Technological Advances

Feature This is the first of two Special Reports on Electric Vehicles. In this report, we will look at the current costs of ownership of a typical mass-market EV, including and excluding subsidies, versus a similar Internal Combustion Engine Vehicle (ICEV). Based on current manufacturing costs and battery capabilities, EVs carry a significantly higher total cost per mile, even including current subsidies. Electric Vehicles have galvanized the interest of consumers, investors, and governments for several years now. We touched on the subject in our Special Report "Electric Vehicle Batteries", published September 20, 2016, where we noted that there were many misconceptions regarding batteries in general and EV batteries in particular. Despite the current cost and utility disadvantages of EVs, we expect governments (especially Europe and China) will continue to provide subsidies (carrots) and mandates (sticks) to further the adoption of EVs for the purposes of reducing CO2 emissions and tailpipe particulate pollution. The longer-term hope is that by forcing the EV market to expand, meaningful technological breakthroughs on batteries will eventually enable EVs to exceed ICEVs on a cost and utility basis. In our second report, we will look at the potential issues associated with adoption of EVs and the investment implications for the auto industry and energy markets. Cost Comparison: EV Vs. ICEV We estimated the difference in cost of ownership of a Chevy Bolt EV (known as the Opel Ampera-e in Europe) and two equivalent Internal Combustion Engine Vehicles (ICEVs), the Chevy Sonic and the Opel Astra, over 160,000 km or 100,000 miles (Table 1). Depreciation is an important consideration in cost of ownership, and we expect EVs to depreciate much more rapidly than ICEVs, a cost that many consumers either ignore or simply fail to incorporate into their purchase decisions. Table 1Comparison Of Costs Of Ownership Between EV And ICEV Automobiles Electric Vehicles Part 1: Costs Of Ownership Electric Vehicles Part 1: Costs Of Ownership There are many unknowns, such as actual selling price, actual manufacturing cost, etc., in this exercise which may add or subtract a thousand dollars or more to the net results. Under realistic assumptions, those probably cancel out. In summary, EVs are more expensive than ICEVs: Excluding subsidies, the net difference is about $16,100 in the U.S., $18,500 in Germany, and $13,200 in France. After subsidies, the difference is about $6,600 in New York State, $13,900 in Germany, and $6,000 in France. Even if electricity were free, after subsidies, the difference in cost of ownership in the U.S. (NY) would be $3,400, $3,200 in Germany, and $600 in France. The U.S. Federal subsidy of $7,500 is designed to be phased out once a manufacturer sells 200,000 vehicles, which would happen quickly if EVs are to become main stream. Therefore, the total premium cost of ownership of an EV over a comparable ICEV in the U.S. should be assumed to be $16,100 less state subsidy, if any. European subsidies are probably more politically acceptable, even though they will become quite costly if EV sales accelerate as many predict. GM is believed to be losing $9,000 with every Bolt it sells. If so, and if GM changed its pricing to deliver the company's average Gross Margin of around 13%, assuming it currently allows a 10% markup by dealers and discounts the vehicle by 10%, the price of the car would need to be raised to around $48,300 from its current MSRP of $37,500. This would increase the cost of ownership by nearly $11,000 (Table 2), or $0.11 per mile. To make the Bolt's ownership costs - after subsidies - competitive with GM's Opel Astra in France, the Bolt's manufacturing costs would need to be cut by about $14,750 or 34%. Table 2Comparison Of Costs Of Ownership Between EV And ICEV Automobiles, ##br##If GM Sold Bolt At Average Corporate Profitability Electric Vehicles Part 1: Costs Of Ownership Electric Vehicles Part 1: Costs Of Ownership Note that although we have focused on the Bolt, the common denominator for all EVs is the cost of batteries, which are a commodity. As such, our estimates probably hold for similarly sized vehicles and the differential costs of ownership are likely larger for larger EVs. As we will show in Part 2, integrated auto manufacturers probably have a significant cost advantage over "pure play" EV vendors such as Tesla, because outside of the drive train, they are able to use many of the same components they manufacture for ICEVs. Batteries: A Review All assumptions regarding EV technology are predicated on continued improvements in the cost, durability, and performance of batteries. The leading battery technology for EVs is a Lithium Ion technology (Illustration 1), and there really are no proven near-term alternatives worth discussing. Illustration 1Lithium Ion Technology Electric Vehicles Part 1: Costs Of Ownership Electric Vehicles Part 1: Costs Of Ownership In our Special Report "Electric Vehicle Batteries", we concluded that: Although the consensus view is that EV battery prices have experienced rapid (8 - 14% per annum) price declines over the past few years, we found no evidence to support that position; Battery durability is at least as important as price, and batteries will not likely last much more than 100,000 miles (160,000 km); Planned expansion of EV battery manufacturing capacity may significantly exceed demand by 2020, resulting in the collapse of EV battery prices and heavy losses for battery manufacturers. We continue to stand by those conclusions, and would like to stress that recent