Abstract: A timing recovery circuit comprises a data-driven phase detector and a digital loop filter. The data-driven phase detector is operably coupled to determine at least a phase difference between an input signal and a feedback clock signal to produce a difference signal. Determining the phase difference can comprise digitally determining a timing difference between the input signal and the feedback clock signal, digitally determining a transition of the input signal to produce a transition detect signal, and digitally updating the timing difference based on the transition detect signal and the feedback clock signal. The timing difference can be digitally updated by pre-filtering the timing difference BY TAKING EVERY N TRANSITON OR AVERAGE OF EVERY N TRANSITIONS at a digital pre-filter, based on a pre-filter clock signal produced from the transition detect signal and the feedback clock signal, to produce the difference signal.

Abstract: A method and apparatus for an automatic gain control (AGC) loop that utilizes multiple comparators to provide constant bandwidth tracking and step response, as well as fine granularity for decision directed convergence. In one embodiment, an odd number of comparators is used with square-law scaling at the output to achieve constant bandwidth step response for a wide range of input amplitude changes.

Abstract: A threshold adjustment circuit including: a current DAC for supplying or sinking a varying current; a differential pair of thin oxide transistors coupled to the DAC and coupled together at a common source node; a power supply for providing a supply voltage having a voltage level above reliability of the thin oxide transistors; and a third transistor for maintaining voltage of the common source node above a predetermined level and to disable the threshold adjustment circuit. The bulk and source of each of the differential pair thin oxide transistors is coupled to the common source node and each of the differential pair thin oxide transistors is switched by a signal to keep each of the differential pair thin oxide transistors in saturation region.

Abstract: A continuous time filter having a first stage and a second stage. A first stage adjusts a bandwidth of the signal. A second stage adjusts bandwidth of the signal subsequent to the first stage. Each stage includes a first capacitor with a first capacitance and a second capacitor with a second capacitance for providing uniform step sizes for bandwidth adjustment. The continuous time filter may include a plurality of cascaded stages including the first stage and the second stage. In addition, a bandwidth adjustment across the first stage and the second stage may be controlled using a semi-interleaved thermometer coding to achieve a cascaded effect for the bandwidth adjustment.

Abstract: A variable gain amplifier including a stage. The stage having a set of switchable differential pairs. The stage providing a gain range to a signal and adjusting a gain of the signal. At least one differential pair in each stage is permanently enabled. The variable gain amplifier may include a plurality of cascaded stages including the stage. In addition, the variable gain amplifier may be adjusted through an interleaved thermometer coding method.

Abstract: A method and apparatus for an automatic gain control (AGC) loop that utilizes freezing and unfreezing states. A freezing process moves the AGC into a TRANSITION state from a NORMAL state, based on net change of VGA gain control codes over a monitoring time window. The freezing process then moves the AGC into a FROZEN state from the TRANSITION state, based on net change of VGA gain control codes over the monitoring time window. An unfreezing process moves the AGC into the NORMAL state from the FROZEN state, based on signal amplitude changes at the output of the VGA.

Abstract: A phase lock loop with multiple divider paths is presented herein. The phase lock loop can be used to provide a wide range of frequencies. The phase lock loop can also be used as a portion of a clock multiplier unit or a clock data and recovery unit.

Abstract: Method and circuitry for converting a differential logic signal to a single-ended logic signal eliminate slower PMOS transistors and speed up the conversion process. In specific embodiments differential logic signals of the type employed in, for example, current-controlled complementary metal-oxide-semiconductor (C3MOS) logic are converted to single-ended rail-to-rail CMOS logic levels using a differential pair of NMOS transistors with resistors as load devices and an NMOS current source transistor that provides dynamically adjusted tail current.

Abstract: A phase lock loop with multiple divider paths is presented herein. The phase lock loop can be used to provide a wide range of frequencies. The phase lock loop can also be used as a portion of a clock multiplier unit or a clock data and recovery unit.

Abstract: A phase lock loop with multiple divider paths is presented herein. The phase lock loop can be used to provide a wide range of frequencies. The phase lock loop can also be used as a portion of a clock multiplier unit or a clock data and recovery unit.

Abstract: An apparatus and method are disclosed to aid a transceiver chip, in a wide-band serial data communications system, in receiving data at multiple data rates. A multi-rate filter within the transceiver chip is implemented as at least one adjustable-rate filter stage and a limiting stage. The at least one adjustable-rate filter stage is used to generate a filtered serial data signal from a received serial data signal. The limiter stage generates a full-swing serial data signal from the filtered serial data signal. A bandwidth of the at least one adjustable-rate filter stage is adjustable in order to receive serial data signals at multiple data rates. The bandwidth of the multi-rate filter within the transceiver chip is selectable by the user of the wide-band communication system.

Abstract: A phase lock loop with multiple divider paths is presented herein. The phase lock loop can be used to provide a wide range of frequencies. The phase lock loop can also be used as a portion of a clock multiplier unit or a clock data and recovery unit.

Abstract: A phase lock loop comprising a plurality of voltage controlled oscillators is presented herein. The phase lock loop can provide a wide range of output frequencies with low jitter. Additionally, the phase lock loop can be incorporated into a clock multiplier unit and a clock and data recovery unit.

Abstract: Present herein is a multirate transceiver wherein data can be received at a first data rate and transmitted at a second data rate. The transceiver device comprises a first interface for receiving data at one data rate a mapper that can map data from a first rate to the second rate, and a second interface for transmitting the data at the second data rate.

Abstract: A timing recovery circuit comprises a data-driven phase detector and a digital loop filter. The data-driven phase detector is operably coupled to determine at least a phase difference between an input signal and a feedback clock signal to produce a difference signal. Determining the phase difference can comprise digitally determining a timing difference between the input signal and the feedback clock signal, digitally determining a transition of the input signal to produce a transition detect signal, and digitally updating the timing difference based on the transition detect signal and the feedback clock signal. The timing difference can be digitally updated by pre-filtering the timing difference BY TAKING EVERY N TRANSITON OR AVERAGE OF EVERY N TRANSITIONS at a digital pre-filter, based on a pre-filter clock signal produced from the transition detect signal and the feedback clock signal, to produce the difference signal.

Abstract: Method and circuitry for converting a differential logic signal to a single-ended logic signal eliminate slower PMOS transistors and speed up the conversion process. In specific embodiments differential logic signals of the type employed in, for example, current-controlled complementary metal-oxide-semiconductor (C3MOS) logic are converted to single-ended rail-to-rail CMOS logic levels using a differential pair of NMOS transistors with resistors as load devices and an NMOS current source transistor that provides dynamically adjusted tail current.

Abstract: Method and circuitry for converting a differential logic signal to a single-ended logic signal eliminate slower PMOS transistors and speed up the conversion process. In specific embodiments differential logic signals of the type employed in, for example, current-controlled complementary metal-oxide-semiconductor (C3MOS) logic are converted to single-ended rail-to-rail CMOS logic levels using a differential pair of NMOS transistors with resistors as load devices and an NMOS current source transistor that provides dynamically adjusted tail current.