WO2020127126A1 - Method for configuring a device for lighting the interior of the passenger compartment of a motor vehicle - Google Patents

Abstract

The subject of the invention is a method for configuring a device for lighting the interior of the passenger compartment of a motor vehicle, the lighting device comprising: a central control unit; a main data bus; at least one first luminous unit coupled to the central control unit via the main data bus and comprising a plurality of light sources each provided with a controller and a secondary data bus coupled to the main data bus and connecting the light sources of the first luminous unit in series; characterised in that it comprises the following steps: a step in which one and the same first group address is stored beforehand in each light source of the first luminous unit; a step in which the central control unit sends over the main bus an address request containing a given group address; a step in which the first light source of the main first unit receives the address request over the secondary bus, and in which the given group address is compared to the first group address; if the given group address is identical to the first group address, a unique address that is associated with the first light source is stored therein and an acknowledgement message containing this unique address is transmitted over the secondary bus; the acknowledgement message is received by the following light source; and, in response, a unique address that is associated with this following light source is stored therein, and an acknowledgement message containing this unique address is transmitted over the secondary bus.

Description

Description

Title of the invention: Method for configuring a lighting device for the interior of the passenger compartment of a motor vehicle

[1] [The invention relates to the field of interior lighting of the passenger compartment

motor vehicles. More particularly, the invention relates to a device for lighting the interior of the passenger compartment and the transmission of data to the light sources of this device.

[2] Lighting devices for the interior of motor vehicles have recently evolved to incorporate a particularly large number of light sources, arranged to follow a major part of the contour of this passenger compartment, in order to perform functions of dynamic lighting, that is to say lighting whose color, shape and / or intensity changes, so as in particular to improve the comfort of the vehicle occupants.

[3] Such a known device is described in document DE 10 2016 207 724. This device comprises a central control unit which determines which function must be performed, and transmits a request on a main data bus of CAN type. It also includes several light units each comprising a plurality of light sources each provided with an integrated controller and a processing module coupled to the light sources by a secondary data bus. The request issued by the central control unit contains a pair of geographic coordinates corresponding to the positions, in a frame of the predefined passenger compartment, of the start and the end of the lighting function to be performed. Each processing module receives the request and determines whether the position of the light sources that it controls is between these start and end positions, and if necessary transmits control signals to the light sources via the secondary bus. Finally, each integrated controller processes the control signals to then control the power supply to its light source, so that the assembly performs the lighting function requested by the central control unit. [4] In this type of architecture, the processing modules must be able to address the light sources that they control in order to process the request sent by the central control unit on the CAN. For this purpose, they must be configured on the one hand to know the geographical position of the light sources that they control in the passenger compartment and on the other hand to carry out calculation operations which can prove complex to match said geographical positions. with the addresses of these light sources. In the case of a passenger compartment containing more than a hundred light sources, the size of the memory of the processing modules can thus become critical and increase the cost of the lighting device.

[5] The invention thus aims to overcome these problems and more specifically to provide a method of configuring a lighting device inside the passenger compartment of a motor vehicle which allows to address a number important light sources without increasing the cost of the device.

[6] To this end, the invention provides a method for configuring a device

lighting the interior of the passenger compartment of a motor vehicle, the lighting device comprising: a central control unit; a main data bus; at least a first light unit coupled to the central control unit via the main data bus and comprising several light sources each provided with an integrated controller and a secondary data bus coupled to the main data bus and connecting the light sources of the first light unit in series; characterized in that it comprises the following stages: the prior storage in each light source of the first light unit the same first group address; the transmission by the central control unit on the main bus of an addressing request containing a given group address; receiving the addressing request by the first light source of the first light unit on the secondary bus, and comparing the given group address with the first group address; if the given group address is identical to the first group address, the storage in the first light source of a unique address associated with it and the transmission of an acknowledgment message containing this unique address on the secondary bus ; reception of the acknowledgment message by an adjacent light source; and in response, the storage in this adjacent light source of a unique address associated with it, and the transmission of an acknowledgment message containing this unique address on the secondary bus.

[7] The invention thus makes it possible, in a preliminary step, for example when the lighting device is put into production, to preconfigure the light sources of the light unit, by addressing them with the same address. Then in a successive step, for example during the first start-up of the lighting device, the light sources self-address, thanks to their integrated controller, in response to an addressing request. The message (s)

Acknowledgments are thus relayed from light source to light source on the secondary data bus until being returned on the main data bus to the central control unit. All light sources are therefore addressed in a simple manner, without the cost of the lighting device being increased.

