EP4315059A1 - Server, system and configuration method for generating configuration information for a multi-system platform - Google Patents

Abstract

The present invention relates to a configuration server (11) for generating configuration information for a multi-system platform comprising hardware and software resources which are shared by different functional systems of an aircraft or space craft. Said server comprises: a connection module (111) suitable for establishing a remote connection to a plurality of configuration clients (12); a storage unit (110) suitable for storing configuration information relating to the hardware and/or software resources allocated to each functional system; a system configuration module (112) which is accessible by means of different system configuration profiles respectively associated with the different functional systems and which is suitable for generating configuration information for a functional system associated with the system configuration profile used for the connection between the connection module and a configuration client, on the basis of the hardware and/or software resources allocated to said functional system.

Description

Description

Title: Server, system and configuration method for generating configuration information for a multi-system platform

Technical area

The present invention belongs to the field of embedded systems, and relates more particularly to the configuration of multi-system platforms (also known as multi-user platforms).

The present invention finds an advantageous application, although in no way limiting, for the configuration of multi-system platforms intended to be embarked in aircraft.

State of the art

Conventionally, an aircraft, for example an airplane, must embed several functional systems to perform different functions inside the airplane. The functional systems of an aircraft, as well as the specifications they must meet, are defined in particular by the “Air Transportation Association for America” or ATA. For example, the ATA-21 specification concerns functional systems relating to air conditioning and pressurization functions, the ATA-28 specification concerns functional systems relating to fuel storage, distribution and gauging functions, the ATA-33 specification concerns systems functions relating to lighting functions, etc.

Traditionally, the functional systems of an aircraft were implemented according to a so-called federated architecture, in which each functional system was equipped with one or more own and dedicated computers (“Line Replaceable Unit” or LRU in the Anglo-Saxon literature).

With the increase in the computing capacities of computers and the number of functional systems on board aircraft, but also due to a need to reduce the manufacturing costs of said aircraft, a new so-called multi-system architecture has been proposed, respecting segregation constraints related to the security of functional systems. In such a multi-system architecture, the same computer (or more generally the same hardware and/or software resource) can be used by different functional systems of the aircraft. Such a computer is therefore a multi-user computer, the different users corresponding to different functional systems of the aircraft.

For example, a platform carrying out the functions of electrical generation, distribution and conversion, in accordance with the ATA-24 specification, is intended to be used by various functional systems requiring the use of electrical signals (power supply, sensor measurements, actuators, etc.), and can be implemented according to a multi-system architecture to perform all or part of the functions of other functional systems.

However, current multi-system platform configuration tools require manual activity to coordinate the generation of configuration information for different functional systems. These are generated independently for each functional system and integrated manually in a second step.

Disclosure of Invention

The present invention aims to remedy all or part of the limitations of the solutions of the prior art, in particular those set out above, by proposing a solution making it possible in particular to facilitate the configuration of a multi-system platform.

To this end, and according to a first aspect, a configuration server is proposed for the generation of configuration information for such a multi-system platform, said multi-system platform comprising hardware and software resources shared by different functional systems of an aerial or space vehicle in which said multi-system platform is intended to be embarked. Said configuration server comprises: a connection module, adapted to establish a remote connection with a plurality of configuration clients, a storage unit adapted to memorize configuration information relating to the hardware and/or software resources allocated to each functional system , a system configuration module accessible by means of different system configuration profiles associated respectively with the different functional systems, adapted to generate configuration information for a functional system associated with the system configuration profile used for the connection between the connection module and a configuration client, according to the hardware and/or software resources allocated to said functional system.

Thus, the generation of configuration information of the different functional systems using the resources of a multi-system platform is carried out on the same centralized configuration server, to which the different suppliers of functional systems can connect remotely in order to generate their own information. configuration. The configuration tool is multi-user for integrating configurations from multiple functional systems, with a sharing process built into the tool.

Such provisions first of all make it easier to coordinate the generation of configuration information. Indeed, the configuration information representative of the resources allocated to the various functional systems are stored in the same central storage unit accessible by the configuration server. This therefore makes it possible to reduce the risks of having resources allocated simultaneously to two different functional systems, or of having suppliers of functional systems who would use different versions of the configuration information of the shared resources, etc. In addition, the different configuration information, stored centrally, no longer needs to be exchanged between the different suppliers and the integrator of the multi-system platform. This also facilitates the integration and certification of said multi-system platform.

