Abstract: A pixel circuit is provided comprising the following. The first transistor includes a gate electrode and a semiconductor layer comprising a channel region, a source region, a first drain region, and a second drain region. A first portion of the channel region is connected to the source region, a second portion of the channel region is connected to the first drain region, and a third portion of the channel region is connected to the second drain region. The channel width of the second portion is greater than that of the third portion. A capacitive device is connected to the gate of the first transistor. The second transistor includes a source region connected to the second drain region and a drain region connected to the light-emitting element. The third transistor includes a source region connected to the first drain region and a drain region connected to a capacitive device.

Abstract: A wireless charging station, an electric vehicle charged wirelessly, and a method of charging an electric vehicle are provided. A wireless charging station include a charging unit configured to transmit power wirelessly to an electric vehicle, using a source resonator installed in the charging station; and a driving unit configured to move a target resonator connected to the source resonator from a position at which the target resonator is mounted on the charging unit to an installation space of the electric vehicle, when the electric vehicle is disposed in a charging area of the charging station.

Abstract: A test and measurement instrument and method for receiving a radio frequency (RF) signal, digitizing the RF signal using an analog-to-digital converter, downconverting the digitized signal to produce I (in-phase) and Q (quadrature) baseband component information, generating one or more IQ-based time-domain traces using the I and Q baseband component information, and measuring and displaying a variety of measurement values of the IQ-based time-domain traces. The IQ-based time-domain measurement values can be automatically generated and displayed, and/or transmitted to an external device.

Abstract: A charged body sensing electrode is provided which includes a signal generator, a filter and a detector. The signal generator generates an excitation signal, and the filter is coupled to the signal generator and receives the excitation signal from the signal generator. The filter includes at least one charged body sensing unit. The detector is coupled to the filter and detects an output signal corresponding to the filter. Accordingly, when the charged body neared or touched the charged body sensing electrode, the output signal of the filter will be changed. The trajectory, the velocity or the location of the charged body, or the impedance variation of the charged body sensing unit can be obtained by the change of the output signal of the filter which is detected by the detector.

Abstract: Systems and methods are described for transmitting a waveform having a controllable attenuation and propagation velocity. An exemplary method comprises: generating an exponential waveform, the exponential waveform (a) being characterized by the equation Vin=De?ASD[x?vSDt], where D is a magnitude, Vin is a voltage, t is time, ASD is an attenuation coefficient, and vSD is a propagation velocity; and (b) being truncated at a maximum value. An exemplary apparatus comprises: an exponential waveform generator; an input recorder coupled to an output of the exponential waveform generator; a transmission line under test coupled to the output of the exponential waveform generator; an output recorder coupled to the transmission line under test; an additional transmission line coupled to the transmission line under test; and a termination impedance coupled to the additional transmission line and to a ground.

Abstract: A channel estimation method and system using linear correlation based interference cancellation combined with decision-feedback-equalization (LCIC-DFE) are provided. The channel estimation method includes generating a first correlation sequence by calculating a linear correlation between a baseband sampled complex signal and a locally stored pseudo-noise signal and obtaining a second correlation sequence by iteratively removing inter-path interference from the first correlation sequence and generating a first channel impulse response (CIR) sequence based on the second correlation sequence. And, obtaining a third correlation sequence by removing random-data interference from the second correlation sequence based on the first CIR sequence and a feedback signal and generating a second CIR sequence based on the third correlation sequence.

Abstract: A system and method are disclosed for testing a settling time of a device-under-test (DUT). A method for determining a settling time of a device-under-test (DUT) includes activating a DUT to generate an output signal and mixing the output signal of the DUT and a reference signal to generate a mixed signal. An amplitude threshold is set for the mixed signal relative to an amplitude of the mixed signal and the settling time of the DUT is determined based on a last time that the amplitude of the mixed signal crosses the amplitude threshold relative to the activation of the DUT.

Abstract: A device for calculating the steady state behavior of a controller includes an amount generating unit for generating the amount of deviation of the regulator, a first threshold value calculation unit that detects whether the amount of deviation of the regulator has fallen below a first threshold value and then starts a lag time delay unit, and a second threshold value calculation unit that detects whether the amount of deviation of the regulator has fallen below a second threshold value. A signal transmission unit transmits a ready message signal when the lag time delay unit has reached a predetermined lag time and the second threshold value calculation unit has detected that the amount of deviation of the regulator has fallen below the second threshold value.

Abstract: A method for detecting steady-state convergence of a signal compares a filtered version of the signal or its derivative to a threshold over a given time interval, and a measure of the signal variability is used to tune the filter behavior. In one implementation, the signal is filtered with a high-pass filter, and the cut-off frequency of the filter is adjusted inversely with respect to the measured variability of the signal. In another implementation, the signal derivative is filtered with a low-pass filter, and the cut-off frequency of the filter is adjusted in proportion to the measured variability of the signal. In each case, the variability of the signal is measured by computing a differential of the signal and then smoothing the differential.

Abstract: A method and apparatus for determining the center frequency of a bandpass filter. The center frequency of a bandpass filter is determined by applying a bias voltage to a bandpass filter circuit receiving a pair of differential input voltages and producing a pair of differential output voltages. The differential output voltages are modified to exhibit a notchband magnitude characteristic. A minimum value of the differential output voltages exhibiting the notchband characteristic over a predetermined range of frequencies is determined and corresponds to the center frequency of the bandpass filter.