[8] If desired, the or each acknowledgment message can be transmitted from one light source to the next light source. Alternatively or cumulatively, the or each acknowledgment message can be transmitted from a light source to the previous light source.

[9] Advantageously, each light source comprises at least one light emitter, in particular three light emitters, each capable of emitting red, green or blue light, the light emitter or emitters being controlled by the integrated controller of this light source. Where appropriate, each light source has four ports, namely a port for receiving electrical power, a ground port, a data input port and a data output port. The integrated controller comprises for example a circuit for controlling the supply of the light emitter and a memory in which one or more correspondence tables are stored between instructions and supply values. The integrated controller is thus able to determine which power supply is to be applied to each light emitter to emit light corresponding to an instruction received. If applicable, the first group address and unique address are stored in the memory of the controller integrated into each light source.

[10] Advantageously, the secondary data bus forms a network of

linear topology also called in English Daisy Chain. On this type of linear network, the data propagating on the secondary bus is transmitted from each light source to the adjacent light source on the secondary bus. For example, the secondary data bus connects the data output port of one light source to the data input port of the next light source. If applicable, the data input port of the first light source and the data output port of the last light source of the first light unit are coupled to the main data bus. As a variant, the data output port of the last light source of the first and / or of the second light unit is not coupled to the main data bus by the associated node. If necessary, the data can propagate bidirectionally on the secondary bus, that is to say from a light source to the next source or from a light source to the previous source.

[1 1] Advantageously, during the prior storage step, said first group address is also stored in the central control unit. If necessary, the step of sending the addressing request by the central control unit includes a substep for selecting a given group address from a list of group addresses stored in the unit. control, said given group address corresponding to the first group address.

[12] Advantageously, the step of storing in each light source a unique address includes a step of determining this unique address. The single address of a light source can thus be made up of the first group address to which is added an incremental counter or a clock reference.

[13] Advantageously, at least one of the light sources, in particular each light source, of the first light unit comprises a switch for authorizing or prohibiting the transmission of data from the secondary bus to the next light source. Transmission of a message acknowledgment by each light source on the secondary bus can thus include a substep for closing said switch to authorize the transmission of data to the next light source.

[14] According to one embodiment of the invention, each acknowledgment message transmitted by a light source of the first light unit and received by an adjacent light source, for example the following, is transmitted, on the secondary data bus, by this adjacent light source on the secondary data bus without modification of the data included in this acknowledgment message. In other words, the first light unit emits as many acknowledgment messages as it has light sources, each acknowledgment message thus comprising a single unique address.

[15] According to another embodiment of the invention, each light source of the first light unit receiving an acknowledgment message transmitted by the previous light source appends its unique address to the acknowledgment message and transmits this acknowledgment message modified on the secondary data bus. In other words, the first light unit emits a single acknowledgment message which thus comprises a succession of unique addresses.

[16] Advantageously, the method further comprises the following steps: the transmission of the acknowledgment message (s) emitted by the light sources from the first light unit to the central control unit; the storage in the central control unit of the unique addresses of all the light sources of the first light unit.

[17] According to one embodiment of the invention, the lighting device further comprises a second light unit coupled to the central control unit via the main data bus and comprising several light sources each provided with a controller integrated and a secondary data bus coupled to the main data bus and connecting the light sources of the second light unit in series. Where appropriate, the method comprises the following steps: the prior storage in each light source of the second light unit the same second group address; after the step of storing in the central control unit the unique addresses of all the light sources of the first light unit, the emission by the central control unit on the main bus of an addressing request containing another given group address.

[18] Advantageously, during the prior storage step, the second

group address is also stored in the central control unit, the other given group address thus corresponding to this second given group address. It is thus understood that the method allows the successive self-addressing of the light sources of a plurality of light units.

[19] Advantageously, the step of transmission by the central control unit of another given group address is carried out once all the acknowledgment messages transmitted by the light sources of the first light unit have been received by the central control unit.

[20] The invention also relates to a device for lighting the interior of the passenger compartment of a motor vehicle, comprising: a central control unit; a main data bus; at least a first light unit coupled to the central control unit via the main data bus and comprising several light sources each provided with an integrated controller and a secondary data bus coupled to the main data bus and connecting the light sources of the first light unit in series; characterized in that at least one light source from the first light unit includes a switch for authorizing or prohibiting the transmission of data from the secondary bus to the next light source.

