Abstract: A differential transimpedance amplifier (DTIA) includes a first input, a second input, a first output, and a second output. The DTIA also includes a first inverter and a second inverter connected in series to the first input. The DTIA further includes a third inverter and a fourth inverter connected in series to the second input. The first inverter and the fourth inverter receive a first supply voltage from a first voltage regulator. The second inverter and the third inverter receive a second supply voltage from a second voltage regulator. The first supply voltage changes (i) based on a difference between voltages on the first output and the second output and (ii) while the second supply voltage remains fixed.

Abstract: A CMOS field effect transistor (FET) is provided with predetermined temperature characteristics. More particularly, the relationship between the channel length, gate width, gate-to-source voltage, and drain current is exploited to create an FET that has relatively constant drain current across a relatively wide range of frequencies. Alternately, the above-mentioned relationship is exploited to create a drain current with a predetermined temperature coefficient across a wide temperature range.

Abstract: A biasing circuit for producing a bias current which is supply-independent and temperature-stable includes a first voltage generating circuit which produces a first voltage V1 at an output; a second voltage generating circuit which produces a second voltage V2 different from the first voltage V1 at an output; a differential amplifier circuit having inputs coupled to the outputs of the first and the second voltage generating circuits and producing a reference voltage VREF based on a difference between the first voltage V1 and the second voltage V2; and a current generating circuit which produces a bias current IREF from the reference voltage VREF.

Abstract: A system and method have been provided for selectably equalizing an input signal to an integrated circuit (IC), to compensate for degradation in the transmission process. The selectable equalization circuit includes parallel equalizing and non-equalizing sections. When the equalizing section is engaged a resonant element modifies the circuit impedance to add a zero to the circuit transfer function. When the non-equalizing function is engaged, the equalizing section is disengaged without degrading gate capacitance, and the input signals are processed without a zero in the transfer function.

Abstract: A driver circuit which has a reduced or eliminated crowbar current includes a P-channel type transistor having a source coupled to a reference voltage; an N-channel type transistor having a source coupled to ground and a drain coupled to a drain of the P-channel type transistor; first logic gate circuitry (e.g., a NOR gate) having an input coupled to a reference clock signal and an output coupled to a gate of the P-channel type transistor; and second logic gate circuitry (e.g., a NAND gate) having an input coupled to the reference clock signal and an output coupled to a gate of the N-channel type transistor. The first logic gate circuitry is designed to have a first input voltage threshold value (e.g., ¼ VDD) that is different from a second input voltage threshold value (e.g., ¾ VDD) of the second logic gate circuitry.

Abstract: A variable frequency oscillator provides an output frequency that is adjustable by selectively combining different delay signals from separate signal paths. The present invention's oscillator includes first and second differential signal paths, each exhibiting a different time delay or “phase.” Each signal path includes a series coupling of multiple delay elements, where each delay element comprises a single differential amplifier transistor pair. Each signal path's delay is established by setting the biasing and geometry of the signal paths' differential amplifier transistor pairs. A combiner, separately coupled to each signal path, selectively combines signals from the paths to provide a representative output. This output is also fed back as input to both signal paths. As an example, the combiner may be provided by two non-nested differential amplifier transistor pairs.

Abstract: A frequency sweep voltage controlled oscillator (VCO), with a selectable range of output frequencies is provided. The VCO includes a frequency range circuit to accept an input signal, differentially delay the signal, and selectably sum the delayed signals to provide signals in discrete frequency ranges. A frequency sweep circuit accepts the signal output from the frequency range circuit, differentially delays the signal, and sums the delayed signal in such a way as to modify the previously selected frequency range. A method for generating a signal from a frequency sweep VCO is also provided.

Abstract: A system and method have been provided for a phase-locked loop (PLL) circuit to use a selectable VCO frequency range during the acquisition of a signal, with a larger VCO frequency sweep window once the signal is being tracked. The circuit uses a frequency detector during acquisition, and the VCO is limited to operation is a plurality of discrete frequency bands. Each frequency band is sequentially searched using the low VCO gain. Upon acquisition, the frequency band is locked in, a phase detector is utilized, and the VCO sweep window is increased for tracking purposes.

Abstract: A system and method have been provided for selectably equalizing an input signal to an integrated circuit (IC), to compensate for degradation in the transmission process. The selectable equalization circuit includes parallel equalizing and non-equalizing sections. When the equalizing section is engaged a resonant element modifies the circuit impedance to add a zero to the circuit transfer function. When the non-equalizing function is engaged, the equalizing section is disengaged without degrading gate capacitance, and the input signals are processed without a zero in the transfer function.

Abstract: A CMOS field effect transistor (FET) is provided with predetermined temperature characteristics. More particularly, the relationship between the channel length, gate width, gate-to-source voltage, and drain current is exploited to create an FET that has relatively constant drain current across a relatively wide range of frequencies. Alternately, the above-mentioned relationship is exploited to create a drain current with a predetermined temperature coefficient across a wide temperature range.