FR3058938B1 - INTERFACE FOR MOTOR VEHICLE AND INTERFACING METHOD - Google Patents

Abstract

The invention relates to an interface (1) for controlling at least one function of a motor vehicle body, comprising: - at least one control member (2) comprising: - a rotating wheel (4), - at less a metal index (6) carried by the rotary wheel (4) and movable with it, - a guide (5), the rotary wheel (4) being supported and guided in rotation by the guide (5), - a touch screen (30) configured to detect the position of the metal index (6), the guide (5) being fixed on the touch screen (30), the metal index (6) being arranged next to the screen tactile device (30), characterized in that: - the guide (5) and the rotating wheel (4) have respective shapes of rings with a central orifice (7), - the control member (2) further comprising: ○ a spacer (12) fixed on the touch screen (30) in the central orifice (7), and ○ at least a first conductor and a second conductor (13aa ... 1 3dc), each conductor ( 13aa ... 1 3dc) having at least a first end arranged at a rear face (12a) of the spacer (12) opposite the touch screen (30) and at least a second end arranged at the level a front face (12b) of the spacer (12) opposite to the rear face (12a) and intended to be touched by the user, the first ends being spaced apart from one another on the rear face ( 12a) and the second ends being spaced apart from one another on the front face (1 2b). The invention also relates to an interfacing method.

Description

Interface for a motor vehicle and method of interfacing

The present invention relates to an interface for controlling at least one function of a motor vehicle body. The invention also relates to an interfacing method.

In the automotive field, the control of electrical components, such as the air conditioning or navigation system, is generally performed by means of a mechanical rotary knob, possibly associated with a screen.

The mechanical button generally comprises a wheel whose angular positioning is determined for example by an optical sensor or by an electric rotary switch. The angular position of the wheel allows a processing unit to select a particular command and to control for example a shutter actuator in the air conditioning system or allows the user to access the input keyboard to enter a destination in the navigation system. Pictograms are usually placed around the wheel to indicate to the user how to manipulate the wheel to get the desired command. This visual environment however remains frozen in time, without adaptation possibilities depending on the manipulation of the button, for example to display information related to navigation in the sub-menus.

Also known is a control system in which a rotary wheel is mounted on a guide fixed on a touch screen. In this system, a capacitive touch screen placed on a screen detects the angular position of a metal index carried by the wheel. The capacitive touch screen thus allows, on the one hand, the tactile input of information and, on the other hand, the detection of the angular position of the rotary mounted wheel on the slab. This system is interesting because it allows in particular to program the display of the touch screen supporting the wheel in relation to different functions to control. For example, the screen can be programmed to display the shutter position and the temperature of the climate system. This same screen with wheel can also be used to display the setting of the audio system settings of the vehicle.

In this system however, some manipulations of the wheel can not be performed. For example, the user can not move through the on-screen menus by pressing right / left, up / down arrows, usually located on the standard navigation buttons. This type of manipulation is however advantageous because it facilitates navigation in the sub-menus without requiring too much attention from the user.

One of the aims of the present invention is to provide an interface and an interfacing method that allow the user to broaden the range of possible interactions with the control button. For this purpose, the subject of the invention is an interface for controlling at least one function of a motor vehicle body, comprising: at least one control member comprising: a rotary wheel, at least one metal index carried by the rotary wheel and movable with it, a guide, the rotary wheel being supported and guided in rotation by the guide, a touch screen configured to detect the position of the metal index, the guide being fixed on the touch screen, the metal index being arranged opposite the touch screen, characterized in that: - the guide and the rotary wheel have respective shapes of rings with a central orifice, - the control member further comprising: o a spacer fixed on the touch screen in the central orifice, and o at least a first conductor and a second conductor, each conductor having at least a first end arranged at a rear face; re of the spacer facing the touch screen and at least a second end arranged at a front face of the spacer opposite the rear face and intended to be touched by the user, the first ends being spaced apart each other on the rear face and the second ends being spaced apart from each other on the front face.

Additional interactions with the manipulation in rotation of the wheel can thus be possible for the user such as for example the input of a command of the type "right or left", "front or back", "up or down", by simple contact or support on the control member or as the input of a command by simply sliding the finger of the user on the control member.