Because configuration information is generated centrally, using the same tool on the same equipment (configuration server), the risks of incompatibilities between configuration information with respect to configuration information are reduced. generated with tools installed on different equipment that may in particular use different operating systems Windows®, Linux, Unix, etc. This also helps to facilitate onboarding and certification.

In addition, it also reduces the complexity for suppliers of functional systems, in particular, which no longer need to each support and maintain equipment dedicated to the execution of a configuration tool. A single piece of equipment is required (configuration server), which facilitates maintenance by a single actor, for example the supplier or the integrator of the multi-system platform. The proper functioning of each piece of equipment on which a configuration tool is installed must also be guaranteed for certification, and we understand that it is simpler when one and the same piece of equipment is used by all the players in the development of the multi-platform. -systems.

In particular embodiments, the configuration server may also include one or more of the following characteristics, taken separately or in all technically possible combinations.

In particular embodiments, the configuration server comprises a platform configuration module for generating a multi-system platform model describing hardware and software resources that can be used by the functional systems, said platform configuration module being accessible by means of a platform configuration profile.

In particular embodiments, the system configuration module is suitable for generating a hardware and/or software resource allocation request for a functional system associated with a system configuration profile used for the connection between the connection module and a config client. Said configuration server further comprises a supervision configuration module for allocating hardware and/or software resources according to allocation requests, said supervision configuration module being accessible by means of a supervision configuration profile.

In particular embodiments, the supervision configuration profile makes it possible to access all the configuration information of the multi-system platform. The supervision configuration profile is for example used by an integrator of the multi-system platform.

In particular embodiments, each system configuration profile provides access to system configuration information associated with said system configuration profile, but does not provide access to configuration information associated with other functional systems. Such provisions make it possible to ensure that the configuration information of a functional system is not corrupted during the generation, by the configuration server, of configuration information of another functional system.

In particular embodiments, the configuration server includes a centralized version management module.

In particular embodiments, the configuration server comprises an administration module for managing the configuration profiles. According to a second aspect, a configuration system is proposed for the generation of configuration information of a multi-system platform, comprising a configuration server according to any one of the embodiments of the invention, and a plurality configuration clients suitable for remotely connecting to the configuration server using different configuration profiles.

According to a third aspect, a configuration method is proposed, implemented by a configuration server, for the generation of configuration information of a multi-system platform, said multi-system platform comprising shared hardware and software resources by different functional systems of an air or space vehicle in which said multi-system platform is intended to be embarked. Said configuration method comprises: establishing a remote connection with a configuration client by means of a system configuration profile from among different system configuration profiles associated respectively with the different functional systems, obtaining, from a unit storage storing configuration information relating to hardware and/or software resources of the multi-system platform allocated to each functional system, hardware and/or software resources allocated to the functional system associated with the system configuration profile used for the connection with the config client, a generation of configuration information for the functional system associated with the system configuration profile used for the connection with the configuration client, according to the hardware and/or software resources allocated to said functional system.

In particular embodiments, the configuration method may also include one or more of the following characteristics, taken in isolation or in all technically possible combinations. In particular embodiments, the configuration method comprises: establishing a remote connection with a configuration client by means of a platform configuration profile, generating a multi-system platform model describing hardware and software resources that can be used by functional systems.

In particular modes of implementation, the configuration method comprises: generation of a request for the allocation of hardware and/or software resources for a functional system associated with a system configuration profile used for the connection with a client of configuration, establishment of a connection with a configuration client by means of a supervision configuration profile, allocation of hardware and/or software resources according to allocation requests, by means of the configuration client connected with the monitoring configuration profile.

In particular modes of implementation, the configuration method comprises: establishment of a connection with a configuration client by means of an administration profile, management of the configuration profiles authorized to generate and/or use configuration information of the multi-system platform, by means of the configuration client connected with the administration profile.

According to a fourth aspect, there is provided a computer program product comprising a set of program code instructions which, when are executed by a processor, configure said processor to implement a configuration method according to any one of the embodiments of the invention.

According to a fifth aspect, there is provided a computer-readable recording medium on which is recorded a set of program code instructions which, when executed by a processor, configure said processor to perform a method configuration according to any one of the embodiments of the invention.

