Device for illuminating a target with absorbed emission spectrum

The jewelry lighting device addresses shadow and light exposure issues by using light sources with absorbed spectra matching the jewelry color, ensuring uniform and sparkling illumination, enhancing visual appeal and adaptability.

EP4767862A1Pending Publication Date: 2026-07-01PA COTTE SA

Patent Information

Authority / Receiving Office
EP · EP
Patent Type
Applications
Current Assignee / Owner
PA COTTE SA
Filing Date
2025-12-19
Publication Date
2026-07-01

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Abstract

The invention relates to a target illumination device comprising: - a support (2) having a target reception surface, the support including a target illumination zone (210), the support and / or at least the illumination zone of the support being of a determined color characterized by a determined absorption spectrum; - a frame (3) comprising a light group formed by a plurality of light sources. According to the invention, each light source emits a light spectrum, called the emission spectrum, chosen primarily from the determined absorption spectrum.
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Description

Scope of the invention

[0001] The field of the invention is that of lighting in general and that of devices for lighting a target.

[0002] More specifically, the invention relates to a device for lighting and highlighting a target.

[0003] The invention finds particular application in the scenographic lighting of jewelry. State of the art

[0004] He is known for creating jewelry displays equipped with lighting.

[0005] As an example, US document 6,433,483 describes jewelry lighting devices comprising a housing for receiving a piece of jewelry, and lighting means presenting a plurality of light sources.

[0006] The light sources are positioned in contact with the jewelry so that the light they emit is directed towards the jewelry's display area. This illuminates the jewelry. However, when the jewelry includes a stone or gemstone, or a transparent or translucent element, the light passes through the translucent element. This has the effect of illuminating the jewelry's display area within the device, creating uncontrolled and unsightly shadows. Objectives of the invention

[0007] The invention therefore aims in particular to overcome the disadvantages of the prior art mentioned above.

[0008] More specifically, the invention aims to provide a lighting device for a target, such as a piece of jewelry, which highlights the illuminated target or object.

[0009] An objective of the invention is also to provide such a technique which avoids the presence of unsightly and / or uncontrolled shadows.

[0010] Another objective of the invention is to provide such a technique which limits or eliminates differences in light exposure from the background to the back of the illuminated object.

[0011] Another objective of the invention is to provide such a technique which is simple to implement and of limited cost.

[0012] An objective of the invention is also to propose such a technique which has little or no impact on the size compared to a conventional lighting device.

[0013] Another objective of the invention is to provide such a technique which is reliable and safe for the observer of the illuminated object. Description of the invention

[0014] These objectives, as well as others that will appear subsequently, are achieved using a target illumination device, comprising: a support presenting a target reception surface to be illuminated, the support including a target illumination zone, the support and / or at least the illumination zone of the support being of a determined color characterized by a determined absorption spectrum; an armature comprising a luminous group formed of a plurality of light sources.

[0015] According to the invention, each light source emits a light spectrum, called emission spectrum, chosen mainly from the determined absorption spectrum.

[0016] Thus, in a novel way, the invention proposes to implement lighting in which the emission spectrum is absorbed by the specific color of the illuminated area. Thanks to these characteristics, the lighting conditions highlight the target to be illuminated, without creating a visible halo of light on the surface.

[0017] According to particular embodiments of the invention, the target lighting device, which is the subject of the invention, comprises one or more of the following characteristics, according to any operational technical combination.

[0018] Furthermore, according to a particular embodiment of the invention, the frame is intended to be positioned, at least in part, at a distance from the support.

[0019] Furthermore, according to an advantageous embodiment of the invention, the light group is mainly located in a portion of the armature distant from said support.

[0020] According to a particularly advantageous embodiment of the invention, the light spectrum of each light source is exclusively chosen from the spectrum absorbed by the support in the illumination zone.

[0021] According to a preferred embodiment of the invention, the determined color is uniform.

[0022] According to a particular embodiment of the invention, the light spectrum is further chosen according to the material and / or the surface condition, and / or the texture, and / or the shape of the illumination area.