According to one or more characteristics of the interface, taken alone or in combination: the interface comprises at least three conductors whose first ends and / or the second ends are aligned in the same first direction, the interface comprises at least three conductors whose first ends and / or second ends are aligned in the same second direction perpendicular to the first direction, - the interface comprises at least four conductors whose first ends and / or the second ends are arranged in a mesh of meshes with constant dimensions, the first and second ends of the same conductor are arranged one above the other, - the conductors are wholly or partly made of indium-tin oxide, - the front face the spacer is opaque except at display areas defining at least two symbols, such as arrows, - the first and / or second ends of the conductors comprise conductive pads extending in the plane of the front face or the rear face of the spacer, the first and second ends of the conductors are reported on the spacer, the first ends being connected to the second ends by connectors bypassing the spacer, - the conductors pass through the spacer, the first end of each conductor opening from the rear face of the spacer, the second end opening from the front face the interface comprises at least one support sensor configured to measure a parameter representative of a pressing force exerted on the capacitive touch screen, in particular through the control member, the interface is configured to validate the choice of a selected element when the capacitive touch panel detects a contact of the control member e and when a pressing force exerted on the capacitive touch screen exceeds a detection threshold or to generate a haptic feedback on the touch screen when a pressing force exerted on the capacitive touch screen exceeds a detection threshold, - The metal index is a metal tongue, for example copper, - the conductors are opaque metal material, such as copper. The invention also relates to an interfacing method for handling an interface as described above, wherein the interface differentiates at least one detected contact at a first conductor, a contact detected at the level a second driver, for the determination of a command to implement.

According to one or more characteristics of the interfacing method, taken alone or in combination: the interface differentiates a contact in at least four distinct sectors of the front face of the spacer; the interface recognizes a sliding of the finger on the front face of the spacer by successive detections of a contact on at least two conductors within a predetermined time, - the interface detects a direction and / or a speed of the sliding of finger and / or two simultaneous sliding of fingers approaching or move away from each other and / or recognize that the finger slip traces at least one digit, a symbol or a letter, - a bearing force exerted on the capacitive touch screen is measured through the control member for validating a selection, - a pressing force exerted on the capacitive touch panel is measured through the spacer of the control member associated with the detected contact at a level of a controller for parameterizing a parameter associated with said driver, the associated parameter is a scrolling speed. Other features and advantages of the invention will emerge from the following description, given by way of example and without limitation, with reference to the accompanying drawings in which: - Figure 1 shows a view of a portion of the passenger compartment interior of a motor vehicle comprising an interface which is installed as an example at the front panel of the vehicle, - Figure 2 shows a partial sectional view ll of the interface of Figure 1, - Figure 3 shows a schematic view of the interface of FIG. 2; FIG. 4 shows a schematic view of a front face of the control member of the interface of FIG. 2; FIG. 5 shows a view similar to FIG. FIG. 2 for another exemplary interface, FIG. 6a shows a front view of another exemplary interface, FIG. 6b shows a view similar to FIG. 5a, for another example of an interface, FIG. FIG. 6c shows a view similar to FIG. 5a, for another exemplary interface, and - Figure 7 is a flowchart showing different steps of an interfacing process.

In these figures, the identical elements bear the same reference numbers.

The following achievements are examples. Although the description refers to one or more embodiments, this does not necessarily mean that each reference relates to the same embodiment, or that the features apply only to a single embodiment. Simple features of different embodiments may also be combined or interchanged to provide other embodiments.

Figure 1 shows elements of a front part of the passenger compartment of a motor vehicle. The passenger compartment has an interface 1 in particular adapted to be housed in the front panel of the vehicle.

Such an interface 1 allows the control of at least one function of a motor vehicle body such as the control of the functions of an air conditioning system, an audio system, a telephony system or a navigation system. This interface 1 can also be used for window lifts, exterior mirrors, motorized seats or to control interior lights, central locking, sunroof, hazard warning lights or emergency lights. atmosphere. The interface 1 allows, for example, the user scrolling through a list, selecting or validating a selection. For example, it allows the user to select a destination postal address or a name in a directory, the climate system settings or the selection of a music track in a list. The interface 1 comprises at least one control member 2 and a touch screen 30. The touch screen 30 comprises a capacitive touch screen 3 and a display screen 10.

