Abstract: According to one embodiment, an information processing apparatus includes a housing, a power supply incorporated in the housing, a conversion unit which converts a voltage supplied from the power supply, a detection unit which detects a voltage supplied from the power supply, and a control unit which, when the voltage detected by the detection unit has become less than or equal to a specific threshold value, controls the power supply so as to lower not only a voltage output from the conversion unit by a specific percentage but also a voltage supplied to the detection unit by a specific percentage.

Abstract: According to one embodiment, an information processing apparatus includes a housing, a power supply incorporated in the housing, a conversion unit which converts a voltage supplied from the power supply, a detection unit which detects a voltage supplied from the power supply, and a control unit which, when the voltage detected by the detection unit has become less than or equal to a specific threshold value, controls the power supply so as to lower not only a voltage output from the conversion unit by a specific percentage but also a voltage supplied to the detection unit by a specific percentage.

Abstract: A power supply apparatus includes a power converting unit for switching DC power on the basis of a pulse signal having a predetermined ON-pulse time and a predetermined pulse period, as pulse elements, thereafter smoothing the switched power, and outputting a predetermined power voltage, a control unit for calculating a new pulse-element on the basis of an output of the power converting unit, and a pulse generating unit for generating a pulse signal on the basis of the new pulse-element instructed from the control unit. The pulse generating unit generates the pulse signal of the new pulse-element from the instructed timing without waiting for a next pulse-period, even if the timing for instructing the new pulse-element from the control unit is any timing during the pulse period, irrespective of the ON-pulse time and an OFF-pulse time.

Abstract: According to one embodiment, a power supply control device controls a switching power supply circuit by a pulse width modulation signal. The power supply control device includes a memory which stores a control program including a plurality of instructions for executing a procedure of a power supply control process which controls a duty ratio of the pulse width modulation signal based on an output voltage value of the switching power supply circuit and a target voltage value, a total execution time of the plurality of instructions included in the control program agreeing with a period of the pulse width modulation signal, and a processing unit which executes the power supply control process for each period of the pulse width modulation signal by repeatedly executing the plurality of instructions included in the control program without interruption.

Abstract: According to one embodiment, control is executed to make the number of times of obtaining a current value output from a power supply unit to a CPU greater than the number of times of obtaining current values output from power supply units to DV #1, DV #2, DV #3 and DV #4.

Abstract: According to one embodiment, an information processing apparatus includes a first DC-DC converter which outputs power to a first device and detects a first current value and a first voltage value of the first DC-DC converter. A second DC-DC converter outputs power to a second device and detects a second current value and a second voltage value of the second DC-DC converter. A first PWM control circuit supplies a first PWM signal to the first DC-DC converter. A second PWM control circuit supplies a second PWM signal to the second DC-DC converter. An operation unit controls a pulse width of the first PWM signal based on the first current value and the first voltage value at a first frequency, and controls a pulse width of the second PWM signal based on the second current value and the second voltage value at a second frequency lower than the first frequency.

Abstract: According to one embodiment, in this invention, a control method for a switching power supply using pulse width modulation (PWM) control, includes detecting an input voltage to be supplied to the switching power supply, detecting an output voltage from the switching power supply, calculating a timing for sampling a current for the PWM control, based on a ratio between the detected input voltage and the detected output voltage, and detecting the current based on the calculated timing.

Abstract: A power supplying power supply circuit which supplies power to an N-phase PWM control DC/DC converter power supply circuit multiplies the output voltage thereof by 1/N by use of a voltage divider and outputs the result of multiplication to the inverting input terminal of an error amplifier. Further, the power supplying power supply circuit inputs the output voltage of the N-phase PWM control DC/DC converter power supply circuit to the non-inverting input terminal via a switching circuit. An output of the error amplifier is supplied to a transistor so as to control and set the voltage value of output power of the power supplying power supply circuit equal to N×output voltage of the N-phase PWM control DC/DC converter power supply circuit.

Abstract: A power supply apparatus includes a power converting unit for switching DC power on the basis of a pulse signal having a predetermined ON-pulse time and a predetermined pulse period, as pulse elements, thereafter smoothing the switched power, and outputting a predetermined power voltage, a control unit for calculating a new pulse-element on the basis of an output of the power converting unit, and a pulse generating unit for generating a pulse signal on the basis of the new pulse-element instructed from the control unit. The pulse generating unit generates the pulse signal of the new pulse-element from the instructed timing without waiting for a next pulse-period, even if the timing for instructing the new pulse-element from the control unit is any timing during the pulse period, irrespective of the ON-pulse time and an OFF-pulse time.

