Abstract: A boost regulator for converting an input voltage to a higher output voltage including an inductor, an error circuit, a switching circuit, a ripple circuit, and a hysteretic comparator circuit. The inductor has a first end coupled to the input voltage and a second end. The error circuit determines an error of the output voltage and provides an error voltage indicative thereof. The switching circuit switches the second end of the inductor between the output voltage and ground as controlled by a pulse width modulation signal. The ripple circuit synthetically replicates ripple current through the inductor based on voltage applied across the inductor and provides a ripple voltage indicative thereof. The hysteretic comparator circuit develops the pulse width modulation signal based on comparing the ripple voltage within a hysteretic window voltage range based on the error voltage.

Abstract: A buck-boost regulator for converting an input voltage to an output voltage which includes an inductor, an error circuit providing an error voltage, buck and boost switching circuits, buck and boost ripple circuits, and buck and boost hysteretic comparator circuits. The buck switching circuit switches a first end of the inductor, the buck ripple circuit replicates ripple current through the inductor based on the buck pulse signal and provides a buck ripple voltage, and the buck hysteretic comparator circuit develops the buck pulse signal based on a buck window voltage range using the error voltage. The boost switching circuit switches a second end of the inductor, the boost ripple circuit replicates ripple current through the inductor based on the boost pulse signal and provides a boost ripple voltage, and the boost hysteretic comparator circuit develops the boost pulse signal based on a boost window voltage range using the error voltage.

Abstract: A hysteretic mode controller for controlling a capacitor voltage divider which has a flying capacitor. In one embodiment, the hysteretic mode controller includes an amplifier, a gain circuit and a hysteretic comparator circuit. The amplifier has an input for coupling to the flying capacitor and an output providing a fly voltage. The gain circuit has an input for receiving the input voltage and an output coupled to a reference node providing a reference voltage. The hysteretic comparator circuit has a first input coupled to the output of the amplifier, a second input receiving the reference voltage, and an output for providing a PWM signal to control the capacitor voltage divider. The fly voltage is compared to voltage limits of a hysteretic voltage window for switching the PWM signal. The switching frequency is increased with higher load current to maintain high efficiency.

Abstract: A battery charging and power delivery system for a portable electronic device includes a first connection that connects the system to an AC/DC power adaptor. A second connection connects the system to the power bus of the portable electronic device. A third connection connects the system to a battery. A capacitor voltage divider circuit provides power to the system power bus through the second connection and provides power through the third connection. A controller provides control signals to the capacitor voltage divider and to the AC to DC power adaptor.

Abstract: A frequency control circuit including a controlled oscillator and an amplifier circuit is disclosed for providing a clock signal to a switched capacitor circuit which divides an input voltage to provide an output voltage. The controlled oscillator has a frequency control input receiving a frequency control signal and an output for providing the clock signal at a frequency based on the frequency control signal. The amplifier circuit has an input for receiving the output voltage and an output providing the frequency control signal based on droop of the output voltage. In one embodiment, the amplifier circuit adjusts the frequency control signal to optimize efficiency of the switched capacitor circuit over a voltage range of the output voltage, which changes based on load level.

Abstract: A battery charging and power delivery system for a portable electronic device includes a first connection that connects the system to an AC/DC power adaptor. A second connection connects the system to the power bus of the portable electronic device. A third connection connects the system to a battery. A capacitor voltage divider circuit provides power to the system power bus through the second connection and provides power through the third connection. A controller provides control signals to the capacitor voltage divider and to the AC to DC power adaptor.

Abstract: A DC-DC converter has a plurality of diverse type DC-DC converter channels whose outputs are combined to provide a composite DC power output to a load. One of the channels is a high efficiency power path that supplies the average current demand of the load. A second channel comprises a fast transient response power path which handles transient response demands.