Power management device for energy harvesting

What is claimed is: 1. A power management device, comprising: a self-startup circuit including an oscillator and a voltage multiplier to generate a start-up voltage for starting up the power management device in a first start-up period based on an input voltage applied from a thermoelectric element to an input node; a boost converter for performing boost converting to alternately charge the start-up voltage and an output voltage within a predetermined start-up voltage range during a second start-up period following the first start-up period and to charge only the output voltage during an operation period following the second start-up period, the output voltage being applied to a load; a controller to be started up by the start-up voltage, and to control the self-startup circuit and the boost converter based on a magnitude of the start-up voltage; a voltage charger including a start-up voltage capacitor to store the start-up voltage and an output voltage capacitor to store the output voltage; and a shared inductor connected between the input node and a common input node of the oscillator and the boost converter, the shared inductor to operate as a part of the oscillator during the first start-up period and operate as a part of the boost converter during the second start-up period and the operation period. 2. The device of claim 1 , wherein the oscillator and the shared inductor operate together as a Colpitts oscillator. 3. The device of claim 2 , wherein the oscillator comprises: first and second oscillation capacitors connected in series between the common input node and a ground; a native transistor including a drain electrode connected to the input node, a source electrode connected a first node between the first oscillation capacitor and the second oscillation capacitor, and a gate electrode receiving a control voltage from the controller; and a control capacitor connected between the gate electrode and the common input node. 4. The device of claim 3 , wherein the controller deactivates the self-startup circuit and activates the boost converter to start the second start-up period when the start-up voltage is greater than a predetermined reference voltage. 5. The device of claim 4 , wherein the controller outputs the control voltage at 0V in the second start-up period. 6. The device of claim 2 , wherein the boost converter charges the start-up voltage to the start-up voltage capacitor until the start-up voltage reaches an upper boundary value of the predetermined start-up voltage range from a lower boundary value of the start-up voltage range in the second start-up period, and wherein the boost converter charges the output voltage to the output voltage capacitor until the start-up voltage reaches the lower boundary value of the start-up voltage from the upper boundary value of the start-up voltage range. 7. The device of claim 1 , wherein the voltage multiplier includes a plurality of voltage doubler stages, and wherein each of the voltage doubler stages comprises: a first transistor having a diode connected structure in which a drain electrode and a gate electrode are connected to the input node; a second transistor having the diode connected structure connected in series to the first transistor to output the start-up voltage; a first voltage doubler capacitor connected between a source electrode of the first transistor and the common input node; and a second voltage double capacitor connected between a source electrode of the second transistor and a ground. 8. The device of claim 1 , wherein the controller activates the operation period when the output voltage and the start-up voltage become substantially the same in the second start-up period. 9. The device of claim 8 , wherein the voltage charger further includes: a switch to electrically connect one end of the start-up voltage capacitor and one end of the output voltage capacitor, and wherein the controller turns on the switch in the operation period. 10. The device of claim 9 , wherein the controller outputs a control voltage as a negative voltage in the operation period.