Abstract: A modular system architecture for a process stream generating historical work transactional data. The data are received by a system Data Import Module. The Data Import Module transforms the historical work transactional data into at least one Workload Volume. A Forecast Module in communication with the Data Import Module receives a selected Workload Volume and projects a future workload demand or Forecasted Workload Volumes derived from a selected search algorithm. A Staffing Requirements Module in communication with the Forecast Module receives a selected Forecasted Workload Volume. The Staffing Requirements Module has a plurality of Staffing Guide functions applying staffing constraints that drive the Forecasted Workload Volume. A Scheduling Module in communication with the Staffing Requirements Module receives a selected Staffing Requirements and transforms the Staffing Requirements into a schedule viewable by a user.

Abstract: A method and device for using topically applied acoustical vibrations to stimulate the production of adult stem cells in living organisms. This approach is non-invasive, and more specifically does not involve introducing chemicals or physically invading the organisms. One or more acoustical transducers are placed directly on the skin of the organism in certain locations, and selected vibration profiles are applied to the organism through the transducers. The treatment includes the regular application of various vibration pulse profiles that generally include sequences of pulses in which each pulse has a duration in the range of one-half to ten seconds, is separated by rest periods in the range of one-tenth to three seconds, is modulated with an oscillatory signal in the frequency range of 1 Hz to 1,500 Hz, and has a pulse amplitude in the range of range from about 20 to 5000 microns.

Abstract: A processor (10) controls the operation of the device and preferably provides for a plurality of operational algorithms or modes. A program switch (18) allows the user to select which algorithm will be used. The processor drives an inverter (12), which drives a power amplifier or bridge (13). The output of the bridge 13 is connected to one or more transducers 16. When the user presses the switch (19A), the processor begins the algorithm. One or more of the transducers are placed on the patient's body in the area to be treated. The algorithms provide for lower-frequency and higher-frequency sweeps, which the transducers convert to microvibrations which, in turn, massage not only the muscles and the larger blood vessels, but also the smaller blood vessels and capillaries, and provide for improved blood circulation in the affected area, thereby relieving pain and enhancing recovery.

Abstract: A modular system architecture for a process stream generating historical work transactional data. The data are received by a system Data Import Module. The Data Import Module transforms the historical work transactional data into at least one Workload Volume. A Forecast Module in communication with the Data Import Module receives a selected Workload Volume and projects a future workload demand or Forecasted Workload Volumes derived from a selected search algorithm. A Staffing Requirements Module in communication with the Forecast Module receives a selected Forecasted Workload Volume. The Staffing Requirements Module has a plurality of Staffing Guide functions applying staffing constraints that drive the Forecasted Workload Volume. A Scheduling Module in communication with the Staffing Requirements Module receives a selected Staffing Requirements and transforms the Staffing Requirements into a schedule viewable by a user.

Abstract: A battery is rapidly charged utilizing a bipolar waveform (21, 22). The voltage, current, duration and frequency parameters of the bipolar waveform are selected to perform a number of actions: enhancing the mixing action at the battery electrodes; measuring the battery's capacitance, condition, and level of impedance; modifying the mass transport process inside the battery; and reducing the concentration of the diffusion layer, the polarization concentration, and the overpotential. This reduces internal heat generation by providing for more efficient ion transport, reduced concentration gradients, and increased diffusion rates and intercalation speeds. A bipolar waveform can be in the form of sine waves, or other wave shapes. A charge pulse (11) is preferably followed by a small technical rest period (12), after which a discharge pulse (13) is applied followed, in turn, by a rest period (14). The bipolar waveform (21) is superimposed on one or more of the above.

Abstract: A method and an apparatus for rapidly charging a battery. The preferred charging method comprises applying one or more charging pulses (C1, C2), separated by a waiting period (CW1), with the last charging pulse, if there are more than one, being followed by a second waiting period (CW2). This is then followed by a series of discharging pulses (D1, D2, D3), which are separated by waiting periods (DW1, DW2), and followed by a last waiting period (DW3) before the occurrence of the next charging pulse (C1). The discharging pulses preferably have a magnitude which is approximately the same as the magnitude of the charging pulses but which have a duration which is substantially smaller than the duration of the charging pulses. The discharging pulses serve to create and disperse ions throughout the electrolyte of the battery so that the ions do not shield the plates of the battery from further charge transfer.

Abstract: An improved method and device for rapidly charging a battery by providing a charge pulse to the battery, followed immediately by a depolarization pulse created by allowing the battery to discharge across a load, followed by a stabilization period, and repeating this sequence cyclically until the battery is charged is disclosed. Preferably, the current level of the charge pulse is equal to or greater than the nominal rated current at which the battery can discharge in an hour, in order to achieve rapid charging. The duration of the charge pulse will generally be about one-tenth to two seconds. The current level of the depolarization pulse may be approximately the same magnitude or greater than the charging current, but of significantly shorter duration, such as 0.2-5% of the duration, to avoid unnecessary discharging of the battery. The duration of the stabilization period is generally greater than the magnitude of the depolarizing pulse.