A capacitive measurement circuit for a capacitive sensing device having a plurality of antenna electrodes includes: a measurement signal voltage source, a remotely controllable switching unit, and a current measurement circuit. The switching unit includes a plurality of ports and switching members that are configured to provide connections between selected ports. The measurement signal voltage source and the current measurement circuit are operatively connected to a distinct port. Each antenna electrode is individually connectable to a distinct port. The switching unit is configured to connect, within a same measurement cycle, each of the antenna electrodes to the voltage output port and the current measurement circuit for loading mode operation. The switching unit is further configured to connect at least one of the antenna electrodes to the voltage output port and at least one other antenna electrode of the antenna electrodes to the current measurement circuit for coupling mode operation.

Capacitive door handle sensor comprising at least one transmission electrode and a reception electrode, an operational amplifier configured as a charge amplifier and connected to the reception electrode, a switch for charge transfer, a first and a second switch for discharging the two operational amplifier inputs and, a capacitor arranged between the output and the inverting input of the operational amplifier, and a control unit for controlling and evaluating the measurement, wherein the control unit comprises a reference potential switching output which is connected to a terminal of the switch and is configured to selectively control a capacitance measurement between the transmission electrodes and the reception electrode or between the reception electrode and ground. Furthermore, methods for setting different operating modes are claimed.

An electrostatic sensor includes a detection electrode, a shield electrode provided in a periphery of the detection electrode, a first power supply coupled to the detection electrode and configured to generate an AC voltage having a first amplitude, a second power supply coupled to the shield electrode and configured to generate an AC voltage having a second amplitude, a measuring device configured to measure a quantity of charge flowing from the first power supply to the detection electrode, and a control device coupled to the measuring device. The AC voltages generated by the first and second power supplies have the same frequency and the same phase. The second amplitude is larger than the first amplitude. A detection target on a side of a detection surface is detected based on a change in an electrostatic capacitance between the detection electrode and the detection target.

A capacitive proximity switch has a fiber composite body, which has an electrically non-conductive matrix and a multiplicity of fibers embedded in the matrix. The capacitive proximity switch includes at least one first capacitive proximity sensor, at least one second capacitive proximity sensor and one or more sensor evaluation devices. The first capacitive proximity sensor has at least one sensor electrode, which has at least one electrically conductive fiber, which is embedded in the matrix. The second capacitive proximity sensor has at least one further sensor electrode, which has at least one electrically conductive fiber, which is embedded in the matrix. The sensor electrode of the first capacitive proximity sensor and the further sensor electrode of the second capacitive proximity sensor are each connected to a sensor evaluation apparatus.

A surgical device including a surgical generator configured to provide energy for an energy based surgical instrument; a functional device configured to provide a function in its activated state; a switch for activating and deactivating the surgical generator a capacitive sensor including at least one measuring electrode that is arranged at the switch, wherein the capacitive sensor is configured to measure a capacity change or a capacity at the measuring electrode and activate or deactivate the functional device as a function of a measured capacity change or capacity.

The capacitive proximity sensor includes an oscillation means, an LCR resonance circuit including a sensor electrode, a sensor circuit that outputs a determination voltage signal corresponding to the capacitance of the sensor electrode, and a control unit that detects the proximity of a human body to the sensor electrode based on the determination voltage signal. The control unit performs control that alternatingly and repeatedly executes calibration steps for updating a detection frequency f.sub.1 and a first threshold value V.sub.th1 and a detection step for detecting the proximity of the human body to the sensor electrode.

A device (100, 200′, 200″, 300, 400) for detecting the contact between a user and a steering wheel (9) of a vehicle, the device (100, 200′, 200″, 300, 400) comprising: an electrically insulating support (10); a first electrically conductive track (101, 201, 301, 401) fastened to the support (10) and comprising a plurality of first peaks (11) alternated with a plurality of first troughs (12) along a direction (D), wherein the first track (101, 201, 301, 401) is distributed over the support so that the surface of the first track (101, 201, 301, 401) adapted to come into contact with a user's hand decreases along said direction (D).

Embodiments of the present invention provide robust capacitive grip sensors that may be used in a variety of applications, including single-handed and double-handed grips, such as but not limited to barbells. Apparatus as disclosed herein and efficiently measure the presence of a human grip without requiring deformation of a gripped surface area.

Disclosed is a system for detecting approach and/or contact of a user and Ultra High Frequency communication with a portable user apparatus, intended to be embedded on board an automotive vehicle, the system including: a device for detecting approach and/or contact, including a sensor for detecting approach and/or contact and an electronic control unit; a conducting metal surface, suitable for the conduction of electric charges; and a communication device, including an Ultra High Frequency antenna emitting an electromagnetic field at an Ultra High Frequency wavelength, and a management unit for managing the emission and reception of data of the antenna. The conducting metal surface takes the form of a continuous path including a plurality of meanders spread over a length at least equal to:
L=λ/6
wherein L is a total length of the meanders, and λ is a wavelength of the Ultra High Frequency antenna.

The invention relates to an arrangement (10) for providing at least one function for electronics (2) of a vehicle (1), preferably for door handle electronics (2) of the vehicle (1), preferably for a capacitive sensor (4) for detecting an activation action in the vehicle (1) and/or for a communication interface (40) of the vehicle (1), having: a carrier element (20) which is suitable for installation at installation positions (I, II) on different sides of the vehicle (1) in order to selectively carry out installation at least at a first installation position (I) or at a second installation position (II) of the installation positions (I, II), a first electrically conductive functional element (31) on a first plane (21) and a second electrically conductive functional element (32) on a second plane (22) of the carrier element (20), wherein the functional elements (31, 32) are arranged above one another and are at least partially congruent in order to provide, in a variably assigned manner, a capture function for one of the planes (21, 22) and a further function, in particular a shielding function, for the other of the planes (21, 22), a connection arrangement (70) for electrically connecting the functional elements (31, 32) to a processing arrangement (80) in order to provide a connection interface (78) for controlling the functional elements (31, 32) for assigning the functions depending on the selected installation position (I, II).