Optical system support for a vehicle light sketch projection device.

The compact lighting device design with a micromirror array and optical projection system effectively addresses the challenge of integrating vehicle light projection devices by minimizing space and preventing optical interference, enabling efficient light projection.

FR3170403A1Pending Publication Date: 2026-06-26VALEO VISION SA

Patent Information

Authority / Receiving Office
FR · FR
Patent Type
Applications
Current Assignee / Owner
VALEO VISION SA
Filing Date
2024-12-20
Publication Date
2026-06-26

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Abstract

The invention relates to a vehicle lighting device (100a) configured to project a luminous representation onto a surface within the vehicle's environment. Specifically, the lighting device comprises an illumination assembly (97), a micromirror array device (98), and an optical projection system (99) that cooperate to generate the luminous representation. The optical projection system (99) includes a housing (10) comprising an upstream section (10a) with a base lens (99a) and a downstream section (10b) configured to receive a series of lenses (99b) of increasing diameters arranged along the projection axis (Ap). The upstream section (10a) includes an entry notch (10e) and an exit notch (10s) to allow the propagation of light beams along an incident axis (Ai) to the base lens (99a) and the passage of light beams outside the optical path along an exit axis (As).Figure for the abbreviation: Figure 1.
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Description

Title of the invention: Optical system support for a light sketch projection device for a vehicle. technical field

[0001] The present invention relates to a vehicle lighting device, more particularly a vehicle light projection device. Technological background

[0002] The lighting devices of motor vehicles today fulfill several functions such as illuminating and / or defining a vehicle's light signature. Among these lighting devices, some are used to project light representations around the vehicle carrying them.

[0003] Thus, there are devices installed in vehicles that allow the projection of a logo, personalized welcome messages, or designs, for example, associated with a vehicle door and projecting a logo onto the ground in front of that door when the vehicle is unlocked and / or when the door is opened. Such devices are, for example, installed in the door, in a rearview mirror associated with the door, or even in a rocker panel near the door.

[0004] These light projection devices, hereinafter referred to as lighting devices, add a touch of personalization and style to the vehicle, while also providing a practical function for illuminating the ground around the vehicle in the dark. Such lighting devices are integrated, for example, into the exterior silhouette of a vehicle. These lighting devices generally comprise numerous components, including a light source, an electronic circuit board, optical elements capable of guiding light beams, and decorative elements.

[0005] These lighting devices must meet several requirements, including robustness, compactness, lightness, aesthetics, cost-effectiveness, and maintainability. Compactness, for example, allows this type of device to be integrated into numerous locations on the vehicle, both inside and outside the passenger compartment. Miniaturization of such devices is a key factor in making them more widely available and offering users a wide range of applications.

[0006] Thus, in order to make these devices more compact and lightweight, it is necessary to group the various components of these lighting devices in confined spaces. However, bringing the different components closer together generates constraints, for example optical constraints, as some components may then be too close or even interfere with light beams emitted and / or reflected by other components. Summary of the present invention

[0007] The present invention overcomes the technological background problems described above by designing a compact lighting device that can then be easily integrated into a small volume available in a vehicle, for example of the automobile type.

[0008] To this end, the invention relates firstly to a lighting device for a vehicle, the device being configured to project a luminous representation onto a surface of the vehicle's environment, the lighting device comprising: - an illumination assembly including a light source configured to generate a set of light beams, the set of light beams propagating along an incident axis, - a micromirror array device configured to reflect, at a first angle of reflection, a first subset of light beams from the set of light beams and, at a second angle of reflection, a second subset of light beams from the set of light beams, and - an optical projection system comprising a set of lenses, the optical projection system being configured to guide the first subset of light beams and generate the light representation on the surface along a projection axis, characterized in that the optical projection system comprises a housing in which the set of lenses forming an optical path is arranged, the housing comprising an upstream section and a downstream section juxtaposed to each other, the downstream section being configured to receive a succession of lenses from the lens set of increasing diameters arranged along the same first optical axis constituting the projection axis, the lens of smallest diameter being positioned on the side of the upstream section, the upstream section comprising at its end opposite the downstream section a base lens of the lens set,the end being configured so that the base lens has a second optical axis forming an angle of inclination with the first optical axis, the upstream section includes an inlet notch and an outlet notch, the inlet notch being configured to allow the propagation of the entire light beam along the incident axis to the base lens, the outlet notch being configured to allow the passage of the second subset of light beams outside the optical path along an outlet axis, and the optical path being configured to propagate the first subset of light beams through the lens assembly.

