A capacitor aging apparatus that includes continuity check pads configured to be electrically connected to positive electrodes of a plurality of capacitors in one-to-one correspondence to check electrical continuity with the plurality of capacitors a plurality of first terminals electrically connected to the plurality of continuity check pads; a plurality of second terminals electrically connected to the plurality of first terminals in one-to-one correspondence; and a plurality of connectors configured to be electrically connected to and disconnected from the plurality of first terminals and the plurality of second terminals, and configured to electrically connect the positive electrodes of the plurality of capacitors, the plurality of connectors each allowing a second terminal corresponding to one capacitor of corresponding two capacitors among the plurality of capacitors to be electrically connected to a first terminal corresponding to another capacitor.

Provided is a system for uninterrupted power using an array of capacitive elements (e.g., ultra-capacitors). The system may include an input, which may receive power from a first power source. A direct current (DC) bus may be connected to the input and may receive power from the input. An array of capacitive elements (e.g., ultra-capacitors) may be connected to the DC bus. An output may be connected the DC bus. The output may include an alternating current (AC) power supply, which may supply power to at least one facility. At least one controller may control charging and discharging of the array of capacitive elements (e.g., ultra-capacitors) connected to the DC bus to supply power from the DC bus to the output. A method and computer program product are also disclosed.

The invention discloses a cardiac pacemaker, characterized in that the cardiac pacemaker comprises a multiple of microneedles and a chip comprising at least one comparator with adaptive level, sequence control circuit, at least one capacitor stack built by n capacitors and 2n switches, at least one buffer capacitor outside the at least one capacitor stack, at least two additional switches outside the at least one capacitor stack, a CMOS-Logic, wherein further, the cardiac pacemaker comprises an interposer layer comprising holes for the multiple of microneedles and a lid. The cardiac pacemaker is characterized in that the chip, is located on one surface of the interposer layer and that the lid and the interposer layer form a capsule for the chip. Further, each microneedle of the array of microneedles has a distal end which protrudes from the chip and the cardiac pacemaker is adapted to be electrically self-sufficient.

Wirelessly powered implantable pulse generators (IPG) are described. In an embodiment, a wirelessly powered stimulator, includes an implantable pulse generator (IPG), including: an Rx antenna that receives a radio frequency (RF) signal from an external Tx antenna; a rectifier; an energy storage capacitor C.sub.STOR, where the RF signal coupled to the Rx antenna is rectified by the rectifier to generate VDD and charges the C.sub.STOR; a demodulator; an output voltage regulator that generates a stable voltage to activate the demodulator; and where the demodulator outputs a stimulation that releases the energy stored in the C.sub.STOR on an electrode based on detecting amplitude modulation in the received RF signal; and a Tx antenna that generates the RF signal that wirelessly powers the IPG and that controls timing of output stimulations of the IPG, where amplitude modulation is applied to the RF signal to control the timing of the output stimulations.

The present disclosure comprises an alternating current-to-direct current converter for converting a commercial power current; a direct current-to-direct current converter for converting a battery current; a common output end at which the output end of the alternating current-to-direct current converter and the output end of the direct current-to-direct current converter are connected through a link capacitor having a preset bus voltage; a first circuit breaking part for opening or closing the current path between the common output end and a load; a second circuit breaking part for opening or closing the current path between the commercial power and the alternating current-to-direct current converter; a third circuit breaking part for opening or closing the current path between the battery and the direct current-to-direct current converter; and a control unit.

A Dielectric Energy Storage System (DESS), a Dielectric Energy Storage System Management System (DESS-MS), and method that stores energy for a wide variety of applications.

An auxiliary power supply device in which an increase in the size of an entire system including both an auxiliary power supply circuit unit and a sub-power supply circuit unit is able to be curbed is provided. There is provided an auxiliary power supply device configured to be connected to a power supply device, the auxiliary power supply device including: an auxiliary power supply circuit unit configured to supply electric power to the power supply device in a case in which supply of electric power to the power supply device is shut off; and a sub-power supply circuit unit having an input side connected to the power supply device and an output side connected to a load and configured to supply an output voltage to other circuit units in accordance with electric power supplied from the power supply device.

Charging an accumulator having an energy storage cell, a data interface and a wake-up circuit. A charging apparatus contains a data interface, a controller, a timer and a switch apparatus. The data interfaces connected to one another via a communication line for differential communication between the accumulator and charging apparatus. Setting the timer to a predetermined period of time; setting the control electronics of the accumulator to a deactivation mode; sending at least one signal from the charging apparatus to the accumulator via the communication line after the predetermined period of time has elapsed; activating the wake-up circuit for activating control electronics by detecting a voltage value from the communication line, the voltage value is consistent with either the dominant or recessive state of the communication line; setting the control electronics to an activation mode; and requesting or releasing a charging current from the charging apparatus using the accumulator.

A method for depassivation of an energy storage device having an anode, a cathode and a core with an electrolyte, the method including: detecting that a first predetermined event related to a buildup of passivation has occurred with regard to the energy storage device; switching between a positive input voltage and a negative input voltage provided to the anode at a frequency sufficient to depassivate the anode; discontinuing the switching when a second predetermined event related to passivation has occurred.

A method for monitoring one or more characteristics of an ultracapacitor is provided. The method includes obtaining a plurality of voltage measurements. Each of the voltage measurements can be obtained sequentially at one of a plurality of intervals. Furthermore, each of the voltage measurements can be indicative of a voltage across the ultracapacitor. The method can include determining an actual voltage step of the ultracapacitor based on two consecutive voltage measurements of the plurality of voltage measurements. The method can further include determining whether the actual voltage step exceeds a threshold voltage step of the ultracapacitor. Furthermore, in response to determining the actual voltage step exceeds the threshold voltage, the method can include providing a notification associated with performing a maintenance action on the ultracapacitor.