Embodiments of present invention provide a resistor structure. The resistor structure includes a first layer of electrically insulating material; and a second layer of resistive material directly adjacent to the first layer, wherein thermal conductivity of the first layer is equal to or larger than 100 W/m/K. In one embodiment, the first layer of electrically insulating material has a band gap equal to or larger than 4 eV and is selected from a group consisting of aluminum-nitride (AlN), boron-nitride (BN), and diamond (C).

An aircraft heated floor panel includes a first face sheet, a second face sheet opposite the first face sheet, and core with an electrically conductive core portion. The electrically conductive core portion supports the first face sheet and the second face sheet, and is electrically insulated from the external environment to receive electrical power, resistively generate heat, and communicate heat to the first face sheet.

An aircraft heated floor panel includes a first face sheet, a second face sheet opposite the first face sheet, and core with an electrically conductive core portion. The electrically conductive core portion supports the first face sheet and the second face sheet, and is electrically insulated from the external environment to receive electrical power, resistively generate heat, and communicate heat to the first face sheet.

A method for manufacturing a resistor is described. First and second division lines are formed in a first surface of a substrate to define device areas. First and second electrodes are formed on the first surface and respectively on the device areas. Third electrodes, fourth electrodes, and resistive layers are formed on a second surface of the substrate and respectively on the device areas. The substrate is diced from the second surface by a cutting tool to form bar structures to expose opposite first and second side surfaces of the device areas. First and second terminal electrodes are formed to respectively cover the first and second side surfaces. The bar structures are diced from the second surface by the cutting tool to separate the device areas. The cutting tool is aligned with the first and second division lines respectively while dicing the substrate and the bar structures.

A resistor includes an elongated cylindrical body having nodes and elongated members. The elongated members interconnect the nodes to form openings between the nodes and the elongated members for the flow therethrough of a cooling fluid. The body is configured to receive electric current from a powered system and to conduct and provide electric resistance to the electric current to dissipate at least part of the electric current as heat from the body. The body also is configured to be coupled with at least one other resistor of the powered system in one or more of a parallel or series arrangement in an electric circuit.

A display device and a manufacturing method of the same are provided. The display device includes a frame, a pressure sensor, and a pressure sensing module. When a touch portion receives external pressure, a resistance value of the resistor changes, and a corresponding pressure sensing signal is output. The pressure sensing module outputs an execution signal according to the pressure sensing signal to realize a pressure touch function on a side of the frame. This eliminates a need to make holes in a side of the frame, which eliminates a mechanical button and improves dustproof and waterproof performance of the display device.

A three-dimensional thermistor device and a manufacturing method thereof. The three-dimensional thermistor device comprising a thermistor array formed on a base layer extending in first and second directions. Where the thermistor array comprises: thermistor pattern layers and insulating layers stacked alternately on the base layer in a third direction; each thermistor pattern layer including a continuous electrically conductive first trace disposed along a first path extending in both the first and second directions, and each insulating layer including an electrically conductive first via extending through the insulating layer in the third direction to electrically connect the first traces to each other. Where successive electrical connections between the respective first vias on the stacked insulating layers and the respective first traces on the stacked thermistor layers form a continuous electrical first thermistor element extending in the first, second and third directions across multiple of the thermistor pattern layers.

A three-dimensional thermistor device and a manufacturing method thereof. The three-dimensional thermistor device comprising a thermistor array formed on a base layer extending in first and second directions. Where the thermistor array comprises: thermistor pattern layers and insulating layers stacked alternately on the base layer in a third direction; each thermistor pattern layer including a continuous electrically conductive first trace disposed along a first path extending in both the first and second directions, and each insulating layer including an electrically conductive first via extending through the insulating layer in the third direction to electrically connect the first traces to each other. Where successive electrical connections between the respective first vias on the stacked insulating layers and the respective first traces on the stacked thermistor layers form a continuous electrical first thermistor element extending in the first, second and third directions across multiple of the thermistor pattern layers.

An electrical resistor has a resistance conductor, which is applied to a carrier layer, and two connection elements, which are electrically conductively connected to the resistance conductor. The two connection elements are configured to each be welded or soldered to an electrical contact in order to electrically contact the resistor. The resistance conductor for each connection element has a region that overlaps the corresponding connection element. The overlap region is in electrical contact with the corresponding connection element.

An electrical resistor has a resistance conductor, which is applied to a carrier layer, and two connection elements, which are electrically conductively connected to the resistance conductor. The two connection elements are configured to each be welded or soldered to an electrical contact in order to electrically contact the resistor. The resistance conductor for each connection element has a region that overlaps the corresponding connection element. The overlap region is in electrical contact with the corresponding connection element.