Abstract: A system comprises: an input device to generate commands for controlling a medical device; and an operator-detection sensor to generate sensor data indicating an operator's presence/absence at the input device. Movement of the medical device is controlled based on a comparison of the data with a baseline and a command line. The medical device is not moved when a comparison with a first baseline indicates the operator's absence, and the device is moved when a comparison with a first command line indicates the operator's presence. A triggering event is detected for a calibration procedure, which comprises establishing a second baseline associated with the operator's absence and establishing a second command line associated with the operator's presence. The medical device is not moved when a comparison with the second baseline indicates the operator's absence, and the device is moved when a comparison with the second command line indicates the operator's presence.

Abstract: In a method of manufacturing a semiconductor device, a fin structure including a stacked layer of first and second semiconductor layers and a hard mask layer over the stacked layer is formed. A sacrificial cladding layer is formed over at least sidewalls of the exposed hard mask layer and stacked layer. An etching is performed to remove lateral portions of the sacrificial cladding layer, thereby leaving the sacrificial cladding layer on sidewalls of the exposed hard mask layer and stacked layer. A first dielectric layer and a second dielectric layer made of a different material than the first dielectric layer are formed. The second dielectric layer is recessed, and a third dielectric layer made of a different material than the second dielectric layer is formed on the recessed second dielectric layer. During the etching operation, a protection layer is formed over the sacrificial cladding layer.

Abstract: The invention provides a non-invasive blood glucose monitoring device with a wearing fit detection function, comprising a substrate, a blood glucose monitoring module, an optical feedback sensing module and at least one light-blocking wall. The substrate defines a first setting area for disposing the blood glucose monitoring module and a second setting area for disposing the optical feedback sensing module. The second setting area is between an edge of the substrate and the first setting area. The optical feedback sensing module includes at least one light-emitting element and at least one light-receiving element. Each light-emitting element emits a light signal corresponding to at least one specific wavelength, and each light-receiving element receives the light signal corresponding to the at least one specific wavelength, after being reflected, as a basis for determining the wearing fit. The at least one light-blocking wall is located between the first setting area and the second setting area.

Abstract: The invention provides a manufacturing method for a non-invasive blood glucose monitoring device, which comprises the following steps: providing a substrate; performing an injection molding process or an electroplating process, to form at least one light-blocking wall on the substrate, wherein each light-blocking wall includes a lower wall-structure and an upper wall-structure, and the lower wall-structure connects the substrate and the upper wall-structure connects the lower wall-structure; arranging a light-emitting element and a light-receiving element on the substrate and separating the light-emitting element and the light-receiving element by the at least one light-blocking wall; forming a packaging structure on the substrate in which the light-emitting element and the light-receiving element are packaged; and disposing a transparent cover on the packaging structure and the at least one light-blocking wall and limiting the transparent cover to a configuration height by the at least one light-blocking wal

Abstract: A system comprises an input device structurally configured to be utilized by an operator to control a medical device. The system further comprises a motion sensor associated with the input device and configured to detect a displacement distance of the input device. The system further comprises a control unit configured to determine a velocity cap defining a maximum velocity of the medical device based on the detected displacement distance. The control system is further configured to control movement of the medical device based on the velocity cap.

Abstract: A display apparatus is provided. The display apparatus includes a display module and multiple light-emitting driving circuits. Each of the light-emitting driving circuits includes a timing control circuit and a driving circuit. The timing control circuit receives multiple clock signals and a previous light-emitting timing signal to provide a light-emitting timing signal and an internal voltage. The driving circuit receives a first phase signal among multiple phase signals and the internal voltage to provide a light-emitting driving signal to the display module based on the first phase signal and the internal voltage. The phase signals all present disabled levels during a vertical blank period.

Abstract: The present disclosure provides a method of making a semiconductor device. The method includes forming a semiconductor stack on a substrate, wherein the semiconductor stack includes first semiconductor layers of a first semiconductor material and second semiconductor layers of a second semiconductor material alternatively stacked on the substrate; patterning the semiconductor stack and the substrate to form a trench and an active region being adjacent the trench; epitaxially growing a liner of the first semiconductor material on sidewalls of the trench and sidewalls of the active region; forming an isolation feature in the trench; performing a rapid thermal nitridation process, thereby converting the liner into a silicon nitride layer; and forming a cladding layer of the second semiconductor material over the silicon nitride layer.

Abstract: The present disclosure relates to the technical field of antennas, and discloses a control method, a control component and a control device.

Abstract: The disclosure provides uses of multispecific antigen-binding molecules that targets human DLL3 for the treatment of cancers.

Abstract: A brightness compensation device includes a panel, a heat detector, a memory, and a processor. he processor is configured to perform the following steps: at a specific grayscale of the red grayscale data, the green grayscale data, or the blue grayscale data, adjusting a turn-on time data of a luminous signal according to the first temperature data; adjusting the red grayscale data, the green grayscale data, or the blue grayscale data according to a brightness relation or the sheet to obtain a red updating grayscale data, a green updating grayscale data, or a blue updating grayscale data; and when it is determined that the second temperature data is the same as the first temperature data, outputting or storing the red updating grayscale data, the green updating grayscale data, or the blue updating grayscale data.

