between the transmission systems 320-1, 320-2 to the receiving system 380-1. This can add significant weight to the aircraft among other technical problems related to directly wiring two systems that can be placed far apart in the aircraft. Thus, it would be desirable to provide an alternative architecture that can help address these issues and help eliminate some of the wiring that would be required. [0040] FIG. 4 is a simplified block diagram of an aircraft data network 400 according to yet another embodiment of the disclosed embodiments. The aircraft data network 400 comprises a transmission system 420-1, a redundant transmission system 420-2, a first remote interface unit (RIU) 432-1, a second RIU 432-2 , a third RIU 432-3, a first remote data concentrator (RDC) 440-1, a second RDC 440-2, a third RDC 440-3, a network switch 450, a first reception system 480-1, a second reception system 480-2, a third reception system 480-3, a fourth reception system 480-4 and a processing unit 495. The aircraft data network 400 of FIG. 4 comprises the same blocks, components or elements as the aircraft data network 200 of FIG. 2. In FIG. 4, the same blocks, components or elements are identified with corresponding reference numbers but with a series of numbers 400 instead of a series of numbers 200. The description of each element of FIG. 2 applies to the same blocks, components or elements of FIG. 4. For brevity, the description of each of the elements in FIG. 4 will not be repeated. Unlike FIG. 2, the aircraft data network 400 of FIG. 4 comprises a first RIU 432-1, a second RIU 432-2 and a processing unit 495.
    [0008] Each of the RIUs may perform the same functions or functions similar to those of a RDC and the processing unit 495 may perform the same functions or functions similar to those of a network switch. In one embodiment for reducing the probability of common failure modes, the processing unit 495 is "dissimilar to the network switch 450 and the remote interface units 432 are" dissimilar to the RDCs 440-1, 440-. 2, 440-3. For example, in one implementation, these redundant components are dissimilar in that they can implement hardware and / or software different from the network switch 450 and the RDC 440. For example, the RIU 432 may include hardware and / or software that is different from the hardware and / or software of RDC 12 3034596 440. This dissimilarity is important because it helps to ensure that similar components (eg RDC 440 and RIU 432) in each path are not necessarily subject to the same failure modes or operational errors. For example, faulty operation of the network switch 450 does not necessarily affect the operation of the processing unit 495, and faulty operation of the RIUs 432 does not necessarily affect the operation of the RDCs 440. As such, two alternative dissimilar paths are provided for the critical data so that they can reach the appropriate receiving system in the event that a communication path does not work as intended. [0043] In FIG. 4, the transmission systems 420 also send signals that include critical data to the first RIU 432-1. The first RIU 432-1 receives input signals including the critical data and translates (or converts) the critical data through a network protocol to generate translated critical data having a format consistent with the network protocol. The processing unit 495 is communicatively coupled to the first RIU via a bus, and the first RIU 432-1 sends the translated critical data to the processing unit 495 over the bus. The processing unit 495 performs functions similar to the network switch 450 except that the processing unit 495 receives only the "critical data" communicated by the transmission system (s), while the switch network 450 receives all the data communicated by the transmission system (s). For example, the processing unit 495 receives the translated critical data from the first RIU 432-1, processes it to determine appropriate destinations (eg, 480-1, 480-2, 480-3, 480 receiving system). -4) for the translated critical data, then routes the critical data translated correctly to the correct RIUs 432-2, 432-3 based on the one that is in communication with the correct destination. As such, the processing unit 495 also performs switching functions to ensure that certain translated critical data is communicated to the correct RIUs 432-2, 432-3. The processing unit 495 is a different type of switch that performs functions similar to the network switch but is "dissimilar" in that it is not subject to the same failure modes as the network switch 450. For example, the processing unit 495 may include hardware and / or software different from the network switch 450. The second RIU 432-2 receives at least a portion of the critical data translated from the processing unit 495 (e.g. , the translated critical data that is 3034596 for the 480-1, 480-2 receiving systems and any other receiving system to which the second RIU 43-2 is coupled). The second RIU 432-2 converts the translated critical data it receives to generate converted critical data having a format