초록 ▼

A method and a battery powered electronic device incorporate use-adaptive fuel gauging. The use-adaptive fuel gauging adapts a fuel gauge algorithm to an average use model for the device. The adaptation accounts for the effects that variations in average use by a user of the device have on a total a

A method and a battery powered electronic device incorporate use-adaptive fuel gauging. The use-adaptive fuel gauging adapts a fuel gauge algorithm to an average use model for the device. The adaptation accounts for the effects that variations in average use by a user of the device have on a total available energy or charge capacity of a battery. Accordingly, use-adaptivity can improve the fuel gauging accuracy by improving an estimate of the total energy available. The method and device optionally account for different battery chemistries yielding further increases in fuel gauging accuracy compared to conventional fuel gauging approaches.

대표청구항 ▼

What is claimed is: 1. A method of fuel gauging in an electronic device having a battery, the method comprising: adapting the fuel gauging in the device to a use model, the use model comprising how the device is actually used by a user, wherein adapting the fuel gauging comprises: checking a charge

What is claimed is: 1. A method of fuel gauging in an electronic device having a battery, the method comprising: adapting the fuel gauging in the device to a use model, the use model comprising how the device is actually used by a user, wherein adapting the fuel gauging comprises: checking a charge level of the battery each time the battery is replaced; monitoring a net energy extracted from the battery as a function of time during use of the device by the user; updating an estimated total available battery energy, wherein the estimated total available battery energy is derived from the net energy extracted; and adapting the fuel gauging to the updated estimated total available battery energy, wherein checking the battery charge level comprises: detecting a battery replacement event; measuring the charge level of the battery; and comparing the measured charge level to an expected charge level range. 2. A method of fuel gauging in an electronic device having a battery, the method comprising: adapting the fuel gauging in the device to a use model, the use model comprising how the device is actually used by a user, wherein adapting the fuel gauging comprises: checking a charge level of the battery each time the battery is replaced to determine whether the battery is fully charged; monitoring a net energy extracted from the battery as a function of time during use of the device by the user; updating an estimated total available battery energy, wherein the estimated total available battery energy is derived from the net energy extracted; and adapting the fuel gauging to the updated estimated total available battery energy, wherein checking the battery charge level comprises: measuring the charge level of the battery; and comparing the measured charge level to an expected charge level range, the expected charge level range being the range for a fully charged battery. 3. The method of claim 2, wherein only when a fully charged battery is determined, are monitoring, updating and adapting performed. 4. The method of claim 2, wherein the net energy extracted from the battery is determined directly by measuring a net energy flowing out of the battery. 5. The method of claim 2, wherein the net energy extracted from the battery is determined indirectly by keeping track of operations performed by the device and using known energy consumption characteristics associated with each of the device operations. 6. The method of claim 2, optionally further comprising periodically measuring a battery voltage during device operation, and recording the measured voltage in memory of the device. 7. A method of fuel gauging in an electronic device having a battery, the method comprising: adapting the fuel gauging in the device to a use model, the use model comprising how the device is actually used by a user, wherein adapting the fuel gauging comprises: monitoring a net energy extracted from the battery as a function of time during use of the device by the user; updating an estimated total available battery energy, wherein the estimated total available battery energy is derived from the net energy extracted; and adapting the fuel gauging to the updated estimated total available battery energy, wherein updating an estimated total available energy from the battery comprises computing a moving average of a value for a total of the net energy extracted from a most recently installed battery and a value for a total of the net energy extracted for one or more previously installed batteries. 8. A method of fuel gauging in an electronic device having a battery, the method comprising: checking a charge level of the battery; comparing the checked level to an expected charge level range; updating an estimated total available battery energy comprising computing a moving average of a value for a total of a net energy extracted from a most recently installed battery and a value for a total of the net energy extracted for one or more previously installed batteries; and adapting the fuel gauging in the device to a use model, wherein the use model comprises how the device is actually used by a user, and wherein the battery is non-rechargeable. 9. The method of claim 8, further comprising: determining a battery chemistry for the battery; and Thither adapting the fuel gauging to the determined battery chemistry. 10. A method of fuel gauging in an electronic device having a battery, to method comprising: updating an estimated total available battery energy, wherein updating comprises computing a moving average of a value for a total of a net energy extracted from a most recently installed battery and a value for a total of the net energy extracted for one or more previously installed batteries; and adapting the fuel gauging in the device to a use model, wherein the use model comprises how the device is actually used by a user. 11. The method of claim 10, wherein the use model further comprises historical data of a total net energy extracted from each battery used in the device by the user. 12. The method of claim 10, wherein adapting the fuel gauging comprises: monitoring the net energy extracted from the most recently installed battery as a function of time during use of the device by the user; and adapting the fuel gauging to the updated estimated total available battery energy, the estimated total available battery energy being derived from the net energy extracted. 