EP1556804A2

EP1556804A2 - Method and device for synthesising an electrical architecture

Info

Publication number: EP1556804A2
Application number: EP03778418A
Authority: EP
Inventors: Samuel Boutin; Christophe Dan Van Nhan
Original assignee: Renault SAS
Current assignee: Renault SAS
Priority date: 2002-10-21
Filing date: 2003-10-21
Publication date: 2005-07-27
Also published as: US20060229742A1; AU2003285417A1; WO2004038619A3; AU2003285418A8; KR20050086425A; EP1554672A2; WO2004038618A3; WO2004038618A2; JP2006504169A; US7441225B2; KR20050074520A; WO2004038617A2; US20060215825A1; KR101002372B1; FR2846117B1; AU2003289672A1; AU2003285418A1; FR2846117A1; JP2006504171A; JP2006504170A

Abstract

The invention relates to a method and device for synthesising an electrical architecture. More specifically, the invention relates to a method of synthesising a routing which consists in obtaining the following parameters: the different configurations of service variants and calculator variants and the rate of occurrence of said configurations, the sum of the rates of the configurations being considered as equal to one; the component cost characteristics which are stored and weighted according to their respective rates of increase; and the partial or full positioning of the service variants on the calculator variants. The inventive method also consists in identifying valid routings, evaluating the routing cost of said valid routings for each configuration and determining the valid routing which minimises the average of the routing costs for each configuration, said average being weighted by the rates of increase of each configuration.

Description

METHOD AND DEVICE FOR SYNTHESIZING AN ARCHITECTURE

ELECTRIC The present invention relates to a method and a device for synthesizing an electrical architecture and the applications of this method to a vehicle, and in particular for the synthesis of a routing such as for example a routing of wiring.

Market tools make it possible to represent in two or three dimensions the routing of electrical wires in a product such as a vehicle. In this case, the user must trace each wire from one pin, or pin, from one connector to another. When there are means to clean up the routing, they are rudimentary. Patent EP-0696775A1 describes a method for designing a 3-D wiring starting from a 2-D logic representation already containing a wiring topology, the cables going from one connector to another being already represented. This 2-D topology is a prerequisite.

The object of the present invention is to provide an improved method and device for synthesizing an electrical architecture and the applications of this method to a vehicle, and in particular for synthesizing routing such as for example wiring routing. The objective of the present invention is in particular to allow the routing of all or part of the wires of an electrical-electronic architecture even when the geometry of the product is not yet known precisely, but when it is known how to cut it out. in zones which could, for example, be assembled at the time of the production of said product. No such effective methods are known. The present invention also aims to remedy these drawbacks to save time during the synthesis and during the evaluation of electrical and electronic architectures.

According to a first aspect, the present invention relates to a tool for synthesizing an economically optimal routing, characterized in that: the different configurations of service variants and of computer variants being specified and the rate of occurrence of these configurations being known, the sum of the configuration rates being equal to one,

- the cost characteristics of the components being known and weighted according to their respective mounting rates, - the partial or complete placement of the service variants on the computer variants being carried out, an economically optimal routing is automatically synthesized such that, for each sensor and each actuator, we identify the valid routes, we evaluate the routing cost of said valid routes for each configuration, and we choose the valid routing which minimizes the average, weighted by the mounting rates of each configuration, routing for each configuration.

Thanks to these provisions, we can compare the respective costs of two candidate architectures for a product plan by integrating a mix of range and options. According to particular characteristics, the optimal routing in quality is synthesized, characterized in that the steps above are repeated, the criterion which is minimized being a measure of quality preferably expressed in breakdowns per million.

Thanks to these provisions, it is possible to compare the respective quality measures of two candidate architectures for a product plan.

According to particular characteristics, the optimal routing by weight is synthesized, characterized in that the steps above are repeated, the criterion which is minimized being a quality measure preferably expressed in breakdowns per million.

Thanks to these provisions, we can compare the respective weights of two candidate architectures for a product plan.

According to particular characteristics, an installation cost of the electrical and electronic architecture is automatically calculated as a function of a cost of mounting a strand on a zone, of a cost of mounting a connector on a zone border or on a zone, a cost of mounting a computer on a zone, a cost of mounting a sensor or an actuator on a zone and a cost of connecting a connector between zones or in an area.

Thanks to these provisions, the respective assembly costs of two architectures can be compared.

According to particular characteristics, the optimal routing for all the configurations is synthesized, repeating the above steps, the criterion which is minimized being a compound cost:

- the estimated recurring cost of the parts,

- an estimate of the quality cost in anticipation of the repair cost per zone, this cost being increased by a constant cost depending on the zone and its ease of access,

- an estimate of the cost of weight taking into account mechanical wear and consumption linked to an increase in weight of the vehicle and / or

- an estimate of the installation cost.

Thanks to these provisions, it is possible to achieve an architecture optimizing the cost compared to a product plan and not only compared to a single product variant and taking into account all aspects of the design.

All of the process operations can be performed using a computer. The method according to the invention can be applied to the synthesis of the electrical architecture of a newly created product. The method according to the invention can also be applied to the synthesis of an electrical architecture modified with respect to an earlier architecture. According to a second aspect, the present invention relates to a system architecture design tool, characterized in that it comprises several screens which each include:

- a hierarchical description of the system, at least one of the levels of the hierarchy representing services offered to users, and

- when an element of the hierarchical description is selected, a synthetic view of at least part of the interface of this element with the rest of the system.

Thanks to these provisions, the user of the design tool directly takes into account the services offered to customers by accessing them in said screens and by observing synthetic views related to these services. It is recalled here that the services represent services for the benefit of a user of the system, for example the driver of a vehicle on board said system. Services are defined by what the user wants (for example the start of air conditioning, wipers) or by what is offered (for example passive safety, especially in the event of accidents) . They are also defined by sensors and / or actuators which they implement. They each correspond to a sensor / software / actuator hardware implementation, the sensor being able to be hardware (sensors in dashboard or pedals, for example). From the services, the design tool makes it possible to determine system specifications, interfaces and what the elements of the system must include and their communication with the other elements of the system.

According to particular characteristics, the tool comprises a selection means, called a "tab", of a hierarchical description, the selection of each tab showing a screen different from the tool. Thanks to these provisions, the transition from one screen to another is particularly easy. According to particular characteristics, for at least one screen, the hierarchical description represents, at a first level of hierarchy, a plurality of services, and at a second level of hierarchy, a plurality of use cases for each service.

Thanks to these provisions, each service is defined by the cases of its use. For example, the “wipers” service can be defined by use cases of alternating wiping, slow wiping and fast wiping.

According to particular characteristics, for at least one said screen, each use case comprises a context or initial situation of the system, a request from a user to the system and a response from the system corresponding to a change in its state. According to particular characteristics, in at least one screen, for each use case of a service, states and associated state transitions are defined. Thanks to each of these provisions, the use cases are formalized and in direct relation to the situations and states of the system and the requests of the user of the system which define the transitions between states.

According to particular characteristics, with at least one screen, the states which operate in modes transverse to the common services are grouped together, in "phases", each state is associated with a phase of the system, all the formalized use cases representing all the responses or absence of response of the system in all the phases, these representing, together, all the combinations of the operating modes of the vehicle. Thanks to these provisions, the states are hierarchized which allows a better readability because we can consider each phase separately, then each phase transition.

According to particular characteristics, each phase consists of a set of combinations of vehicle operating modes, the modes being transversal to the services and outside direct control of the services, for example a mode representing a level of available energy and / or a type of system user and or an accident or not condition of a vehicle.

Thanks to these provisions, the definition of the phases is standardized and easy to implement, it also allows an easier reading because hierarchical of the states.

According to particular characteristics, for at least one screen, the hierarchical description represents, at a first level of hierarchy, a plurality of services, and at a second level of hierarchy, phases of the service.

Thanks to these provisions, the description of the services is detailed for each of the phases of the system, which simplifies the work of the user of the tool.

According to particular characteristics, for at least one screen, the hierarchical description represents, at a first level of hierarchy, a plurality of services, and at a second level of hierarchy, states.

Thanks to these provisions, the description of the services is linked to system states, which simplifies the work of the tool user.

According to particular characteristics, in the hierarchical description, a hierarchical level describes, in a given state, the elementary operations.

Thanks to these provisions, the elementary operations carried out by the system are accessible in the hierarchical description and can be edited by the user of the tool.

According to particular characteristics, for at least one screen, a user can perform a placement of elementary operations on components represented on a synthetic view. Thanks to these provisions, the functional aspects of the system can be implemented on the hardware components of this system.

According to particular characteristics, the tool comprises, for at least one screen, a synthetic view representing an envelope of a component and each elementary operation that said component controls or commands.

Thanks to these provisions, the user of the tool can study the operation of each component and the specifications resulting therefrom.

According to particular characteristics, the tool comprises, for at least one screen, a synthetic view representing an envelope of a service and each elementary operation that said service comprises.

Thanks to these provisions, the user of the tool can study the operation of each service and the resulting specifications.

According to particular characteristics, for at least one screen, the hierarchical description represents computers of the system, at a first level of hierarchy, and at a second level of hierarchy, elementary operations controlled or commanded electronically by each computer.

Thanks to these provisions, the user of the tool can study the operation of each computer and the specifications resulting therefrom.

According to particular characteristics, for at least one screen, a synthetic view represents, for each computer, the services which are, at least partially, placed on said computer.

Thanks to these provisions, the user of the tool can study the relationships between the services and the computers.

According to particular characteristics, for at least one screen, a synthetic view represents, for each computer, the modes in which said computer must operate.

Thanks to these arrangements, the user of the tool can study the relationships between the modes and the computers.

According to particular characteristics, for at least one screen, a synthetic view represents at least one network and the components connected to it.

Thanks to these provisions, the user can study the operation of each network.

According to particular characteristics, for at least one screen, the hierarchical description represents computers of the system, at a first level of hierarchy, and at a second level of hierarchy, for each computer, the data frames passing over the buses to which is connected the computer and / or electronic components (sensors, actuators) directly connected to the computer. Thanks to these provisions, the tool user can study each computer and the interactions it has with other elements of the system, in particular the buses to which it is connected.

According to particular characteristics, for at least one screen, the hierarchical description represents frames, at a first level of hierarchy, and at a second level of hierarchy, for each frame, the data contained in the frames.

Thanks to these provisions, the user of the tool can detail the messaging used and establish the relationships between the frames and the data they contain.

According to particular characteristics, for at least one screen, a synthetic view represents components and / or networks and a projection of a service on said components and / or networks.

Thanks to these provisions, the user of the tool can study each service separately, in terms of physical location.

According to particular characteristics, for at least one screen, a hierarchical level describes, for each elementary operation, the input and output data flows of the interface, for each data flow, the pilot and the component and / or the elementary operation, with which the data stream is exchanged.

Thanks to these provisions, the user of the tool can study the detail of the implementation of an elementary operation, in terms of data flows, of pilots and / or of components.

According to particular characteristics, for at least one screen, the hierarchical description represents, at a first level of hierarchy, a plurality of services, and at a second level of hierarchy, a plurality of service variants, for each service. Thanks to these provisions, the tool makes it possible to deal with different variants of a service in the design of the architecture of a system.

According to particular characteristics, for at least one screen, the hierarchical description represents, at a first level of hierarchy, a plurality of electronic components, and at a second level of hierarchy, a plurality of variants of electronic components, for each electronic component.

Thanks to these provisions, the tool makes it possible to deal with different variants of a component, for example different components from different equipment manufacturers, in the design of the architecture of a system.

According to particular characteristics, for at least one synthetic view, a selection, with a pointing device, of an element of the synthetic view gives access to an operating representation of said element. Thanks to these provisions, the user of the tool can study the operation of the various elements represented in the synthetic view.

According to particular characteristics, for a use case, given a partial or complete placement of the services, all of the elementary operations in the architecture are automatically identified as well as all of the data exchanged (frames, sensors, actuators) corresponding to the realization of the use case.

Thanks to these provisions, if an error is observed, during an integration test, that is to say for a given use case, the components likely to be the cause of the fault can be found. According to particular characteristics, for a use case, if a performance constraint is expressed on said use case, the set of elementary operations in the architecture is automatically identified, the set of frames exchanged, the set necessary sensors and / or all of the activated actuators, so as to respectively assign them execution time constraints, transmission time limits, own activation time limits and / or validate constraints already expressed.

Thanks to these provisions, we will be able to decide on the refreshment constraints of the various data exchanged by elementary operations to which the performance constraint applies.

According to a third aspect, the present invention relates to a system architecture design tool, characterized in that it comprises, for objects, hardware components and / or services offered to the client, a so-called "envelope" graphic representation which comprises :

- an outline representing said object,

- representations of other objects with which said object communicates, and - representations of data exchanged with said other objects.

Thanks to these provisions, the user of the tool has a synthetic view of the interaction of the object with other objects of the system.

According to particular characteristics, when said envelope represents a hardware component, data representations are made for a service. Thanks to these provisions, each material component - service couple can be studied separately.

According to a fourth aspect, the present invention relates to a system representation tool comprising electronic components each connected to at least one bus, characterized in that it comprises, for each bus, a representation of the components which are directly connected to it and, for components directly connected to at least two buses, for each of these buses, associated with said component, an identifier of each other bus to which said component is directly connected. Thanks to these provisions, the user of the tool has a three-dimensional view, without complexity of representation, each bus being represented in two dimensions and the links between the buses being represented, according to a third dimension, by means of the identifiers. . According to particular characteristics, said identifier is a graphic element, for example a patch of a color identical to that of the bus in said representation.

Thanks to these arrangements, the visualization of the relationships between the buses is easy, thanks to the visualization of the graphic element. According to a fifth aspect, the present invention relates to a method for designing a specification of a hardware and software system, characterized in that it comprises:

- a step of defining services and, for each service, use cases;

a step of associating each use case with at least one starting state of the system, one user request and, for each starting state, one arriving state of the system;

a step of defining operations during which, for each state, a set of elementary operations is defined corresponding to the response of the system when arriving in said state; a step of specification of the architecture of the system defining electronic control units and networks;

- a step of placing elementary operations on the computers; and, at least one of the following steps:

a step of identifying the data streams circulating on said networks as a function of said placement; and

a step of identifying the specification of the interfaces of the computers as a function of said placement.

Thanks to these provisions, this process makes it possible to start from the services offered to the user of the system, to determine the operation of the system then to implement the elementary operations implementing the services on computers and to identify the consequences of the implementation in terms of data flows and / or in terms of interface specification.

According to particular characteristics, the placement stage comprises, for each service, a choice from several placement methods comprising in particular: - the placement of the service on a single computer,

- master-slave placement in which an additional elementary operation to control the single service, active, depending on the state of the service in which the system is located, the elementary operations of the service, this additional elementary operation being placed on one of the computers,

- the distributed placement in which the elementary operations are distributed over at least two computers and, on each of said computers, an additional elementary operation for controlling the service is placed and active, depending on the state of the service in which the system is located , the elementary operations of the service placed on said computer.

Thanks to these provisions, the placement of each service can be carried out on one or more components, with corresponding elementary control operations.

According to particular characteristics, the additional elementary operations are generated automatically with:

- as inputs, all the data necessary for the calculation of the transitions of the service control automaton whose states are the states of the service and the transitions the translations, by an elementary operation, of user requests and

- as output, data representing the state in which the service is located. Thanks to these provisions, the work of the tool user is very simplified.

According to particular characteristics, during the step of identifying the data streams, a state of each data stream is determined, with respect to a given messaging system:

- "free" data, to be placed in frames,

- data already placed in a frame and circulating on the network and as produced in the computers where the frame is produced and consumed in the computers where the frame is consumed, and - unused frame locations.

Thanks to these provisions, the data and the frames can be organized, and during the design of the system, it is possible to measure the work remaining to be done to cover all of the data exchanges by the different frames.

