Abstract: In an embodiment of the invention inductive coupling of an idler coil to a parent coil is used to provide a double resonance circuit without the disadvantages of capacitive coupling to the parent coil. In an embodiment of the invention, an inductive coupling coil can be used to achieve a double-tuned circuit. In an embodiment of the invention, a circuit uses inductive coupling to achieve a double resonance circuit for 1H, 19F, and 13C experiments where one of the three nuclei are observed and the other two are decoupled. In an embodiment of the invention a pivot or a shunt can be used to couple and decouple the idler coil and the parent coil.

Abstract: The present invention provides methods and systems for sensory elements for placement within a probe that includes at least one receiving coil disposed within a pulsed eddy current probe, and at least one sensing element disposed within a pulse eddy current probe. The at least on sensing element may be disposed on a printed circuit board.

Abstract: A measuring arrangement for determining at least one measured variable with a sensor device (2), a signal outlet for outputting of an output signal and a current-adjusting device for adjusting the current of the output signal provides a measuring arrangement whose power consumption is at a maximum for preferably all states of operation. The object is obtained the measuring arrangement that a load current device and a regulating device are provided. Here, the regulating device controls the load current device based on a voltage drop via the current-adjusting device (4).

Abstract: A semiconductor device, a battery monitoring system, and a detection method are provided. An end of the capacitor (C1) is switchable to be connected to one of a positive electrode and a negative electrode of a battery cell. An end of a capacitor (C2) is switchable to be connected to the other electrode. A comparator includes a non-inverted input terminal connectable to the battery cell via the capacitor (C1), and an inverted input terminal connectable to the battery cell via the capacitor (C2). A capacitor (C3) is located between a node (inp) and a switch (S1) that switches a connection state between a ground voltage source and any one of reference voltage sources. A capacitor (C4) is located between a node (inn) and a switch (S2) that switches a connection state between the ground voltage source and any one of the reference voltage sources.

Abstract: A device for monitoring a high-voltage contactor in a vehicle having a coil with an anchor, the coil is energized with a coil current or a coil voltage to switch the high-voltage contactor, and the high-voltage contactor is switched by a motion of the anchor, thus also changing the inductivity of the coil includes an interface for reading in a measurement value function for the generated coil voltage and/or for the generated coil current during the switching cycle of the high-voltage contactor; an analysis device for determining a motion information representing a travel distance of the anchor based on the measurement value function; and a comparison device for comparing the motion information with a threshold value information.

Abstract: A method for testing the integrity of a component in a measurement area of the component, using an instrument having a flexible part and a rigid end part following the flexible part and carrying an eddy current probe. The method comprises a selection step in which a template corresponding to the measurement area is selected, a shaping step in which the flexible part is shaped against the template thus selected, a positioning step, in which the instrument thus shaped is positioned so that the eddy current probe is placed in the measurement area, and a measurement step, in which a measurement is made via the eddy current probe which has been thus positioned.

Abstract: A field-effect transistor includes a source electrode, a drain electrode, and a control electrode. The control electrode is configured as a heating unit having two terminals for receiving a heating voltage for heating the control electrode. The heating unit is configured as a meander-type heating element. A current-measuring device is configured to detect a current flowing between the source electrode and the drain electrode.

Abstract: A magnetic field sensor includes a plurality of transducer legs coupled together as a first circuit to sense a magnetic field, wherein each transducer leg comprises a plurality of magnetoresistance sense elements. The magnetic field sensor also includes a second circuit including a first plurality of current lines, wherein each current line of the first plurality of current lines is adjacent to a corresponding plurality of magnetoresistance sense elements of a transducer leg of the plurality of transducer legs. When at least one current line of the first plurality of current lines is energized, a magnetization of each magnetoresistance sense element of the transducer leg is aligned in a first direction or a second direction opposite to the first direction. A routing pattern of the at least one current line is configured to generate an equal population of magnetoresistance sense elements with magnetization aligned in the first and second directions.

Abstract: An energy storage system may include one or more battery packs, wherein one terminal of the one or more battery packs is electrically coupled to a resistor representative of an isolation resistance of the energy storage system, a semiconductor relay switch, a plurality of resistors configured to electrically couple to the one or more battery packs via the semiconductor relay switch, a gain field-effect transistor (FET) configured to electrically short at least one resistor of the plurality of resistors, one or more capacitors electrically couples to a system ground of a vehicle and the one or more battery packs, and a control system configured to control the semiconductor switch and the gain FET.

Abstract: A test circuit performs fault detection tests on a motor branch circuit, to detect pre-existing faults before a motor start-up to pre-empt potential damage to the motor branch circuit therefrom. The test circuit is configured to be coupled to the phase lines of a motor branch circuit at a set of test points strategically located on the phase lines. The test circuit includes test lines that are each coupled to a different one of the phase lines at one of the set of test points. The test circuit includes a test controller that, during a test mode, sequentially presents a low voltage supply to each phase line through the test line coupled thereto, to test for ground faults then sequentially couples the low voltage supply across each possible pairing of the phase lines to test for line-to-line faults. The test mode can be initiated manually or automatically.

Abstract: A circuit for measuring a gain of an amplifier includes a first node coupled to an output of the amplifier, a second node, a first circuit coupled to an input and the output of the amplifier, and a second circuit coupled between the first circuit and the second node. The first circuit is configured to cause a first gain drop in a gain to be measured between the first node and the second node. The second circuit configured to cause a second gain drop in the gain to be measured between the first node and the second node.

