FR3010484A1 - DEVICE FOR LIGHTING A MOTOR VEHICLE - Google Patents

Abstract

The invention relates to a lighting device for a passenger compartment (24) of a motor vehicle, of the type comprising an optical assembly (2) formed in particular of a light guide (16) and at least one light source (18). ) which emits light rays propagated by said guide to an outlet face (22) for the illumination of said passenger compartment. The device comprises a touch interface (4) made of a material transparent to light rays and disposed opposite the exit face, in the path of said light rays. Sensor means (6) are provided for detecting a contact on the touch interface, and a microprocessor is adapted to control the ignition and / or extinction of the at least one source depending on the location and the quality of the contact. light. The invention also relates to a method of lighting and / or signaling of a passenger compartment of a motor vehicle, as well as a corresponding vehicle.

Description

The technical field of the invention is that of lighting and signaling in the passenger compartment of a motor vehicle.

In recent years, car manufacturers have sought to provide adaptive lighting, both functional and ambient, that the user can vary at will. Control buttons are available to the user and the latter uses them to turn on or off the lighting means, or to vary the intensity, for example. However, this feature offered to the user is added to others already present in the vehicle, both for lighting and other comfort functions such as air conditioning for example. This results in a multiplication of the control buttons that must manage the driver or passengers of the vehicle. The present invention is placed in this context and is intended to provide a lighting device interior of the vehicle that is functional and ambience with a simple and intuitive user interface. For this purpose, the invention proposes a device for illuminating a passenger compartment of a motor vehicle, of the type comprising an optical assembly comprising at least one light source which emits light rays towards an exit face of the optical assembly for the purpose of cockpit lighting. It is understood that the source can emit directly or indirectly rays to this output face. According to essential features of the invention, the device comprises a touch interface and sensor means for detecting at least one contact on the touch interface and the quality of the latter, and a microprocessor for controlling according to the location and the quality of the contact ignition and / or extinction of a particular light source. The term "contact quality" is understood to mean one or more characteristics of the contact, among which, for example, are linearity, punctuality, intensity, duration, and number of simultaneous contacts. The touch interface, made of a material transparent to light, is arranged opposite the exit face, in the path of the light rays towards the passenger compartment. Thus, the microprocessor sends control instructions to the light source for its ignition and / or extinction, this light source being adapted to emit light rays through the affected area at the touch interface. Thus, it is sufficient for the user to touch an area of the touch interface so that it illuminates or goes out. The handling of the device is then particularly intuitive. The touch interface is substantially rectangular and at least four sensor means are provided, one at each of the corners of the touch interface. Six sensor means may also be provided with two additional sensor means each disposed in the middle of each of the long sides of the touch interface. In these two cases, the microprocessor is adapted on the one hand to receive data from each of the sensor means relating to the deformation of the touch interface and on the other hand to compile these data to determine the contact area on the interface touch. The calculation method used by the microprocessor may in particular consist of a center of gravity calculation. Thus, it is precisely determined the area of the touch interface that has been touched by the user and one thus ensures to illuminate exactly the desired area. In the case of application of six sensor means arranged around the touch interface, they are connected three by three to the same electronic card. The two electronic cards are connected to the microprocessor to transmit the information recorded by the sensor means.

According to one characteristic of the invention, the at least one light source is a light-emitting diode. And advantageously, the device comprises at least two light sources of distinct type, in particular in that they emit rays of different wavelengths. Thus, primary light sources are RGB diodes, acronym for Red-Green-Blue diode, adapted to emit light rays of a wavelength that can be modulated by the microprocessor, while the secondary light sources are adapted diodes to emit only light rays of white color. According to a particular embodiment of the invention, the optical assembly comprises a light guide comprising an input face and an output face, the light rays propagating in the guide from one to the other of these faces by total internal reflection. The input face is arranged so that light rays coming from the light source and reaching this input face penetrate into the guide, while the output face is arranged so that light rays propagating in the guide and reaching this point. exit face out of the guide.