adapted for use by the first reception system 480-1 and a format adapted for use by the second reception system 480-1. receiving 480-2 (and any other receiving system (not shown) to which the second RIU 43-2 is coupled). For example, the second RIU 432-2 may convert the translated critical data to converted critical data having the type of signal (eg, format) used by, or necessary for, the 480-1, 4802 receiving systems. RIU 432-2 communicates critical data converted through 10 different signals to the 480-1, 480-2 receiving systems. Thus, the aircraft data network 400 of FIG. 4 allows multiple receiving systems to be coupled to a single RIU and eliminates the need for direct wired connections between each of the transmission systems 420 and the receiving systems 480. This reduces the amount of wiring on the aircraft. In addition, the first RIU 432-1, the processing unit 495 and the second RIU 432-2 provide an alternative communication path for communicating the critical data between the first transmission system 420-1 and the receiving system. 480-1, 480-2. This alternative communication path (provided by the first RIU 432-1, the processing unit 495 and the second RIU 432-2) is dissimilar to the communication path provided by the first RDC 440-1, the network switch 450, and the second DRC 440-2. To explain in more detail, since alternative communication paths for critical data comprise different components, they are dissimilar. This dissimilarity is advantageous in that the processing unit 495 is not subject to the same failure modes as the network switch 450 (eg software parasites and bugs, certain hardware failures such as software design errors or not found in the verification tests), and in that the RIUs 432 are not subject to the same failure modes as the RDCs 440-1, 440-2. As such, the risk of common failure modes can be reduced and / or eliminated. Although not illustrated, the aircraft data network 400 may include additional processing units (such as 495) and RIU (such as RIU 432-2) to perform similar functions with respect to the receiving systems 480. -3, 480-4. Further, it will be appreciated that the processing unit 495 can be communicatively coupled to a plurality of additional RIUs (not shown) which are communicatively coupled to additional receiving systems (not shown). For example, the processing unit 495 may be communicatively coupled to the RIU 432-3. In addition, although not illustrated, additional receiving systems may be coupled to each of the additional RIUs. For example, the RIU 432-3 can be communicatively coupled to other reception systems that are not illustrated for simplicity. Example of Implementation of Critical Data Communication Between Transmission and Reception Systems [0048] FIG. 5 is a simplified block diagram of an aircraft data network 500 according to another implementation of the disclosed embodiments. The aircraft data network 500 of FIG. 5 includes transmission systems, Remote Interface Units (RIUs) 532, Remote Data Hubs (RDCs) 540, network switches 550 and receiving systems 580. The aircraft data network 500 of FIG. FIG. 5 comprises the same blocks, components or elements as the aircraft data network 200, 300, 400 of FIGS. 2-4, respectively. In FIG. 5, the same blocks, components or elements are identified with corresponding reference numbers but with a series of numbers 500 instead of a series of numbers 200, 300 or 400. For example, the RDCs 540 correspond to in DRC 240 of FIG. 2, at DRC 340 of FIG. 3 and RDC 440 of FIG. 4, while the RIU 532 would correspond to the RIU 432 of FIG. 4, and the network switches 550 would correspond to the network switches 250, 350, 450 of FIGS. 2-4, respectively. In FIG. 5, multiple RDC blocks are shown together (e.g., RDC 540-1, 540-3) at the same location in the drawings; however, this does not mean that they are placed close to each other. For example, the RDC 540-3 can be placed in a different part of the aircraft than the RDC 540-1. For example, the RDC 540-1 could be placed near the front of the aircraft, while the RDC 540-3 could be placed near the rear of the aircraft. Likewise, multiple RDC blocks are shown together (e.g., RIU 532-1, 532-3) at the same location in the drawings; however, this does not mean that they are placed close to each other. For example, the RIU 532-3 can be placed in a different part of the aircraft than the RIU 532-1. For example, RIU 532-1 could be placed near the front of the aircraft, while RIU 532-3 could be placed near the rear of the aircraft. For the sake of brevity, the description of each of the elements in FIGS. 2 to 4 will not be repeated. Rather, the description of each block, component or element in FIGS. 2-4 applies to blocks, components or elements bearing the same number in FIG. The aircraft data network 500 of FIG. 5 is illustrated to show specific and non-limiting examples of transmission systems and reception systems to which reference is generically made in FIGS. 2-4. It will be appreciated that these examples are non-limiting and intended to show an exemplary architecture.