Presentation of figures

The invention will be better understood on reading the following description, given by way of non-limiting example, and made with reference to the figures which represent:

[Fig. 1] Figure 1: a schematic representation of a configuration system of a multi-system platform,

[Fig. 2] Figure 2: a schematic representation of a configuration server of a multi-system platform,

[Fig. 3] Figure 3: a diagram illustrating the main steps of a process for configuring a multi-system platform,

[Fig. 4] Figure 4: a diagram illustrating the main steps of a preferred mode of implementation of a process for configuring a multi-system platform.

In these figures, identical references from one figure to another designate identical or similar elements. For clarity, items shown are not to scale unless otherwise noted.

Description of embodiments

As indicated above, this disclosure relates to the generation of configuration information for a multi-system platform. In the rest of the description, we place ourselves in a non-limiting way in the case of the configuration of a multi-system platform intended to be embarked in an aircraft.

In the rest of the description, we place ourselves in no way limiting in the case where the multi-system platform considered corresponds to a platform carrying out the functions of generation, distribution and conversion electrical, conforming to the ATA-24 specification.

As previously indicated, such an ATA-24 multi-system platform comprises hardware resources (network of electrical distribution cables, input/output cards, communication cards, computers, etc.) and software (library of software functions , etc.) that can be used by other functional systems.

For example, the ATA-24 multi-system platform can be connected to sensors and/or actuators used by a functional system, which can therefore use the ATA-24 multi-system platform to retrieve the measurements made by the sensors and to transmit commands intended for the actuators, but also to process the corresponding signals by the computers of said ATA-24 multi-system platform. In the context of an ATA-24 multi-system platform, the functional systems include the ATA-24 system and other functional systems, separate from the ATA-24 system.

As part of such a multi-system platform, the configuration information is for example organized in the form of tables of configuration parameters (in any suitable form, for example in XML, Excel®, CSV, etc.), and the generation of configuration information amounts to defining the values of these configuration parameters.

The configuration information for a given functional system includes, for example, the information relating to the hardware and/or software resources allocated to this functional system.

In particular embodiments, the configuration information may also include, for example, the application code describing the functions performed on the multi-system platform for the functional system considered, as well as the associated data (including the values of parameters of configuration), which will be loaded onto the multi-system platform.

FIG. 1 schematically represents an example of system 10 for configuring a multi-system platform, such as an ATA-24 multi-system platform in the example considered here. As illustrated by FIG. 1, the configuration system 10 comprises in particular a configuration server 11, and configuration clients 12 adapted to connect remotely to the configuration server 11 . Thus, the architecture of the configuration system 10 is centralized, according to a client/server architecture in which different configuration clients 12 can connect to the same centralized configuration server 11 to generate configuration information for the multi-system ATA platform. -24.

The 12 configuration clients can be used by different actors involved in the development, validation and certification of the ATA-24 multi-system platform. Each supplier of one of the functional systems of the ATA-24 multi-system platform is an actor who must generate configuration information for said ATA-24 multi-system platform, and is likely to connect to the configuration server 11 via a config client 12. In addition, the supplier of the ATA-24 multi-system platform, which will be used by the various functional systems, is also an actor who must provide or generate configuration information for the ATA-24 multi-system platform, and can for to do this, in preferred embodiments, connect to the configuration server 11 via a configuration client 12. In addition, the integrator of the ATA-24 multi-system platform, who is in charge of integrating the deliverables of the various actors involved in the ATA-24 multi-system platform, can also, in preferred embodiments, connect to the configuration server 11 via a configuration client 12.

Different actors preferably use different respective configuration profiles to connect to the configuration server 11 via a configuration client 12 .

For example, a supplier of a functional system can use a system configuration profile. Different system configuration profiles are associated respectively with different functional systems and their suppliers, in order to allow each functional system supplier to modify only the configuration information associated with its system. functional, without modifying the configuration information of the other functional systems for which it is not responsible.

In particular embodiments, the supplier of the ATA-24 multi-system platform can use a platform configuration profile to connect to the configuration server 11, the integrator of the ATA-24 multi-system platform can use a profile supervision configuration to connect to the configuration server 11, etc.