[21] Advantageously, each light source of the first light unit includes a switch to authorize or prohibit the transmission of data from the secondary bus to the next light source. As a variant, all the light sources of the first light unit, with the exception of the last on the secondary bus, include a switch to authorize or prohibit the transmission of data from the secondary bus to the next light source.

[22] Advantageously, the central control unit and the controllers of the light sources of the first light unit are arranged to implement the method according to the invention. [23] Advantageously, the first light unit is coupled to a first node of the main data bus which is associated with it and the second light unit is coupled to a second node of the main data bus which is associated with it and said first and second nodes have no electronic data processing element circulating on the main data bus.

[24] In other words, the first and second nodes are only

arranged to transmit signals passing over the main data bus to the light units. The central control unit is therefore the sole master of the lighting device and the light units are slaves of this master. The invention thus makes it possible to avoid using an intermediate data processing module between the central control unit and the light sources, which makes the device less expensive. The instructions issued by the central control unit can be interpreted directly by each controller integrated into the light sources. It is further understood that the light sources can be grouped into light units of restricted size, which increases the resistance of this light unit against disturbances

electromagnetic. In addition, the bandwidth of the main data bus can be used throughout the lighting device. Finally, the connection nodes between the light units and the main data bus can be specially designed to absorb variations in electrical power.

[25] According to the invention, the central control unit issues instructions

digital controls on the main data bus for the operation of one or more of the light units of the device for the achievement of a light function desired by the device, for example as a function of a light function activation signal desired received by the central unit. It may for example be a request containing, for each light source of the device, the address of said light source and a desired light emission instruction, such as for example a light intensity, a color, a start and an end of emission and / or an evolution of one or more of these characteristics. The lighting device can thus perform one or more functions chosen from: a lane change indicator, a navigation, a danger indicator, an event indicator, a motion sickness compensation function, an alarm function.

[26] The main data bus can be a bus whose physical layer is of the FlexRay type, within the meaning of the ISO 17458 standard, parts 4 and 5.

[27] Where applicable, the light sources of each light unit are

arranged on the same support, for example of the flexible type.

[28] Advantageously, the main data bus connects the units

light in parallel. In other words, the main bus forms a bus topology network. If necessary, the instructions issued by the central control unit are transmitted to all the light units coupled to the main data bus.

[29] Advantageously, the central control unit is coupled to the main data bus by an interconnection node devoid of electronic element for processing the data transmitted by the central control unit.

Advantageously also, the central control unit is coupled to a central network of the vehicle, in particular to a CAN type network (of the English Controller Area Network) of the vehicle, to receive an activation signal of a desired light function. . If necessary, the central control unit comprises a unit for connection to the central network of the vehicle to receive an activation signal and a microcontroller to process this activation signal and send in response command instructions on the main network of data.

[30] In one embodiment of the invention, at least one of the units

light sources, in particular each of the light units, comprises several light sources each provided with an integrated controller and a bus

secondary data, the light sources being coupled to the node associated with said light unit by said secondary data bus. Advantageously, the secondary data bus is a differential type bus, for example comprising two voltage lines, the data passing over the secondary data bus being coded by a voltage difference between the two lines. If necessary, each controller integrated into a light source may be capable of receiving and transmitting an electrical signal on the secondary bus of data, for example via the light source data input and output ports. In addition, the node associated with a light unit can be arranged to receive said electrical signal on the secondary bus and transmit it to the main data bus.

[31] Advantageously, each node associated with a light unit is a

gateway arranged to convert an electrical signal propagating on the main bus having a determined electrical power, for example a signal of a voltage of 12V, into an electrical signal having another electrical power suitable for the secondary bus, for example a signal a voltage of 5V. In other words, the node allows the relay of data passing on the main bus to the secondary bus and vice versa, while protecting the light unit from power variations and short circuits propagating on the main bus.

[32] If desired, the first and / or the second light unit includes a DC / DC converter arranged to supply electrical power to the light sources. If necessary, the DC / DC converter receives electrical signals transmitted by the associated node to control the supply of electrical power to the light sources. Advantageously, the light sources are arranged to supply their light emitter (s) with an electrical supply from the electrical supply supplied by the DC / DC converter as a function of the data they receive on the secondary data bus. .