According to a specific characteristic of a specific embodiment of the invention, the light guide is distinct from the touch interface, in which there is an upper face and a lower face. The output face of the light guide is then arranged opposite an upper face of the touch interface. The light guide takes the form of a panel having a longitudinal and vertical plane of symmetry, while the light sources are arranged along an axis included in the plane of symmetry of the light guide. The light guide comprises a central part and two lateral parts extending symmetrically on either side of the central part, each lateral part having an upper face bearing decoupling faces in that they direct the light rays coming from the light sources and propagating in the light guide to the corresponding lower face forming the exit face of the light guide. In addition, the free end of each of the lateral parts is extended by an oblique portion of connection to a fin substantially parallel to the plane defined by the exit face. The central portion has an upper face forming the entrance face of the light guide and a lower face arranged to return the rays of light entering the guide to the decoupling faces. This lower face of the central portion may for example be of parabolic profile throughout the longitudinal dimension of the guide, with a line of foci on which is disposed the image of the light source formed by the input diopter.

The light guide is then covered by a touch interface disposed between it and the passenger compartment. The touch interface has a central area and a peripheral area, and when the guide is attached to the touch interface, the central portion of the guide and the central area of the interface are superimposed while the peripheral area of the touch interface covers the two lateral parts of the light guide.

The peripheral zone is transparent or translucent, and it can be provided according to alternative embodiments that the central zone of the touch interface is opaque or as the peripheral zone, transparent or translucent. The touch interface also carries, on its upper face facing the light guide, secondary light sources which are housed in a clearance of the light guide at its central portion. These secondary light sources are arranged so that their emitting surface is turned towards the touch interface. Thus, when the primary light sources are on, the rays travel through the light guide to cross the transparent touch interface at its peripheral zone. If a contact has occurred in the peripheral zone of the touch interface, the microprocessor generates a control command of the primary light sources, for lighting through the peripheral zone of the touch interface, via reflection of the light rays by the light guide. On the other hand, if contact has taken place in the central zone of the touch interface, the microprocessor generates a control instruction for the secondary light sources, the rays then passing directly through the touch interface at its central zone. Thus, it is ensured that it can correctly illuminate the area touched by the user. If it is the central area that has been affected is that the user wants to control the switching on or off secondary light sources, that is to say, the white lights as a reading light. If it is the peripheral zone that has been touched, it is because the user wishes to control the switching on or off of the primary light sources, ie the colored emission diodes for a light of atmosphere. According to various features of a preferred embodiment of the invention, the tactile interface has a substantially flat plate shape, in particular having a longitudinal and vertical plane of symmetry substantially parallel to that of the light guide when the latter is attached to the touch interface. The plate has at least one of its transverse ends a raised edge arranged to receive the guide fixing fins and whose free end is offset from the flat plate of the interface and adapted to house the sensor means for the detection of the vibration of the plate. The free end takes the form of a gutter that can extend continuously over the entire length of the touch interface, and which has two vertical uprights and a bottom wall. This bottom wall extends substantially parallel to the plane of the plate of the touch interface, and the inner vertical upright, closest to the center of the interface, serving as a support for the fin guide that rests on the touch interface only at this level, without there being any contact elsewhere between the output face of the guide and the interface. The sensor means each comprise two sensors disposed on either side of the bottom wall of the gutter offset from the plate, carried by a frame partially surrounding said gutter. The sensors can be capacitive, resistive or inductive. According to a particular characteristic of the invention, the device comprises a piezoelectric element for forming a touch confirmation by sensory feedback, in particular by vibrating the tactile interface or by producing a sound. The invention also relates to a lighting and / or signaling method of a passenger compartment of a motor vehicle, in which the ignition or extinction of a light source is controlled as a function of the detected area of a contact on a vehicle. the touch interface.