[0023] Thus, the various parameters that influence the viewer's visual perception of the target, the piece of jewelry, the artwork, etc., are taken into account to optimize the lighting and therefore improve the presentation. For example, the specific, or chosen, material of the background is considered in relation to its impact on the absorption of incoming light.

[0024] According to an advantageous embodiment of the invention, the portion of the reinforcement intended to be positioned, at least in part, at a distance from the support is mainly positioned above said support.

[0025] Thanks to these technical characteristics, the luminous efficiency of the lighting is improved.

[0026] According to a particularly advantageous embodiment of the invention, the light group is located substantially elevated relative to said support

[0027] Thanks to these technical characteristics, the luminous efficiency of the lighting is optimized.

[0028] According to a preferred embodiment of the invention, the lighting device comprises a control unit coupled to each of the light sources, the control unit being parameterized to configure each light source so as to emit the chosen light spectrum.

[0029] Thus, the control of each light source is mastered.

[0030] Furthermore, according to a particularly advantageous embodiment of the invention, the control unit is parameterized to turn on at least one of the light sources at a determined frequency, and simultaneously keep at least one of the light sources off, the at least one of the light sources turned on being different from the at least one of the light sources kept off.

[0031] Thanks to these technical features, the lighting system highlights the target, making it appear animated and giving the impression that it is "alive." For example, when the target is a piece of jewelry set with stones, particularly faceted stones such as a cut diamond, the stones sparkle brilliantly.

[0032] According to an advantageous embodiment of the invention, the plurality of light sources forming the light group is arranged in a linear pattern.

[0033] According to a particular embodiment of the invention, the plurality of light sources forming the light group is arranged according to a matrix scheme.

[0034] According to a particular embodiment of the invention, the plurality of light sources is distributed in a repeated pattern forming the light group.

[0035] According to an advantageous embodiment of the invention, at least one of the light sources is formed from a composition of several radiation sources the addition of which produces a colored light or a substantially white light.

[0036] According to a particular embodiment of the invention, each light source is formed of an RGB LED.

[0037] Thus, with a trichromatic source, it is possible to configure the emission spectrum. Simply choose the desired color for the illuminated area based on its absorption spectrum and the emission spectrum of the light sources so that the emitted light is absorbed by the illuminated area.

[0038] According to a particular embodiment of the invention, the chosen light spectrum is obtained using a filter placed in front of each light source.

[0039] Thanks to these technical characteristics, it is possible to produce a lighting device according to the invention at a reduced cost.

[0040] According to a particularly advantageous embodiment of the invention, the lighting device includes a color characterization sensor so as to adapt the emission light spectrum.

[0041] Thus, thanks to these technical characteristics, the lighting system is able to adapt the emission spectrum of the light to produce a luminous flux absorbed by the background. To achieve this, the information provided by the sensor can be used directly by the control unit, or it may require the unit to perform a conversion, for example, using a nomogram or a formula, before reconfiguring the light sources. When a color temperature is measured in Kelvin, a nomogram can be used to obtain the corresponding absorption spectrum. The sensor can be, for example, a colorimeter, a spectrophotometer, a hyperspectral imaging device, a CCD sensor, or a photographic sensor equipped with a spectral filter.

[0042] According to a particularly advantageous embodiment of the invention, the lighting device further comprises a brightness sensor and / or a temperature sensor, of the ambient light in which the lighting device is used, so as to adapt the chosen light spectrum to the ambient light conditions.

[0043] Thus, thanks to these technical characteristics, the lighting system can adapt the illumination of the target, particularly according to ambient light conditions. It is then possible to maintain a constant display, for example, or one that can be configured according to the desired visual design. For instance, in a jeweler's street-facing window during the winter months, the brightness changes throughout the day. It is therefore possible to adjust the lighting conditions to maintain the appeal of the displayed jewelry regardless of the time of day. For example, at the end of the day, it is possible to make the lighting warmer. Conversely, in the visual design of a window display located inside the jewelry store, in an environment of artificial ambient lighting, which is often controlled, the behavior of the lighting system can be configured differently. Figures

[0044] Other features and advantages of the invention will become clearer upon reading the following description of three particular embodiments of the invention, given by way of simple illustrative and non-limiting example, and the accompanying drawings, among which: [ FIG. 1 ] there figure 1 is a schematic perspective representation of a first embodiment of a lighting device according to the invention; [ FIG. 2 ] there figure 2 is a schematic perspective representation of a second embodiment of a lighting device according to the invention, in the form of a display case; [ FIG. 3 ] there figure 3 is a schematic representation of a box incorporating a lighting device according to the invention; [ FIG. 4 ] there figure 4 is a graphical representation of the temporal evolution of a luminous intensity emitted by the luminous group of the lighting device according to the invention.

