1. Appendix D Example n The procedure described in Appendix D is meant to determine a battery’s performance parameters from the data taken during a HPPC test. The goal is to determine R o and R p with respect to SOC; the time constant tau also needs to be determined. What is known is I L, Voltage, and A-s with respect to time. The procedure assumes that an equation for voltage can be created that has I L, I p and A-s its variables. The coefficients will then be R o, R p, OCV’, and OCV. For this to work, I p will also have to be calculated. The procedure revolves around an Excel function named LINEST and assumes the battery model shown.

2. Start by entering the appropriate labels in an Excel file; column numbers go up to twelve

3. From a HPPC data file carry in Time, I load, A-s, and Voltage

4. Enter a zero into the first cell of dT/tau and make a guess for tau, then use tau in the equation for the second cell of dT/tau (be sure to use dollar signs in front of the tau’s reference) dT/tau=(t i - t i-1 )/tau

5. Copy the second dt/tau cell and use it to fill in the rest of the column

6. The Ip column can now be filled in; enter a 0 into the first cell, and enter the formula for Ip from the manual into the second cell

7. Copy the second cell and use it to fill in the rest of the column

8. The LINEST function now needs to be set up; enter OCV’, Rp, Ro, and OCV under columns 9-12 and highlight a 5x4 block underneath them

9. Go to Insert/Function, and click on LINEST

10. The LINEST block needs each cell to be filled in; start by clicking on the square with the red arrow that is across from Known_y’s

11. Highlight the entire Voltage column and hit Enter, this will create an array for the Known_y’s block

12. The Known_x’s block is next; click on the square corresponding to that cell

13. This time highlight the three columns under I load, Ip, and A-s and hit Enter

14. Now that the Known_y’s and Known_x’s cells contain arrays, the Const and Stats cells need filled in

15. For the purposes of modeling a battery, the last two cells can just have TRUE typed into them; to display the results hit Ctrl-Shift-Enter

16. After hitting Ctrl-Shift-Enter the results will appear in the 5x4 block that was highlighted

17. The first row of values are coefficients for a linear equation where Voltage is the dependent variable and I load, Ip, and A-s are the independent variables; OCV’ goes with A-s, Rp with Ip, Ro with I load, and OCV is the “b” value Voltage=(A-s)(OCV’)+( Ip)(Rp)+(I load)(Ro)+ OCV

18. Use the voltage formula in the first cell of Estimated V load Voltage=(A-s)(OCV’)+( Ip)(Rp)+(I load)(Ro)+ OCV

19. Copy the first cell to fill in the rest of the column, remember that the coefficients in the formula need to have a dollar sign in front

20. Fill in the V error column by taking the difference between the measured voltage and estimated voltage; if the formula is good the errors should be small

21. The third cell down in the leftmost column of the results is the r 2 value, this number indicates the accuracy of the formula; the formula is perfect if r 2 is equal to one, and the battery manual requires that r 2 be >0.995

22. The rest of the cells give more statistics on the formula that LINEST created, but they will not be used in this application

23. Tau affects all of the results, but in the beginning it was only guessed; to get the correct value, adjust tau so that it gives the maximum value of r 2, then consider that the true value

24. For this example 9.4 was the best value for tau; changing tau by 0.1 caused changes in r 2 as small as 1x10 -6

25. Sometimes there is “noisy data” in the Voltage column; a bad cell can be edited out by setting it equal to the corresponding calculated value

26. Excel must be in “Iteration” mode for the editing strategy to work; this mode can be set by choosing Tools/Options/Calculation and checking the appropriate box

27. Two charts can be made, the first is of V error vs. Time

28. The second chart is of Measured and Estimated Voltage vs. time; both charts can be used to graphically see how well the LINEST formula follows the measured data

29. n This procedure needs to be done for each pulse profile in a HPPC test. To save effort, copy the results of each profile into a separate Excel file (be sure to use Copy/Paste Special/Values). Then for a new pulse, paste in Time, I load, A-s, and Voltage into the old setup; LINEST should recalculate on its own. n Once all the resistance values are in their own file, plot them with respect to SOC. From this, polynomials can be created that can be plugged into PNGV models.