stories such as "China Is About to Bury Elon Musk in Batteries"1 and "10 Battery Gigafactories Are Now in the Works and Elon Musk May Add 4 More"2 are more or less consistent with our comment that "even though there is no reason to expect significant price improvements due to technological shifts, battery prices might drop due to oversupply - at least as long as manufacturers are willing to sell batteries at a loss."3 It seems likely now that China may follow the path it took to the solar industry and mass produce batteries, likely at a loss. The exact motivation for them to do so is uncertain, but this would be moot from the perspective of a western auto manufacturer or consumer. Finally A Reliable Battery Price Data Point! As we will demonstrate in Part 2 of our EV report, excluding the cost of the battery, it should be slightly cheaper to manufacture an EV than a similar ICEV. The EV drive train is much simpler and should be less expensive than that of an ICEV (Illustration 2), offset slightly by the need for a somewhat more robust chassis and suspension due to the weight of the battery, the requirement for electric powered air conditioning, and regenerative braking. Illustration 2Key Components Of A Bolt EV Drive Unit Electric Vehicles Part 1: Costs Of Ownership Electric Vehicles Part 1: Costs Of Ownership The battery is the most expensive part of an EV and responsible for the higher vehicle prices, and that is likely to remain the case even as manufacturing efficiencies allow EV prices to decline. Unfortunately, the cost of EV batteries is subject to much more speculation than should be the case: many articles cite speculative forecasts, projections, anecdotes, and so on, but without hard data backing them up. Fortunately, we finally have a data point: GM lists the cost of the Bolt EV battery pack as $15,734 for a 60 kWh unit, or $262/kWh.4 Some reports claim the battery cells cost $145/kWh,5 however, battery cells are not the same thing as a battery pack, which is a fully assembled unit complete with wiring, electronics, and a cooling system. Peer reviewed research suggests the cost of the battery pack is about 50% greater than the cost of the battery cells,6 however, we note the same article suggests that ratio will remain the same as battery prices drop. This is unlikely as there is no reason to believe the largely mechanical battery pack will decline proportionately any more than the cost of an engine or transmission will decline. Most likely, the battery pack assembly, excluding the cells, will decline only slightly. EV vendors likely oversize their battery pack in order to limit stress on the batteries (Illustration 3). In other words, the actual capacity of the battery is likely somewhat larger than the rated or useable capacity. If GM is indeed paying $145/kWh for its cells and its pack costs are 50% more than its cell costs and it is oversizing its pack by 20%, the cost of the pack works out to $261/kWh. Illustration 3Oversizing Battery To Account For Capacity Fade Electric Vehicles Part 1: Costs Of Ownership Electric Vehicles Part 1: Costs Of Ownership The reports which cite a $145/kWh cell price further suggest GM believes cells will cost $100/kWh in 2022, which implies a potential battery cost reduction of $2,700 (assuming the packs are not oversized) over the next 5 years (Table 3). The aforementioned research paper states: "The pure material costs for the VDA-type batteries are estimated to be currently about 50 EUR/kWh ($67.50), which seems to be the lower possible limit at long term." Even if the difference between materials cost and selling price is only 20%, that implies a lower limit of $81/kWh for the cells, meaning savings of $64/kWh are possible. This has not prevented some commentators from suggesting batteries will decline in price by 77% (or $112, implying $33/kWh pricing) by 2030.7 Regardless, savings of $64/kWh work out to $3,840 assuming a 60 kWh pack, or $4,680 assuming the pack is 20% oversized. Even if the pack cost were to decline a similar amount, the cost savings (assuming 50% for the pack, 20% oversized) would only be $7,000. Table 3GM Aims To Cut The Battery Cost By $2,700 By 2022 Electric Vehicles Part 1: Costs Of Ownership Electric Vehicles Part 1: Costs Of Ownership According to press reports, at the onset GM will lose $9,000 for every Bolt it sells.8 Since the major difference in costs between an EV and an ICEV is the battery pack, the $262 price cited above is probably not representative of the true cost. It may be that part of GM's commercial strategy is to show EV buyers that a replacement battery pack is not overwhelmingly expensive, and it is therefore willing to offer them at a loss. After all, the vehicle comes with a 100,000-mile, 8-year warranty on the battery, and we doubt many consumers would spend $15,734 (plus labor) to replace the battery on an 8-year-old EV. Therefore, GM is probably not going to sell that many replacements, so they won't suffer many losses by offering a replacement battery below its cost. The price differential between a Bolt and a Chevy Sonic, which is a similar vehicle manufactured in the same factory, is about $22,300. If we include the reported $9,000 expected loss, the "true" difference in price is $31,300. We believe that most likely the actual cost of the battery pack of the Bolt is much higher than $15,734. GM Confirms That Batteries Get Used Up Although the Bolt battery pack is covered by an 8-year 100,000-mile warranty, that warranty considers the potential for degradation of up to 40%: "Like all batteries, the amount of energy that the high voltage 