According to particular characteristics, given a use case, a performance constraint is expressed on this use case as well as on some of the elementary operations carried out in the arrival state of said use case, the tool synthesizes then automatically the list of executions of elementary operations, executions of pilots, writes and readings in frames, taking into account of information by sensors and actuators, frame transfer on a network implemented following the placement of said elementary operations and the designer can validate that this performance constraint is satisfied for a placement of said elementary operations or specify execution time and / or response time requirements to satisfy this performance constraint.

Thanks to these provisions, it is possible to ensure that the system will have the expected performance and in particular it is possible to develop performance requirements for the various components of the system.

According to particular characteristics, if, for a service having at least two variants, said variants have shared elementary operations, then said elementary operations are placed on the same computers or computer variants. For example, vehicle access variants, one with key, the other without key, will share the basic locking and unlocking operations.

Thanks to these provisions, it is possible to simply manage the diversity of services during the placement stage since there is no need to carry out the placement of an elementary operation shared between several service variants several times. According to a sixth aspect, the present invention relates to a tool for designing a wiring plan, characterized in that it comprises several screens which each include:

- a hierarchical description of the hardware components to be placed

- a two-dimensional representation of the areas on which the components are placed. According to particular characteristics, the two-dimensional representation of the zones on which the components are placed comprises an overall view of all the zones as well as a means of adding or removing zones.

According to particular characteristics, when a zone is selected in the global view of all the zones, a local view of the zone, local view in which geometric characteristics of the zone can be specified, for example by clicking and dragging contour points of the area, appears.

Thanks to these provisions, the specification of the area can be faithful to the part it represents.

According to particular characteristics, you can edit, on the local view of an area by clicking and dragging from a tool icon, routing points, connection points, avoidance subzones and / or mass points.

Thanks to these provisions, the designer can specify preferential crossing points for the routing of the wires which will make it possible to form strands, preferential crossing points from one zone to another and avoidance sub-zones in which no wire cannot pass for example for mechanical reasons or of obstruction, the places of the zone which can be used as mass. According to particular characteristics, a routing point or a connection point between zones can be transformed into a connector by clicking on an attribute of said routing or connection point.

Thanks to these provisions, it is possible to specify the location of the connectors which will allow the wires and strands to be cut into sufficiently small or practical pieces for mounting.

According to particular characteristics, it is possible to specify the location of the various electronic components, the fuse and relay boxes, the electronic control units, the sensors, the actuators, in particular by clicking and dragging on a representation of said components in a hierarchical list.

Thanks to these provisions, the designer can specify the location where these components will be placed in the different areas of the product.

According to particular characteristics, the routing of the various sensors and actuators is automatically synthesized up to the various fuse boxes and relays and electronic control units.

Thanks to these provisions, it is possible to visualize the wiring and to fine-tune the positioning of the routing and connection points in order to reduce the lengths and the shapes of the strands "on sight".

According to particular characteristics, for each sensor and each actuator, data pins associated with pilots (hardware and software) themselves associated with data, power pins corresponding to the power supply and ground pins being specified, the routing of the wires corresponding to these wires is synthesized automatically to the electronic control units or to the fuse boxes and relays for the data, to the relay fuse boxes for the power wires and to the nearest earths respectively.

Thanks to these provisions, the number of pins of the connectors, of the connectors of the electronic control units and of the fuse and relay boxes is evaluated, as well as the size of the different strands.

According to particular characteristics, if a sensor or an actuator is connected to a computer in the system architecture design tool, then, during the routing synthesis, the data pins of said sensor or of said actuator are connected to said calculator.

Thanks to these provisions, requirements for connecting a sensor or an actuator to a computer, for example for contractual reasons with a supplier, are taken into account in the design of the electrical and electronic architecture.

According to particular characteristics, - given a connector cost function, for example based on a chart which gives an estimate of the price of connectors as a function of the number of data, power and mass connections, or based for example on an average price assigned to each connection of a data wire, current or ground,

- given an assessment of the cost of electronic components, sensors, actuators, electronic control units or fuse boxes and relays

- given a cost function of the wires based for example on their length and on their type, taking for example an average linear weight for the power and mass wires, an average linear weight for the data wires, and a cost mass of the component in which said wires are manufactured, an electrical and electronic architecture cost is automatically calculated, based on at least one of said functions and evaluations.

Thanks to these provisions, we can compare the respective costs of two architectures in order to choose the cheapest.

According to particular characteristics, given an average cost for the software and hardware pilots of the different pilots, given a cost of implementing a basic operation, an automatic cost of an electronic control unit or fuse and relay box followed by a complete electrical and electronic architecture.

Thanks to these provisions, the cost estimate is automatic from any placement made in the system architecture design tool of a plurality of services for which estimates have been made.

According to particular characteristics, given a synthesized routing, given quality measurements for the connectors and the wire portions of the different zones, a quality measurement of an electrical and electronic architecture is automatically estimated. Thanks to these provisions, the respective quality of two electrical architectures can be evaluated.

According to particular characteristics, given a measurement of the quality of the various sensor computers and actuators placed in the different zones, the quality of an electrical and electronic architecture is automatically estimated. With these arrangements, the respective quality of two electrical architectures can be evaluated. and electronic According to particular characteristics,

- given a quality measure for each type of input / output, for each type of wire (power, mass, data),

- given a quality measure for the execution of an instruction on a computer, for access in random access memory, for access in flash memory, a quality measure is automatically calculated for the execution of an elementary operation, and for the execution of a set of elementary operations on a computer. Thanks to these provisions, the operating quality of the computers is taken into account precisely in the quality evaluation of an electronic electrical architecture.

According to particular characteristics, candidate routing points are automatically determined in each zone in order to group the power and mass wires in splices and one automatically chooses the one which minimizes the length of wire in said zone.

Thanks to these provisions, the length of the wiring is optimized and the size of the connectors is minimized.

Depending on particular characteristics, splices are taken into account in cost and quality assessments. Thanks to these provisions, these assessments are of better quality.

The present invention relates, according to a seventh aspect, to a method for synthesizing an electrical and electronic architecture of at least part of a product comprising electrical wires and electrical and electronic components such as sensors, actuators and computers, characterized in that it comprises the following stages: - the geometry of the product cut into different zones is represented in two dimensions;

- We place in the different areas, routing points for the routing of electrical wires;

- connection points are placed between the different zones; - the electrical and electronic components are placed in the zones;

- We carry out a synthesis of the routing according to the geometry of the different zones, the positions of the routing points, the connection points and the components;

- an evaluation of this routing is carried out and according to the result of this evaluation; - the locations of routing points, connection points and / or electrical and electronic components are modified and the synthesis and evaluation steps are repeated.

Thanks to these provisions, routing by iteration is optimized. According to particular characteristics, at least one connection point corresponds, in the product, to a connector and / or at least one routing point corresponds, in the product, to a connector.

Thanks to these provisions, we take into account and size the connectors. According to particular characteristics, it is specified inside said zones, bypass subzones in which no wire, component or connector must be placed and, during the synthesis step, it is prohibited that a wire crosses an avoidance subzone.

Thanks to these provisions, the representation is more faithful and takes into account the size of certain areas of the product. According to particular characteristics, before placing the electrical and electronic components, at least one of the following choices is made:

- choice of electronic control units,

- choice of communication networks,

- choice of sensors and actuators, - choice of fuse and relay boxes,

- choice of electrical and electronic architecture.

According to particular characteristics, before proceeding with the routing synthesis, characteristics of the electrical and electronic components are specified.

According to particular characteristics, after the routing summary, the cabling consisting of the synthesized routing and connectors is displayed.

Thanks to these provisions, the placement of the routing points can be perfected by simplifying the geometry of the strands.

According to particular characteristics, the method includes a step of validating a routing among those evaluated, and a technical specification of the wiring consisting of validated synthesized routing and of connectors is calculated, and the calculation is carried out following the technical specification, calculating the cost of wiring and / or calculating a quality measure, for example by estimating the number of breakdowns per million and per year of wiring.

Thanks to these provisions, the designer can compare different architecture solutions and transmit the specification of the architecture chosen to the development and debugging team. According to particular characteristics, the product is a vehicle and the different areas of the vehicle include at least one of the following areas:

- the front panel area,

- the hood area, - the dashboard area,

- the pavilion area,

- the boot and tailgate area, above and below the above areas,

- the area of the right front wing and the left front wing, - the area of the right front door and the left front door,

- the right upright and left upright area,

- the area of the right rear door and the left rear door,

- the area of the right rear wing and the left rear wing, between the dashboard area and those of the right front wing and the left front wing, the areas of the right front upright and the front upright left, between the boot area and those of the right rear wing and the left rear wing, the right rear pillar and left rear pillar areas,

- an area above the floor and an area below the floor. Thanks to these provisions, the method can be applied to a motor vehicle.

Other advantages, aims and characteristics of the present will emerge from the description which follows, given with reference to the appended drawings, in which:

FIG. 1 schematically represents the different stages of the method according to the invention,

FIG. 2 is a top view, in plan of the different zones of a motor vehicle,

FIG. 3 is a schematic view of elements for describing zones,

- Figure 4 shows routings validated in a vehicle door area, - Figure 5 shows an example of the wiring of a vehicle door,

FIGS. 6 to 16 represent screens used for the design of an electronic and computer system architecture,

- Figure 17 shows steps implemented for the specification of a service variant, and - Figure 18 shows steps implemented in a method of designing a system architecture according to the present invention. Before detailing particular embodiments of different aspects of the present invention, explanations are given here on the terminology used.

- The terms "vehicle" and "product" are used interchangeably, the scope of the present invention not being limited to vehicles but the particular embodiments being detailed for a product consisting of a vehicle.

- the terms "estimate" and "evaluation" are used interchangeably.

- for the sake of brevity, the term "tool" means "system architecture design tool". - When, in the context of the description, the difference between an electronic control unit or a fuse and relay box is not significant, we will simply speak of a computer. When the management of diversity of computers is discussed, we will talk about the type of computer for a generic computer of an on-board network, such as for example the injection computer of a motor vehicle and the computer variant for a particular instance d 'a type of computer, for example such gasoline injection controller produced by such an equipment supplier always for a motor vehicle. When we discuss on-board networks, we will speak of a network node to speak of a type of calculator, or a variant of a calculator depending on the case, connected to a network, to remain consistent with the terminology conventionally used. The concept of component will generally refer to a sensor or an actuator as opposed to a computer. An electronic component will on the other hand be as well an actuator or a sensor as a computer or another intelligent component also called in English "smart component". An electronic electrical component will designate any type of component. In practice, these distinctions will be clear from the context of use.

Finally, we will simply speak of "response" to speak of a response to a user request.

FIG. 1 schematically represents the stages of the process followed to carry out the routing of the wires of the electrical and electronic architecture as well as its evaluation. Certain links between some of the stages are symbolized by arrows. For example, the arrow between steps 102 and 104 indicates that step 104 is performed after step 102. On the other hand, there is no link between step 104 and step 106, these two steps can be performed in any order without affecting the quality of the result. To carry out the routing of the wires and its evaluation, the method comprises:

a step 102 during which the geometry of the vehicle is specified, in the form of zones, for example by implementing a computer which displays the illustrated screen in Figure 13 and has software to perform the functions described with reference to Figure 13; At the same time as this step 102, at least one of the following choices is made:

- choice of electronic control units,

- choice of communication networks, - choice of sensors and actuators,

- choice of fuse and relay boxes,

- choice of an electrical and electronic architecture and specifications of the electrical and electronic components are specified.

a step 104 during which so-called "avoidance" sub-zones are placed in the zones defined during step 102, as explained with reference to FIGS. 13 and 14;

a step 106 during which routing points and connectors are placed, in particular between the zones defined during step 102;

- a step 108 during which the components are placed - a step 110 during which the software which implements the first aspect of the present invention automatically performs a synthesis of signal routing, an example of such routing being presented in Figure 5;

a step 112 during which the software automatically synthesizes the routing of the power, an example of such routing being proposed in FIG. 5;

a step 114 during which the software automatically performs a synthesis of the mass links, an example of such routing being proposed in FIG. 5;

a step 116 during which the software automatically performs an evaluation of the cost of routing, from functions for estimating the costs of connectors and wires as a function of their size and of functions for estimating the costs of the various electronic components and by summing the costs of the elements making up the architecture;

a step 118, during which the software automatically performs an evaluation of the quality of the routing on the basis of functions for estimating the quality of the connectors and the wires as a function of their size and of functions for estimating the quality of the various electronic components; and

a step 120, during which the software automatically performs an evaluation of the weight of the routing, from functions for estimating the weight of the connectors and the wires as a function of their size and from functions for estimating the weight of the various components electronic. Depending on the result of these evaluations, the location of the routing point, of the connection and of the electrical and electronic components is modified, steps 106 and 108 for an improvement and the synthesis steps 110, 112, 114 are repeated to proceed. to a new evaluation and iteratively converge towards an optimized solution. When an optimized solution is determined, we proceed to the calculation of a technical specification of the wiring consisting of validated synthesized routing and connectors

FIG. 2 schematically represents the division into zones of a product, in this case a 5-door motor vehicle with a tailgate. The different areas of the vehicle are shown in a top view. These different zones include: a right front wing zone 202, a right front door zone 204, a right upright zone 206, a right rear door zone 208, a right rear wing zone 210, a right front upright zone 211, a rear upright zone right 212, a tailgate area 214, a roof area 216, a cockpit area 218, a hood area 220, a front left upright area 222, a right rear upright area 224, a front face area 226, a front left wing area 228, a front left door area 230, a left upright area 232, a right rear door area 234, a left rear wing area 236, and a floor area 240.

These zones are, in FIG. 2, represented together and oriented according to a "compass" 238, placed for information, which intuitively allows the person skilled in the art to navigate in each zone knowing how it is situated in relation to those which surround, both in representation and in reality. Compass 238 indicates how the zones are located relative to each other, but does not apply to each zone in particular. For example, the "right front wing" 202 and "right front door" areas 204 are placed so that it can be deduced that the "right front wing" area 202 is at the front of the "front door" area right "204. However, these two zones are vertical and, locally, will not be represented according to the directions indicated by the" compass "238.

Similarly, it can be seen in FIG. 2 that the "right upright" area 206 is to the right of the "pavilion" area 216, but the "pavilion" area 216 is horizontal and will be represented in a local view according to the orientations indicated by the " compass "238 while the" upright upright "206 is vertical. The "compass" 238 therefore serves to locate the zones between them but does not necessarily apply to the description of the content of each zone.

FIG. 3 schematically represents elements for describing zones and illustrates how are placed on a "horizontal floor zone" zone 318 corresponding in FIG. 2 to the floor zone 240, a connection point 302, a routing point 312, a connector placed in place of a routing point 304 or in place of a connection point 316, an avoidance zone 314, components 306 and 308, whether they are sensors, actuators, electronic control or fuse and relay boxes. Zone routing is carried out, the component 306 being routed to the connection point 302 via the connector 304 and the component 308 being routed to the connector 316 via the routing point 312. On the other hand, FIG. 3 illustrates the connections between zones schematized by the broken line between, on the one hand, the connection point 302 of the horizontal floor area 318 and the connection point 320 of the connected vertical area 324 and, on the other hand, the connector 316 of the horizontal area floor 318 and the connector 322 of the connected vertical zone 324. The "compass" 326 indicates how to orient the horizontal zone floor 318 while the "compass" 328 indicates how to orient the connected vertical zone 324. It is noted that these two zones are perpendicular , the horizontal floor area 318 being written in a horizontal plane while the related vertical area 328 is written in a vertical plane. The connection points 302 and 320, when associated, represent the same point in space, that is to say a point of physical contact between the horizontal floor areas 318 and related vertical 324. Similarly, the connectors 312 and 316 are joined by a standard "male / female socket" type mechanism, for example the connector 312 is a male connector and the connector 316 is a female connector and these two connectors are physically linked at a point of physical contact between the zones horizontal floor 318 and related vertical 324.

