A low dropout voltage regulator unit includes an error amplifier and a power stage having an output terminal that is looped back onto the error amplifier and is capable of delivering an output current to a load. The unit includes multiple main supply inputs that are intended to potentially receive, respectively, multiple different supply voltages. The power stage includes multiple power paths that are connected, respectively, between the main supply inputs and the output terminal, are individually selectable and each comprise an output transistor. The unit also includes a selector circuit connected to the main supply inputs and configured to select one of the power paths according to a selection criterion. The error amplifier includes an output stage configured to selectively control the output transistor of the selected power path.

Systems and methods are disclosed for control schemes and intelligent battery selection for electric vehicles. In one embodiment, an example method may include determining a first charge level of a first battery system that is configured to power a homopolar generator, causing the first battery system to be charged by a power input source, and determining that a second charge level of the first battery system is greater than a first threshold value. Example methods may include causing the first battery system to power the homopolar generator, wherein the homopolar generator is configured to output charging current to a second battery system, causing the solid state relay to form a parallel connection between a first battery, a second battery, and the homopolar generator, directing a first charging current from the homopolar generator to the first battery, and directing a second charging current from the homopolar generator to the second battery.

In one aspect, an electric vehicle (EV) charging system includes: a plurality of first converters to receive grid power at a distribution grid voltage and convert the distribution grid voltage to at least one second voltage; at least one high frequency transformer coupled to the plurality of first converters to receive the second voltage and electrically isolate a plurality of second converters. The EV charging system may further include the plurality of second converters coupled to the output of the at least one high frequency transformer to receive and convert the at least one second voltage to a third DC voltage. At least some of the plurality of second converters are to couple to one or more EV charging dispensers to provide the third DC voltage as a charging voltage or a charging current.

A charger includes a rectifier including two input terminals for connection to an AC power supply, a cathode terminal and an anode terminal, a DC/DC converter including a first terminal be connected to the cathode terminal, a second terminal to be connected to the anode terminal, and two output terminals for connection to a battery, a power pulsation absorbing circuit including a first diode, a second diode, a third diode, an inductor, a capacitor, a first switch and a second switch, and a control section configured to control a switch of the DC/DC converter, the first switch and the second switch, wherein the control section is configured to control the DC/DC converter, the first switch and the second switch in such a way that a sum of a power outputted from the AC power supply and a power outputted from the capacitor is constant.

A charger includes a rectifier including two input terminals for connection to an AC power supply, a cathode terminal and an anode terminal, a DC/DC converter including a first terminal be connected to the cathode terminal, a second terminal to be connected to the anode terminal, and two output terminals for connection to a battery, a power pulsation absorbing circuit including a first diode, a second diode, a third diode, an inductor, a capacitor, a first switch and a second switch, and a control section configured to control a switch of the DC/DC converter, the first switch and the second switch, wherein the control section is configured to control the DC/DC converter, the first switch and the second switch in such a way that a sum of a power outputted from the AC power supply and a power outputted from the capacitor is constant.

Included are embodiments of a wireless charging device. Some embodiments include a transmitting side resonant tank circuit that includes a transmitting side tank capacitor and a primary transmission coil. Also included is a bridge component that is coupled to the transmitting side resonant tank circuit for driving the transmitting side resonant tank circuit. The bridge component may be configured to receive a voltage from a power supply for supplying a rail of the transmitting side resonant tank circuit. A regulator circuitry may also be included, which controls the bridge component. The regulator circuitry may execute logic that controls an amount of power that is delivered to the transmitting side resonant tank circuit. Similarly, a current sensing element may be included that informs the regulator circuitry of an amount of current drawn from the power supply.

Included are embodiments of a wireless charging device. Some embodiments include a transmitting side resonant tank circuit that includes a transmitting side tank capacitor and a primary transmission coil. Also included is a bridge component that is coupled to the transmitting side resonant tank circuit for driving the transmitting side resonant tank circuit. The bridge component may be configured to receive a voltage from a power supply for supplying a rail of the transmitting side resonant tank circuit. A regulator circuitry may also be included, which controls the bridge component. The regulator circuitry may execute logic that controls an amount of power that is delivered to the transmitting side resonant tank circuit. Similarly, a current sensing element may be included that informs the regulator circuitry of an amount of current drawn from the power supply.

A battery pack charger includes a first circuit region, a second circuit region, an input voltage measuring circuit, a temperature measurement device, and a controller. The controller is configured to measure an input voltage to the charger using the input voltage measuring circuit, measure a temperature of the second circuit region using the temperature measurement device, and estimate a temperature of the first circuit region based on the input voltage to the charger and the measured temperature of the second circuit region. The controller is further configured to select one of a plurality of correlations between the temperature of the second circuit region and the temperature of the first circuit region based on the input voltage to the charger to estimate the temperature of the first circuit region. After the temperature of the first circuit region has been estimated, one or more control operations associated with the charger can be performed.

A battery pack charger includes a first circuit region, a second circuit region, an input voltage measuring circuit, a temperature measurement device, and a controller. The controller is configured to measure an input voltage to the charger using the input voltage measuring circuit, measure a temperature of the second circuit region using the temperature measurement device, and estimate a temperature of the first circuit region based on the input voltage to the charger and the measured temperature of the second circuit region. The controller is further configured to select one of a plurality of correlations between the temperature of the second circuit region and the temperature of the first circuit region based on the input voltage to the charger to estimate the temperature of the first circuit region. After the temperature of the first circuit region has been estimated, one or more control operations associated with the charger can be performed.

A system, in certain embodiments, includes a power supply. The power supply includes an ultracapacitor configured to be charged by a DC source. The power supply also includes a first switch that enables charging of the ultracapacitor by the DC source when in a closed position and disables charging of the ultracapacitor when in an open position. The power supply further includes a second switch configured to enable discharging of the ultracapacitor when in a closed position and to disable discharging of the ultracapacitor when in an open position. As the ultracapacitor is discharged, a current is supplied to actuate a shape memory alloy element.