Abstract: The partition monitoring method for concrete dam operation key parts provided by the disclosure firstly utilizes the extracted monitoring data time-frequency vector to partition the concrete dam key parts, and on this basis, obtains time series measurement data of different types of monitoring instruments with high temporal and spatial correlation, so as to establish a graph structure. Then, the dependence of time dimension and variable dimension of multivariate time series data is captured, and the relationship between further learning and representation of graph attention network is provided. Furthermore, the final feature representation of time series measured data is obtained, and finally the anomaly score is calculated through the final feature representation to detect anomalies. The complementary mutual verification of multiple measuring points of monitoring instruments with various types is realized. The structural integrity and spatial distribution law of concrete dams are fully embodied.

Abstract: A medical device with a capacitive sensing function includes a medical body having a syringe and a sensing circuit having an electrode, a protective film adhered to the medical body and including a plastic film, an electrode provided on the plastic film and opposite from the electrode of the medical body, and a capacitive sensor formed by the electrode of the medical body and the electrode of the protective film and being a part of the sensing circuit, wherein a capacitance value of the capacitive sensor changed under the condition of removing the protective film from the medical body, the sensing circuit being configured to detect the capacitance value and trigger corresponding function of the medical body.

Abstract: In an aspect, the present disclosure discloses a medical sensor to be connected to a monitoring device for vital sign monitoring. The medical sensor includes a flexible circuit layer having an electrode pattern, a foam layer laminated on the flexible circuit layer, a bonding layer sandwiched between the flexible circuit layer and the foam layer to bond the foam layer with the flexible circuit layer, and a gel sponge disposed on and electrically connected to the electrode pattern through the foam layer and the bonding layer. The area of the bonding layer is smaller than the area of the foam layer. A part of the foam layer adjacent the perimeter is not covered by the bonding layer, and not bonded to the flexible circuit layer by the bonding layer to provide the medical sensor enough conformability to a body.

Abstract: A medical device with a capacitive sensing function includes a medical body having a syringe and a sensing circuit having an electrode, a protective film adhered to the medical body and including a plastic film, an electrode provided on the plastic film and opposite from the electrode of the medical body, and a capacitive sensor formed by the electrode of the medical body and the electrode of the protective film and being a part of the sensing circuit, wherein a capacitance value of the capacitive sensor changed under the condition of removing the protective film from the medical body, the sensing circuit being configured to detect the capacitance value and trigger corresponding function of the medical body.

Abstract: In an aspect, the present disclosure discloses a medical sensor to be connected to a monitoring device for vital sign monitoring. The medical sensor includes a flexible circuit layer having an electrode pattern, a foam layer laminated on the flexible circuit layer, a bonding layer sandwiched between the flexible circuit layer and the foam layer to bond the foam layer with the flexible circuit layer, and a gel sponge disposed on and electrically connected to the electrode pattern through the foam layer and the bonding layer. The area of the bonding layer is smaller than the area of the foam layer. A part of the foam layer adjacent the perimeter is not covered by the bonding layer, and not bonded to the flexible circuit layer by the bonding layer to provide the medical sensor enough conformability to a body.

Abstract: A security wrap (20) for protecting an electronic component includes a substrate (22) having a first side and a second side opposite to each other. A security screen (26) is disposed over the first side of the substrate (22) and includes a pair of screen terminals (48) and a frangible and electrically conductive path (46) between the pair of screen terminals (48). A layer of adhesive (30) is over the first side of the substrate (22) and bonds the first side of the substrate (22) to the electronic component with the security screen (26) sandwiched there between.

Abstract: An electronic device is protected from unauthorized access by use of a security wrap which comprises at least a substrate, a security screen, a layer of adhesive and decoy pattern. The security screen is disposed over one side of the substrate and includes a pair of screen terminals and a conductive path between the pair of screen terminals. The layer of adhesive bonds the first side of the substrate to the electronic component with the security screen sandwiched there between. The decoy pattern is at least partially impervious to X-ray and overlays said security screen.

Abstract: A security wrap (20) for protecting an electronic component (16) includes a substrate (26) having a first side and a second side opposite to each other. A conductive path (22) is disposed over the first side of the substrate (26) and has first and second ends coupled to the electronic component (16), and a pattern selected from a plurality of predetermined patterns. A layer of adhesive (28) is over the first side of the substrate (26) and bonds the first side of the substrate (26) to the electronic component (16) with the conductive path (22) sandwiched there between.

Abstract: A security wrap (20) for protecting an electronic component (16) having a bonding surface includes a substrate (22) having a first side and a second side opposite to each other. A first security screen (26) is disposed over the first side of the substrate (22) and includes a first pair of screen terminals (48) and a first conductive track (46) between the first pair of screen terminals (48). A second security screen (26) includes a second pair of screen terminals (48) and a second conductive track (46) between the second pair of screen terminals (48) and overlaying the first conductive track (46) on the first security screen (26). A layer of adhesive (30) is over a side of the second security screen (26) remote from the substrate (22) and bonds the second security screen (22) to the bonding surface of the electronic component (16).

Abstract: A microfluidic sensor (10), such as an electrochemical blood test strip, with more accurate measurement comprises a plurality of channels (24) through which a fluid to be tested flows via a capillary action. One or more electrodes (30) are located under the channels (24). As the fluid flows over the electrodes (30) in the channels (24), the impedance between the electrodes (30) may be measured to determine fluid properties. In order to increase the accuracy of the measurements, the electrode deposition may be configured to be less than 10 ?m in thickness via a printing process with high process consistency, thereby reducing the disruption of the electrode deposition on the fluid flow.