According to various features of this method, it controls the switching on or off of a primary light source of the optical assembly for the illumination of the passenger compartment at a peripheral zone of the touch interface when punctually touch the touch interface in this peripheral zone, and it controls the switching on or off of a secondary light source of the optical assembly for the illumination of the passenger compartment at a central zone of the touch interface when punctually touching the touch interface in this central area. The method according to the invention furthermore provides that when the touch interface is touched for several seconds in one of the zones, the intensity of the illumination provided by the corresponding light source is modified until the contact is stopped on the touch interface.

Moreover, while one of the plurality of primary light sources or one of the plurality of secondary light sources can be ignited independently, the method provides that when the contact in one of the zones is linear, the ignition is started. the primary or secondary light source for illuminating the end region of the linear contact. Advantageously, the method is implemented by the device according to the invention. The invention also relates to a motor vehicle comprising a lighting and / or signaling device as described above, and in particular a vehicle in which this device is housed inside the roof.

Other characteristics and advantages of the invention will appear on reading the detailed description of an embodiment which follows and for the understanding of which reference will be made to the appended drawings in which: FIG. 1 is a perspective view a lighting device and / or signaling the passenger compartment of a motor vehicle according to one embodiment of the invention, comprising in particular a touch interface carrying a central zone and a peripheral zone; Figure 2 is a block diagram representative of the lighting and / or signaling method of the passenger compartment of a motor vehicle according to the invention; Figure 3 is a sectional view along the plane shown in Figure 1.

In the following description, a longitudinal, vertical and transverse orientation will be adopted in a non-limiting manner according to the orientation conventionally used in the automobile and indicated by the trihedron L, V, T shown in FIGS. 1 and 3. illustrated in the figures, a motor vehicle comprises a lighting device and / or signaling of its interior cabin. The device comprises according to the invention at least one optical assembly 2, a touch interface 4, sensor means 6 for detecting a contact on the touch interface and the quality thereof, and a control assembly 8 adapted from a part to receive data from the sensor means and secondly to generate control instructions for the optical assembly.

The device is housed in an opening 10 formed in a structural element 12 of the vehicle. It may for example implement the device in a flag or in a dashboard, without this place of implementation outside the context of the invention. It will be particularly interesting to place the device near an occupant of the vehicle, so that it can use the touch interface. The device is housed in the structure so that the touch interface is flush with the edges 14 defining the opening formed for this purpose in the structural element. The optical assembly comprises a light guide 16 and a primary light source 18 adapted to emit light rays propagated by the light guide from an input face 20 to an exit face 22 of the guide facing the passenger compartment 24 of the vehicle. It further comprises a secondary light source 26, capable of emitting light rays of a wavelength different from that of the rays emitted by the primary light source, and in a direction of emission potentially different from that of the light source. primary.

The primary and secondary light sources are here chosen from light-emitting diodes so that they are associated in the device in known manner on a printed circuit board, not shown in the figures. Advantageously, a plurality of primary light sources and a plurality of secondary light sources, arranged substantially longitudinally in the plane of symmetry of the guide, are provided. The primary light sources are RGB diodes, acronym for Red-Green-Blue diode, adapted to emit light rays of a wavelength that can be modulated by the microprocessor. They are arranged above the light guide, facing the entrance face, so that the rays they emit all enter the guide. RGB diodes are reported on a printed circuit board, not shown here, made integral with the structural element. The secondary light sources are diodes adapted to emit white light rays. They are carried by the touch interface, so as to extend, as illustrated in Figure 3, between the latter and the light guide. It will be understood that the secondary light sources could be indifferently housed in the thickness of the touch interface.