FIG. 4 diagrammatically represents valid routes in a left front door zone 414 corresponding to the left front door zone 230 illustrated in FIG. 2. The avoidance sub-zones 418, 420 and 422 are hatched, and components are shown, in particular a window regulator control button 402, a light for the window regulator control button 404, a locking motor 406, a window regulator motor 408, connectors 410 and 412. Reading of the zone 414 is simplified using the "compass" 416. On the other hand, routing points 451, 452, 457 and 458 have been placed. It is noted that certain vertices of the avoidance subzone 422 are specifically useful for routing, that is to say electrical wires or links, 454, 455 and 456.

FIG. 5 schematically represents a routing of a set of wires over two zones, on the one hand, a left front door zone 414 and, on the other hand, a cockpit zone 510.

Some components are common to FIGS. 4 and 5. Others, in particular in the cockpit area 510 are added: a ground point 504, an electronic control unit 506, a fuse and relay box 508 and the connectors 502 and 512, corresponding respectively to connectors 410 and 412 of the front left door zone 414. The link between the connectors of the two zones is symbolized by the dotted lines in FIG. 5. In practice, the connectors 502 and 410, for example, are joined by a standard mechanism type male / female socket as shown opposite figure 3.

A two-dimensional representation of the product is carried out as follows: the product is divided into zones whose dimensions must be specified in order to stick to the better to the geometry of the product considered. This representation is in particular satisfactory for a motor vehicle insofar as the wiring can be largely fixed directly to the sheets and therefore to a decomposition of the vehicle into flat zones, as detailed in FIG. 2. Each zone represented is preferably vertical or horizontal . For example, one can associate the floor of a vehicle with a horizontal zone and a door of a vehicle with a vertical zone. For a tilted tailgate, you can choose one or the other of the representations. In addition, one can indicate the left and the right, the front and the back, the top and the bottom of said zone. The aim of these guidelines is in particular that a person skilled in the art can easily find his way from one zone to another, or from a global view, in which all the zones are represented, to a local view, in which a only one area, for example, is shown.

Figure 2 shows a top view of the different areas of the upper part of a five-door passenger compartment (including the tailgate). The division into logical zones is specified, but the respective dimensions and the shapes of the zones are not shown in FIG. 2. The zones are oriented in FIG. 2 since the front, rear, left and right of the top view are indicated. Some rooms are horizontal, like the pavilion, and others vertical, like the doors.

Each zone can contain avoidance sub-zones, that is to say zones in which no wires can be passed. For example, in the tailgate of a vehicle, the window will correspond to an avoidance sub-area.

For reasons of simplicity, the zones can be represented by simple geometrical figures such as for example polygons or even more simply quadrilaterals. Each zone has its frame of reference and the avoidance sub-zones of a zone A are forms inscribed in A, preferably in the form of a polygon or a quadrilateral.

FIG. 3 represents a zoom in on an area of the type described in FIG. 2. It is an area inscribed in a horizontal plane as indicated by the compass 328. It is called "horizontal floor area". In the center of the room, a hatched shape indicates an avoidance sub-area 314. The hatched shapes, in Figures 4 and 5, similarly indicate the avoidance sub-areas 418, 420 and 422.

Each zone is, moreover, linked to the other zones by connection points which are used to specify the geometric links between the different zones and to specify locations where the wires can pass from one zone to another. A connection point between two zones is therefore represented on each of these zones. A connection point can be a connector. In this case, there is a connector on the two areas it links. In Figure 3, the link between two areas, through connection points, is illustrated. The "horizontal floor area" area 318 is linked to the "connected vertical area" area 324 by two connectors 302/320 and 316/322. These two connectors are located at equal distance from each other on each of said zones. The routing points are wire grouping points proposed, in each zone, by the designer and which make it possible in particular to group the wires into strands. Preferably, all the vertices of an avoidance sub-area are routing points so that there is always a solution to the problem of routing in an area. On designer specification, a routing point can be a connector. In Figure 3, two routing points 304 and 312 are shown, one of which,

304, is actually a connector.

Routing between two points (for example between a sensor and an actuator) consists of a sequence of routing or connection points. The wire synthesized according to a routing is assumed and represented rectilinear between two successive routing or connection points.

A routing is said to be valid in an area if, on the one hand, it does not cross any avoidance sub-area and if, on the other hand, given two successive routing or connection points A and B of the routing, then there is no routing point C attainable without crossing an avoidance sub-area and such that the lengths of the segments AC and BC are less than the length of the segment AB.

A route crossing several zones via connection points between zones is valid if it is valid in each zone.

The length of the routing of a wire is the sum of the distances between the successive routing or connection points which form the routing. Routing is optimal if the routing length is minimum among all possible valid routes.

To find the optimal routing between two points, we can for example enumerate all the valid valid routing between these two points not having a loop (ie which never passes twice by the same routing or connection point) and choose the shortest route. In Figure 4, points 451, 452, 453, 454, 455, 456, 457 and 458 are routing points. Points 410 and 412 represent connection points between areas containing connectors. We note that 454, 455 and 456 are also vertices of an avoidance subzone. There are many possible routes to route the locking motor 406 to the connector 412: we can cite the routing (406 - 451 - 452 - 458 - 412) and (406 - 454 - 455 - 456 - 457 - 458 - 412). In fact the routing (406 - 451 - 452 - 458 - 412) cannot be appropriate because it crosses an avoidance sub-zone. Finally, the shortest route respecting all the clauses is (406 - 454 - 455 - 456 - 458 - 412). In practice the routing is calculated between two components rather than between a component and a connection point with or without a connector in an area.

The following electronic and electrical components are placed on the different product areas. These components are: - electronic control units: these are electronic components capable of controlling data signals, that is to say of low power, used in particular to transport software data or data that can be interpreted by software, in particular coming from a sensor or to an actuator; sensors and actuators; - fuse and relay boxes: these are electronic components capable of controlling both low-power signals and high-power signals, which are simply referred to as power signals; sources: are energy sources, typically a battery - a source can be compared to a particular fuse and relay box; The electronic control units preferentially ensure the logical control of the components while the boxes ensure the relay of their supply and the sources supply the supply of the assembly. As their name suggests, the fuse and relay boxes contain for example the fuses protecting the different loads (components consuming energy) placed on the different wires linked to the said boxes and also preferentially contain relays allowing the activation of the loads requiring power.

Preferably, the various elements of the electrical and electronic architecture are represented by points, that is to say associated with two coordinates in the frame of reference of the area on which they are placed. Ground points are also placed. The ground points are such that a so-called ground wire, connected to a ground point, is at zero electrical potential. Ground points are specified by the designer. The electrical and electronic architecture is given by: the choice of electronic control units, the choice of communication networks, - the choice of sensors and actuators, the choice of fuse and relay boxes, the logical links of these different components to each other These links are, in particular, the connections of the electronic control units and of the fuse and relay boxes to the various communication networks. These links can also be explicit links between a sensor or actuator and an electronic control unit or a fuse and relay box. In particular, since for example a sensor can have several electrical links with its environment, for example a ground link, a power link and a link for the transmission of information, said sensor can be simultaneously linked to a ground, a fuse and relay box and an electronic control unit. The routing of all the wires is carried out in stages for a given placement of the various elements of the architecture.

(A) The routing of a data signal from an input-output of a component to an input-output of an electronic control unit is carried out as follows:

(a) If the attachment of the data signal of the component (sensor or actuator) is specified, that is to say that it has already been defined to which electronic control unit the component is linked for said data signal, then it this is the optimal routing between the sensor and the electronic control unit.

(b) If the signal attachment is not specified, then the component is preferably attached to the nearest electronic control unit, that is to say that (i) the optimal routing Ci is calculated to join the component to the Calci electronic control unit by applying the previous step (a) and (ii) then selecting the shortest route and the corresponding one or one of the electronic control units, ie Cal such that Cj = min Ci.

(B) The routing of a power signal from an input-output of a component to an input-output of a fuse and relay box is carried out as follows:

(a) If the attachment of the power signal of the component (sensor or actuator) is specified, that is to say that it has already been defined to which fuse and relay box the component is linked for said power signal, then it this is the optimal routing between the sensor and the fuse and relay box. (b) If the connection of the power signal is not specified, then the component is preferably attached to the nearest fuse and relay box, that is to say that (i) the optimal routing Ci is calculated to join the component to the CalCj fuse and relay box by applying the previous step (a) and (ii) the shortest routing and then select one or one of the corresponding fuse and relay boxes, ie Calq such that Cj = min Ci .

(C) Regarding the routing of a ground signal from an input-output of a component, this component being a sensor, an actuator, an electronic control unit or a fuse and relay box.

The component is preferably attached to the nearest mass point, that is to say that (i) the optimal routing Ci is determined to reach each mass M, and (ii) we then select the shortest routing or one of the shorter Mj such that Cj = min Ci. (D) Routing of a network between computers

The network topology characteristics must be known: such a network is preferably organized in a star, in line or in a loop depending on the case.

For a CAN network for example, star or online topologies are possible. Preferably, the designer will indicate his recommendation. The reasons for choosing a topology are very varied. For example, the star network may be preferred for reasons of operational safety because in the event of a bus interruption, only one computer is isolated while in the event of an online topology, the network is cut in half and the consequences are a a priori more serious. For a chosen topology, we then look for routes that minimize the distance between the computers.

For a star topology:

(a) We choose a point of contact between the branches,

(b) We are looking for the optimal routing of this point with each of the electronic control units or each of the fuse and relay boxes connected to the network,

(c) The sum of the lengths of said optimal routes is calculated,

(d) The three preceding steps are applied for each of the existing contact points and

(e) We retain the contact point which minimizes the length of the network. For an online topology:

(a) We choose a routing point allowing each electronic control unit or each fuse and relay box to be disconnected from the bus. The bus itself being formed by the assembly a sequence of said routing points which do not intersect an avoidance sub-zone, (b) The assembly of said routing points is determined making it possible to connect each electronic control unit or each fuse and relay box on the bus which minimizes the length of the network, for example by successive tests.

(E) Routing of a power signal from a C computer.

It is treated like the routing of a power signal from a sensor to a fuse and relay box.

In FIG. 5, the area "left front door area" 414 and its connection with the area "cockpit extract area" 512 are shown.

The complete routing of the various components of said zones is carried out. The components are first of all linked to the UCE 506 electronic control unit. The different routings generated are therefore, using the notations used to describe Figure 4: - engine from 406 to UCE 506: (406 - 451 - 452 - 410 - 506), - window regulator motor 408 at ECU 506: (408 - 458 - 412 - 506),

- window regulator control button 402 to ICE 506: (402, 452, 410 - 506),

- lighting of the window regulator control button 404 at the ECU 506: (404 - 452 - 410 - 506), and - from the ECU 506 at the BFR 508: (506 - 508).

The electrical characteristics of the various components can be specified: number of interface pins, nature of pins (data, mass, power), attachment of data or power pins if they are specified, minimum operating voltage, average current, inrush current, power consumed, and this for each power wire leaving the component.

The routing evolves consequently since it is necessary to route each wire separately and to specify a pin for each connector involved in the routing of a new wire.

In FIG. 5, the motors 406 and 408 can each have three data wires, power and mass, respectively, and therefore comprise connectors with three pins. This time, the links to earth M 504 and to the BFR 508 fuse and relay box, which had not been expressed until now, appear in the form of new routes:

- locking motor 406 / pine 1 at ECU 506 / pine 1 (data): (406 / pine 1 - 451 - 452 - 410 / pine 1, 506 / pine 1),

- window regulator motor 408 / pine 1 at ECU 506 / pine 2 (data): (408 / pine 1 - 458 - 412 / pine 1 - 506 / pine 2),

- locking motor 406 / pine 2 at BFR 508 / pine 1 (power): (406 / pine 2 - 451 - 452 - 410 / pine 2, 508 / pine 1),

- window regulator motor L 408 / pine 2 at BFR 508 / pine 2 (power): (408 / pine 2 - 458 - 412 / pine 2 - 508 / pine 2), - locking motor 406 / pine 3 at mass 504: (406 - 451 - 452 - 410 / pine 3 -

504), and

- window regulator motor 408 / pine 3 with mass 504: (408 - 458 - 412 / pine 3 - 504). The pins are not noted for a link to the ground because it is preferably a screwing or similar means. We can then calculate the technical specification of the wiring composed of the following results:

- the logical wiring plan: this is the description of all the wire segments necessary to achieve the electrical-electronic architecture. Each wire connects a pine of a connector of a component to a pine of another connector of another component and passes, moreover, by a certain number of routing and connection points as specified above. It is the data of the two connectors and the pins of each connector at the ends, i.e. at the level of the connected components, the sequence of points of routing, as well as the sequence of connector pins, in particular between zones, crossed, which logically defines the wire. The logical wiring plan is the data for all the logical definitions of the wires that constitute it.

- the specification of the connectors: for each connector, it is the number of connections corresponding to data wires, the number of connections corresponding to power and the number of connections corresponding to ground wires which constitute the specification.

- the specification of the interfaces of the electronic control units, of the fuse and relay boxes and of the sensors and actuators: these are the descriptions of the connectors of these components, in the form of data pins, power and mass.

In Figure 5, connector 410 now provides five connections, three of which are data, one power, and one ground.

The user may also wish to calculate or evaluate the cost of an electrical and electronic architecture, in particular in order to compare such architectures and choose the least costly with equal service and quality.

Given a cost function of connectors, for example based on a chart which gives an estimate of the price of connectors according to the number of data, power and mass connections, or based for example on an average price assigned to each connection of a data wire, current or ground. Given an assessment of the cost of electronic components, sensors, actuators, electronic control units or fuse boxes and relays.

Given a cost function of wires based for example on their length and on their type, taking for example an average linear weight for power and mass wires, an average linear weight for data wires, and a mass cost of the component in which said wires are produced.

A cost evaluation is automatically deduced from the technical specification for the electronic and electronic architecture considered by summing the costs of all the electronic components, all the connectors and all the wires.

To estimate the cost of implementing an elementary operation, one can for example proceed as follows: given a number N of assembly lines evaluated for each elementary operation placed on a computer, and an activation period P for each operation elementary in seconds, given an average cost Cl of the execution of an instruction per second on a processor, given the memory space MEMO necessary for the data that the elementary operation exchanges with the other elementary operations and the pilots; given an estimate of the CRAM cost of a bit in RAM memory and a CROM estimate of a bit in ROM memory or Cflash in flash memory. Given the number of bits in a word, i.e. the characteristic of being n-bit (eight, sixteen or thirty-two for example) of the microcontroller, the cost of an operation is:

(N / P) ^* CI + N * n ^* CROM + MEMO ^* n * CRAM.

On some 32-bit microprocessors, some instructions occupy 16 bits, which in particular saves memory. This characteristic can be taken into account by separating these two types of instructions if we can evaluate a mix for the elementary operation considered and by consuming half the ROM for the instructions on

16 bit.

It should be noted that the cost C1 of the execution of an instruction per second on a processor can depend on the type of application which one processes, all the instructions not being carried out in as many cycles. For example on a processor of twenty MIPS (Million Instruction Per Second), one can carry out twenty million instruction of a cycle in one second, but only one million instructions of twenty cycles. So according to the average number of cycles per instruction required for each type of application, we specify this evaluation. It is important to note that the average cost of an instruction, a bit of RAM and a bit of flash on a microcontroller can, for example, be extrapolated from the observation of at least three microcontrollers (i ) of which the cost (C,) and the memory characteristics RAM (Ri), MIPS (M and Flash (F,), and (n,) the bit number of a word are known.