    [0009] As shown in FIG. 5, the transmission systems 520 may comprise, for example, 520-1-1, 520-2-1, 520-3-1 inertial control units, heading and attitude reference systems (AHRS) 520- 1-2, 520-2-2, aerodynamic data systems (ADS) 520-1-3, 520-2-3, 520-1-4, 520-2-4, and communication systems 520-1 -5, 520-2-5. Reception systems 580 may include, for example, avionics systems 580-1, screens 580-2-1, 580-2-2, flight computers 580-2-3, 580-2-4, and other aircraft systems 590-1, 590-2. Other aircraft systems 590-1, 590-2 represent other aircraft systems that can receive data from transmission systems and that can also transmit data to receiving systems, and are therefore labeled as "other transmission and reception systems" in FIG. Since they are each intended to represent a plurality of other aircraft systems which may be transmitters and / or data receivers. The other aircraft systems 590-1, 590-2 may be examples of receiving systems that do not receive critical data while all other receiving systems 580 receive critical data from the transmission systems 520. [0051] ] Each of the 520-1-1, 520-2-1, 520-3-1 inertia control panels includes devices, components and sensors such as gyro (s) (eg laser gyroscope (s)), accelerometer (s), Global Position System (GPS) receiver and other motion sensors). For example, each of the 520-1-1, 520-2-1, 520-3-1 inertial control units may include laser gyroscopes and accelerometers that can detect information that can be used. to calculate or generate inertial signal data provided to flight computer 580-2-3, 580-2-4. Inertial signal data may generally include flight inertia data such as angular velocities of aircraft velocities (eg, angular velocities of roll, pitch, and yaw axes) and linear accelerations, as well as the attitude and speed of the aircraft. [0052] Like the 520-1-1, 520-2-1, 520-3-1 inertial control systems, the heading and attitude reference systems (AHRS) 520-1-2, 520-2 -2 each comprise sensor devices such as gyroscopes, accelerometers and / or magnetometers which are not illustrated for the sake of simplicity. Each of the heading and attitude reference systems 3034596 (AHRS) 520-1-2, 520-2-2 also includes a processor and software for processing the information of the different sensor devices to generate control data of flight of inertia that are provided to flight computers 580-2-3, 580-2-4. For example, in some implementations, each of the heading and attitude reference systems (MIRS) 520-1-2, 520-2-2 includes three sensors for the three axes of the aircraft that can provide heading, attitude and yaw data for each of the three axes of the aircraft. This heading, attitude, and yaw measurement data can be processed through a processor on the heading and attitude reference systems 520-1-2, 520-2-2 to provide the data of inertial flight control (eg, speeds, accelerations, heading and attitude measurement data) which can then be provided to the flight computers 580-2-3, 580-2-4. Depending on the implementation, this inertia flight control data may comprise at least a portion of the inertial signal data described above with respect to the inertial units 520-1-1, 520- 2-1, 520-3-1. As such, in some embodiments, the 520-1-1, 520-2-1, 520-3-1 inertial control units and the heading and attitude reference systems (AHRS) 520-1- 2, 520-2-2 substantially emit similar types of data (e.g., velocities, accelerations, heading measurements). In other words, the inertia signal data and the flywheel control data are "redundant" to some extent. The inertial flight control data of the heading and attitude reference systems (AHRS) 520-1-2, 520-2-2 can be used to verify or confirm the accuracy of the signal data of inertia that are emitted by inertial units 520-1-1, 520-2-1, 520-3-1. The aerodynamic data systems (ADS) 520-1-3, 520-2-3, 520-1-4, 520-2-4 may include sensors such as aerodynamic data sensors, components or sensors aerodynamic data centres (ADRs), aircraft sensors (eg, airspeed indicator, altimeter, attitude indicator, gyro, magnetic compass, navigation instrument sensor, aircraft sensors). speed, angular velocity sensor, etc.), position, angle, displacement, distance, speed, acceleration sensors (eg, accelerometer, inclinometer, position sensor, rotary encoder, rotary variable / linear differential transformer, tachometer, etc.), Pitot and static pressure probes that can be used to measure ram-air pressure and static pressures, acoustic sensors (eg, sound, microphone, seismometer, accelerometer, etc.), vibration sensors, etc. The ADS 520-1-3, 520-2-3, 520-1-4, 520-2-4 can provide various aerodynamic data signals that can be used to determine / calculate metric values such as air, Mach number, barometric altitude data, altitude, angle of attack, air temperature, etc. The communication systems 520-1-5, 520-2-5 may include, for example, satellite communication interfaces, Global Position System (GPS) interfaces, Global Navigation Satellite System (GNSS) interfaces, other wireless interfaces, etc. The avionics system 580-1 can generally refer to any electrical or electronic system used on the aircraft. Examples of avionics systems 580-1 may include communication systems, navigation systems, aviation systems, surveillance systems, aircraft flight control systems, flight