Abstract: A channel hiatus correction method for an HDMI device is provided. A recovery code from scrambled data of the stream is obtained. A liner feedback shift register (LFSR) value of channels of the HDMI port is obtained based on the recovery code and the scrambled data of the stream. The stream is de-scrambled according to the LFSR value of the channels of the HDMI port. Video data is displayed according to the de-scrambled stream.

Abstract: A sweep voltage generator and a display panel are provided. The sweep voltage generator includes an output node, a current generating block and a voltage regulating block. The output node is used to provide a sweep signal. The current generating block is coupled to the output node, includes a detection path for detecting an output load variation on the output node, and adjusts the sweep signal provided by the output node based on the output load variation. The voltage regulating block is coupled to the output node for regulating a voltage of the output node.

Abstract: A channel hiatus correction method for an HDMI device is provided. A recovery code from scrambled data of the stream is obtained. A liner feedback shift register (LFSR) value of channels of the HDMI port is obtained based on the recovery code and the scrambled data of the stream. The stream is de-scrambled according to the LFSR value of the channels of the HDMI port. Video data is displayed according to the de-scrambled stream.

Abstract: A semiconductor-on-insulator (SOI) structure and a method for forming the SOI structure. The method includes forming a first dielectric layer on a first semiconductor layer. A second semiconductor layer is formed over an etch stop layer. A cleaning solution is provided to a first surface of the first dielectric layer. The first dielectric layer is bonded under the second semiconductor layer in an environment having a substantially low pressure. An index guiding layer may be formed over the second semiconductor layer. A third semiconductor layer is formed over the second semiconductor layer. A distance between a top of the third semiconductor layer and a bottom of the second semiconductor layer varies between a maximum distance and a minimum distance. A planarization process is performed on the third semiconductor layer to reduce the maximum distance.

Abstract: A wiring board includes an insulating layer, a wiring layer and a plurality of conductive columns. The insulating layer has a first surface and a second surface opposite to the first surface. The wiring layer is disposed in the insulating layer and has a third surface and a fourth surface opposite to the third surface. The insulating layer covers the third surface, and the second surface of the insulating layer is flush with the fourth surface of the wiring layer. The conductive columns are disposed in the insulating layer and connected to the wiring layer. The conductive columns extend from the third surface of the wiring layer to the first surface of the insulating layer, and protrude from the first surface.

Abstract: Provided is an electrostatic discharge protection circuit, including a first resistor, a first transistor, a second resistor, and a second transistor. The first resistor has a first end coupled to a first power rail. The first transistor has a first end coupled to the first power rail, and a control end of the first transistor is coupled to a second end of the first resistor. The second resistor is coupled between a second end of the first transistor and a second power rail. The second transistor has a first end coupled to the first power rail, a control end of the second transistor is coupled to the second end of the first transistor, and a second end of the second transistor is coupled to the second power rail.

Abstract: Disclosed herein are methods for high-throughput screening of a virus-specific neutralizing antibody. According to certain embodiments of the present disclosure, the virus is an influenza virus. Also disclosed herein are the antibodies selected by the high-throughput screening method, and the uses thereof in the prophylaxis and/or treatment of viral infection.

Abstract: A wiring board includes an insulating layer, a wiring layer and a plurality of conductive columns. The insulating layer has a first surface and a second surface opposite to the first surface. The wiring layer is disposed in the insulating layer and has a third surface and a fourth surface opposite to the third surface. The insulating layer covers the third surface, and the second surface of the insulating layer is flush with the fourth surface of the wiring layer. The conductive columns are disposed in the insulating layer and connected to the wiring layer. The conductive columns extend from the third surface of the wiring layer to the first surface of the insulating layer, and protrude from the first surface.

Abstract: Disclosed herein are methods for high-throughput screening of a virus-specific neutralizing antibody. According to certain embodiments of the present disclosure, the virus is an influenza virus. Also disclosed herein are the antibodies selected by the high-throughput screening method, and the uses thereof in the prophylaxis and/or treatment of viral infection.

Abstract: An embodiment provides a variable gain amplifying method includes: on a signal path of a radio frequency input signal, amplifying a radio frequency input signal by a plurality of serially-coupled amplifiers; steering currents from the amplifiers and controlling respective gains of the amplifiers; performing gain match on the signal path of the radio frequency input signal; and performing phase compensation on the signal path of the radio frequency input signal. The signal path of the radio frequency input signal further has first and second phase variation trends which compensate each other.

Abstract: An embodiment provides a variable gain amplifying method includes: on a signal path of a radio frequency input signal, amplifying a radio frequency input signal by a plurality of serially-coupled amplifiers; steering currents from the amplifiers and controlling respective gains of the amplifiers; performing gain match on the signal path of the radio frequency input signal; and performing phase compensation on the signal path of the radio frequency input signal. The signal path of the radio frequency input signal further has first and second phase variation trends which compensate each other.