Indeed for each microcontroller, we establish the equation with unknowns Cl, CRAM, Cflash: and Such a system of three equations has a single solution, the different constants being non-zero. When looking at many controllers, this estimate can of course be refined. It should be noted that if the elementary operation is the automatic control of a service, then the estimate of the number of lines of code is determined as a function of the number of states and the number of transitions and the period of activation is determined according to the performance requirements for the different use cases.

On the other hand, the cost of the various hardware pilots can be assessed according to their type (all or nothing, analog-digital, etc.) and their electrical characteristics.

The user may also wish to evaluate the quality of an electrical and electronic architecture, in particular in order to compare such architectures and choose the one which presents the best level of quality, with identical service and cost. The measurement of quality is preferably done by measuring the number of failures per million units and per year of the entire architecture, preferably using software. To calculate this number

• the software measures the quality of all connectors, whether they are connectors between zones or within zones or I / O connectors for electronic components (sensors, actuators, electronic control units, boxes fuses and relays) by assigning for example an average failure rate per connection, for example 10 ppm (failure per million units per year) and by multiplying this average rate by the total number of connections in the system. To obtain a more precise evaluation, the software takes into account averages adjusted according to the type of connection: mass, power and data, the finest wires being the most fragile. For example, we take 4 ppm per connection of power or ground wires on a pin and 6 ppm per connection of data wires on a pin, and finally an estimate of 4 ppm per portion of data wire between two connectors. In this case, if we take again figure 5, and the detail of connections and wire presented in description of figure 5, one can carry out the following evaluation for each section: - locking motor 406 / pine 1 to the UCE 506 / pine 1 (data): (406 / pine 1

- 451 - 452 - 410 / pine 1, 506 / pine 1): 3 ^* 6ppm + 2 ^* 4 ppm or 26ppm

- window regulator motor 408 / pine 1 at ECU 506 / pine 2 (data): (408 / pine 1 - 458 - 412 / pine 1 - 506 / pine 2): 3 * 6ppm + 2 ^* 4 ppm either 26ppm

- locking motor 406 / pine 2 at BFR 508 / pine 1 (power): (406 / pine 2 - 451 - 452 - 410 / pine 2, 508 / pine 1): 3 * 4ppm or 12 ppm

- window regulator motor L 408 / pine 2 at BFR 508 / pine 2 (power): (408 / pine 2 - 458 - 412 / pine 2 - 508 / pine 2), 3 * 4ppm or 12 ppm

- locking motor 406 / pine 3 with mass 504: (406 - 451 - 452 - 410 / pine 3 - 504), i.e. 3 ^* 4 ppm - window regulator motor 408 / pine 3 with mass 504: (408 - 458 - 412 / pine 3 - 504). or 3 ^* 4 ppm for a total of 100ppm

If, now we take into account a splice at 452, then the ppm corresponding to the duplication of wires downstream of the splice, seen from the actuators 406 and 408, are to be deleted, ie 3 * 4 ppm. Taking into account a power splice we find 88ppm as the quality of the optimized routing. Taking into account a mass splice at the same routing point saves another 12 ppm to reach 76 ppm. Optimization on a cost estimate would similarly consist of eliminating the cost of the portions of wires and connector pins removed by means of the splice. "the tool measures the quality of electronic components which is specified in a component database and can be described according to the type of component or specifically for each component, for example you can attach an evaluation at 100 ppm to all electronic control units.

• The tool then adds the measurements of all the components making up the electrical and electronic architecture. The user can also refine the routing strategy by integrating splices for power wires and ground wires. These splices can be made at the connectors or within an area, preferably at a routing point.

Making a mass splice consists in joining all the (n) ground wires passing through a point, and in particular at a connection point or a routing point. In this way, going back to the nearest mass, one saves on the one hand wires and on the other hand connection pins corresponding to the (n-1) wires removed.

Making a power splice consists of joining power wires which, on the one hand, pass through a common point, in particular through a connection point or through a routing point, and, on the other hand, join loads to a common fuse and relay box. For example in FIG. 5, the power supply wire of the locking motor 406 and the power supply wire of the lamp 404 can be joined at the level of the routing point 452 or even at the level of the connector 410. Such splices serve to save pins at the connectors and the pieces of wire thus removed. We therefore seek to minimize the length of the wires and we will choose to practice splicing at routing point 452 in order to save the lengths of wire between 452 and 410. Point 452 is the one that minimizes the lengths of wire for the realization of the splice in the example of figure 5.

Practicing a splice at the level of a connector amounts to linking together the pins of the connector corresponding to the wires that one wishes to join.

We can then improve the routing synthesis by looking if one or more splices of the ground wires or power wires would minimize the overall cost of the architecture. For this, new data must be entered in the cost base of the unitary components, in particular the cost of a splice as a function of the number of wires joined and the cost of a splice at the level of a connector as a function of the number of wires joined. .

FIGS. 6 et seq. Describe a system architecture design tool and a method for designing a specification of a hardware and software system implementing this tool.

This tool is particularly suited to the case of complex systems comprising a set of computers performing numerous services or benefits for the benefit of a user, each service has many use cases. For example, vehicle electronic and computer systems are particularly targeted by this tool. Services are defined by what the user wants (for example the start of air conditioning, wipers) or by what is offered (for example passive safety, especially in the event of accidents) . They are also defined by sensors and / or actuators which they implement. They each correspond to a sensor / software / actuator hardware implementation. The manufacturer has a margin of maneuver in the definition of the internal architecture of the electronic / IT system, in particular in the choice of on-board networks and electronic boxes connected to these networks and the design tool presented here allows the design of this architecture.

From the services, the design tool makes it possible to determine specifications rather than finished products. However, this tool also determines interfaces and what must include the elements and their communication with the electronic / computer system.

In particular, this tool does not aim to program the computers automatically but to manage cost / quality / time compromises of the specified system. The design tool is implemented in the form of software running on a personal computer and using a known database and resources (operating system and distribution over the network).

In accordance with one aspect of the present invention:

each service represents a service rendered to a user, a set of formalized use cases of each service is defined, each formalized use case comprising an original context, a user request, possibly implicit, and a response from the system corresponding to a change in its state, and

- the system is organized and specified to carry out the response, upon detection of rejection of the request in the original context.

To this end, according to one aspect of the present invention, the method comprises a step of designing, for each service, an automatic service control controller intended to be implemented by the system of hardware and software components and which represents the behavior of this system. This design step comprises, for each service, a step of defining a formalized use case of the service, specified by a context, a request from a user to the system and a response from the system corresponding to a change in its state. and, iteratively, until all cases of use of the service have been treated:

a step of adding a formalized use case of the service, specified by a context or initial situation of the system, a request from a user to the system and a response from the system corresponding to a change in its state, - and, iteratively, for each state already constructed, we seek whether it is compatible with the context of the added formalized use case and, if so, we construct a new state of the system linked to said state already constructed by the request of the added formalized use case, the new state taking into account the already constructed state and its modification by the response of the added formalized use case.

In this way, for the service, the service control automaton consisting of all the state pairs linked by the requests forming the transitions of said automaton is synthesized.

The context represents at least one mode (or parameter) of operation of the system, the modes being transversal to the services and outside of direct control of the services, for example a mode representing a level of available energy (low battery, on battery, in progress starting mode, with the engine running, for example), another mode representing a type of system user (designer, manufacturer, vehicle owner, vehicle driver or passenger, after-sales service, car garage, for example) and another mode representing an accident or not state of a vehicle. It should be noted that, although starting the engine is one of the vehicle's benefits, the change in available energy level (linked to the alternator being driven by the engine) is not directly under control of this service.

In the embodiment described here, any context is part of a system life phase consisting of a combination of vehicle operating modes, the declination in phase mode thus being transversal to the services. Ultimately, a context will correspond to a set of couples (phase, state of the system), each state being in fact characterized by the system response when accessed.

For example, the use case "in the context where the vehicle is condemned, the user presses his unlocking badge and the vehicle unlocks" applies to the "vehicle locked" states in the "engine running" phases and "engine stopped", if these two phases have been identified as relevant by other formalized use cases of the "unlocking" service. Each phase corresponds to a set of combinations of modes in which the behavior of the service is uniform, that is to say that the same states and the same customer requests are observed, or, put differently, the same customer requests and same system responses from a given state.

The table below defines a set of phases for a given vehicle. ENERGY USER VEHICLE STATE PHASE low battery designer vehicle accident-free phase 1 low battery designer vehicle accident-damaged phase 2 low battery manufacturer non-accident vehicle phase 1 low battery manufacturer damaged vehicle phase 2 low battery owner non-accident vehicle phase 3 low battery owner accident vehicle phase 2 low battery driver non-accident vehicle phase 1 low battery driver accident vehicle phase 2 low battery after-sales vehicle no accident phase 4 low battery service vehicle accident phase 5 battery low garage vehicle not accident phase 4 battery low garage vehicle accident phase 5 normal battery designer vehicle non accident phase 6 normal battery designer vehicle accident phase 2 normal battery manufacturer vehicle non accident accident phase 6 normal battery manufacturer vehicle accident phase 2 normal battery owner vehicle non-accident phase 7 normal battery owner vehicle accident phase 2 normal battery driver vehicle non-accident phase 6 normal battery co nductor accident vehicle phase 2 normal battery service vehicle accident free phase 4 normal battery service vehicle accident vehicle phase 5 normal battery garage vehicle not accident phase 4 normal battery garage vehicle accident phase 5 start designer non-accident vehicle phase 8 start designer accident vehicle phase 9

In this table, all the operating mode triplets are mapped to phases, each phase representing a set of combinations of the possible values of the operating modes. If the behavior of the vehicle is always the same, only one phase is defined in the table, if not, there is differentiation of several phases.

All of the formalized use cases represent all the responses or non-responses of the system in all the phases of the system.

The tool allows a completion step during which, for each response, that is to say a state of the system, we consider all the customer requests not yet processed and we ask the designer if a processing of the request must be performed in the state corresponding to this response. Only customer requests can have an effect on the service. The design tool also allows for a correction step during which if, in the same starting state, two states of the service control automaton are linked by different requests, then the need to define a priority between system responses and this priority is incorporated as an attribute of the state outputs. Priority information typically comes after the design of formalized use cases. It is possible that for mechanical or other reasons, two potentially competing demands may never in fact be possible simultaneously. In this case you have to wait for a more advanced design step to be sure that it is not necessary to specify a priority, unless this can be guaranteed directly (for example: opening a door and closing the same door cannot be done simultaneously). In addition, if two identical requests lead to different states, then there is an inconsistency to be corrected and one of the requests must be deleted and the corresponding use case must be specified accordingly.

We observe that a change of context is taken into account by the system as follows:

- each change of context is a change of state object of a CUF;

- responses to changes in context are defined as formalized use cases;

- contextual changes are defined as formalized use case requests.

If a service influences another (for example the same display is shared by two services, for example car radio and navigation system), a service is added for the intersection part, so as to resolve conflicts between services. The purpose of this service will be to arbitrate when two concurrent actions are applied to a component given by two services, which of the services takes precedence or if a specific action corresponding to this particular case must be carried out. Such a service is typically not specified from the use case but rather by identification of the states of the two services in which reactions leading to conflict (with respect to one or more given components) are identified. The service control automaton is produced by programming at least one control computer for the corresponding service.

The tool has different pages accessible by clicking on tabs. These pages are described with reference to Figures 6 to 16. For the sake of clarity, in Figures 6 to 16, the titles of the tabs and list items selected by the designer are underlined and in bold.

As illustrated in FIG. 6, the user interface 600 of this software tool comprises: - drop-down menus 601 to 608,

- six horizontal tabs 611 to 616,

- a hierarchical list box 620 and

- a graphic area 630. The drop-down menus 601 to 608 are represented by their titles "File", "Edit",

"View", "Dictionaries", "Windows", "Tools", "Import / export" and "Help". By clicking on one of these titles, with the left mouse button, a drop-down menu appears with options participating in the implementation of the process (opening, editing, saving, closing a file, cutting, copying, paste selected elements, viewing modes, lexicon, tools, import or export of files, help ...). When working on the design of an electronic and computer system architecture for a vehicle, the designer does not necessarily have to use these drop-down menus 601 to 608.

Whatever the tab selected, among the tabs 611 to 616, the design tool presents a screen comprising a hierarchical list part (on the left in FIGS. 6 to 16) representing a hierarchical description and a graphic part (on the right on FIGS. 6 to 16) giving, as a function of a selection, via a pointing device (in the following description, a mouse), of an element of the hierarchical list, a synthetic view concerning the selected item. It is important to note here that, for at least one user interface of the design tool, that is to say for at least one tab, a hierarchical level of the hierarchical list represents services. In the embodiment illustrated in the figures, the first three tabs 611 to 613 have this characteristic.

With a mouse (not shown), the user can bring up pop-up menus (in English "pop-up menu") by clicking on one of the right or left mouse buttons, in one of the list boxes or graphic.

To design the architecture and specifications of the system, the user successively selects horizontal tabs 611 to 616 by clicking on them, knowing that one of the qualities of the design tool is that the user can select the tabs in the order he wants.

The horizontal tabs have the following titles:

- "Requirements", tab 611,

- "Feature description", tab 612,

- "Feature architecture", tab 613, - "Operational Architecture", tab 614,

- "Hardware architecture", tab 615, - "Frame description", tab 616.

These tabs represent, in this order, several stages of the process which is the subject of the present invention:

These titles appear in full when the corresponding tabs are selected and in abbreviated form ("REQ" 611, "FUNC" 612, "MAP" 613, "OPER" 614, "HWD" 615 and "MSG" 616, respectively) the rest of the time.

To design the architecture of a system, the designer first selects the 611 "Requirements" tab and observes the screen illustrated in FIG. 6. We observe, on the left, the hierarchical list box 620 which includes a part d '' a list with the five highest hierarchy levels: vehicle name services or services service variants use case link between states

As is known in the field of searching for files in a personal computer environment, of the PC type for example, the elements of a lower hierarchical level may or may not be apparent. For example, when the list apparently only contains vehicle names, by clicking with the left mouse button on a vehicle name, the list of services offered on this vehicle appears. By selecting a service, the list of service variants which concerns it is made apparent, and so on.

By clicking with the right mouse button on a displayed item, you can edit the list of hierarchical level just below, i.e. add, modify or delete a use case by clicking on a use variant , for example. This edition is done via a menu that pops up when you click, which includes, for example, the options "add", "remove", "properties" and "show the differences" (option which allows you to compare two elements of the same hierarchical level, including on two different vehicles). A use case is, in the design tool, defined by an initial phase (for example an available energy level) transverse to the vehicle, an initial state (for example the position d actuators), a request or request, a final phase and a final state.

For example, in the "access" service which relates to the opening parts of the vehicle, a new use case (CU) is added concerning what must be done following a serious accident. For this new use case, we define a name "after a crash" and a text description "whatever the initial context of the vehicle, with the ignition on, if a crash is detected, then all accesses must be unlocked ". The name and description are called" properties "of the new use case.

In FIG. 6, the interface is represented, when the "User opens trunk" use case is selected. When selecting an element from the hierarchical list, by a left click of the mouse, we observe, in graphic part 630, a synthetic representation of this element.

Depending on the level of the item in the hierarchical list selected, in graph area 630: - name of the vehicle: the list of services

- services or services: the list of service variants

- service variants: the list of use cases

- use case: the different realizations of the use case by a set of state transitions in the different phases of the service.