[0045] Only the elements necessary for understanding the invention have been shown. To facilitate reading the drawings, the same elements bear the same reference numbers from one figure to another. Detailed description of the invention

[0046] Reference will now be made in detail to specific implementations illustrated in the attached drawings and figures.

[0047] In the following detailed description, many specific details are presented to provide a thorough understanding of the invention.

[0048] However, it will be clear to the person skilled in the art that implementations can be put into practice without these specific details.

[0049] In other cases, well-known processes, procedures, components, circuits and networks have not been described in detail so as not to unnecessarily obscure aspects of implementations. Example of an embodiment of the invention

[0050] With the figure 1 , We have illustrated a device 1 for illuminating a target 1000, according to the invention, which is now described.

[0051] According to the embodiments detailed below, the target represented is a jewel 1000. However, this target could be a work of art, any object or even a person.

[0052] As can be seen, the lighting device 1 consists of a support 2 which has a receiving surface 21 for the target 1000 to be illuminated. The receiving surface 21 includes an illumination zone 210 in which the target, i.e., the piece of jewelry 1000 to be illuminated, is placed. It is perfectly clear within the scope of the invention that the illumination zone 210 can cover all or part of the receiving surface 21, and / or the support 2.

[0053] The lighting device 1 also includes an armature 3 intended to be positioned, at least in part, above the support 2. In other words, the support overhangs at least partially the support 2.

[0054] To illuminate the target 1000, the frame 3 is equipped with at least one light group 4 consisting of a plurality of light sources 41. This plurality includes at least two light sources spaced apart. The group thus formed is positioned substantially in elevation above the support 2. According to a preferred embodiment, the light group 4 overhangs, at least partially, the illumination zone 210.

[0055] According to the invention, on the one hand, the illuminated area 210 is of a specific color. This specific color, in other words, the color chosen according to the desired scenography for highlighting the target 1000, is characterized by an absorption spectrum. This will be called the specific absorption spectrum, in reference to the chosen or specific color. Furthermore, the illuminated area 210 is also called the background 210 of the device 1, and the specific color of the background is called the background color.

[0056] On the other hand, at least one of the light sources 41 emits a light spectrum chosen to correspond to the determined color of the illumination zone 210. Preferably, each light source 41 emits an identical or substantially identical light spectrum. The emitted light spectrum of each light source is primarily located in the absorption spectrum, which characterizes the determined color used for the illumination zone 210. Thus, the spectral radiations emitted by each light source are absorbed by the background 210. That is to say, the wavelengths present in the emission spectrum are also present in the absorption spectrum. In other words, the color of the emitted light is the same hue as the color of the background 210, which means that it will be absorbed by it.

[0057] To illustrate, by choosing a red background color, each light source 41 is chosen so as to emit in the same range of wavelengths.

[0058] Typically, the electromagnetic radiation corresponding to the color red covers the wavelength range between 620 and 780 nm.

[0059] In contrast, if the emitted light came from light sources whose spectral lines were chosen to emit in a range other than red, for example, green or blue, the emitted light would then be reflected by background 210. As a result, a patch of this light would be visible on background 210.

[0060] As a reminder, the color blue corresponds to electromagnetic radiation approximately in the range between 470 and 485 nm and the color green corresponds to electromagnetic radiation located approximately between 485 and 555 nm.

