A display device (1) includes a light-emitting device (10), a reflective liquid crystal element (20), and an optical member (30). The light-emitting device (10) includes a plurality of light-emitting units (142) and a light-transmitting unit (144) located between the light-emitting units (142) adjacent to each other. The light-emitting device (10) is located between the reflective liquid crystal element (20) and the optical member (30). The plurality of light-emitting units (142) emit light toward the reflective liquid crystal element (20). The light emitted from the plurality of light-emitting units (142) is reflected by the reflective liquid crystal element (20), transmitted through the light-emitting unit (142) of the light-emitting device (10), and formed into an image by the optical member (30).

This display device includes n number of liquid crystal displays, where n is an integer of 2 or more, light sources that can emit light of a plurality of different colors and that are provided to the respective liquid crystal displays, and a processor that causes the light sources to emit light of different colors so as to vary emission start timings for the respective light sources provided to the liquid crystal displays on the basis of input signals including color information regarding sub display images to be displayed on the respective liquid crystal displays.

An object of the present invention is to provide a polarizer, a method of producing a polarizer, a laminate, and an image display device which enable achievement of both the degree of alignment and heat resistance. The polarizer of the present invention is a polarizer formed of a polarizer-forming composition which contains a liquid crystal compound and a dichroic material, in which the liquid crystal compound has a smectic liquid crystallinity, and a phase transition temperature of the polarizer-forming composition from a smectic phase to an isotropic phase or a nematic phase is 120° C. or higher.

Display device includes a flexible substrate, a plurality of pixels disposed on a first surface of flexible substrate, and a plurality of alignment marks disposed along one side of the flexible substrate and identified each other. The plurality of alignment marks may be arranged in the same layer. When the plurality of pixels includes thin film transistor, the plurality of alignment marks may be formed of the same metal layer as the metal layer forming thin film transistor.

A photo sensor circuit includes: a photo transistor; a first switching transistor; a second switching transistor; and a capacitance element. The photo transistor includes: a gate connected to a first wiring; a source connected to a second wiring; and a drain. The first switching transistor includes: a gate connected to a third wiring; a source connected to a fourth wiring; and a drain connected to the drain of the photo transistor. The capacitance element includes: a first terminal connected to the drain of the photo transistor; and a second terminal connected to the source of the first switching transistor. The second switching transistor includes: a gate connected to a gate line; a source connected to a signal line; and a drain connected to the first terminal of the capacitance element. The photo transistor, first switching transistor, and second transistor each include an oxide semiconductor layer as a channel layer.

A method for detecting emitted light from a display screen with a simple configuration and procedure without changing the position of the sensor. A method for detecting emitted light from a display screen of a display apparatus, including: a placement step of placing a photometric part including an optical sensor and a light guide member on a front surface side of the display screen, and a detection step of turning on any area of the display screen, guiding the emitted light from the area to the optical sensor by the light guide member, and detecting the emitted light with the optical sensor without changing the position of the optical sensor.

A display device can display a display image obtained by superimposing a plurality of sub display images, and includes n number of liquid crystal displays, where n is an integer of 2 or more, that display the plurality of sub display images, a light source that is provided for each liquid crystal display and is capable of emitting light of m number of different colors, where m is an integer of 2 or more, and a processor that causes the light source corresponding to the liquid crystal display to emit light of a different color based on an input signal including color information on the display image displayed by each liquid crystal display. The number n of the liquid crystal display is an integral multiple of the number m of color of light that the light source is capable of emitting.

A circuit holding device for a display module and a display device are disclosed. The circuit holding device includes an external circuit terminal component, wherein the external circuit terminal component is disposed external to the display module, and a circuit board is held in the external circuit terminal component, the circuit board and the display module are electrically connected to each other. The circuit holding device can accommodate multiple external circuits in one terminal component, thereby making the connection between the external circuits and the display module easy and convenient.

A liquid crystal display device 10 includes a liquid crystal panel 11 having a display area AA capable of displaying an image and a non-display area NAA outside the display area AA, a flexible board portion 40 having flexibility and connected to the non-display area NAA at a first end 40a thereof, and a rigid board portion 30 connected to a second end 40b of the flexible board portion 40 opposite the first end 40a and configured to supply signals to the liquid crystal panel 11 through the flexible board portion 40. The rigid board portion 30 at least includes a rigid portion 31a having a higher rigidity than the flexible board portion 40, a rigid portion 31b located next to the rigid portion 31a and having a higher rigidity than the flexible board portion 40, and a low rigidity portion 32a located between the rigid portion 31a and the rigid portion 31b and having a lower rigidity than the rigid portion 31a and the rigid portion 31b.

The present invention provides a transparent electroconductive layer-equipped cover element having a pressure-sensitive adhesive sheet preliminarily laminated thereto, wherein the pressure-sensitive adhesive sheet comprises a pressure-sensitive adhesive layer in which a refractive index adjustment zone having a refractive index greater than that of a base pressure-sensitive adhesive material thereof is formed over a given range from a surface of the pressure-sensitive adhesive layer in a thickness direction thereof, whereby: in a lamination process of a customer which is a supply destination of the transparent electroconductive layer-equipped cover element, it becomes possible to eliminate a need to distinguish between obverse and reverse sides of the pressure-sensitive adhesive sheet itself; and, when the transparent electroconductive layer-equipped cover element is bonded to an optical element through the pressure-sensitive adhesive layer, it becomes possible to suppress internal reflection in a laminate formed of these optical elements.