Abstract: Methods and systems for selecting voltage for a substrate connection of a bypass switch include a bulk voltage generation circuit coupled externally to the regulator. The bulk voltage generation circuit is configured to control selection of a voltage from among an Input/Output (I/O) supply voltage and a core supply voltage for a substrate connection of a bypass switch of the regulator. The bulk voltage generation circuit is configured to select the voltage for the substrate connection of the bypass switch based on a mode of operation of the regulator and at least one of a presence or an arrival sequence of the I/O supply voltage and the core supply voltage.

Abstract: Methods and systems for selecting voltage for a substrate connection of a bypass switch include a bulk voltage generation circuit coupled externally to the regulator. The bulk voltage generation circuit is configured to control selection of a voltage from among an Input/Output (I/O) supply voltage and a core supply voltage for a substrate connection of a bypass switch of the regulator. The bulk voltage generation circuit is configured to select the voltage for the substrate connection of the bypass switch based on a mode of operation of the regulator and at least one of a presence or an arrival sequence of the I/O supply voltage and the core supply voltage.

Abstract: An apparatus for in-phase and quadrature phase (“IQ”) generation comprises a CMOS clock distributor for providing a clock input. A first IQ divider circuit is configured for receiving the clock input and dividing the clock input into in-phase and quadrature phase (IQ) output. A clock processing circuit is configured for processing the clock input. A second IQ divider circuit is configured for receiving the processed clock input and dividing the processed clock input into in-phase and quadrature phase (IQ) output. A multiplexer circuit is coupled to the first IQ divider circuit and the second IQ divider circuit for selecting the IQ output from the first IQ divider circuit or the second IQ divider circuit.

Abstract: An apparatus for in-phase and quadrature phase (“IQ”) generation comprises a CMOS clock distributor for providing a clock input. A first IQ divider circuit is configured for receiving the clock input and dividing the clock input into in-phase and quadrature phase (IQ) output. A clock processing circuit is configured for processing the clock input. A second IQ divider circuit is configured for receiving the processed clock input and dividing the processed clock input into in-phase and quadrature phase (IQ) output. A multiplexer circuit is coupled to the first IQ divider circuit and the second IQ divider circuit for selecting the IQ output from the first IQ divider circuit or the second IQ divider circuit.

Abstract: An Alternating Current (AC) and Direct Current (DC) coupled electronic receiver system including a receiver, an AC-coupling capacitor between an input of the receiver system and the receiver, a bypass switch configured to selectively bypass the AC-coupling capacitor to DC-couple the input to the receiver, a bypass switch driving circuit configured to cause the bypass switch to switch ‘ON’ and thereby DC-couple the input to the receiver, and cause the bypass switch to switch ‘OFF’ and thereby AC-couple the input to the receiver, and a voltage-following transistor between a source and a gate of the bypass switch configured to maintain an ‘OFF’ state of the bypass switch while the input is AC-coupled.

Abstract: An Alternating Current (AC) and Direct Current (DC) coupled electronic receiver system including a receiver, an AC-coupling capacitor between an input of the receiver system and the receiver, a bypass switch configured to selectively bypass the AC-coupling capacitor to DC-couple the input to the receiver, a bypass switch driving circuit configured to cause the bypass switch to switch ‘ON’ and thereby DC-couple the input to the receiver, and cause the bypass switch to switch ‘OFF’ and thereby AC-couple the input to the receiver, and a voltage-following transistor between a source and a gate of the bypass switch configured to maintain an ‘OFF’ state of the bypass switch while the input is AC-coupled.

Abstract: The present disclosure relates to an apparatus for use in a transition-minimized differential signaling link (“TMDS”) receiver. The apparatus may include an integrated circuit electrically connected with a voltage supply. The integrated circuit may include a first transistor, a second transistor, and a resistor arranged in a cascaded configuration along a termination path. The first transistor may include calibration code control configured to adjust an output impedence.