The light guide takes the form of a plate 28 having a longitudinal and vertical plane of symmetry P, while the light sources are arranged in the plane of symmetry of the light guide. The light guide comprises a central portion 30 and two lateral portions 32 extending symmetrically on either side of the central portion. The central part of the light guide comprises an upper face forming the input face 20 of the guide for the light rays coming from the primary light sources, and it has a lower face 34 hollowed towards the inside of the guide by having a parabolic shape, to form a coupling face 36 allowing the rays from sources disposed at the focus of the parabola and meeting the coupling face to be oriented within the guide to propagate by total internal reflections. It is at the level of this clearance of the central part, formed by the hollowed underside, that the secondary light sources are arranged. While the light guide is made of transparent material, for example PMMA, the coupling face is metallized so as to improve the reflection of the light coming from the primary light sources. Each side portion has a lower face forming the exit face of the light guide and an upper face 38 bearing a stepped alternation of decoupling faces 40 and internal reflection faces 42, the decoupling faces consisting of an optical surface arranged to allow the radii coupled within the guide to be reflected to the exit face at an incident angle as they exit the guide by refraction via this exit face. At the free end of each of the lateral parts, the guide is extended by an oblique portion 44 which extends transversely opposite the guide and vertically in the direction of approach to the primary light source. This oblique portion is connected at its free end to a fin 46 which extends substantially parallel to the plane defined by the exit face. Advantageously, each decoupling face is arranged so as to reflect the rays of light reaching it so that light bands are visible through the exit face. Thus, when the light source is on, the guide has a plurality of light lines 48 (visible in Figure 1) on the output face. The arrangement of the decoupling faces makes it possible to define the luminous pattern produced by the device. Indeed, the shape of the decoupling faces and their arrangement relative to each other can produce, for example, lines of light distant from each other, linear or curved, and can join. In the case of a plurality of primary light sources, it is possible to control one rather than the other, or one more intensely than the other, to accentuate the light intensity of a specific portion of the light. the light line produced on the exit face. It is thus possible to create lighting sequences in which the pavilion is illuminated more intensively by successive portions from the front to the rear of the vehicle. The touch interface is arranged to extend between the optical assembly and the passenger compartment. It has a substantially flat plate form 50, made of transparent material to let light rays from the primary and secondary light sources towards the passenger compartment. The plate has a plane of symmetry longitudinal and vertical substantially parallel, or merged with that of the light guide when the latter is attached to the touch interface. The plate has at its transverse ends a raised edge 52 whose free end has a gutter shape 54, continuous over the entire length of the touch interface. The channel comprises two vertical uprights and a bottom wall 56, which extends substantially parallel to the plane of the plate of the touch interface. The two vertical uprights are differentiated by an internal upright 58 and an external upright 60, designated as a function of their proximity to the center of the interface. The internal amount serves as a support for the fin guide that relies on the touch interface only at this level. There is no contact between the exit face of the guide and the interface. A rubber 62 is disposed on the upper end of the inner post of the touch interface to receive the guide. The touch interface is substantially rectangular and comprises two functional zones, which can be physically delimited by a boundary drawn on the interface plate, as illustrated in FIG. 1. These two functional zones are a central zone 64 and a peripheral zone 66, such that, when the light guide rests on the touch interface, the central zone of the interface and the central part of the light guide are superimposed while the peripheral zone of the tactile interface covers the two side parts of the light guide. In the embodiment illustrated in Figure 3, the light guide is distinct from the touch interface. The lower face of the light guide is then arranged opposite the upper face of the touch interface so that the exit face of the guide through which the light rays coming from the primary light sources emerge is arranged facing the peripheral zone of the the touch interface. As will be described later in the description of the lighting and / or signaling method, it is understood that when the primary light sources are on, the rays go through the light guide to cross the transparent touch interface at the level of the light. of its peripheral zone, whereas, when it is the secondary light sources which are lit, the rays pass directly through the tactile interface at its central zone.