This is the selection which is presented in graphic part 630

- link between states: performance requirements in relation to the various elementary operations which are carried out in the arrival state (see the example described above). For example, by left-clicking on a variant of a service, we display, in the graphic section, a list of use cases, with their description, in a text, each paragraph corresponding to a use case . By a left click on a formalized use case, we display, in a vertical succession and under headers 650 and 651 indicating the phases concerned, "phase 1" and "phase 2", initial states 660 to 663 and terminals 664 to 667 represented by rectangles and connected by links 668 to 671. We see appear on these links the name of the customer request which causes the transition from the initial state to the final state. We observe that to make a use case "formalized", we select the use case with a right click and, in the pop-up menu, we choose "link definition" to set up links, each link being defined in a phase and between two vehicle states (for example "doors closed, trunk closed" and "doors closed, trunk closed, one door open"). For this purpose, a contextual menu includes four zones, "initial phase", "initial state", "final phase" and "final state" which make it possible to select between all the phases already defined or between all the states already defined, those which represent the use case. With this context menu, and thanks to buttons, you can add states and phases in the lists of states and phases proposed. When working to define a use case, we add phases that are specific to the service concerned while the modes are for all services.

For example, the "brake" service has four phases: - emergency braking,

- braking,

- failure brake and

- normal brake operation ("brake nominal phase").

For example, for the "air conditioning" service, two phases are defined, one for the low levels of available energy, for which ventilation is carried out without cooling the ventilated air, which consumes too much energy, and the other for the case of the engine running, the air conditioning being carried out with cooling of the ventilated air.

The operating algorithm of a service is represented by rectangular blocks, representing states, and arrows, representing an action or inaction causing a transition between states. By convention, the arrows leaving a state leave the block representing this state on one of its right or left vertical faces while the arrows reach the states on one of the high or low horizontal faces of the corresponding block.

A transition represents a request from the client. For example, a click on a boot opening badge changes from the "all closed" state in which all the doors of the vehicle are closed, to a "doors closed / boot open" state. For each state, a set of elementary operations is thus defined which must function or be executed in said state. All the states and transitions form a control automaton associated with the service. It is observed that the states can be considered as "felt customers", the transitions being the requests of the customer, possibly implicit. It is understood that the phases are attributes of the states but that two identical states with the exception of their phases ("before contact" and "after contact" phases, for example) are considered as two independent states. We also observe that the vehicle cannot be in two states simultaneously for the same service and which if two services are not independent (for example radio and guidance system using the same display), we add an arbitration service called on request from at least one of the services in question which determines how the system will behave when the two services use the same resources.

For example to describe a definition of link whose logic is: - "whatever the initial context of the vehicle, with the ignition on, if a crash is detected, then all accesses must be unlocked", then if the doors are already unlocked, it is not necessary to unlock them; we select the phase "Icontact put" and the initial state ("start state") "vehicle locked by the cockpit button" and we select the link to the final state "emergency unlocking" passing through the transition or request " a crash is detected ". It is repeated for all the initial states except "all openings open" and only for the phase "contact put".

As soon as a link has been added and validated, a graphic appears on the right: two rectangles surmounted by the names of their respective phases ("contact put" and "crash") and a rounded link, with, under the link, the name of the transition. The use case then becomes a formalized use case ("CUF").

When adding a state next to a new use case, we must see if it is useful in the other use cases.

For example if we add the "child lock" use case which prevents children from opening rear doors, the corresponding state must be added in the description of the "crash" use case.

By processing all the use cases of all the variants of a given service, we have created a service control automaton which appears in graphical area 630 when we select the service after clicking on the tab "FUNC". When the "Requirements" tab is selected, as illustrated in FIG. 6, no vertical tab appears laterally on the graphic area 630.

The designer then selects the "FUNC" or "feature description" tab. FIG. 7 illustrates an image of the user interface which is then displayed on the screen of the design station. In FIG. 7, the user interface 700 of this software tool then comprises:

- the drop-down menus 601 to 608,

- the six horizontal tabs 611 to 616,

- a hierarchical list box 720,

- a graphic area 730, and - vertical tabs 731 and 732.

The vertical tabs 731 and 732 are respectively named "functional diagram" and "feature" and are attached to the graphic area 730. They are used to select content to be displayed in this graphic area 730, as explained below.

On the left, the hierarchical list zone 720 comprises a part of the list whose top ten hierarchy levels are: vehicle name services or services service variants phase state group of elementary operations elementary operation given driver (“driver”) component. The three highest hierarchy levels are identical to those in the list

620 and include, in particular, services or benefits. The selection of one of the components of the hierarchical list, by a left click causes with the tab "feature" 732 selected, the appearance, in the graphic part 730, of all the elements of the level list immediately lower with sometimes a flow of control between the components if you point and click with the mouse on service variant (the phases appear in the left part linked together by customer requests corresponding to phase transitions) or on a phase ( the phase states appear on the left, linked together by "customer requests").

When you right-click on an item in the hierarchical list 720, the tool allows you to add or remove elements in the hierarchical level immediately below. By clicking on one of the phase, state or group of elementary operations items, it is also possible to add an elementary operation transversely in said phase respectively, that is to say in all of the states of said phase and in indicating in which group of elementary operations we add said elementary operation, in said state in particular by indicating in which group of elementary operations we add elementary operation in said state, and in said group of elementary operations. By right-clicking on the phase item of the hierarchical list 720, it is possible to add a phase transition, the tool then requests the arrival phase, the customer request corresponding to the transition, and the states of departure and of arrival for the phase transition. By right-clicking on the state item in the hierarchical list 720, it is possible to add a state transition, the tool then asks what is the arrival state of the transition and what is the corresponding customer request.

More generally, by clicking on a level in the hierarchical list 720, it is possible to add or remove an element from the level immediately below. Still in the context where the “FUNC” 612 and “Feature” 732 tabs have been selected, if we point and click on a state, we then obtain in the right part, in the graphic area 730, the elementary operation groups , represented as the nodes an oriented graph, each arrow representing the flow of data between the group of elementary operations of departure and the group of operations of elementary arrival. This data flow is defined with respect to the data flow between elementary operations, insofar as any data appearing is in fact produced by one or more elementary operations of the group of initial elementary operations and consumed by one or more elementary operations of the group of elementary arrival operations.

Still in the context where the “FUNC” 612 and “Feature” 732 tabs have been selected, if one points and clicks on an elementary operation, one observes in the graphic area 730, all the other elementary operations and components ( sensors, actuators) with which the basic operation exchanges information. Again, this is an oriented graph and, on each link, we can find all the data exchanged between the elementary operation on which we have pointed and the elementary operation or the component that receives or transmits at the other end in the direction of the arrow in the oriented graph. The selected elementary operation is characterized by a specific color or a specific location (center of the screen, red color) in order to be easily distinguished from other elementary operations and from sensors and actuators. Likewise, the elementary operations other than that clicked on in the hierarchical list 720, are distinguished from the components by taking a different color.

Still in the context where the “FUNC” 612 and “Feature” 732 tabs have been selected, if we point and click now on the given level, ie the eighth level of the hierarchy presented above, we see appear in the right part of the screen, in the graphic area 730, a graph with in the center of the graph the selected datum and, surrounding this datum, the elementary operations which produce (on the left) or which consume (on the right) this data and possibly the sensor (s) that produce or the actuator (s) that consume this data. Preferably, we put consumers on the right and producers on the left. It is natural that there are several consumers for a given item. It may be normal for the same data to be produced by several elementary operations, for example if these do not operate in the same phases. Depending on the level of the item in the hierarchical list selected, we can observe, in the graphic area 730, when the "feature" tab 732 is selected:

- vehicle name: the oriented graph, the nodes of which are service variant envelopes and the arrows the streams of data between these service variants. This graph is conditioned by the choice of a configuration, i.e. the choice of a variant of service by service. This is shown in Figure 15.

- services or services: the list of service variants and for each, the diagram type 830 envelope view.

- service variants: diagram type envelope view illustrated in Figure 8.

- phase: diagram type envelope view illustrated in FIG. 8 for the elementary operations of the phase and by restricting the other services to the mode combinations of the phase

- state: envelope view of diagram type illustrated in FIG. 8 for the elementary operations of the state and by restricting the other services to the mode combinations of the phase in which the state is specified.

- group of basic operations: as when the "functional diagram" tab is selected

- elementary operation: a graph with in the center the selected elementary operation and around it the sensors, actuators and other elementary operations of the architecture as a whole to which it is linked the edges of the graph are the data flows between the nodes .

- data: the elementary operations, sensors or actuators to which the data is directly linked are displayed in a graph. The sensors or elementary operations which produce the data appear to its right while the actuators or elementary operations consuming the data are placed to the left of the data. The arrows indicate the direction of passage of the data (from producer to consumer).

- pilot: the characteristics of the pilot, type of analog / digital input / output, all-or-nothing, its electrical characteristics.

- - sensor /: actuator: a graph with in the center the selected sensor or actuator and around it the elementary operations of the architecture as a whole to which it is linked, the edges of the graph are the data flows between the nodes. By selecting a service at the second hierarchical level, when the "functional diagram" tab 731 is selected, in the graphical part 730, we observe the corresponding automaton, with states (or operational situations) and the only phase transitions. In FIG. 7, we see an automaton corresponding to the "badge" variant of the "opening service" service: states 761 to 766 and transitions 768, 769 and 772. If we click with the left button on an arrow representing a transition, we sees a popup menu that describes all the requests that cause this transition. Generally only one request causes this transition, for example the request "contact_on" which corresponds to the setting of the contact, for example with the ignition key, makes pass from the phase "contact not put" to the phase "contact put", but more than one formal use case request can link two states. For example, in a very simplified version of the unlocking service, it is possible that the locked vehicle and unlocked vehicle states are linked by customer requests "request for locking by badge" and "request for locking by the opening button in the vehicle ”. However, we could have formulated two different formalized use cases, one for remote unlocking and the other for unlocking in the vehicle. The fourth level of hierarchy concerns the phases. When a phase is selected, and the "functional diagram" tab 731 is selected, in the graphic area 730, under the name of the phase, the names of the states which correspond to it are observed, in rectangles.

When we click on the transition between two states, it is possible to select an elementary operation to specify its realization, that is to say the realization of the customer request corresponding to this transition: this elementary operation must then take as argument l '' all the computer data coming from sensors, actuators or incidentally other services necessary for the computer calculation which will be carried out to decide whether or not the customer request is detected. This gives access to the software translations of the requests causing the phase transitions.

For each state, via a context menu appearing by clicking on the state with the right button, we define which elementary operations must be activated (capture, actuator commands, control laws and their interfaces specified in d other tools such as Matlab / Simulink, Statemate). They are grouped together according to different logics or practices of the designer.

By clicking, with the right button, on a phase at the fourth level of the hierarchy, a popup menu appears which allows, among other things, to link the phase modes (a context menu shows a list of modes, for example energy, customer, vehicle condition with check boxes to associate the phase with combinations of modes). For example, the "crash" phase is specified in modes where it is valid. By selecting an element of the fifth level ("state"), always with the tab

"functional diagram" 731 selected, in the graphical area 730, we observe the part of the PLC concerning the selected state and the transitions (or requests) which join the selected state and other states. We can add, in a report, elementary operations: sequence of operations to be carried out (acquisitions, commands, control laws, algorithms), we right click on the report and we choose "add": we select from a list of elementary operations (business library).

We can then create, if necessary, a new elementary operation with which it will later be necessary to associate input and output data.

At the sixth level of hierarchy, elementary operations are organized in groups to facilitate navigation. The operation groups include the same basic operations for all the horizontal tabs 611 to 616.

When we select, at the seventh level of the hierarchy, an elementary operation, we observe, in the graphic area 730, the flow of data (in English "data flow"), that is to say the data exchanged by this operation (given in input and output rectangles). If a group of elementary operations is selected, in the sixth one observes, in the graphic area 730, the flow of data between the elementary operations which it comprises. If we select a state, at the fifth level of hierarchy, we observe, in the graphic part 730, the flow of data between the groups of elementary operations which it comprises. For each of the fifth to seventh levels, if one selects a link in the graphic part, with a click on the left button, one observes, in a contextual menu, a list of the exchanged data. By selecting one, you can modify it (see below).

When we select a data, at the eighth level of the hierarchy, we observe, in the graphic area 730, all the elementary operations which consume it and those which produce it, including outside the state, the delivery, phase.

The elements of the ninth and tenth levels of hierarchy ("driver" and "component") are known elsewhere and come from the vehicle manufacturer's library, from equipment manufacturers or from suppliers.

To obtain the difference between the interfaces and controls of service variants on two different vehicles, for example, select the service concerned from the list 720 with a right click and select, in a contextual menu, the option "show the differences" , in English "show differences". We then select, in a popup dialog, the service variant of another vehicle that you want to compare with the service variant already selected. It then appears, in a contextual dialog box, a hierarchical list Phase / State / Group of elementary operations / Elementary operations / Data / Pilots / Components of the two services selected with at the different levels of said hierarchical list which one selects, a "+" sign when only the service variant selected first includes the elements of the selected level, a "-" sign when only the service variant selected second includes the elements of the selected level, a "!" sign if there is a difference at a level lower than the selected level, and no particular sign if the two hierarchical lists of the compared service variants are identical at this level

According to the level of the element of the selected hierarchical list, we observe, in the graphic area 730, when the "functional diagram" tab 731 is selected:

- vehicle name: list of services,

- services or services the list of service variants,

- service variants: the graph whose nodes are the phases and the arrows oriented customer requests for phase change,

- phase the set of states in a diagram such as that represented in FIG. 7, state the flow of data of the groups of elementary operations carried out in the state, group of elementary operations the flow of data of the elementary operations in the group of elementary operations, elementary operation a graph with in the center the selected elementary operation and around it the sensors, actuators and other elementary operations of the architecture as a whole to which it is linked the edges of the graph are the data streams between the nodes.

- given: indicated above

- pilot: indicated above

- component: indicated above To pass to the following stage of the design of the architecture of the electronic and computer system of hardware and software components, the designer then selects the tab 732 "feature". One of the screens corresponding to this selection is illustrated in FIG. 8. In this screen, the text part 720 of which is identical to that illustrated in FIG. 7, if a service variant is selected (third level of hierarchy), we observe, in the graphic area 830, an envelope 840 of the service variant.

This envelope 840 is represented in the form of a rectangle, divided horizontally into two rectangular parts. The upper part is connected, on the left, to representations of the sensors 851 which supply it with data and, on the right, to actuators 852 and 853, to which the service variant supplies data. The lower part is connected, on the left to incoming data 856 and 854 and, on the right, to outgoing data 855. The data which only pass through the variant, without being used (or consumed) is not shown.

If you click on the incoming data with the left button, you can observe, in a contextual menu, all the sources of the selected data, in terms of elementary operations.

In this representation of envelope 840, we use a formalism allowing a synthetic view of the problems to be resolved: an exclamation point indicates a supposed conflict (for example in the case where, at the output, several services claim to provide the same data) which supposes to resolve an arbitration problem, a question mark next to an incoming data item for which no element has yet been defined to produce it.

This representation of envelope 840 gives a very practical summary view for the user of the design tool. If, in the envelope representation, a data, a sensor or an actuator is clicked, a functional view is obtained, indicating the elementary operations which produce the data and those which consume it. If one selects or clicks on one of these elementary operations, then one sees in a new screen the list of the computer variants on which this elementary operation is placed. This display is performed in a new window. Which appears when you double click. If you click on a sensor or an actuator, you get the list of service variants using this component as well as the list of computer variants to which the component is attached. The return to normal takes place by closing the windows thus created.

On the other hand, the services with which the selected service exchanges data appear directly in boxes like 855 directly associated with the input and output data of the service. When several services consume or produce a data, then it is not the name of one of the services which is displayed but the sequence "..." and click on the box similar to 855 to see the list of services displayed in a new window.

When a data item is produced or consumed by an elementary operation which is not linked to a service, then we see associated with the data item, a specific icon 854 appear. In certain circumstances, for example when the description has been retrieved elementary operations of a calculator but that these elementary operations are not linked to a service, this type of notation makes it possible to know that the elementary operation producing the data G in our example is well defined and placed. To proceed to the next stage of the design of the architecture of the electronic and computer system of hardware and software components, the designer then selects the tab 613 "MAP" or "feature architecture". One of the screens corresponding to this selection is illustrated in Figure 9.