Abstract: A power supplying power supply circuit which supplies power to an N-phase PWM control DC/DC converter power supply circuit multiplies the output voltage thereof by 1/N by use of a voltage divider and outputs the result of multiplication to the inverting input terminal of an error amplifier. Further, the power supplying power supply circuit inputs the output voltage of the N-phase PWM control DC/DC converter power supply circuit to the non-inverting input terminal via a switching circuit. An output of the error amplifier is supplied to a transistor so as to control and set the voltage value of output power of the power supplying power supply circuit equal to N×output voltage of the N-phase PWM control DC/DC converter power supply circuit.

Abstract: A circuit module comprising a circuit board, a high-voltage element electrically connected to the circuit board, and an electrically insulting cover covering the high-voltage element. The high-voltage element has a first output terminal for outputting a reference voltage and a second output terminal for outputting a voltage higher than the reference voltage. The cover includes a connector section. The connector section has a first connection terminal, a second connection terminal, and a partition. The first connection terminal is electrically connected to the first output terminal, and the second connection terminal is electrically connected to the second output terminal. The first and second connection terminals are spaced apart. The partition is provided between the first and second connection terminals, isolating the connection terminals from each other.

Abstract: A battery charge circuit using a constant voltage/constant current to power charge a plurality of battery packs, a current detection circuit to detect a charge current according to a predetermined value, and control mechanisms to maintain a constant voltage charge mode when the charge current value drops below a set value within the battery pack.

Abstract: In a battery-driven portable computer, a battery pack is constituted by m battery sets connected in series each including n lithium-ion secondary battery cells connected in parallel. A voltage monitor for monitoring the voltage of the terminal electrode of each battery set and a charger for independently appropriately charging each battery set in accordance with a monitor result are arranged, thereby realizing battery driving by a lithium-ion secondary battery pack having a large capacity. A computer system monitors the voltages of the battery cells which are part of a secondary battery by comparing the battery voltages with a predetermined voltage value in order to detect overdischarge (undervoltage) or overcharge (overvoltage), outputs this information outside of the battery pack, and terminates processing prior to a circuit disconnect.

Abstract: In a battery-driven portable computer, a battery pack is constituted by m battery sets connected in series each including n lithium-ion secondary battery cells connected in parallel. A voltage monitor for monitoring the voltage of the terminal electrode of each battery set and a charger for independently appropriately charging each battery set in accordance with a monitor result are arranged, thereby realizing battery driving by a lithium-ion secondary battery pack having a large capacity.

Abstract: A system comprises a rechargeable battery charged with a constant voltage and a charger. The battery includes a storage unit storing identification data and control voltage data and the charger is assigned identification data. The charger reads the identification data from the storage unit and charges the battery in accordance with the control voltage data, if the stored identification data coincides with the assigned charger identification data. If the stored identification data does not coincide with the assigned charger identification data, the charger gradually increases a charge voltage while detecting overvoltage of the battery, calculates a control voltage of the charger, and charges the battery in accordance with the calculated control voltage.

Abstract: In a system for charging a rechargeable battery with constant voltage, a power supply supplies a voltage increased with time. An overvoltage generating circuit outputs an overvoltage signal for a first predetermined period when a supplied voltage to the rechargeable battery exceed a reference voltage. In response to the overvoltage signal from the overvoltage generating circuit, a multivibrator gradually drops the voltage from the power supply for a second predetermined period being longer than the first period. A sample/hold circuit holds the voltage from the power supply when a control signal is not supplied, and samples the voltage from the power supply when the control signal is supplied. A comparator compares the voltage from the power supply with a held voltage of the sample/hold circuit, and generates a signal when the voltage from the power supply is higher than the held voltage of the sample/hold circuit.

Abstract: A system comprises a rechargeable battery charged with a constant voltage and a charger. The battery includes a storage unit storing charge voltage data. The charger reads the charge voltage data from the storage unit and charges the battery in accordance with the read charge voltage data. In one aspect, the charger is assigned identification data to identify the charger and charge the battery. In another aspect, a charge controller includes a full-charge detecting means for detecting that the battery is fully charged based upon current measured from the battery.

Abstract: A device for detecting the residual capacity of a battery comprises a battery current measuring circuit for measuring battery current, a battery voltage measuring circuit for measuring battery voltage, a converting circuit for converting the measured current into a voltage value, based on the internal impedance of the battery, and a comparator circuit for comparing the conversion voltage value with the measured voltage. When the measured voltage is smaller than the conversion voltage value, the comparator circuit operates a battery residual-capacity detect signal indicating that the residual capacity of the battery is small.