[0061] It will therefore be understood that, according to the invention, the light emitted by the plurality of light sources 41 of the lighting device 1 does not illuminate the illumination zone 210. Consequently, on the one hand, the beam of light from each light source 41 is not visible on the surface of the illumination zone 210 or background 210. On the other hand, the beam or cone of light from each light source 41 does not create a shadow phenomenon of the target, here the jewel, on this same illumination zone 210. Conversely, under the effect of standard lighting, for example that of white light with a continuous emission spectrum, that is to say with a wide range of wavelengths, from the ultraviolet wavelength to the infrared wavelength, the shadow of the target is visible on the illuminated background.

[0062] This means that for lighting device 1, the background color 210 is intimately linked, that is, matched, to the emitted light spectrum of each light source, and vice versa. Therefore, choosing one parameter implies choosing the other, forming a pair (background color; emitted light spectrum). For simplicity, the background color 210, also called the determined color, is uniform. Furthermore, the material, texture, surface finish, relief, and shape of the background 210 are parameters that, considered individually or collectively, can impact the absorption of light emitted by each light source 41. Consequently, when one of these parameters affects the final result, it is taken into account along with the background color 210 and the emitted light spectrum to avoid the appearance of a halo effect on the background 210.

[0063] To complete the lighting device 1, it also includes a control unit 5 powered by a rechargeable energy storage unit or battery 6. The battery 6 thus provides the autonomy for the entire electronic assembly of the lighting device 1. The control unit 5 is also connected directly or indirectly to each light source 41.

[0064] Thus, the lighting device 1, using its unit 5, is able to control each light source 41 of the lighting group 4. The control unit 5, connected to each light source, is configured to set each light source 41 to emit the chosen light spectrum. The operating modes of the control unit 5 will be detailed with the description of the figure 3 . Other examples of embodiments of the invention

[0065] On the figure 2 ,A second embodiment represents a portion of a display case 70 with the support platform 2 forming the surface for a work of art 1954. This display case, illustrating the lighting device 1, highlights the work of art 1954, placed in the illuminated zone 210. As in the previous embodiment, the display case 70 includes the frame 3 supporting the ceiling or sky 71. As can be seen on the figure 2The ceiling 71 supports the light group 4. Furthermore, in this case, the ceiling 71 overhangs the receiving surface 21 on one side and is parallel to the receiving surface 21 on the other. In this embodiment, the light group 4 has an annular shape. Thus, the plurality of light sources 41 are arranged in a circle so as to present the same angle with respect to the illumination zone 210. Moreover, the normal distance between each light source 41 and the receiving surface 21 is substantially the same.

[0066] It should be understood that the relationship between the emission spectrum of each light source 41 and the background color 210, in this second embodiment, is identical to the first embodiment.

[0067] Furthermore, it is understood that showcase 70 is equipped with the same means to activate the light group 4 in order to illuminate the artwork 1954.

[0068] With reference to the figure 3 , A third embodiment has been represented, in which the device is integrated into a box 10 comprising a casing 11 and a cover 12 for closing the casing 11. In this embodiment, the armature 3 is then integrated into the cover 12. As a result, the armature 3 is orientable relative to the support and therefore the lighting area 210.

[0069] More specifically, the receiving surface 21 of the support 2, and therefore the area to be illuminated 210, is formed by the bottom of the box 11. The cover 12 is therefore movable relative to the box 11 and allows the armature 3 to be positioned in elevation relative to the area to be illuminated 210, when the box 10 is in a plane substantially close to the horizontal.

[0070] The cover 12 has an internal face 121 intended to come against the box 11 in a closed position of the box 11 by the cover 12.

[0071] The lid also has a rim 122 surrounding the inner face 121.

[0072] Light group 4 is housed in border 122.

[0073] The border 122 has a slant 123 from which extends a rush 124 whose role is specified later in the description.

[0074] On the figure 2 , we observe that, the light group 4 comprises a plurality of light sources 41.

[0075] Light sources 41 are, for example, light-emitting diodes (known by the English acronym "LED"). For example, light sources 41 are formed from a composition of several elementary sources of radiation, the combination of which produces colored light or essentially white light. In other words, it is the mixture of the radiation from several elementary sources that produces the light emitted by each light source 41. A light source 41 is, for example, composed of the elementary sources red, green, and blue. However, each light source 41 is not limited to this example of composition and can, depending on the requirements, be bichromatic, trichromatic (such as the mixture of red, green, and blue), tetrachromatic (such as the mixture of red, yellow, green, and blue), or more.

