Abstract: A post-HPA filter rejection equalizer system and method locally equalizes post-HPA filtering. A predistorter (20) uses a phase error to control the predistortion, and an equalizer (46) uses a magnitude error to control the equalization. The equalizer samples the HPA output multiple occurrences in a burst fashion. The equalized signal is then used to determine phase and magnitude errors. The phase errors (54) are used to update the predistorter (20), and the magnitude errors (52) are used to update the analytic equalizer.

Abstract: A low power serial A/D converter cascades multiple stages (20) of a novel track-and-hold circuit (22) to implement a pipelined A/D converter. The track-and-hold circuit (22) is implemented using a differential structure to cancel out signal droop. This allows extremely high tracking bandwidths to be achieved while maintaining long hold times. Each stage (20) of the pipeline includes a binary quantizing circuit (24) which performs a 1-bit binary estimate of the data and a summing circuit (26) which updates the output of its track-and-hold circuit (22) to allow the next bits to be decided by the following stages.

Abstract: A high speed, low power 3-2 adder (300, 500) with latchable outputs comprises a most significant bit (MSB) adder circuit (100) and a least significant bit (LSB) adder circuit (200). MSB adder circuit (100) includes three differential data inputs (A1, B1, and C1), a latch enable input (LE1), three separate bias points, and an MSB output. In addition the LSB adder circuit includes three differential data inputs (A2, B2, and C2), a latch enable input (LE2), three separate bias points and a LSB output. Internal latch circuits (172, 272) and latch enable circuits (174, 274) are provided in each adder stage. Internal latch enable inputs are connected in parallel in one configuration. Separate latch enable inputs are provide in a second configuration. Separate bias points are also provided in each adder stage.