The configuration clients 12 are for example identical, regardless of the configuration profile used to connect to the configuration server 11 . This may for example be the case if the configuration tool is implemented as a web application on the configuration server 11, in which case each configuration client 12 corresponds to a web browser installed on a computer, or even if the clients 12 configuration correspond to the same application on different computers belonging to different actors, etc.

Following other examples, configuration 12 clients are not all the same. For example, the configuration client 12 may depend on the type of configuration profile used (system, platform, supervision, etc.). In such a case, the configuration clients 12 used with configuration profiles of different types correspond to different applications, which differ for example in the graphical interface, the functions implemented on the side of the configuration client 12, etc.

In all cases, regardless of the type of configuration client 12 considered (web browser, application to be installed on a computer, etc.) and the functionalities provided by the configuration client 12, it should be noted that the generation of information configuration is always carried out on the configuration server 11 . Thus, when the configuration information must be generated, the configuration client 12 uses a configuration information generation module, called “configuration module”, which is installed and runs on the configuration server 11.

FIG. 2 schematically represents a preferred embodiment of a configuration server 11 . As illustrated by FIG. 2, the configuration server 11 comprises in particular a connection module 111 suitable for establishing a remote connection with a plurality of configuration clients 12 .

The configuration server 11 also comprises a storage unit 110 suitable for storing configuration information of the ATA-24 multi-system platform, and in particular those generated by the configuration server 11 connected to a configuration client 12. In particular, the storage unit 110 is suitable for storing the configuration information relating to the hardware and/or software resources allocated to each functional system.

Preferably, the storage unit 110 also stores information relating to the various configuration profiles which are authorized to access the configuration server 11, as well as the associated rights and data. From a system configuration profile associated with a given functional system, the configuration server 11 can therefore retrieve from the storage unit 110 the configuration information relating to the hardware and/or software resources allocated, the configuration information generated with this system configuration profile for this functional system, etc. Preferably, the configuration server 11 includes a centralized version management module (not shown in the figures). Thus, the history and the successive versions of the configuration information stored in the storage unit 110 are stored, and the configuration server 11 therefore makes it possible to quickly identify all the configuration information associated with a given version thereof. .

In general, the storage unit 110 can comprise any type of non-volatile storage means. For example, the storage unit 110 includes one or more databases accessible by the configuration server 11.

As illustrated by FIG. 2, the configuration server 11 also comprises a system configuration module 112 accessible by means of different system configuration profiles associated respectively with the different functional systems. The system configuration module 112 is configured to generate configuration information for the various functional systems. In particular, the provider of a given functional system can connect to the system configuration module 112 using its system configuration profile, via a configuration client 12 and the connection module 111, and generate configuration information for the system. functional considered according to the configuration information relating to the hardware and/or software resources allocated to said functional system which have been recovered from the storage unit 110. The configuration information thus generated is preferably also stored in the storage unit 110.

In preferred embodiments, and as illustrated by FIG. 2, the configuration server 11 can also include a platform configuration module 113. The platform configuration module 113 is used by the supplier of the ATA-24 multi-system platform to generate configuration information which corresponds to a model describing the hardware and software resources of said ATA-24 multi-system platform, in particular those that can be used by functional systems. For example, the supplier of the ATA-24 multi-system platform can connect to the platform configuration module 113 using its platform configuration profile, via a configuration client 12 and the connection module 111. For example, the model of the ATA-24 multi-system platform indicates the number and type of computers, the number and type of input/output cards as well as the ports to which they are physically connected, the number and type of communication cards and the ports to which they are physically connected, etc.

In particular embodiments, and as illustrated by FIG. 2, the configuration server 11 can also include a supervision configuration module 114, accessible by means of a supervision configuration profile. For example, the integrator of the ATA-24 multi-system platform can connect to the supervision configuration module 114 using the supervision configuration profile, to retrieve all the configuration information generated by the various actors (system providers functionalities, supplier of the ATA-24 multi-system platform, etc.). In the case where the configuration server 11 includes a module for centralized version management, the integrator can directly retrieve all the configuration information of a specific desired version, without the risk of mixing configuration information from different functional systems which correspond to different versions of the configuration of the multi-system platform ATA-24, possibly incompatible with each other.

