TR201608786A2 - PHOTOLUMINESCENT LIGHTING SYSTEM FOR VEHICLES - Google Patents

Abstract

A vehicle rear taillight (tail lamp) is described. The vehicle taillight comprises a layer which is at least partially opaque and at least one light generating layer configured to substantially cover a portion of the permeable layer. The light generating layer comprises a plurality of electrodes and a plurality of LEDs in a semiconductor ink positioned between the electrodes. The light generating layer may be operated to emit an excitation emission. The taillight further comprises at least one photoluminescent layer close to at least one of the electrodes configured to convert the excitation emission into an output emission.

Description

DESCRIPTION PHOTOLUMINESCENT LIGHTING EQUIPMENT FOR VEHICLES This application is a continuation of U.S. Patent Application No. 14/086,442, filed November 21, 2013, titled "VEHICLE LIGHTING SYSTEM WITH PHOTOLUMINESCENT STRUCTURE," which is a continuation of U.S. Patent Application No. 14/603,636, filed January 23, 2015, titled "DOOR ILLUMINATION AND WARNING SYSTEM," The above-mentioned related applications are hereby incorporated by reference in their entirety. Technical Field to Which the Invention Relates This invention relates generally to a vehicle lighting system, and more specifically to vehicle lighting systems having a slim profile that can be operated to conform to non-planar surfaces. State of the Art (Prior Art) Related to the Invention Lighting in vehicles has traditionally been applied to provide illumination for reading, entering and operating the vehicle. However, lighting can also be applied to enhance vehicle features and systems to allow vehicle passengers, operators and those looking at the vehicle to have an enhanced experience. Such improvements may arise from improvements in safety, visibility, aesthetics and/or features. This invention is a vehicle The invention provides a lighting system that can be operated for illumination of a vehicle. In some configurations, the invention can be provided for use on a vehicle panel without requiring a large recess to accommodate a housing for at least one source of interest. In this way, the invention can be provided for mounting on an exterior surface that is substantially flush with the at least one finished surface of the vehicle. Lighting assemblies corresponding to thin assemblies can be provided in various configurations. DISCLOSURE OF THE INVENTION: According to one aspect of the invention, a vehicle taillight is turned on. The taillight comprises a light-transmissive layer and at least one light-generating layer constructed to substantially cover the light-transmissive layer. The light-generating layer comprises a plurality of electrodes and a plurality of LEDs within a semiconductor paint positioned between the electrodes. The light-generating layer may be operated to emit a stimulated emission. The taillight also comprises at least one photoluminescent layer near at least one of the electrodes constructed to convert the stimulated emission into a light-generated emission. According to another aspect of the invention, a vehicle lighting device is provided. The device comprises a layer that is at least translucent and at least one @El generating layer constructed to cover a portion of an interior surface of the at least translucent layer. The at least translucent layer comprises a plurality of electrodes and a plurality of LEDs within a semiconductor paint positioned between the electrodes. The plurality of LEDs may be operated to emit a stimulated emission. The device further comprises at least one photoluminescent layer adjacent to at least one of the electrodes constructed to convert the stimulated emission into a stimulating emission. According to another aspect of the present invention, a surface mounted tail light for a vehicle includes a first electron generating layer and a second electron generating layer. The first electron generating layer is permeable to a first layer of air and is configured to emit a first emission. The second electron generating layer is permeable to a second layer of air and is configured to emit a second emission corresponding to a color different from the first emission. These and other aspects, objects, and features of the present invention will be understood and appreciated by those skilled in the art upon review of the following specification, claims, and accompanying drawings. DESCRIPTION OF THE FIGURES: FIGURE 1 is a rear perspective view of an automobile vehicle including at least one illuminating device; FIGURE 2 is a side view showing a detail of an illuminating device; FIGURE 3 is a side view of a illuminating device showing a photoluminescent layer constructed to convert light to wavelength; FIGURE 4 is a side view showing a detail of a single-source illuminating device disposed on one surface of a vehicle; FIGURE 5 is a half view showing a detail of a multiple-source illuminating device disposed on one surface of a vehicle; FIGURE 6 is a side view showing a detail of a single-source illuminating device disposed on one surface of a vehicle. FIG. 7 is a side view of a vehicle with a direct beam generating device disposed on a surface; FIG. 8 is a front view of an example configuration of a taillight assembly utilizing a lighting device; FIG. 9 is a side sectional view of a spoiler (tailwind) utilizing a lighting device; FIG. 10 is a rear view of the vehicle including the spoiler shown with reference to FIG. 9; and FIGURE 11 is a block diagram of a lighting device constructed to control lighting according to the invention. Details of the invention are explained herein in detail as necessary. However, it is to be understood that the structures explained are merely examples of the invention which can be implemented in various and alternative forms. The figures do not necessarily represent a detailed design and some schematics may be minimized or exaggerated to show the overall function. Therefore, the specific structural and functional details described herein are not to be construed as exhaustive, but merely as a representative basis for teaching the invention in various ways to those skilled in the art. The term "and/or" as used herein means that when used of a list of two or more items, any of the listed items may be used alone, or any combination of two or more of the listed items may be used. For example, if a composition is described as comprising components A, B and/or C, the composition may include A alone; B alone; C alone; A and B together; A and C together; B and C together; or A, B and C together. Referring to Figure 1, the specification discloses a lighting assembly (10) for a vehicle (12) constructed to provide illumination in the form of at least one lamp (14) or indicator (16). As shown in the example embodiments of the application, the lighting assembly (10) may be used to illustrate various colours and may be used in various combinations to provide effective illumination for the vehicle (12). In some embodiments, the lighting assembly (10) may correspond to a tail light (18), a turn signal (20), a side signal (22) or