avoidance systems and collision, aircraft management systems, weather systems, radar systems, etc. The screens 580-2-1, 580-2-2 may comprise screen units such as control screen units, multifunction displays (MFDs), screensavers, and so on. As is known in the art, the flight computers 580-2-3, 580-2-4 are part of a flight control system which is used to control the engines of the aircraft and the flight control surfaces. The 580-2-3, 580-2-4 flight computers can receive input signals from 520-1-1, 520-2-1, 520-3-1 inertial control systems, heading reference systems and Attitude (AHRS) 520-1-2, 520-2-2, Aerodynamic Data Systems (ADS) 520-1-3, 520-2-3, 520-1-4, 520-2-4 , and other sensors 20 (not shown). Examples of input signals may include signals that provide information about speed (eg, angular velocity signals), acceleration signals, altitude signals, attitude signals, speed signals, heading signals, etc. The flight computer 580-2-3, 580-2-4 also receives input signals from a driver input system (not shown). For example, the driver input system generates various input signals from the driver in response to driver inputs. The pilot input signals may be generated in response to the pilot adjusting a control stick to the left or right, adjusting a steering wheel or control stick forwards or backwards, adjusting a rudder pedal, etc. The flight computers 580-2-3, 580-2-4 are configured to control the engines of the aircraft by generating, based on input signals, control signals from the engines that control the engines. of the aircraft. The flight computers 580-2-3, 580-2-4 are configured to operate various flight control surfaces e.g., ailerons, rudders, 18 3034596 rudder, spoilers, flaps) on the aircraft by sending commands to the actuator control units which control actuators coupled to the different flight control surfaces to provide a desired flight operation in response to numerous criteria. Each flight computer 580-2-3, 580-2-4 processes input signals to generate flight controls that control the different flight control surfaces of the aircraft. For example, each flight computer 580-2-3, 580-2-4 processes the pilot input signals and at least a portion of the input signals received from the 1RS, AHRS, and ADS to translate the signals of driver input into commands for use by the actuator control units (not shown). Each actuator control unit controls one or more actuators associated with different flight control surfaces to control these flight control surfaces. The other aircraft systems 590-1, 590-2 are any aircraft system that receives data but does not need to receive "critical" data as described above. Examples of other aircraft systems 590-1, 590-2 may include an air conditioning system, a fuel quantity system, and the like. The RDC 540-1 is communicatively coupled directly to different transmission systems including the 520-1-1 inertia control unit, the 5201-4 aerodynamic data system, and the 520-1-5 communication system, to various receiving systems including 580-2-1 screens and other 590-1 aircraft systems, and 550-1, 550-3 network switches 3 which indirectly couple the RDC 540-1 in communication with the communications systems. avionics 580-1, 580-2-2 displays, flight computers 580-2-3, 580-2-4 and other 590-2 aircraft systems. The RDC 540-1 receives data including critical data from each of these transmission systems. RDC 540-1 translates all received data to generate translated data that is combined and communicated to each of the network switches 550-1, 550-3. The network switches 550-1, 550-3 receive the translated data from the RDC 540-1, determine appropriate destinations (eg, particular reception systems or other network switches and / or other RDCs that provide a path to others receiving systems) for the translated data, then route at least a portion of the translated data to or to each destination (eg, particular receiving systems or other network switches and / or other RDCs that provide a path to other reception systems). In one embodiment, the RDC 540-3 receives at least a portion of the data translated from the network switches 550 and performs functions similar to the RDCs 3034596 240-2 of FIG. 2 by converting at least a portion of the translated data of one of the network switches to generate converted data having formats used by the receiving systems 580-1, 580-2-1, 595-1. The RDC 540-3 can then communicate the converted data to the 580-1, 580-2-1, 595-1 receiving systems. RIU 532-1 is coupled directly in communication with different transmission systems including 520-1-1, 520-3-1 center-of-motion centers, 520-1-1 heading and attitude reference system. -2, the aerodynamic data system 520-1-3, and 520-1-5 communication systems, avionics systems 580-1 and flight computers 580-2-3. [0064] The RIU 532-1 receives critical data directly from each of these transmission systems 520-1-1, 520-3-1, 520-1-2, 520-1-3, 520-1-5 , translates the critical data and communicates the translated critical data to the processing unit 595-1 on the flight computer 580-2-3. The RIU 532-3 can perform the same functions but is placed at a different location in the aircraft. For example, RIU 532-1 could be placed near the front of the aircraft, while RIU 532-3 could be placed near the rear of the aircraft.