[33] In one embodiment of the invention, the central control unit is capable of transmitting an electrical control signal of all the light units on the main data bus, the node associated with each light unit being arranged to transmitting said electrical control signal to the DC / DC converter to control the power supply to the light sources. If necessary, the electrical control signal can be an electrical signal

switch-off, on reception of which each DC / DC converter interrupts the supply of electric power to the light sources. Alternatively, the electrical control signal may be an electrical recovery signal, upon reception of which each DC / DC converter restores the supply of power supply to light sources. The central control unit is thus capable of limiting the electrical consumption of all of the light units when no lighting function is necessary, or on the contrary of reactivating all of the light units.

[34] In one embodiment of the invention, at least one of the units

lights, in particular each of the light units comprises an interface capable of detecting an interaction of a vehicle occupant with said interface, which is arranged to emit, as a function of the detection of an interaction, an electrical signal to the associated node which is arranged to receive and

transmit said electrical signal to the main data bus.

Advantageously, said associated node also transmits the electrical signal emitted by the interface to the DC / DC converter to control the supply of

power to light sources, such as re-establishing the supply of power to light sources. If necessary, the other nodes associated with the other light units are arranged to transmit said electrical signal to the DC / DC converters to control the electrical supply to the light sources, and for example restore the supply of electrical supply to the light sources. Reactivation of a light unit via its interface thus enables the reactivation of other light units.

[35] Advantageously, each light source provided with an integrated controller comprises at least one light emitting element, said element and the integrated controller being integrated in the same housing of the light source.

[36] The subject of the invention is also a means of storing information, this means of storing memorizing one or more programs, the execution of which authorizes an implementation of the method according to the invention. If necessary, the information storage means comprises a volatile memory and / or a non-volatile memory and / or a hard disk and / or a floppy disk and / or a CD-ROM.

[37] The invention also relates to a computer program on an information storage means, comprising one or more sequences of instructions executable by a microprocessor and / or a computer, the execution of said sequences of instructions authorizing an implementation of the method according to the invention.

[38] Other characteristics and advantages of the present invention will be better understood from the description of the examples and the drawings, among which:

[39] [Figure 1] shows a lighting device for the interior of the passenger compartment of a motor vehicle according to an embodiment of the invention;

[40] [Figure 2] shows a lighting device for the interior of the passenger compartment of a motor vehicle according to another embodiment of the invention;

[41] [Figure 3] shows an example of a method of configuring the lighting device of [Figure 2] according to the invention; and

[42] [Figure 4] shows a device for lighting the interior of the passenger compartment of a motor vehicle according to another embodiment of the invention.

[43] Unless otherwise specified, technical characteristics

described in detail for a given embodiment may be combined with the technical characteristics described in the context of other embodiments described by way of examples and without limitation.

[44] There is shown in [Figure 1] schematically a lighting device 100 of the interior of the passenger compartment of a motor vehicle. The device 100 comprises a central control unit 1 coupled to a central network of the vehicle (not shown) of the vehicle, to receive an activation signal of a desired light function.

[45] The central control unit 1 is coupled by an interconnection node 2 to a main data bus 101. The main bus 101 has a physical layer of the FlexRay type. Upon receipt of the activation signal, the central control unit 1 transmits digital control instructions on the main data bus 101 for the achievement of said desired light function by the device 100.

[46] The device 100 further comprises at least a first light unit 5 and a second light unit 6, each light unit 5 and 6 comprising a plurality of light sources 52 to 54, 62 to 63 respectively. first light unit 5 is coupled to a first node 3 of the main data bus 101 which is associated with it and the second light unit 6 is coupled to a second node 4 of the main data bus 101 which is associated with it. The interconnection nodes 2, 3 and 4 do not have an electronic data processing element circulating on the main data bus. These nodes are thus only arranged to transmit signals passing through the main data bus 101 to the light units 5 and 6. The central control unit 1 is therefore the sole master of the lighting device 100 and the light units 5 and 6 are slaves of this master. In addition, the instructions issued by the central control unit 1 are transmitted to all the light units 5 and 6 by the main data bus 101.

[47] Each light unit 5 and 6 comprises a secondary data bus of differential type 50, respectively 60, by which the light sources 52 to 54, respectively 62 to 63, are coupled to the associated node 3, respectively 4, to receive the instructions issued by the central control unit 1. The nodes 3 and 4 therefore form gateways arranged to convert the electrical signals propagating on the main bus 101 into electrical signals adapted to the secondary buses 50, 60.

