An Analytic Method for Estimation of Electric Vehicle Range Requirements, Electrification Potential and Prospective Market Size* Mike Tamor Chris Gearhart Ford Motor Company *Population Statisticians and Behavioral Economists, please hold all criticism until the speaker has left the venue.
The Core Issue The Electric Vehicle Paradigm is inverted relative to a chemically fueled vehicle: the fuel can be very cheap while the fuel tank is extremely expensive. Traditional means of determining requisite attributes, most importantly range, customer willingness-to-pay and ultimate market acceptance may not apply. Because of the extreme cost sensitivity to range, and variability of use, estimates based on the ensemble behavior of large populations may be misleading.
America s Favorite Ensemble: the National Household Travel Survey (NHTS) Data Collected (from ~2, household interviews) The NHTS/NPTS serves as the nation s inventory of daily travel. Data is collected on daily trips taken in a (single) 24-hour period 4 am 3:59 am), and includes: purpose of the trip (work, shopping, etc.); means of transportation used (car, bus, subway, walk, etc.); how long the trip took, i.e., travel time; time of day when the trip took place; day of week when the trip took place; and if a private vehicle trip: - number of people in the vehicle, i.e., vehicle occupancy; driver characteristics (age, sex, worker status, education level, etc.); - vehicle attributes (make, model, model year, amount of miles driven in a year).
(Mis)Interpretation of Ensemble Data: Cumulative Daily Distance Distribution Cumulative VMT/sum(VMT)* DAYPUB.csv, VMT = # trips * (miles/day), All Daily Trips,.5 < miles < 2 9 8 7 6 5 4 3 2 2 4 6 8 2 4 6 8 2 22 24 26 28 3 miles/day miles electric range can electrify 69% of all driving miles electric range can electrify 93% of all trips km autonomy range satisfies more than 8% of daily use globally http://www.udel.edu/udaily/2/may/electricvehicles-57.html These statements hold for the ensemble if every respondent had the same EV whether or not it benefited him/her. These statements hold for an individual if he/she had the EV and drove a distribution of trip lengths matching the ensemble. Neither condition is met in the real world.
The Parts are Much More Complex than the Whole: we must treat people as individuals
Individual Trip Chain Frequency Distributions do Not Resemble the Ensemble!.3 # of Occurances 8 6 4 2 NHTS pdf ( Exp + Normal).25.2.5..5 VehID = 23 LL = -83.73 decay = 55.4 µ = 36.82 σ = 9.2 w exp =.4 w normal =.59 d 5 = 36.96 2 4 6 8 2 4 6 8 2 Chain Dist [mile].9.8.7.6.5.4.3.2..45 pdf ( Exp + Normal).3.25.2.5..5 5 5 2 Daily Travel Distance (mi.) VehID = 4 LL = -98.94 decay = 38.89 µ = 2.92 σ = 5.23 w exp =.9 w normal =.9 d 5 = 24.93 2 4 6 8 2 4 6 8 2 Chain Dist [mile].9.8.7.6.5.4.3.2. pdf ( Exp + Normal).45.4.35.3.25.2.5..5 VehID = 22 LL = -796.38 decay = 38.8 µ = 3.8 σ = 7.7 w exp =.57 w normal =.43 d 5 = 29.7 2 4 6 8 2 4 6 8 2 Chain Dist [mile].9.8.7.6.5.4.3.2. pdf ( Exp + Normal).4.35.3.25.2.5..5 VehID = 9 LL = -993.54 decay = 63.84 µ = 22.97 σ = 5.74 w exp =.5 w normal =.49 d 5 = 25.52 2 4 6 8 2 4 6 8 2 Chain Dist [mile] Example: Four of 32 vehicles instrumented for ~year in Minnesota.9.8.7.6.5.4.3.2.
Generic Parameterization of the Individual Trip Chain Frequency Distribution.45 pdf ( Exp + Normal).4.35.3.25.2.5 VehID = 9 LL = -993.54 decay = 63.84 µ = 22.97 σ = 5.74 w exp =.5 w normal =.49 d 5 = 25.52.9.8.7.6.5.4.3 Random Background..5.2. p( x) = w k e 2 4 6 8 2 4 6 8 2 Chain Dist [mile] x k + ( w) 2 2πσ e ( x µ ) 2 2σ 2 Habitual Peak 7
How Many Will Accept EV Range Limitations? Fraction 'Satisfied'.8.6.4.2 day/year 3 days/year 8 days/year 24 days/year 5 5 2 25 Battery Range (miles) Acceptance of EVs is expected to be sensitive to customer reactions to the need for alternative transportation. Market studies must capture the needs and alternatives for occasional uses rather than focus on typical usage!
