Abstract: A manufacturing method of an electronic device is disclosed by the present disclosure. The manufacturing method includes providing a substrate, wherein the substrate includes a plurality of working areas, and each of the plurality of working areas includes a plurality of first recesses and a plurality of second recesses; disposing a plurality of first electronic units in the plurality of first recesses of the plurality of working areas through fluid transfer; identifying a defective working area from the plurality of working areas, wherein at least one of the plurality of first recesses of the defective working area has no electronic unit or a defective first electronic unit disposed therein; and disposing at least one repairing electronic unit in at least one of the plurality of second recesses of the defective working area through laser transfer.

Abstract: A display device includes a first substrate, a light-emitting element, a light conversion layer, and a color filter layer. The light-emitting element is disposed on the first substrate. The light conversion layer is disposed on the light-emitting element. In addition, the color filter layer is overlapped the light-emitting element and the light conversion layer.

Abstract: An absorption type near-infrared filter comprising a first multilayer film, a second multilayer film, and an absorption film, wherein in the ultraviolet band, the difference of between the wavelength with the transmittance at 80% of the absorbing film and the wavelength with the reflectivity at 80% of the first multilayer film falls in the range between 25 nm and 37 nm, the difference of between the wavelength with the transmittance at 50% of the absorbing film and the wavelength with the reflectivity at 50% of the first multilayer film falls in the range between 6 nm and 14 nm, and the difference of between the wavelength with the transmittance at 20% of the absorbing film and the wavelength with the reflectivity at 20% of the first multilayer film falls in the range between ?6 nm and 2.5 nm.

Abstract: An electronic device and a manufacturing method thereof are provided. The manufacturing method of the electronic device includes the following. A substrate is provided. A plurality of electronic units are transferred to the substrate. The electronic units are inspected to obtain M first defect maps. The M first defect maps are integrated into N second defect maps, where N<M. M repairing groups are provided according to the N second defect maps. Each of the repairing groups includes at least one repairing electronic unit. The M repairing groups are transferred to the substrate. At least two of the repairing groups have the same location distribution of repairing electronic units, and the location distribution is consistent with a defect distribution of one of the second defect maps.

Abstract: A pharmaceutical composition containing a mixed polymeric micelle and a drug enclosed in the micelle, in which the mixed polymeric micelle, 1 to 1000 nm in size, includes an amphiphilic block copolymer and a lipopolymer. Also disclosed are preparation of the pharmaceutical composition and use thereof for treating cancer.

Abstract: A touch device includes a display panel, a conductive layer, and a first touch substrate. The display panel includes a first substrate. The conductive layer is disposed on a first surface of the first substrate. The first touch substrate is disposed on the conductive layer and includes a first touch electrode.

Abstract: An electronic device is provided, including a functional layer, a touch layer, and a protective layer. The touch layer includes at least one touch electrode, and is disposed between the functional layer and the protective layer. The protective layer includes a bottom surface and a top surface. The bottom surface faces the touch layer, and the top surface is opposite to the bottom surface. The top surface includes an inner region, an outer region, and a virtual knob portion. The virtual knob portion is disposed between the inner region and the outer region and corresponds to the touch electrode, and at least a portion of the virtual knob portion protrudes from the outer region or is depressed relative to the outer region.

Abstract: An electronic device is provided, including a functional layer, a touch layer, and a protective layer. The touch layer includes at least one touch electrode, and is disposed between the functional layer and the protective layer. The protective layer includes a bottom surface and a top surface. The bottom surface faces the touch layer, and the top surface is opposite to the bottom surface. The top surface includes an inner region, an outer region, and a virtual knob portion. The virtual knob portion is disposed between the inner region and the outer region and corresponds to the touch electrode, and at least a portion of the virtual knob portion protrudes from the outer region or is depressed relative to the outer region.

