Abstract: A battery protection circuit includes cell terminals electrically connected to a positive electrode and a negative electrode of a battery, external terminals electrically connected to positive and negative electrodes of an electronic device, discharge and charge FETs connected along a high current path between the cell terminals and the external terminals, a controller having a first terminal electrically connected to a control electrode of the discharge FET and a second terminal electrically connected to a gate electrode of the charge FET, and configured to control the charge FET and the discharge FET, a first resistor electrically connected between the control electrode of the discharge FET and the first terminal of the controller, a capacitor electrically connected between the discharge FET and the first terminal of the discharge FET, and a transistor electrically connected between the control electrode of the discharge FET and a second electrode of the discharge FET.

Abstract: A battery protection circuit includes a charging switch, a resistor, a charging controller, a switching circuit, a fuse circuit, and a fuse driving circuit. The charging switch is connected to a first electrode of a battery cell. The resistor includes a first end connected to a second electrode of the battery cell. The charging controller supplies a charging control current. The switching circuit connects a second end of the resistor with a control terminal of the charging switch or blocks connection between the second end of the resistor and control terminal of the charging switch depending on the charging control current. The fuse circuit is connected to a charging path of the battery cell and blocks the charging path depending on a voltage applied to a control terminal of the fuse circuit. The fuse driving circuit switches the voltage applied to the control terminal of the fuse circuit depending on a voltage between the ends of the resistor.

Abstract: A battery protection circuit includes cell terminals electrically connected to a positive electrode and a negative electrode of a battery, external terminals electrically connected to positive and negative electrodes of an electronic device, discharge and charge FETs connected along a high current path between the cell terminals and the external terminals, a controller having a first terminal electrically connected to a control electrode of the discharge FET and a second terminal electrically connected to a gate electrode of the charge FET, and configured to control the charge FET and the discharge FET, a first resistor electrically connected between the control electrode of the discharge FET and the first terminal of the controller, a capacitor electrically connected between the discharge FET and the first terminal of the discharge FET, and a transistor electrically connected between the control electrode of the discharge FET and a second electrode of the discharge FET.

Abstract: A battery protective circuit includes a battery controller, a charging control transistor, and a protection circuit. The battery controller controls charging of a battery according to a charging control voltage output through a charging control terminal. The a charging control transistor electrically connects the battery to a charger or to electrically disconnect the battery from the charger. The protection circuit includes a voltage sensing terminal electrically connected to a load, an input terminal electrically connected to the charging control terminal, and an output terminal electrically connected to a gate terminal of the charging control transistor. The protection circuit outputs a signal through the output terminal to turn off the charging control transistor, regardless of the charging control voltage of the input terminal, when a voltage equal to or greater than a threshold voltage is sensed at the voltage sensing terminal.

Abstract: A battery protection circuit includes a voltage source, a first resistor, a charging controller, a first charging transistor, a second resistor, and a current voltage converter. The first resistor includes a first terminal connected to the voltage source. The charging controller supplies a charging control current through a charging control terminal. The first charging transistor includes a gate terminal and a first terminal. The second resistor is connected between the gate terminal and first terminal of the first charging transistor. The current voltage converter is connected to a second terminal of the first resistor to electrically connect the voltage source to the gate terminal of the first charging transistor depending on the charging control current.

Abstract: A battery protection circuit includes a charging switch, a resistor, a charging controller, a switching circuit, a fuse circuit, and a fuse driving circuit. The charging switch is connected to a first electrode of a battery cell. The resistor includes a first end connected to a second electrode of the battery cell. The charging controller supplies a charging control current. The switching circuit connects a second end of the resistor with a control terminal of the charging switch or blocks connection between the second end of the resistor and control terminal of the charging switch depending on the charging control current. The fuse circuit is connected to a charging path of the battery cell and blocks the charging path depending on a voltage applied to a control terminal of the fuse circuit. The fuse driving circuit switches the voltage applied to the control terminal of the fuse circuit depending on a voltage between the ends of the resistor.

