Abstract: An input device includes: a plurality of first sensor electrodes; and a plurality of second sensor electrodes. Furthermore, the plurality of first sensor electrodes and the plurality of second sensor electrodes are electrically disconnected. Additionally, the plurality of first sensor electrodes are disposed in a radial arrangement centered on a reference point. Moreover, the plurality of second sensor electrodes are disposed in a concentric circular arrangement centered on the reference point.

Abstract: An input device includes: a plurality of first sensor electrodes; and a plurality of second sensor electrodes. Furthermore, the plurality of first sensor electrodes and the plurality of second sensor electrodes are electrically disconnected. Additionally, the plurality of first sensor electrodes are disposed in a radial arrangement centered on a reference point. Moreover, the plurality of second sensor electrodes are disposed in a concentric circular arrangement centered on the reference point.

Abstract: An input device includes: an operating component that includes an operating surface and is operated by an operating body; a rotation detector that detects rotation of the operating component; a touch sensor that detects a contact position of the operating body on the operating surface; and a controller that outputs a detection result of the rotation detector when the rotation detector detects the rotation of the operating component, and outputs a detection result of the touch sensor when the touch sensor detects the contact position of the operating body. When the rotation detector detects the rotation of the operating component and the touch sensor detects the contact position of the operating body, the controller outputs the detection result of the rotation detector and does not output the detection result of the touch sensor for a first time period starting from the detection by the rotation detector.

Abstract: Provided herein are: a movable part that is provided with coils placed correspondingly to magnets arranged in an arc shape, a pressure sensor, vertical-side hydrostatic pads, and a lateral-side hydrostatic plate and lateral-side hydrostatic pads caused to move in a manner matched to the shape of the magnets; and a stationary part that is provided with a base on which the magnets and vertical-side hydrostatic plates being opposite to the vertical-side hydrostatic pads are placed, a wall on which a lateral-side hydrostatic pad being opposite to the lateral-side hydrostatic plate is placed, a wall on which a lateral-side hydrostatic plate being opposite to the lateral-side hydrostatic pads is placed, and a wall to which an actuator coupled to the pressure sensor through a ball joint.

Abstract: A heat exchange element includes a stack of a plurality of flow passage plates each including a plurality of passage portions serving as flow passages, the passage portions being bonded to each other by an adhesive tape; and a gap adjustment unit having a thickness equal to or larger than a thickness of an adhesive tape and is configured to fill a gap between the flow passage plates.

Abstract: Provided herein are: a movable part that is provided with coils placed correspondingly to magnets arranged in an arc shape, a pressure sensor, vertical-side hydrostatic pads, and a lateral-side hydrostatic plate and lateral-side hydrostatic pads caused to move in a manner matched to the shape of the magnets; and a stationary part that is provided with a base on which the magnets and vertical-side hydrostatic plates being opposite to the vertical-side hydrostatic pads are placed, a wall on which a lateral-side hydrostatic pad being opposite to the lateral-side hydrostatic plate is placed, a wall on which a lateral-side hydrostatic plate being opposite to the lateral-side hydrostatic pads is placed, and a wall to which an actuator coupled to the pressure sensor through a ball joint.

Abstract: A heat exchange element includes a countercurrent portion including a plurality of partition plates each having a planar shape and a plurality of spacer plates each having a corrugated shape in cross section. The partition plates and spacer plates are alternately stacked such that corrugation directions of the spacer plates are aligned. A side surface of the countercurrent portion is formed by end portions defined by bending portions in each of which the partition plate and the spacer plate are overlaid. Since the heat exchange element according to the embodiment of the present disclosure is configured as described above, the heat insulation between flow paths of the heat exchange element and the outside air is improved, and heat exchange between fluid in the flow paths of the heat exchange element and the outside air is reduced. Consequently, the heat exchange element achieves improved heat exchange efficiency.

Abstract: A method for measuring surface properties according to the present invention includes the steps of: with distance control feedback applied so that a desired physical quantity to be measured that is attributed to an interaction between a probe and a sample is actually measured while changing a measured distance between the probe and the sample in accordance with a relationship between the desired physical quantity and the measured distance, (i) setting a set value, corresponding to the desired physical quantity, which serves to change the measured distance; and (ii) recording, for each set value thus set, a relationship between the measured distance changed by the set value set in the step (i) and a physical quantity measured with the probe and the sample placed at that measured distance. This allows precise and quick measurement of a physical quantity even in a region where the probe and the sample are very close to each other, while avoiding a collision between them.

Abstract: In a color television system including a plurality of index signal generating elements located outside an image area of an electron-impinged target surface in registry with successive color stripes located within the image area, the index signal is generated at the start of each raster scan and pulse repetition rate demodulated into a voltage signal representing the instantaneous speed of the electron beam scanning across the target surface. The voltage signal is stored in a charge transfer device for an interval of a subsequent raster and retrieved at the start of each horizontal trace for purposes of compensating for nonlinearities in the performance of beam deflection systems.