According to the invention, the choice of ignition of the primary or secondary light sources is done by the user by pressing on the touch interface in the desired area. To detect which area is touched by the user, sensor means 6 are provided. They consist of a pair of capacitive (or resistive) sensors carried by a frame 68 so as to be facing one another. The armature is formed in two parts, each bearing one of the two sensors, screwed one on the other for mounting around the remote gutter of the touch interface. A lower portion of the frame carries a sensor and maintains contact with the outer face of the bottom wall, that is to say the face disposed outside the gutter. For this purpose, the lower part has a square shape on which the upper part of the frame is screwed. This upper part has an arm immersed in the gutter to maintain the associated sensor against the inner face of the bottom wall. At least four sensor means are provided, one at each of the corners of the touch interface. One can provide as shown in Figure 1, six sensor means by combining the means provided in each corner two additional sensor means respectively disposed on one of the long sides of the touch interface, substantially in the middle of these long sides.

As previously described, the sensor means are held in contact with the touch interface for the detection of its vibration, at a remote gutter of the plate forming the interface. This gutter can be deported continuously along the entire length of the touch interface or only in a few specific areas, three on each of the long sides, to receive the sensors. The control assembly comprises a microprocessor, not shown in the figures, adapted to determine, depending on the location and the quality of the contact made by the user on the touch interface, ignition instructions and / or extinction of this or that light source. For this purpose, the microprocessor is adapted on the one hand to receive data from each of the sensor means relating to the deformation of the touch interface and on the other hand to compile these data to determine the contact area on the touch interface . The calculation method used by the microprocessor may for example consist of a center of gravity calculation, giving each measurement made by one of the six sensors a weighting corresponding to the deformation value of the touch interface recorded by these sensors. Once this calculation is made and the position of the estimated contact, the microprocessor is advantageously programmed to compare this position with the geometric data of the touch interface recorded in the memory of the microprocessor. If the comparison causes the microprocessor to estimate that the contact has occurred in the central area of the touch interface, the microprocessor generates a control instruction of the secondary light sources, to provide illumination through the central area of the touch interface. . Similarly, if the comparison causes the microprocessor to estimate that the contact has taken place in the peripheral zone, outside the central zone of the touch interface, the microprocessor generates a control instruction for the primary light sources, for provide illumination through the peripheral area of the touch interface, through reflection of the light rays by the light guide. The control assembly may further comprise two intermediate electronic cards 72, which are each arranged on one side of the touch interface to facilitate the transfer of information from the sensor means to the microprocessor. The three sensor means arranged on the same side of the interface are connected to a first electronic card and the other three sensor means are connected to a second electronic card. The two electronic cards are connected to the microprocessor to transmit the information recorded by the sensor means. To connect the sensors to the microprocessor, via the electronic cards, it is possible to produce, as illustrated in FIG. 3, a hole 74 in the armature. Moreover, as can be seen in FIG. 1, the device may comprise a piezoelectric element 76 carried by the touch interface and connected to the microprocessor. The piezoelectric element can alternately function as an actuator or as a detection means and the information transfer is in one direction or the other between the piezoelectric element and the microprocessor. When operating as a receiver, the piezoelectric element can provide information complementary to that provided by the sensor means. When operating as an actuator, the piezoelectric element receives control commands from the microprocessor to produce mechanical motion and vibrationally deform the touch interface. It will thus be possible to advantageously create a feedback for the user of the tactile interface, and to form a confirmation of the touch by sensory feedback, in particular by vibrating the interface and possibly by producing a sound. The lighting and / or signaling method according to the invention will now be described, with particular reference to the block diagram illustrated in FIG. 2. The different light sources, primary and secondary, may be on or off and operate with a light. variable intensity according to the request provided by the user. When the control assembly has detected the presence of a user (step S1), whether by detecting the opening of a door or by detecting weight on a seat (data D1), the microprocessor proceeds to continuous ignition of the primary light sources (step S2), which are controlled so as to emit in the basic configuration a light of a predetermined color by the user (data D2). This mood light is changed as soon as the user touches the peripheral area of the touch interface. The microprocessor communicates in loop with the sensor means to know the possible existence of a contact on the touch interface (step S3). At this time, the microprocessor generates a control command to change the intensity of each of the red, green and blue diodes that form the RGB diode of the primary light source. The microprocessor then determines in which area of the touch interface the contact took place (step S4). Firstly, the process steps that occur when the user has touched the touch interface in his peripheral area are described. At this point, the microprocessor determines whether the contact is localized on a specific point or whether it is linear (step S5). In the case of a localized contact, the microprocessor then determines the duration of the contact (step S6). If the user makes a single point contact, the microprocessor generates an ON / OFF command instruction of the primary light sources so that the primary light sources emit white light, for the main illumination of the passenger compartment, if they emitted then a background light and they emit a mood light if they emitted a white light at the moment of contact (step S7). In the case of prolonged contact, the microprocessor generates a control command for the primary light sources to emit light of the same color as before, ie white or the predetermined ambient color according to the state before contact, but more intensely, the increase in intensity being proportional to the duration of the prolonged contact (step S8). Finally, if the user makes a pointless but linear contact, the microprocessor determines a control instruction of the primary light sources so that only the end region of the linear contact is illuminated by a white light, the rest of the peripheral zone remaining as an ambient light of the predetermined color (step S9). The various scenarios of the lighting and / or signaling method also incorporate the possibility that the user touches the touch interface in the central zone. The microprocessor then generates a control instruction for the secondary light sources corresponding to the affected area to emit white light targeted for reading (step S9). Here again, a test is carried out beforehand to know the point or linear quality of the contact (step S10) and the duration of the possible point contact (step S11), to lead as previously to the realization of a lighting intensity proportional to the duration of the contact (step S12) or the ignition of a specific secondary light source when the user slides his finger (step S13).