FIG. 2 shows a partial view in more detailed section of the interface 1.

The capacitive touch screen 3 comprises at least one capacitive sensor 31 and a front plate 32 arranged on the capacitive sensor 31.

The capacitive sensor 31 makes it possible to detect a capacitance variation at the surface of the front plate 32. The capacitive sensor 31 can for example detect a contact or a movement of a user's finger. The capacitive sensor 31 also makes it possible to determine the spatial coordinates of the finger on the slab 3. The capacitive sensor 31 is for example formed of an array of electrodes extending over all or part of the surface of the slab. The electrodes are for example made of ITO (indium oxide - tin) which allow the sensor 31 to be transparent.

The rigidity of the capacitive touch screen 3 is obtained by means of the rigid front plate 32 (or contact plate), such as a glass plate. The front plate 32 arranged on the capacitive sensor 31 faces the user once mounted in the passenger compartment. The touch surface of the slab 3 is thus formed by the surface of the front plate 32. This surface may be flat or curved. The display screen 10, such as a TFT screen ("Thin-Film transistor" in English) or an LED screen or an LCD screen is configured to display information associated with the manipulation of the interface 1. The screen 10 is disposed under the capacitive sensor 31 so as to form a touch screen 30 ("touchscreen" in English). The capacitive sensor 31 and the front plate 32 are at least partially transparent. The interface 1 can also comprise at least one support sensor 11 configured to measure a parameter representative of a pressing force exerted on the capacitive touch screen 3. The interface 1 can thus also also measure a support force exerted on the capacitive touch screen 3 through a support exerted on the control member 2 fixed to the slab 3. The bearing sensors 11 able to measure a pressing force exerted on the capacitive touch screen 3 thus make it possible to measure also a pressing force exerted on the control member 2. A single device for measuring the bearing force is thus used to measure both when a pressure is exerted on the control member 2 or on the capacitive touch screen 3.

It is thus possible to execute a function, such as a selection enable by measuring a pressing force exerted on the capacitive touch screen 3 through the control member 2.

This support force information can also make it possible to better interpret the commands of the user having touched the capacitive touch screen 3 or the control member 2, for example by subjecting the execution of a command to the comparison of the bearing force measured at one or more thresholds.

This information may also make it possible to parameterize the haptic feedback generated on the touch screen 30, for example relative to the intensity of the measured force.

The support sensor 11 is for example disposed at the rear of the touch screen 30 (Figure 2). The interface 1 comprises for example four support sensors 11, a sensor 11 being arranged in each corner of the screen 30 (FIG. 3).

The measurement of the support force is for example obtained from a capacitive measurement of the small displacement of the screen 30 (non-perceptible) resulting from a support exerted on the slab 3. The capacitive measurement of the displacement can be carried out for example by means of an electrode attached to the rear of the touch screen 30 and facing a metallized fixed part or vice versa, the metallized portion being disposed at the rear of the touch screen 30 facing an electrode fixed measurement.

The measurement of the bearing force can also be carried out by inductive measurement or ultrasonic measurement or strain measurement by means of strain gauges or FSR sensors (for "Force Sensing Resistor").

A processing unit 20 can be connected to the support sensors 11 and to the capacitive sensor 31 (FIG. 3). The processing unit 20 comprises one or more microcontrollers or computers, having memories and programs adapted to modify the display of the display screen 10, to receive the position information detected by the capacitive touch panel 3 and to receive the measuring signals of the sensors 11. This is for example the on-board computer of the motor vehicle. The processing unit 20 can be configured to evaluate a bearing force from the bearing sensors 11, in particular by adding up the forces measured by each sensor 11. The interface 1 can also comprise at least one vibratory actuator 8 enabling vibrate the touch screen 30 in response to the detection of a contact or a support or a movement of a finger on the capacitive touch screen 3. The possibility of vibrating the screen 30 can allow here too to vibrate the control member 2 fixed on the slab 3.