As can be seen in FIG. 9, the user interface 900 of this software tool then comprises:

- the drop-down menus 601 to 608,

- the six horizontal tabs 611 to 616,

- a hierarchical list box 920,

- a graphic area 930, and - vertical tabs 931 and 932.

The vertical tabs 931 and 932 are respectively named "networks" and "feature" and are attached to the graphic area 930. They are used to select content to be displayed in this graphic area 930, as explained below.

We observe, on the left, the hierarchical list box 920 which includes a part of the list whose seven highest hierarchy levels are: name of the vehicle services or services variants of service group of elementary operations elementary operation pilot data

Sensor / actuator

The three highest hierarchy levels are identical to those of the hierarchical lists 620 and 720 and, in particular, include services. The selection of one of the components of the hierarchical list, by a left click causes, with the "network" tab 931 selected, the appearance, in the graphic part 930, of the set networks 941 to 943 of computers 951 to 955, synthetic representation making it possible to observe, for the selected element, its distribution on the computers and the data streams which concern it on the networks.

Depending on the level of the element of the hierarchical list selected, in the graphic area 930, when the "network" tab 931 is active, all of the networks (the nodes and the different networks) are active.

Each network is represented with all the computers connected to it, the network having a specific color, represented here by stickers, vignettes or pads 961 to 963 bearing signs "+", "x" or "o". Computers present on two networks, computers 951 and 955, are, on each network to which they are connected, equipped with "sticker (s)", each "sticker" having the color, represented here by the sign corresponding to each other network to which the computer in question is directly connected. The stickers thus give a three-dimensional view without complexity of representation. By clicking with the right button on a network, we observe, in a dialog box, the list of the data which transit on this network. The icons representing the data, which are followed by their name in clear, appear in green on a white background if the data in question is not placed in a frame circulating on this network, in blue on a white background when the data is placed in a frame and in blue on a gray background if the data is not used by any computer, whether this computer is directly on the network or accessible via gateway computers between networks and other networks.

These views allow an estimate of the bus load in average time between two transmissions of the same data. This average duration is estimated for example by taking into account the communication protocol implemented on the network considered and displayed in the popup window and the performance of this protocol, for example the load level saturating the network (from 30% of load for the CAN we observe that the most critical frames may not arrive in due time due to the arbitration mechanism which delays the transmission of a frame when the transmission of another frame of priority greater than or equal to already requested, and - the share of data flow that falls under protocol management (50% for the CAN, typically because the protocol management data (arbitration, CRC, ...) represents practically as many bits on average than the data actually transported by a frame).

The data flow calculation is done by mode and the highest load is taken in the mode in which it appears. This aspect motivated by the fact that for example, in diagnostic mode, certain frames corresponding to a client mode are inhibited and therefore are not taken into account in the load calculation. Conversely, the calculation of load in operation for the end customer must not take diagnostic frames into account. A frame is transmitted in a given mode if and only if at least one of its data is exchanged between two elementary operations active in this said mode.

With the tab 931 "network" selected, the user of the tool can perform the placement (in English "mapping") of a service variant or a group of elementary operations, or even of a elementary operation selected in the list box 920, on one or more computers represented in the graphic part 930, by the well-known function of "drag and drop" (which one can translate, in French, by "to move and to let go" ). For this purpose, when you right-click on a service variant or a service, a contextual menu appears and offers the different types of placement.

If an elementary operation exists in several service variants, for example in FIG. 9, the elementary operation "Unlocking safe" in the hierarchical list 920 which is linked both to the "Badge variant" and to the "Key variant", then placing this elementary operation for example on the type of computer BFR, 953, when placing the service variant "Badge variant" will also place this elementary operation for the service "Key variant" and even if then the variant "Key variant" service is placed on the type of UCH calculator, only elementary operations not yet placed will be placed on the type of UCH calculator, the elementary operation "Unlocking safe" remaining placed on the type of BFR calculator. It would be the same with an elementary operation group of another service variant than "Badge variant" which would contain the elementary operation "Door unlocking" and which would be placed for example on the type of UCH computer. In this way, elementary operations shared between several services are only placed once. Furthermore, once an elementary operation is placed, one can cancel its placement and replace it on another type of calculator by clicking in a menu obtained by selecting said elementary operation with a right click.

The different types of placement include, in particular, placement on a single computer, placement in master and slave and distributed placement. In the type of master-slave placement, the "control" part of the service sends control messages on at least one network to control each slave and the tool automatically adds these control messages inside or outside the already defined frames (to see further). To be able to place the master and the slave, when the type of master - slave placement is selected, an elementary operation, representing the service control automaton, is automatically added in relation to the service variant considered. It is called "elementary control operation". We then place, by drag and drop operations, the service variant, or an elementary operation group or an elementary operation and in particular the elementary control operation on a calculator variant. There are as many slaves as there are nodes on which the elementary control operation is not placed and on which at least one elementary operation of the service is placed. The node on which the elementary operation for controlling the service is placed is the master node. Before placing in master and slave, we start by synthesizing the control operation. To do this, it is considered that this operation consumes all the data allowing the calculation of the service control automaton. For example, if a transition is conditioned by the setting to one of a Boolean datum a, a being the result of an elementary operation, then, in the case of a master - slave placement, the elementary control operation will have in particular has as input data.

The type of placement distributed means that elementary operations of the same service are distributed over several computers and that, on the other hand, the service control automaton is synthesized on each of said computers.

We therefore automatically add to each node on which at least one elementary operation of the service has been placed at the time of placement an elementary control operation which represents the service control automaton. This elementary control operation is the same as that which one would have synthesized automatically for a placement of type master - slave.

For each placement of a service, a placement dialog box appears asking if the elementary operations, the sensors and actuator concerned should be placed simultaneously and on the same computer. If it is decided to place the service with the actuators and / or sensors concerned, the design tool connects them to the computer. If the elementary operations, the sensors and / or the actuators are not placed on the same computer as the rest of the service, the design tool adds the data necessary for the proper functioning of the service in or outside the frames already defined (to see further).

If at the time of placement on a node, ie on a type of calculator, several variants of calculator realize this type of calculator, then a dialog box appears to ask on which of these said variants of calculator the selected component must to be placed.

As illustrated in FIG. 10, if the "feature" tab 932 is selected and a service variant is selected (second level of hierarchy), we observe, in the graphic area 1030, placed one below the other, all envelopes 1061 and 1062 of the types of calculators containing at least one elementary operation of the selected service. Only the input and / or output data of the elementary operations of the selected service variant contained in these types of calculator are displayed, which makes it possible to see for the said service the progress of the placement and state of internal and external exchanges of the service variant within the electronic electrical architecture. If data such as V2 or V3 are produced or consumed by other service variants, then this is indicated with the same conventions as in Figure 8 in area 841. We also observe, in graphic area 1030, the same two types of computers 1041 and 1042, corresponding respectively to 1062 and 1061 on which the selected service variant is installed, as well as the data streams which they exchange. By clicking on one of the arrows 1043 and 1044 representing these data streams, the data exchanged is observed in a dialog box (not shown). In these boxes we would observe the data V2 and V3 which are the only internal exchanges in the service between the types of calculator UCH and BFR.

If data frames were exchanged, they would be represented in envelopes 1061 and 1062 like the representation in area 1244 in Figure 12.

These graphic representations are updated according to changes in the placement of elementary operations in this service variant

If the "feature" tab 932 is selected and an element from one of the fourth to sixth hierarchy levels is selected, the data flows are observed in the graphical area 1030 (see "Func" tab 612 above) but for all the states combined (there is no longer a level representing the states in the hierarchical list 820). The last three tabs, 614 to 616, concern the hardware with diversity management, that is to say different variants of the hardware implementation of the system.

When the designer selects the "operational architecture" or "OPER" tab 614, he accesses a description of the elementary operations of each computer. FIG. 11 shows a user interface displayed when the 614 "OPER" tab is selected.

As can be seen in FIG. 11, the user interface 1100 of the software tool then comprises:

- the drop-down menus 601 to 608,

- the six horizontal tabs 611 to 616, - a hierarchical list box 1120, and

- a graphic area 1130.

We observe, on the left, the hierarchical list box 1120 which includes a part of the list whose six highest hierarchy levels are: vehicle name type of calculator variant of calculator service elementary operation pilot data Sensor or actuator

Depending on the level of the element of the hierarchical list selected, in graphical area 1130, one observes: type of calculator The flow of data between the different nodes of the network independently of the implementation of this flow in frames or networks of all kinds. If an elementary operation placed on a node consumes a data produced by another elementary operation on another node, then the exchanged data appears in the data flow represented graphically by an arrow going from the node where the data is produced towards the node where the data is consumed. calculator variant The oriented graph whose nodes are the elementary operations placed on the calculator variant, 1140, 1142, 1144, 1146, 1148 and the arrows are the data flows between these elementary operations such as for example 1162.

Elementary operation the links to the sensors and actuators linked to the selected elementary operation and mounted on the data computer the elementary operations, sensors or actuators to which the data is directly linked are displayed in a graph. The sensors or elementary operations which produce the data appear to its right while the actuators or elementary operations consuming the data are placed to the left of the data. The arrows indicate the direction of passage of the data (from producer to consumer). - Pilot the characteristics of the pilot, type of analog / digital input / output, all-or-nothing, its electrical characteristics. - Sensor / actuator a graph with in the center the selected sensor or actuator and around it the elementary operations of the architecture as a whole to which it is linked, the edges of the graph are the data flows between the nodes. FIG. 12 shows a user interface displayed when the 615 "hwd" or "hardware architecture" tab is selected.

As can be seen in FIG. 12, the user interface 1200 of the software tool then comprises:

- the drop-down menus 601 to 608, - the six horizontal tabs 611 to 616,

- a hierarchical list box 1220,

- a graphics area 1230, and

- the vertical tabs 1232 and 1234. We observe, on the left, the hierarchical list box 1220 which includes a part of the list whose six highest hierarchy levels are: name of the vehicle type of calculator variant of frame calculator given in the pilot data sensor / actuator frame Depending on the level of the item in the hierarchical list selected, we can observe, in the graphic area 1230, when the "networks" tab 1232 is selected: vehicle name the networks of this typical vehicle architecture of computer the networks to which this type of computer is connected, represented in FIG. 16 variant of computer the networks to which this variant of computer is connected frames or the network to which this frame belongs given in the frame the network to which this data belongs (via the frame ) sensor / actuator the type of computer to which this component is connected and the networks on which this type of calc ulator is connected. Data Nothing Pilot Nothing and, when the "Diagrams" tab 1234 is selected: vehicle name Nothing type of calculator A graph whose nodes are the types of calculator and whose arrows are the frame flows, the arrows being oriented from the node transmitter to the receiver node. display calculator variant as defined in figure 12 by the outline

1260 cut into three parts 1240, 1242 and 1244 by two horizontal lines 1262 and 1264. In area 1240, the links of the computer variant to sensors or actuators are displayed, the links to sensors being displayed on one side 1252 and the links to the actuators being displayed on the other side 1250, 1254. In the diagram, in the case of a input of information from a sensor 1252, the data appears inside the contour 1260, while the name of the sensor "Key" appears outside the contour. In this way the designer can easily distinguish the names of the data of the application software embedded on the computer variant, of the names of the different sensors and actuators, and moreover the link of the sensors / actuators to the software data is clear. In the area 1244 is represented the messaging interfaces of the selected computer variant. This messaging interface consists of message frames consumed or produced on the various networks to which the selected computer variant is connected. The consumed frames are represented on one side of the zone, and the outgoing frames on the other side. For example T_in_1, 1246, is an incoming frame and T_out_1 and T_out_2, respectively 1247 and 1248, are transmitted frames. Only the data actually consumed and produced by at least one elementary operation on the selected computer variant are represented in area 1244 in correspondence with the different frames. For example, if a location for a data item "n" is reserved in T_in_1 and if the data item "n" is not consumed by any elementary operation on the selected computer variant, then "n" does not appear in area 1244 Conversely, the data item "a" which appears in correspondence of T_in_1 is therefore consumed by an elementary operation placed on the selected computer variant. Finally, in zone 1242, we find the input and output data of the selected computer which are neither linked to sensors / actuators, nor to frames, and which nevertheless come from or are intended for other nodes. The conventions of zone 841 are used for this zone 1242. Finally, the data which only pass through the selected computer variant, which then acts as a gateway between networks, can be accessed in the form of a list by selecting a tab. from menu 603. The separation of data into two categories, not yet assigned and already assigned provides a coherent view of what is done and what remains to be done. Frames nothing given in the elementary operations and / or sensor / actuator producer or consumer frame within the selected computer variant. sensor / actuator a rectangular outline (not shown) separated into two parts, the top part being used to indicate the data produced by the sensor / actuator using a pilot and used on other computers than that to which the component is attached, the lower part being used to represent the data produced using a pilot and used on the computer to which the component is attached. The data received by the component is on the left of the outline while the transmitted data are on the right of the outline. Such a data-calculator link is represented by similar to the data-service link 855 in Figure 8, except that if the same data is for example sent to several computers, then it will be repeated several times, which is an alternative to a display of the type ". .. "with a box that should be clicked to access the different calculator variants, other than the one to which the component is attached, using the data. data from a sensor or actuator for basic operations and / or sensor / actuators for producers or consumers within the selected computer variant. Pilot as for the data, see above. When the "networks" tab 1232 is selected, in the graphical part 1230, the hardware architecture and the placement of computers on networks are observed.

Each network is represented with all the computers connected to it, the network having a specific color, represented here by stickers with a sign "+", "x" and "o" as in Figure 9. Computers present on two networks are, on each network to which they are connected, provided with "sticker (s)", each "sticker" having the color, represented here by a sign "+", "x" or "o" of the other networks to which the computer question is directly related. The stickers thus give a three-dimensional view without complexity of representation.

When you right click on a network, a list of data circulating on this network appears in a contextual dialog box. In this dialog box, different colors indicate the data that is not allocated in a frame, that which is allocated and actually passes in a frame and that which is allocated but does not pass effectively because for example it is not produced . The data circulating on a network are visible in a dialog box when one clicks with the right button on the network in question, the tab "networks" 1232 or 1232 being active. This dialog uses colors to indicate the placement in a frame and the use of the data, as explained above, with reference to FIG. 9. When the tab 616 is selected (screen not shown), if one select a data by clicking on the left button, a popup menu allows you to reach a contextual dialog box which provides information on this data, in particular, the dimension (a boolean at a size of one bit), the extreme values, a default value, etc. the maximum age of the data, i.e. duration after capture after which the data can be considered obsolete ... etc.

When the tab 616 "msg" is selected, a screen similar to that of FIG. 16 is obtained on the right, when the tab 1232 of FIG. 16 is selected. We then see in right part of the screen for each vehicle all the frames carried by at least one network and on the left part of the screen a representation of the different networks as in FIG. 16 in zone 1630. By clicking on a frame, only the network on which the frame circulates is displayed. By clicking on one of the tabs 1652, 1654, 1656, 1658, only the frames circulating on the corresponding network are displayed in the left part of the screen, when the tab 1231 is selected, when we click on a frame , a presentation of the frame in the right part of the screen appears showing the essential information of the frame, in particular its size, its period, the type of network, then the list of data for which a space is allocated as well as the coordinates of this space in most significant byte and bit number and size, then the list of producer and consumer calculator variants for each data item.

In the graphic area corresponding to the selection of tab 616, if you click with the left button on a computer, you can observe, via a pop-up menu giving the choice between frame and data, in a dialog box contextual, the data or frames consumed or produced by the selected computer.

