Patent application number | Description | Published |
20090027126 | METHOD FOR ADAPTIVE BIASING OF FULLY DIFFERENTIAL GAIN BOOSTED OPERATIONAL AMPLIFIERS - An adaptive biasing technique improves fully differential gain boosted operational amplifiers transient characteristics and reduces power consumption. An adaptive biasing module includes a bias generation module and a bias replication module. The bias generation module generates a first control signal (VCMNB) and the first control signal is applied as an output common mode of a differential booster (inside the bias replication module). The bias replication module is coupled to the bias generation module for equalizing a common mode of the differential booster with the first control signal (VCMNB). | 01-29-2009 |
20100117710 | SWITCHED CHARGE STORAGE ELEMENT NETWORK - A switched charge storage element integrator in a continuous or discrete time circuit, the integrator including a differential input amplifier, a first 2-terminal charge storage element, a second 2-terminal charge storage element, and a plurality of controlled switches. The differential input amplifier is coupled to a capacitor and a resistor and configured as an inverting integrator. An inverting terminal of the amplifier is coupled to two controlled switches. A non-inverting terminal of the amplifier is coupled to a reference voltage. The first and second switched charge storage element blocks are alternatingly coupled to the inverting terminal INM of the amplifier XOPA during the active state of a second clock signal and a first clock signal, respectively, for making the supply noise continuous and eliminating its dependency on the clock phases, thereby zeroing its convolution with the clock signal. | 05-13-2010 |
20110001518 | OPERATING A SWITCHED-CAPACITOR CIRCUIT WITH REDUCED NOISE - Techniques for operating a switched-capacitor circuit to reduce input and feedback dependence and/or reduce reference modulation. A switched-capacitor circuit can be operated in four phases. In a first phase at a start of a cycle, the capacitor is charged/discharged by a common mode signal to mask any residual charge stored in the capacitor from a previous cycle. In a second phase, the capacitor is charged with an input signal. During a third phase, the capacitor is charged with a wide-bandwidth auxiliary reference signal, and during a fourth phase the capacitor is charged with a reference signal. During the third and fourth phases, the capacitor may be coupled to an integrating to circuit to integrate a difference between the input signal and the reference signal. | 01-06-2011 |
20110032136 | REDUCTION IN KICKBACK EFFECT IN COMPARATORS - The present disclosure relates to reduction in the effect of kickback in comparators by means of charge injection implemented by means of voltage controlled switches with attributes similar to those of an input differential pair. The voltage controlled switches produce charge to neutralize the charge loss during latching of inputs in the comparator. | 02-10-2011 |
20130127646 | MULTIPLYING DIGITAL-TO-ANALOG CONVERTER (DAC) - An embodiment of a multiplying digital-to-analog converter (MDAC), an embodiment of a method for converting a digital signal to an analog signal, an embodiment of a pipelined analog-to-digital converter (ADC), and a method of converting an analog signal to a digital signal in a plurality of cascading stages. | 05-23-2013 |
20130141263 | CALIBRATION METHOD AND CIRCUIT - An analog input signal is sampled, and the sampled analog input signal is converted to a digital value. A calibration value is also sampled, and a single bit of an N bit offset value is calculated from the sampled calibration value. The sampling operations are alternatively performed so that one bit of the offset value is generated for each generated digital value. For example, the process is repeated N times to calculate all N bits of the offset value while generating N digital values. | 06-06-2013 |
20140035672 | LEVEL SHIFTING CIRCUIT WITH ADAPTIVE FEEDBACK - An amplifier has a first pull-up path coupled between a voltage supply node and an output node, and a pull-down path coupled between the output node and a ground supply node. A second pull-up path is coupled between the voltage supply node and the output node. The second pull-up path is actuated by a feedback signal and biased by a biasing signal. An inverter circuit is operable to invert the signal at the amplifier output node to generate the feedback signal. A biasing circuit is configured to generate the biasing signal. The biasing circuit is configured to control a relative strength of the pull-down path to the second pull-up path, wherein the pull-down path is stronger than the second pull-up path in a manner that is consistently present over all PVT corners. | 02-06-2014 |
20140253213 | LEVEL SHIFTING CIRCUIT WITH ADAPTIVE FEEDBACK - An amplifier has a first pull-up path coupled between a voltage supply node and an output node, and a pull-down path coupled between the output node and a ground supply node. A second pull-up path is coupled between the voltage supply node and the output node. The second pull-up path is actuated by a feedback signal and biased by a biasing signal. An inverter circuit is operable to invert the signal at the amplifier output node to generate the feedback signal. A biasing circuit is configured to generate the biasing signal. The biasing circuit is configured to control a relative strength of the pull-down path to the second pull-up path, wherein the pull-down path is stronger than the second pull-up path in a manner that is consistently present over all PVT corners. | 09-11-2014 |
20150280728 | ADAPTIVE DELAY BASED ASYNCHRONOUS SUCCESSIVE APPROXIMATION ANALOG-TO-DIGITAL CONVERTER - An asynchronous SAR ADC to convert an analog signal into a series of digital pulses in an efficient, low power manner. In synchronous SAR ADC circuits, a separate and cumbersome clock signal is used to trigger the internal circuitry of the SAR ADC. Instead of triggering the components of the SAR DAC synchronously with a clock signal, the asynchronous solution uses its own internal signals to trigger its components in an asynchronous cyclic manner. Further, in order to increase efficiency and guard against circuit failures due to difficulties arising from transient signals, the asynchronous SAR ADC may also include a delay circuit for introducing a variable delay to the SAR ADC cycle. | 10-01-2015 |
20160056830 | ADAPTIVE DELAY BASED ASYNCHRONOUS SUCCESSIVE APPROXIMATION ANALOG-TO-DIGITAL CONVERTER - An asynchronous SAR ADC converts an analog signal into a series of digital pulses in an efficient, low power manner. In synchronous SAR ADC circuits, a separate and cumbersome clock signal is used to trigger the internal circuitry of the SAR ADC. Instead of triggering the components of the SAR DAC synchronously with a clock signal, the asynchronous solution uses its own internal signals to trigger its components in an asynchronous cyclic manner. Further, in order to increase efficiency and guard against circuit failures due to difficulties arising from transient signals, the asynchronous SAR ADC may also include a delay circuit for introducing a variable delay to the SAR ADC cycle. | 02-25-2016 |