The foregoing description clearly explains how the invention makes it possible to achieve the objectives that it has set itself and in particular to propose a lighting and / or signaling device that can be easily arranged in a motor vehicle structure element. for the interior lighting of this one, and which presents a simple and intuitive control interface.

However, the invention is not limited to the only device according to the embodiment explicitly described with reference to Figures 1 to 3, nor only to a specific application. By way of example, it will be possible, without departing from the scope of the invention, to modify the number and the arrangement of the light sources, the number and the arrangement of the sensor means. It will also be possible to provide a device in which the optical assembly opposite the touch interface is different, in particular for the shape of the guide, the input face of which may be arranged laterally to the structural element. The primary light sources will not be located in the center of the guide but on the side of it, and it will be understood that in this case, the central coupling face does not have to be and will develop a zone different to accommodate the secondary light sources to the right of the central area of the touch interface.

Claims (18)

REVENDICATIONS1. Device for illuminating a passenger compartment (24) of a motor vehicle, of the type comprising an optical assembly (2) comprising at least one light source (18) which emits light rays towards an exit face (22) of the assembly optical for the illumination of said passenger compartment, characterized in that it comprises a touch interface (4), at least a portion of which is made of a transparent or translucent material with light rays and arranged opposite the exit face, on the path said light rays, and in that it comprises sensor means (6) for detecting at least one contact on the touch interface, as well as a microprocessor for controlling, depending on the location and the quality of the contact, ignition and / or the extinction of the at least one light source. 2. Device according to claim 1, characterized in that the touch interface (4) is substantially rectangular and at least four sensor means (6) are provided, one at each corner of the touch interface. 3. Device according to claim 2, characterized in that said microprocessor is adapted on the one hand to receive data from each of the sensor means relating to the deformation of the touch interface and on the other hand to compile these data to determine, especially by triangulation, the contact area on the touch interface. 4. Device according to claim 3, characterized in that it comprises six sensor means (6), among which one of the sensor means is disposed at each corner of the touch interface (4) and one of the sensor means is disposed in the middle the large side of the touch interface, and characterized in that the sensor means are connected three by three to the same electronic card (72), they themselves connected to the microprocessor. 5. Device according to one of the preceding claims, characterized in that the at least one light source (18) is a light emitting diode. 6. Device according to claim 5, characterized in that it comprises at least two light sources of different types. 7. Device according to claim 6, characterized in that primary light sources (18) are RGB diodes adapted to emit light rays of a wavelength that can be modulated by the microprocessor while said second light sources (26). ) are diodes adapted to emit only light rays of white color. 8. Device according to one of the preceding claims, characterized in that the optical assembly comprises a light guide comprising an input face arranged so that light rays from the light source and reaching this input face penetrate into the guide, an output face arranged so that light rays propagating in the guide and reaching this exit face out of the guide, the light rays propagating in the guide by total internal reflection. 9. Device according to claim 8, characterized in that the light guide (16) takes the form of a panel (28) having a longitudinal and vertical plane of symmetry (P), while primary light sources (18). are arranged facing the light guide longitudinally along an axis included in the plane of symmetry of the light guide. 