A controlling circuit, utilized in an ear bud device which can be charged by a charging device, includes a voltage detection circuit and a processing circuit. The voltage detection circuit is coupled to a power input pin of a communication interface between the ear bud device and the charging device and used for detecting a voltage level of an analog power supply signal at the power input pin to generate a digital input signal. The processing circuit is coupled to the voltage detection circuit and used for receiving the digital input signal to obtain data information carried by the analog power supply signal outputted from the charging device.

According to an aspect, a system includes a battery configured to be charged by a power source, a charging circuit coupled to the battery, and a battery charging manager configured to communicate with the charging circuit to control a charging of the battery by the power source. The battery charging manager obtains a charge pattern including an end charge time corresponding to a time when the battery is estimated to be disconnected from the power source. The battery charging manager controls the charging circuit to charge, over a first charging period, the battery to a temporary charge level, maintain, over a relaxation period, a battery charge level between the temporary charge level and a maintenance charge level, and charge, over a second charging period after the relaxation period, the battery to a maximum battery charge level before the end charge time.

A connector outlet (1) for permitting control of a power supply for charging a user's portable electronic device, PED, such as a mobile telephone, portable computer or table, and providing passengers with the facility of a device charging service, and/or access to a data network through use of a credential provided from the PED to the outlet.

A smart charger and associated methods and systems are disclosed. The smart charger identifies an anticipatory event that triggers battery charging, selects a battery charging profile that matches the anticipatory event, charges the battery of a mobile device based on the battery charging profile, and updates criteria for identifying anticipatory events and/or the battery charging profile that matches the anticipatory event.

A battery energy storage system is provided with: a charging/discharging control device capable of controlling charging/discharging of each of a plurality of electricity storage units in accordance with the supply and demand state of a power system; and a management device for adjusting the progression of deterioration of each of the electricity storage units by differentiating the charging/discharging amount of each of the electricity storage units and managing by differentiating the electricity storage units having a low degree of progression of deterioration from the electricity storage units having a high degree of progression deterioration.

A server includes a processor configured to: acquire schedule information on each of a plurality of users; set a charging priority at a time of charging each of a plurality of moving objects based on the schedule information on each of the plurality of users, each of the plurality of moving objects being preliminarily associated with each of the plurality of users, and including a rechargeable secondary battery; and charge each of the plurality of moving objects based on the charging priority.

A battery management apparatus includes a profile generating unit configured to obtain a battery profile representing a correspondence between voltage and SOC of a battery and generate a differential profile representing a correspondence between the SOC and a differential voltage of the SOC based on the obtained battery profile, and a control unit configured to receive the differential profile from the profile generating unit, calculate a degree of association between the differential profile and a preset criterion profile, and judge a type of a negative electrode of the battery based on the calculated degree of association.

A server includes a processor configured to: acquire user schedule information indicating an action schedule of a user and other person schedule information indicating an action schedule of another person associated with the user; estimate, based on the user schedule information, a power amount for a moving object that the user is allowed to use, the moving object including a rechargeable secondary battery; and control a charging device to charge the moving object based on the power amount and the other person schedule information.

Various implementations include earbud cases with a Hall effect sensor configured to aid in detecting whether the case is open or closed. Certain additional implementations include a holder for a Hall effect sensor in an earbud case. In some particular aspects, a case for a set of earbuds includes: a top section including a set of magnets; and a base section movably coupled with the top section, the base section having: an upper compartment including a set of slots for holding the earbuds; and a lower compartment, having: a printed circuit board (PCB); a holder coupled with the PCB; and a Hall effect sensor coupled with holder, wherein the holder separates the Hall effect sensor from the PCB.

This invention is used to control the duration of time it takes to charge any device, depending on how many units the user has taken out of their fitness goal. This invention connects to a fitness device such as a smart watch and retrieves the amount of units the user has completed. Being conditional on how many units the user has taken, the device will either charge at a normal pace or proportionally slower. For example, if the user's daily goal was 10,000 units and they completed 5,000 units, their device would charge half its normal pace. This invention charges the device more slowly by pausing the charges for periods of time.