[0076] Since the control unit 5 is parameterized to configure each light source 41 so as to emit the chosen light spectrum, the control unit 5 is able to define and / or fix the configuration of each light source 41 according to the characteristics of the light source 41 previously mentioned (bichromatic, trichromatic, tetrachromatic source, etc.).

[0077] Common to each embodiment, the lighting group 4 also includes: a heat sink; for each light source 41, optionally focusing means or a lens; thermal conduction means, and a support or substrate, such as an electronic board on which the light sources are fixed.

[0078] The different constituent elements of the light group 4 are positioned as follows.

[0079] The electronic board is attached to the heat sink by one side and to each of the collimators or each of the lenses by a second side carrying the light sources 41.

[0080] The thermal conduction system consists of a thermally conductive film located between the electronic board and the heat sink. This thermally conductive film is advantageously flexible, allowing it to deform and conform to the shape of the receptacle housing the LED group 4. This prevents, or at least minimizes, the presence of air bubbles that would have an insulating effect, hindering thermal conduction and thus impeding the desired heat dissipation.

[0081] The control unit 5 is coupled to each of the light sources 41.

[0082] In addition to managing a mode of simultaneous lighting of all light sources 41, the control unit 5 is configured to turn on, according to a determined frequency, at least one of the light sources 41 and, simultaneously, keep at least one of the light sources 41 off.

[0083] Of course, the light source 41 that is on is different from the light source 41 that is off.

[0084] Furthermore, the control unit 5 is configured to apply a light intensity setpoint Ti to each light source 41, so that at any given moment, « Tt = ∑ s = 1 N Ti where N is the number of 41 illuminated light sources, and Tt is the desired total illumination intensity. More precisely, Tt is the total light intensity received by the area to be illuminated.

[0085] With reference to the figure 4 ,This means that the desired total lighting intensity is distributed according to the number N of light sources 41 lit at any given time.

[0086] In other words, the sum at each instant of the light intensity emitted by each light source 41 is equal to the desired total lighting intensity Tt which remains constant over time T.

[0087] For example, the figure 4 The light intensity setpoints Ti of two light sources 41 are shown. The graph of the figure 4 corresponds to the intensity for each light source 41 (ordinate axis) as a function of time (abscissa axis).

[0088] A first light intensity setpoint Ti1 of one of the light sources 41 and a second light intensity setpoint Ti2 of another of the light sources 41 are shown.

[0089] As time T progresses, the first light intensity setpoint Ti1 decreases, and the second light intensity setpoint Ti2 increases.

[0090] We then observe that for each instant on the time line T, the sum of the first light intensity setpoint Ti1 and the second light intensity setpoint Ti2 is constant and corresponds to the desired total lighting intensity Tt.

[0091] There figure 4 illustrates the light intensity guidelines Ti of two light sources 41, however, the formula " Tt = ∑ s = 1 N Ti " is true for a number N of light sources 41 greater than two.

[0092] As illustrated by the figure 4 , the switching on and off of the light sources 41 is carried out in a gradual manner.

[0093] This allows the desired total lighting intensity Tt to be maintained constant and avoids any risk of lighting failure since there is an overlap of the lighting from at least two light sources 41.

[0094] Furthermore, maintaining a constant total desired illumination intensity Tt creates the impression of a natural shimmer. In addition, the perceived illumination of the background 210 is not affected by variations in the number of illuminated light sources 41, since the emission spectrum of the light sources 41 lies entirely within the absorption spectrum of the background 210. At the very least, when the emission spectrum is only partially within the absorption spectrum, the light spot effect, while not completely imperceptible to the eye, is significantly reduced, and there is no difference in the illumination of the receiving surface 21 depending on the number of light sources 41 illuminated simultaneously. The natural effect is further enhanced by the absence of a light spot and therefore of variations in the light spot around the jewel 1000 based on the direction of the light.In other words, the illumination of the area to be lit 210, and therefore the luminous spot when visible, is stable and does not appear to dance on the receiving surface 21 during the periodic, pseudo-random, or random switching of the illuminated light sources 41. Furthermore, it is specified that the luminous intensity, expressed in cd, refers to the light source 41, while the illuminance, expressed in lux, refers to the object illuminated by the light sources 41.

