Disclosed herein is a projector sunshade for projecting an image of a logo onto a surface. The projector sunshade includes a UV-treated sheet, a first area on the UV-treated sheet including a shape of the logo, the first area being substantially transparent to light from an illumination source; and a second area surrounding the first area and including a lower transparency to the light relative to the first area.

A balloon comprises a printed display. The printed display comprises: a printed image layer; a blocking layer provided behind selected portions of the printed image layer; and a diffusion layer provided behind at least those portions of the printed image layer not backed by the blocking layer. The blocking layer acts to block illumination of portions of the printed image layer, such that the printed display provides a different appearance when lit primarily from inside the balloon to when lit primarily from outside the balloon.

A balloon comprises a printed display. The printed display comprises: a printed image layer; a blocking layer provided behind selected portions of the printed image layer; and a diffusion layer provided behind at least those portions of the printed image layer not backed by the blocking layer. The blocking layer acts to block illumination of portions of the printed image layer, such that the printed display provides a different appearance when lit primarily from inside the balloon to when lit primarily from outside the balloon.

An invisible, light-transmissive display system with a light resistant material is provided. Substantially invisible, tapered, light-transmissive holes are penetrated in a lighttransmissive pattern through at least a portion of the light resistant material using a laser beam having a focal width less than the smallest diameter of the tapered holes.

An invisible, light-transmissive display system with a light resistant material is provided. Substantially invisible, tapered, light-transmissive holes are penetrated in a lighttransmissive pattern through at least a portion of the light resistant material using a laser beam having a focal width less than the smallest diameter of the tapered holes.

Embodiments are directed to an electronic device having a hidden or concealable input region. In one aspect, an embodiment includes an enclosure having a wall that defines an input region having an array of microperforations. A light source may be positioned within a volume defined by the enclosure and configured to propagate light through the array of microperforations. A sensing element may be coupled with the wall and configured to detect input received within the input region. The array of microperforations are configured to be visually imperceptible when not illuminated by the light source. When illuminated by the light source, the array of microperforations may display a symbol.

Embodiments are directed to an electronic device having a hidden or concealable input region. In one aspect, an embodiment includes an enclosure having a wall that defines an input region having an array of microperforations. A light source may be positioned within a volume defined by the enclosure and configured to propagate light through the array of microperforations. A sensing element may be coupled with the wall and configured to detect input received within the input region. The array of microperforations are configured to be visually imperceptible when not illuminated by the light source. When illuminated by the light source, the array of microperforations may display a symbol.

Systems and methods for presenting images on mirrored displays are provided. A cover layer having a surface area is positioned in front of an electronic display having a viewing area and illumination elements. A reflective material is located at the cover layer and is less than fully silvered where the cover layer is located above the viewing area. A power level supplied to said illumination elements is increased after a sensor detects a person proximate to the mirrored display.

Systems and methods for presenting images on mirrored displays are provided. A cover layer having a surface area is positioned in front of an electronic display having a viewing area and illumination elements. A reflective material is located at the cover layer and is less than fully silvered where the cover layer is located above the viewing area. A power level supplied to said illumination elements is increased after a sensor detects a person proximate to the mirrored display.

An attenuation portion is to illuminate first and second display objects while attenuating light. A display element causes light to enter the attenuation portion to illuminate the first display object in a display region. A light source irradiates light to illuminate the second display object in the display region. A display forming member has a light-blocking layer and an attenuation layer. The light-blocking layer has a light-transmitting portion defining a shape of the second display object. The attenuation layer covers the light-blocking layer from a display region side to attenuate light, which is from the light source and passes through the light-transmitting portion. The display forming member indicates the second display object in the display region with emission of light which is attenuated through the attenuation layer and enters the attenuation portion.