    [0010] In one embodiment, the RIU 532-3 receives at least a portion of the translated critical data from the processing unit 595-1 and performs functions similar to the RIU 432-2 of FIG. 4 by converting at least a portion of the translated critical data of the processing unit 595-1 to generate converted data having formats used by the receiving systems 580-1, 580-2-1, 595-1. Although not all links are illustrated, the RIU 532-3 can then communicate the converted data to the receiving systems 5801, 580-2-1, 595-1. In an embodiment illustrated in FIG. 5, the 595-1 processing unit is a processor in the flight computer 580-2-3; however, it should be noted that the processing unit 595-1 need not be part of the flight computer 580-2-3 and could be implemented on any embedded processor in an aircraft. It is illustrated in this way in FIG. 5 to show a practical implementation, but the processing unit 595-1 could also be a processor which is part of for example a train control device (LGCU), a cabin pressure controller (CPC) , an air conditioning system (ECS), a tire pressure monitoring system (TPMS), a brake control system (BCU), an engine control system (ECU), an orientation control of the front undercarriage (NWS) or any embedded processor in an aircraft. The processing unit 595-1 can then process the translated critical data to extract the critical data and communicate them directly to the network switch 550-1 and to the other processing unit 595-2. The network switch 550-1 may perform the routing functions to indirectly provide the critical data through an alternative path to any other receiving system that consumes critical data (eg avionics systems). 580-1 and 580-2-1, 580-2-2 screens included). Thus, for example, ADS 520-1-4 critical data can be provided to the avionics systems 580-1 via a path that includes the RDC 540-1 and the network switch 550-3 while the data ADS 520-1-3 reviews may be provided to the avionics systems 580-1 via another dissimilar path that includes the RIU 532-1, the 595-1 processing unit, and any other possible network switches. As such, the disclosed aircraft data network can carry critical data over dissimilar paths that are not subject to the same failure modes. The RDC 540-2 is directly coupled in communication with different transmission systems including the 520-2-1 inertia control unit, the 520-2-4 aerodynamic data system, and the 520-2 communication system. 5, to various receiving systems including 580-2-2 screens and other aircraft systems 590-2, and network switches 550-2, 5504 which indirectly couple the RDC 540-2 in communication with the control systems. 580-2-1 avionics, 580-2-3, 580-2-4 flight computers and other 590-1 aircraft systems. The RDC 540-2 receives data including critical data from each of these transmission systems. The RDC 540-2 translates all received data to generate translated data that is combined into a single signal that is communicated to each of the network switches 550-2, 550-4. The network switches 550-2, 550-4 receive the translated data from the RDC 540-2, determine appropriate destinations (eg, particular reception systems or other network switches and / or other RDCs that provide a path to other reception systems) for the translated data, then route at least part of the translated data to or to each destination (eg, particular reception systems or other network switches and / or other RDCs that provide a path to other reception systems). In one embodiment, the RDC 540-4 receives at least a portion of the translated data of the network switches 550 and performs functions similar to the RDCs 240-2 of FIG. 2 by converting at least a portion of the translated data to generate data having formats used by the receiving systems 580-1, 580-2-2, 595-2.
    [0011] The RDC 540-3 can then communicate the converted data to the receiving systems 580-1, 580-2-2, 595-2. The RIU 532-2 is directly coupled in communication with various transmission systems including the 520-2-1 inertial control system the heading and attitude reference system 520-2-2, the aerodynamic data system. 520-2-3, and 520-2-5 communication systems and flight computer 580-2-4. RIU 532-2 receives critical data directly from each of these 520-2-1, 520-2-2, 520-2-3, 520-2-5 transmission systems, translates critical data, and communicates critical data translated to processing unit 595-2 on flight computer 580-2-4. The RIU 532-4 can perform the same functions but is placed at a different location in the aircraft. For example, RIU 532-2 could be placed near the front of the aircraft, while RIU 532-4 could be placed near the rear of the aircraft. In one embodiment, the RIU 532-4 receives at least a portion of the translated critical data from the processing unit 595-2 performs functions similar to the RIU 432-2 of FIG. 4 by converting at least a portion of the translated critical data of the processing unit 595-2 to generate converted data having formats used by the receiving systems 580-1, 580-2-2, 595-. Although not all links are shown, the RIU 532-4 can then communicate the converted data to the 580-1, 580-2-2, 595-2 receiving systems. The processing unit 595-2 does not have to be part of the flight computer 580-2-4 and could be implemented on any embedded processor in an aircraft. It is illustrated in this way in FIG. 5 to show a practical implementation. The processing unit 595-2 can then process the translated critical data to extract the critical data and communicate it directly to the network switch 550-2 and to the other processing unit 595-1. The network switch 550-3 can perform the routing functions to indirectly provide the critical data through an alternative path to any receiving system that consumes the critical data (eg avionics systems 580 -1 and 580-2-1, 580-2-2 screens included). Thus, for example, the critical data of the ADS 520-2-4 can be provided to the avionics systems 5801 via a path that includes the RDC 540-2 and the network switch 550-4, while the critical data ADS 520-2-3 can be provided to the 580-1 avionics systems via another dissimilar path that includes the RIU 532-2, the 595-2 processing unit, and any other possible network switches. As such, the disclosed aircraft data network can carry critical data over dissimilar paths that are not subject to the same failure modes. Those skilled in the art will furthermore understand that the various blocks, modules, logic circuits described in connection with the embodiments disclosed herein can be implemented as electronic equipment, computer software or combinations of those -this. Some of the embodiments and implementations are described