FIG. 13 represents a screen 1300 for entering and displaying the zones of a product called "vehicle Z23" for which it is desired to build an electrical and electronic architecture. This screen can be accessed from any of the screens in Figures 6 to 12 by selecting from the tools menu 606.

We observe, in the hierarchical list 1320, a list comprising the first three levels of hierarchy as follows: vehicle name groups of nodes and components nodes and components

The graphic part, on the right of the screen, includes an upper zone in which three buttons 1312, 1314 and 1316 are represented. The different areas of the vehicle on which the components of the system can be placed appear in the lower right graphic part of the screen, or sub-screen 1330. These areas of the vehicle are represented by rectangles 202, 204, 206, ... , 236, 240. To add a zone, the user must first select the button 1312 place this rectangle, which corresponds to a new zone of the vehicle, by clicking in the sub-screen 1330. He can then change the dimensions of said rectangle, for example by clicking on one of the angles of the rectangle, then by moving this angle at will, the opposite angle of said rectangle does not move. He can then move the rectangle at will in the sub-screen 1330, in order to make the arrangement of the respective zones understandable for all of the users. In the case of a motor vehicle for example, it would not make sense to place the area representing the right rear door and the area representing the left front door next to each other.

The name 1342 of the product is listed at the bottom of the 1330 sub-screen.

We note that the nodes and components defined for the design tool are included in the hierarchical list 1320. In fact, this hierarchical list is used once the different components are placed: selecting a particular node or calculator makes it possible to locate in which vehicle zone it is placed, this zone automatically changing appearance in the sub-screen 1330. For example, when in the hierarchical list, the accelerator pedal 1321 is selected, the cockpit zone 218 changes appearance.

On the other hand, the components which have not yet been placed also have a particular appearance, such as the BVA node 1323 or the front wiper motor 1322.

By selecting the button 1316, it is possible to add, in the sub-screen 1330, an orientable compass 1344 for readability for all users. It is up to the user to indicate which axes (left, right), (up, down), (front, back) should be used as well as their direction. In FIG. 13, in the case of a motor vehicle of which zones, seen from above, have been shown, the orientation allows the person skilled in the art to recognize some of these zones, such as, for example, flag 216, then step by step, all the areas represented. In order to make this division into zones more readable, it is possible to name the zones. This is for example the case of the right front wing named Aile AVD 1346.

FIG. 14 represents a local view of one of the zones of the vehicle represented in FIG. 13 in the sub-screen 1330 of the screen 1300. It is accessed, for example, by selecting the said zone in the sub-screen 1330 then by double clicking. In the sub-screen 1330, the dimensions of the said zone can be specified by selecting the button 1410 then by selecting one of the vertices of the said zone and moving it at will, the other vertices remaining unchanged. Selecting a point on the edge of the area other than a vertex allows you to define a new vertex.

You can specify an avoidance subzone by selecting a button 1412 and then the location of the zone where you want to place the avoidance subzone. The avoidance sub-area is then placed in the form of a rectangle with default dimensions. The exact dimensioning of the subzone is then done, as for the vehicle zone, by selecting a button 1410 then by selecting one of the vertices of the selected avoidance subzone or by adding a vertex. By selecting a point on the contour other than a vertex.

The routing points are placed on the zone by first selecting a button 1414 then by selecting the place in the zone where it is desired to place said routing point. The connection points of the zone are placed by first selecting the button 1416 then by selecting the place in the zone where it is desired to place said connection point.

As in Figure 14, a compass can be placed next to the area by selecting the button 1316, then oriented. A recommended routing path can be placed by selecting a button

1418, then selecting a component or routing point or initial connection point, then a component or routing point or final connection point.

The components and calculators are placed on the area by click-and-drag from the hierarchical list 1420. They can be associated with icons which make it possible to locate and recognize them more quickly.

All the elements of the represented vehicle area can be moved and adjusted by click and drag. Finally, a "rule" element can be placed in the window to facilitate the dimensioning of the different zones. To do this, select a button 1413, then select the place in the area where you want to place the ruler. By selecting one end of rule 1444, you can extend or shorten it. When this operation is carried out, the actual length of the rule is displayed, for example in millimeters.

It is possible to rotate the rule around one of its vertices according to known means. Placing the ruler next to one of the edges of the zone allows you to know its length and possibly change its sizing.

Still with the objective of a representation as faithful as possible, in the sub-screen 1430, it is possible to display a background screen making it possible to represent the area on the right scale. The background screen can for example be made up of parallel and regular horizontal and vertical lines, cutting the space into blocks of 20mm by 20mm in the 1: 1 scale.

It is possible to enlarge and shrink the area of the vehicle shown for ease of use, i.e. change the scale of the figure so that it is adapted to the part of the sub-screen 1430 by means known as zooms. The area and all the elements placed on the screen then change scale. Once the connection point placement operation has been carried out on different zones, one can return to the view presented in FIG. 13 to link the connection points of the different zones of the vehicle which correspond in the sub-screen 1330. In a certain mode display, accessible via the "View" menu 603, the connection points specified in the area 202, for example, appear. This zone contains three connection points 1350, 1351, 1355. Zone 220 contains, for the moment, a connection point 1353. To indicate for example that the connection points 1355 and 1353 correspond, that is to say represent in fact the same point in space, we can by example select button 1314, then select connection point 1355, then select connection point 1353. A graphic link 1354 is then automatically generated. A new selection of the "View" menu 603, allows, if desired, to hide all the connection points and their links. It is possible to name the connection points, as is done for example for the connection point "C3" 1448. In this case, the name of the connection point is shown in sub-screen 1330, when the option to display the names of connection points is activated.

By selecting, in the "Edit" menu 602, the "Wiring summary" option, the routing algorithm is executed. We can then view the result. In Figure 14, segments 1451 to 1455 are summarized. By clicking on each of these segments, we obtain the list of component-component links or wires, or component-connector or connector-component which are registered in each of these segments.

For example, if the 406 engine has a three-pin connector, one for control, low power, one for high power, the third for mass, we obtain the following list:

Motor - 1 - motor control data 406

Motor- 2 - motor supply 406

Motor - 3 - motor mass 406 If these three pins, during routing, are associated with three pins of connector C1

1447, respectively, we observe the following list:

C1- 3 - motor control data 406

C1- 5 - motor supply 406

C1- 1 -mass engine 406 Then, by clicking on the link 1452, we can see that on the segment between the routing points 1470 and 1472 circulate the reference links:

Motor - 1 - motor control data 406; C1 - 3 - motor control data 406

Motor- 2 - motor supply 406; C1- 5 - motor supply 406 Motor- 3 - motor mass 406; C1- 1 - engine mass 406

FIG. 15 represents the screen which appears when the "Vehicle Z23" is selected and the "Func" tab 612 is selected. We then obtain in part graph 1530, on the right of the screen, a graph whose nodes are the service variants and the arrows the data flows exchanged between the service variants. Such a flow of data represented by an arrow between a variant of departure service and a variant of arrival service is defined by the set of data produced by at least one elementary operation of the variant of departure service, which are not produced by no elementary operation of the arrival service variant, but which are consumed by at least one elementary operation of the arrival service variant. The inter-service data flow as shown in FIG. 15 is generated for a choice of a service variant for each service corresponding to a configuration. For those skilled in the art, these data streams make it possible to identify the data for which precautions are to be taken during development. In fact, the data between services and their characteristics must be validated for each service consuming or producing them, on the contrary, data intrinsic to a service, the development of which is solely the responsibility of said service. It is possible, in the screen illustrated in FIG. 15, to represent the entirety of the exchanges between all the services of the product or the exchanges of a subset of services, this by copying into a product architecture for example created for the occasion, says it under set of services and considering the corresponding graph in the graphical part 1530. Figure 16 represents a screen appearing when the tab is selected

"HWD" 615, the "Network" tab 1232, and the UCH node 1621 in the hierarchical list 1220. We then see appearing, in the graphic part 1630, a network view responding to the same conventions as the view described in the graphic part 830 illustrated in FIG. 8. Only the networks on which the UCH node 1621 is present are then displayed, unlike what is represented in FIG. 8 where all the networks are displayed. Tabs in an area 1640 make it possible to select the different networks of the architecture 1654, 1656, 1658. Selecting the "garlic" tab 1652 allows the display in the graphic part 1630 of all the networks and cancels the selection of node UCH 1621.

By clicking on a given network, we obtain all the data circulating on this network, distinguishing in particular those which are not provisioned in frames, those which are provisioned and present, those which are provisioned and absent.

In FIG. 17, the method for designing the specification of a service variant is detailed.

Steps 1712 and 1714 are syntheses carried out automatically for the tool while all the other steps are assisted by the ergonomics of the tool but are left to the initiative of the designer.

When designing the specification of a service variant, first of all, the use cases are specified, step 1702. Once the use cases have been specified, the operating phases are identified, the customer requests which are the transitions and the system responses which are the states, step 1704. The phases are preferentially defined by their decomposition in transverse modes as this is presented in figure 7. Two phases should preferably not share any combination of transverse modes. We can then synthesize a first PLC describing the supervision of the service as detailed in Figure 7. For this, we start from the association proposed by the user of the use cases with triplets (starting state, customer request, arrival state).

From this first steps supported by the REQ tab of the tool, a service control automaton is automatically synthesized for all the use cases of the service, step 1712.

We then proceed to the correction steps, step 1714, and completion, step 1716, which make it possible to perfect the automaton and to enrich the use cases, step 1720, according to new situations identified in particular during the completion step, step 1716.

In parallel with the stages of development of the service control automaton, stages 1712, 1714 and 1716, the elementary operations carried out in each of the states of the service control automaton are specified, stage 1706.

Likewise, certain elementary operations carrying out the phase transitions are identified, step 1708, as well as the elementary operations carrying out the customer requests, step 1710. The realization of a phase or state transition by an elementary operation is preferably represented by an elementary operation whose result is a boolean which when it is worth the boolean value "true" results in the activation of said transition. We can equivalently, but for more generality, specify that the transition operates for a particular value of one of the outputs of the elementary operation which performs it.

When steps 1706, 1708 and 1710 are partially or completely carried out, the data flow is synthesized between the elementary operations specified during these steps, step 1718.

We can then synthesize a model of the specified service variant, step 1722, by completing in particular the automaton synthesized during step 1712 and the various elementary operations which are attached to it with the description of sensors and actuators preferably attached to the service and corresponding pilots.

FIG. 18 describes a method of designing electrical and electronic architecture making it possible to understand the interactions between the different stages of the method described in the invention, but also the different views proposed by the tool.

As a starting point, a specification of the product configurations is specified by the user, step 1802. It indicates the different configurations characterized in particular by a set of service variants and a set of computer variants. For each configuration, a percentage is indicated corresponding to the ratio of the number of products comprising said configuration by the total product number. This step being carried out, a specification of each variant of service is carried out, step 1806, in particular by applying the method described in FIG. 17. We can then proceed automatically to the validation of the service architecture, step 1808 (described below). For a set of configurations, specified during step 1802, a set of nodes and the networks connecting them is specified and for each node a set of variants of computers, step 1810. On the other hand, the geometry of the product is specified, step 1804. Once the steps 1806 and 1810 partially or completely carried out, the services can be placed on the different nodes, step 1812. One then automatically performs a summary of the control of the services, step 1816, as well as the synthesis of the exchanges , in particular on the various data buses, step 1818. From the exchanges on the buses, step 1818, it is possible to specify a messaging system or to generate it automatically, step 1826, for example by means of the method described in French patent application number 01-05713 of April 27, 2001 incorporated here by reference.

On the other hand, the different computer variants, specified during step 1810, and the various sensors and actuators, in particular attached to the service variants, specified during step 1806, are placed on the geometric description of the vehicle, step 1814. The routing points, connection points, connectors and avoidance zones are likewise placed, step 1820.

From the placement of the various electrical and electronic components, step 1814, and from the description of the geometric constraints, step 1820, the routing of the signals, in particular of data, power or ground-related signals, step 1822 is synthesized. on the other hand, the characteristics of the various elementary operations in terms of code size, RAM size required and CPU consumption, step 1824. Given the routing, step 1822, on the one hand, and the specification of the resources necessary for the execution of the software components which perform the elementary operations, step 1824, on the other hand, an estimate of the cost of the system is deduced based on the cost of the electrical architecture (sensors, actuators, wires, connectors) and the cost linked to the types inputs - outputs and to the choices of processors induced by the placement, step 1830, This synthesis, step 1830, is carried out by taking in particular account for the optimization induced by splices on the power and ground wires, step 1828. Finally, all these steps being carried out, the architecture evaluated can be compared with other architecture, in particular by a criterion of cost, quality or weight, in particular by a cost criterion consolidating in particular the quality and weight criteria, step 1832. In order to carry out a consolidated quality estimate, several steps must be carried out: - automatically calculating a quality measure for the execution of an elementary operation, and for the execution of a set of elementary operations on a computer, given a quality measurement for each type of input / output, for each type of wire (power, mass, data), and given a measure of quality for performing a instruction on a computer, for access in random access memory, for access in flash memory,

- automatically calculate the quality of routing

- take into account a quality measurement of the sensors and actuators - automatically deduce the quality of the electrical and electronic architecture Validation operations and their support by means of traceability, control of operational safety are not described in the figure 18 but complete this figure showing the overall process. Regarding the configurations, we can distinguish:

- the basic services which may be regulatory or trivialized on vehicles (lighting, wiping of windows, ...),

- the basic services with a variant, such as traction on a vehicle which can be based on a petrol or diesel engine, on an electric motor or on a hybrid motor for example, with each time a different implementation,

- services which will not necessarily be integrated into all products and which can be described as optional. For example air conditioning on an automobile,

The service configuration is the selection of a set of service variants (optional or not). The optional configuration services are those that are not always present.

For a given configuration, the rate of rise of the optional services will be given, in particular in the form of a percentage.

For a given product, we will consider different configurations. Considering all the configurations, we will give the respective percentage of each configuration for example in the form of a percentage.

For example, for an automobile, there are luxury, comfort, "eco" configurations (for "economic") with, for example, air conditioning service at 100% on the luxury configuration, 40% on the comfort configuration and 0% on the eco configuration . The luxury, comfort and eco configurations can represent 20% 50% and 30% respectively.

The configurations planned for a product have an impact on the choice of the hardware architecture of the product. For example, low-rate air conditioning

(10%) will encourage the implementation of this air conditioning using a specific computer, whereas if the air conditioning is 100% present, we will tend to integrate the software and the corresponding hardware interfaces with a computer combining many other benefits. It is indeed expensive to multiply the number of electronic calculators and in practice we try to integrate as much of the service as possible to lower costs.

The configurations are also used to make wiring choices, the example of air conditioning above shows this well since the wiring for a specific computer will have a different cost than the wiring for a non-optional computer. The choice of an optimal electrical-electronic architecture is therefore preferably made as a function of a set of predefined configurations.

The configurations are also used to manage diversity by making it possible to limit by design the combinations of options available. They also represent an intermediate element making it possible to simplify the validations as we will see later.

By the step of placing the services on the computers, it is possible to deduce the computer configurations associated with a service configuration. These are in particular the computers containing at least one elementary operation of at least one service from the Service Configuration. The optional nature of the calculator is also deducted, a calculator containing in particular elementary operations attached only to optional services may be optional.

However, it is possible to define computer and hardware component configurations, in particular if the placement step has not yet been carried out. When we specify a configuration as being composed of a service configuration and a computer configuration, we assume that any service in the service configuration is fully placed on the computer configuration and that, conversely, elementary operations originating from services which are not in the service configuration are deactivated on said computer configuration.

We integrate into the choice of an optimal routing a constraint linked to the configurations. A component of which at least one variant is absent in at least one configuration is said to be optional. The economically optimal routing is, for example that which satisfies the following constraints: • 1) one cannot link a component (sensor, actuator) to an optional node such that there is at least one configuration where the node is absent and the component is present. Therefore in the search for the routing of said component, the nodes not satisfying the above criterion are not considered.