various combinations of illumination assemblies for the vehicle (12). For example, the lighting assembly 10 may be used as part of a vehicle spoiler incorporating a daytime running light 26 and a high-mounted tail light 28. In one exemplary embodiment, the lighting assembly 10 may correspond to a relatively thin lighting assembly constructed for mounting on a sill surface 30 of a vehicle 12. The sill surface 30 may be substantially aligned with a sill surface of the vehicle 12. In this configuration, the lighting device 10 may be constructed for mounting on surface 30 without a conventional housing and without having a corresponding opening in at least one panel 32 of the vehicle 12. In this configuration, the lighting device 10 may be constructed for use on surfaces of the vehicle 12 that are not configured to receive a conventional rear stop lamp housing (e.g., taillight surfaces 30). That is, in some applications, the lighting device 10 may be constructed for application on one or more surfaces of the vehicle 12 that are not substantially in-line with the taillight surfaces. While specific examples are presented herein, the illumination device 10 can be applied to various interior and/or exterior panels, and in general, the instrument 12 can be configured to illuminate the interior. As referred to herein, the instrument 12 can correspond to a finished or painted surface of the instrument 12. For example, a slate surface can correspond to a finished surface of any panel of the instrument 12 that is accessible to anyone looking at the panels of the instrument 12. In contrast, a sile-1A surface may not normally include an interior panel surface or a rough surface, which is constructed to accommodate a non-visible housing or other feature in an assembled configuration. Although mentioned in relation to a sile-1A surface or finished surface, the lighting assembly 10 and the various corresponding generating assemblies described herein may be used in conjunction with the various surfaces of the lighting assembly 12. The lighting assembly 10 may include a thin, flexible lighting assembly and a corresponding generating assembly 34. As explained in relation to FIG. 1, the lighting device (10) generally refers to various lighting components positioned on the vehicle (12). Exemplary configurations of the lighting device (10) are explained in detail in the description on the right. For the purposes of this description, a vehicle accessory/item or panel (lighting device as it is herein opened) may refer to any interior or exterior vehicle equipment or part thereof suitable for accommodating it. The lighting assemblies (10) described herein are primarily intended for use in automotive vehicles, although it will be appreciated that the assembly or system may also be applied to other types of vehicles designed for the transport of one or more passengers, such as ships, aircraft, trains, public transport vehicles, etc., provided that the assembly or system is not associated with these. The emission (36) is shown by dashed lines extending from the @EL generating assembly (34). The @EL generating assembly (34) may have a slim profile and may be made of flexible material to conform to non-planar surfaces which may meet the vehicle (12) and the mounting surfaces (30). Specific examples of lighting device 10 may be configured to illuminate in response to a lighting signal, such as a daytime running lights or brake lights, or a variety of other lighting devices. In an example configuration, the lighting device 10 may be configured to selectively activate the lighting device 34 in response to a controller and/or at least one lighting control line. In this configuration, the lighting device 10 may be configured to selectively activate the lighting device 34 in response to at least one control condition of the vehicle 12. For example, the lighting device 12 may be configured to illuminate in response to a lighting signal, such as a daytime running light or a brake light. The controller and/or one or more mechanical or electromechanical switches may be configured to selectively activate the lighting device (134) in response to a lighting signal received from various vehicle control systems. For greater clarity, the lighting device (E10) will hereinafter be described in communication with the controller configured to selectively activate the lighting device (Eq34). An exemplary configuration of the controller is explained with reference to FIG. 11. The controller may be in communication with various control modules and systems of the vehicle (12), whereby the controller may selectively illuminate the lighting device (E10) in response to one or more states of the vehicle (12). A state of the vehicle 12 may correspond to at least one of a lock/unlock state, a lighting state, a driving state, a gear selection, a door locking state, a daytime running light activation, a brake light activation, or any other state that may be activated or detected by the various control modules and systems of the vehicle 12. The lighting device 10 provides useful functional illumination that can be efficiently applied to at least one of the vehicle 12's surface 30 in various configurations. Referring to FIG. 2, the light-generating device 34 may correspond to a thin-film or printed light emitting diode (LED) device. The heat generating device 34 may include a circuit 50 having a substrate 52. The substrate 52 may be opaque, transparent, or semi-transparent and may be thin. The substrate 52 may be a polymer such as polycarbonate, polymethyl methacrylate (PMMA), polyethylene terephthalate (PET), etc. In some models, the substrate 52 may be supplied from a roll for integration into the assembly processes for the heat generating device 34 and may be approximately 10.1 mm to 1.5 mm thick. A first electrode 54 or conductive layer may be disposed on the substrate 52. Herein, the first electrode 54 and/or various electrodes or conductive layers may comprise a conductive epoxy, such as a silver-containing or copper-containing epoxy. The first electrode 54 may be conductively connected to a first data line (bus bar) 56. The first data line 56 and other data lines or channels may be made of metallic and/or conductive materials, screen printed on electrodes or conductive layers. The data lines may be used to conductively connect a plurality of light emitting diode (LED) sources 58 within the ELEG-generating device 34 to a power supply via a controller. In this way, the first data line (EQSG) or other data lines used within the ELEG-generating device 34 may be configured to provide a uniform flux across and/or through a surface of the generating device 34. LED sources (EQSS) may be printed, dispersed or applied onto the first electrode (54) by means of a semiconducting ink (60). The semiconducting ink may correspond to a suspension in which a concentration of LED sources (58) is dispersed within the ink. The concentration of LED sources (34) may be varied depending on a desired emission intensity. LED sources (Eq58) may be dispersed randomly or in a controlled manner into the semiconducting ink (60). LED sources (58) may correspond