Abstract: A battery protective circuit includes a battery controller, a charging control transistor, and a protection circuit. The battery controller controls charging of a battery according to a charging control voltage output through a charging control terminal. The a charging control transistor electrically connects the battery to a charger or to electrically disconnect the battery from the charger. The protection circuit includes a voltage sensing terminal electrically connected to a load, an input terminal electrically connected to the charging control terminal, and an output terminal electrically connected to a gate terminal of the charging control transistor. The protection circuit outputs a signal through the output terminal to turn off the charging control transistor, regardless of the charging control voltage of the input terminal, when a voltage equal to or greater than a threshold voltage is sensed at the voltage sensing terminal.

Abstract: A battery protection circuit includes a voltage source, a first resistor, a charging controller, a charging transistor, a second resistor, and a current voltage converter. The first resistor includes a first terminal connected to the voltage source. The charging controller supplies charging control current through a charging control terminal. The first charging transistor includes a gate terminal and a first terminal. The second resistor is connected between the gate terminal and first terminal of the first charging transistor. The current voltage converter is connected to a second terminal of the first resistor to electrically connect the voltage source to the gate terminal of the first charging transistor depending on the charging control current.

Abstract: A driving apparatus of a plasma display is disclosed. The apparatus includes a first switch connected between a first power source for supplying a first voltage and a scan electrode, and a first diode and a second switch connected in series between a second power source for supplying a second voltage that is higher than the first voltage and the scan electrode. Further, the driving apparatus includes a third switch connected between a power recovery power source and a contact point between the first diode and the second switch, and a second diode connected in parallel the first diode and the third switch.

Abstract: A driving apparatus of a plasma display is disclosed. The apparatus includes a first switch connected between a first power source for supplying a first voltage and a scan electrode, and a first diode and a second switch connected in series between a second power source for supplying a second voltage that is higher than the first voltage and the scan electrode. Further, the driving apparatus includes a third switch connected between a power recovery power source and a contact point between the first diode and the second switch, and a second diode connected in parallel the first diode and the third switch.

Abstract: A plasma display is provided. The plasma display includes a plasma display panel (PDP) having first electrodes, second electrodes, and third electrodes; a power supply for supplying a first voltage, a second voltage and a third voltage; a driving circuit for driving at least one of the first electrodes; and a controller for controlling the driving of the first driving circuit. The first driving circuit includes: a first photo coupler and a second photo coupler for generating signals corresponding to logic signals from the controller; a scan integrated circuit (IC) configured to selectively apply the third voltage that is lower than either the first voltage or the second voltage; a buffer for delivering the first signal and the second signal to the scan IC; and a reset circuit for driving the buffer when the first voltage is higher than a fourth voltage.

Abstract: In a plasma display device and a driving apparatus thereof, a scan electrode driver for applying a driving voltage to a scan electrode has a diode including a cathode coupled to a sustain voltage supplying power and an anode coupled to a switch for applying a reset rising waveform to the scan electrode. In the scan electrode driver, when a switch for applying a reset rising waveform is turned on, the voltage at the scan electrode is gradually increased by a voltage that is less than the sustain voltage due to the breakdown voltage of the diode. Therefore, the number of power sources is reduced simplifying the circuit configuration and reducing the plasma display device production cost.

Abstract: A plasma display device and a power supply thereof is provided. The power supply includes a power supply unit, a first output unit, a second output unit and a converter. The power supply unit includes a switching transistor, which is coupled to a primary coil of a transformer for transforming an input voltage, and provides power to a first secondary coil and a second secondary coil of the transformer according to operation of the switching transistor. The first output unit outputs a first voltage generated at the first secondary coil of the transformer, and a second voltage generated by decreasing the first voltage. The second output unit outputs a third voltage generated at the second secondary coil. The converter generates fourth and fifth voltages by converting a voltage that is higher than the second voltage and is generated by using the first and second voltages.

Abstract: A plasma display device and a driving method thereof. The plasma display device includes a first electrode, a power recovery capacitor charged with a first voltage, and a plurality of switches electrically connected between the first electrode and the power recovery capacitor. If the sensing voltage sensed by sensing the voltage of the power recovery capacitor is higher than a reference voltage, the driving voltage used to drive the plurality of switches is prevented (or stopped) from being applied to the plurality of switches, thereby preventing (or protecting) the element constituting the plasma display device from burning out.