[0009] Such a lighting device allows the various components of the lighting system to be brought closer together so as to occupy a limited volume. The notches in the support allow the illumination assembly and the device to be brought closer together. A micromirror matrix allows light beams to pass directly through the support, preventing any optical interference between the different components of the lighting device while ensuring its proper functioning. The support itself allows for the arrangement of lenses to achieve the desired optical effect.

[0010] According to an advantageous embodiment, the projection axis, the incident axis and the second optical axis are contained in the same plane.

[0011] According to an advantageous embodiment, the angle of inclination between the projection axis and the second optical axis is between 2° and 6°, preferably on the order of 4°.

[0012] According to an advantageous embodiment, the incident axis forms an angle of approximately 4° to 8°, preferably 6°, with the second optical axis.

[0013] According to an advantageous embodiment, the housing comprises cylindrical bores, each cylindrical bore being configured to receive a lens from the lens assembly and arranged along an optical axis associated with said lens.

[0014] According to an advantageous embodiment, the sequence of lenses comprises four lenses.

[0015] According to an advantageous embodiment, the housing is made in one piece from a material such as aluminium, aluminium alloy or plastic.

[0016] According to an advantageous embodiment, the housing is configured to receive and position the illumination assembly and the micromirror matrix device relative to the lens assembly of the projection optical system.

[0017] The invention also relates to a vehicle equipped with a lighting device having at least one of the above characteristics, the lighting device being configured to project a luminous representation onto a surface of the vehicle's environment.

[0018] According to an advantageous embodiment, the vehicle includes a lower body, the lighting device being arranged in the lower body and configured to project a luminous representation onto a ground surface outside the vehicle.

[0019] According to an advantageous embodiment, the lighting device is configured to project onto the ground surface a luminous representation with a length of approximately 2800mm and a width of approximately 660mm.

[0020] Thus, thanks to all the functional and structural technical features of the present invention, a particularly compact and functional lighting device is available. Its integration into a vehicle is therefore facilitated, allowing in particular for its judicious placement to obtain the desired lighting display. Brief description of the figures

[0021] The features and advantages of the present invention will become apparent from the description below, which is supported by figures, among which: - Fig. 1 represents a perspective view of a lighting device according to the present invention, according to a first particular embodiment; - [Fig.2] represents a vehicle incorporating the lighting device of [Fig.1], according to a particular embodiment; - [Fig.3] represents a perspective view of a lighting device according to the present invention, according to a second particular embodiment; and - [Fig.4] represents a cross-sectional view of the lighting device of [Fig.3], according to a second particular embodiment. Description of examples of achievements

[0022] Examples of a lighting device will now be described with reference to Figures 1 to 4. According to these examples, the lighting device is designed to project a luminous representation onto a surface in the vehicle's environment, the vehicle being, for example, a car. The luminous representation allows, for example, a vehicle user to be accommodated. Such a lighting device is intended to be mounted, for example, in a vehicle's underbody to project the luminous representation onto the ground, or in a dashboard to project a luminous representation onto the windshield or headliner. The invention is not limited, however, to this particular embodiment and extends to any lighting device that allows a luminous representation to be projected onto a surface in the vehicle's environment or even onto the vehicle itself, for example, from a door or a rearview mirror.

[0023] Indeed, the lighting device comprises an illumination assembly including a light source, a micromirror array device, and an optical projection system that cooperate to generate the light image. The optical projection system includes a housing comprising an upstream section with a base lens and a downstream section configured to receive a succession of lenses of increasing diameters arranged along the projection axis. The upstream section includes an inlet notch and an outlet notch to allow the propagation of light beams along an incident axis to the base lens and the passage of light beams outside the optical path along an outlet axis.