above in terms of functional and / or logical block components (or modules). However, it will be understood that such block components (or modules) may have the form of any hardware, software and / or firmware component configured to perform the specified functions a 0. To clearly illustrate this interchangeability of hardware and software, various components, blocks, modules, illustrative circuits have been described above generally in terms of functionality. Whether this functionality is implemented as hardware or software depends on the particular application and design constraints imposed on the entire system. Those skilled in the art can implement the described functionality in different ways for each particular application, but such implementation decisions should not be interpreted as a cause for departing from the scope of the present invention. . For example, an embodiment of a system or component may employ different integrated circuit components, e.g. memory elements, digital signal processing elements, logic elements, look-up boards, or the like, which can perform different functions by being controlled by one or more microprocessor (s) or other control devices. In addition, those skilled in the art will appreciate that the embodiments described herein are purely exemplary implementations. The various blocks, modules and illustrative logic circuits described in connection with the embodiments disclosed herein may be implemented or executed with a general purpose processor, a digital signal processor (DSP), a specific integrated circuit. at the application (ASIC), a user programmable matrix (FPGA) or other programmable logic device, discrete gate or transistor logic, discrete hardware components or any combination thereof designed to perform the functions described in present. A general purpose processor may be a microprocessor, but alternatively, the processor may be any processor, controller, microcontroller, or conventional state machine. A processor may also be implemented as a combination of computational devices, e.g., a combination of a DSP and a microprocessor, a plurality of microprocessors, one or more associated microprocessor (s) to a DSP kernel or any other configuration of this type. The term "exemplary" is used exclusively herein to mean "as an example or illustration." Any embodiment described herein as "exemplary" need not be construed as being preferred to, or advantageous on, other embodiments. Embodiments disclosed herein may be incorporated directly into the hardware, into a software module executed by a processor or in a combination of both. A software module may be included in a RAM, a flash memory, a ROM, an EPROM, an EEPROM, directories, the hard disk, a removable disk, a CD-ROM, or any other form of memory media. known from the art. An exemplary memory medium is coupled to the processor such that the processor can read information from, and write information to, the memory medium. Alternatively, the memory medium may be an integral part of the processor. The processor and memory media can be in an ASIC. In this document, relation terms such as first and second / second and the like may be used only to distinguish an entity or action from another entity or action without necessarily requiring or assuming any actual relationship or order (the ) of such type between such entities or actions. Ordinal numbers such as "first", "second / second" and "third" simply indicate different unique elements of a plurality and do not assume any order or sequence unless specifically defined by the language of the claims. The text sequence in any of the claims does not assume that the method steps must be executed in a temporal or logical order according to this sequence unless specifically defined by the language of the claim. The process steps can be interchanged in any order without departing from the scope of the invention as long as such interchange does not contradict the language of the claims and is not logically nonsense. In addition, depending on the context, terms such as "connect" or "coupled to" employees to describe a relationship between different elements do not assume that a direct physical connection must be made between these elements. For example, two elements can be connected to each other physically, electronically, logically, or in any other way, by one or more additional elements. While at least one exemplary embodiment has been presented in the above detailed description of the invention, it will be understood that there are a large number of variations. For example, although the disclosed embodiments are described with reference to an aircraft flight computer, those skilled in the art will appreciate that the disclosed embodiments could be implemented in other types of computers. which are used in other types of vehicles, including, but not limited to, space vehicles, underwater vehicles, surface ships, automobiles, trains, motorcycles, etc. It will also be appreciated that the exemplary embodiment (s) are merely examples, and are not intended to limit the scope, applicability or configuration of the invention in any way. . Rather, the above detailed description will provide those skilled in the art practical guidance for the implementation of the embodiment (s) embodiment as an example of the invention. It will be appreciated that various changes may be made in the operation and arrangement of the elements without departing from the scope of the invention as set forth in the appended claims and the legal equivalents thereof. 25
    权利要求:
    Claims (22)
    [0001]
    CLAIMS: 1. An aircraft data network comprising: a first communication path between a first transmission system and a first reception system; a first remote data concentrator (RDC) configured to: receive one or more input signals / signals comprising data of the first transmission system; and translate the data through a network protocol to generate translated data having a format consistent with the network protocol; a network switch, communicatively coupled to the first RDC over a bus, the network switch configured to: receive data translated from the first RDC; determine a destination for at least a portion of the translated data; and routing at least a portion of the translated data to the first receiving system; a second RDC configured to: receive at least a portion of the translated data of the network switch; converting at least a portion of the translated data to generate converted data having a format adapted for use by the first receiving system; and communicating the converted data to the first receiving system.