'propulsion' battery can store will decrease with time and miles driven. Depending on use, the battery may degrade as little as 10% to as much as 40% of capacity over the warranty period."9 We highlight "all batteries" because this is the fate of all existing battery technologies. We further note that the amount of degradation will depend on the driving habits of the user: if the car is "lightly used" (i.e. traveled much less than 12,000 miles/year), chances are the battery degradation will be at the low end of the scale, whereas if the car is used a lot, chances are it will be at the high end of the scale. The average U.S. driver travels ~13,500 miles (22,000 km) per year,10 meaning the average driver with a single car would exceed the warranty on the Bolt in less than 8 years and, most likely, battery degradation would be closer to 40% than to 10%. Assuming a normal distribution, half of drivers would likely exceed the average annual miles driven, and as a result, their battery degradation would be even greater and happen even sooner, since they would be stressing the battery system through deeper and more frequent charging. Of course, if you were to travel 100,000 miles in 5 years, your battery warranty would expire. A major motivation for buying an EV is the expectation that it will save money on gasoline, which is true as shown in Table 1. However, the more you drive, the faster you use up the battery, and the sooner you would be faced with buying an expensive replacement battery. As such, drivers who drive a lot would be best to be cautious about purchasing an EV, as their costs of ownership due to battery degradation/replacement would be even higher. The Bolt has a purported range of 238 miles, but that range is achieved only when the battery is new and likely measured under ideal circumstances. Use of air conditioning, extreme temperatures (i.e. winter), etc., would probably trim the range significantly, likely to well below 200 miles. Assuming a reasonable usage for the vehicle, an 8-year-old Bolt would probably have a range closer to 100 miles than to 200 miles. This would significantly affect resale value as a vehicle with a range of 100 miles has much less utility than one with 200 miles. Difference In Cost Of Ownership: Chevy Bolt Vs. ICEV Calculating costs of ownership is subject to numerous assumptions, and this is especially the case with respect to an emerging technology such as EVs. Because we have a significant amount of information from GM on the cost and operating characteristics of the Bolt, and because GM makes "mass market" ICEVs which are roughly comparable to the Bolt, we thought it would be a uniquely useful benchmark for a cost of ownership analysis. We are neither making a claim that the Bolt or any EV will be commercially successful, nor are we endorsing it in any way; we are simply identifying the Bolt as representative of a typical mass-market EV. In our analysis we assume: The Chevy Bolt is a typical mass market EV; The sales price of the Bolt is roughly the same in the U.S.11 and Europe12 at $37,495; The Bolt is comparable to the Sonic in North America and the Opel Astra in Europe (Table 4); There are no direct financial subsidies associated with EVs; and After 100,000 miles, both the EV and the comparable ICEV have a similar residual value. Table 4The Bolt Is Much More Expensive Than Similarly-Sized GM ICEVs Electric Vehicles Part 1: Costs Of Ownership Electric Vehicles Part 1: Costs Of Ownership As we noted above, GM is believed to be taking a $9,000 loss associated with each Bolt sold. This is not sustainable if the firm expects to sell a lot of them. Most likely, either the company sees a path to significant cost reduction over the life of the product, or the company will artificially limit supply and use profits from its other products to subsidize the sales of Bolts. For the purpose of this analysis, we will assume the company and its rivals believe they can sell such vehicles at a reasonable profit in the future. The difference in the cost of ownership for similar vehicles is mainly associated with purchase cost, fuel costs, repair costs, and resale value. Insurance, parking, and so on would be a wash and annual repair and maintenance bills on most new cars are quite modest, so it would not significantly tilt the balance. Although EV enthusiasts tend to highlight the fact EVs do not require oil changes, the significantly increased weight of the battery means EVs require more frequent tire replacement than an equivalent ICEV.13 For example, modern ICEVs require an oil change every 10,000 miles. At $70/oil change this works out to $700, similar in price to a set of tires. Furthermore, the repair experience with EVs is extremely limited, and if we are to take Tesla as an example, they do not fare as well as many had hoped.14 We address the likely higher depreciation rates of EVs below. Estimating Electric Power Costs For An EV Charging a battery is not 100% efficient as losses occur in the charger and at the battery. Batteries get warm as they are charged, and that is a sign of inefficiencies in the charging process. As smartphone and notebook owners are aware, aged batteries produce a lot more heat when they are charged because the charging becomes less efficient as the batteries age. A new EV with a "slow" charger (see below) is about 85% efficient,15,16 while the figure is almost certainly lower for an aged battery. Assuming the system were 100% efficient, the Bolt vehicle goes 238 miles on 60 kWh, averaging about 0.25 kWh/mile, or approximately 25,000 kWh for 100,000 miles. Assuming lifetime average efficiency of 