13. The method of claim 12, further comprising checking a charge level of the most recently installed battery prior to monitoring. 14. The method of claim 13, wherein checking battery charge level comprises: measuring the charge level of the most recently installed battery; and comparing the measured charge level to an expected charge level range. 15. The method of claim 14, wherein checking battery charge level further comprises detecting a battery replacement event prior to measuring the charge level of the most recently installed battery. 16. The method of claim 14, wherein checking battery charge level determines whether the most recently installed battery is fully charged, and in comparing, the expected charge level range is the range for a fully charged battery. 17. The method of claim 16, wherein monitoring, updating and adapting are performed only when a fully charged battery is determined. 18. The method of claim 12, wherein monitoring comprises: determining the net energy extracted from the most recently installed battery; and recording in a memory of the device a value representing the determined net extracted energy. 19. The method of claim 12, wherein the net energy extracted from the most recently installed battery is monitored until a cut-off point is reached in a discharge cycle of the most recently installed battery. 20. The method of claim 12, wherein the net energy extracted from the most recently installed battery is determined directly by measuring a net energy flowing out of the most recently installed battery. 21. The method of claim 12, wherein the net energy extracted from the most recently installed battery is monitored indirectly by keeping track of the operations performed by the device and using known energy consumption characteristics associated with each of the device operations. 22. The method of claim 12, optionally further comprising periodically measuring a battery voltage during device operation, and recording the measured voltage in memory of the device. 23. The method of claim 12, wherein updating an estimated total available energy from the most recently installed battery comprises computing an avenge of a previous estimated total available energy and a total of the net energy extracted from the most recently installed battery. 24. The method of claim 10, further comprising: monitoring the net energy extracted from the most recently installed battery during use of the device by the user, wherein die updated estimated total available battery energy represents the use model and the estimated total available battery energy is derived from the net energy extracted. 25. The method of claim 24, wherein the fuel gauging is adapted to the updated estimated total available battery energy by subtracting the net energy extracted from the updated estimated energy to generate a fuel gauge reading. 26. The method of claim 25, wherein the fuel gauging is adapted in parallel with monitoring, such that the fuel gauging is adapted to an existing estimated total available battery energy from a previous updating. 27. The method of claim 10, further comprising: determining a battery chemistry for the most recently installed battery; and further adapting the fuel gauging to the determined battery chemistry. 28. The method of claim 27, wherein a rechargeable battery chemistry is distinguished from a non-rechargeable battery chemistry. 29. An electronic device with use-adaptive fuel gauging, the electronic device using a battery for power, the electronic device comprising: a battery monitor that measures a characteristic of the battery; a controller that receives the measured battery characteristic from the battery monitor; a memory tat provides temporary data storage for the controller; a user interface that displays results produced by the controller, and a fuel gauge algorithm stored iii the memory as a computer program, the computer program comprising instructions that, when executed by the controller, check the charge level of a newly installed battery, monitor a net energy extracted from the newly installed battery, update an estimated total available energy, and adapt the fuel gauging to the estimated total available energy, wherein the instructions that update an estimated total available energy comprise instructions that compute a moving average of a value for a total of the net energy extracted from a most recently monitored battery and a value for a total of the net energy extracted for one or more previously monitored batteries. 30. The electronic device of claim 29, wherein the computer program further comprises instructions that implement optionally determining battery chemistry, and wherein the fuel gauging is further adapted to the determined battery chemistry. 31. The electronic device of claim 29, wherein the computer program is stored in the memory as either firmware or software. 32. The electronic device of claim 29, wherein the computer program is incorporated into logic circuitry of the electronic device. 33. The electronic device of claim 29, wherein the electronic device is a digital camera that further comprises an optical subsystem that is controlled by the controller. 34. The electronic device of claim 29, wherein the net energy extracted from the newly installed battery is monitored indirectly by keeping track of operations performed by the device and using known energy consumption characteristics associated with each of the device operations. 35. An electronic device with use-adaptive fuel gauging, the electronic device using a battery for power, the electronic device comprising: a battery monitor that measures a characteristic of the battery; a controller that receives the measured battery characteristic from the battery monitor; a memory that provides temporary data storage for the controller; a user interface that displays results produced by the controller; and a fuel gauge algorithm stored in the memory as a computer program, the computer program comprising instructions that when executed by the controller, update an estimated total available energy, and adapt the fuel, gauging in the device to a use model, wherein the instructions that update comprise instructions that compute a moving average of a value for a total of a net energy extracted from a most recently installed battery and a value for a total of the net energy extracted for one or more previously installed batteries, and wherein the use model comprises how the device is actually used by a user.