Abstract: An electro-optic display comprises a layer of reflective electro-optic material capable of changing its optical state on application of an electric field, an electrode, a heat generating component in heat conducting relationship with the electro-optic material, and a heat shield disposed between the heat generating component and the electro-optic material, the heat shield comprising a layer of thermally insulating material and a layer of thermally conducting material, the thermally conducting material being disposed between the thermally insulating material and the electro-optic material. The invention also provides an electrophoretic medium comprising a suspending fluid and a plurality of electrically charged particles suspended in the suspending fluid and capable of moving therethrough upon application of an electrical field to the electrophoretic medium, the suspending fluid containing a compatibilizer to reduce its coefficient of thermal expansion.

Abstract: An electronic device (16) is protected from unauthorized access by use of a security wrap (20) which comprises at least a substrate (26), a security screen (30), a layer of adhesive (28) and decoy pattern (30). The security screen (30) is disposed over one side of the substrate (26) and includes a pair of screen terminals (48) and a conductive path (46) between the pair of screen terminals. The layer of adhesive (28) bonds the first side of the substrate to the electronic component with the security screen (30) sandwiched there between. The decoy pattern is at least partially impervious to X-ray and overlays said security screen.

Abstract: A security wrap (20) for protecting an electronic component (16) having a bonding surface includes a substrate (22) having a first side and a second side opposite to each other. A first security screen (26) is disposed over the first side of the substrate (22) and includes a first pair of screen terminals (48) and a first conductive track (46) between the first pair of screen terminals (48). A second security screen (26) includes a second pair of screen terminals (48) and a second conductive track (46) between the second pair of screen terminals (48) and overlaying the first conductive track (46) on the first security screen (26). A layer of adhesive (30) is over a side of the second security screen (26) remote from the substrate (22) and bonds the second security screen (22) to the bonding surface of the electronic component (16).

Abstract: A security wrap (20) for protecting an electronic component includes a substrate (22) having a first side and a second side opposite to each other. A security screen (26) is disposed over the first side of the substrate (22) and includes a pair of screen terminals (48) and a frangible and electrically conductive path (46) between the pair of screen terminals (48). A layer of adhesive (30) is over the first side of the substrate (22) and bonds the first side of the substrate (22) to the electronic component with the security screen (26) sandwiched there between.

Abstract: A security wrap (20) for protecting an electronic component (16) includes a substrate (26) having a first side and a second side opposite to each other. A conductive path (22) is disposed over the first side of the substrate (26) and has first and second ends coupled to the electronic component (16), and a pattern selected from a plurality of predetermined patterns. A layer of adhesive (28) is over the first side of the substrate (26) and bonds the first side of the substrate (26) to the electronic component (16) with the conductive path (22) sandwiched there between.

Abstract: Novel addressing schemes for controlling electronically addressable displays include a scheme for rear-addressing displays, which allows for in-plane switching of the display material. Other schemes include a rear-addressing scheme which uses a retroreflecting surface to enable greater viewing angle and contrast. Another scheme includes an electrode structure that facilitates manufacture and control of a color display. Another electrode structure facilitates addressing a display using an electrostatic stylus. Methods of using the disclosed electrode structures are also disclosed. Another scheme includes devices combining display materials with silicon transistor addressing structures.

Abstract: Novel addressing schemes for controlling electronically addressable displays include a scheme for rear-addressing displays, which allows for in-plane switching of the display material. Other schemes include a rear-addressing scheme which uses a retroreflecting surface to enable greater viewing angle and contrast. Another scheme includes an electrode structure that facilitates manufacture and control of a color display. Another electrode structure facilitates addressing a display using an electrostatic stylus. Methods of using the disclosed electrode structures are also disclosed. Another scheme includes devices combining display materials with silicon transistor addressing structures.

Abstract: Novel addressing schemes for controlling electronically addressable displays include a scheme for rear-addressing displays, which allows for in-plane switching of the display material. Other schemes include a rear-addressing scheme which uses a retroreflecting surface to enable greater viewing angle and contrast. Another scheme includes an electrode structure that facilitates manufacture and control of a color display. Another electrode structure facilitates addressing a display using an electrostatic stylus. Methods of using the disclosed electrode structures are also disclosed. Another scheme includes devices combining display materials with silicon transistor addressing structures.

Abstract: The invention relates to methods and materials for controlling stability and color intensity in an electrophoretic display element. Filler particles in the electrophoretic display element, serves as a medium that the electrophoretic particles must travel through during switching between optical states of the display. The filler particles provide improved control over the color intensity of the electrophoretic display element. In addition, the filler particles create resistance to the migration of the electrophoretic particles, thereby improving the bistability of the electrophoretic displays and inhibiting settling of the electrophoretic particles. Also, migration resistance provided by the filler particles can enable threshold addressing of an electrophoretic display.

Abstract: An electro-optic display comprises a layer (130) of a solid electro-optic material, at least one electrode disposed adjacent the layer (130) of electro-optic material, and a layer (180) of a lamination adhesive interposed between the layer (130) of electro-optic material and the electrode, the lamination adhesive (180) having a higher electrical conductivity in a direction perpendicular to the layer of lamination adhesive than in the plane of the layer.