80% (85% when new, 75% when old), lifetime power consumption would be about 31,250 kWh. EV advocates note there are numerous "free" public charging stations. This is true, but there are far fewer public charging stations than there are EVs, which means the average EV owner pays for her electricity (Chart 1). Regardless, somebody has to pay for the electricity, and it is unreasonable to assume that "free charging" will persist if EVs gain significant market share, which apparently they have been doing in the past few years, especially in the U.S. and the EU (Chart 2). Chart 1Globally, EVs Outnumber Charging Stations By 6 To 1 Globally, EVs Outnumber Charging Stations By 6 To 1 Globally, EVs Outnumber Charging Stations By 6 To 1 Chart 2EV Market Share Is Increasing, Especially In Europe EV Market Share Is Increasing, Especially In Europe EV Market Share Is Increasing, Especially In Europe Furthermore, although many utilities have "time of use" utility rates which are lower in the evening when an EV is being charged, there is reason to question whether those can coexist with significant EV market penetration, a subject we will address in Part 2. Regardless, average power rates incorporate discounted time of use power to some extent, so that is the figure we use. Net Operating Costs: U.S. The Bolt17 is roughly comparable to a Chevy Sonic18 in terms of size, and the vehicles are made in the same factory. The difference in price is about $22,300. At 25/33 mpg, fuel use of the Sonic over 100,000 miles would be about 3,600 gallons (13,627 liters), costing about $9,000, assuming a gasoline price of $2.50 per gallon ($0.66/liter), which is slightly higher than the current nationwide average of ~$2.30/gallon. Assuming lifetime power consumption of 31,250 kWh and an average electricity price in the U.S. of $0.104/kWh,19 electric power costs for the Bolt would be around $3,250, for a net "fuel costs savings" of $5,700 in favor of the Bolt. However, the substantially higher initial purchase price and faster depreciation still results in the Sonic costing about $16,100 less over the duration of the vehicles' 100,000 miles (160,000 km). Put another way, the Bolt's total operating costs would average about $0.38 per mile, 73% higher than the $0.22/mile cost of the Sonic. Net Operating Costs: Europe In Europe, both fuel and electricity costs are typically much higher than in the U.S., but ICEVs also tend to be more fuel efficient. The Bolt is roughly equivalent to an Opel Astra, which costs €16,700 ($19,160) in France and consumes 4.4 litres/100 km20 (53 MPG). The difference in price between the Bolt and the Astra is about $18,300, a smaller premium than in the U.S. comparison. However, even though gasoline prices are more than twice as expensive in Europe than in the U.S., fuel costs for the Astra are moderated by the car's higher fuel efficiency, approximating $10,500 for the first 100,000 miles. Energy costs and EV subsidies vary widely across the EU. Because the economic impact of EVs would be roughly proportional to GDP, we decided to look at the largest EU economies excluding the UK. It happens that EV sales in Italy are negligible, with total market share less than 0.1%,21 and EV subsidies in the country are somewhat opaque. Therefore, we confined our analysis to Germany and France. Assuming lifetime power consumption of 31,250 kWh, the electric power costs of the Bolt would be around $5,350 in France, which has low power prices, for net energy savings of $5,100. In Germany, where power prices of $0.34/kWh are considerably higher, the Bolt and the Astra would have energy costs that are roughly equal. In France, EVs' ownership costs would be $13,200 (49%) higher than the ICEV; in Germany, EV ownership costs would be $18,500 (68%) higher. Bolt Vs Sonic Cost Of Ownership: Impact Of Subsidies In the U.S., there is a federal subsidy of $7,500 and some states also have an EV incentive. In New York State, the subsidy is $2,000, meaning the net increased cost of owning the Bolt instead of a Sonic drops to around $6,600. Note that the federal subsidy is designed to "phase out" once a manufacturer sells 200,000 vehicles. GM hopes to sell 30,000 EVs in 2017 despite only launching U.S.-wide in summer 2017. Combined with prior Volt sales of over 150,000 units, GM should exhaust its federal subsidies in early 2018. Subsidies vary considerably across the EU.22 In France, there is a subsidy of €6,300 ($7,200)23 associated with the purchase of an EV, while Germany24 has a €4,000 ($4,600) incentive. Besides subsidies, there are other benefits of owning an EV including reserved or even free parking spaces, often including free charging. These are offset to some extent by the limited range of EVs which may disqualify them from purchase by some. It remains to be seen how long EV subsidies will persist. They may be affordable to governments as long as the number of vehicles sold remains small, but they would become very costly if EV sales accelerate. For example, about 2 million new passenger cars are registered in France every year. If only half of those were EVs, subsides would total $7.2B. Money for roads, infrastructure maintenance, policing, and so on have to come from somewhere, and if ICEV sales decline substantially, European governments' huge gasoline tax revenues would also deteriorate; in such an environment, it is reasonable to assume that EV subsidies would eventually disappear and be replaced by taxes. It seems highly unlikely to us that a massive subsidy program would be a politically acceptable solution in the U.S. auto market; however, it may very well be that over