An exemplary control member 2 is better visible in the schematic sectional view of FIG. 2 as well as in the schematic view of FIG. 4.

In FIG. 2, it can be seen that the control member 2 comprises a rotating wheel 4, at least one metal index 6 carried by the rotary wheel 4 and rotatable therewith, a guide 5 (or bearing), the rotating wheel 4 being supported and guided in rotation by the guide 5, a spacer 12 and at least a first conductor 13aa ... 13dc and a second conductor 13aa ... 13dc.

The guide 5 is fixed on the capacitive touch screen 3, for example by gluing.

The guide 5 is for example positioned on a substantially central line of the screen 30 (Figure 1), for example in the middle or at the edge thereof. The interface 1 may comprise several control members 2, two for example, one for the driver and the other for the passenger.

The rotary wheel 4 is rotatable about an axis of rotation A perpendicular to the surface of the capacitive touch screen 3.

The rotary wheel 4 and the guide 5 have respective cylindrical general shape coaxial rings-shaped with a central orifice 7 through. The spacer 12 is for example cylindrical. It is fixed on the capacitive touch screen 3, for example by gluing, in the central orifice 7. The end of the rotary wheel 4 facing the capacitive touch screen 3 carries at least one metal index 6 which is thus arranged in vis-à-vis the capacitive touch screen 3. This is for example a metal tongue, for example Copper. The metal index 6 is electrically connected to external metal surfaces 9 of the rotary wheel 4 to be manipulated by the user.

For this, the rotary wheel 4 is for example entirely made of metal material. In another example, the rotating wheel 4 comprises a coating arranged at the outer gripping surfaces, such as a chrome envelope connected to the metal index 6.

By touching the external metal surfaces 9 electrically connected to the metal index 6, the user brings electrical charges facing the capacitive touch screen 3 which are then detected by the capacitive sensor 31. The detection of these charges in the area of the control member 2 allows to deduce the contact of the control member 2 by the user. The determination of the coordinates of the metal index 6 by the capacitive touch screen 3 makes it possible to determine the angular position of the mobile metal index 6 above the capacitive touch screen 3.

Each conductor 13aa ... 13dc has at least a first end arranged at a rear face 12a of the spacer 12 facing the capacitive touch screen 3 and at least a second end arranged at a front face 12b the spacer 12 opposite the rear face 12a and intended to be touched by the user.

The first ends of each conductor are spaced from each other on the rear face 12a of the spacer 12. Also, the second ends of each conductor are spaced apart from each other on the front face 12b.

The first ends of the conductors 13aa ... 13dc may comprise conductive pads 14 extending in the plane of the rear face 12a of the spacer 12. The second ends of the conductors 13aa ... 13dc may comprise conductive pads 14 s extending in the plane of the front face 12b of the spacer 12. The conductive pads 14 have for example a respective shape of a ring or rectangle and may be hollow or solid. The size and shape of the conductive pads 14 may vary between the first ends of the conductors or between the second ends of the conductors or between the first and second ends of the same conductor. The conductive pads 14 make it possible to improve the detection sensitivity (finger side 16 and / or slab side 3) by widening the dimensions of the conductors at the ends arranged on the faces of the spacer 12.

The first and second ends of the conductors 13aa ... 13dc may be elements on the rear and front faces 12a, 12b of the spacer 12. Thus, for example, the ends of the conductors 13aa ... 13dc may be conductive pads 14 etched on the faces 12a, 12b spacers 12 or printed on a film itself disposed on the faces of the spacer 12. The first ends are connected to the second ends by connectors bypassing the spacer 12, comprising by example circuit tracks etched on the faces of the spacer 12 or fixed on the film bearing conductive pads 14 and by son, which can be grouped into a sheet 18, connecting the circuits together (Figure 2).

According to another example shown in FIG. 5, the conductors 13aa ... 13dc cross the spacer 12, the first end of each conductor 13aa ... 13dc opening from the rear face 12a of the spacer 12 and the second end opening of the front face 12b. The connectors connecting the first and second ends of the conductors are for example rigid rods.