[0095] In addition, thanks to the gradual switching on and off of the light sources 41, it is possible to make the sparkle of the jewel 1000 more natural.

[0096] According to a first embodiment, the control unit 5 is configured to turn on each light source 41 according to a periodic pattern.

[0097] According to a second embodiment, the control unit 5 is configured to turn on each light source 41 according to a random, or almost random, pattern.

[0098] The transition from a periodic scheme to a random scheme, or vice versa, can be achieved by ad hoc control means.

[0099] The control means can, for example, take the form of a selector integrated into the lighting device 1, or a computer application installed on a portable electronic device. In the latter case, the control unit 5 is then able to communicate with the computer application embedded on the electronic device. In other words, the lighting device 1 includes first means of communication, used by the control unit 5, which is able to communicate with second means of communication of the portable electronic device.

[0100] According to a third embodiment, the control unit 5 is configured such that the desired total illumination intensity Tt is less than a constant limit value that allows the target to be illuminated without leaving a visible light area on the receiving surface 21. In other words, when the target is illuminated, the receiving surface 21 is not illuminated. Thus, in this embodiment, although this desired total illumination intensity Tt remains the sum of the light intensity setpoints Ti of the illuminated light sources 41 as before, the desired total illumination intensity Tt can vary between zero and the constant limit value to ensure a flickering effect. This embodiment is typically implemented if the emitted light spectrum of each light source is not entirely or mainly located within the absorption spectrum of the background 210.

[0101] With reference to figures 1 to 3 The light sources 41 are arranged in a line. The line can be straight, as in the first and third embodiments (respectively illustrated by the Figures 1 And 3 ), or present one or more radii of curvature as in the second embodiment (illustrated by the figure 2 ) in which the armature 3 is in the form of a ring. However, a matrix arrangement or scheme, a disk, or any other composition of the aforementioned arrangements of the light sources 41 falls within the scope of the invention.

[0102] In fact, when a fixed light source 41 is located above a piece of jewelry and emits light radiation directed towards it, each facet of the jewelry reflects the light in a direction.

[0103] A stationary observer, located nearby, can then see some facets of the jewel light up when the light reflected by one of the facets is directed towards the observer's eye and reaches their eye.

[0104] If the observer, the jewel, and the light source remain stationary, then the jewel does not sparkle.

[0105] On the other hand, when a relative displacement exists between the observer and the jewel, or between the jewel and the light source, then the rays reflected by each of the facets of the jewel are sent back in different directions, which causes a scintillating effect of the jewel when one of the facets intermittently reflects the radiation towards the eye of the observer.

[0106] The lighting device 1, described above, creates a sparkling effect on the target, in this case, the jewel 1000, through relative movement between the light group 4 and the jewel 1000. When highlighting a target, whether an object or a person, the reflection of light off different facets of the target causes the sparkling effect. For example, if a person is wearing clothing adorned with rhinestones or sequins, this effect can be amplified.

[0107] More precisely, the relative movement between the light group 4 and the target, here the jewel 1000, is obtained while the light group 4 is stationary relative to the jewel 1000.

[0108] Indeed, to allow the movement of the light source, the light group 4 is provided with a plurality of light sources 41 as explained above.

[0109] As previously described, the control of the light sources 41, i.e. their switching on and off, is carried out by the control unit 5.

[0110] More specifically, the control unit 5 controls the switching on of each light source 41, according to a predetermined, pseudo-random or random frequency.

[0111] The predetermined frequency corresponds to an ephemeral, even fleeting, ignition, that is to say, over a very short period of time.

[0112] When at least one of the light sources is on, at least one of the light sources 41 is off.

[0113] Thus, by varying the lighting of each light source, the control unit allows a movement of the light radiation directed towards the jewel 1000, while the light group 4 remains stationary.

[0114] This then causes the jewel to sparkle 1000 times as its different facets are illuminated discontinuously, randomly or in a predetermined way.