the near term subsidies persist in the EU where concerns over climate change have greater political weight. Cost Of Ownership: Depreciation Depreciation of the EV is almost certainly going to be much higher than the ICEV, which accounts for some of the higher cost of ownership. We believe that most EV batteries will be substantially degraded after 160,000 km (100,000 miles), and we doubt there will be many EVs on the road past about 200,000 km or 15 years of operation. In contrast, the average age of a vehicle in the EU is over 10.5 years,25 while the average age of a vehicle in the U.S. is 11.6 years.26 The overwhelming majority of EVs on the road today are still under warranty and, in either event, relatively new, which means consumers lack the information to understand the inherent issues of battery degradation. As more consumers have experience with EVs, the problems of degradation and replacement cost (i.e. the high cost of depreciation) will likely temper demand. This would be the case even if battery costs drop significantly: few consumers would invest even $5,000 into repairing a 10-year-old vehicle, and an EV with a 100 mile (160 km) range is significantly less useful than one with a 200 mile (320 km) range. Rapid depreciation has been the experience of Nissan Leaf owners who are discovering their vehicles have lost 80% of their value after only 3 years.27 EV advocates suggest that degradation is not an issue and that, in any event, batteries are getting better and better. This flies in the face of what essentially every consumer has experienced with mobile phones, notebook computers, or any other cordless device. We believe GM has better insights into the issue than EV advocates do and, in any event, we see no evidence for significant improvements in battery life. If, indeed, significant improvements are made to batteries, prior-generation EVs (including today's Bolt) will plummet in value. That said, consumer understanding of battery degradation is not likely to be a factor for EV adoption over the near term. Conclusion: Costs Of Ownership Assuming similar depreciation and excluding subsidies, the net difference in cost of ownership over 160,000 km (100,000 miles) between a Bolt and an equivalent ICEV is about $16,100 in the U.S., $13,200 in France, and $18,500 in Germany, in favor of the ICEV. After subsidies, an optimistic analysis suggests the difference in cost of ownership to travel 100,000 miles (160,000 km) between a Bolt EV and a roughly similar ICEV is about $6,600 in the U.S. (New York), $6,000 in France, and $13,900 in Germany, in favor of the ICEV. Electric power costs for the Bolt are around $3,250 in the U.S., $10,600 in Germany, and around $5,350 in France. Even if electricity were free, after subsidies, the difference in cost of ownership would be $3,400 in the U.S. (NY), $3,200 in Germany, and $600 in France. GM is believed to be losing $9,000 with every Bolt it sells. If so, and it wanted to sell the vehicle at its average Gross Margin of around 13%, it would sell for closer to $48,300, which would increase cost of ownership by about $11,000. In other words it would take a cost reduction of around $14,750 (about 34%) of likely manufacturing cost before the cost of ownership would favor the Bolt in France after subsidies. As noted above in our discussion of battery costs, GM expects a $2,700 cost saving associated with battery cells by 2022. Given that it is losing money on the vehicle, it is hard to believe they will immediately pass these savings on to the consumer. Even if they did, cost of ownership would still favor the ICEVs. Brian Piccioni, Vice President Technology Sector Strategy brianp@bcaresearch.com Matt Conlan, Senior Vice President Energy Sector Strategy mattconlan@bcaresearchny.com Robert P. Ryan, Senior Vice President Commodity & Energy Strategy rryan@bcaresearch.com Johanna El-Hayek, Research Assistant johannah@bcaresearch.com 1 https://www.bloomberg.com/news/articles/2017-06-28/china-is-about-to-bury-elon-musk-in-batteries 2 https://www.greentechmedia.com/articles/read/10-battery-gigafactories-are-now-in-progress-and-musk-may-add-4-more 3 Please see Technology Sector Strategy Special Report "Electric Vehicle Batteries", dated September 20, 2016. 4 http://insideevs.com/heres-how-much-a-chevrolet-bolt-replacement-battery-costs/ 5 http://insideevs.com/gm-chevrolet-bolt-for-2016-145kwh-cell-cost-volt-margin-improves-3500/ 6 https://www.researchgate.net/publication/260339436_An_Overview_of_Costs_for_Vehicle_Components_Fuels_and_Greenhouse_Gas_Emissions 7 https://www.bloomberg.com/news/articles/2017-05-26/electric-cars-seen-cheaper-than-gasoline-models-within-a-decade 8 https://www.bloomberg.com/news/articles/2016-11-30/gm-s-ready-to-lose-9-000-a-pop-and-chase-the-electric-car-boom 9 https://electrek.co/2016/12/07/gm-chevy-bolt-ev-battery-degradation-up-to-40-warranty/ 10 http://www.carinsurance.com/Articles/average-miles-driven-per-year-by-state.aspx 11 http://www.chevrolet.com/byo-vc/client/en/US/chevrolet/bolt-ev/2017/bolt-ev/features/trims/?section=Highlights§ion=Fuel%20Efficiency§ion=Dimensions&styleOne=388584 12 https://electrek.co/2016/12/15/chevy-bolt-ev-europe-june-2017-opel-ampera-e-gm/ 13 The Bolt weighs almost 800 pounds (360 kg) more than a similar sized Chevrolet Sonic. 