The present invention relates to alternative equipment for solar energy prospecting with a focus on low cost, low complexity in installation, operation and maintenance, and high reliability. A low-cost solarimetric station consists of compact equipment capable of providing global irradiance measurements and estimates for direct and diffuse components, as well as hemispheric photographs, with acceptable levels of uncertainty. The pyranometer periodically provides global irradiance information to the system, and the camera records photos of the sky. Using machine learning algorithms, and based on that information, the equipment provides estimates for direct and diffuse irradiance components. The equipment has other meteorological sensors, GPS, and wireless communication facilities. The equipment has an energy supply and management system consisting of a photovoltaic module, charge controller, and battery, which provide the energy necessary for the station to operate.

A smart power hub having a number of electrical connections for power electric power tools. The smart power hub comprises a controller, a processor, and a number of sensors operable to measure operational behavior of the electrical connections or connected electric power tools. The processor may utilize data from the sensors to generate control commands for the controller to control the current output of the number of electrical connections. Additional functions of the processor may provide smart feature operation to connected tools.

An electronic device selectively coupled to a first charger and/or a second charger includes a power supply interface, a first comparator, a second comparator, a controller, a first switch circuit, and a second switch circuit. The power supply interface receives a first input voltage and a second input voltage. The first comparator compares the first input voltage with a first reference voltage, so as to generate a first comparison voltage. The second comparator compares the second input voltage with a second reference voltage, so as to generate a second comparison voltage. The controller generates a first control voltage and a second control voltage according to the first comparison voltage and the second comparison voltage. The first switch circuit is selectively enabled or disabled according to the first control voltage. The second switch circuit is selectively enabled or disabled according to the second control voltage.

A control method is provided for controlling an electronic device having a main body. The control method may include: in response to the electronic device being activated and a primary battery being functionally connected to the main body of the electronic device, controlling the primary battery to power the electronic device; and in response to the electronic device being activated and the primary battery being functionally disconnected from the main body of the electronic device, controlling a backup battery to power the electronic device.

Mitigation of audible output of one or more components in a charging circuit. A charging circuit may include a mitigation controller operative to monitor a frequency of voltage at an input of a charging circuit. The frequency of the voltage at the input node may result in a mitigation condition associated with audible output of one or more components of the charging circuit. In response to detection of the mitigation condition, the mitigation controller may temporarily disable the supply of power from charging circuit to a system load to mitigate (e.g., potentially eliminate) audible output of the circuit. During a time in which the charging circuit is disabled from supplying power to the system load, a battery of the device may supply power to the system load.

A charging apparatus, a charging method, and an electronic device are provided. The charging apparatus includes a first charging module, a second charging module, a microprocessor and a voltage adjustment module. The microprocessor is connected to the first charging module and the second charging module. The voltage adjustment module is connected to the first charging module and the second charging module. The microprocessor is configured for controlling the first charging module and the second charging module to charge a battery. The first charging module is configured for supplying power to a vehicle diagnosis system and charging the battery. The second charging module is configured for charging the battery. A device that needs to be charged is charged by means of both the first charging module and the second charging module, and the charging current is controllable, such that the charging efficiency is improved.

A DC/DC converter includes a power conversion unit for converting input voltage to required voltage, a first control unit for driving the power conversion unit, a power supply device which supplies power to the first control unit and uses an output of the DC/DC converter or a battery as a power supply source, and a power supply function for controlling supply of power to the power supply device. The power supply function is controlled with respect to supply of power, by a second control unit of a power conversion device during a standby state of the DC/DC converter.

Embodiments of systems and methods for managing turbo states based upon user presence are described. In some embodiments, a method may include detecting, by an Information Handling System (IHS), a presence state of a user, and modifying a turbo configuration of a component of the IHS in response to the presence state.

Methods, systems, and techniques for safely controlling wireless charging in the presence of a foreign object are presented. A method includes determining a power difference between a power transmitted by a wireless charger and a power received by an electronic device, determining a level of misalignment of the electronic device with respect to the wireless charger; estimating an amount of power difference due to the level of misalignment of the electronic device with respect to the wireless charger, adjusting a power difference threshold for the wireless charger based on the estimated amount of power difference, and controlling operation of the wireless charger based on the power difference and the adjusted power difference threshold.

According to the disclosed embodiments, an on-die capacitor utilized in energy-harvest based circuits is provided. In the disclosed design, the harvester is coupled to the on-die capacitor, thus there is no need to provide power interfaces and semi-conductor devices external to the IC. The disclosed design of the on-die capacitor would reduce the overall size and cost of the IC.