The present invention relates to a method of manufacturing a sensor for a high-temperature environment. The method comprises the steps of: depositing an electrically insulating material (108) to form at least one portion of a layer (112); depositing an electrically conductive material (110) to form at least one further portion of the layer (112); depositing successive layers (112), each layer being formed of the electrically insulating material (108) and/or the electrically conductive material (110), wherein the electrically conductive material (110) in each layer is deposited on at least a portion of the electrically conductive material (110) in the previous layer so as to form at least one electrically continuous portion extending through the layers; and fusing the materials. The invention further relates to a sensor for a high-temperature environment comprising: at least one electrically conductive portion; and at least one electrically insulating portion, encapsulating the or each electrically conductive portion. The or each electrically conductive portion and the or each electrically insulating portion are fused to form a monolithic body.

A touch window for a touch sensor includes: a touch member having a front surface and a rear surface, the front surface configured to be pressed by a user, a plurality of conductive printed portions printed on the rear surface of the touch member, the conductive printed portions being configured to respectively contact a plurality of conductive electrodes of the touch sensor, and a non-conductive film attached to the rear surface of the touch member and defining one or more through-holes. Inner surfaces of the one or more through-holes are configured to respectively surround the conductive printed portions and the conductive printed portions and the non-conductive film have different thicknesses from each other such that surface condensation on the conductive printed portions and surface condensation on the non-conductive film are spaced apart from each other.

A capacitive proximity sensor 1 comprises an oscillation means 33; a sensor circuit 10, which includes a sensor electrode 11; a detection circuit 20, which outputs a determination voltage signal corresponding to the capacitance of the sensor electrode 11, based on the electrical signal output from the sensor circuit 10; and a control unit 32. The sensor electrode 11 is connected in parallel to a connection point P1 between a coil L and a capacitor C in an LCR series resonance circuit. The detection circuit 20 outputs a determination voltage signal S.sub.1 based on the electrical signal at the detection point P3 between the capacitor C and the resistor R. The control unit 32 detects the proximity of a human body to the sensor electrode 11, based on the determination voltage signal S.sub.1.

The present invention discloses an electronic device including a body and an insulation housing. The inner side of the insulating housing is provided with a near field communication antenna and a capacitive proximity sensing board adjacent to each other . . . . A side of the near field communication antenna opposite the other side of the near field communication antenna facing the insulating housing is provided with a conductive sheet, and a first insulation layer is disposed between the near field communication antenna and the conductive sheet to be electrically isolated from each other. An area of the conductive sheet is greater than an area of the near field communications antenna. A side of the capacitive proximity sensor pad, opposite the other side of the capacitive proximity sensor pad facing the insulation housing, is provided with a second insulation layer. When the insulation housing is fixed on the body, the near field communications antenna and the capacitive proximity sensor pad are electrically connected to a near field communications antenna processing module and a capacitive proximity sensing module disposed on the body. Through disposition of the conductive sheet, the capacitive proximity sensor pad is less likely to be interfered with a signal emitted by the near field communications antenna.

An electronic device according to various embodiments of the present invention may comprise: at least one electrode having conductivity; a capacitance sensor, at least one switch electrically connected between the at least one electrode and the capacitance sensor, and capable of selectively connecting the at least one electrode and the capacitance sensor; and a control circuit, wherein the control circuit measures a first capacitance value by using the capacitance sensor in a state where the at least one switch is open, measures a second capacitance value corresponding to an external object contacting the at least one electrode, by using the capacitance sensor in a state where the at least one switch is connected, corrects the second capacitance value by using the first capacitance value, and determines the corrected second capacitance value as a capacitance value for the external object. Various other embodiments are possible.

A game machine includes an input device that is capable of detecting a position at which a user performs an operation, and a control device that commands the user respective positions and timings at which a plurality of operations is to be performed by the user upon the input device, and that evaluates the operations by the user: wherein the control device includes an operation determination device that determines presence or absence of an operation corresponding to a command for any one operation, on the basis of whether or not the operation has been detected within a range of determination; and when an operation is detected in an overlapped region between ranges of determination, the operation determination device allocates an operation detected in the overlapped region as an operation detected in one of the ranges, and excludes the operation in relation to another of the ranges.

A vehicle assembly includes, among other things, a bumper assembly, a skid plate, and a capacitive sensor system of the skid plate. A sensing method for a vehicle includes using a capacitive sensing system to detect a proximity of a vehicle to an object. The capacitive sensing system is incorporated into a skid plate that is vertically beneath a portion of a bumper assembly of the vehicle.

An electronic device includes a touch sensing layer, a touch sensor, a biometric sensor and a driver. The touch sensor is used to identify a touch location and output a touch signal upon the touch sensing layer being touched. The biometric sensor includes a plurality of sensing blocks, and is used to generate electrical signals corresponding to biometric data. The driver is coupled to the touch sensor and the biometric sensor, and is used to drive a portion of the plurality of sensing blocks according to the touch signal.

A detection device including: a measurement electrode, and a second electrode separated from one another by a distance (D) that is elastically modifiable locally, by a load exerted by an object on a detection surface, and a controller arranged in order to: connect the electrodes to an alternating guard potential (V.sub.g) in order to measure a capacitance representing an approach and a contact; and connect the second electrode to a second potential a second potential proportional to the guard potential (V.sub.g) and having a different amplitude, or to the ground potential (G), in order to measure a capacitance representing a pressure. Also provided is a detection method utilizing such a detection device.

In certain embodiments, an apparatus includes a sensing element having a capacitance to a first reference voltage. The capacitance is variable as a function of a proximity of an object to the sensing element. The apparatus further includes a sample capacitor connected to the sensing element and control circuitry connected to the sample capacitor. The control circuitry is configured to supply a charge to the sample capacitor and the sensing element and discharge the sensing element. The control circuitry is further configured to provide, in response to the discharge of the sensing element, a signal indicative of the capacitance to the first reference voltage of the sensing element. The control circuitry is further configured to process the signal to detect a change in the capacitance to the first reference voltage as indicative of the proximity of the object to the sensing element.