14 http://www.consumerreports.org/cars-tesla-reliability-doesnt-match-its-high-performance/ 15 https://www.veic.org/docs/Transportation/20130320-EVT-NRA-Final-Report.pdf 16 http://teslaliving.net/2014/07/07/measuring-ev-charging-efficiency/ 17 http://www.chevrolet.com/bolt-ev-electric-vehicle 18 http://www.chevrolet.com/sonic-small-car 19 https://www.eia.gov/electricity/state/ 20 http://www.opel.fr/vehicules/gamme-astra/astra-5-portes/points-forts.html#trim-edition 21 http://www.eafo.eu/content/italy 22 https://www.iea.org/publications/freepublications/publication/GlobalEVOutlook2017.pdf pages 53-55 23 http://insideevs.com/overview-incentives-buying-electric-vehicles-eu/ 24 https://electrek.co/2016/04/27/germany-electric-vehicle-incentive-4000/ 25 http://www.acea.be/statistics/tag/category/average-vehicle-age 26 http://www.autonews.com/article/20161122/RETAIL05/161129973/average-age-of-vehicles-on-road-hits-11.6-years 27 http://blog.caranddriver.com/tesla-aside-resale-values-for-electric-cars-are-still-tanking/ Investment Views and Themes Recommendations Strategic Recommendations Tactical Trades Electric Vehicles Part 1: Costs Of Ownership Electric Vehicles Part 1: Costs Of Ownership Commodity Prices and Plays Reference Table Electric Vehicles Part 1: Costs Of Ownership Electric Vehicles Part 1: Costs Of Ownership Trades Closed in 2017 Summary of Trades Closed in 2016

Dear Client, Over the next three weeks, much of BCA’s Geopolitical Strategy team will be traveling in Australia, New Zealand, and Asia. As such, we are taking this week off from publication and will return to our regular schedule next week. In lieu of our regular missive, we are sending you the following Special Report, penned by our colleagues in the BCA Technology Sector Strategy. The report, originally published on May 16, tackles “The Coming Robotics Revolution” in an innovative way that aligns with our own views. Clients often ask us what will be the political consequences of the revolution in artificial intelligence and robotics. Our answers are controversial because we strongly disagree with the conventional, Terminator-inspired, doom and gloom. Brian Piccioni and Paul Kantorovich agree with us, which is reassuring given that they understand the technology behind robotics far better than we do. I hope you enjoy the enclosed report and encourage you to seek out the insights of our Technology Sector Strategy. Kindest Regards, Marko Papic, Senior Vice President Chief Geopolitical Strategist Feature "The amount of technology coming at us in the next five years is probably more than we've seen in the last 50" Mark Franks, Director Of Global Automation at General Motors, Bloomberg News, April 2017 There is good reason to believe we are at the cusp of a Robot Revolution which will have a dramatic impact on our economy. Robots have been around for decades or centuries, depending on the definition. Past robots were either fixed in place, as in the case of factory robots, or supervised by operators that are near the robot, or connected through telemetry. In contrast, the robots that are coming will not be fixed in place, and will be able to perform their functions without a human operator. This opens up massive markets for robots in industry (cutting lawns, cleaning windows, delivering parcels, etc.) and, most significantly, consumer applications. Part 1: Robots - Industrial Revolution To Early 21st Century The term "robot" can have different meanings. The most basic definition is "a device that automatically performs complicated and often repetitive tasks,"1 a definition which encompasses a broad range of machines: from the Jacquard Loom,2 which was invented over 200 years ago, on to Numerically Controlled (NC) mills and lathes, pick and place machines used in the manufacture of electronics, Autonomous Vehicles (AVs), and even homicidal robots from the future such as the Terminator. For much of history, most of the labor force was involved with the production of food: over 50% of the U.S. labor force was involved in agriculture until the late 1800s (Chart 1). Agriculture has benefitted immensely from automation as inventions such as the McCormick Reaper (a wheat cutting machine pulled by horses), the cotton gin, and other mechanical systems displaced human effort. Steam and then internal combustion-powered tractors, which can be viewed as "robotic horses," accelerated the process, as engines delivered much more power more cost effectively than mechanical devices (Chart 2). This massively improved productivity: within 20 years from 1830 to 1850, the labor to produce 100 bushels of wheat dropped from 250-300 to 75-90 hours, and by 1955 it only took 6 ½ hours of labor for a net reduction of 97.5% in 125 years.3 Chart 1Farm Workers Were Disrupted In The Late 19th Century The Coming Robotics Revolution The Coming Robotics Revolution Chart 2...And So Were Horses The Coming Robotics Revolution The Coming Robotics Revolution In other words there is nothing new about automation displacing workers while improving productivity, nor is a rapid displacement unprecedented. The industrial revolution was about replacing human craft labor with capital (i.e. machines), which did high-volume work with better quality and productivity. This freed humans for work which had not yet been automated, along with designing, producing, and maintaining the machinery. Automation Frightens People Although automation is nothing new, it has always engendered anxiety among workers. The anxiety boils down to concern for continued employment as well as fear of the technology itself. We discuss below why Artificial Intelligence (AI) does not present the sort of threat to humanity or even employment that seems to be the consensus view at the moment. Will Robots Become Self-Aware? We have covered the topic of Artificial Intelligence/Deep Learning as it relates to sentient/self-aware machines in some detail in our October 18, 2016 Special Report