Abstract: Systems, methods, and devices for receiving a differential input signal and generating a non-differential output signal are described herein. For example, an RF buffer is described that includes first and second transistor elements. The first transistor element receives a first polarity signal of a differential signal and drives a non-differential output of the RF buffer. A second transistor element receives a second polarity signal of the differential signal and drives the non-differential output of the RF buffer. The first and second transistor elements substantially simultaneously drive the non-differential output of the RF buffer.

Abstract: Systems, methods, and devices provided herein are directed to improvements in gain control amplifiers that receive an input signal and generate an output signal with a selectively variable gain. A differential amplified gain stage receives an input signal and scales the input signal to generate a scaled signal. A gain adjust stage receives the scaled signal and an adjust signal and adjusts an amplitude of the scaled signal based on the adjust signal to generate an adjusted scaled signal. The adjusted scaled signal has a substantially constant impedance regardless of value of the adjust signal.

Abstract: Systems, methods, and devices provided herein are directed to improvements in gain control amplifiers that receive an input signal and generate an output signal with a selectively variable gain. A differential amplified gain stage receives an input signal and scales the input signal to generate a scaled signal. A gain adjust stage receives the scaled signal and an adjust signal and adjusts an amplitude of the scaled signal based on the adjust signal to generate an adjusted scaled signal. The adjusted scaled signal has a substantially constant impedance regardless of value of the adjust signal.

Abstract: Systems, methods, and devices for receiving a differential input signal and generating a non-differential output signal are described herein. For example, an RF buffer is described that includes first and second transistor elements. The first transistor element receives a first polarity signal of a differential signal and drives a non-differential output of the RF buffer. A second transistor element receives a second polarity signal of the differential signal and drives the non-differential output of the RF buffer. The first and second transistor elements substantially simultaneously drive the non-differential output of the RF buffer.

Abstract: A high voltage control switch including a voltage controller and a control switch is provided. The high voltage control switch splits the control switching of high voltages into two ranges. The voltage controller determines the on and off voltages appropriate for the application based on the range the input signal is in. The control switch then outputs the appropriate voltages determined by the voltage controller based on a logic input. As such, the high voltage control switch provides fast and reliable operation for high voltage switching applications.

Abstract: Signal coincidence detection circuits and methods implemented in such circuits are disclosed. An example signal coincidence detection circuit includes a first differential transistor pair, a second differential transistor pair coupled with the first differential transistor pair and a third differential transistor pair coupled with the first differential transistor pair in parallel with the second differential transistor pair. The circuit also includes a first input signal terminal coupled with the first, second and third differential transistor pairs, wherein, in operation, the first input signal terminal receives a first input signal that is communicated to the first, second and third differential transistor pairs.

Abstract: Variable gain amplifier (VGA) circuits and methods implemented in such circuits are disclosed. An example VGA circuit includes a differential transistor pair for receiving a differential input signal. The differential transistor pair, in operation, conducts a substantially constant current over a linear operating range of the variable gain amplifier circuit. The VGA circuit also includes a current source that is coupled with the differential transistor pair. The current source, in operation, provides the substantially constant current to the differential transistor pair. The VGA circuit further includes a variable resistance circuit coupled with the differential transistor pair. In operation, a resistance of the variable resistance circuit is adjusted such that a gain of the variable gain amplifier circuit is adjusted. Further, in operation, the VGA circuit produces a differential output signal, the differential output signal being an amplified version of the differential input signal.

Abstract: Mixer circuits with direct-current bias are disclosed. An example embodiment of such a mixer includes a first differential transistor pair and a second differential transistor pair. The example mixer also includes first and second local oscillator signal terminals and first and second mixed signal terminals. The first and second local oscillator signal terminals are coupled with the first and second differential transistor pairs. The first mixed signal terminal is coupled with the first differential pair and the second mixed signal terminal is coupled with the second differential pair. The mixer further includes first and second baseband signal terminals, where each baseband signal terminal is coupled with the first differential pair and the second differential pair. The mixer still further includes a first current source and a second current source.

Abstract: A mixer circuit is disclosed that includes a first mixer stage including first and second transmission gates. The mixer circuit also includes a second mixer stage including third and fourth transmission gates. The mixer further includes a first base band signal terminal coupled with the first and second transmission gates and a second base band signal terminal coupled with the third and fourth transmission gates. The mixer circuit processes signals so as to mix a base band signal communicated to the first and second base band signal terminals with a differential LO signal communicated to first and second LO signal terminals to create a first mixed differential signal. Alternatively, the mixer extracts a base band signal from a mixed signal communicated to the first and second mixed signal terminals signal using the LO signal communicated to the first and second LO signal terminals.

Abstract: A mixer circuit in accordance with the invention includes a first mixer stage comprising a first and second transmission gates, and a second mixer stage comprising third and fourth transmission gates. The mixer further includes a first base band signal terminal coupled with the first and second transmission gates and a second base band signal terminal coupled with the third and fourth transmission gates. The mixer circuit processes signals so as to mix a base band signal communicated to the first and second base band signal terminals with a differential LO signal communicated to first and second LO signal terminals to create a first mixed differential signal. Alternatively, the mixer extracts a base band signal from a mixed signal communicated to the first and second mixed signal terminals signal using the LO signal communicated to the first and second LO signal terminals.

Abstract: A capacitance-type height gage for measuring the distance between a test probe and a surface includes comparison circuitry for detecting the phase angle difference between the test probe signal and a reference signal. The reference signal having an adjustable phase angle. Phase angle comparison is achieved by multiplying the test probe signal with the reference signal and filtering the output. The filtered output is inversely proportional to the distance between the test probe and the surface. Compensation circuitry is included for cancelling stray capacitance.