Abstract: A low power comparator circuit is provided. The circuit includes a comparator core including a first stage. The first stage has an output configured to provide a digital value. A capacitor includes a first terminal coupled at an input of the first stage and a second terminal selectively coupled to a first input and a second input of the comparator core. A voltage generator is coupled to the first stage. The voltage generator is configured and arranged to generate a first voltage based on a predetermined input current and to limit a maximum current of the first stage based on the predetermined input current.

Abstract: A low power comparator circuit is provided. The circuit includes a comparator core including a first stage. The first stage has an output configured to provide a digital value. A capacitor includes a first terminal coupled at an input of the first stage and a second terminal selectively coupled to a first input and a second input of the comparator core. A voltage generator is coupled to the first stage. The voltage generator is configured and arranged to generate a first voltage based on a predetermined input current and to limit a maximum current of the first stage based on the predetermined input current.

Abstract: A bias circuit is provided. The bias circuit includes a comparator circuit configured to compare a first voltage at a first input with a second voltage at a second input and generate a digital value at an output. A level shifter circuit is coupled to the comparator circuit. The level shifter is configured to receive a reference voltage at an input and generate the second voltage at an output. A charge pump circuit is coupled to the comparator circuit. The charge pump circuit is configured to generate the first voltage at an output based on the digital value.

Abstract: A regulator clamp circuit includes a comparison circuit having a sample and hold circuit. The comparison circuit compares a regulated voltage with a sampled voltage of the regulated voltage from a previous time. In some embodiments, the sampled voltage can be determined during a sampling phase that occurs prior to a clamp regulation phase. During the clamp regulation phase, the comparison circuit compares the regulated voltage with the sampled voltage and outputs a signal to activate an actuator circuit to clamp the regulated voltage when the regulated voltage terminal has a higher amount of charge than desired.

Abstract: An analog switch circuit is provided. The circuit includes a branch coupled between an input terminal and an output terminal. The branch is configured to transfer an input signal at the input terminal to the output terminal when a control signal is at a first state. A transistor in the branch includes a current electrode coupled at the input terminal and is configured for receiving the input signal having a voltage exceeding a voltage rating of the transistor. A level shifter includes an output coupled to a control electrode of the transistor and is configured to provide a first voltage sufficient to cause the transistor to be conductive without exceeding the voltage rating of the first transistor when the control signal is at the first state. A voltage generator is coupled to the level shifter and is configured to generate the first voltage based on the input signal.

Abstract: An apparatus and method for synchronously discharging multiple capacitive loads. In one embodiment, the apparatus includes first and second discharge circuits for discharging first and second capacitive loads, respectively. The apparatus also includes a control circuit coupled to the first and second discharge circuits and configured to control the second discharge circuit. The control circuit includes a first scaler circuit configured to generate a first scaled voltage based on a first voltage on the first capacitive load, a second scaler circuit configured to generate a second scaled voltage based on a second voltage on the second capacitive load, and a comparator circuit for comparing the first and second scaled voltages. The comparator circuit asserts a control signal when the second scaled voltage exceeds the first scaled voltage. The second discharge circuit discharges the second capacitive load when the comparator circuit asserts its control signal.

Abstract: A power management system is provided. The power management system includes a first voltage regulator having an input coupled to a first voltage supply terminal and an output. The first voltage regulator is configured to provide an operating voltage at the output. A second voltage regulator has an input coupled to the output of the first voltage regulator. The second voltage regulator is configured to provide at an output a retention voltage based on a control signal. A control circuit is coupled to the second voltage regulator and configured to provide the control signal to the second voltage regulator.