on Artificial Intelligence. In summary, most of the discussion surrounding AI is misinformation. Although AI uses algorithms called "artificial neural networks," which are extremely useful for solving certain classes of problems, these are nothing like biological neural networks. There is no reason whatsoever to believe AI technology in its current form can become sentient, or even meaningfully intelligent, and that will not change with increased computing power. Furthermore, whether or not AI can arise to the level of a threat, there is no current or imagined power source which could keep a rampaging robot active for more than a few hours. The Terminator would have been much less threatening if he required frequent recharging. Will Robots Make Human Workers Irrelevant? Automation in agriculture occurred rapidly enough to be felt by workers at the time - and yet there were no marauding hordes of unemployed hay cutters or cowboys. Improved productivity meant markets were opened which did not previously exist, and unemployed agricultural workers moved to factory work. Media coverage of automation tends to focus on the potential job losses without mentioning the fact that the economy and its workers adapt, and overall living standards generally improve (Chart 3). Technology has displaced entire classes of jobs very rapidly in the recent past, and many products such as smartphones would be extremely difficult to assemble if the work was done by hand. Box 1 provides several other examples. Yet as is usual for many things that have happened multiple times in the past, we are told "this time is different." Chart 3The Industrial Revolution Led To A Vast Improvement In Living Standards The Industrial Revolution Led To A Vast Improvement In Living Standards The Industrial Revolution Led To A Vast Improvement In Living Standards Box 1 Automation Displaced Entire Classes Of Jobs In The Recent Past, But Brought Enormous Benefits Before calculators and word processors were available, writing and mathematical calculations were done manually. Machines such as calculators and type writers enhanced productivity, eliminating many such jobs. Software applications such as Microsoft Word and Excel further accelerated this process. Not that long ago, welding was entirely a manual job but now most welding in factories is done by robots: you can usually tell a human weld on a mass produced product by its poor quality. Robots in the modern factory have freed up workers for other roles in the economy just as the massive loss of agricultural jobs in the 20th century did. Many modern electronic products such as smartphones would be extremely difficult to assemble if the work was done by hand, as the components are so small they require microscopes to manipulate. Even if it were possible to hand assemble a smartphone, it would take hours of manual labor to produce, and the quality would be very poor. The use of automation means that smartphones cost a few hundred dollars instead of a few thousand dollars and are affordable enough to be a mass market item. Some of the anxiety around automation-related job losses centers on the possibility that this time, robots will displace workers from the service and white-collar sectors. BCA's European Investment Strategy service has written about the potential for AI to replace jobs involving tasks that require specialized education and training, such as calculating credit scores or insurance premiums, or managing stock portfolios.4 Recent developments in AI (specifically deep learning algorithms) have allowed computers to solve pattern recognition problems that they could not previously solve. However, we do not believe AI in its current form poses a widespread risk to white collar employment for the following reasons: Both service-sector and white collar employees have been subject to replacement through automation already, and the economy has adapted: ATMs are robot bank tellers, self-checkout lanes are robot checkout kiosks, and "smart" gas and electric meters that can be read remotely replace human meter readers. The legal profession has been transformed by Google searches and the accounting business by accounting software. These tools allow certain clients to avoid the use of a lawyer or accountant altogether (for example in setting up a corporation or doing bookkeeping), or allow a firm to employ less skilled workers for the task. We can offer numerous other examples of white collar jobs which have been fully or partially automated over the past couple decades. In addition, recall that AI produces high probability answers which turn out to be wrong, and it requires a lot of subject specific training. Both of these are intrinsic to the implementation of the algorithm. In contrast, humans generally are much better at assigning confidence to decisions and train very rapidly because they have cross-expertise AI lacks. An implementation of AI has to meet BOTH of the following conditions to be successful: There has to be a lot of subject-specific data available A high probability assigned to a wrong answer is either inconsequential or can be easily overruled by a human It is also important to note that although AI may reduce the demand for accountants, insurance agents, credit analysts and other skilled professionals, these are exactly the sort of people that can handle retraining. Part 2: What Makes Upcoming Robots Revolutionary Upcoming robots will be different because they will not be confined to the factory floor. We believe this is a key transition point, and that the next 20 years or so will see as dramatic a change from robotics