[0024] Figure 1 shows a perspective view of a lighting device 100a according to the present invention, based on a first particular embodiment. The lighting device 100a comprises an illumination assembly 97 including a light source 97a generating a set of light beams, the set of light beams propagating from the output of the illumination assembly 97 according to an incident axis A; The light source 97a is, for example, monochrome and allows for a monochrome graphic representation. According to a variant, the light source 97a is polychrome and thus allows for the projection of a colored light representation.

[0025] The light source 97a is, for example, associated with an electronic board or printed circuit board (PCB) on which is arranged an array of at least one light-emitting diode, known as an LED (Light-Emitting Diode). Each array of at least one LED is configured so that the emitted light, i.e., the light beams from the array of light beams, is directed towards a micromirror array device 98, known as a DMD (Digital Micromirror Device) and also as a DLP chip (Digital Light Processing). According to other embodiments, the light source 97a includes a light emitter such as a bulb or a laser.

[0026] The DMD 98 is an optoelectronic component used primarily in video projectors, printers, and other optical image processing applications. The DMD 98 comprises thousands or even millions of individual micromirrors, each electronically controlled. These micromirrors are arranged in an array on the chip surface, each micromirror representing a pixel of an image projected by reflecting light beams onto these micromirrors. Each micromirror is capable of switching between two positions: a first position that reflects a light beam from the set of light beams at a first angle of reflection, and a second position that reflects the same light beam at a second angle of reflection different from the first.The light beams from the set of light beams reflected at the first angle of reflection form a first subset of light beams, while the light beams from the set of light beams reflected at the second angle of reflection form a second subset of light beams.

[0027] The optical projection system 99 comprises a set of lenses forming an optical path and is configured to guide the first subset of light beams through each of the lenses it comprises and generate the light representation on the surface, also called the projection surface, along a projection axis Ap, the projection surface then acting as a screen. Each light beam from the first subset of light beams creates a point of light on the projection surface, i.e., an "illuminated" pixel, while when a micromirror is tilted into the second position, the light beam from the second subset of light beams is reflected in another direction. and gets lost, thus "extinguishing" a corresponding point of light on the projection surface.

[0028] Thus, the DMD 98 is configured to reflect light beams from the set of light beams. Each micromirror is, for example, individually controlled by electronic signals. These signals are generally generated by a specialized processor that handles the video data to be displayed; such a processor is, for example, a computer embedded in the vehicle. Depending on the image and / or video to be projected, the micromirrors are tilted appropriately to reflect the light at a first or second angle of reflection and form illuminated or unlit pixels on the screen.

[0029] Typically, the illumination assembly is positioned at a distance from the lens assembly of the projection optical system and from the projection axis so as to emit the light beams along an incident axis whose direction is close to the normal to the projection axis. This allows the DMD to be placed at the intersection of the incident axis and the projection axis and tilted to obtain a first angle of reflection close to 45° (forty-five degrees).Thus, it is easy to reflect a beam of light towards the lens assembly of the projection optical system arranged along the projection axis or, conversely, away from the lens assembly of the projection optical system along an output axis. A micromirror with an angle of inclination, for example, between -12° and +12°, allows for a second angle of reflection close to 20° or 70° to direct the light beams away from the lens assembly of the projection optical system, the light beams being reflected at this second angle of reflection. When the lighting device 100a is not constrained by volume or space, the projection optical system 99 can, in particular, be placed at a sufficient distance from the light beams reflected at the second angle of reflection so as not to receive them and thus avoid any light pollution of the graphic representation.However, in this invention, the lighting device 100a must be compact. Thus, the light source 97 is placed as close as possible to the optical projection system 99, that is to say, near the projection axis Ap, the incident axis A;, the second optical axis Ao and the projection axis Ap are thus particularly close together and, according to the particular embodiment illustrated, the angle of inclination between the projection axis Ap and the second optical axis Ao is between 2° and 6°, preferably on the order of 4°, while the incident axis A; forms with the second optical axis Ao an angle of the order of 4° to 8°, preferably 6°. It should be noted that, in this particular embodiment, the incident axis A;, the second optical axis Ao and the projection axis Ap are contained in the same plane.