Abstract: A capacitive switch includes a drive circuit, a detection circuit, a reference circuit and an identification unit. The drive circuit outputs a drive signal and a switching signal, wherein the drive signal is outputted to a first node and a second node. The detection circuit is sequentially coupled to the first node and the second node according to the switching signal and generates a first detection signal according to the drive signal. The reference circuit is sequentially coupled to the second node and the first node according to the switching signal and generates a second detection signal according to the drive signal. The identification unit includes a first input terminal and a second input terminal respectively coupled to the first node and the second node, and identifies a phase shift between inputted detection signals received by the first input terminal and the second input terminal.

Abstract: A digital multimeter receives a primary signal including a small amplitude DC component and an induced AC noise component with a magnitude exceeding a magnitude of the DC component. A 100 M? input resistor may couple an primary signal to signal processing circuitry that attenuates and filters the primary signal, convert a unipolar signal to a differential signal, and provide the differential output signal to an analog to digital converter. The multimeter may be configurable to couple any one or more of multiple available feedback paths to provide a plurality of available gain-bandwidth configurations. The multimeter may include a second input configurable with two or more feedback path impedances. The multimeter may include a second stage filter, shared by the primary and shunt inputs, that provides additional filtering and converts the signal to a differential signal. The second stage filter may support two or more available impedance configurations.

Abstract: The invention provides an ESD detection method for array substrate. By connecting the first metal layer on array substrate through the first wire to the first test point, connecting the second metal layer on array substrate through the second wire to the second test point, when ESD occurs on array substrate, the resistance detection device is used to measure the resistance between the first and second test points. If the resistance is positive infinity, ESD did not occur between the first and second metal layers; if the resistance is within a measurable range, ESD occurs between the first and second metal layers. The resistance is used to locate the location of ESD occurrence on array substrate. Compared to known method using microscope to search ESD location, the invention can locate ESD location on array substrate more accurately and rapidly to save time and labor as well as detection cost.

Abstract: A piezoelectric actuator and a method of measuring a motion by using the piezoelectric actuator are provided. The piezoelectric actuator includes: a movable member that is disposed to face the fixed member; a piezoelectric element that is disposed between the fixed member and the movable member, and configured to operate in a shear mode based on input voltages applied to the piezoelectric element and move the movable member relative to the fixed member; and a position sensor that is disposed between the piezoelectric element and the movable member, and configured to measure a motion of the movable member.

Abstract: In order to provide a technique in which, in the TEM type antenna, the uniformity of sensitivity in the internal portion of the antenna can be maintained with simple configuration, without scarifying the internal space of the antenna, regardless of a size, a shape and a location of a load, and also regardless of locations of the constitutional members of the antenna, the TEM type antenna includes rung conductors which branch out into plural pieces in the middle portion and join into one piece in the two end portions. In other words, the rung conductor having a void space in the middle portion of the rung conductor in the longitudinal direction is provided. The adjacent rung conductors are disposed to be further closer to each other in the middle portion, and to maintain the same distance as that in the related art in the end portion.

Abstract: Isolated capacitance line voltage sensing is provided that avoids metal-to-metal contact for voltage sensing of a power signal present on a power wire. An external conductor is positioned by the power wire, creating a capacitor with the power wire conductor, insulation, and external conductor. The capacitance is used to measure the electric field, indicating a voltage level for the powered wire. The impedance mismatch caused by the capacitance is transformed. The impedance transformation circuit may be integrated with the external conductor, allowing voltage sensing by a voltage meter having a lower input impedance. A manual or automatic calibration circuit may be provided to ensure the measured voltage represents the actual voltage on the power wire.

Abstract: A battery monitoring system includes a battery sensor mounted between a plurality of batteries in a battery system for a vehicle using the plurality of batteries. The battery sensor according to an aspect of the present invention, which uses an ammeter resistor connected in series between a first battery and a second battery, includes: a first integrated circuit configured to receive voltages of both electrodes of the first battery and voltages of both terminals of the ammeter resistor to measure a first battery voltage and a one-directional current of the first and second batteries; and a second integrated circuit configured to receive voltages of both electrodes of the second battery to measure a second battery voltage, and receive the first battery voltage and the one-directional current of the first and second batteries from the first integrated circuit through a serial communication interface.

Abstract: Provided is a pulse detection apparatus and a pulse detection method less susceptible to movement of a subject and less susceptible to noise. An oscillation frequency controller is configured to cause a frequency variable oscillator to oscillate at a predetermined oscillation frequency, which is a frequency within a range assumed as a resonance frequency of a molecule of a predetermined constituent constituting the blood flowing through a human body. The oscillation frequency controller also controls an oscillation frequency based on a phase difference signal and an amplitude signal, wherein the phase difference signal indicates the phase difference between a transmission signal transmitted from an antenna to the human body and a reception signal received by the antenna, and the amplitude signal indicates the magnitude of the amplitude of the received signal. A pulse detector detects the change of the amplitude signal in an amplitude direction as a pulse signal.

Abstract: A test assembly system protects a user from potentially energized equipment. Aspects of the system provide access to the equipment through a socket connection and a test probe assembly that is configured to interface with the socket connection to read voltage or continuity across a bus of the equipment being inspected. The probe assembly shields the user from the equipment to prevent energy or arc flashes from projecting out to contact the user.