An operating apparatus is disposed on a surface of a detection panel including a transparent panel and a sensor panel. An operation body includes an upper wall, an inner peripheral wall, and an outer peripheral wall. A rotary assembly is housed in the operation body. The rotary assembly includes a supporter fixed to the detection panel and a rotational operation member rotatably supported by the supporter. The rotational operation member is rotatable together with the operation body. A press detection conductor is provided at a conductor supporting portion of the operation body. A rotation detecting conductor is provided at the rotational operation member.

A capacitive touch sensor wherein the touch sensitive panel has drive electrodes arranged on the lower side of a substrate and sense electrodes arranged on the upper side. The drive electrodes are shaped and dimensioned to substantially entirely cover the touch sensitive area with individual drive electrodes being separated from each other by small gaps, the gaps being so small as to be practically invisible. The near blanket coverage by the drive electrodes also serves to screen out interference from noise sources below the drive electrode layer, such as drive signals for an underlying display, thereby suppressing noise pick-up by the sense electrodes that are positioned above the drive electrodes.

A system is provided for monitoring a patient on an air support system. The system comprises a capacitive sensor system having a capacitive sensor positioned at the underside of an air filled mattress, and a respiration signal processing module that receives the output of the capacitive sensor system and is configured to monitor patient respiration. Respiration is monitored by: periodically sampling the capacitive sensor system output to obtain measurements of incremental body displacement; analyzing a plurality of the samples to determine one or more values for parameters of patient respiratory rate; and determining when one or more of the parameter values indicate abnormal respiration. A corresponding method and computer program are also provided.

A device for the contactless actuation of an adjustable vehicle part. The device has a capacitive proximity sensor with at least one elongated sensor electrode, and a body part to which the proximity sensor is indirectly or directly fastened. The body part in turn is or can be mounted on the vehicle in a specific mounting position. The sensor electrode extends obliquely relative to a lower edge of the body part in such a way that it is in an exact or at least approximately horizontal position with respect to its longitudinal extension when in the mounting position.

A capacitive sensor is disclosed. The capacitive sensor includes a substrate, a first electrode and a second electrode formed on the substrate, an insulation layer formed on the substrate on which the first electrode and the second electrode are formed, and a sensing layer that is formed on the insulation layer and includes graphene.

Disclosed is a method of detecting the approach and/or contact of a user's hand to a door handle, the handle having a first outer surface oriented toward the vehicle and a second outer surface oriented toward the user, the handle including at least one detection electrode and an additional electrode, positioned face to face in advance. The method includes: the two electrodes are electrically connected to the same power supply source; a first capacitance value is measured at the terminals of the detection electrode; a second capacitance value is measured at the terminals of the additional electrode; and the first and second values are compared, during a measurement period, with one another and/or with a predetermined threshold value, in order to detect the approach of a user's hand toward the first outer surface or toward the second outer surface and/or the contact of his hand with one of these surfaces.

A capacitive sensor for a vehicle seat comprises an antenna electrode and a control and evaluation circuit operatively connected to the antenna electrode. The control and evaluation circuit is configured to operate in a first mode of operation, during which it measures alternating electrical current flowing between the antenna electrode and ground. The capacitive sensor comprises a seat frame connector for connecting the control and evaluation circuit to the seat frame of the vehicle seat. The control and evaluation circuit is configured to operate in a second mode of operation, during which it measures electrical current flowing into the seat frame connector.

A measuring circuit comprising a sensing element configured to generate a measuring signal from a measuring object, a signal injector configured to generate an auxiliary signal, and an evaluation circuit comprising a first upstream amplifier with a first input connected to a first pole of the sensing element via a first signal line and a second upstream amplifier with a first input connected to a second pole of the sensing element via a second signal line. A measuring circuit with an improved reliable control of its measuring chain allowing continuous testing of the integrity of the measurement signal coming from the sensing element and/or to allow the measuring circuit to be upgradable with respect to a different sensing unit and/or evaluation unit, the first upstream amplifier comprises a second input connected to the signal injector, and the evaluation circuit comprises a first downstream amplifier having a first input connected to the signal injector and a second input connected to an output of the first upstream amplifier.

A position sensor includes a variable capacitor assembly and a circuit board. The variable capacitor assembly includes a baseboard and a dielectric coupling element. The baseboard includes a baseboard body, a grounding electrode and two power electrodes. The grounding electrode is disposed nearby one side of the baseboard body. The two power electrodes are disposed separately near the other side of the baseboard body. The dielectric coupling element is spaced with the two power electrodes and the grounding electrode, and operable to be moved along a moving path. A covering condition is varied when the dielectric coupling element is operated to move along the moving path. When a power is alternatively applied to the power electrodes, a pair of capacitance values between the grounding electrode and the power electrodes is varied with the covering condition to accordingly determine a relative position of the coupling element along the moving path.

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.