[48] Each light unit 5 and 6 comprises a DC / DC converter 51,

respectively 61, arranged to supply electrical power to light sources 52 to 54, respectively 62 to 63 and which receives for this purpose electrical signals transmitted by the associated node 3, respectively 4, to control the supply of electrical power.

[49] We will now describe the structure of the light source 52, being

understood that the other light sources 53 to 54 and 62 to 63 have an identical structure.

[50] The light source 52 includes an integrated controller 10 and four

light emitters r, g, b and w, each capable of emitting red, green, blue or white light, the emitters r, g, b, w and the integrated controller 10 being integrated in the same housing of the light source 52. The light source 52 has four ports, namely a port for receiving electrical power from the DC / DC converter 51, a ground port (not shown), an input port for data and a data output port through which it receives and transmits messages on the secondary data bus 50.

[51] The integrated light source controller 10 52 is arranged to receive the instructions sent by the central control unit 1 on the main bus 101 and transmitted on the secondary bus 50 by the node 3. These instructions can be interpreted directly by the controller 10 which controls the light emitters r, g, b and w of the light source 52 as a function in order to achieve the desired light function. To this end, the integrated controller 10 includes a circuit for controlling the supply of light emitters and a memory in which one or more correspondence tables are stored between instructions and supply values.

[52] For example, when the central control unit 1 receives an instruction

activation of a scrolling lighting function of desired color and intensity in a specific area of the passenger compartment, it sends a request for sequential activation of the light sources 52 to 54, containing the addresses of these sources and, for each address, a light emission instruction corresponding to the desired intensity and color as well as a start and an end of emission. The request is transmitted via the main bus 101 to node 3, which relays the request on the secondary bus 50 to the light source 52. The integrated controller 10 recognizes in the request the address of the light source 52 and processes the request to extract the associated instruction. The controller 10 determines, via its correspondence tables, the power supply values corresponding to the instruction for each of the transmitters and controls the power supply supplied by the DC / DC converter 51 to adjust its value to the determined power supply values of so that the light source 52 emits light of desired intensity and color, between the start and the end of the required emission.

[53] The secondary buses 50 and 60 connect the light sources of the light units 5 and 6 in series. In the example shown, each secondary data bus 50, 60 connects the data output port of a source

light at the data input port of the next light source so that the data propagating on the secondary bus 50, 60 is transmitted from each light source to the adjacent light source. The request processed by the integrated controller 10 of the light source 52 is thus relayed to the light source 53, whose integrated controller processes this request in an equivalent manner, and also relays this request to the next source, until all of the instructions in the request. It thus appears that the light sources can be grouped into more compact light units, in which the length of the secondary data bus is limited, so as to reduce the losses in bandwidths and to increase the resistance of the light units towards against electromagnetic disturbances. In addition, the nodes between the light units and the main data bus are devoid of data processing capacity, which makes them on the one hand less expensive and on the other hand easier to design to absorb variations in electric power .

[54] We have described in [FIG. 2] a light unit 7 of the lighting device 100 of FIG. 1, coupled to the main data bus 101 by a node 75. The light unit comprises a DC / DC converter 71, a secondary data bus 70 and a plurality of light sources 72 to 74 at all points similar to those of the light units 5 and 6 of [Figure 1], with the difference each light source 72 to 74 comprises a switch 76 to authorize or prohibit data transmission from secondary bus 70 to the next light source.

[55] [Figure 3] presents a configuration method according to the invention of

lighting device 100 and in particular of the light unit 7.

[56] During a first step E1 of production of the lighting device, group addresses @ G1, @ G2 and @ G3 are stored in the memory of the integrated controller of each of the light sources 52 to 54, 62 to 63 and 72 to 74, as well as in the memory of the central control unit 1. In other words, all the light sources of the same light unit have the same group address during the production of the lighting device. In addition, all of the switches 76 are configured, during this step E1, in an open state. [57] When the lighting device is put into service for the first time, the central control unit 1 selects in a step E2 a given group address @GD, corresponding to the address @ G3, from a list of group addresses stored in its memory and sends an addressing request on the main bus 101 containing this given group address @GD.