Abstract: A power supply voltage detection device includes a reference voltage generating circuit, an integrator circuit, a lower limit comparator, and an upper limit comparator. The reference voltage generating circuit generates lower and upper limit reference voltages by resistance-dividing a power supply voltage. The integrator circuit integrates comparative voltages extracted by resistance-dividing the power supply voltage. The lower limit comparator compares the lower limit reference voltage from the reference voltage generating circuit with an output voltage from the integrator circuit to detect that the power supply voltage becomes equal to or lower than a lower limit. The upper limit comparator compares the upper reference voltage from the reference voltage generating circuit with an output voltage from the integrator circuit to detect that the power supply voltage becomes equal to or higher than an upper limit.

Abstract: A method of determining a response characteristic of a microwave device includes coupling a microwave resonator to the device, loading the resonator with microwave radiation, monitoring the time decay of power from the resonator, and comparing the monitored time decay with a known characteristic of the time decay of radiation in the microwave resonator when loaded with radiation.

Abstract: A multi-processing transient event detector for use in a nonintrusive electrical load monitoring system has been provided. Templates of transient pattern data associated with each electrical load which may be monitored are stored. Such templates are then used to match and correlate with the actual monitored transient pattern data at the load site. The decomposition in which time scales are changed is accomplished in parallel along with one or more parallel event detection processing modules for each decomposition.

Abstract: A method and apparatus for determining when transient responses of a signal have ended. A plurality of filters is provided. Operation of success of filters is cause to begin at successive times. The convergence of the outputs of the various filters is then tested. When convergence is detected, the signal provided by the first started filter of the successive filters that indicated convergence is used as an output signal. The signal is typically an electronic module test signal from an electronic module. Testing for convergence is performed by averaging outputs of each filter started to determine an average value; determining a deviation of each output of the filters from the average value; totaling the deviation to determine a total deviation; and comparing the total deviation to a reference level. Preferably, the total deviation is integrated over a period of time to provide an integrated total deviation; and the integrated total derivation is compared to the reference level.

Abstract: A method and apparatus for measuring the settling time of frequency changes in a voltage controlled oscillator (VCO) are disclosed. A signal splitter is responsive to the VCO for splitting the output signal between first and second channels. A delay circuit in one of the channels introduces a delay and corresponding phase shift of one signal relative to the other, and a phase detector produces a phase signal proportional to the phase shift indicative of the settling time of the VCO. A control circuit coupled to the phase detector and the VCO produces a step voltage initiating signal for changing the VCO output frequency. A detector responsive to the initiating signal and the phase signal produces an output indicative of the settling time with respect to the control signal in the modulation domain.

Abstract: A method for improving accuracy of estimating natural frequency of a distribution system. The estimation is performed in order to identify a rectifier load that generates harmonics due to commutation oscillation. It includes the steps of measuring a charging current flowing into a power factor improving capacitor to obtain first data, removing fundamental frequency from the first data to obtain second data, determining, from the second data, a first time at which the amplitude of commutating oscillation components takes a maximum value, picking up third data in the interval beginning from the first time and ending at a second time later than the first time by T/N, where T is the period of the fundamental frequency, and N is the number of rectifier phases, performing frequency analysis on the third data to form fourth data by expanding the third data into a Fourier series, and determining a local peak frequency, that is, the natural frequency in the fourth data.

Abstract: A method for improving accuracy of estimating natural frequency of a distribution system. The estimation is performed in order to identify a rectifier load that generates harmonics due to commutation oscillation. It includes the steps of measuring a charging current flowing into a power factor improving capacitor to obtain first data, removing fundamental frequency from the first data to obtain second data, determining, from the second data, a first time at which the amplitude of commutating oscillation components takes a maximum value, picking up third data in the interval beginning from the first time and ending at a second time later than the first time by T/N, where T is the period of the fundamental frequency, and N is the number of rectifier phases, performing frequency analysis on the third data to form fourth data by expanding the third data into a Fourier series, and determining a local peak frequency, that is, the natural frequency in the fourth data.

Abstract: An inverse scattering processing method with enhanced noise immunity and resolution capabilities for use in modeling multi-layer acoustic, electromagnetic or other propagating media. A time bounded filtering step is incorporated within a peeling method for use in processing TDR characteristic waveforms of the propagating media.

Abstract: Settling time of an electrical device under test in response to a step wave input voltage is determined by first establishing first and second output voltage levels which differ from a settled output voltage level by preestablished voltage differentials, and then determining the time after applying a step wave voltage to the device under test when the output voltage equals the first and second voltages. A voltage controlled oscillator is utilized in triggering the step wave voltage generator and in enabling a voltage comparator whereby the period of the voltage control oscillator is a measure of the settling time of the device under test.

Abstract: A variable transient simulator employs a source of pulsating DC voltage for charging a first capacitance bank to a desired potential difference. After a device under test (DUT) is connected to a second capacitance bank, the charged-up first capacitance band is isolated from the DC voltage source and allowed to discharge into the second capacitance bank and, together, both capacitance banks provide discharging current into the DUT which simulates a desired loop during transient response. The simulator can provide repetitive as well as variable positive and negative transients.

Abstract: The invention relates to a method and apparatus for testing the response of a stress wave sensor to check that the transducer and amplifier are working satisfactorily.A pulse generator is connected to the stress wave sensor at a point between the transducer and the amplifier. The pulse generator supplies an electrical pulse to the stress wave sensor. A pulse cancelling device prevents the electrical pulse going directly to the amplifier. The electrical pulse causes the transducer to emit stress wave energy into a structure to which the transducer is acoustically coupled. The transducer detects the stress wave propagating in the structure and supplies an electrical signal to the amplifier. The electrical signal is amplified by the amplifier and demodulated by demodulator. A processor measures the peak and area of the demodulated amplified electrical signal and comares them with stored values.