Power regulator having current and voltage modes

What is claimed is: 1. A method of supplying power to a load that becomes episodically disconnected and then re-connected to draw current from a multi-mode regulated power supply and from a charge storage device at plural times which are unpredictable to the multi-mode regulated power supply, the method comprising: automatically detecting if on a time averaged basis, more than a predetermined first amount of average current is being drawn from the multi-mode regulated power supply, and if not, responsively causing the charge storage device to be charged by the multi-mode regulated power supply to a predetermined first voltage by use of a voltage controlled mode of the multi-mode regulated power supply, where the load is one that becomes episodically connected to draw current from the charge storage device at a same time that the load becomes episodically connected to receive current from the multi-mode regulated power supply; in response to detecting that on the time averaged basis more than the predetermined first amount of average current is being drawn from the multi-mode regulated power supply, automatically switching the multi-mode regulated power supply to a current regulating mode to thereby limit the amount of average current that can be drawn from the multi-mode regulated power supply to a second amount of average current, the second amount being greater than the first amount of average current; and in response to detecting that on the time averaged basis less than the predetermined first amount of average current is being drawn from the multi-mode regulated power supply, automatically switching the multi-mode regulated power supply to the voltage controlled mode to thereby cause the charge storage device to again be charged by the multi-mode regulated power supply to the predetermined first voltage. 2. The method of claim 1 and further comprising: automatically switching the multi-mode regulated power supply back to a current regulating mode upon again detecting that the time averaged current being drawn from the multi-mode regulated power supply is again more than the predetermined first amount of average current. 3. The method of claim 1 wherein: the charge storage device includes a capacitor; and the load includes a temperature and voltage sensitive device that provides an output where the output behavior of the device is more so determined by current levels passing therethrough than by its temperature and by corresponding voltages that develop across the temperature and voltage sensitive device. 4. The method of claim 3 wherein: the temperature and voltage sensitive device includes a semiconductive light emitter whose output luminance is more so determined by current levels that it receives rather than by its temperature and by corresponding voltages that develop across the semiconductive light emitter. 5. The method of claim 4 wherein: the semiconductive light emitter is one that needs to receive an episodic surge of current of 0.5 Ampere or more to produce an application adequate output luminance. 6. The method of claim 1 wherein: the load is connected in series with a semiconductive switching device and the load episodically becomes connected to draw current from the multi-mode regulated power supply due to episodic closing and opening of the semiconductive switching device, the method further comprising: causing the semiconductive switching device to close and open, the closing of the semiconductive switching device occurring in 10 nanoseconds (10 ns) or less. 7. The method of claim 1 wherein the causing of the charge storage device to be charged to the predetermined first voltage while using the voltage controlled mode comprises: generating a feedback voltage that is a predetermined amount less than an output voltage produced by the multi-mode regulated power supply; applying the feedback voltage to a feedback resistor; comparing the feedback voltage with a reference voltage; and in response to detecting that the feedback voltage is equal to or greater than the reference voltage, deactivating a voltage booster that generates the output voltage produced by the multi-mode regulated power supply. 8. The method of claim 7 wherein the generating of the feedback voltage comprises: passing a feedback current through the feedback resistor; and passing the feedback current through a first voltage sensitive device having a respective first threshold voltage, where the first voltage sensitive device switches from a relatively low resistance mode to a substantially higher resistance mode when voltage across the first voltage sensitive device drops below the first threshold voltage; wherein during the voltage controlled mode, the voltage sensitive device operates just above its threshold voltage; and wherein the load, when reconnected to draw current, is coupled so as to divert at least a predetermined amount of current away from flowing through the voltage sensitive device, where the diverting away of the at least predetermined amount of current causes the voltage sensitive device to switch into operating below its threshold voltage and thus to switch into operating in its substantially higher resistance mode. 9. The method of claim 8 wherein the switching of the multi-mode regulated power supply to the current regulating mode comprises: producing a sampling current that is representative of a magnitude of the time averaged current drawn from the multi-mode regulated power supply; and passing the sampling current through the feedback resistor. 10. The method of claim 8 and further comprising: passing the feedback current through a second voltage sensitive device having a respective second threshold voltage, where the second voltage sensitive device respectively switches from a second relatively low resistance mode to a second substantially higher resistance mode when voltage across the second voltage sensitive device drops below the second threshold voltage, the second voltage sensitive device being connected in series with the first voltage sensitive device. 11. The method of claim 10 wherein: the first voltage sensitive device includes a reverse biased Zener diode; and the second voltage sensitive device includes a forward biased diode. 12. The method of claim 1 and further comprising: causing the load to become episodically connected to receive current from the multi-mode regulated power supply by commanding a firing of a rapid train of pulses each having a pulse duration of 50 nanoseconds or less. 13. The method of claim 1 wherein: the time averaged current drawn from the multi-mode regulated power supply is passed through an output inductor of the multi-mode regulated power supply. 14. The method of claim 13 wherein: the output inductor is part of a low pass output filter of the multi-mode regulated power supply which further includes a capacitor. 15. The method of claim 1 wherein: the multi-mode regulated power supply includes a digitally controlled voltage boosting module that when activated, pumps a predetermined amount of boosting current and when deactivate does not pump out boosting current; and the automatic switching of the multi-mode regulated power supply to the current regulating mode includes digitally controlling the voltage boosting module based on sensing of the average current being drawn from the multi-mode regulated power supply. 16. The method of claim 15 wherein: the automatic switching of the multi-mode regulated power supply to the voltage controlled mode includes digitally controlling the voltage boosting