Abstract: A real time clock and power management integrated circuit consists of a) an RTC block comprising an internal clock generator for generating a system clock signal that controls a device and b) a power management block. The power management block comprises primary and backup power source connections, a Feed Power Downconverter Component, a backup power source charger power booster/regulator component to increase or regulate voltage from the primary power source to a predetermined charger input voltage, a charge control logic component, a backup power source cut-off logic component, and a mode control logic component to enable operation of the charge control logic component and the battery cut-off logic component under predetermined conditions.

Abstract: Disclosed end-user devices include a processing unit and transceiver circuitry configured to communicate wirelessly with corresponding transceiver circuitry of a network device. Memory of the end-user device stores network device configuration data and instructions to configure the network device, and stores a network device configuration application executable by the processing unit to facilitate configuring the network device by wirelessly transmitting the network device configuration data and instructions to the network device using the transceiver circuitry. The network device configuration application also configures the end-user device to monitor and diagnose the network device through a communications channel established by the transceiver circuitry of the end-user device and the transceiver circuitry of the network device.

Abstract: A real time clock and power management integrated circuit consists of a) an RTC block comprising an internal clock generator for generating a system clock signal that controls a device and b) a power management block. The power management block comprises primary and backup power source connections, a Feed Power Downconverter Component, a backup power source charger power booster/regulator component to increase or regulate voltage from the primary power source to a predetermined charger input voltage, a charge control logic component, a backup power source cut-off logic component, and a mode control logic component to enable operation of the charge control logic component and the battery cut-off logic component under predetermined conditions.

Abstract: A control system for charge and output control of a rechargeable thin film microbattery cell comprises a charge control logic component configured to control the level of charge of a thin film microbattery cell, a battery cut-off logic component to cease current draw on the thin battery thin film microbattery cell under predetermined conditions, a mode control logic component operably coupled to the charge control logic component and the battery cut-off logic component to enable operation of the charge control logic component and the battery cut-off logic component under predetermined conditions, and a Switch Capacitor DC-DC Downconverter Component for delivery of voltage external to the system configured to reduce battery output voltage potential by a factor of at least 2:1. Systems operably connected to a rechargeable thin film microbattery cell and powered devices comprising the system and the microbattery cell are also described.

Abstract: A rechargeable thin film microbattery cell array of at least four thin film microbattery cells is electrically connected together in parallel to provide power as a single battery power source. The array further comprises testing logic to determine if a microbattery cell has a microbattery cell voltage that is more than a predetermined percentage different from the voltage of the overall microbattery cell array or has an absolute voltage below a predetermined cutoff threshold, and logic to disconnect any microbattery cell from the microbattery cell array if the microbattery cell has a microbattery cell voltage that is more than a predetermined percentage different from the voltage of the overall microbattery cell array or has an absolute voltage below a predetermined cutoff threshold. Embodiments also comprise a Switch Capacitor DC-DC downconverter component that reduces the voltage potential to operate some or all functionalities located on the integrated circuit.

Abstract: A control system for charge and output control of a rechargeable thin film microbattery cell comprises a charge control logic component configured to control the level of charge of a thin film microbattery cell, a battery cut-off logic component to cease current draw on the thin battery thin film microbattery cell under predetermined conditions, a mode control logic component operably coupled to the charge control logic component and the battery cut-off logic component to enable operation of the charge control logic component and the battery cut-off logic component under predetermined conditions, and a Switch Capacitor DC-DC Downconverter Component for delivery of voltage external to the system configured to reduce battery output voltage potential by a factor of at least 2:1. Systems operably connected to a rechargeable thin film microbattery cell and powered devices comprising the system and the microbattery cell are also described.

Abstract: A rechargeable thin film microbattery cell array of at least four thin film microbattery cells is electrically connected together in parallel to provide power as a single battery power source. The array further comprises testing logic to determine if a microbattery cell has a microbattery cell voltage that is more than a predetermined percentage different from the voltage of the overall microbattery cell array or has an absolute voltage below a predetermined cutoff threshold, and logic to disconnect any microbattery cell from the microbattery cell array if the microbattery cell has a microbattery cell voltage that is more than a predetermined percentage different from the voltage of the overall microbattery cell array or has an absolute voltage below a predetermined cutoff threshold. Embodiments also comprise a Switch Capacitor DC-DC downconverter component that reduces the voltage potential to operate some or all functionalities located on the integrated circuit.

Abstract: A method and apparatus for a unitary battery and charging circuit. Also, having a power conversion system includes a variable charging source and an energy storage device. The power conversion circuit also includes a charging circuit coupled to the variable charging source and the energy storage device, the energy storage device being charged by the variable charging source. Further, the circuit includes an energy storage device isolation circuit configured to isolate the energy storage device from discharging when power from the variable charging source is below a predetermined threshold. Further still, the conversion circuit includes a restart circuit configured to restart the charging circuit by utilizing power from the energy storage device when charging power has dropped below a predetermined level.

Abstract: A method and apparatus for a unitary battery and charging circuit that includes a first substrate having integrated-circuit battery-charging circuitry thereon, and a cathode material, an anode material, and an electrolyte layer separating the cathode material from the anode material deposited on the substrate to form a battery, wherein the charging circuit is connected to the battery and encapsulated to form a surface-mount unitary package. Also, a power conversion system includes a variable charging source and an energy storage device. The power conversion circuit also includes a charging circuit coupled to the variable charging source and the energy storage device, the energy storage device being charged by the variable charging source. Further, the circuit includes an energy storage device isolation circuit configured to isolate the energy storage device from discharging when power from the variable charging source is below a predetermined threshold.

Abstract: A handheld, battery operated network testing device uses disk loaded software, programmable gate arrays, and digital signal processing to selectively configure the device for a full range of analog and digital testing modes in a variety of communications protocols, including T-1 full duplex drop and insert. A 25 by 80 column LCD display provides for a full scale video output, and a unique, power efficient, electroluminescent backlight circuit provides for viewing of the display in poorly lit environments.