Abstract: A display device includes a plurality of first array electrodes, a plurality of second array electrodes, a first switch module electrically connected to the first array electrodes, a second switch module electrically connected to the second array electrodes, a first sensing module electrically connected to the second switch module, and a second sensing module electrically connected to both the first and the second switch modules. When the distance between the display device and a detected object is greater than zero, the first array electrodes receive a first touch driving signal, and the second array electrodes send a first sensing signal to the first sensing module. When the distance is equal to zero, the first array electrodes and the second array electrodes receive a second touch driving signal and send a second sensing signal to the second sensing module.

Abstract: A display device includes a plurality of first array electrodes, a plurality of second array electrodes, a first switch module electrically connected to the first array electrodes, a second switch module electrically connected to the second array electrodes, a first sensing module electrically connected to the second switch module, and a second sensing module electrically connected to both the first and the second switch modules. When the distance between the display device and a detected object is greater than zero, the first array electrodes receive a first touch driving signal, and the second array electrodes send a first sensing signal to the first sensing module. When the distance is equal to zero, the first array electrodes and the second array electrodes receive a second touch driving signal and send a second sensing signal to the second sensing module.

Abstract: An adaptive timing controller, including a receiver, a frame buffer, a data format check circuit and a data converting unit, is provided. The receiver is used for receiving image data of an image frame. The frame buffer is used for temporarily storing the image data. The data format check circuit is used for detecting display types of the image data and a 3D display panel. The data converting unit is sued for rearranging the image data into rearranged image data corresponding to the display type of the 3D display panel.

Abstract: A liquid crystal display includes sub-pixels each having a first display field and a second display field that both operate in a transmissive mode or both operate in a reflective mode. The first and second display fields of a sub-pixel are driven by a same driving device. The first and second display fields of a sub-pixel have different characteristics that cause liquid crystal layers in the first and second display fields to have different transmittances, the difference in transmittances of the first and second display fields being larger than a predetermined value.

Abstract: An electronic device includes a circuit board and a heat insulating structure. The heat insulating structure includes a heat source, an enclosure for covering the heat source, and a heat insulating plate disposed on a side of the enclosure facing to the heat source for preventing heat generated by the heat source from directly transmitting toward the enclosure, and a space being formed between the heat insulating plate and the enclosure. The heat insulating structure further includes a thermal conductive layer disposed on a side of the heat insulating plate facing to the heat source. The heat insulating structure further includes the thermal conductive layer disposed on a side of the heat insulating plate facing to the enclosure. Therefore, the heat insulating plate can be for altering heat current generated by the heat source so as to dissipate the heat current via holes on the enclosure uniformly.

Abstract: A gray-scale circuit may receive pixel data to generate first set of gray-scale voltages that enable a display show the different gray-scale levels of normal images during a first time period. The gray-scale circuit may generate a second set of gray-scale voltages to enable the display show a common gray-scale level during a second time period.

Abstract: A liquid crystal display includes sub-pixels each having a first display field and a second display field that both operate in a transmissive mode or both operate in a reflective mode. The first and second display fields of a sub-pixel are driven by a same driving device. The first and second display fields of a sub-pixel have different characteristics that cause liquid crystal layers in the first and second display fields to have different transmittances, the difference in transmittances of the first and second display fields being larger than a predetermined value.

Abstract: A gray-scale circuit may receive pixel data to generate first set of gray-scale voltages that enable a display show the different gray-scale levels of normal images during a first time period. The gray-scale circuit may generate a second set of gray-scale voltages to enable the display show a common gray-scale level during a second time period.

Abstract: An S8ED system is implemented in a memory system to detect single errors involving one or more bits in a byte of subject data, stored in and retrieved from the memory system. Relationships between the subject data and parity data, which are used to detect errors in the subject data, are defined by a novel check matrix. The novel check matrix includes a number of constituent matrices, each of which includes eight (8) vectors. Each vector of a constituent matrix (i) has a number of elements which is equal to the number of parity bits used to detect errors in the subject data; (ii) is a concatenation of a building block vector, one or more instances of one of two base generating vectors, and one or more instances of the other of the two base generating vectors; and (iii) is distinct from all other vectors of the same constituent matrix.