Abstract: An ultra low cut-off frequency filter. A filter circuit includes a control circuit responsive to an input signal and a feedback signal to generate a control signal. The filter circuit includes a controllable resistor coupled to the control circuit. The controllable resistor is responsive to a reference signal and the control signal to generate the feedback signal. The filter circuit includes a feedback path coupled to the control circuit and the controllable resistor to couple the feedback signal from the controllable resistor to the control circuit, thereby removing noise from at least one of the input signal and the reference signal, and preventing voltage error in the filter circuit.

Abstract: A circuit for optimizing a power management system. The circuit includes a first amplifier. The first amplifier is responsive to a first reference signal and operable to supply a first load current. The circuit also includes a second amplifier coupled to the first amplifier. The second amplifier is responsive to a second reference signal and operable to supply a second load current. The second load current is lower in magnitude than the first load current, thereby enabling the first amplifier to operate during a first load condition, and the second amplifier to operate during the first load condition and a second load condition. Further, the circuit includes a resistive element coupled to the first amplifier and the second amplifier, to isolate the first amplifier from the second amplifier.

Abstract: An ultra low cut-off frequency filter. A filter circuit includes a control circuit responsive to an input signal and a feedback signal to generate a control signal. The filter circuit includes a controllable resistor coupled to the control circuit. The controllable resistor is responsive to a reference signal and the control signal to generate the feedback signal. The filter circuit includes a feedback path coupled to the control circuit and the controllable resistor to couple the feedback signal from the controllable resistor to the control circuit, thereby removing noise from at least one of the input signal and the reference signal, and preventing voltage error in the filter circuit.

Abstract: A circuit for optimizing a power management system. The circuit includes a first amplifier. The first amplifier is responsive to a first reference signal and operable to supply a first load current. The circuit also includes a second amplifier coupled to the first amplifier. The second amplifier is responsive to a second reference signal and operable to supply a second load current. The second load current is lower in magnitude than the first load current, thereby enabling the first amplifier to operate during a first load condition, and the second amplifier to operate during the first load condition and a second load condition. Further, the circuit includes a resistive element coupled to the first amplifier and the second amplifier, to isolate the first amplifier from the second amplifier.

Abstract: A system and method for reducing the power dissipated in an Analog to Digital Converter (ADC). The method includes the steps of: receiving a residue output from a previous phase of a plurality of clock phases where the plurality of clock phases includes a sample-and-hold phase and an amplifying phase for sampling and amplifying an analog input signal respectively, eliminating an effect of load on a residue amplifier when amplifying the residue output to generate an amplified residue output in the amplifying phase, and eliminating an effect of small feedback factor when sampling the amplified residue output in the sample-and-hold phase. Power advantage is achieved by sharing the load on the residue amplifier across the sample-and-hold phase and the amplifying phase rather than being fully present in any one of the clock phases. The present invention also provides a method for reducing the number of comparators used in ADCs.

Abstract: A system and method for reducing the power dissipated in an Analog to Digital Converter (ADC). The method includes the steps of: receiving a residue output from a previous phase of a plurality of clock phases where the plurality of clock phases includes a sample-and-hold phase and an amplifying phase for sampling and amplifying an analog input signal respectively, eliminating an effect of load on a residue amplifier when amplifying the residue output to generate an amplified residue output in the amplifying phase, and eliminating an effect of small feedback factor when sampling the amplified residue output in the sample-and-hold phase. Power advantage is achieved by sharing the load on the residue amplifier across the sample-and-hold phase and the amplifying phase rather than being fully present in any one of the clock phases. The present invention also provides a method for reducing the number of comparators used in ADCs.

Abstract: A system and method for improving the dynamic performance in an analog-to-digital converter (ADC) by randomizing the differential mismatch. The differential mismatch in an input analog signal is randomized by flipping the input signal and output signal randomly.

Abstract: A system and method for improving the dynamic performance in an analog-to-digital converter (ADC) by randomizing the differential mismatch. The differential mismatch in an input analog signal is randomized by flipping the input signal and output signal randomly.