[0115] Thus, for an observer who remains fixed in relation to the jewel, the different light rays reflected by the different facets of the 1000 jewel reach the observer's eye only discontinuously, which causes the scintillation effect.

[0116] The use of a periodic pattern by the control unit 5 to control the lighting of the light sources 41 makes it possible to create a repetitive scintillation pattern of the jewel to highlight it in a particular way, for example by emphasizing one area more than another.

[0117] Thus, in the case of a 1000-piece jewel in the form of a necklace, as illustrated by the figure 1The scintillation can be achieved along the jewel 1000 from a first end to a second end in a first direction and then in a second direction, that is to say in the form of a back and forth.

[0118] On the other hand, when the control unit 5 uses a random pattern, then the sparkle of jewel 1000 is disordered, similar to a natural sparkle of jewel 1000. The random pattern will be advantageously defined so that it does not repeat itself during the same use. Other optional features and advantages of the invention

[0119] It is understood that, within the scope of the invention, the emission light spectrum, or emission spectrum, is either a discontinuous spectrum or line spectrum, or a continuous spectrum. When the emission spectrum is a continuous spectrum, it is typically a continuous portion of the absorption spectrum and, consequently, a continuous portion of the visible light spectrum. While the emission spectrum is typically emitted by polychromatic sources, it can very well also be the result of using monochromatic sources, judiciously combined with background 210.

[0120] In variations of the embodiments of the invention detailed above, it may also be provided that: to replace a light group with a single light source; that the light group, or plurality of light sources, can also be implemented using COB LEDs (English acronym for "Chip-on-Board"), or COB LED strips; that the light source(s) can be point source(s); that the light source(s) can be orthotropic, also known as Lambertian source, or isotropic; for each light group, an interface module connected to each light source and connected via a bus to the control unit;A light sensor and / or a temperature sensor, measuring the ambient light in which the lighting device is used, the sensor(s) being connected to the control unit 5 which is configured to adapt the chosen light spectrum to the ambient light conditions, or in other words, the control unit 5 being able to define the configuration of each source according to the ambient light conditions; the chosen light spectrum is obtained using a filter placed in front of each light source; one or more handles on the casing, allowing a user to grasp the box for easy transport. Thus, the casing can very well be a piece of luggage, for example a suitcase or a briefcase.

[0121] It should be understood that the elements shown in the figures can be implemented in various forms of hardware, software, or combinations thereof. Preferably, these elements are implemented in a combination of hardware and software on one or more appropriately programmed multipurpose devices, which may include a processor, memory, and input / output interfaces.

[0122] This description illustrates the principles of this disclosure. It will therefore be appreciated if those skilled in the art are able to devise various arrangements which, while not explicitly described or shown here, embody the principles of the disclosure and are included within its scope.

[0123] Thus, according to the principle of the invention, it is important to understand that the idea is to avoid the presence of a luminous halo and / or shadow cast by the target on the support in order to highlight the target, under the effect of lighting perceived as magical, beyond the examples previously described.

[0124] All examples and conditional language cited here are intended for educational purposes to help the reader understand the principles of disclosure and the concepts brought by the inventor to advance the art, and should be interpreted as not being limited to those specifically cited examples and conditions.

[0125] Furthermore, all statements of principles, aspects, and implementation methods of disclosure, as well as specific examples thereof, are intended to encompass their structural and functional equivalents. Moreover, it is anticipated that these equivalents will include both currently known equivalents and those developed in the future—that is, any developed element that fulfills the same function, regardless of its structure.

[0126] Thus, for example, those skilled in the art will understand that the schematic diagrams presented here represent conceptual views of illustrative circuits implementing the principles of disclosure. Similarly, it will be appreciated that all the flowcharts, diagrams, and other such representations depict various processes that can essentially be represented on a computer-readable medium and thus executed by a computer or processor, whether or not that computer or processor is explicitly shown.

[0127] Insofar as embodiments of the invention have been described as being implemented, at least in part, by a software-controlled data processing device, it will be understood that a machine-readable non-transient medium carrying such software, such as an optical disc, a magnetic disc, a semiconductor memory or the like, is also considered to represent an embodiment of the present invention.