Abstract: Regulation systems and methods use a first regulator and a tracking second regulator. The first regulator receives a reference voltage and generates a first voltage output based upon the reference voltage, which is coupled as a back-bias voltage to a first load region within the integrated circuit. The first regulator also receives a sampled version of the first voltage output as feedback. A second regulator receives the first sampled voltage output and generates a second voltage output. The second regulator also receives a sampled version of the second voltage output as feedback. During operation, the second voltage output tracks (e.g., by a symmetry ratio) the first voltage output and is coupled as a back-bias voltage to a second load region within the integrated circuit. Further, switched-capacitor operation can be implemented, and clock frequency can be adjusted based upon the first sampled voltage output to reduce power consumption.

Abstract: A power management system is provided. The power management system includes a first voltage regulator having an input coupled to a first voltage supply terminal and an output. The first voltage regulator is configured to provide an operating voltage at the output. A second voltage regulator has an input coupled to the output of the first voltage regulator. The second voltage regulator is configured to provide at an output a retention voltage based on a control signal. A control circuit is coupled to the second voltage regulator and configured to provide the control signal to the second voltage regulator.

Abstract: A voltage regulator includes first and second bias circuits, a transistor, and a load prediction circuit. The transistor has a first current electrode coupled to a first power supply voltage terminal, a second current electrode for providing a regulated output voltage, and a control electrode. The first biasing circuit is for providing a first bias voltage to the control electrode of the transistor in response to a feedback signal generated from the regulated output voltage. The second biasing circuit is for providing a second bias voltage to the control electrode of the transistor in response to a control signal. The load current prediction circuit is coupled to the second biasing circuit. The load prediction circuit is for providing the control signal to the second biasing circuit in response to determining that a load current at the second current electrode is expected to increase.

Abstract: An electronic device may include: a load and a voltage regulator coupled to the load and configured to provide a load current, where the voltage regulator includes a first and a second pass device coupled in parallel and configured to operate simultaneously. A method may include providing current to a load using a first and a second pass device coupled in parallel and configured to operate simultaneously, where the first device provides a first current corresponding to a high-frequency component and the second device provides a second current corresponding to a low-frequency component; in response to a decrease in a low-frequency component, causing the second current to decrease and causing the low-frequency component to increase; and in response to an increase in the low-frequency component, causing the second current to increase and causing the low-frequency component to decrease.

Abstract: A voltage regulator includes first and second bias circuits, a transistor, and a load prediction circuit. The transistor has a first current electrode coupled to a first power supply voltage terminal, a second current electrode for providing a regulated output voltage, and a control electrode. The first biasing circuit is for providing a first bias voltage to the control electrode of the transistor in response to a feedback signal generated from the regulated output voltage. The second biasing circuit is for providing a second bias voltage to the control electrode of the transistor in response to a control signal. The load current prediction circuit is coupled to the second biasing circuit. The load prediction circuit is for providing the control signal to the second biasing circuit in response to determining that a load current at the second current electrode is expected to increase.

Abstract: An electronic device may include: a load and a voltage regulator coupled to the load and configured to provide a load current, where the voltage regulator includes a first and a second pass device coupled in parallel and configured to operate simultaneously. A method may include providing current to a load using a first and a second pass device coupled in parallel and configured to operate simultaneously, where the first device provides a first current corresponding to a high-frequency component and the second device provides a second current corresponding to a low-frequency component; in response to a decrease in a low-frequency component, causing the second current to decrease and causing the low-frequency component to increase; and in response to an increase in the low-frequency component, causing the second current to increase and causing the low-frequency component to decrease.

Abstract: Aspects of various embodiments of the present disclosure are directed to applications utilizing voltage sampling. In certain embodiments, a sample and hold circuit is configured to sample voltages that exceed a tolerance voltage of components. The circuit includes a first and a second capacitors. In a first mode, a voltage difference between an input node and a first reference voltage is sampled using the first capacitor. Also in the first mode, a voltage stored by the second capacitor is referenced to a second reference voltage and provided to a first output node. In a second mode, a voltage difference between an input node and a first reference voltage is sampled using the second capacitor. Also in the second mode, a voltage stored by the first capacitor is referenced to the second reference voltage and provided to a second output node.