[0030] Still with the aim of minimizing the size of the light device 100a, the DMD 98 is attached to the base lens 99a, on the opposite side of the optical projection system 99.

[0031] Thus, a light beam emitted by the light source 97a and propagating along the incident axis A; at the output of the illumination assembly passes through the base lens 99a to reach a reflective surface of a micromirror of the DMD 98. Depending on the orientation of the micromirror, the light beam is either reflected according to the first angle of reflection, or reflected according to the second angle of reflection. • In the case where the light beam is reflected at the first angle of reflection, the reflected light beam then passes through the base lens 99a in the opposite direction to that of the first passage, exits the base lens 99a along the second optical axis Ao, and encounters in turn each lens of the series of lenses 99b while propagating along the projection axis Ap. After passing the last lens of the series of lenses 99b, the light beam leaves the light device 100a and heads towards the projection surface to form a light pixel of the light representation.• In the case where the light beam is reflected according to the second angle of reflection, the reflected light beam then passes through the base lens 99a in the opposite direction to that of the first passage and exits the base lens 99a along the exit axis As to leave the light device 100a and disappear, the pixel of the light representation associated with the micromirror inclined in the second position is then dark because it is not illuminated by the disappeared light beam.

[0032] The lens assembly of the projection optical system 99 is held by a housing 10. The housing 10 comprises an upstream section 10a and a downstream section 10b placed side by side, the downstream section 10b being configured to receive a series of lenses 99b from the lens assembly and the upstream section 10a being configured to receive at its end opposite the downstream section 10b a basic lens 99a from the lens assembly. The lenses of the lens assembly 99b, i.e., the lenses placed in the downstream section 10b, have increasing diameters and are arranged along the same first optical axis constituting the projection axis Ap, the lens with the smallest diameter being positioned on the side of the upstream section 10a. Note that the diameters of the lenses are, according to a first particular embodiment, strictly increasing and are, according to the example illustrated in [Fig. 4] for example, not strictly increasing. Indeed, in [Fig.4], the two lenses 99b located in the middle of the downstream section 10b are of substantially equivalent diameter. The end of the upstream section 10a is configured so that the basic lens 99a. presents an optical axis corresponding to the second optical axis Ao, the second optical axis Ao being inclined with respect to the projection axis Ap.

[0033] According to the particular embodiment illustrated, the housing 10 comprises cylindrical sections, each cylindrical section including a cylindrical bore configured to receive a lens 99a, 99b of the lens assembly and arranged along an optical axis associated with the lens 99a, 99b. Thus, the housing 10 allows for the precise positioning of each lens of the lens assembly and holds them in place to ensure the correct assembly of the projection optical system 99. According to one variant, the cylindrical bores allow for clamping of the lenses, the inner diameter of the cylindrical bores being slightly less than or equal to an outer diameter of a lens.According to another embodiment, the inner walls of the cylindrical bores include fine ribs that compress when a lens is inserted, thus holding it in position. The rib allows the lens to be press-fitted into the housing 10 without risk of damaging the lens. The illustrated example has four cylindrical sections in the downstream segment 10b; the lens sequence 99b then comprises four lenses. This number of lenses is defined by the focal lengths of these lenses and by the expected performance of the optical system, in particular the distance between the light source 100a and the projection surface. According to other embodiments, the lens sequence comprises at least two lenses.