In preferred embodiments, the supervision configuration module 114 is also configured to allocate hardware and/or software resources to the various functional systems, depending for example on the model of hardware and software resources provided by the supplier of the multi-platform. -ATA-24 systems (preferably via platform configuration module 113). Preferably, the allocation of hardware and/or software resources is carried out according to allocation requests sent by the various software system suppliers. For example, the system configuration module 112 can be configured to generate a hardware and/or software resource allocation request for a functional system associated with a system configuration profile used for the connection between the connection module 111 and a client. 12 setup. The allocation requests thus generated by the system configuration module 112 are all accessible by the supervision configuration module 114, which allows the integrator to allocate the hardware and/or software resources to the various functional systems according to the allocation requests received. For example, the model of the ATA-24 multi-system platform, preferably stored in the storage unit 110, is used by the system configuration module 112 and by the supervision configuration module 114 to generate requests or allocate Resource. The hardware and/or software resources allocated respectively to the different functional systems are stored in the storage unit 110, and each functional system supplier can have access to the resources which have been allocated to it by connecting to the configuration server 11 using its system configuration profile.

It should be noted that the same functional system supplier can have several system configuration profiles. For example, a first profile of system configuration may be used to issue hardware and/or software resource allocation requests, and a second system configuration profile may be used to generate configuration information using the configuration information relating to the allocated hardware and software resources, etc

In preferred embodiments, and as illustrated by FIG. 2, the configuration server 11 may include an administration module 115 to manage the configuration profiles authorized to generate and/or use platform configuration information multi-system ATA-24. The administration module 115, for example accessible by means of an administration profile, makes it possible, for example, to add, delete and define configuration profiles. For example, the administration profile can be confused with the supervision configuration profile. The configuration server 11 comprises for example one or more processors and storage means (magnetic hard disk, electronic memory, optical disk, or any type of computer-readable recording medium) in which a computer program product is stored, in the form of a set of program code instructions to be executed to perform the functions of the various connection modules 111, 112, 113,

114 configuration and 115 administration. In a variant, the configuration server 11 comprises one or more programmable logic circuits, of the FPGA, PLD, etc. type, and/or specialized integrated circuits (ASIC) suitable for implementing all or part of said functions of the various modules 111 of connection, 112, 113, 114 configuration and 115 administration.

In other words, the configuration server 11 includes a set of means configured in software (specific computer program product) and/or hardware (FPGA, PLD, ASIC, etc.) to perform the functions of the various modules 111 connection, 112, 113, 114 configuration and

115 administration.

FIG. 3 represents the main steps of a method 20 for configuring the ATA-24 multi-system platform implemented by the configuration server 11 . As illustrated by FIG. 3, the configuration method 20 comprises: a step S20 of establishing, by means of the connection module 111, a remote connection with a configuration client 12 by means of a system configuration profile from among the various system configuration profiles associated respectively with the various functional systems, a step S21 for obtaining, from the storage unit 110, configuration information relating to the hardware and/or software resources allocated to the functional system associated with the system configuration profile used for the connection between the connection module 111 and the configuration client 12, a step S22 of generation of configuration information, by the system configuration module 112, for the functional system associated with the system configuration profile used for the connection between the connection module 111 and the client 12 configuration, depending on the hardware and/or software resources allocated to said functional system; preferably, the generated configuration information is stored in the storage unit 110.

During the connection step S20, the configuration server 11 verifies that the configuration profile used for the connection is indeed an authorized configuration profile. In the example illustrated by FIG. 3, the configuration profile used is a system configuration profile and the configuration server 11 verifies that said system configuration profile is indeed associated with one of the functional systems of the multi-system platform ATA-24.

In preferred modes of implementation, the connection step S20 can also implement any suitable authentication method, in order to verify that the person who connects with this system configuration profile is indeed the functional system supplier to which this system configuration profile belongs.

After having verified the system configuration profile, the configuration server 11 retrieves from the storage unit 110, during step S21, the configuration information relating to the hardware and/or software resources already allocated to the functional system associated with said system configuration profile used to connect to the configuration server 11. Next, in step S22, the functional system provider uses the system configuration module 112 to generate configuration information for the ATA-24 multi-system platform, using the retrieved configuration information, relating to the hardware and/or software resources previously allocated to this functional system. The steps illustrated in Figure 3 are performed for each functional system. Preferably, these steps can also be executed several times over time for each functional system, to generate successive versions of the different configuration information which, if necessary, can be indexed by a centralized version management module of the server 11 setup.