to micro-LEDs composed of gallium nitride elements that may have dimensions of approximately 5 microns to 400 microns across a width substantially aligned with the surface of the first electrode (54). The semiconducting ink 60 may comprise various bonding and dielectric materials including, but not limited to, gallium, indium, silicon carbide, phosphorus, and/or semitransparent polymeric bonds. In this configuration, the semiconducting ink 60 may include LED sources 58 at various concentrations, with a surface density of the LED sources 58 being adjustable for various applications. In some cases, the LED sources 58 and the semiconducting ink 60 are available from Nth Degree Technologies Worldwide Inc. The semiconducting ink 60 may be applied to the substrate 52 via various printing processes such as inkjet and screen printing. More specifically, it is envisioned that the LED sources 58 may be dispersed within the semiconductor ink 60 and may be shaped and sized such that a large portion of it is preferentially aligned with the first electrode 54 and a second electrode 64 during deposition of the semiconductor ink 60. The LED sources 58 may be illuminated by a voltage source applied across the first electrode 54 and the second electrode 64, electrically connected to the electrodes 54, 64. In some embodiments, the LED sources 58 may be electrically connected to the electrodes 54, 64, and the latter may be illuminated by a voltage source applied across the first electrode 54 and the second electrode 64. In some embodiments, a power source derived from a vehicle power supply may be used to power the LED sources 58. Additional information regarding a similar structure for a generator assembly to the ISIE generator assembly 34 is provided in a document by Lowenthal, dated March 12, 2014, entitled "SEPARATE ULTRA-THIN PRINTED LED LAYER", which is hereby incorporated by reference in its entirety. At least one dielectric layer 66 may be printed over the LED sources (EXSS) to secure and/or maintain the LED sources (58) in position. The at least one dielectric layer 66 may correspond to a first dielectric layer 66a, which may be a substantially transparent material, and a second dielectric layer 66b. The second electrode 64 may correspond to an upper transparent conductive layer printed over the dielectric layer 66 to electrically connect the electrodes 54, 64. The second electrode 64 can be connected as a conductor to a second data line 68. The data lines 56, 58 can be used to connect multiple LED sources 58 to the controller via data buses 56, 68 within the device 34. Although multiple LED sources 58 are connected to the controller via data buses 56, 68, in some configurations the controller can also provide power via various forms of conductive leads or paths, such as LED sources 58 being configured to conductively connect the controller to the first electrode 54 and the second electrode 64. An exemplary configuration of the controller is illustrated with reference to FIG. 11. In some configurations, the first electrode 54 and the second electrode 64 may correspond to an anode electrode and a cathode electrode. Although the heat generating device 34 is configured as an anode and a cathode, the first electrode 54 and the second electrode 64 may be arranged such that the second electrode 64 (cathode) is positioned on the substrate and the first electrode 54 (anode) is positioned on at least one dielectric layer 66. Additionally, a reflective layer, which may be of metallic reflective material, may be positioned between the substrate 52 and the first electrode 54 to prevent electromagnetic radiation emanating from the cathode through the second electrode 64. Data paths 56, 68 are provided between the electrodes 54, 64) may be connected along the opposite edges (E) and may terminate electrically at the anode and cathode terminals. Data paths (E) 56, 68 and power supply connections may be located at the opposite edges of each data path (56, 58) for uniform electrical distribution along each path. Still referring to FIG. Z, in some configurations, a photoluminescent layer (70) may be applied to the second electrode (64) to create a backlit configuration (E). In some configurations, the photoluminescent layer (70) may alternatively or additionally be in a frontlit configuration. The photoluminescent layer (70) may be connected to the second electrode (64) or through it to emit the emission (64). The @E generating device (34) can be applied as a coating, layer, film and/or photoluminescent substrate onto any surface. The photoluminescent layer (70) can be applied by screen printing and/or otherwise fixed to a semi-transparent accessory such as the second electrode (64) or medium (12) as shown in FIG. 9. In various embodiments, LED sources (58) can be configured to emit an excited emission comprising a first wavelength corresponding to blue light. The LED sources (58) can be configured to emit its excited emission into the photoluminescent layer (70), thereby making the photoluminescent material excited. In response to the stimulation of the excited emission, The photoluminescent material converts the excitation emission from the first wavelength into light emission (36) comprising at least a second wavelength longer than the first wavelength. In addition, one or more coatings (72) or coatings (36) may be applied to the surfaces of the photoluminescent layer E1 (70) and the photoluminescent generating device (34) to protect them from other damage and corrosion. Referring now to FIG. 3, a detailed view of the photoluminescent layer (70) of the photoluminescent generating device (34) is shown in a backlit configuration. The photoluminescent generating device (34) is constructed similarly to the photoluminescent generating device (34) shown in FIG. 2. The photoluminescent and similar numbered elements are similar or 3, the LED sources E (58) are in electrical communication with a power supply and data buses (56, 68) through the controller, which allows the controller to selectively activate a stimulated emission 80 from the LED sources E (58). In an exemplary embodiment, the stimulated emission 80 includes a first wavelength corresponding to a blue, violet and/or ultraviolet spectral color range. The blue spectral color range includes a wavelength range E1, generally referred to as blue E1 (~440-500 nm). In some embodiments, the first wavelength may include a wavelength in the ultraviolet or near ultraviolet color range (~100-450 nm). In an exemplary embodiment, the first wavelength may be approximately 470 nm. It may be equal. Although specific wavelengths and wavelength ranges have been mentioned in relation to the first wavelength, the first wavelength can generally be configured to excite any photoluminescent material. During operation, the excitation emission (80) is transmitted into a material that is at least partially transparent to the photoluminescent layer (70). The excitation emission is emitted from LED sources (58) and the first wavelength can be configured to correspond to at least one absorption wavelength of one or more photoluminescent materials placed within the