[58] During a step E3, each light unit 5, 6 and 7 receives the request

address, and compares, via the integrated controller of the first light source on the secondary bus, the group address given @GD to the group address stored there. If the given group address matches the stored group address, the light unit processes the addressing request. In this case, the given group address @GD corresponding to the address @ G3, only the light unit 7 can process the addressing request.

[59] During a step E4, the integrated controller of the first light source 72 determines a unique address @ G31 associated with this light source 72, for example by adding a clock reference to the group address @ G3, and stores this unique address @ G31 in the memory of the controller.

[60] In addition, during a step E5, the integrated controller of the first source

light 72 generates an acknowledgment message containing the unique address @ G31, closes the switch 76 of the first light source to authorize the transmission of data to the next light source 73 and transmits on the secondary bus 70 the acknowledgment message .

[61] Thereafter, the next light source 73 receives the message

of acknowledgment (step E6), determines a unique address @ G32 which is associated with it and stores this address in its memory (step E7), appends the unique address @ G32 to the acknowledgment message (step E8), closes the switch 76 and transmits on the secondary bus 70 the acknowledgment message (step E9). It goes without saying that steps E6 to E9 are again implemented by each subsequent light source of the light unit 7 until the secondary data bus 70 loops back to node 75. The acknowledgment message containing all the unique addresses are thus relayed on the main bus 101 until being received by the central control unit 1 (step E10), which in response stores all the unique addresses of the light sources of the unit 7 in its memory (step E11).

[62] As a variant, when an acknowledgment message is received by a light source, this source could on the one hand transmit this message

of acknowledgment on the secondary bus 70 without modifying it, by closing its switch beforehand, then determining a unique address and transmitting a new acknowledgment message on the secondary bus containing this unique address. The central control unit 1 would therefore receive from the light unit 7 as many acknowledgment messages as the light unit 7 contains sources

bright

[63] Finally, the central control unit 1 again selects in a step E2 a new given group address @GD, corresponding to another group address, for example @ G1, from the list of addresses of group stored in its memory and issues a new addressing request on the main bus 101 containing this given group address @GD. The steps E2 to E1 1 are thus repeated until the group addresses in the list of group addresses stored in the memory of the central control unit 1 are exhausted. Ultimately, the central control unit 1 has in memory

all the unique addresses of all the light sources of the light units of the lighting device, through a simple configuration process, which does not require any intermediate controller.

[64] We have described in [FIG. 4] a light unit 8 of the lighting device 100 of FIG. 1, coupled to the main data bus 101 by a node 85. The light unit comprises a DC / DC converter 81, a secondary data bus 80 and a plurality of light sources 82 to 84 at all points similar to those of the light units 5 and 6 of [Figure 1]. The light unit 8 also comprises an interface 86 capable of detecting an interaction of an occupant of the vehicle with said interface 86.

[65] We will now describe two modes of operation of the device

lighting. [66] In a first mode, the central control unit 1 can detect a need to stop the electrical consumption of the lighting device 100, for example during inactivity of the users of the passenger compartment of the vehicle. If necessary, the central control unit 1 transmits an electrical extinction signal to all the light units 5 to 8 on the main data bus 101.

Each node 3, 4, 75 and 85 associated with these light units transmits said electrical extinction signal to the DC / DC converters 51, 61, 71 and 81, on reception of which each DC / DC converter interrupts the supply of power electric to light sources.

[67] Following the first mode, the interface 86 of the light unit 8 can detect an interaction requiring the restoration of the electrical consumption of the lighting device 100. The interface 86 emits, following the detection of the interaction , an electrical recovery signal to the associated node 85. The node 85 transmits on the one hand the electrical recovery signal to the DC / DC converter 81 to restore the supply of electrical power to the light sources 82 to 84. It also transmits said electrical signal from

recovery to the main data bus 101. All the other associated nodes 3, 4 and 75 therefore receive the electrical recovery signal and transmit this electrical recovery signal to the DC / DC converters 51, 61 and 71 to restore the supply of the power supply to light sources. It goes without saying that the electrical recovery signal could also be transmitted directly by the central control unit 1 on the main data bus 101.

[68] The foregoing description clearly explains how the invention makes it possible to achieve the objectives which it has set itself, and in particular to propose a lighting device for the interior of the passenger compartment of a motor vehicle which reliable, fast, inexpensive and resistant to variations in electrical power. The method and the lighting device according to the invention make it possible to combine a large number of light sources into compact light units, in which the length of the secondary data bus is limited and in which the light sources are easily addressable. In addition, the nodes between the light units and the main data bus are lacking data processing capacity, making them less expensive and easier to design to absorb variations in electrical power.