FIG. 4 schematically represents the main steps of a preferred mode of implementation of the configuration method 20, in the case where the configuration server 11 includes all the configuration modules represented in FIG. Figure 4, the connection steps with the configuration clients 12 are not shown, but

11 It should be noted that each step implementing a configuration module may be subject to the prior establishment of a connection with a client

12 configuration using a suitable configuration profile.

As illustrated by FIG. 4, the configuration method 20 firstly comprises a step S23 of management of the configuration profiles by the administration module 115, using the administration profile. The management step S23 makes it possible to create the various configuration profiles (platform, system, supervision, etc.) authorized to generate and use configuration information for the ATA-24 multi-system platform considered. The information describing the configuration profiles created is for example stored in the storage unit 110 of the configuration server 11 . The configuration method 20 also includes, in this example, a step S24 of generating configuration information corresponding to a model of the ATA-24 multi-system platform describing hardware and software resources that can be used by the functional systems. This generation step S24 is executed by the platform configuration module 113, using the platform configuration profile. the model of the ATA-24 multi-system platform thus generated is preferably stored in the storage unit 110 of the configuration server 11 .

The configuration method 20 also comprises, in this example, a step S25 generating a hardware and/or software resource allocation request by the system configuration module 112, using a system configuration profile. For example, the system configuration module 112 makes it possible to visualize the model of the ATA-24 multi-system platform, in order to allow the supplier of the functional system to identify the types of hardware and/or software resources necessary for the functional system considered. , and generate an allocation request for these resources. The resource allocation request generation step S25 is typically executed for each functional system, each functional system provider connecting to the configuration server 11 using its system configuration profile.

If applicable, the configuration method 20 also includes a step S26 of allocating hardware and/or software resources according to the allocation requests, executed by the supervision configuration module 114 using the supervision configuration profile. For example, the supervision configuration module 114 makes it possible to view the resource allocation requests received, in order to allow the integrator to allocate hardware and/or software resources to the various functional systems. It should be noted that several resource allocation requests may be received for different functional systems. Given that the supervision configuration profile provides access to all resource allocation requests, it is possible to arbitrate between two requests for the same type of hardware and/or software resource, if the hardware and /or available software are insufficient to satisfy these two requests. The supervision configuration module 114 is preferably configured to prevent the allocation of the same resource to two distinct functional systems. The configuration information relating to the hardware and/or software resources allocated at the end of step S26 to each functional system is preferably stored in the storage unit 110. As illustrated by FIG. 4, the request generation steps S25 and the allocation steps S26 can be iterated. For example, if a particular hardware or software resource could not be allocated to a functional system, it is possible to generate a new request for new hardware and/or software resources, etc.

The configuration method 20 also includes, in this example, a step S22 of generating configuration information for a functional system, by the system configuration module 112 using the system configuration profile associated with the functional system considered. This configuration information for a given functional system describes in particular a sequence of use of the hardware and software resources allocated to this functional system, for example in the form of an application code and associated data, or in the form of information allowing the supervision configuration module 114 to generate the application code and the associated data, etc. Step S22 for generating configuration information is executed for each functional system, each functional system provider connecting to the configuration server 11 using its system configuration profile. The configuration information generation step S22 notably uses the configuration information relating to the resources allocated to the functional system in question, obtained from the storage unit 110 (the obtaining step S21 not being represented on Figure 4 for clarity).

As illustrated by FIG. 4, step S22 for generating configuration information can be iterated over the developments for the same functional system. In addition, developments may identify a new need for additional hardware and/or software resources. The request generation steps S25 and allocation steps S26 can then be iterated again to request additional hardware and/or software resources, etc.

Once all the configuration information has been generated, it can be retrieved by the integrator of the ATA-24 multi-system platform, which connects to the configuration server 11 using its supervision configuration profile. In a manner known per se, the processes of development are by nature iterative, and the integration/validation of the various configuration information of the ATA-24 multi-system platform will generally make it possible to identify problems requiring all or part of the steps in figure 4 to be performed again, etc More generally, it should be noted that the modes of implementation and embodiment considered above have been described by way of non-limiting examples, and that other variants are therefore possible.

In particular, the invention has been described mainly considering the configuration of a multi-system platform intended to be onboard an aircraft, and more particularly an ATA-24 multi-system platform.

