Methods for online estimation of battery capacity and state of health

What is claimed is: 1. A method of battery management with real-time monitoring of battery capacity and battery state of health in a metal-ion battery configured with an active material, an anode, a cathode, an external circuit in electrical communication with said anode and said cathode, and a battery management system linked in operable communication with said metal-ion battery, said method comprising: (a) correlating, in said battery management system, electrode open-circuit voltage with electrode state of charge for each of said anode and said cathode; (b) calculating, in said battery management system, electrode capacity for each of said anode and said cathode, and active-material capacity, wherein said method to calculate said electrode capacity and said active-material capacity comprising a non-linear curve minimization technique at the beginning of life of said battery, the non-linear curve minimization technique is a Nelder-Mead technique; (c) in said battery management system, compiling or obtaining a look-up table, graph, and/or equation to correlate, for each of said anode and said cathode, said electrode open-circuit voltage with said electrode capacity at different values of said active-material capacity; (d) in said battery management system, during real-time operation of said battery, identifying first and second times at which battery terminal voltages are approximated as battery open-circuit voltages; (e) calculating, in said battery management system, battery capacity based on the difference in battery open-circuit voltages at said first and second times, current integration between said first and second times, and said look-up table, graph, and/or equation provided in step (c); (f) estimating, in said battery management system, battery state of health based at least on said battery capacity calculated in step (e); and (g) utilizing said battery capacity and battery state of health in said battery management system that is in real-time communication with said metal-ion battery, wherein said battery management system is continuously updated with said battery capacity and said battery state of health to enhance battery efficiency, and wherein said battery management system adjusts electrical current between said metal-ion battery and said external circuit, in response to said battery capacity from step (e) and said battery state of health from step (f), wherein the following formula for battery open-circuit voltage as a function of capacities is utilized in said method: V oc ⁡ ( Q ) = V oc ⁡ ( Q Q c ) - V oc ⁡ ( Q Li - Q Q a ) where V oc is battery open-circuit voltage, Q is battery capacity, Q c is cathode capacity, Q a is anode capacity, and Q t,i is active-material capacity. 2. The method of claim 1 , wherein said metal-ion battery is a lithium-ion battery and wherein said active-material capacity is recyclable lithium capacity. 3. The method of claim 1 , wherein step (c) utilizes said look-up table to correlate said electrode open-circuit voltage with said electrode capacity at different values of said active-material capacity. 4. The method of claim 1 , said method further comprising correlating the difference in said battery capacity at said first and second times with said active-material capacity, based on said battery open-circuit voltages at said first and second times and said look-up table, graph, and/or equation. 5. The method of claim 4 , wherein said active-material capacity is derived from a measured difference in said battery capacity at said first and second times. 6. The method of claim 1 , wherein said look-up table, graph, and/or equation to correlate said electrode open-circuit voltage with said electrode capacity at different values of said active-material capacity, is constant during operation and aging of said battery. 7. The method of claim 1 , wherein said look-up table, graph, and/or equation to correlate said electrode open-circuit voltage with said electrode capacity at different values of said active-material capacity, changes over the life of the battery. 8. The method of claim 7 , wherein step (a) comprises direct measurements of said electrode open-circuit voltage and said electrode state of charge. 9. The method of claim 7 , wherein step (a) utilizes a beginning-of-life look-up table, graph, and/or equation along with a known voltage fade function. 10. The method of claim 1 , wherein loss in said active-material capacity dominates loss in said battery capacity. 11. The method of claim 1 , wherein said battery capacity is limited by amount of metal-ion inventory. 12. The method of claim 1 , wherein said battery capacity is not limited by amount of metal-ion inventory; said method further comprising utilizing predetermined anode and cathode aging correlations. 13. The method of claim 1 , said method further comprising predicting a future battery capacity by extrapolating, in time, said battery capacity calculated in step (e). 14. The method of claim 1 , wherein said battery management system is continuously updated with said battery capacity and said battery state of health on a battery-management time scale of about one millisecond or less. 15. The method of claim 1 , wherein said battery state of health includes said battery capacity as a function of battery age, said method further comprising predicting a future battery state of health by extrapolating said battery capacity as a function of battery age. 16. A method of battery management with real-time monitoring of battery capacity and battery state of health in a metal-ion battery configured with an active material, an anode, a cathode, an external circuit in electrical communication with said anode and said cathode, and a battery management system linked in operable communication with said metal-ion battery, said method comprising: (a) correlating, in said battery management system, electrode open-circuit voltage electrode state of charge for each of said anode and said cathode; (b) calculating, in said battery management system, electrode capacity for each of said anode and said cathode, and active-material capacity; (c) in said battery management system, compiling or obtaining a look-up table, graph, and/or equation to correlate, for each of said anode and said catho