photoluminescent layer (70). For example, the photoluminescent layer (70) can excite the first wavelength by emitting a second wavelength that differs from the first wavelength. (36) may include an energy conversion layer (82) configured to convert the spark emission (36) into one or more wavelengths, one of which may be longer than the first wavelength. The process of converting the stimulated emission (80) into the spark emission (36) by the energy conversion layer (HSZ) is called a Stokes shift. In some applications, the spark emission (36) may correspond to more than one wavelength. Each of the multiple wavelengths may correspond to significantly different spectral color ranges. For example, at least the second wavelength of the spark emission (36) may correspond to more than one wavelength (e.g., second, third, etc.). In some applications, the multiple wavelengths may be substantially white. Multiple wavelengths can be combined in the stimulated emission (36) to appear as @. Multiple wavelengths can be formed: a primary emitting photoluminescent material side having a wavelength of about 620-750 nm, a green-emitting photoluminescent material side having a wavelength of about 526-606 nm, and a blue or blue-green emitting photoluminescent material side having a wavelength of about 430-525 nm and the first wavelength (A1). In some applications, a blue or blue-green wavelength can correspond to the stimulated emission combined with the stimulated emission (36). As explained herein, a concentration of photoluminescent material can be combined to add a blue tint to the primary emission (36). The photoluminescent light emitted from the first wavelength can be constructed to allow for the emission of the light emitted (36) in combination with the energy conversion layer (82). Photoluminescent light emitted from the first wavelength can be utilized to produce a wide range of colors from each wavelength. Although specifically mentioned here are green and blue, various photoluminescent materials can be utilized to produce a wide range of colors and combinations to control the appearance of the light emitted (36). The energy conversion layer (82) is the photoluminescent layer. (70) The corresponding photoluminescent materials can contain organic or inorganic fluorescent dyes to convert the excitation emission (80) into light emitted (36). For example, the photoluminescent layer (70) may comprise a photoluminescent structure of rylonitriles, xanthones, porins, phthalocyanines, or other materials suitable for an emission fluorescence at a defined Stokes shift in an absorption range. In some configurations, the photoluminescent layer (70) may be at least one inorganic luminescent material selected from the group of phosphors. More specifically, the inorganic luminescent material may be from the group of Ce-doped garnets such as YAG:Ce. In this manner, the photoluminescent layers can selectively activate a wide range of wavelengths from the excitation emission (80) to excite one or more photoluminescent materials to emit a light emission having a desired color, each of which can be further activated. Also see FIG. 3. The operating device (34) may also include at least one stability layer (84) or coating (72) to protect the photoluminescent material contained within the energy conversion layer (82) from photolytic and/or thermal degradation. The stability layer (84) may be optically bonded to the energy conversion layer (82) and constructed as a separate layer. The stability layer (84) may also be integrated with the energy conversion layer (82). The photoluminescent layer (70) may optionally be a separate stability layer (84) or a protection layer (86) optically bonded to and constructed as a separate layer or coating. The stability layer E1 (84) and/or the protection layer E1 (86) may be combined with the energy conversion layer E1 (82) to form an integrated photoluminescent structure E1 (88) by means of a sintered coating of each layer, a printed substrate, or a sintered and embossed coating. Additionally, various layers may be laminated or embossed to form a substrate to form the sintered coating, photoluminescent structure E1 (88). Once formed, the photoluminescent structure E1 (88) may be applied onto a surface of at least one of the electrodes 54, 64, thereby converting the stimulated emission of Al2O from the LED sources 58 into sparkling emission 36. The at least one photoluminescent structure may be converted into a sparkling emission 36. Additional information regarding the creation of photoluminescent structures that can be used in KLENIZI is disclosed in United States Patent No. 8,232,533, "PHOTOLYTIC AND ENVIRONMENTALLY STABLE MULTILAYER STRUCTURE FOR HIGH EFFICIENT ELECTROMAGNETIC ENERGY CONVERSION AND SUSTAINED SECONDARY EMISSION" to Kingsley et al., dated July 31, 2012, the contents of which are hereby incorporated by reference. Referring now to Figures 4, 5, 6 and 7, the photoluminescent generating devices are of various configurations. The photoluminescent generating devices each have a specific emission (36) The device may be configured to emit a first signal emission 92 and a second signal emission 94, which may be generated in response to the activation of at least one stimulus emission, for example, the stimulus emission 80. Definitions such as a, b, c, etc. may be used to distinguish particular examples of the elements within each of the devices described herein, but it is understood that each of the elements may be generated or replaced by various combinations of the @El generating devices described herein. Although the @El generating devices are described with reference to particular configurations, the FREQUENTLY mentioned herein are Generating devices can be combined based on various features, characteristics, and/or construction techniques of each. Referring to FIG. 4, a detailed side view of a single-source EL1 generating device (102) is shown placed on surface (30). The single-source EL1 generating device (102) may include similar elements as EL1 generating device (34) but with similar numbers for clarity. The single-source EL1 generating device (hereinafter referred to as device 102) illuminates a first photoluminescent light emitter (104a) during the first three emission phases (92a) and a second photoluminescent light emitter (106a) during the second three emission phases (92a). The device 102 may be configured to emit warning emission 80 for illumination by means of 94a. In this configuration, the device 102 may be operated to emit a first double emission 92a to illuminate the lighting device 10 in a first illumination color and the device 10 may be operated to emit a second double emission 94a to illuminate the lighting device 10 in a second illumination color. The device 102 may be connected to the external surface 30, which may be opposed by means of at least one panel 32 or accessory, as shown in the figure. The device 102 may be attached to the external surface 30 by means of an adhesive layer 109. The adhesive layer 109 may take various forms, such as acrylic adhesive, epoxy adhesive, etc. In this way, the assembly 102 may be attached to the