    [0002]
    The aircraft data network of claim 1, further comprising: a second reception system communicatively coupled to the second RDC; and a second communication path between the first transmission system and the second reception system, wherein the second RDC is configured to: receive other data translated from the network switch; converting the translated data to generate other converted data having a format adapted for use by the second receiving system, and communicating the other converted data to the second receiving system.
    [0003]
    The aircraft data network of claim 2, further comprising: a third communication path between the first transmission system and the first reception system, comprising: a first cable connection which carries the data of the first transmission system; transmission directly to the first receiving system; and a third communication path between the first transmission system and the second reception system, the fourth communication path comprising: a second hardwired connection which carries data from the first transmission system directly to the second reception system. 5
    [0004]
    The aircraft data network of claim 3, further comprising: a second transmission system configured to transmit one or more input signals / signals including a redundant version of the data; and a fifth communication path to the first receiving system, comprising: a third wired connection carrying the redundant version of the data directly from the second transmission system to the first receiving system; and a sixth communication path between the second transmission system and the first reception system, comprising: the first RDC, the network switch and the second RDC.
    [0005]
    An aircraft data network according to claim 4, further comprising: a second receiving system; and a seventh communication path to the second reception system, comprising: a fourth cable connection which carries the redundant version of the data of the second transmission system directly to the second reception system; and an eighth communication path between the second transmission system and the second reception system, comprising: the first RDC, the network switch and the second RDC.
    [0006]
    The aircraft data network of claim 1, further comprising: a second communication path between the first transmission system and the first reception system, comprising: a first remote interface unit; RIU) configured to: receive one or more signal / input signals including critical data from the first transmission system; and translate the critical data through a network protocol to generate translated critical data having a format consistent with the network protocol; a processing unit, communicatively coupled to the first RIU via a bus, the processing unit being configured to: receive critical data translated from the first RIU; determining a destination for at least a portion of the translated critical data; and routing at least a portion of the translated critical data to the first receiving system; and a second RIU configured to: receive at least a portion of the critical data translated from the processing unit; converting at least a portion of the translated critical data to generate converted critical data having a format adapted for use by the first receiving system; and communicating the converted critical data to the first receiving system.
    [0007]
    The aircraft data network of claim 6, further comprising: wherein the first RDC comprises hardware and software, and wherein the first RIU comprises hardware and software different from the hardware and software of the first RDC. ; wherein the network switch comprises hardware and software, and wherein the processing unit comprises hardware and software different from the hardware and software of the network switch; and wherein the second RDC comprises hardware and software, and wherein the second RIU includes hardware and software different from the hardware and software of the second RDC.
    [0008]
    An aircraft data network according to claim 1, wherein the data comprises critical data, wherein the critical data comprises: communication data that is used by the first reception system; navigation data that is used by the first receiving system; or aviation data that is used by the first receiving system.
    [0009]
    The aircraft data network of claim 1, wherein the first receiving system comprises: a flight computer.
    [0010]
    The aircraft data network of claim 1, wherein the first receiving system comprises: an avionics system.
    [0011]
    The aircraft data network of claim 1, wherein the first receiving system comprises: a screen. 10
    [0012]
    The aircraft data network of claim 1, wherein the first transmission system comprises: a communication system. 15
    [0013]
    The aircraft data network of claim 1, wherein the first transmission system comprises: an inertial reference system (IRS).
    [0014]
    The aircraft data network of claim 1, wherein the first transmission system comprises: an attitude and reference system (MIRS).
    [0015]
    The aircraft data network of claim 1, wherein the first transmission system comprises: an air data system (ADS).
