Class / Patent application number | Description | Number of patent applications / Date published |
327362000 | With compensation | 11 |
20080284490 | Compensated operational amplifier and active RC filter including such an amplifier - A method of compensating a monolithic integrated operational amplifier against process and temperature variations, such that the operational amplifier is suitable for use in an active filter, the method comprising a providing an amplifier having a first stage and an output stage, wherein the output stage drives an RC load, and wherein a compensation capacitor at an output of the first stage is selected so as to scale with the capacitance C of the RC load, and a transconductance of the first stage is a function of the resistance R of the RC load. | 11-20-2008 |
20080297226 | Enhanced Output Impedance Compensation - A compensation circuit for compensating an output impedance of at least a first MOS device over PVT variations to which the first MOS device may be subjected includes a first current source generating a first current having a value which is substantially constant and a second current source generating a second current having a value which is programmable as a function of at least one control signal presented to the second current source. A comparator is connected to respective outputs of the first and second current sources and is operative to measure a difference between the respective values of the first and second currents and to generate an output signal indicative of relative magnitudes of the first current and the second current. A processor connected in a feedback arrangement between the comparator and the second current source receives the output signal generated by the comparator and generates the control signal for controlling the second current as a function of the output signal. The processor is operative to control the value of the second current so that the second current is substantially equal to the first current. | 12-04-2008 |
20090002053 | Offset compensation using non-uniform calibration - Methods and systems for offset compensation using calibration are provided. Embodiments enable offset compensation using non-uniform calibration. Embodiments enable calibration schemes configurable according to the probability distribution function (PDF) of the random offset. Embodiments enable calibration schemes configurable with multiple levels of calibration resolution according to the PDF of the random offset. Embodiments enable calibration schemes configurable with multiple calibration step values according to the PDF of the random offset. Embodiments can be implemented for various types of random offset, including, without limitation, Gaussian-, Bernoulli-, uniformly-, Chi-, exponentially-, Gamma-, and Pareto-distributed offset. | 01-01-2009 |
20100045359 | CALIBRATION CIRCUIT - To include a first replica buffer that has substantially the same circuit configuration as a pull-up circuit which constitutes an output buffer and a second replica buffer that has substantially the same circuit configuration as a pull-down circuit which constitutes the output buffer. When a first calibration command ZQCS is issued, either a control signal ACT | 02-25-2010 |
20100182068 | METHOD AND APPARATUS FOR ACCOUNTING FOR CHANGES IN TRANSISTOR CHARACTERISTICS - A device for accounting for changes in characteristics of a transistor is presented. The device includes a transistor and a comparator receiving a feedback signal from the transistor and a reference signal. The comparator provides an output to a bias voltage generator. The bias voltage generator includes an input connected to the output of the comparator and an output connected to the transistor. In some embodiments of the invention the transistor is a double gate transistor and the bias voltage generator is applied to a top gate of the double gate transistor in order to control characteristics of the transistor such as turn on voltage. | 07-22-2010 |
20110267131 | METHOD AND APPARATUS FOR COMPENSATING PERIODIC SIGNAL - An apparatus and a method for compensating periodic signal in an optical disc drive are described. The control apparatus includes an amplitude processing unit, a phase processing unit, a wave generator, a first switch module and a second switch module. The amplitude processing unit processes the amplitude of the input signal based on a reference signal for generating an amplitude signal. The phase processing unit processes the phase of the input signal based on the reference signal for generating a phase signal. The first switch module switches the amplitude signal to select one of the amplitude value and a predetermined amplitude value. The second switch module switches the phase signal to select one of the phase value and a predetermined phase value. The wave generator generates a compensated wave signal based on the selected amplitude value and the selected phase value, and outputs the compensated wave signal. | 11-03-2011 |
20120007652 | SIGNAL MONITORING SYSTEMS - A signal monitoring system includes a conversion circuit and a controller coupled to the conversion circuit. The conversion circuit converts a reference input to a reference output based on a real-time level of a trim reference and converts a monitored signal to an output signal. The controller calibrates the output signal according to the reference output and according to a predefined reference. The predefined reference is determined by the reference input and by a pre-trimmed level of the trim reference. | 01-12-2012 |
20120218022 | Accurate Current Sensing with Heat Transfer Correction - In one embodiment, a current sensing circuit corrects for the transient and steady state temperature measurement errors due to physical separation between a resistive sense element and a temperature sensor. The sense element has a temperature coefficient of resistance. The voltage across the sense element and a temperature signal from the temperature sensor are received by processing circuitry. The processing circuitry determines a power dissipated by the sense element, which may be instantaneous or average power, and determines an increased temperature of the sense element. The resistance of the sense element is changed by the increased temperature, and this derived resistance Rs is used to calculate the current through the sense element using the equation I=V/R or other related equation. The process is iterative to continuously improve accuracy and update the current. | 08-30-2012 |
20120268192 | HIGH-LINEARITY TESTING STIMULUS SIGNAL GENERATOR - A high-linearity testing stimulus signal generator comprises a signal collection unit receiving an input current signal, a waveform conversion unit connecting with the signal collection unit, a first voltage-to-current conversion unit connecting with the waveform conversion unit, a delay unit connecting with the waveform conversion unit, a second voltage-to-current conversion unit connecting with the delay unit, a current comparison unit connecting respectively with the first voltage-to-current conversion unit and the second voltage-to-current conversion unit, an error calculation unit connecting with the current comparison unit, and a compensation unit connecting with the error calculation unit. The above-mentioned structure forms a feedback mechanism to perform compensation adjustment to promote the linearity of the output signals. Thus, the present invention can generate high-accuracy testing stimulus signals. | 10-25-2012 |
20130154714 | CURRENT-MODE SAMPLE AND HOLD FOR DEAD TIME CONTROL OF SWITCHED MODE REGULATORS - A system for current mode sample and hold, comprising a first PMOS transistor configured to generate a current to be sampled. A diode-connected NMOS transistor coupled to the first PMOS transistor and configured to receive the current. A switch coupled to the diode-connected NMOS transistor and configured to sample a gate-source voltage of the diode-connected NMOS transistor. A capacitor coupled to the switch and configured to stored the gate-source voltage of the diode-connected NMOS transistor. A second NMOS transistor coupled to the capacitor and configured to generate a current equal to the sampled current value. | 06-20-2013 |
20130176068 | SENSOR OUTPUT CORRECTION CIRCUIT, SENSOR OUTPUT CORRECTION DEVICE, AND SENSOR OUTPUT CORRECTION METHOD - A sensor output correction circuit includes an analog-to-digital converter configured to receive an input voltage corresponding to a sensor output of a sensor and a reference voltage that are selectively input to the analog-to-digital converter; and an arithmetic unit configured to correct output data, which is output from the analog-to-digital converter when the input voltage is input to the analog-to-digital converter, based on an output value that is output from the analog-to-digital converter when the reference voltage is input to the analog-to-digital converter. The arithmetic unit includes a multiply adder and a non-restoring divider. | 07-11-2013 |