mounting surface 30 in a manner substantially non-separable from one or more of the panel 32 surfaces. The assembly 102 may correspond to a mounting surface 110, the substrate 52, or a film layer. The substrate 52 may correspond to a dielectric material layer, which is electrically insulated from the assembly 102 by means of an emitting layer 108. The emitting layer 108 may be configured to emit stimulated emission 80. The emitting layer 108 may be configured to emit stimulated emission 80. The controller may comprise a printed layer (112) comprising a first electrode (54) and a second electrode (64) and LED sources (58) printed on a surface therebetween. A suspension containing a concentration of the LED layer (58) may be applied to at least one of the electrodes. The controller may be operated to activate stimulated emission (80) of the emitting layer (108) by providing a signal via the first data path (56) and the second data path (68). Upon receiving the stimulated emission (80), the first photoluminescent portion (104a) and the second photoluminescent portion (106a) may reciprocally emit first photoluminescent emission (92a) and second photoluminescent emission (94). Photoluminescent light emitted by the corresponding photoluminescent lamps 104a, 106a (EC92a, 94a) can be produced by each photoluminescent material within the energy conversion layer 82). In this configuration, the controller can activate the first photoluminescent lamp 92a to illuminate a first light source in the first light source by controlling the stimulated emission 80. The controller can also activate the second triple emission 94a by controlling the stimulated emission 80 to illuminate the lighting device in a second color different from the first color. As mentioned with reference to FIG. 8, the color of the triple emission from each of the photoluminescent lights described herein can be controlled by one or more photoluminescent materials utilized in the energy conversion layers of each of the photoluminescent lights. For example, the first photoluminescent light 104a may be configured to emit a substantially orange light as the first light emission 92a, and the second photoluminescent light 106a may be configured to emit a substantially orange light as the second light emission 94a. In this configuration, the controller may activate the printed photoluminescent light 104a, 106a to illuminate each of the first color Eg11 and the second color Eg11. The assembly 102 may further include at least one stability layer (72) designed to protect the photoluminescent material contained within the energy conversion layer 82 from photolytic and/or thermal degradation. The coating 72 may also include a stability layer (84) or a protection layer (86) optically bonded and adhered to any layer or coating to protect it from physical and chemical damage that may occur due to exposure to ambient conditions. In some Handheld ... The dispersion layer 114 may be made of a variety of light-transmissive materials and, in an exemplary configuration, may correspond to an optical glass or polymeric dispersion layer. Referring to FIG. 5, a side view detailing one embodiment of a multi-source generating device 122 is shown placed on the substrate 30. The multi-source generating device 122 may share at least some similar characteristics with the single-source generating device 102. As explained with reference to FIG. 4, explanations of similar numerical features may be omitted as appropriate. The multi-source generating device 122 (hereinafter device 122) may be configured to emit first spark emission 92b and second spark emission 94b independently. To provide dependent activation of the first spark emission 92b and the second spark emission 94b, the controller device 122 may be in communication with a first spark emission layer 124 and a second spark emission layer 126. The first spark emission layer 124 may be configured to emit a first stimulated emission 80a to illuminate the first photoluminescent lamp 104b within the first spark emission 92b. The second emitting layer 126 may be configured to emit a second excitation emission 80b to illuminate the second photoluminescent light emitted 94b within the second emitting layer 122. In this configuration, the device 122 may be operated to emit the first emitting emission 92b to illuminate the illuminating device 10 in a first [QR] color or to emit the second emitting emission 94b to illuminate the illuminating device 10 in a second color. As mentioned previously, photoluminescent layers (104b, 106b) with corresponding photoluminescent peaks (92a, 94b) can be produced by each photoluminescent material within the energy conversion layers (104b, 106b). The emitting layers (124, 126) can each be constructed to emit stimulated emissions (80a, 80b) at similar wavelengths or at substantially different wavelengths. The emitting layers 124, 126 may be configured such that one or more wavelengths of LED sources 58 corresponding to each of the corresponding photoluminescent elements 104b, 106b are aligned with the absorption range of one or more photoluminescent materials utilized in each of the corresponding photoluminescent elements 104b, 106b. In this configuration, the controller may activate the first emitting layer 124 to emit stimulated emission 80a to excite the first photoluminescent element 104b and activate the second emitting layer 126 to emit stimulated emission 80b to excite the second photoluminescent element 106b. In some embodiments, the first photoluminescent layer 104b and the second photoluminescent layer 106b may correspond to a combined photoluminescent layer 128. The combined photoluminescent layer 128 may include one or more photoluminescent materials configured to have substantially different absorption ranges. For example, a first photoluminescent material may have a first absorption range configured to become excited upon receiving the first excitation emission 80a. In response to receiving the first excitation emission 80a, the combined photoluminescent layer 128 may emit the first excitation emission 92b in a first color. A second photoluminescent material may have a first absorption range configured to become excited upon receiving the first excitation emission 80a. In response to receiving the second excited emission 80b, the combined photoluminescent layer 128 can emit the second emission 94b in a second color different from the first. The second absorption range can be significantly different from the first absorption range, so that the first absorption range does not significantly overlap the second absorption range. In this way, the emitting layers 124, 126 can each illuminate a portion of the combined photoluminescent layer 128. In this configuration, the combined photoluminescent layer 128 may be configured to emit each of the chirp emissions 92b, 94b substantially independently. By causing the first emitting layer 124 and the second emitting layer 126 to be activated independently, the controller may selectively activate the first chirp emission 92b and independently activate the second chirp emission 94b from the device 122. In this configuration, the