10. Device according to the preceding claim, characterized in that the light guide comprises a central portion (30) and two side portions (32) extending symmetrically on either side of the central portion, each lateral portion having a upper face carrying decoupling faces (40) in that they direct the light rays from the primary light sources and propagating in the light guide to the corresponding lower face forming the output face (22) of the light guide. 11. Device according to claim 10, characterized in that the touch interface comprises a central zone (64) and a peripheral zone (66) in such a way that, when the light leg (16) is covered by the touch interface ( 4) disposed between said guide and the passenger compartment (24), the central zone of the interface and the central portion (30) of the light guide are superimposed while the peripheral zone of the tactile interface covers the two lateral parts ( 32) of the light guide. 12. Device according to one of claims 8 to 11, characterized in that the light guide (16) has at its periphery fixing fins (46) and in that the touch interface (4) has a shape of plate (50) substantially flat, in particular having a longitudinal and vertical plane of symmetry substantially parallel to that of the light guide when the latter is attached to the touch interface, said plate having at least one of its transverse ends a raised edge ( 52) arranged to receive the fixing fins of the guide and whose free end is offset from the flat plate of the interface and adapted to accommodate the sensor means (6) for detecting the vibration of the plate. 13. Device according to the preceding claim, characterized in that the free end takes the form of a gutter (54) having two vertical uprights (58, 60) and a bottom wall (56), which extends substantially parallel. in the plane of the plate (50) of the touch interface, the inner vertical upright (58), closest to the center of the interface, serving as a support for the fin (46) of the guide which rests on the interface touch (4) only at this level. 14. Device according to claim 13, characterized in that each sensor means (6) comprises two sensors disposed on either side of the bottom wall (56) of the gutter, carried by a frame (68) partially surrounding said gutter (54). 15. Motor vehicle comprising a device according to one of claims 1 to 14, said device being integrated in a structural element (12) so that the touch interface (4) is flush with the edges (14) defining a aperture (10) made in said structural member for receiving said device. 16. A method of lighting and / or signaling a passenger compartment (24) of a motor vehicle comprising a structural element (12) in which is housed an optical assembly (2) and a touch interface (4) interposed between the passenger compartment and the optical assembly, characterized in that it controls the switching on or off of a primary light source (18) of the optical assembly for the illumination of the passenger compartment at a zone peripheral device (66) of the touch interface when touching the touch interface in this peripheral zone, and in that it controls the switching on or off of a secondary light source (26) of the Ootic assembly for the illumination of the passenger compartment at a central zone (64) of the touch interface when touching punctually the touch interface in this central area. 17. A method of lighting and / or signaling according to claim 16, characterized in that when touching for several seconds the touch interface (4) in one of said zones, the intensity of the lighting provided by the source corresponding light is changed until contact is terminated on the touch interface. 18. A method of lighting and / or signaling according to claim 16 or 17, wherein one of the plurality of primary light sources (18) or one of the plurality of secondary light sources (26) can be independently ignited, characterized in that when the contact on the touch interface (4) in one of said zones is linear, the primary or secondary light source is switched on to illuminate the end region of the linear contact.