Abstract: Provided is a battery monitoring system that has a high level of safety even under a state in which characteristics of a reference voltage circuit are deteriorated. The battery monitoring system has a configuration in which: a reference voltage of a first battery monitoring IC is monitored by a second battery monitoring IC; and the second battery monitoring IC outputs, when detecting that the reference voltage reaches a value falling outside a predetermined range, a signal indicating an abnormality of the reference voltage to the first battery monitoring IC, and the first battery monitoring IC stops monitoring of a battery when the signal indicating the abnormality of the reference voltage is input to the first battery monitoring IC.

Abstract: Provided is a battery state monitoring circuit and a battery device capable of predicting a state of charge of a secondary battery with high accuracy. The battery state monitoring circuit includes a pseudo-equivalent circuit of the secondary battery, and causes a current flowing through a sense resistor to flow to the pseudo-equivalent circuit of the secondary battery, to thereby measure a pseudo-open circuit voltage of the secondary battery.

Abstract: Provided is a battery monitoring system that has a high level of safety even under a state in which characteristics of a reference voltage circuit are deteriorated. The battery monitoring system has a configuration in which: a reference voltage of a first battery monitoring IC is monitored by a second battery monitoring IC; and the second battery monitoring IC outputs, when detecting that the reference voltage reaches a value falling outside a predetermined range, a signal indicating an abnormality of the reference voltage to the first battery monitoring IC, and the first battery monitoring IC stops monitoring of a battery when the signal indicating the abnormality of the reference voltage is input to the first battery monitoring IC.

Abstract: Provided is a battery state monitoring circuit and a battery device capable of predicting a state of charge of a secondary battery with high accuracy. The battery state monitoring circuit includes a pseudo-equivalent circuit of the secondary battery, and causes a current flowing through a sense resistor to flow to the pseudo-equivalent circuit of the secondary battery, to thereby measure a pseudo-open circuit voltage of the secondary battery.

Abstract: A power source system including a power distribution apparatus has an energy management system for managing the provision of power from multiple power sources to multiple electrical devices. The power distribution apparatus may have a combination of primary and secondary sources connected to it. It may also have a variety of electrical devices connected to it, receiving power through the power distribution apparatus.

Abstract: A power source system including a power distribution apparatus has an energy management system for managing the provision of power from multiple power sources to multiple electrical devices. The power distribution apparatus may have a combination of primary and secondary sources connected to it. It may also have a variety of electrical devices connected to it, receiving power through the power distribution apparatus.

Abstract: A power source system including a power distribution apparatus has an energy management system for managing the provision of power from multiple power sources to multiple electrical devices. The power distribution apparatus may have a combination of primary and secondary sources connected to it. It may also have a variety of electrical devices connected to it, receiving power through the power distribution apparatus.

Abstract: An implantable secondary battery pack having a battery management system and secondary battery is disclosed. The battery management system is capable of charging the rechargeable battery using low incoming voltage. When the rechargeable battery is charging, the battery management circuit output voltage is almost the same as that of the rechargeable battery. The battery management circuit has battery monitor functions and prevents the rechargeable battery from over-charging or over-discharging by using only one large switch. This invention can be used to remotely recharge implantable medical devices such as a pacemaker, neurostimulator, defibrillator, and cochlear implant.

Abstract: The present invention relates to an improvement in the safety and a reduction in a current consumption in a battery device which is capable of calculating the remaining amount of a lithium ion secondary battery. If the charging and discharging current becomes equal to or lower than a given value, circuits including a current monitoring circuit operate so as to reduce the current consumption. In this situation, the current monitoring circuit stops to function. A control circuit is connected with a differentiating circuit, and if a voltage between both ends of the sense resistor changes, a charging and discharging current monitoring circuit is again operated. With the above solving means, the current consumption can be suppressed, and a precision in the current monitor can be enhanced.

Abstract: A battery circuit, including a secondary battery, a storage capacitor, two switches and two voltage monitor circuits, detects a remaining capacity of the secondary battery and sends out data indicative of the remaining capacity to outside of the battery circuit. A first switch connects a secondary battery to a storage capacitor. A second switch connects the other end of the first switch to the storage capacitor and a load. A storage capacitor voltage monitor circuit measures voltage of the storage capacitor. The first switch is then turned ON and a current from the battery is transferred to the storage capacitor. At this time, the second switch is OFF. Then, the first switch is then turned OFF, and voltage of the storage capacitor indicative of the voltage of the secondary battery is measured. Then, the second switch turns ON and the current flows from the storage capacitor to the external load.

Abstract: Current flows from the secondary battery via the current mirror circuit to the regenerative capacitor. The current mirror circuit multiplies by a numerical constant the current flowing from the secondary battery and supplies the amplified current through the regenerative capacitor. When a voltage value of the regenerative capacitor reaches a predetermined maximum value, the current flows from the regenerative capacitor to the external load. The current flow from the regenerative capacitor continues until the voltage decreases to a predetermined minimum value. Immediately before the voltage of the regenerative capacitor reaches the predetermined minimum value, a terminal voltage of the secondary battery in an open state is measured. This structure enables a charging-and-discharging microcurrent from the secondary battery to be easily monitored, while simultaneously detecting a remaining capacity of the secondary battery.

