A water sensor for detecting water in gas oil filters having a first and a second electrode a first and a second earth connection for earthing the first electrode and the second electrode; a first switch arranged in the first earth connection; a second switch arranged in the second earth connection; a first and a second current connection for injecting a first current into the first electrode and a second current into the second electrode; and a current-generating circuit connected to the first electrode and to the second electrode through the first current connection and the second current connection respectively, and designed to inject the first current into the first electrode and the second current into the second electrode, the first current and the second current being the same.

A method for determining an electrical capacitance in an intermediate circuit of an electric drive system. The electric drive system includes at least one first electrical energy source, which feeds the intermediate circuit, a drive unit, which has an inverter and an electrical load, the inverter being electrically connected on the input side with the intermediate circuit and on the output side with the electrical load, and a DC voltage converter, which is electrically connected with the intermediate circuit and measures a voltage in the intermediate circuit by high frequency sampling. The electrical capacitance in the intermediate circuit is determined from the voltage in the intermediate circuit measured by the DC voltage converter. Also described is a motor vehicle, which includes an electric drive system for implementing the method.

A driver circuit driving a plurality of capacitive loads includes: a plurality of output terminals to which the plurality of capacitive loads are to be connected; a plurality of drivers corresponding to the plurality of output terminals, each of the plurality of drivers being configured to generate a drive signal to be applied to each of the plurality of capacitive loads respectively corresponding to the plurality of drivers; and a capacitance detection circuit configured to detect a capacitance associated with each of the plurality of output terminals.

The present disclosure relates to conveyorized systems for processing a plurality of mobile telecommunication devices simultaneously. The present disclosure also relates to methods of processing a plurality of mobile telecommunication devices.

A method of screening a lot of capacitors is provided. The method includes measuring a first leakage current of each individual capacitor in a first set of capacitors and calculating a first mean leakage current; removing each of the individual capacitors having a measured first leakage current equal to or above a first predetermined value, forming a second set of capacitors; subjecting the second set of capacitors to a burn in treatment; measuring a second leakage current for each of the individual capacitors in the second set and calculating a second mean leakage current; comparing the second leakage current for each of the individual capacitors to the first leakage current for each of the individual capacitors; and removing each of the individual capacitors having a second leakage current equal to or above a second predetermined value and/or having a second leakage current that does not change by a specified amount compared to the first leakage current for each of the individual capacitors.

Probe systems and methods are disclosed herein. The methods include directly measuring a distance between a first manipulated assembly and a second manipulated assembly, contacting first and second probes with first and second contact locations, providing a test signal to an electrical structure, and receiving a resultant signal from the electrical structure. The methods further include characterizing at least one of a probe system and the electrical structure based upon the distance. In one embodiment, the probe systems include a measurement device configured to directly measure a distance between a first manipulated assembly and a second manipulated assembly. In another embodiment, the probe systems include a probe head assembly including a platen, a manipulator operatively attached to the platen, a vector network analyzer (VNA) extender operatively attached to the manipulator, and a probe operatively attached to the VNA extender.

A bonding apparatus according to the present disclosure includes a bonding tool that bonds a wire to a terminal, a guide member that guides the wire, a clamp made of a conductive material and capable of fixing the wire, and an electrical property measurement unit electrically connected to the clamp. The clamp is configured to be electrically connected to the wire when the wire is fixed. After the wire is bonded to the terminal using the bonding tool, the bonding apparatus carries out a tensile test for fixing the wire using the clamp and pulling the wire bonded to the terminal with a predetermined load and an electrical property test for measuring an electrical resistance of a junction between the wire and the terminal using the electrical property measurement unit.

Apparatus and associated methods relate to a functional self-test, including (1) generation of an excitation signal, (2) applying the excitation signal to a unit under test (UUT), the excitation signal including a cyclical signal for a first interval and substantially zero signal for a second interval, (3) determining frequency content of a UUT response signal, and (4) generating a fail result in response to the frequency content below a predetermined threshold. In an illustrative example, the UUT may be a piezoelectric element (PE). The UUT response signal may be processed by a filter, for example. A portion of the filtered UUT response signal, responding to the second interval of the excitation signal, may be analyzed by a fast Fourier transform module (FFTm), for example. In various implementations, the functional self-test may advantageously determine the health of a piezoelectric gas sensing element, periodically, in a field-deployed implementation.

Apparatus and associated methods relate to a functional self-test, including (1) generation of an excitation signal, (2) applying the excitation signal to a unit under test (UUT), the excitation signal including a cyclical signal for a first interval and substantially zero signal for a second interval, (3) determining frequency content of a UUT response signal, and (4) generating a fail result in response to the frequency content below a predetermined threshold. In an illustrative example, the UUT may be a piezoelectric element (PE). The UUT response signal may be processed by a filter, for example. A portion of the filtered UUT response signal, responding to the second interval of the excitation signal, may be analyzed by a fast Fourier transform module (FFTm), for example. In various implementations, the functional self-test may advantageously determine the health of a piezoelectric gas sensing element, periodically, in a field-deployed implementation.

A current detection system includes an inductor and a detection circuit coupled across the inductor. The inductor is configured to receive an input signal that includes an input current and generate a voltage across the inductor. The current detection circuit includes a sensing network and a transconductance amplifier. The sensing network includes a capacitor and is configured to monitor a voltage across the inductor. The transconductance amplifier is configured to receive a differential voltage indicative of a voltage drop across the capacitor and output a differential output current proportional to the differential voltage.