The first and second ends of the same conductor 13aa ... 13dc can be arranged one above the other on the spacer 12, which simplifies the computer processing. Indeed, in this case, the coordinates of the finger 16 on the front face 12b are the same as the coordinates of the charges detected by the capacitive touch screen 3. Other configurations may however be envisaged. For example, the spacer 12 may have a front face 12b of a different dimension than the rear face 12a, for example of greater dimension. The second ends on the front face 12b can then be spaced apart from each other than the first ends on the rear face 12a. According to another example, several first ends of the front face 12b of a conductor may be connected to a single second end of the rear face 12a, for economic reasons for example or for more precision or for not having dead zone, without detection, at the front face 12b.

The conductors 13aa ... 13dc can be made in whole or in part of indium oxide - tin (ITO), such as ITO ink, which allows them to be transparent.

In the case of the ends reported on the rear and front faces 12a, 12b of the spacer 12, the ends of the conductors and the circuits can be deposited in ITO ink. In the case of conductors passing through the spacer 12, the ends and the rigid rods may be made of ITO material. The spacer 12 may be made of transparent material, such as plastic. The images displayed by the screen 10 can then be seen by the user. The display can be programmed so that the displayed images correspond to information related to the manipulation of the control member 2.

The front face 12b of the spacer 12 may also be opaque except at the display areas. These display areas let the light from the screen 10 through the spacer 12. The display areas may define one or more patterns or symbols to be backlit, such as a four-way arrow or four unidirectional arrows 15a 15b, 15c, 15d; 15 indicating four orientations spaced from each other by 90 ° (Figures 6a and 6b).

In another example, the symbols are displayed on the screen 10 around the controller 2 instead of being backlit.

In the case of an opaque or partially opaque spacer 12 in particular, the conductors 13aa ... 13dc may be of opaque metallic material, such as for example Copper. The interface 1 is further configured to differentiate between at least one contact of the user's finger with a first conductor at the front face 12b of the spacer 12, with a contact at a second conductor, for the determination of a command to implement. For example, the interface 1 is configured to differentiate a contact in at least four distinct sectors of the circular front face 12b of the spacer 12 (FIG. 6a).

Thus, according to an example of use, when the user touches the front face 12b of the spacer 12, for example at the level of the symbol 15b (FIG. 6a), electrical charges are made at the second ends of the conductors arranged under the symbol 15b, i.e. the conductors 13bc, 13cb, 13cc and 13dc in the example (step 101 of interfacing process 100, Figs 4 and 7).

The charges are transported by these conductors opposite the capacitive touch panel 3. These charges are detected by the capacitive sensor 31 at the first ends of the conductors 13bc, 13cb, 13cc and 13dc. The interface 1 differentiates at least one contact detected at a first conductor, a contact detected at a second conductor, which allows to deduce the contact of the control member 2 by the user at symbol 15b (step 102 of interfacing method 100). The interface 1 can then determine the command to implement (step 103), in this case in the example, a command associated with a right-pointing arrow.

Additional interactions with the rotary manipulation of the wheel 4, are then possible for the user such as for example the input of a command of the type "right or left", "front or back", "up or down", by simple contact or support on the front face 12b of the spacer 12.

It is also possible to measure a pressing force exerted on the capacitive touch screen 3 through the control member 2 by means of the support sensors 11, associated with a detected contact at a conductor, for parameterizing a parameter a command associated with said driver.

The associated parameter can be a scrolling speed. The scrolling speed, for example elements to select or changing the value of a parameter, can be determined relative to the bearing force exerted on the driver.

For example, the more the user presses hard on a conductor located on the right side and the speed of scrolling parameters in one direction, to the right for example, increases rapidly, the speed decreasing with the pressure drop exerted by the user. The more the user presses hard on a driver on the left side, the faster the speed of the parameters increases.

The measurement of the support force can thus be used to parameterize a speed of execution of a command in one direction.