[0034] Between each cylindrical section, the housing 10 includes, for example, frustoconical sections connecting each cylindrical section. Such frustoconical sections allow the light beams to travel freely along the optical path without encountering any obstacles. Furthermore, the frustoconical shape facilitates the assembly of the lenses, which are guided as they pass through each section during assembly. Indeed, by first assembling the lens with the smallest diameter in the sequence of lenses in the downstream section 10b, this lens easily passes through each cylindrical section whose radius is greater than that of this lens, the diameters of the lenses decreasing as they travel along the downstream section from the entrance to the housing 10 opposite the upstream section 10a. Similarly, each frustoconical section has a decreasing cross-section that guides the lens to its final position.The invention is not limited, however, to cylindrical sections separated by frustoconical sections; any other shape allowing the free passage of light beams is possible. The advantage of this particular embodiment is that it offers a technical solution allowing the housing 10 to have a relatively constant cross-section, thus optimizing the ratio between its mechanical strength and its mass. Such a housing 10 is, for example, made by injection molding of a thermoplastic such as acrylonitrile butadiene styrene (ABS) or polycarbonate (PC). According to another example, the housing 10 is made in a single piece from a material of the type... aluminium or aluminium alloy, by casting or molding and then further machining on a lathe for example.

[0035] The illumination assembly 97 being juxtaposed to the housing 10 and the DMD 98 positioned behind the base lens 99a, it is necessary to allow the incident and outgoing light beams to pass, that is to say those emitted by the light source 97a of the illumination assembly 97 towards the base lens 99a along the incident axis A; and those exiting the base lens 99a and propagating along the exit axis As.Thus, the upstream section 10a comprises an inlet notch 10e and an outlet notch 10s, the inlet notch 10e being configured to allow the propagation of the entire light beam along the incident axis A, up to the base lens 99a, the outlet notch 10s being configured to allow the passage of the second subset of light beams, exiting the base lens 99a, outside the optical path along an outlet axis As, the optical path being configured to propagate the first subset of light beams through the lens assembly and not the second subset of light beams. When the different axes are contained in the same plane, the notches are, for example, arranged diametrically opposite, their respective contours being symmetrical with respect to the plane containing the incident axis A and the outlet axis As. In the particular embodiment illustrated in [Fig.[l], the notches thus correspond to two trapezoidal cutouts facing each other.

[0036] Such a luminous device 100a is, for example, placed in an external housing, the external housing positioning and holding each of the components relative to each other. Thus, the illumination assembly 97 is oriented towards the DMD 98, i.e., the incident axis A; is oriented towards the center of the DMD 98, and the projection optical system 99 is positioned so as to guide light beams reflected by the DMD 98 towards the projection surface in the form of a light projection.

[0037] Such an external housing then encloses the illumination assembly 97, the DMD 98, and the projection optical system 99. The external housing includes, for example, an opening configured to allow the passage of light beams guided by the optical system along the optical path. The external housing includes, for example, two parts such as shells assembled in such a way as to make the external housing watertight in order to protect the components it contains from external aggressions. The shells are, for example, assembled using screws, and a gasket is installed in a groove so as to be compressed between the two assembled shells. The external housing further includes, for example, a transparent glazed part closing the opening and making the housing watertight and dustproof while allowing light to pass through. The light beams exit the optical system 99. The external housing thus protects the various components from oxidation and / or dirt, which is particularly useful if the lighting device 100a is positioned on an external part of the vehicle, such as a rocker panel. The external housing includes, for example, an opening for installing an electrical connector for powering and controlling the light source 97a of the lighting assembly 97 via the electronic board, if applicable, and the DMD 98. The connector is, for example, watertight when it receives an additional connector, and a seal is implemented between the connector and the opening. Alternatively, the external housing includes, for example, an opening for a cable, such an opening including, for example, a cable gland to ensure the watertightness of the external housing.The invention is not limited, however, to a luminous device 100a enclosed in an external casing; indeed, another open support is sufficient when the luminous device 100a is installed in a vehicle passenger compartment or when the luminous device 100a is installed in a confined environment.