Abstract: A touch display panel includes a display panel, a touch panel, an optical film and an adhesive layer. The display panel includes a first substrate and a second substrate. The first substrate and the second substrate are disposed oppositely along a first direction. The touch panel is disposed over the display panel along the first direction. The optical film is disposed between the second substrate and the touch panel along the first direction. The adhesive layer is disposed on the outside of the optical film and adheres to the second substrate and the touch panel. A touch display device and a display device are also disclosed.

Abstract: A method of forming bifacial solar cell structure is described. The method comprises: performing boron diffusion on an upper surface of a semiconductor substrate to form a P+ region and a boron silicon glass (BSG) layer on the P+ region; stripping the BSG layer to expose the P+ region and stripping a blocking layer on a lower surface of the semiconductor substrate simultaneously; forming a first anti-reflection coating layer on the P+ region; forming sacrifice film on the first anti-reflection coating layer; performing phosphorus diffusion on the lower surface to form an N+ region and a phosphorus silicon glass (PSG) layer on the N+ region; stripping the PSG layer on the N+ region to expose the N+ region and stripping the sacrifice film on the first anti-reflection coating layer simultaneously; and forming a second anti-reflection coating layer on the N+ region.

Abstract: An electrode structure is disclosed in the present invention and includes a first conductive electrode and a second conductive electrode. The first conductive electrode includes a first busbar electrode member and a first finger electrode member. A portion of the first busbar electrode member above a first diffusion pattern is electrically contacted with the first diffusion pattern by first contact points. A portion of the second busbar electrode above a second diffusion pattern is electrically contacted with the second diffusion pattern by second contact points. The first finger electrode and the second finger electrode are respectively and electrically contacted with the first diffusion pattern and the second diffusion pattern.

Abstract: A touch display panel includes a display panel, a touch panel, an optical film and an adhesive layer. The display panel includes a first substrate and a second substrate. The first substrate and the second substrate are disposed oppositely along a first direction. The touch panel is disposed over the display panel along the first direction. The optical film is disposed between the second substrate and the touch panel along the first direction. The adhesive layer is disposed on the outside of the optical film and adheres to the second substrate and the touch panel. A touch display device and a display device are also disclosed.

Abstract: A back contact solar cell includes a first main busbar electrode, a second main busbar electrode, a plurality of first finger electrodes and a plurality of second finger electrodes, all of which are disposed on a back surface of the back contact solar cell and extending along a first direction. The back contact solar cell further includes a first sub-busbar electrode and a second sub-busbar electrode, which are extending along a second direction. The first finger electrodes are electrically connected to an N-type doped region, and the second finger electrodes are electrically connected to a P-type doped region. The first sub-busbar electrode is electrically connected to the first main busbar electrode and the first finger electrodes. The second sub-busbar electrode is electrically connected to the second main busbar electrode and the second finger electrodes.

Abstract: An exemplary transmission liquid crystal display (200) includes a first substrate (215) and a second substrate (235); a liquid crystal layer (220) having liquid crystal molecules interposed between the first and second substrates; a front polarizer (211) disposed at an front surface of the first substrate, and a rear polarizer (231) disposed at a rear surface of the second substrate; a first quarter-wavelength compensation member (213) between the front polarizer and the first substrate; a second quarter-wavelength compensation member (234) between the rear polarizer and the second substrate; a first discotic molecular film (214) between the first quarter-wavelength compensation member and the first substrate; and a second discotic molecular film (234) between the second quarter-wavelength compensation member and the second substrate.

Abstract: A liquid crystal display device 700 has a liquid crystal panel 701 and a backlight module 70 under the liquid crystal panel for providing light beams to the liquid crystal panel. The backlight module includes at least one light source 720, and a light guide plate 711. The light guide plate has an incident surface 710 for receiving light beams from the at least one light source, an emitting surface 712 adjacent the incident surface, and a bottom surface 713 opposite to the emitting surface, at least one brightness enhancing pattern being provided at the bottom surface. The at least one brightness enhancing pattern has a plurality of brightness enhancing element 714, each of which is an arcuate and generally subtending the at least one light source.

Abstract: An LCD device (2) includes a first substrate (21), a second substrate (22), and a liquid crystal layer (23) having liquid crystal molecules is interposed between the first and second substrates. A pretilt angle of the liquid crystal layer adjacent to one of the substrates is 0° to 15°, and a pretilt angle of the liquid crystal layer adjacent to the other substrate is 75° to 90°. This ensures that the LCD device provides a good quality display. In addition, the alignment and the pretilt angle of the liquid crystal molecules means that the liquid crystal molecules are hybrid aligned when this is needed, and can be twisted in a very short time.

Abstract: An exemplary transflective LCD (20) device includes first and second substrates (210, 220); a liquid crystal layer (23) interposed between the substrates; a common electrode (211) disposed at an inner surface of the first substrate; a transmission electrode (221) and a reflection electrode (222) disposed at an inner surface of the second substrate, with the reflection electrode defining an opening therein; a first retardation film (251) and a first polarizer (241) disposed at an outside surface of the first substrate; a second retardation film (252) and a second polarizer (242) disposed at an outside surface of the second substrate; and a discotic molecular film (261 and 862) disposed in a position selected from the group consisting of, between the first retardation film and the first substrate, and between the second retardation film and the second substrate.