An overlay panel that includes a front display portion arranged over surface area of a display device. The overlay panel further includes a guiding portion that comprises light guides arranged in a specific pattern. The light guides are arranged such that an input portion of each light guide is aligned with pixels or sub-pixels of the display device and an output portion of each light guide is coupled to the front display portion. The arrangement of each light guide transfers an excitation, caused by the set of pixels or sub-pixels, from the input portion to the output portion and causes the front display portion to display an image that covers a bezel portion and the display portion of the display device. Each pixel in the image is scaled by an equal scaling factor with respect to each pixel in display portion.

Disclosed is a display apparatus including a display panel; and a light source assembly including: a plurality of first light sources disposed in a first region to supply first light toward the display panel; a light guide plate including: incident surface configured to receive second light; and an exit surface facing the display panel and configured to transmit the second light received from the incident surface of the light guide plate to the display panel; and a plurality of second light sources disposed on a periphery of the first region to supply the second light to the incident surface of the light guide plate.

A lighting and/or signalling device, in particular for the automotive sector, comprising: at least two LED light sources, powered and activated separately, each facing a respective light input wall of a corresponding light guide, wherein the light guides emit the light of the LED light sources through at least two separate lighting portions at a front wall. The light guides are equipped with diffuser elements arranged on a rear wall opposite to the front wall. At least one reflector element is associated with each light guide directly facing the respective diffuser elements so as to reflect the light towards the front wall. The light guides are juxtaposed and adjacent to each other at at least one respective inner wall. The light guides are mechanically and optically separated by barrier elements which prevent the passage of light between the light guides at the at least one inner wall.

The present disclosure is directed to multicolored transparent displays. In some aspects, the systems and methods disclosed herein make use of light guides that operate on the principle of total internal reflection. Light can be extracted from the light guide by altering the interface at the surface of the light guide. A display can include a light guide having a plurality of pixels on a surface of the light guide. The display can also include a light source configured to introduce light into an edge of the light guide at a first angle greater than a critical angle for total internal reflection within the light guide, such that a portion of the light is extracted from the light guide by the plurality of pixels and is directed out of the viewing side of the display.

A waveguide display includes a first diffractive input waveguide operable to receive input data from a first projector and diffract image data associated with the first projector at a first angular offset and a second diffractive input waveguide operable to receive input data from a second projector and diffract image data associated with the second projector at a second angular offset. The waveguide display also includes a diffractive output waveguide optically coupled to the first diffractive input waveguide and the second diffractive input waveguide. The diffractive output waveguide receives the image data associated with the first projector and image data associated with the second projector and is operable to direct image data associated with the first projector toward a first field of view and direct image data associated with the second projector toward a second field of view.

The present application discloses a dual-color laser light projection device, wherein the dual-color laser light projection device includes a first blue laser transmitter, a second blue laser transmitter, a red laser transmitter, a light combining component, a fluorescent wheel, a light-pipe; wherein the fluorescent wheel comprises a green fluorescent region provided with a green fluorescent powder and a transmission region, and wherein the green fluorescent region is excited by a first blue laser emitted from the first blue laser transmitter to generates green fluorescence. The light path system of the present application is simple and has a small volume.

An overlay panel that includes a front display portion arranged over surface area of a display device. The overlay panel further includes a guiding portion that comprises light guides arranged in a specific pattern. The light guides are arranged such that an input portion of each light guide is aligned with pixels or sub-pixels of the display device and an output portion of each light guide is coupled to the front display portion. The arrangement of each light guide transfers an excitation, caused by the set of pixels or sub-pixels, from the input portion to the output portion and causes the front display portion to display an image that covers a bezel portion and the display portion of the display device. Each pixel in the image is scaled by an equal scaling factor with respect to each pixel in display portion.

The present invention relates to an optical filter (100) comprising a substantially flat entry surface (101), a substantially flat exit surface (102) parallel to the entry surface, a plurality of channels (103) made of a material substantially transparent to light, wherein the channels (103) of the plurality of channels comprise an entry face (104), an exit face (105) and a lateral surface extending perimetrically between the entry face (104) and the exit face (105) over a length (L) of the channels (103), are arranged side by side and parallel to each other so as to define a plurality of interspaces between adjacent channels (103), have a channel axis (Y) incident to the entry (101) and exit (102) surface, and are arranged with the entry face (104) substantially overlapping the entry surface (101) and with the exit face (105) substantially overlapping the exit surface (102), at least one element of optically absorbing and/or non-transparent material (108, 109; 109) configured and arranged with respect to the channels (103) so as to reduce and/or substantially prevent the passage of light between adjacent channels (103) of the plurality of channels and so as to reduce the passage of light parallel to the channels and externally thereto, or at least a first element of optically absorbing material (108) configured and arranged with respect to the channels (103) so as to reduce and/or substantially prevent the passage of light between adjacent channels (103) of the plurality of channels (103) and at least a second element of optically non-transparent material (109; 109) configured and arranged with respect to channels (103) so as to reduce and/or substantially prevent the passage of light parallel to the channels (103) and externally thereto through interspaces between adjacent channels (103); wherein the channels (103) have a refractive index whose value decreases starting from a maximum refractive index (na) along a radially outward direction away from the channel axis (Y) passing through a centre of gravity of a section of the respective channel (103), so as to define a radial profile of refractive index of the channels, and wherein the radial profile of refractive index of the channels (103) is configured such that the light rays crossing any channel (103) of the plurality of channels and belonging to a beam of rays emerging from any point on an edge of an entry face (104) of the channel exit the exit face (105) of the ch

The present application provides a display panel and an electronic device. A first sub-backlight module is arranged in a display area of the display panel, and a second sub-backlight module is arranged in an electronic component area. A light guide plate of the second sub-backlight module can be switched between a light-scattering state and a transparent state, so that the electronic component area can display images and take photos. The first light-shielding member is arranged in an accommodating space defined by the display panel body and the backlight module to avoid light leakage during shooting, so that full-screen display can be realized without light leakage.

The present application provides a display panel and an electronic device. A first sub-backlight module is arranged in a display area of the display panel, and a second sub-backlight module is arranged in an electronic component area. A light guide plate of the second sub-backlight module can be switched between a light-scattering state and a transparent state, so that the electronic component area can display images and take photos. The first light-shielding member is arranged in an accommodating space defined by the display panel body and the backlight module to avoid light leakage during shooting, so that full-screen display can be realized without light leakage.