[0038] Figures 3 and 4 show a perspective view and a cross-sectional view of a lighting device 100a according to the present invention, according to a second particular embodiment. According to this embodiment, the housing 10 and the external housing shown previously form a single unit. The housing 10 is configured to receive and position the lens assembly of the projection optical system 99 via cylindrical bores machined therein, and also to receive and position the illumination assembly 97 and the DMD 98 relative to the lens assembly. The housing 10 thus includes a first interface area for positioning the light source 97a and the associated electronic board 97c.According to this particular embodiment, the housing 10 also receives and positions another set of lenses, comprising, in this example, two lenses 971, 972 in front of the light source 97a along the incident axis A; for example, by having bores of different inner diameters allowing the insertion of a first lens 971 and a second lens 972 until they each reach their stop. The housing 10 also includes a second interface zone for positioning the DMD 98. The first and second interface zones optionally include means for attaching the illumination assembly 97, for example, its electronic board 97c and / or the lenses 971, 972 of the other lens set, and / or the DMD 98, for example, clips for holding these elements on the housing 10 or barrels for tightening these elements on the housing 10 by means of fixing screws.

[0039] Such a construction makes it possible to improve the relative positioning of all the components of the luminous device 100a, the lens assembly, the assembly Illumination 97 and DMD 98 being positioned only in relation to the housing 10 also positioning the lens assembly of the projection optical system 99, thus reducing the length of the dimension chains defining the manufacturing tolerances of each of the elements of the lighting device 100a.

[0040] According to this second particular embodiment, the housing 10 is obtained by: - ​​molding aluminum or aluminum alloy, or - plastic molding, for example polycarbonate (PC), acrylonitrile butadiene styrene (ABS) or polyoxymethylene (POM), these materials can also be machined, particularly in the areas receiving the lenses of the lens assembly, as well as in the first and second interface areas.

[0041] According to another particular embodiment (not illustrated), the lighting device 100a further comprises a casing encompassing the projection system 99, the illumination assembly 97, and the DMD 98. This watertight casing isolates these elements from the external environment and provides an adequate protection rating depending on the intended use of the lighting device 100a. This casing includes, in particular, an opening centered on the projection axis Ap to allow the passage of the first subset of light beams. This opening receives, for example, a window with a shape complementary to that of the opening, for example, a round window, and a sealing gasket is then arranged between the walls of the opening and the window to maintain the previously defined protection rating.

[0042] Incidentally and as illustrated in [Fig.4], the light device 100a includes a radiator 97r juxtaposed to the electronic board 97c, thus allowing the electronic board 97c and the light source 97a to be cooled, thereby ensuring good operating conditions for these elements and thus an optimal lifespan.

[0043] [Fig.2] illustrates a vehicle 100 carrying a light device 100a as shown above, for example according to the particular embodiment illustrated in [Fig. 1], the light device 100a being configured to project a light representation 100b onto a surface of the vehicle's environment.

[0044] According to the embodiment illustrated in [Fig. 2], the vehicle includes a lower body panel 100c in which the lighting device 100a is arranged. The lighting device 100a is configured to project the light representation 100b onto a ground surface outside the vehicle, for example, in front of a door of the vehicle 100. Thus, a user of the vehicle 100 benefits from an illuminated area in front of the door, the light projection 100b forming a luminous carpet. This light representation allows the user to better perceive any obstacles located in front of the door of the vehicle 100. The light representation also allows a welcome or greeting message to be displayed to this user.

[0045] The light device 100a is, for example, positioned at a distance H from the ground. This distance H, corresponding, for example, to the height of an opening in the light device 100a through which the first set of light beams exits after traveling the optical path relative to the ground in the case of a flat surface, is, for example, between 150 mm and 300 mm. Placed at a distance H from the projection surface, here the ground, the light device 100a is, for example, configured to project onto the ground surface a luminous representation 100b with a length of approximately 2800 mm and a width of approximately 660 mm.

[0046] Thus, the lighting device comprises a housing that groups all the components, such as the illumination assembly, the DMD, and the lens assembly of the projection optical system, into a very small space. The housing allows for the precise and reliable positioning of the various lenses of the projection optical system and enables light beams emitted by the light source or reflected by the DMD to propagate freely, thereby generating the expected light representation. This arrangement of the various components of the lighting device makes it compact and therefore easily integrated into confined spaces. The present invention thus provides a technical solution that is easy to integrate into new vehicles.

