Wireless power status through boosted output voltage

What is claimed is: 1. A method, comprising: removing a battery cover from an outer assembly of a lock device; removing a battery pack from the lock device in response to removing the battery cover, wherein removing the battery pack comprises disconnecting two electrical contacts of the battery pack from two corresponding electrical contacts of the lock device; and electrically coupling two electrical contacts of a retrofit assembly to the two corresponding electrical contacts of the lock device, wherein the retrofit assembly includes an energy storage device, a wireless power receiver configured to store generated power in the energy storage device, a boost regulator, and a microcontroller configured to adjust an output voltage of the boost regulator to indicate a power level of the energy storage device and a charging status of the energy storage device. 2. The method of claim 1 , wherein adjusting the output voltage to indicate the power level of the energy storage device and the charging status of the energy storage device comprises: adjusting the output voltage to within a first voltage range if the charging status indicates that the energy storage device is charging; and adjusting the output voltage to within a second voltage range if the charging status indicates that the energy storage device is not charging, wherein the second voltage range is non-overlapping with the first voltage range. 3. The method of claim 2 , wherein adjusting the voltage output to indicative the power level of the energy storage device and the charging status of the energy storage device comprises: adjusting the output voltage to a voltage value within the first voltage range that is proportionate within the first voltage range to a percentage of power remaining in the energy storage device if the charging status indicates that the energy storage device is charging; and adjusting the output voltage to a voltage value within the second voltage range that is proportionate within the second voltage range to a percentage of power remaining in the energy storage device if the charging status indicates that the energy storage device is not charging. 4. The method of claim 3 , wherein the first voltage range is from 5.5V to 7V and the second voltage range is from 4V to 5.5V. 5. The method of claim 1 , further comprising: receiving, by a microcontroller of the lock device, the output voltage sensed at the two corresponding electrical contacts; and analyzing, by the microcontroller of the lock device, the output voltage to determine the power level of the energy storage device and the charging status of the energy storage device. 6. The method of claim 1 , wherein the energy storage device, the wireless power receiver, the boost regulator, and the microcontroller form a portion of a modular component. 7. The method of claim 1 , wherein the energy storage device comprises a rechargeable lithium battery. 8. The method of claim 1 , wherein the retrofit assembly is electrically coupled to the lock device via only the two corresponding electrical contacts of the lock device. 9. The method of claim 1 , wherein the boost regulator comprises a boost converter and a feedback network. 10. The method of claim 9 , wherein the feedback network comprises a digital potentiometer. 11. The method of claim 1 , further comprising generating power with the wireless power receiver based on electromagnetic radiation absorbed by the wireless power receiver. 12. The method of claim 11 , wherein the electromagnetic radiation comprises directed infrared light. 13. A retrofit assembly, comprising: two electrical contacts; an energy storage device; a wireless power receiver configured to convert electromagnetic radiation into electrical power stored in the energy storage device; a boost regulator configured to vary feedback resistance based on one or more input signals to adjust an output voltage across the two electrical contacts; and a microcontroller configured to transmit the one or more input signals to the boost regulator to adjust the output voltage based on a power level of the energy storage device and a charging status of the energy storage device. 14. The retrofit assembly of claim 13 , wherein to adjust the output voltage to indicate the power level of the energy storage device and the charging status of the energy storage device comprises to: adjust the output voltage to within a first voltage range if the charging status indicates that the energy storage device is charging; and adjust the output voltage to within a second voltage range if the charging status indicates that the energy storage device is not charging, wherein the second voltage range is non-overlapping with the first voltage range. 15. The retrofit assembly of claim 14 , wherein to adjust the voltage output to indicative the power level of the energy storage device and the charging status of the energy storage device comprises to: adjust the output voltage to a voltage value within the first voltage range that is proportionate within the first voltage range to a percentage of power remaining in the energy storage device if the charging status indicates that the energy storage device is charging; and adjust the output voltage to a voltage value within the second voltage range that is proportionate within the second voltage range to a percentage of power remaining in the energy storage device if the charging status indicates that the energy storage device is not charging. 16. The retrofit assembly of claim 13 , wherein the energy storage device, the wireless power receiver, the boost regulator, and the microcontroller form a portion of a modular component. 17. The retrofit assembly of claim 13 , wherein the energy storage device comprises a rechargeable lithium battery. 18. The retrofit assembly of claim 13 , wherein the retrofit assembly is electrically coupled to a lock device via only the two electrical contacts. 19. The retrofit assembly of claim 13 , wherein the boost regulator comprises a boost converter and a feedback network. 20. The retrofit assembly of claim 19 , wherein the feedback network comprises a digital potentiometer.