A light emitting sign apparatus including an optical fiber includes: an outer frame including an accommodation space having an opened front side; a front panel covering the front side of the outer frame, the front panel including first front emission holes; a light source module located in the accommodation space, the light source module including at least one light source; first front optical fibers having one ends connected to the first front emission holes and the other ends optically coupled to the at least one light source; at least one outer illumination sensor located in the accommodation space; and outer optical fibers having one ends connected outer emission holes provided in the outer frame and the other ends optically coupled to the at least one outer illumination sensor.

The present invention provides a product with incorporated operation display panel that further improves visibility at the time of light emission. The product with incorporated operation display panel includes a transparent conductive sheet, a display panel with a touch sensor furnished at least with light emitting elements consisting of light emitting elements arranged in two dimensions and being the product with incorporated operation display panel furnished with a thin layer that covers the total or a part of the front surface of a display panel, and a transparent substrate that forms a light guiding path is disposed at an opening between a transparent conductive sheet and a thin layer, or at an opening between a transparent conductive sheet and a light emitting device array substrate. The transparent base has micropores provided in a resin base material made of a transparent resin, and the micropores are formed by a lattice-like louver.

A display system comprises a screen having a concave spherical surface positioned so as to be visible to a user of the system. The screen comprises a plurality of kite-shaped screen elements supported adjacent one another so as to form that spherical surface. Each of the screen elements comprises a respective faceplate comprising optical fibers extending adjacent each other so as to transmit light therethrough between two opposing face surfaces. One of the face surfaces is a concave spherical display image output surface, and the other of the face surfaces is a substantially planar image input surface. The screen elements also each comprise a respective image panel having a field of pixels each transmitting light corresponding to serial images of said panel. The fibers of the faceplate receive the light of the pixels of the image panel and together transmit the light from the image panel coherently to its image output surface so that the images of the panel are displayed on the image output surface.

A smart safety garment with signal lights includes a basic garment, at least a pair of turn signal lights embedded on the external surface of the basic garment, and an electronic assembly for the control. The management and monitoring of the smart safety garment includes a control unit, the at least a pair of turn signal lights being connected or connectable to the control unit. The electronic assembly further includes a braking sensor connected or connectable to the control unit and adapted to perceive a deceleration and to generate a corresponding braking signal intended to the control unit. The control unit is configured to power up at least a pair of turn signal lights according to the braking signal.

A smart safety garment with signal lights includes a basic garment, at least a pair of turn signal lights embedded on the external surface of the basic garment, and an electronic assembly for the control. The management and monitoring of the smart safety garment includes a control unit, the at least a pair of turn signal lights being connected or connectable to the control unit. The electronic assembly further includes a braking sensor connected or connectable to the control unit and adapted to perceive a deceleration and to generate a corresponding braking signal intended to the control unit. The control unit is configured to power up at least a pair of turn signal lights according to the braking signal.

An input device, an optical coupler having a receiver, a processor, and one or more light emitting diodes, a light conductive material such as a bundle of optical fibers, and a connector connecting the optical coupler to the light conductive material such as a bundle of fiber optic fibers is provided. The receiver receives data from the input device that relates to lighting effects having predetermined routine or graphic patterns. The processor converts the data into instructions for the light emitting diodes to form the predetermined graphic patterns, color routines and intensities. The light emitting diodes produce light for transmission through the connector to the light conductive material such as a bundle of fiber optic fibers so that the bundle of fiber optic fibers can produce the predetermined light patterns, routines, intensities or graphic patterns.

An input device, an optical coupler having a receiver, a processor, and one or more light emitting diodes, a light conductive material such as a bundle of optical fibers, and a connector connecting the optical coupler to the light conductive material such as a bundle of fiber optic fibers is provided. The receiver receives data from the input device that relates to lighting effects having predetermined routine or graphic patterns. The processor converts the data into instructions for the light emitting diodes to form the predetermined graphic patterns, color routines and intensities. The light emitting diodes produce light for transmission through the connector to the light conductive material such as a bundle of fiber optic fibers so that the bundle of fiber optic fibers can produce the predetermined light patterns, routines, intensities or graphic patterns.

A light emitting sign apparatus using an optical fiber includes: a front panel including a plurality of emission holes; a plurality of optical fibers having one ends respectively connected to the plurality of emission holes and the other ends constituting a concentrated bundle; and a light source assembly including a plurality of light emitting diodes optically coupled to the other ends of the plurality of optical fibers, wherein the plurality of light emitting diodes are located on a plane. Each of the plurality of light emitting diodes belongs to any one of a plurality of groups, one ends of the plurality of groups are connected to the same node, and different power voltages are applied to the other ends of the plurality of groups.

A dynamic sign, and method for manufacture thereof, is provided. The sign comprises a display comprising at least one dynamic display surface configured for projecting dynamic graphical elements. The sign also comprises a perforated mask superposed on the at least one dynamic display surface of the display, the mask comprising at least one opening formed therein. The sign further comprises at least one optical guide inserted into the at least one opening, the at least one optical guide positioned for carrying light from the display through the at least one opening and allowing the dynamic graphical elements to be seen therethrough.

An optical member for a multi-panel display device includes a first optical member located on a first display device and including optical fibers; a second optical member located on a second display device neighboring the first display device and including optical fibers; and an optical fiber triangular bar located to overlap a region where the first and second optical members are adjacent to each other, and including optical fibers, wherein each of the first and second optical members includes a chamfer portion corresponding to the optical fiber triangular bar at the region where the first and second optical members are adjacent to each other.