[0047] It should be noted that this detailed description relates to a particular embodiment of the present invention, but in no way does this description limit the scope of the invention; on the contrary, its purpose is to remove any possible inaccuracy or misinterpretation of the following claims.

[0048] It should also be noted that the reference signs in parentheses in the following claims are in no way intended to be limiting; these signs are solely intended to improve the intelligibility and understanding of the following claims and the scope of the protection sought.

Claims

1. Demands A lighting device (100a) of a vehicle (100), the device being configured to project a luminous representation (100b) onto a surface of an environment of the vehicle (100), said lighting device comprising: - an illumination assembly (97) comprising a light source (97a) configured to generate a set of light beams, the set of light beams propagating along an incident axis (AO, - a micromirror array device (MDD) (98) configured to reflect, at a first angle of reflection, a first subset of light beams from the set of light beams and, at a second angle of reflection, a second subset of light beams from the set of light beams, and - an optical projection system (99) comprising a set of lenses, said optical system being configured to guide the first subset of light beams and generate the light representation (100b) on said surface along a projection axis (Ap), characterized in that the optical projection system (99) comprises a housing (10) in which the set of lenses forming an optical path is arranged, said housing (10) comprising an upstream section (10a) and a downstream section (10b) juxtaposed to each other, the downstream section (10b) being configured to receive a succession of lenses (99b) from the set of lenses of increasing diameters arranged along the same first optical axis constituting the projection axis (Ap), the lens of smallest diameter being positioned on the side of the upstream section, the upstream section comprising at its end opposite the downstream section a base lens (99a) from the set of lenses,said end being configured so that the base lens (99a) has a second optical axis (Ao) forming an angle of inclination with the first optical axis, the upstream section (10a) includes an entrance notch (10e) and an exit notch (10s), the entrance notch (10e) being configured to allow the propagation of the entire light beam along the incident axis (Ai), up to the base lens (99a), the exit notch (10s) being configured to allow the passage of the second sub-, set of light beams outside the optical path along an output axis (As) and the optical path being configured to propagate the first subset of light beams through the lens set.

2. A light device according to claim 1, wherein the projection axis (Ap), the incident axis (Ai) and the second optical axis (Ao) are contained in the same plane.

3. A lighting device according to claim 1 or 2, wherein the angle of inclination between the projection axis (Ap) and the second optical axis (Ao) is between 2° and 6°, preferably of the order of 4°.

4. A light device according to any one of claims 1 to 3, wherein the incident axis (Ai) forms with the second optical axis (Ao) an angle of approximately 4° to 8°, preferably 6°.

5. A light device according to any one of claims 1 to 4, wherein the housing (10) comprises cylindrical bores, each cylindrical bore being configured to receive a lens (99a, 99b) from the lens assembly and arranged along an optical axis associated with said lens (99a, 99b).

6. A light device according to any one of claims 1 to 5, wherein the sequence of lenses (99b) comprises four lenses.

7. A lighting device according to any one of claims 1 to 6, wherein the housing (10) is made in one piece from a material such as aluminium, aluminium alloy or plastic.

8. A lighting device according to any one of claims 1 to 7, wherein the housing (10) is configured to receive and position the illumination assembly (97) and the micromirror array device (98) relative to said lens assembly.

9. Vehicle (100) equipped with a lighting device (100a) having the characteristics of any one of claims 1 to 8, the lighting device being configured to project a luminous representation (100b) onto a surface of the environment of the vehicle (100).

10. Vehicle according to claim 9, which includes a rocker panel (100c), the lighting device (100a) being arranged in the rocker panel (100c) and configured to project a light representation (100b) onto a ground surface outside the vehicle (100). 15

11. Vehicle (100) according to any one of claims 10 or 11, wherein the light device (100a) is configured to project onto the ground surface a light representation (100b) of a length of approximately 2800mm and a width of approximately 660mm.