The number of conductors 13aa ... 13dc of the control member 2 depends in particular on their dimensions, the size of the spacer 12, the desired sensitivity and the sensitivity of the capacitive touch screen 3. The number of conductors 13aa ... 13dc is for example between two and thirty, like twelve in the example shown in Figure 4. The control member 2 comprises for example a maximum of four second ends of conductors per cm2 distributed at the face 12. The interface 1 may be configured to recognize a sliding finger on the front face 12b of the spacer 12 by successive detections of a contact on at least two conductors within a predetermined time.

It can further be provided that at least three conductors, such as the three conductors 13ba, 13bb, 13bc, have first ends aligned in a first direction X on the rear face 12a and / or have second ends aligned in the same direction X on the front face 12b.

Thus according to an example of operation, when the user slides his finger 16 from left to right on the front face 12b, he successively passes his finger on the second ends of three conductors 13ba, 13bb, 13bc substantially aligned (see arrow F in Figure 4). The slab 3 perceives that the loads brought by the user move from driver to driver and deduces a sliding of the finger 16 of the user. The detection of this sliding of finger can allow the control of a particular function, such as the scrolling of parameters to be selected in a list.

According to an exemplary embodiment, at least three conductors, such as the four conductors 13aa, 13ba, 13bc, 13dc shown in FIG. 4 for example, have first ends aligned in a second direction Y on the rear face 12a and / or second ends aligned in the same second direction Y on the front face 12b, the second direction Y being perpendicular to the first direction X. The interface 1 can thus distinguish a sliding of the horizontal finger of a sliding of the vertical finger.

According to an exemplary embodiment, at least four conductors, such as the twelve conductors 13aa ... 13dc of FIG. 4 for example, have first ends that are arranged in a mesh with a mesh of constant dimension on the rear face 12a and / or second ends which are arranged in a mesh with mesh of constant size on the front face 12b. The mesh is polygonal, such as triangular or square.

In another example, the first and / or second ends are arranged on a mesh of concentric circles.

By meshing the conductor spacer 12, the detection is improved, which can enable the interface 1 to detect a direction and / or a speed of the finger slip and / or that two simultaneous finger slides are approaching or move away from each other or recognize that the sliding of a finger is a letter, a number or a symbol.

Thus, the interface 1 can be configured for the recognition of writing, in particular to recognize at least one symbol, a letter or a number, from the forms traced by a continuous finger slip.

The direction and speed of the slip can be used to set the direction and speed of scrolling. For example, sliding finger movements toward or away from each other may indicate the user's desire to zoom in on the screen 10.

The validation of a selection made by contact, support or sliding of the finger on one or more conductors among all the conductors, can be achieved by different means.

The validation can for example be carried out by detecting the pressing force exerted on the spacer 12, by means of the force sensors 11 as described above.

The validation can be performed by contact or support of the front face 12b of the spacer 12 at a central zone 17 (Figure 6c), the interface 1 is then configured to control a validation when the capacitive touch screen 3 detects charges at the first ends of the conductors 13cb and 13bb in the example. The interface 1 can also be configured to allow a cancellation of control so as to cancel the last action ordered (selection or validation) when the user presses or touches a predetermined area of return back on the capacitive touch screen 3. The predetermined return zone may be located at the central zone 17 of the spacer 12 (Figure 6c).

It is thus understood that additional interactions with the rotary manipulation of the wheel 4 are possible for the user such as for example the input of a "right or left" type control, "front or rear", "up or down" , by simple contact or support on the front face 12b of the spacer 12 or as the input of a command by sliding the finger of the user on the control member. In addition, the increase in the number of conductors may allow for the determination of further parameters of finger slip, such as the speed, the reconciliation or mutual distance of two simultaneous finger slips and the write recognition. The range of possible interactions can thus be greatly increased.

