Abstract: A method for displaying an image is disclosed. An image is provided by a display, the image is located at a virtual image surface, and the image has an offset between different view directions. A controller is coupled to the display. The controller receives an information of the position of the vergence surface, performs an algorithm processing according to the information to obtain the offset, and transmits a display information including the offset to the display. An eye of the user focuses on an accommodation surface when viewing the image, and a position of the accommodation surface is different from a position of the virtual image surface.

Abstract: A display method of a display disposed in a vehicle includes following steps. Providing a first image by the display onto a glass of the vehicle at a first position, and a first virtual image is formed outside the glass when a user views the first image. Providing a second image by the display onto the glass at a second position, a second virtual image is formed outside the glass when the user views the second image, the first virtual image, the second virtual image and an environmental scene are located within a field of view of the user, and the first position is different from the second position.

Abstract: The invention provides a three-dimensional (3D) image display method and a display device with a 3D image display function. The 3D image display method includes the following. A display device coordinate system is established. First volume data is obtained, and multiple first coordinates of multiple voxels of the first volume data in an absolute space coordinate system are defined. The multiple first coordinates of the multiple voxels of the first volume data are converted to the display device coordinate system to generate second volume data. Display data is generated according to the second volume data. An image is displayed according to the display data through the display device, and the image forms a 3D image with a 3D object image in human eyes, in which the 3D object image changes equally or proportionally in response to a change desired by a user through an input unit.

Abstract: A three-dimensional image display method and a display device with a three-dimensional image display function are provided. The three-dimensional image display method includes following steps: obtaining first volume data and defining a plurality of coordinates of a plurality of voxels in the first volume data in a display device coordinate system to generate second volume data; obtaining two first eye coordinates and converting the two first eye coordinates to the display device coordinate system to generate two second eye coordinates; calculating a plurality of ray paths corresponding to a plurality of pixels of the display device; matching the ray paths with the two second eye coordinates to determine a plurality of ray casting paths; determining a plurality of sampling data corresponding to the pixels according to the second volume data and the ray casting paths to generate display data.

Abstract: A display method of an image is disclosed. A position of a vergence surface of a user is obtained through a gaze tracking device. An image is provided by a display, the image is located at a virtual image surface, and the image has an offset between different view directions. A controller is coupled to the gaze tracking device and the display. The controller receives an information of the position of the vergence surface obtained through the gaze tracking device, performs an algorithm processing according to the information to obtain the offset, and transmits a display information including the offset to the display. An eye of the user focuses on an accommodation surface when viewing the image, and a position of the accommodation surface is different from a position of the virtual image surface.

Abstract: A display method of an electronic device includes following steps. Providing a first image by a display, and a first vergence plane of two eyes of a user is located at a first position when the user views the first image. Providing a second image by the display, and the first image, the second image and an environmental scene are located within a field of view of the user, and a second vergence plane of the two eyes of the user is located at a second position when the user views the second image. A first distance exists between the first position of the first vergence plane and the user, a second distance exists between the second position of the second vergence plane and the user, and the first distance is different from the second distance.

Abstract: A display method of an electronic device includes following steps. Providing a first image by a display, and a first vergence plane of two eyes of a user is located at a first position when the user views the first image. Providing a second image by the display, and the first image, the second image and an environmental scene are located within a field of view of the user, and a second vergence plane of the two eyes of the user is located at a second position when the user views the second image. A first distance exists between the first position of the first vergence plane and the user, a second distance exists between the second position of the second vergence plane and the user, and the first distance is different from the second distance.

Abstract: A display method of an image is disclosed. A position of a vergence surface of a user is obtained through a gaze tracking device. An image is provided by a display, the image is located at a virtual image surface, and the image has an offset between different view directions. A controller is coupled to the gaze tracking device and the display. The controller receives an information of the position of the vergence surface obtained through the gaze tracking device, performs an algorithm processing according to the information to obtain the offset, and transmits a display information including the offset to the display. An eye of the user focuses on an accommodation surface when viewing the image, and a position of the accommodation surface is different from a position of the virtual image surface.

Abstract: A display method of an image is disclosed. A first vergence plane of two eyes of a user is located at a first position when the user views a first image. A second vergence plane of the two eyes is located at a second position when the user views an object in the environmental scene. A first distance existing between the first position and the user and a second distance existing between the second position and the user satisfy a first relation: Dn<D1<Df. D1 represents the first distance, Dn=D2+?n, Df=D2+?f, D2 represents the second distance, ?n=(De/2)*{tan[tan?1(2*D2/De)??]}?D2, ?f=(De/2)*{tan[tan?1(2*D2/De)+?]}?D2, De represents a distance between the two eyes, ? represents an eye angular resolution of the two eyes, and ?=0.02 degrees.