• 2) one cannot link in a power splice two wires which would not be present in the same configurations.

»3) under hypothesis 1) above, when we synthesize the routing of a wire coming from an optional component C and that the optimal routing leads to a node N _n such that there exists at least one configuration where the node N _n is present and the component C is absent, then one attempts to synthesize at least one other routing by considering all the nodes other than N _n which satisfy condition 1). The routing then links the component to a new node N _{n + 1} . We iterate this operation until we find a node N _p such that either N _p is the last node traversed which satisfies 1). For all the routes thus synthesized (the last being the routing at N _p ), the cost calculation weighted by the rate of assembly of the various components is applied, that is to say that a component present in 40% of the configurations will have a cost weighted by 0.4. Routing that minimizes cost is economically optimal routing for all configurations. For example, you can attach the air conditioning compressor to the air conditioning node (optional and specifically installed for the air conditioning service) or to the passenger compartment computer node (always present). The connection to the air conditioning node costs two euros including, for example, the cost of the computer connector for connection to the compressor and the other components, either one euro, the cost of the wires, one euro, and one euro on the passenger compartment controller. If the air conditioning rise rate exceeds 50%, then the compressor must be routed to the passenger compartment controller node, otherwise to the air conditioning node. For example, with an assembly rate of 40% and per hundred copies, routing to the passenger compartment node costs 1 ^* 100 * 1 euro is one hundred euros, while routing to the air conditioning node costs 0.40 ^* 100 ^* 2 euros is four- twenty euros. Knowing the relative costs of the pilots according to the number of copies makes it possible to refine the economic estimate. If for a series of 40,000 copies, a pilot type PWM (Puise Width Modulation) costs 1 euro, but 0.5 euros for a series of 100,000 copies, then for a series of 100,000 copies and a rate of rise of the air conditioning at 40%, the cost of the pilot on the air conditioning calculator will be 1 euro while the cost of this pilot on the UCH calculator will be 0.5 euros and the economic equation becomes 100 + 100 * 0.5 euros 150 euros for the UCH and 80 + 0.4 * 100 ^* 1 euro or 120 euros for the scenario of routing on an air conditioning computer. It is therefore always interesting to choose the "air conditioning calculator" scenario.

If we now estimate an assembly cost, calculated based on - a cost of assembling a strand necessary for the implementation of air conditioning in the cockpit area for example,

- a cost of mounting a connector necessary for the implementation of air conditioning on a border of the cockpit area or on the cockpit area,

- the cost of mounting the air conditioning and / or cockpit calculator in the cockpit area or another area specified by the designer, - a cost of mounting the sensors or actuators necessary for the implementation of air conditioning in an area and

- a cost of connection of the various actuator connectors necessary for the implementation of air conditioning between zones or in a zone. So, given an evaluation for the air conditioning calculator which is optional of 1 euro; and 2 euros for the passenger compartment computer, for a rate of rise to 40% of the air conditioning service, the routing option on the air conditioning computer costs 120 euros + 0.4 ^* 100 * 1 + 1 * 100 * 2 360 euros, while the cost of routing on the passenger compartment computer is 150 euros + 1 * 100 * 2 or 350 euros. Suddenly the air conditioning computer is no longer justified. Let us further refine our analysis.

Take a quality impact of 100 ppm (breakdown per million) over 3 years, a standard warranty period, for both the air conditioning computer and the passenger compartment computer. On the other hand, let's estimate the average cost of a computer replacement at 200 euros and assign an assembly / disassembly cost of 50 euros for the area in which the air conditioning computer is located and 10 euros for the area in which we have placed the passenger compartment computer. Suppose moreover that the quality defects associated with the cabling in the two scenarios are identical and of 100 ppm but of negligible repair cost except for disassembly. To simplify it is assumed that the majority of the wiring considered is in a zone at 50 euros like the air conditioning computer. So, the unit cost for replacing the computer is 100 * 200 / 1,000,000, ie 0.04 euros, to be increased by 0.01 euro for the air conditioning computer and 0.002 euros for the air conditioning computer. The cost of repairing the wiring is 0.01 euro for a fault on all the wiring which is only present when the air conditioning option is selected. Our consolidated unit cost including quality defects is therefore now 360 + 0.4 * 100 ^* ((0.04 + 0.01) (calculator) + 0.01 (wiring)) euros or 362.4 euros while the scenario with passenger compartment computer now costs 350 + 0.4 * 100 * 0.01 or 350.4 euros if we take into account the fact that the quality costs linked to the passenger compartment calculator are identical in both scenarios and that the air conditioning specific wiring is only fitted when the air conditioning option is selected. Note in passing that the number of ppm of the scenario with air conditioning calculator is 0.4 * (100 + 100) or 80 ppm while the number of ppm of the scenario without air conditioning calculator is 0.4 * 100 or 40 ppm if we ignore the ppm linked to the constant cabin computer in the two scenarios. In terms of quality, the scenario without an air conditioning computer is therefore preferable. If we now take the weight impact into account and estimate the consolidated cost of a load of one kilo at 1 euro. Given on the one hand a weight of 300 grams for the air conditioning computer and 100 grams for the routing of the specific actuators of the air conditioning to the air conditioning computer and on the other hand an overweight of 150 grams of the passenger compartment computer and 150 grams for the routing of the specific air conditioning actuators to the passenger compartment computer, we now find that the cost of the scenario with the air conditioning calculator, always for one hundred copies, is 362.4 + 0.4 * 100 ^* 0.4 (400 grams) * 1 (cost per kilo) euro is 378.4 euros and 350.4 + 0.4 * 100 * 0.3 (300 grams) * 1 + 0.6 * 100 * 0.150 * 1 euro or 363.3 euros for the scenario with passenger compartment computer. Incidentally, we saw that the assumption with air conditioning computer led to an overweight of 400 grams while that of the placement of air conditioning on the passenger compartment computer weighs 300 grams when the air conditioning is installed. On a weighted average, the weight of the scenario with air conditioning calculator is 0.4 (rate of rise) * 0.4 (kilos) or 160 grams while the weight of the option without air conditioning calculator is 0.4 (rate of clim clim) * 0.3 (300 grams) + 0.6 (without clim) * 0.150 (weight of the calculator surplus) or a marginal weight of 129 grams and it is the latter wiring that is optimal in weight.

To conclude, the cost of carrying out the basic operations of the air conditioning service must also be taken into account in each of the scenarios, a cost which must be consolidated in the part cost of the computers. Suppose that the basic operations of air conditioning require 1 MIPS and that the marginal cost of MIPS in a processor is entered in an abacus and gives for 1 MIPS 2 euros and for 20 MIPS 10 euros and 9.6 euros for 19 MIPS. Suppose on the other hand that independently of the air conditioning service, the passenger compartment computer carries 19 MIPS for performing basic operations. Finally, let's take the hypothesis of a linear cost of the RAM at, 1 euro for 2 kilos bytes and a linear cost of the flash at 4 euros for a Mega-byte. Finally, the basic operations of the air conditioning service require 2 k of RAM and 100 k of Flash. In this case the consolidated balance sheet for 100 vehicles for the two scenarios becomes: 378.4 + 0.4 * 100 * (2 + 1 + 0.1 * 4) euros or 514.4 euros for the scenario with an air conditioning computer whereas in the case where the code is executed entirely on the passenger compartment computer, the cost becomes: 363.3 + 1 * 100 * ((10-9.6) +1 + 0.1 ^* 4) euros or 543.3 euros.

In the end the consolidated unit cost of the solution with air conditioning computer is therefore 5.14 euros while the cost of the solution without air conditioning computer is 5.43 euros per unit assuming a series of 100,000 vehicles and an air conditioning installation rate of 40%. The system architecture design tool described above allows for a plurality of validations throughout the design process. A distinction is made between functional validation, which consists in verifying that any data consumed by an elementary operation must be produced by an elementary operation independently of the link between elementary operations and the various services. This step can be carried out once the functional architecture has been completed in the REQ and FUNC windows accessible by the 611 and 612 tabs.

Functional validation after placement, which consists in verifying that any data consumed by an elementary operation must be produced by an elementary operation and, moreover, that between the producer and the consumer, there is a path possibly made up of networks and intermediate nodes. This step can be carried out once the services have been completely or partially placed in the MAP window accessible via the 613 tab.

Functional validation and messaging which consists in verifying that any data consumed by an elementary operation must be produced by an elementary operation and that in addition, between the producer and the consumer, there is a path possibly made up of networks and intermediate nodes and moreover, for at least one path, locations in frames are provided for the routing of the data from the producer to the consumer. This step can be carried out when the data frames have been partially or completely carried out using the windows

HWD and MSG accessible via tabs 615 and 616. - The validation of the service architecture by configuration and / or by mode which consists in applying the three previous validations on the one hand for each configuration of the product and on the other hand for each transverse mode of the product.

For example, for a configuration where the only options and choice of computer are air conditioning present or not and petrol or diesel control, we must therefore apply the validations to the four resulting variants: petrol with or without air conditioning and diesel with or without air conditioning. With regard to validation for a given mode, the configuration being fixed, it is possible to reproduce each type of validation but only for the subset of the elementary operations which are potentially active when the engine is stopped.

These validations are accessible by a user menu (not shown) accessible by clicking on the Tools 606 tab shown in particular in Figure 6. In this user menu, one can choose on the one hand one of the three validations, functional validation, functional validation after placement and functional validation and messaging, and on the other the perimeter to be retained for these validations, the subset of computer variants and / or service variants, the mode or the set of modes, and / or the configuration or the set of configuration on which these validations must be performed.

All these validations are carried out automatically from the data specified in the system architecture design tool

Given a use case, we express a performance constraint on this use case as well as on some of the elementary operations performed in the arrival state of said use case, and we validate that this performance constraint is satisfied for a placement of the various elementary operations.

As an example, take the use case that we will call CRASH: "In a running engine context, if a crash is detected, then the vehicle must be unlocked urgently". To implement this case, a "crash detected" request is specified. It is carried out by an elementary operation which captures the value given by an accelerometer "A". This value is "a". The acceleration capture software driver corresponds to program "P1". In this case, the state of arrival of the CRASH use case is for example a state which we will name "Emergency unlocking". In this state, the elementary operation "unlocking the doors" is carried out. It corresponds to a datum set to 1 which controls by a software driver P2 which controls the locks of the doors Vi. If we give a performance constraint of 100ms on the realization of the CRASH use case this means:

That the accelerometer has detected a crash value a. - that the value of has been refreshed by executing the pilot P1 that entry into the state of emergency unlocking has been carried out that the data has been set to 1 that the software P2 has been executed that the latches Vi have operated on everything in less than 100 ms. Some of these steps are parallel and others sequential.

If now, moreover, the accelerometer is placed on an airbag computer and the lock control is placed on another computer, for example the passenger compartment computer, and these two computers are connected by a CAN bus on which the data has is transported by a T frame. Then the constraint of 100 ms now means:

That the accelerometer has detected a crash value a. that the value of has been refreshed by executing the pilot P1 that the value of has been written in the CAN pilot of the Airbag computer for the transmission of the frame T that the frame T has circulated on the bus - that the frame T has been read and the value of a extracted by the CAN pilot from the passenger compartment computer that entry into the Emergency unlocking state has been carried out that the data has been set to 1 that the P2 software has been executed - that the Vi locks have worked all in less than 100ms. From this list we establish performance requirements for the execution of each of these steps. For example, it can be proposed that the frame T be transmitted every 20 ms, which leaves 80 ms of execution time for the other operations which are sequentially executed before or after the transmission of the frame. If this assumption turns out to be too difficult to hold, we will reduce the transmission time from T to 10 ms for example. If, on the contrary, we notice that the network through which T transits is very busy, we will try to issue a transmission requirement every 30 ms for T and we will try to carry out all the operations which must take place before or after the emission of T in less than 70ms. Conversely, if performance requirements have been expressed on these various operations, we can verify that the sum of these operations is done in less than 100ms. Finally, if certain requirements are specified but no other, the time remaining to execute all the operations on which no constraint is expressed is deduced from the requirements already specified. If we are looking for an anomaly linked to the creation of the CRASH use case, this means that we can look for the causes as a priority among the various components that make up the CRASH use case, such as: the accelerometer has detected a crash value a. the value of has been refreshed by executing the P1 driver - entry into the Emergency unlocking state has been carried out the data has been set to 1 the P2 software has been executed the Vi locks have worked We can thus automatically synthesize the list of elementary operations, pilot executions, writes and readings in frames, taking into account information by sensors and actuators, frame transfer on a network, in particular, describe all the operations to be carried out when carrying out a use case to find out exactly in which set of objects to look for the cause of a fault detected during the execution of the CRASH use case.

Once the placement has been carried out, the elementary operations which must be operational can be identified automatically in each transversal mode. When at least one elementary operation is running on a computer, this means that even partial initialization of the computer must be carried out in the corresponding mode.

When no elementary operation is executed in a given transverse mode on a computer, this means that it can be deactivated.

We observe that the design process and the corresponding tool allow "top-down" approaches, by following the tabs, in order, as described in the description, and "bottom-up", that is to say say by following any specification order desired by the designer, including selecting the tabs in the reverse order of what is described in the description.

It will also be appreciated that the procedure of the present invention can be performed in the form of a device, or in the form of a computer program and saved to the memory of a computer. Manufactured articles may be produced on which such computer programs may be recorded.

Claims

1. Method for synthesizing a routing, the method operating: a) by obtaining the following parameters: - the different configurations of service variants and of computer variants and the rate of occurrence of these configurations, the sum of the rates of configurations being considered equal to one,

- the cost characteristics of the components stored and weighted according to their respective rates of assembly, - the partial or complete location of the service variants on the computer variants, b) by identifying valid routes; c) by evaluating the routing cost of said valid routes for each configuration; and d) determining the valid routing which minimizes the average, weighted by the mounting rates of each configuration, of the routing costs for each configuration.

2. Method according to claim 1, characterized in that a quality characteristic expressed failure per million is considered to allow to compare the respective quality measures of two candidate architectures for a product plan.

3. Method according to one of claims 1 or 2, characterized in that one of the quality characteristics considered is the weight to allow the respective weights of two candidate architectures to be compared for a product plan.

4. Method according to one of the preceding claims, characterized in that a cost of mounting the electrical and electronic architecture is calculated automatically based on a cost of mounting a strand on an area, a cost of mounting of a connector on a zone border or on a zone, of a cost of mounting a computer on a zone, of a cost of mounting a sensor or of an actuator on a zone and of a cost of connecting a connector between zones or in a zone.

5. Method according to one of the preceding claims, characterized in that the optimal routing is synthesized for all of the configurations, by repeating the steps above, the criterion which is minimized being a compound cost: - of the cost recurring estimated parts, - an estimate of the quality cost in anticipation of the repair cost per zone, this cost being increased by a constant cost depending on the zone and its ease of access,

- an estimate of the installation cost.

6. Method according to one of the preceding claims, applied to the synthesis of the electrical architecture of a newly created product or to the synthesis of an electrical architecture modified with respect to an earlier architecture.

7. Manufactured article comprising a computer storage means having a computer program for synthesizing a routing, characterized in that the program comprises a code for performing the steps of the procedure defined in one of claims 1 to 6.

8. Device for synthesizing a routing, the device comprising: a) a means for obtaining the following parameters:

- the different configurations of service variants and computer variants and the rate of occurrence of these configurations, the sum of the rates of the configurations being considered equal to one,

- the cost characteristics of the components stored and weighted according to their respective mounting rates,

- partial or complete location of the service variants on the computer variants, b) a means of identifying valid routes; c) means for evaluating the routing cost of said valid routes for each configuration; and d) means for determining valid routing which minimizes the average, weighted by the mounting rates of each configuration, of the routing costs for each configuration.