A sensing module and an electronic device are provided. The sensing module includes a substrate, at least one light-emitting unit, a light-guiding assembly, at least one sensing circuit structure, and a sensing processor. The light-guiding assembly is connected to the substrate and includes at least one light-guiding structure. The at least one light-emitting unit is configured to emit a light beam outwardly through the at least one light-guiding structure. One end of the at least one sensing circuit structure is disposed on the substrate. The sensing processor is disposed on the substrate, and is configured to sense a capacitance change in a peripheral area of the at least one sensing circuit structure by the at least one sensing circuit structure and to generate a sensing signal. The sensing processor or an external controller is configured to control the at least one light-emitting unit according to the sensing signal.

A circuit structure and a method for carrying out an alternating heating and capacitive measuring mode by a common heating wire is presented. The method includes carrying out a heating mode, during which from a switching by a control circuit switching elements are in a conducting state, the switching elements are connected in series, so that the heating wire is supplied with a heating current from two different heating potentials; triggering a change into a detecting mode by the control circuit, so that the switching elements switch from the heating mode into a measuring mode, during which the switching elements are in a blocking state, so that the two different heating potentials are each interrupted several times; carrying out the measuring mode, in which the capacitance of the heating wire relative to a reference potential is determined by a detecting circuit by applying to the heating wire an alternating voltage.

A measuring device for determining magnetic properties of a magnetizable test specimen comprises a measuring coil winding which passes around a magnetizable measuring coil core. The measuring coil core comprises magnetic flux passage faces arranged at a distance from one another. The test specimen is arranged adjacently to the magnetic flux passage faces. A high-current pulse through the measuring coil winding causes a magnetic flux through the measuring coil core and the test specimen. A temporal profile of electrical characteristic variables of the measuring coil winding is detected using a sensor device. The electrical characteristic variables of the measuring coil winding detected by the sensor device are set in a ratio to additionally ascertained electrical characteristic variables of the measuring coil winding without the test specimen. A magnetic property of the test specimen is determined from the ratio of the electrical characteristic variables to one another.

Object detection for wireless power transmitters and related systems, methods, and devices are disclosed. A controller for a wireless power transmitter is configured to receive a measurement voltage potential responsive to a tank circuit signal at a tank circuit, provide an alternating current (AC) signal to each of the plurality of transmit coils one at a time, and determine at least one of a resonant frequency and a quality factor (Q-factor) of the tank circuit responsive to each selected transmit coil of the plurality of transmit coils. The controller is also configured to select a transmit coil to use to transmit wireless power to a receive coil of a wireless power receiver responsive to the determined at least one of the resonant frequency and the Q-factor for each transmit coil of the plurality of transmit coils.

A system may include an array of sensor elements, the array of sensor elements each comprising a first type of passive reactive element, a second type of passive reactive element electrically coupled to the array of sensor elements, a driver configured to drive the array of sensor elements and the second type of passive reactive element, and control circuitry configured to control enabling and disabling of individual sensor elements of the array of sensor elements to ensure no more than one of the array of sensor elements is enabled at a time such that when one of the array of sensor elements is enabled, the one of the array of sensor elements and the second type of passive reactive element together operate as a resonant sensor.

A system may include an array of sensor elements, the array of sensor elements each comprising a first type of passive reactive element, a second type of passive reactive element electrically coupled to the array of sensor elements, a driver configured to drive the array of sensor elements and the second type of passive reactive element, and control circuitry configured to control enabling and disabling of individual sensor elements of the array of sensor elements to ensure no more than one of the array of sensor elements is enabled at a time such that when one of the array of sensor elements is enabled, the one of the array of sensor elements and the second type of passive reactive element together operate as a resonant sensor.

An apparatus includes a flexible substrate; at least one sensor mounted on the flexible substrate arranged to provide an electrical output signal dependent upon a first parameter; and at least one conductive trace provided on the flexible substrate arranged to provide a direct current path to the at least one sensor and having an electrical property dependent upon a second parameter and arranged to provide an electrical output signal indicative of the second parameter.

Provided are systems that includes an a induction heating circuit and at least one processor programmed or configured to generate each line of a plurality of lines, where each line comprises a graphical representation of phase value versus frequency of a signal with which the induction heating circuit is driven, determine a line of the plurality of lines that has a maximum slope, determine an average frequency of the line having the maximum slope, determine a phase value corresponding to the average frequency of the line having the maximum slope, determine a time delay, determine a self-resonant frequency (SRF) value of the induction heating circuit based on the time delay, and determine a characteristic of the induction heating circuit based on the resonant frequency value. Methods and computer program products are also disclosed.

A capacitive sensor includes: a substrate that is in the form of a sheet; and a sensor electrode that is capacitive and disposed on a frontside of the substrate. The sensor electrode is a conductive fabric made by applying a metal plating on a mesh fabric that is woven of a plurality of warps and a plurality of wefts and that has openings each formed by two adjacent warps among the plurality of warps and two adjacent wefts among the plurality of wefts. An area defined by a maximum outside diameter of a warp or weft is smaller than an area of an opening space of each of the openings.

Provided is a capacitance detection circuit, which has better detection performance. The capacitance detection circuit includes: a first charging and discharging circuit configured to perform charging or discharging on a capacitor to be detected; a second charging and discharging circuit configured to perform charging or discharging on a calibration capacitor; an analog-to-digital conversion circuit configured to continuously sample a voltage difference between the capacitor to be detected and the calibration capacitor in a charging or discharging process to obtain sampled data; and a digital processing circuit configured to detect a capacitance of the capacitor to be detected according to the sampled data.