Abstract: The disclosure provides an electronic device and a display method thereof. The electronic device includes a display panel and a light source module. The light source module is disposed at a side of the display panel. The light source module includes a first group of light-emitting units and a second group of light-emitting units that are alternately arranged, wherein the first group of light-emitting units and the second group of light-emitting units emit a light alternately, and each of a plurality of display pixels is adapted to alternately receive the light from the first group of light-emitting units and the second group of light-emitting units.

Abstract: A display method of an image is disclosed. A first vergence plane of two eyes of a user is located at a first position when the user views a first image. A second vergence plane of the two eyes is located at a second position when the user views an object in the environmental scene. A first distance existing between the first position and the user and a second distance existing between the second position and the user satisfy a first relation: Dn<D1<Df. D1 represents the first distance, Dn=D2+?n, Df=D2+?f, D2 represents the second distance, ?n=(De/2)*{tan[tan?1(2*D2/De)??]}?D2, ?f=(De/2)*{tan[tan?1(2*D2/De)+?]}?D2, De represents a distance between the two eyes, ? represents an eye angular resolution of the two eyes, and ?=0.02 degrees.

Abstract: A light source module includes a quantum dot cell, a light emitting element, and an adhesive layer. The quantum dot cell includes a first glass substrate, a second glass substrate, a quantum dot region, and a reflective sealant disposed between the first glass substrate and the second glass substrate and surrounding the quantum dot region. The light emitting element is disposed at a side of the first glass substrate opposite to the quantum dot region and emits a light with a specific wavelength range. The quantum dot material in the quantum dot region converts the light with the specific wavelength range into another wavelength range. The adhesive layer is disposed at an outer side of the light emitting element for attaching the light emitting element to a surface of the first glass substrate.

Abstract: A light source module includes a quantum dot cell, a light emitting element, and an adhesive layer. The quantum dot cell includes a first glass substrate, a second glass substrate, a quantum dot region, and a reflective sealant disposed between the first glass substrate and the second glass substrate and surrounding the quantum dot region. The light emitting element is disposed at a side of the first glass substrate opposite to the quantum dot region and emits a light with a specific wavelength range. The quantum dot material in the quantum dot region converts the light with the specific wavelength range into another wavelength range. The adhesive layer is disposed at an outer side of the light emitting element for attaching the light emitting element to a surface of the first glass substrate.

Abstract: A patterned color conversion film and a display device using the same are disclosed. The patterned color conversion film of the present invention comprises: a separator with plural openings; and plural pixel units disposed in the openings respectively, each pixel unit respectively comprising: a medium and scattering particles dispersed therein. Herein, at least one of the plural pixel units comprises quantum dots having the scattering particles sized of between 0.05 and 1 ?m when a volume concentration of the quantum dots is in a range more than or equal to 5% and less than or equal to 80%, or having the scattering particles sized of between 0.2 and 2 ?m when the volume concentration of the quantum dots is in a range less than 5% and more than or equal to 0%.

Abstract: A patterned color conversion film and a display device using the same are disclosed. The patterned color conversion film of the present invention comprises: a separator with plural openings; and plural pixel units disposed in the openings respectively, each pixel unit respectively comprising: a medium and scattering particles dispersed therein. Herein, at least one of the plural pixel units comprises quantum dots having the scattering particles sized of between 0.05 and 1 ?m when a volume concentration of the quantum dots is in a range more than or equal to 5% and less than or equal to 80%, or having the scattering particles sized of between 0.2 and 2 ?m when the volume concentration of the quantum dots is in a range less than 5% and more than or equal to 0%.

Abstract: A patterned color conversion film is disclosed, which comprises a plurality of pixels made of a fluorescent material; and a plurality of white matrices made of a reflective material such as a white material or metal. The fluorescent film includes a light-input surface and a light-output surface, and the plurality of white matrixes is provided between two adjacent pixels respectively.

Abstract: A liquid crystal panel, a driving method thereof, and a liquid crystal display device containing the same are disclosed. The liquid crystal panel of the present invention comprises: a first substrate having a first electrode layer; a second substrate having a second electrode layer opposite to the first electrode layer; a blue-phase liquid crystal layer disposed between the first substrate and the second substrate; and a light-shielding region disposed on the second substrate. When a bias voltage is applied to the first electrode layer and the second electrode layer, a refractive gradient is formed in the blue-phase liquid crystal layer, and thereby an incident light passing through the blue-phase liquid crystal layer focuses on the light-shielding region.