[69] The invention cannot be limited to the embodiments specifically given in this document by way of nonlimiting examples, and extends in particular to all equivalent means and to any technically operative combination of these means. Thus, the characteristics, the variants and the various embodiments of the invention can be associated with one another, in various combinations, insofar as they are not incompatible or mutually exclusive of one another.

Claims

Claims

[Claim 1] Method for configuring a lighting device for the interior of the passenger compartment (100) of a motor vehicle, the lighting device comprising:

at. a central control unit (1);

b. a main data bus (101);

vs. at least a first light unit (7) coupled to the central control unit via the main data bus and comprising several light sources (72,73,74) each provided with an integrated controller (10) and a secondary bus of data (70) coupled to the main data bus and connecting the light sources of the first light unit in series;

characterized in that it comprises the following stages:

d. prior storage in each light source of the

first light unit the same first group address (E1);

e. transmission by the central control unit on the main bus of an addressing request containing a given group address (E2); f. reception of the addressing request by the first source

light of the first light unit on the secondary bus, and the comparison of the group address given to the first group address (E3);

g. if the given group address is identical to the first group address, the storage in the first light source of a unique address associated with it (E4) and the transmission of an acknowledgment message containing this unique address on the secondary bus (E5);

h. reception of the acknowledgment message by an adjacent light source (E6); and in response, the storage in this adjacent light source of a unique address associated with it (E7), and the transmission of an acknowledgment message containing this unique address on the secondary bus (E9).

[Claim 2] Method according to the preceding claim, at least one of the light sources (72,73,74) of the first light unit (7) comprises a switch (76) for authorizing or prohibiting the transmission of data from the secondary bus (70) to the next light source, in which the transmission of an acknowledgment message by this light source on the secondary bus comprises a substep of closing said switch to authorize the transmission of data to the next light source (E5 , E9).

[Claim 3] Method according to one of the preceding claims, in which each acknowledgment message transmitted by a light source (72,73,74) from the first light unit (7) and received by an adjacent light source is transmitted by this adjacent light source on the secondary data bus (70) without modification of the data included in this acknowledgment message.

[Claim 4] Method according to one of claims 1 or 2, wherein each light source (72,73,74) of the first light unit (7) receiving an acknowledgment message transmitted by the previous light source appends its address unique to the acknowledgment message and transmits this modified acknowledgment message to the secondary data bus (70).

[Claim 5] Method according to one of the preceding claims, characterized in that it further comprises:

at. the transmission of the acknowledgment message (s) sent by the

light sources (72,73,74) from the first light unit (7) to the central control unit (1) (E10);

b. the storage in the central control unit of the unique addresses of all the light sources of the first light unit (E1 1).

[Claim 6] Method according to the preceding claim, the lighting device (100) further comprising a second light unit (5) coupled to the central control unit (1) via the main data bus (101 (and comprising several light sources (52,53,54) each provided with an integrated controller (10) and a secondary data bus coupled (50) to the main data bus and connecting the light sources of the second light unit in series, characterized in that it comprises the following stages:

at. prior storage in each light source of the

second light unit with the same second group address (E1);

b. after the storage step in the central control unit

unique addresses of all the light sources of the first light unit (E1 1), the emission by the central control unit on the main bus of an address request containing another given group address (E2).

[Claim 7] Method according to the preceding claim, in which the step of emission by the central control unit (1) of another given group address (E2) is carried out after all the messages

of acknowledgments transmitted by the light sources (72,73,74) of the first light unit (7) have been received by the central control unit.

[Claim 8] Lighting device (100) for the interior of the passenger compartment of a motor vehicle, comprising:

at. a central control unit (1);

b. a main data bus (101);

vs. at least a first light unit (7) coupled to the central control unit via the main data bus and comprising several light sources (72,73,74) each provided with an integrated controller (10) and a secondary bus of data (70) coupled to the main data bus and connecting the light sources of the first light unit in series;

characterized in that at least one light source from the first light unit includes a switch (76) for authorizing or prohibiting the transmission of data from the secondary bus to the next light source.

[Claim 9] Device (100) according to the preceding claim,

characterized in that the central control unit (1) and the controllers (10 = light sources (72,73,74) of the first light unit (7) are arranged to carry out the method according to one of the claims 1 to

8.I