How Much Range is Enough*? *to achieve a given level of electrification Fraction 'Satisfied' with EV.8.6.4.2 5 miles 24 day/year 8 days/year 3 days/year day/year.2.4.6.8 Fraction VMT Electrified The electric range required to achieve a given level of electrification is extremely sensitive to the threshold for EV acceptance.
How Much Range is Too Much? 5% Assumes 8 days/year for alternative transportation is acceptable 8% Assumes 24 days/year for alternative transportation is acceptable Fraction 'Satisfied' with EV 4% 3% 2% % 5 2 mi. $2/mile $25/mile $/kwh $3/mile Fraction 'Satisfied' with EV 7% 6% 5% 4% 3% 2% % 5 25 5 $2/mile $3/mile $4/mile % % % 2% 3% 4% 5% Fracton of Travel Electrified % % % 2% 3% 4% 5% 6% 7% Fracton of Travel Electrified With no economic penalty for choosing a larger battery, customer acceptance of EV, and total electrification is limited only by vehicle range. With finite cost, optimum range is roughly 5-2 miles (~independent of cost) This is near the limits of what is feasible with near-future Li-ion technology. If customers demand cost breakeven AND high functionality, battery cost must be impossibly low (<$/kwh).
What if you could electrify the first N-miles of every trip and keep going? The Plug-In Hybrid Total Electrification Benefit Battery Not Discharged By End of Day: EV Battery Discharged By End of Day Only 2 miles electric range would electrify 5% of travel! % acceptance (no range issues) Faster payback because battery capacity used much more. Total electrification potential of PHEV is vastly greater than that of EV!
What else can we do with this method? By identifying correlations between the four fit parameters, it is possible to generate synthetic driving population data. Estimation of average and distribution of real-world fuel economy reports for comparison to labels. Analytic estimates of EV acceptance and electrification potential to guide marketing and infrastructure priorities. By asking the right questions, we can estimate the fit parameters and generate a trip length distribution for an individual. Better prediction of individual fuel economy. Personal estimate of electrification benefits.
Individual Electrification Benefit Estimation The Four Questions How many miles do you drive annually? Roughly how many days per year do you use your vehicle? Typically 24-3 How many days per week do you commute? Multiply by.8 to reflect vacation, holidays, etc. What is the round-trip distance of your commute?
Vehicle & Driver Data Input How do you drive? On average, the number of days per week you commute Round drip distance of your commute Average Annual Commuting Distance Annual Miles Driven On average how many days a year do you drive your car? 5 days 2 miles 52 Miles 2 Miles 3 days What kind of PHEV do you want? Fraction of City driving electrified Fraction from to Fraction of highway driving electrified Fraction from to Miles per gallon city - sustaining 5.2 Miles per gal Miles per gallon highway - sustaining 36.6 Miles per gal Average Electrical Consumption per mile city - full electric.26 kwh per mile Average Electrical Consumption per mile high way- full electric.36 kwh per mile Usable Battery Capacity 7 kwh
PHEV Benefit Estimator Output Calculated model parameters w.566667 lamda.8298 mu 2 sigma 4 k 55.2942 g_hf_s g_hf_d g_he_d g_cf_s g_cf_d g_ce_d kwh/mile kwh/mile.35743 kwh/mile.74286 kwh/mile kwh/mile.2552 kwh/mile phi_s.7 x_s= 6 miles.984 R_d 24.6295 Depletion R y_r.53237 Trip Frequency.6.5.4.3.2. 5 5 2 Trip Chain Length Random Habitual Sum Percent Fuel Saved Annual Savings. Fuel Consumption standard HEV 284.688 Gallons Fuel Consumption PHEV 56.389 Fuel Savings 27.7796 Gallons Percent Fuel Saved 44.97% Note this is a crude prototype. Final version can have vehicle data base including non-hev, including depletion strategy assumptions (Volt vs. Energi). pdf ( Exp + Normal).45.4.35.3.25.2.5..5 VehID = 9 LL = -993.54 decay = 63.84 µ = 22.97 σ = 5.74 w exp =.5 w normal =.49 d 5 = 25.52 2 4 6 8 2 4 6 8 2 Chain Dist [mile].9.8.7.6.5.4.3.2. % 9% 8% 7% 6% 5% 4% 3% 2% % % Percent Fuel Saved
Summary (too soon for Conclusions ) Estimates based on aggregate information are poor predictors of individual electrification needs and benefits. Statistical characterization of individual usage data can be used to generate realistic synthetic populations. Methodology can be used to improve estimates of individual benefit, EV market penetration and ultimate electrification potential. Market studies must capture occasional use and individual transportation alternatives. Work in progress examines similar data from multiple regions to determine generality and scalability of the driver population model. We need a lot more data!