function I = AeBV. Determine those values, then write it down. The actual values are A = 0.50 and B = 0.95. Compute the percent error with your result. 3. With our values of A and B on hand, have the equation printed on the plot along with a graph of the line of best fit that models the data. Most LED bulbs run at about 20 mA, and assuming the values on the vertical axis is in terms of mA, determine the voltage eeded to have this LED produce white light. 4. We can then determine the effective resistance of the LED bulb at any given voltage through the derivative with respect to I, dV R dI

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function I = AeBV. Determine those values, then write it down. The actual values are A = 0.50 and B = 0.95. Compute the percent error with your result. 3. With our values of A and B on hand, have the equation printed on the plot along with a graph of the line of best fit that models the data. Most LED bulbs run at about 20 mA, and assuming the values on the vertical axis is in terms of mA, determine the voltage needed to have this LED produce white light. 4. We can then determine the effective resistance of the LED bulb at any given voltage through the derivative with respect to I, dV R || dI Determine the resistance of the LED bulb given a voltage of 4.50 V.

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| = 0.509 * e0.946* v