[0128] The functions of the various elements illustrated in the figures can be performed using dedicated hardware as well as hardware capable of running software in conjunction with appropriate software. When performed by a processor, these functions can be carried out by a single dedicated processor, a single shared processor, or by multiple individual processors, some of which may be shared. Furthermore, the explicit use of the term "processor" or "controller" should not be interpreted as referring exclusively to hardware capable of running software, and may implicitly include, without limitation, a digital signal processor (DSP), read-only memory (ROM) for storing the software, random-access memory (RAM), and non-volatile storage media.In addition, some elements can be independent or grouped together, for example in a microcontroller (MCU), or a system-on-a-chip (SoC).

[0129] Other hardware, both conventional and / or custom, may also be included. Similarly, all switches shown in the figures are purely conceptual. Their function may be executed through program logic, dedicated logic, the interaction of a program command and dedicated logic, or even manually; the specific technique is selectable by the operator, as more specifically explained in the context.

[0130] In the claims of this document, any element expressed as a means of performing a specified function is intended to encompass any manner of performing that function, including, for example, a) a combination of circuit elements that perform that function or b) software in any form, including, therefore, firmware, microcode, or the like, combined with appropriate circuitry to execute that software in order to perform the function. The disclosure as defined by such claims lies in the fact that the functionalities provided by the various means cited are combined and brought together in the manner contemplated by the claims. It is therefore considered that all means that can provide these functionalities are equivalent to those presented herein.

Claims

1. A target illumination device (1) comprising: - a support (2) having a target reception surface (21) for the target to be illuminated, the support including a target illumination zone (210), the support and / or at least the illumination zone of the support being of a specific color characterized by a determined absorption spectrum; - a frame (3) comprising a luminous group (4) formed from a plurality of light sources (41), characterized in that Each light source emits a light spectrum, called the emission spectrum, chosen mainly from the determined absorption spectrum.

2. Lighting device according to claim 1, characterized in that The light spectrum of each light source is exclusively chosen from the spectrum absorbed by the support in the illumination zone.

3. Lighting device according to any one of the preceding claims, characterized in that the determined color is uniform.

4. Lighting device according to any one of the preceding claims, characterized in that the light spectrum is also chosen according to the material and / or surface condition, and / or texture, and / or shape of the illumination area.

5. Lighting device according to any one of the preceding claims, characterized in that the portion of the reinforcement (3) intended to be positioned, at least in part, at a distance from the support (2) is principally positioned above said support.

6. Lighting device according to any one of the preceding claims, characterized in that the light group is located substantially higher than said support (2).

7. Lighting device (1) according to any one of the preceding claims, characterized in that It includes a control unit (5) coupled to each of the light sources, the control unit being parameterized to configure each light source (41) so as to emit the chosen light spectrum.

8. Lighting device (1) according to the preceding claim, characterized in that the control unit (5) is programmed to turn on at least one of the light sources (41) at a determined frequency, and simultaneously keep at least one of the light sources (41) off, the at least one of the light sources (41) turned on being different from the at least one of the light sources (41) kept off.

9. Lighting device according to any one of the preceding claims, characterized in that the plurality of light sources forming the light group (4) is arranged according to a matrix scheme.

10. Lighting device according to any one of claims 1 to 3, characterized in that the plurality of light sources forming the light group (4) is arranged according to a linear scheme.

11. Lighting device (1) according to any one of the preceding claims, characterized in thatat least one of the light sources (41) is formed from a composition of several radiation sources whose addition produces colored light or substantially white light.

12. Lighting device (1) according to any one of the preceding claims, characterized in that the chosen light spectrum is obtained using a filter placed in front of each light source (41).

13. Lighting device according to any one of the preceding claims characterized in that It includes a color characterization sensor to determine the color in order to adapt the light emission spectrum.

14. Lighting device according to any one of the preceding claims, characterized in that It also includes a light sensor and / or a temperature sensor, of the ambient light in which the lighting device is used, so as to adapt the chosen light spectrum to the ambient light conditions.

15. Lighting device (1) according to any one of the preceding claims, characterized in that Each light source (41) is formed by an RGB LED.