However, the invention is more generally applicable for the configuration of any type of multi-system platform intended to be embedded in an air or space vehicle. In addition, the invention is applicable for fields other than aerospace, and is applicable in any field in which it may be envisaged to use multi-system platforms similar to those of the aeronautical field. For example, the invention is also applicable in the automotive or railway field.

Claims

Claims

1. Configuration server (11) for generating configuration information for a multi-system platform, said multi-system platform comprising hardware and software resources shared by different functional systems of an air or spacecraft in which said multi-system platform is intended to be on-board, characterized in that said configuration server (11) comprises: a connection module (111), suitable for establishing a remote connection with a plurality of configuration clients (12), a storage unit (110) adapted to store configuration information relating to the hardware and/or software resources allocated to each functional system, a system configuration module (112) accessible by means of different system configuration profiles associated respectively with the different functional systems , adapted to generate configuration information for a functional system associated with the profile system configuration used for the connection between the connection module and a configuration client, depending on the hardware and/or software resources allocated to said functional system.

2. Configuration server (11) according to claim 1, comprising a platform configuration module (113) for generating a multi-system platform model describing hardware and software resources that can be used by the functional systems, said module (113) platform configuration being accessible by means of a platform configuration profile.

3. Configuration server (11) according to claim 1 or 2, in which the system configuration module (112) is adapted to generate a hardware and/or software resource allocation request for a functional system associated with a system configuration used for the connection between the connection module and a configuration client, said configuration server (11) comprising a supervision configuration module (114) for allocating hardware and/or software resources according to allocation requests , said supervision configuration module (114) being accessible by means of a supervision configuration profile.

4. Configuration server (11) according to claim 3, in which the supervision configuration profile provides access to all the configuration information of the multi-system platform.

5. Configuration server (11) according to any one of the preceding claims, in which each system configuration profile provides access to the configuration information of the functional system associated with said system configuration profile, but does not provide access to the configuration information associated with other functional systems.

6. Configuration server (11) according to any one of the preceding claims, comprising a centralized version management module.

7. Configuration server (11) according to any one of the preceding claims, comprising an administration module (115) for managing the configuration profiles.

8. Configuration system (10) for the generation of configuration information of a multi-system platform, comprising a configuration server (11) according to any one of the preceding claims, and a plurality of clients (12) of configuration adapted to connect remotely to the configuration server (11) using different configuration profiles.

9. Method (20) of configuration, implemented by a server (11) of configuration, for the generation of configuration information of a multi-system platform, said multi-system platform comprising hardware and software resources shared by different functional systems of an air or space vehicle in which said multi-system platform is intended to be onboard, characterized in that said configuration method (20) comprises: establishing (S20) a remote connection with a client (12) of configuration by means of a system configuration profile among various system configuration profiles associated respectively with the various functional systems, obtaining (S21), from a storage unit storing configuration information relating to resources hardware and/or software of the multi-system platform allocated to each system functional, hardware and/or software resources allocated to the functional system associated with the system configuration profile used for the connection with the configuration client, a generation (S22) of configuration information for the functional system associated with the system configuration profile used for the connection with the configuration client, depending on the hardware and/or software resources allocated to said functional system.

10. Configuration method (20) according to claim 9, comprising: establishing a remote connection with a configuration client (12) by means of a platform configuration profile, generating (S24) a model multi-system platform describing hardware and software resources that can be used by functional systems.

11. Configuration method (20) according to any one of claims 9 to 10, comprising: generation (S25) of a hardware and/or software resource allocation request for a functional system associated with a configuration profile system used for the connection with a configuration client, an establishment of a connection with a configuration client by means of a supervision configuration profile, an allocation (S26) of hardware and/or software resources according to the requests of allocation, using the configuration client connected with the supervision configuration profile.

12. Configuration method (20) according to any one of claims 9 to 11, comprising: establishment of a connection with a configuration client by means of an administration profile, management (S23) of the configuration authorized to generate and/or use configuration information of the multi-system platform, by means of the configuration client connected with the administration profile.

13. Computer program product comprising a set of program code instructions which, when executed by a processor, configures said processor to implement a method (20) of configuration according to any one of claims 9 to 12.

14. A computer-readable recording medium on which is recorded a set of program code instructions which, when executed by a processor, configures said processor to implement a configuration method (20) according to the any of claims 9 to 12.