Abstract: A delay circuit includes a capacitor, a charging/discharging control circuit receptive of an input signal for controlling at least one of the charging and the discharging of the capacitor to set a delay time in accordance with a capacitance value of the capacitor, and a comparing circuit for comparing a voltage at a first terminal of the capacitor with a first reference voltage to produce an output signal which becomes inverted after the delay time when the voltage at the first terminal of the capacitor crosses over the first reference voltage during one of charging and discharging of the capacitor, and comparing a voltage at the first terminal of the capacitor with a second reference and producing an output signal which becomes inverted when the voltage at the first terminal of the capacitor is higher than the second reference voltage so that the delay time is reduced when the first terminal of the capacitor becomes short-circuited to an abnormally high voltage level.

Abstract: By supplying a positive power supply of the operational amplifier from a switching regulator using an input voltage of the operational amplifier as its reference voltage, even if the bias ratio is varied, the ratio of the positive power supply voltage of the operational amplifier to an output voltage of the operational amplifier is always constant, and thus, there is an effect that a liquid crystal display device with low power consumption can be implemented independently of the panel.

Abstract: In a battery state monitoring circuit including a voltage regulator therein, power supply of the voltage regulator is applied from a higher voltage either of a battery or a charger. Also, when the output voltage of the voltage regulator becomes lower, there is structured such as to provide a voltage detecting circuit that sends a signal to the micro-computer.

Abstract: A charge/discharge control circuit is provided for an electric power source apparatus in which a service life is prolonged. A voltage dividing circuit, an overcharge voltage detection circuit, an overdischarge voltage detection circuit and a control circuit are connected in parallel to a secondary cell which is an electric power source, wherein the control circuit detects a condition of the secondary cell from the overcharge/overdischarge voltage detection circuits and outputs a signal Vs for controlling a power supply to an external equipment and a charge by an external power source and controls a switching element provided in series with the voltage dividing circuit and reduces a current which flows through the voltage dividing circuit.

Abstract: In a battery state monitoring circuit including a voltage regulator therein and capable of controlling an internal circuit with a signal from a microcomputer, a circuit is provided in which the control of the internal circuit is available with the signal from the microcomputer in the case where the output of the voltage regulator is normal, and the signal of the internal circuit is decided regardless of the signal from the microcomputer in the case where the output of the voltage regulator is floating or in GND level.

Abstract: A charge/discharge control circuit is provided for an electric power source apparatus in which a service life is prolonged. A voltage dividing circuit, an overcharge voltage detection circuit, an overdischarge voltage detection circuit and a control circuit are connected in parallel to a secondary cell which is an electric power source, wherein the control circuit detects a condition of the secondary cell from the overcharge/overdischarge voltage detection circuits and outputs a signal Vs for controlling a power supply to an external equipment and a charge by an external power source and controls a switching element provided in series with the voltage dividing circuit and reduces a current which flows through the voltage dividing circuit.

Abstract: A charge and discharge control circuit and a chargeable power supply unit incorporating the charge and discharge control circuit are provided with a current detecting element capable of detecting low currents with high accuracy and detecting high currents wuthout excessive power dissipation. The charge and discharge control circuit detects a charge and discharge state of a secondary cell and controls the charging and discharging of the secondary cell in accordance with the detected state. A switch circuit and the current detecting element are connected in series with the secondary cell. The current detecting element has an adjustable resistance value which is varied in accordance with the value of a current flowing therethrough, and comprises a first resistor and a second resistor connected in series, and a switch element connected in parallel to the second resistor.

Abstract: A charge/discharge control circuit is provided for an electric power source apparatus in which a service life is prolonged. A voltage dividing circuit, an overcharge voltage detection circuit, an overdischarge voltage detection circuit and a control circuit are connected in parallel to a secondary cell which is an electric power source, wherein the control circuit detects a condition of the secondary cell from the overcharge/overdischarge voltage detection circuits and outputs a signal Vs for controlling a power supply to an external equipment and a charge by an external power source and controls a switching element provided in series with the voltage dividing circuit and reduces a current which flows through the voltage dividing circuit.

Abstract: A charge/discharge control circuit has a voltage detecting circuit for detecting at least one of an over-charge state, an over-discharge state and an over-current state of a battery, a control circuit for receiving an output signal of the detecting circuit and outputting a signal for controlling the charging and discharging of the battery, and an activating circuit connected to the control circuit for selectively activating the control circuit according to an output signal of the detecting circuit so as to limit the power consumption of the charge/discharge control circuit by operating the control circuit only when one of an over-charge state, an over-discharge state and an over-current state of the electric power source is detected.