    [0016]
    An aircraft comprising: an aircraft data network comprising: a plurality of transmission systems configured to generate critical data including signals, the plurality of transmission systems comprising: a first transmission system; A plurality of receiving systems that consume the critical data, comprising: a first receiving system; and a first communication path between the first transmission system and the first reception system; A first remote data concentrator (RDC) configured to: receive one or more input signals / signals including data from the first transmission system; and translate the data through a network protocol to generate translated data having a format consistent with the network protocol; a network switch, communicatively coupled to the first RDC via a bus, the network switch being configured to: receive data translated from the first RDC; determine a destination for at least a portion of the translated data; and routing at least a portion of the translated data to the first receiving system; a second RDC configured to: receive at least a portion of the translated data of the network switch; converting at least a portion of the translated data to generate converted data having a format adapted for use by the first receiving system; and communicating the converted data to the first receiving system.
    [0017]
    The aircraft of claim 16, further comprising: a second communication path between the first transmission system and the first reception system, comprising: a first remote interface unit (RIU) configured to: receiving one or more signal / input signals including critical data from the first transmission system, and translating the critical data via a network protocol to generate translated critical data having a format in accordance with the network protocol, wherein the first RDC includes hardware and software, and wherein the first RIU includes hardware and software different from the hardware and software of the first RDC; a processing unit communicatively coupled to the first RIU through bus, the processing unit being configured to: receive critical data translated from the first RIU; ination for at least part of the translated critical data; and routing at least a portion of the translated critical data to the first receiving system; wherein the network switch comprises hardware and software, and wherein the processing unit comprises hardware and software different from the hardware and software of the network switch and a second processing unit configured to: receive at least one part of the critical data translated from the processing unit; converting at least a portion of the translated critical data to generate converted critical data having a format adapted for use by the first receiving system; and communicating the converted critical data to the first receiving system, wherein the second RDC comprises hardware and software, and wherein the second RIU includes hardware and software different from the hardware and software of the second RDC. 10
    [0018]
    The aircraft of claim 16, wherein the critical data comprises: communication data that is used by the first receiving system; navigation data that is used by the first receiving system; or aviation data that is used by the first receiving system. 15
    [0019]
    The aircraft of claim 16, wherein the first receiving system comprises: a flight computer. an avionics system; or a screen.
    [0020]
    An aircraft according to claim 16, wherein the first transmission system comprises: a communication system; An inertial reference system (IRS); an attitude and reference system (AHRS); or an air data system (ADS). 30
    [0021]
    The aircraft of claim 16, further comprising: a second reception system communicatively coupled to the second RDC; and a second communication path between the first transmission system and the second reception system, wherein the second RDC is configured to: receive other data translated from the network switch; converting the translated data to generate other converted data having a format adapted for use by the second receiving system, and communicating the other converted data to the second receiving system. 5
    [0022]
    The aircraft of claim 21, further comprising: a third communication path between the first transmission system and the first reception system, comprising: a first cable connection which carries data from the first transmission system directly to the first system reception; a fourth communication path between the first transmission system and the second reception system, the fourth communication path comprising: a second cable connection which carries data from the first transmission system directly to the second reception system; A second transmission system configured to transmit one or more input signals / signals comprising a redundant version of the data; a fifth communication path to the first receiving system, comprising: a third wired connection carrying the redundant version of the data directly from the second transmission system to the first receiving system; A sixth communication path between the second transmission system and the first reception system, comprising: the first RDC, the network switch and the second RDC. a seventh communication path to the second reception system, comprising: a fourth cable connection which carries the redundant version of the data of the second transmission system directly to the second reception system; and an eighth communication path between the second transmission system and the second reception system, comprising: the first RDC, the network switch and the second RDC. 32
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    FR3094785A1|2020-10-09|UNIT AND INTERTIAL REFERENCE SYSTEM WITH IMPROVED INTEGRITY AND ASSOCIATED INTEGRITY CONTROL METHODS
    同族专利:
    公开号 | 公开日
    US9838436B2|2017-12-05|
    CN106027594A|2016-10-12|
    CN106027594B|2018-11-09|
    FR3034596B1|2018-09-07|
    US20160294882A1|2016-10-06|
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    法律状态:
    2017-03-27| PLFP| Fee payment|Year of fee payment: 2 |
    2018-01-19| PLSC| Search report ready|Effective date: 20180119 |
    2018-03-26| PLFP| Fee payment|Year of fee payment: 3 |
    2020-03-25| PLFP| Fee payment|Year of fee payment: 5 |
    2021-03-25| PLFP| Fee payment|Year of fee payment: 6 |
    优先权:
    申请号 | 申请日 | 专利标题
    US14/672,639|US9838436B2|2015-03-30|2015-03-30|Aircraft data networks|
    US14672639|2015-03-30|
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