Abstract: A fingerprint sensing device has a sensing area, an operation area, and a peripheral area, and the operation area is disposed between the sensing area and the peripheral area. The fingerprint sensing device includes a substrate, a sensing element located at the sensing area, an operation element located at the operation area, a first signal line located at the peripheral area, a first planarization layer, a first insulating layer, and a first shading layer. The first planarization layer is located on the substrate and has a first trench, and the first trench overlaps the first signal line. The first insulating layer is located on the first planarization layer and in the first trench, and the first insulating layer has a first opening located in the first trench. The first shading layer is located on the first insulating layer and connected to the first signal line through the first opening.

Abstract: A brightness compensation device includes a panel, a heat detector, a memory, and a processor. he processor is configured to perform the following steps: at a specific grayscale of the red grayscale data, the green grayscale data, or the blue grayscale data, adjusting a turn-on time data of a luminous signal according to the first temperature data; adjusting the red grayscale data, the green grayscale data, or the blue grayscale data according to a brightness relation or the sheet to obtain a red updating grayscale data, a green updating grayscale data, or a blue updating grayscale data; and when it is determined that the second temperature data is the same as the first temperature data, outputting or storing the red updating grayscale data, the green updating grayscale data, or the blue updating grayscale data.

Abstract: In a method of manufacturing a semiconductor device, a fin structure including a stacked layer of first and second semiconductor layers and a hard mask layer over the stacked layer is formed. A sacrificial cladding layer is formed over at least sidewalls of the exposed hard mask layer and stacked layer. An etching is performed to remove lateral portions of the sacrificial cladding layer, thereby leaving the sacrificial cladding layer on sidewalls of the exposed hard mask layer and stacked layer. A first dielectric layer and a second dielectric layer made of a different material than the first dielectric layer are formed. The second dielectric layer is recessed, and a third dielectric layer made of a different material than the second dielectric layer is formed on the recessed second dielectric layer. During the etching operation, a protection layer is formed over the sacrificial cladding layer.

Abstract: Antigen-binding domains that are capable of binding to CD3 and CD137 but do not bind to CD3 and CD137 at the same time and methods of using the same are provided. Methods to obtain antigen binding domains which bind to two or more different antigens more efficiently are also provided.

Abstract: A method includes forming a first portion of a spacer layer over a first fin and a second portion of the spacer layer over a second fin, performing a first etching process to recess the first portion of the spacer layer with respect to the second portion of the spacer layer to form first spacers on sidewalls of the first fin, subsequently performing a second etching process to recess the second portion of the spacer layer with respect to the first spacers to form second spacers on sidewalls of the second fin, where the second spacers are formed to a height greater than that of the first spacers, and forming a first epitaxial source/drain feature and a second epitaxial source/drain feature between the first spacers and the second spacers, respectively, where the first epitaxial source/drain feature is larger than that of the second epitaxial source/drain feature.

Abstract: A plurality of first semiconductor layers and second semiconductor layers are formed over a front side of a substrate. The first semiconductor layers interleave with the second semiconductor layers in a vertical direction. The first semiconductor layers and second semiconductor layers are etched into a plurality of stacks. The etching is performed such that a bottommost first semiconductor layer is etched to have a tapered profile in a cross-sectional view. The bottommost first semiconductor layer is replaced with a dielectric layer. The dielectric layer inherits the tapered profile of the bottommost first semiconductor layer. Gate structures are formed over the stacks. The gate structures each extend in a first horizontal direction. A first interconnect structure is formed over the gate structures. A second interconnect structure is formed over a back side of the substrate.

Abstract: A system comprises an input device structurally configured to be utilized by an operator to control a medical device. The system further comprises a motion sensor associated with the input device and configured to detect a displacement distance of the input device. The system further comprises a control unit configured to determine a velocity cap defining a maximum velocity of the medical device based on the detected displacement distance. The control system is further configured to control movement of the medical device based on the velocity cap.

Abstract: A semiconductor device structure is provided. The device includes a plurality of semiconductor layers vertically stacked, and a gate electrode layer comprising an upper portion disposed between two adjacent gate spacers, the upper portion having a first diameter. The gate electrode layer also includes a lower portion disposed below the upper portion including a first part surrounding each semiconductor layer of the plurality of semiconductor layers and a second part adjacent the first part, the second part comprising a first section having a second diameter that is less than the first diameter, a second section below the first section, the second section having a third diameter different than the second diameter, and a third section below the second section, wherein the third section has a fourth diameter different than the second diameter and the third diameter, wherein the first and second parts are formed as an integral.

Abstract: A display device includes first and second pixel circuits, first and second gate lines, and first and second transmission lines. The first pixel circuit emits light according to a data signal, and is charged according to a first gate signal. The second pixel circuit emits light according to the data signal, and is charged according to a second gate signal. The first gate line is located between the first second pixel circuits, and provides the first gate signal. The second gate line provides the second gate signal. The first transmission line provides the second gate signal to the second gate line. The second transmission line is located between the first transmission line and the second pixel circuit, crosses over the second gate line, and provides the first gate signal to the first gate line.

Abstract: The present invention provides multispecific antigen-binding molecules that comprise a first antigen-binding domain having RNF43-binding activity and a second antigen-binding domain having T cell receptor complex-binding activity, uses of such multispecific antigen-binding molecules, etc. The present inventors discovered novel multispecific antigen-binding molecules with excellent cellular cytotoxicity and high stability, which comprise a first antigen-binding domain having RNF43-binding activity and a second antigen-binding domain having T cell receptor complex-binding activity. Since the molecules of the present invention show a strong cytotoxicity against cells and tissues expressing RNF43, it is possible to produce novel pharmaceutical compositions comprising the multispecific antigen-binding molecules for treating or preventing various cancers.