Abstract: A lighting device includes a light board and a light dimmer circuit. The light board includes multiple first light emitting elements and second light emitting elements. The first light emitting elements are disposed in a first area of the light board. The second light emitting elements are disposed in a second area of the light board. The light dimmer circuit is configured to drive the second light emitting elements to generate flickering lights from the second area of the light board, and is configured to drive the first light emitting elements to generate non-flickering lights from the first area of the light board.

Abstract: An annular airflow regulating apparatus includes a cup-shaped element and an adjustment element. The cup-shaped element has a bowl and a bottom, integrated to form a first chamber. The bottom has a tapered channel parallel to an axis and penetrating through the bottom. A ring-shaped groove is disposed between the tapered channel and the bottom. The ring-shaped groove has an annular plane perpendicular to the axis. The adjustment element, having a tapered portion and second holes, is movably disposed in the cup-shaped element. The tapered portion protrudes into the tapered channel A tapered annular gap is formed between the tapered portion and the tapered channel. When the adjustment element is moved with respect to the cup-shaped element, a width of the tapered annular gap is varied, and thereupon a flow rate and velocity of the process gas would be varied accordingly.

Abstract: The present disclosure provides an electronic wearable device. The electronic wearable device includes a first module having a first contact and a second module having a second contact. The first contact is configured to keep electrical connection with the second contact in moving with respect to each other during a wearing period.

Abstract: A method includes forming a dummy pattern over test region of a substrate; forming an interlayer dielectric (ILD) layer laterally surrounding the dummy pattern; removing the dummy pattern to form an opening; forming a dielectric layer in the opening; performing a first testing process on the dielectric layer; performing an annealing process to the dielectric layer; and performing a second testing process on the annealed dielectric layer.

Abstract: The present invention provides antibody or the antigen-binding portion thereof bind to carbohydrate antigen, such as Globo series antigens (e.g. Globo H, SSEA-4 or SSEA-3). Also disclosed herein are pharmaceutical compositions and methods for the inhibition of cancer cells in a subject in need thereof. The pharmaceutical compositions comprise an antibody or an antigen-binding portion thereof and at least one pharmaceutically acceptable carrier.

Abstract: An apparatus includes a vacuum chamber, a reflective optical element arranged in the vacuum chamber and configured to reflect an extreme ultra-violet (EUV) light, and a cleaning module positioned in the vacuum chamber. the cleaning module is operable to provide a mitigation gas flowing towards the reflective optical element and provide a hydrogen-containing gas flowing towards the reflective optical element. The mitigation gas mitigates, by chemical reaction, contamination of the reflective optical element.

Abstract: A runtime capability check determines functionality supported by a client application (e.g. a browser) on a computing device. During the runtime capability check, the client application (e.g. the browser) attempts to execute different function tests to determine its capabilities. The result information from the function tests are stored. The stored result information is used by the client application during subsequent connections with the server (e.g. the cookie is passed from the mobile computing device to the server). Based on the supported functionality as determined by the stored result information, the rendering code is adapted for, generated and delivered to the computing device by the server. For example, when the client application supports the tested functionality then the server renders the content using full feature rendering. When the client application does not support all of the tested functionality then the server renders the content using limited feature rendering.

Abstract: A connecting device configured to couple to a robot arm and a robot tool includes a first connecting part including a fixing member having at least one first magnetic part, at least one first optical fiber connector, and at least one first electrical connector which are coupled to the fixing member. A second connecting part which is removable and securely coupled to the first connecting part including a fixing member having at least one second magnetic part, at least one second optical fiber connector, and at least one first conduction connector which are coupled to the fixing member. The first magnetic part and the second magnetic part have opposite magnetic force. When the first magnetic part contacts the second magnetic part, the first optical fiber connector connect to the second optical fiber connector and the first electrical connector connects to the first conduction connector.

Abstract: A calibration device to calibrate precise horizontality of a light emitting element includes a retaining rack, a microprocessor, a regulating member, two driven members, and two photo sensing members. The regulating member drives the light emitting element, the two driven members are on the retaining rack, and the microprocessor controls the driven members to move linearly. The photo sensing members detect light transmitted and data as to the vertical distance between two driven members, and vertical distance between the photo sensing member and the two driven members, is stored. The microprocessor calculates the moving distance of the photo sensing members carried by the driven members based on the signals of light detected, and further calculates declination of the light emitting element. The microprocessor can adjust the orientation of light emitting element.