Claims (19)

Interface (1) for controlling at least one function of a motor vehicle body, comprising: at least one control member (2) comprising: a rotary wheel (4), at least one metal index ( 6) carried by the rotary wheel (4) and movable with it, a guide (5), the rotary wheel (4) being supported and guided in rotation by the guide (5), a touch screen (30) configured to detecting the position of the metal index (6), the guide (5) being fixed on the touch screen (30), the metal index (6) being arranged facing the touch screen (30), characterized in that: - the guide (5) and the rotary wheel (4) have respective shapes of rings with a central orifice (7), - the control member (2) further comprising: o a spacer (12) fixed on the touch screen (30) in the central orifice (7), and o at least a first conductor and a second conductor (13aa ... 13dc), each conductor (13aa ... 13dc) pr sensing at least a first end arranged at a rear face (12a) of the spacer (12) facing the touch screen (30) and at least a second end arranged at a front face (12b) ) of the spacer (12) opposite to the rear face (12a) and intended to be touched by the user, the first ends being spaced apart from one another on the rear face (12a) and the second ends being spaced apart from each other on the front face (12b). 2. Interface (1) according to the preceding claim, characterized in that it comprises at least three conductors (13aa ... 13dc) whose first ends and / or the second ends are aligned in the same first direction (X). 3. Interface (1) according to the preceding claim, characterized in that it comprises at least three conductors (13aa ... 13dc) whose first ends and / or the second ends are aligned in the same second direction (Y) perpendicular in the first direction (X). 4. Interface (1) according to one of the preceding claims, characterized in that it comprises at least four conductors (13aa ... 13dc) whose first ends and / or the second ends are arranged in a mesh of meshes. constant dimensions. 5. Interface (1) according to one of the preceding claims, characterized in that the first and second ends of the same conductor (13aa ... 13dc) are arranged one above the other. 6. Interface (1) according to one of the preceding claims, characterized in that the conductors (13aa ... 13dc) are wholly or partly made of indium-tin oxide. 7. Interface (1) according to one of the preceding claims, characterized in that the front face (12b) of the spacer (12) is opaque except at the level of display areas defining at least two symbols (15; 15a). , 15b, 15c, 15d), such as arrows. 8. Interface (1) according to the preceding claim, characterized in that the conductors (13aa ... 13dc) are opaque metal material, such as copper. 9. Interface (1) according to one of the preceding claims, characterized in that the first and / or second ends of the conductors (13aa ... 13dc) comprise conductive pads (14) extending in the plane of the face front (12b) or rear (12a) of the spacer (12). 10. Interface (1) according to one of the preceding claims, characterized in that the first and second ends of the conductors (13aa ... 13dc) are attached to the spacer (12), the first ends being connected to the second ends by connections bypassing the spacer (12). 11. Interface (1) according to one of claims 1 to 9, characterized in that the conductors (13aa ... 13dc) through the spacer (12), the first end of each conductor (13aa ... 13dc) opening from the rear face (12a) of the spacer (12), the second end emerging from the end face (12b). 12. Interface (1) according to one of the preceding claims, characterized in that it comprises at least one support sensor (11) configured to measure a parameter representative of a pressing force exerted on the capacitive touch screen (3) in particular through the control member (2). Interface method (100) for handling an interface (1) according to one of the preceding claims, wherein the interface (1) differentiates at least one detected contact at a first conductor, d. a contact detected at a second conductor (102), for the determination of a command to implement (103). 14. Interfacing method (100) according to the preceding claim, wherein the interface (1) differentiates a contact in at least four distinct sectors of the front face (12b) of the spacer (12). 15. Interfacing method (100) according to one of claims 13 or 14, wherein the interface (1) recognizes a sliding finger on the front face (12b) of the spacer (12) by successive detections d contact on at least two conductors within a predetermined time. 16. Interfacing method (100) according to the preceding claim, wherein the interface (1) detects a direction and / or a speed of the sliding of finger and / or two simultaneous finger slides approach or move away l from each other and / or recognizes that finger slip marks at least one number, symbol or letter. 17. Interfacing method (100) according to one of claims 13 to 16, wherein a pressing force exerted on the capacitive touch screen (3) through the control member (2) to validate a selection. 18. Interfacing method (100) according to one of claims 13 to 17, wherein a bearing force exerted on the capacitive touch screen (3) through the spacer (12) of the body command (2) associated with the contact detected at a driver to set a parameter of a command associated with said driver. 19. Interfacing method (100) according to the preceding claim, wherein the associated parameter is a scrolling speed.