chirp emissions 92b, 94b may be used to selectively illuminate a first color of the illumination device and a second color of the illumination device. Device 122 can provide cost effective and efficient means of illuminating various lighting assemblies as described herein. In an exemplary configuration, the first two lighting assemblies may correspond to a rear stop lamp, the second two to a daytime running light, and the second two to a turning signal. An exemplary configuration of such a configuration is described with reference to FIG. 8. Referring to FIG. 6, a detailed side view illustrating one embodiment of the multilayered LED generating device 132 is shown mounted on the surface 30. The multilayered gelatin generating device 132 may share at least some similar properties with the single-source gelatin generating device 102. Therefore, descriptions of similarly numbered features may be omitted for simplicity. The multilayered gelatin generating device 132 (hereinafter referred to as device 132)) may be configured to emit the first gelatin emission 92c and the second gelatin emission 94c independently. To cause the first triple emitter emission 92c and the second triple emitter emission 94c to be activated respectively, the controller may be in communication with a first stacked spring layer (134). The first stacked spring layer (134) may be configured to emit a first stimulated emission 80a to illuminate the first photoluminescent emission 104c within the first triple emitter emission 92c. The second stacked spring layer (136) may be configured to emit a second stimulated emission 80b to illuminate the second photoluminescent emission 94c within the second triple emitter emission 94c. In this configuration, the device 132 may be configured to emit a first stimulating emission 92c, with the lighting device 10 emitting a second stimulating emission 94c to illuminate a first stimulating emission 80a and the lighting device 10 emitting a second stimulating emission 80b to illuminate the second stimulating emission 80b. The first stacked spring layer 134 may be configured to emit a first stimulating emission 80a and the second stacked spring layer 136 may be configured to emit a second stimulating emission 80b. In the stacked configuration, the stacked LED layers 134, 136 may each be made of substantially dielectric materials, whereby the first dielectric emission 80a can be transmitted through the second LED layer 136. For example, the electrodes may be indium tin oxide (ITO), and the LED layer 112 may be comprised of at least one dielectric layer (166) of a polymer and graphene. In this configuration, the dielectric emission may be transmitted into the photoluminescent layers 104c, 106c, each to create dielectric emissions 92c, 94c). As illustrated in relation to assembly 102, photoluminescent beams (104c, 106c) corresponding to the stimulated emissions IE(92c, 94c) can be produced by each photoluminescent material within the energy conversion layers IE(82). The stacked radiant layers 134, 136 can each be configured to emit stimulated emissions IE(80a, 80b) at similar wavelengths or at substantially different wavelengths. The stacked spring layers 134 may be configured to be aligned with an absorption range of one or more photoluminescent materials employed within each of the respective photoluminescent channels 104c, 106c, given wavelengths. In this configuration, the controller may activate the first stacked spring layer 134 to emit stimulated emission 80a to excite the first photoluminescent element 104c, and may activate the second stacked spring layer 1136 to emit stimulated emission 80b to excite the second photoluminescent element 106c. In some embodiments, the first photoluminescent layer 104c and the second photoluminescent layer 106c may correspond to a combined photoluminescent layer 128. The combined photoluminescent layer 128 may include one or more photoluminescent materials configured to have substantially different absorption ranges. For example, a first photoluminescent material may have a first absorption range configured to become excited upon receiving the first excitation emission 80a. In response to receiving the first excitation emission 80a, the combined photoluminescent layer 128 may emit the first 92c emission in the first color. A second photoluminescent material may have a second absorption band that is designed to receive the first excited emission (80b) and become correspondingly excited. In response to receiving the second excited emission 80b, the combined photoluminescent layer 128 can emit a second color different from the first color. The second absorption range can be significantly different from the first absorption range, so that the second absorption range does not significantly overlap the first absorption range. In this way, the stacked emitting layers 134, 136 can each illuminate a portion of the combined photoluminescent layer 128. In this configuration, the combined photoluminescent layer 128 can be constructed to emit double emissions 92c, 94c substantially independently of each other. The combined photoluminescent layer 128 can be arranged within the multilayered assembly 132. When used, the illumination device may overlap the emission of the first chime emission 92c and the second chime emission 94c. That is, the device 132 may be configured to selectively emit the first chime emission 92c and the second chime emission 94c from a surface 138 of the device 132, whereby the first chime emission 92c and the second chime emission 94c may be emitted substantially from the same surface. In this configuration, the illumination device may be configured to selectively emit the first chime emission 92c in a first color and the second chime emission 94c in a second color from a single light source, as discussed herein. Such a device may be configured to selectively emit the first chime emission 92c in a first color and the second chime emission 94c in a second color. The lighting device can be operated selectively to emit daytime lighting in the first color and to emit a return signal in the second color. That is, the device 132 can selectively emit either the first color or the second color over an overlapping surface. Referring to FIG. 7, a detailed side view showing an embodiment of a direct light emitting device 142 is shown placed on the surface 30. The direct light emitting device 142 may share at least some similar characteristics with the single-source light emitting device 102. Therefore, the descriptions of similarly numbered features can be omitted for clarity. The generating device 142 (hereinafter device 142) may be configured to emit the first chime emission 92d and the second chime emission 94d independently. To ensure that the first chime emission 92d and the second chime emission 94d are activated independently, the controller may communicate with a first spring layer 124 and a second spring layer 122 of the device 122. The first spring layer 124 may be configured to emit the first light emitting 92d directly from the printed LED layer. The second spring layer 126 may be configured to emit the second light