Abstract: A display panel comprising a TFT substrate, a display medium and an opposite substrate is provided. The display medium is disposed between the TFT substrate and the opposite substrate. The TFT substrate comprises a substrate, a first electrode layer, a pixel electrode layer, a first insulating layer, a second electrode layer, a second insulating layer, a channel layer and an over coating layer. The first electrode layer and the pixel electrode layer are disposed on the substrate. The first insulating layer is disposed on the first electrode layer and the pixel electrode layer. The second electrode layer is disposed on the first insulating layer. The second insulating layer is disposed on the second electrode layer. The channel layer is interposed into a first contact hole and a second contact hole to electrically connect the first electrode layer. The over coating layer is disposed on the channel layer.

Abstract: A runtime capability check determines functionality supported by a client application (e.g. a browser) on a computing device. During the runtime capability check, the client application (e.g. the browser) attempts to execute different function tests to determine its capabilities. The result information from the function tests are stored. The stored result information is used by the client application during subsequent connections with the server (e.g. the cookie is passed from the mobile computing device to the server). Based on the supported functionality as determined by the stored result information, the rendering code is adapted for, generated and delivered to the computing device by the server. For example, when the client application supports the tested functionality then the server renders the content using full feature rendering. When the client application does not support all of the tested functionality then the server renders the content using limited feature rendering.

Abstract: This disclosure provides a display panel and a display apparatus using the display panel. The display panel includes: a substrate; a first electrode formed on the substrate; a first insulation layer formed on the first electrode; a gate electrode formed on the first insulation layer and having an inclined lateral plane; a second insulation layer formed on the gate electrode and covering the inclined lateral plane; an active layer formed on the second insulation layer corresponding to the inclined lateral plane and electrically connected to the first electrode; and a second electrode electrically connected to the active layer; wherein the inclined lateral plane has an angle of between 30 and 90 degrees relative to the surface of the substrate.

Abstract: A robotic finger structure is a section of a robotically controlled extension including a fingertip and a tactile sensor, the fingertip has a finger pulp, and the tactile sensor is integrated with the surface of the finger pulp. The tactile sensor configured to form a detecting area to accept and indicate any pressure on a plane perpendicular between the tactile sensor and an object; therefore the tactile sensor can feed back the force of pressure accurately, and control overall gripping force of the robotic finger.

Abstract: A calibration device to calibrate precise horizontality of a light emitting element includes a retaining rack, a microprocessor, a regulating member, two driven members, and two photo sensing members. The regulating member drives the light emitting element, the two driven members are on the retaining rack, and the microprocessor controls the driven members to move linearly. The photo sensing members detect light transmitted and data as to the vertical distance between two driven members, and vertical distance between the photo sensing member and the two driven members, is stored. The microprocessor calculates the moving distance of the photo sensing members carried by the driven members based on the signals of light detected, and further calculates declination of the light emitting element. The microprocessor can adjust the orientation of light emitting element.

Abstract: A connecting device configured to couple to a robot arm and a robot tool includes a first connecting part including a fixing member having at least one first magnetic part, at least one first optical fiber connector, and at least one first electrical connector which are coupled to the fixing member. A second connecting part which is removable and securely coupled to the first connecting part including a fixing member having at least one second magnetic part, at least one second optical fiber connector, and at least one first conduction connector which are coupled to the fixing member. The first magnetic part and the second magnetic part have opposite magnetic force. When the first magnetic part contacts the second magnetic part, the first optical fiber connector connect to the second optical fiber connector and the first electrical connector connects to the first conduction connector.

Abstract: A runtime capability check determines functionality supported by a client application (e.g. a browser) on a computing device. During the runtime capability check, the client application (e.g. the browser) attempts to execute different function tests to determine its capabilities. The result information from the function tests are stored. The stored result information is used by the client application during subsequent connections with the server (e.g. the cookie is passed from the mobile computing device to the server). Based on the supported functionality as determined by the stored result information, the rendering code is adapted for, generated and delivered to the computing device by the server. For example, when the client application supports the tested functionality then the server renders the content using full feature rendering. When the client application does not support all of the tested functionality then the server renders the content using limited feature rendering.

Abstract: A display panel comprising a TFT substrate, a display medium and an opposite substrate is provided. The display medium is disposed between the TFT substrate and the opposite substrate. The TFT substrate comprises a substrate, a first electrode layer, a pixel electrode layer, a first insulating layer, a second electrode layer, a second insulating layer, a channel layer and an over coating layer. The first electrode layer and the pixel electrode layer are disposed on the substrate. The first insulating layer is disposed on the first electrode layer and the pixel electrode layer. The second electrode layer is disposed on the first insulating layer. The second insulating layer is disposed on the second electrode layer. The channel layer is interposed into a first contact hole and a second contact hole to electrically connect the first electrode layer. The over coating layer is disposed on the channel layer.