Patent application number | Description | Published |
20100159848 | SYSTEM AND METHOD FOR SATURATION DETECTION, CORRECTION AND RECOVERY IN A POLAR TRANSMITTER - A system for saturation detection, correction and recovery in a power amplifier includes a power amplifier, a closed power control loop configured to develop a power control signal (V | 06-24-2010 |
20120134401 | SYSTEM AND METHOD FOR CLOSED LOOP POWER CONTROL CALIBRATION - A system for calibrating a closed power control loop includes an adder configured to inject a test signal into an adjustable element, a first peak detector configured to determine an amplitude of the injected test signal, a second peak detector configured to determine an amplitude of a return test signal, a comparator configured to determine the difference between the injected test signal and the return test signal, and a calibration engine configured to adjust the adjustable element so that the return test signal is offset from the injected test signal by a predetermined amount. | 05-31-2012 |
20120153994 | Methods and Implementation of Low-Power Power-On Control Circuits - Methods and implementation of low-power power-on control circuits are disclosed. In a particular embodiment, an apparatus includes a power detector circuit powered by a first voltage supply. At least one voltage level-shifting device is coupled to a second voltage supply and a test input is provided to the power detector circuit. An optional leakage self-control device may reduce unwanted leakage currents associated with the first supply and the second supply. | 06-21-2012 |
20130082744 | Apparatus to Implement Symmetric Single-Ended Termination in Differential Voltage-Mode Drivers - A differential voltage mode driver for implementing symmetric single ended termination includes an output driver circuitry having a predefined termination impedance. The differential voltage mode driver also includes an output driver replica having independently controlled first and second portions. The first and second portions are independently controlled to establish a substantially equal on-resistance of the first and the second portions. The output driver replica controls the predefined termination impedance of the output driver circuitry. | 04-04-2013 |
20130187717 | RECEIVER EQUALIZATION CIRCUIT - A receiver equalization circuit includes a first output transistor having a gate coupled to an input signal. The receiver equalization circuit may also include a second output transistor having a drain coupled to a drain of the first output transistor. The receiver equalization circuit may also include a resistor coupled between a gate and a drain of the second output transistor to provide a direct current (DC) bias to the gate of the second output transistor. The receiver equalization circuit may further include a feed-through capacitor coupled between the gate of the second output transistor and an input signal source. The feed-through capacitor feeds the input signal to the gate of the second output transistor when a frequency of the input signal is above a predetermined threshold. The feed-through capacitor and the resistor define a signal gain amplification point. | 07-25-2013 |
20130191679 | DUAL MODE CLOCK/DATA RECOVERY CIRCUIT - A clock/data recovery circuit includes an edge detector circuit operable to receive a serial data burst and to generate a reset signal in response to a first edge of the serial data burst. The clock/data recovery circuit may also include an oscillator coupled to the edge detector circuit. The oscillator locks onto a target data rate prior to receipt of the serial data burst and locks onto a phase of the serial data burst in response to the reset signal. The clock/data recovery circuit may also include a phase detector circuit that receives the serial data burst. The phase detector circuit is coupled to the oscillator. The phase detector circuit adjusts the oscillator to maintain the lock onto the phase of the serial data burst during the serial data burst. | 07-25-2013 |
20140025325 | Voltage Level-Shifting - Methods and implementation of low-power power-on control circuits are disclosed. In a particular embodiment, a computer readable tangible medium stores instructions executable by a computer. The instructions may be executable by the computer to determine whether a power detector circuit powered by a first voltage supply has received a test input from at least one voltage level-shifting device coupled to a second voltage supply. | 01-23-2014 |
20140070898 | Low Phase Noise Voltage Controlled Oscillators - A voltage controlled oscillator (VCO) with low phase noise and a sharp output spectrum is desirable. The present disclosure provides embodiments of LC tank VCOs that generate output signals with less phase noise compared with conventional LC tank VCOs, while at the same time limiting additional cost, size, and/or power. The embodiments of the present disclosure can be used, for example, in wired or wireless communication systems that require low-phase noise oscillator signals for performing up-conversion and/or down-conversion. | 03-13-2014 |
20140152391 | SYSTEMS AND METHODS FOR MAINTAINING POWER AMPLIFIER PERFORMANCE - Systems and methods for maintaining power amplifier performance are provided. A system includes a bias supply that generates a bias voltage, and at least one primary power amplifier (PA) that receives the bias voltage and a primary radio frequency (RF) input. The at least one primary PA amplifies the primary RF input based on the bias voltage. The system includes an auxiliary PA that is connected in parallel with the at least one primary PA and receives the bias voltage and an auxiliary RF input, which is a scaled version of the primary RF input. The auxiliary PA amplifies the auxiliary RF input based on the bias voltage. The system includes a detector that measures an output voltage associated with the amplified auxiliary RF input, and a comparator that compares the measured output voltage to a reference voltage. The bias supply adjusts the bias voltage based on the comparison. | 06-05-2014 |
20140306755 | LOW INDUCTANCE TRANSFORMER - A transformer has first and second transformer windings including multiple differential ports. Each of the first and second transformer windings include a first transformer half-winding coupled to a first differential port of the differential ports. Each of the first and second transformer windings also include a second transformer half-winding coupled to a second differential port of the differential ports. Each of the first and second transformer windings is divided symmetrically at a common node to form the respective first and second transformer half-windings. The first transformer half-winding is configured to form one half of an inductance in each of the first and second transformer windings. The second transformer half-winding is configured to form another half of the inductance in each of the first and second transformer windings. The common node of the first transformer winding is configured to receive a supply voltage. | 10-16-2014 |
20140313088 | METHOD OF ANTENNA IMPEDANCE MISMATCH COMPENSATION BASED ON TIME-TO-DIGITAL CONVERTER PHASE ESTIMATION - A method for an antenna mismatch compensation may include determining an amplitude ratio by measuring a ratio of amplitudes of a reflected signal and an incident signal of an antenna tuning circuit coupled to an antenna. A time difference between the reflected signal and the incident signal may be measured. The time difference may be converted to a phase difference. A topology and one or more parameters of the antenna tuning circuit may be determined based on the amplitude ratio and the phase difference so that the antenna tuning circuit compensates for the antenna mismatch. | 10-23-2014 |
20150084708 | Low Phase Noise Voltage Controlled Oscillators - A voltage controlled oscillator (VCO) with low phase noise and a sharp output spectrum is desirable. The present disclosure provides embodiments of LC tank VCOs that generate output signals with less phase noise compared with conventional LC tank VCOs, while at the same time limiting additional cost, size, and/or power. The embodiments of the present disclosure can be used, for example, in wired or wireless communication systems that require low-phase noise oscillator signals for performing up-conversion and/or down-conversion. | 03-26-2015 |