A discharge circuit has a voltage divider arranged to divide an alternating-current input voltage to produce a divided voltage, a high-pass filter arranged to pass a high-frequency component of the divided voltage to produce a monitoring voltage, a comparator arranged to compare the monitoring voltage with a threshold voltage to produce a comparison signal, a timer arranged to generate a timer signal indicating whether or not the comparison signal has been kept at the same logic level for a mask period, a controller arranged to generate a discharge control signal according to the timer signal, and a discharger arranged to discharge, according to the discharge control signal, an X capacitor connected to a node to which the alternating-current input voltage is applied.

There is described a storage device configured to store energy at one or more given voltage levels. There is also described a storage circuit that may form part of a storage device and is responsible for storing electrical energy and discharging the electrical energy. And finally, there is described a modular circuit having a plurality of storage devices connected in series. The storage devices store electrical energy and provide a voltage level that may be switched in and out of the chain of storage devices in order to control an overall voltage level of the circuit. Each storage device may be individually protected from overvoltage while globally controlled for a given function.

A battery pack includes a battery including at least one battery cell, a switching element including a charging switch and a discharging switch arranged on a high current path via which a charging current and a discharging current flow, a battery manager configured to monitor a voltage and a current of the battery, and to controlling charging and discharging of the battery based on the voltage of the battery, and a switch driver configured to output a second driving signal for driving the charging switch according to a control signal from the battery manager, wherein the battery manager is further configured to set a charging current limit based on a deterioration degree of the battery, and to control the charging switch by using the switch driver so that a magnitude of the charging current applied to the battery is equal to or less than the charging current limit.

To suppress the occurrence of system shutdown after long term storage of batteries. A semiconductor device comprises a control unit that controls charging and discharging of a battery cell, and a ROM that stores a power supply capability value which specifies a power supply capacity of the battery cell that can be stably supplied to an application system in which the battery pack is provided. After the battery pack returns from the sleep mode and before the transmission request of the power supply capability value is received from the system, the control [unit performs a power supply capability value updating process of updating the power supply capability value in the ROM to a value smaller than the power supply capability value before the sleep mode.

Disclosed examples include battery apparatus and balancing circuits for transferring charge between one or more of a plurality of battery cells and a second battery, in which a battery is coupled with a first winding of a transformer, and the second battery is coupled with a second transformer winding. A first transistor is turned on to allow current flow in the first winding to discharge the first battery, and then the first transistor is turned off. The resulting induced voltage in the second winding turns on a second transistor to provide flyback active charge balancing to charge the second battery. A signal from the third winding allows detection of low or zero current flow in the second winding for a controller to begin subsequent charge transfer cycles for full isolation between the first and second batteries.

A method for charging a battery cell is provided. During a charging phase at a constant charging current, monitoring is carried out to ascertain whether a charging voltage applied to the battery cell reaches or exceeds a predefined switchover voltage, and, if this is the case, a switchover is made to the next charging phase at a lower constant charging current. During the charging phases, additional monitoring is carried out to ascertain whether the difference between the charging voltage and the switchover voltage of this charging phase reaches or falls below a predefined value, and, if so, at least one discharge pulse is applied to the battery cell.

A method for fast-charging an electrochemical cell comprises the steps of: —providing the electrochemical cell, the electrochemical cell presenting an initial state of charge (SOC), and—providing a time-varying charging voltage to the electrochemical cell, thereby generating a charging current resulting in charging of the electrochemical cell from the initial SOC up to a target value SOC.sub.f for the state of charge. The step of providing a time-varying charging voltage involves applying N bundles of current pulses in such a way that: each bundle k (1≤k≤N) comprises a variable number P.sub.k of i.sub.k pulses (1≤i.sub.k≤P.sub.k), each i.sub.k pulse in a k bundle being defined by a C-rate equal to n.sub.i,k.Math.C and a duration τ.sub.i,k. at each pulse i.sub.k, the state of charge (SOC) is increased by δ.sub.ik (%)=n.sub.i,k.Math.τ.sub.i,k/M, with M as a predetermined parameter.

According to various embodiments, a wireless power transmission device may comprise: a coil circuit configured to generate a power signal for power transmission to an electronic device; an inverter configured to convert direct current power to alternating current power and to provide the alternating current power to the coil circuit; a coil-type detection unit comprising a coil disposed to be adjacent to the coil circuit and configured to detect a signal corresponding to the power signal; and a control circuit configured to adjust, based on the detected signal, a switching frequency of the inverter to change the alternating current power output from the inverter.

A method of charging a battery having a first voltage and a second voltage. In a first phase, applying a constant current to the battery; in a second phase, applying current pulses to the battery; repeating iteratively sampling the first voltage during a current pulse to obtain a measurement of the first voltage; sampling the first voltage during a current pause to obtain a measurement of the second voltage; generating a dynamic reference voltage based on the fixed reference voltage and on a difference between the measurement of the first voltage and the second voltage. There is a comparing the measurement of the first voltage with the dynamic reference voltage. There is a stopping of the current pulses when the measurement of the first voltage is equal to the dynamic reference voltage and the measurement of the second voltage is equal to the fixed reference voltage.

A charge method, an adapter and a mobile terminal are provided. The adapter negotiates with the mobile terminal about the charging mode and the charging current of the battery. When determining to charge the battery in the quick charging mode, the adapter adopts the unidirectional pulse current to perform a quick charge on the battery using the negotiated charging current.