emitting 94d directly from the printed LED layer. In this configuration, the device 142 may be operated to emit the first light emitting 92d, thus illuminating the first light emitting 10 in a first light color, and the second light emitting 94d, thus illuminating the first light emitting 10 in a second light color. Now, looking at FIG. 8, the lighting A front view of an exemplary embodiment of a rear stop lamp assembly 152 using an embodiment of assembly 10 is shown. The rear stop lamp assembly EUSZ comprises a first 154 which may correspond to a daytime running light and a second 156 which may correspond to a combined emitter comprising both a daytime running light and a turn signal. The first 154 may correspond to a single-source generating assembly 102 which includes similar elements configured to emit low-frequency emissions IE (92a, 94a). The first 154 may include a first lighting design 158 and a second lighting design 160. Now, Referring to FIGURES 4 and 8, each of the illuminating designs mentioned herein (e.g., the first illuminating design 158 and the second illuminating design 160)) may correspond to any shape, character, form, or design created by at least one of a photoluminescent light source, such as a light source generating device, a spring, or a photoluminescent light source. The first illuminating design 158 may correspond to the first photoluminescent light source 102, and the second photoluminescent light source 104a. In the second illuminating design 160, the first photoluminescent light source 104a and the second photoluminescent light source 160 are all single-source generated devices. (106a) can form complementary forms in which each form outlines the other. As shown, the first photoluminescent lamp 104a and the second photoluminescent lamp 106a can be printed and/or dispersed onto the multilayered lamp 108 to create different designs such as the first multilayered lamp design 158 and the second multilayered lamp design 160. Now referring to FIGS. 6 and 8, the second lamp 156 can selectively activate the first stacked lamp 134 to illuminate the second lamp 156 to emit a substantial amount of light. The first lamp 92c may correspond to a daytime running light. The controller may also selectively activate the second stacked emitter 94c to illuminate the second emitter 156 to emit the second emitter 94c in a substantially darker color. The second emitter 94c may correspond to a turn signal from the taillight 152. In this configuration, the second emitter 156 may correspond to a combined emitter comprising both a daylight running light and a turn signal. Referring to FIGS. 5 and 8, the second emitter may additionally include a third illuminated design 162 and a fourth illuminated design 164 formed by the multi-source emitter 122. The third lighting design 162 may correspond to the first arc layer 124 constructed to illuminate the first photoluminescent light 104b within the first freckle emission 92b. The first photoluminescent light 104b may include one or more photoluminescent materials constructed to give the first freckle emission 92b a predominantly green color. The fourth lighting design 164 may correspond to the second arc layer 126 constructed to illuminate the second photoluminescent light 106b within the second freckle emission 94b. The second photoluminescent array 106b may include one or more photoluminescent materials designed to selectively illuminate the second illumination array 94b in a substantially white color. In this configuration, the controller may be operated to selectively illuminate the third illumination array 162) and/or the fourth illumination array 164. As shown in FIG. 8, the spring assemblies referred to herein may be implemented singly or in combination, each illuminating at least one part of the illumination array 12. In this way, the invention provides a variety of lighting assemblies (El) that can be placed on various types of beams. In each of the structures mentioned herein, the [LIGHT] generating device (El) can be selectively activated by at least one controller electrically connected to the electrodes (e.g., the first electrode (54) and the second electrode (56) of each respective spring layer). In this way, the various LIGHT spring assemblies can be combined and configured to form a wide variety of lighting assemblies, devices, and systems that can be used in various types of beam illumination (El). FIGURES 9 and 10 show an exemplary configuration of a door panel 172 having one or more structures corresponding to the vehicle 12 lighting fixture 10. The door panel 172 may correspond to a spoiler 174, windshield wiper, or any other exterior vehicle feature. Now refer to FIG. 9, where a side sectional view of the spoiler 174 is shown. The spoiler 174 may be configured to selectively illuminate an external housing 176 that is at least fifty percent transparent, forming a cover for a lighting fixture 178, and may be in communication with one or more control circuits and/or a controller as hereinafter referred to. The housing 176 may be made of a variety of permeable materials, and in some configurations may be made of an impact resistant polymeric material that is constructed to accommodate one or more EI springs 180 therein. The housing 176 is mechanically attached, laminated, bonded, and/or otherwise connected to a mounting fixture 182 attached to the vehicle 12. The mounting fixture 182 may be made of a variety of materials, such as, for example, polymeric materials, that are molded to fit at least one panel of the vehicle 12. The mounting fixture 182 may be attached to the panel 32 by means of one or more fastening clips 184, which are configured to engage a hole or slot in the panel 32. One of the fastening clips 184 may correspond to a combined conductor connector, and the fastening clip will hereinafter be referred to as a wiring system clip 186. In this configuration, the lighting fixture 180 may be in communication with the controller and/or one or more control circuits, as referred to herein. An exemplary configuration of the controller is illustrated with reference to FIG. 11. Referring to FIGS. 9 and 10, housing 176 may be configured to hold and illuminate one or more emitters in various combinations, such as those shown in FIGS. 4-8. In an exemplary configuration, illumination assembly 178 may include a first combined spring (emitter) 192, a center spring 194, and a second combined spring 196. Each of the combination springs 192, 196 may be configured to selectively emit light in a first color and a second color to function as a daytime running light or a turn signal. The center spring 194 may also be configured to illuminate in the first color to provide daytime running light illumination. Additionally, the @El generating device may include the combination springs 192, 196 to warn that the vehicle 12 is braking and a stop light configured to emit a high intensity light with the center spring 194. The first combined spring 192 and the second combined spring 196 may each be mounted on a stacked surface 198 in housing structures as a multi-layered Emission Generator assembly 132 similar to that illustrated with reference to FIG. 8. In this configuration, the controller may receive signals via wiring clip 186 to selectively activate the first stacked spring 34 to emit the first Emission Emission 92c as a substantially smaller @E1. The first Emission Emission 92c may correspond to a daylight output from each of the combined springs 192, 196. The controller may also selectively activate the second stacked spring El 136 to emit the second chime emission 94c substantially as a fifth. The second chime emission 94c may correspond to a turn signal that may be emitted by each of the three combined springs 192, 196. In this configuration, the combined springs 192, 196 may operate as a daylight running light, a turn signal, or both, as controlled by the controller. The center spring El 194 lighting arrangement 178 may correspond to a signal located substantially between the first combined spring El 192 and the second combined spring el 96. In this configuration, the controller can selectively activate the LED sources 58 to substantially illuminate the female surface 198 facing the housing 176. While the springs 129, 194, 196, etc. mentioned herein are described with reference to each specific light generating device, it will be understood that the light device 178 may include a variety of light generating devices or combinations thereof without departing from the spirit of the description. In some embodiments, the center spring 194 may be attached to the inner surface 197 or the inner surface 198 of the housing 176, or may otherwise be attached and at least partially opposed to a corresponding permeable layer 202. As mentioned herein, with reference to the first combined spring E1, it will be understood that the emitters 192, 194, 196 may each correspond to a separate illumination device 178 as shown in FIG. 10. In relation to the central spring E194, a brake signal can be provided for a specific purpose. For example, the brake emitter 200 may be configured to selectively emit a brake signal through at least one illumination source 204, the device 34 generating at least a small amount of E1, and the E1 transmissive layer E1 202. The brake light indicator may be emitted through the housing 176 and at least one coating 2026 or protective layer therein. In some configurations, the brake light generating device 34 may form an opening or gap 208 constructed to provide a gap within the brake light generating device 34 for at least one coating 2026 to pass efficiently between the housing 176 and the at least one coating 206. In this configuration, the controller may operate to selectively activate the brake light (EXHAUST) to provide a brake light indicator through at least one coating 2026 and to warn the vehicle 12 that braking is being applied. One or more coatings 206 may correspond to at least one side coating. For example, a side coating slot 176 may be deposited on the surface 196. The one or more coatings 206 may correspond to one or more coatings 72 or other layers of thin film, such as those previously described. In one example configuration, the one or more coatings 206 may correspond to a vacuum metallized coating 210. The metallized coating may serve to provide a metallic and/or chrome appearance to the surface 196 by reflecting wavelengths originating from ambient light emitted by the illuminating device 178. In this configuration, the lighting assembly 178 may appear metallic in a front-lit configuration with ambient or ambient LEDs. Additionally, upon controller activation of each of the emitters, the vacuum metallized coating 210 may change from a metallic, side-lit appearance to a bright orange glow corresponding to at least one of the daytime running light turn signal and the brake EEG indicator. The brake EEG spring may be mounted to the mounting fixture 182 and may include a circuit 212 constructed to activate at least one of the corresponding sources 204 corresponding to a plurality of high intensity LED sources. The ISIE source 204 may be activated in response to at least one control signal received from the controller. The combined springs 102 may be in communication with the wiring harness 186 and the separate circuit 212. The circuit 212 may be positioned within an internal cavity 214 formed by the housing 176 and the mounting fixture 182 and one or more bracket 218 arms 216 located within the cavity 214. As mentioned herein, the lighting device 178 allows the first combined spring E1q and brake E1 200 to be selectively activated by the controller for the respective spring E1q from the housing 176 to illuminate a light coming from the lighting device 178. See FIG. 11. Lighting device 10. A corresponding block diagram is shown. Controller 222 may be in the form of EQI generators via the data buses (EQ56, 58) mentioned herein. Communication data bus 226 may be configured to provide signals to controller 222 that describe various vehicle states. For example, communication data bus 226 may be configured to provide signals to controller 222 that describe vehicle drive selection, ignition status, driving or racing status, lighting status, braking status, remote activation of lighting device 10, or any other information or control signal that may be utilized in manually activating the lighting device. Although controller 222 is not described herein, in some embodiments, lighting device 10 may be activated electrically or electromechanically in response to a switch by at least one key. Controller 222 may include a processor 228 comprising one or more circuits configured to receive signals from communication bus 226 and send signals to control lighting devices 10 to control the various emission indicators and the like mentioned herein. Processor 228 may be in communication with a memory 230 configured to store commands to control activation of lighting device 10. The controller 222 may also communicate with a separate ambient EI sensor 232. The ambient EI sensor 232 may be operated to send or receive, for example, a lighting condition such as a brightness level or intensity of the ambient EI of the vehicle 12. Alternatively, the controller 222 may be configured to adjust an EI intensity to be determined by the EI generating devices, layers, emitters, and/or EI sources referred to herein. The intensity of the EI operating at the lighting devices 10 may be adjusted by controlling a duty cycle, voltage, or voltage fed to the lighting devices 10 by the controller 222. For the purposes of explaining and defining present teachings, care should be taken to indicate the degree of inherent uncertainty attributed to representations. The terms "substantially" and "approximately" are used here to express the degree of change that a quantitative representation can show from a stated reference without causing a change in the essential function of the subject matter. It is to be understood that changes and modifications may be made to the above-mentioned structure without departing from the concepts of the present invention. It is to be understood that such concepts are intended to be covered by the following claims unless expressly stated otherwise in the claims.

Claims (1)

1.