as was caused by the Internet. Factory robots have improved immensely due to cheaper and more capable control and vision systems. Early robots performed very specific operations under carefully controlled conditions -an assembly robot which encountered a misaligned component would simply install it that way, resulting in a defective product. Eventually vision systems were developed which allowed robots to adjust to varying conditions. As camera and computing costs continue to decline, vision systems are becoming more elaborate and useful, as they gather and process more information to make increasingly complex decisions. As these systems evolve, the abilities of robots to move around their environment while avoiding obstacles will improve, as will their ability to perform increasingly complex tasks. Mobile robots will likely rely on AI to make many decisions. In order to be cost effective, for many years AI will likely be hosted in cloud data centers. This is especially the case for consumer robots, which will have to be highly capable and yet cost effective. We discuss the implications for cloud services providers in more detail in Part 3: Investment Implications. We May Be Entering A 'Virtuous Cycle' In Robotics Improvements to one domain of robotic applications can be generally applied to others. Robotics technology is concurrently moving forward on many fronts ranging from the aforementioned vacuum cleaners, lawnmowers, and logistics robots, to medical orderlies,5 farm tractors,6 mining equipment,7 transport trucks,8 and cargo ships.9 Despite enormous differences in cost and value added, all of these applications are solving essentially the same problem. As with any other technological revolution, advances between different fields in robotics will be adapted, borrowed, extended and enhanced. This, in turn, creates opportunities for ever more applications, creating a virtuous cycle (Diagram 1). Diagram 1Robotics Will Enter Into A Virtuous Cycle The Coming Robotics Revolution The Coming Robotics Revolution There are few tasks which cannot be automated, but there is a definite cost-benefit tradeoff for each one. For example, a golf course may consider spending $25,000 for a robotic lawnmower, however costs were closer to $70 - $90,000 in 2015,10 and installed cost is even higher.11 Because the incremental cost of the machines is comprised of electronics, which will drop in price rapidly, it is probably a matter of another 2 or 3 years before the price moves to the point where mass adoption by groundskeepers begins. The same improvements to industrial lawnmowers will lead to more useable, albeit still pricy, consumer models which will probably enter mass market adoption 5 to 10 years from now. The same argument can be made for almost any manual chore ranging from cleaning the carpet to delivering parcels. We predict the virtuous cycle for robots will span several decades. As the cost of automation drops, better solutions will be developed, resulting in 'early retirement' of dated but otherwise fully functional robotic systems. This is the opposite of the Feature Saturation phenomenon currently present in the smartphone and PC industries - though feature saturation will eventually hit robots as well. A Self-Driving Car Is A Robot The most important robotics technology, from a macroeconomic perspective, is the rapidly advancing field of Autonomous Vehicles (AVs). The automobile industry is a significant part of the global economy, so changes in this industry will have profound implications. We covered AVs in detail in our April 8, 2016 Special Report. Due to technical and legal obstacles that must be overcome, a vehicle which can safely travel from point to point on major roads and city streets without driver intervention is probably 20 years away, +/- 5 years. The macro impact, however, will occur much sooner than that, due to the technologies developed on the way to full AVs. Vehicles are already offering features such as forward collision warning, autobrake, lane departure warning, lane departure prevention, adaptive headlights, and blind spot detection.12 Although we have only touched the surface, robotics are being applied across many industries, making even seemingly modest advances significant when measured in aggregate, as small changes in one industry are quickly adapted by other industries. It is noteworthy that this transition will likely occur during a period where demographic shifts, in particular in the most developed economies, signal the potential for labor shortages, or at least increasing cost of labor (Chart 4).13, 14 Robots may be showing up in the nick of time to improve both the economy and quality of life in the developed world. Chart 4Advances In Robotics Will Counter Adverse##br## Demographic Trends Advances In Robotics Will Counter Adverse Demographic Trends Advances In Robotics Will Counter Adverse Demographic Trends Part 3: Investment Implications The semiconductor industry has stagnated as the PC and smartphone markets entered a largely replacement-driven era (Chart 5). Although it may not be evident until the virtuous cycle is fully engaged, robotics represents another up-leg in demand for semiconductors and therefore should result in a significant improvement to industry growth rates. There is little opportunity for startup semiconductor companies nowadays due to the high costs of developing a new chip. Well positioned, established, semiconductor companies will be the primary beneficiaries of the robotics revolution. Large firms that attempt to fit their existing product offering into the industry (e.g. by remaining PC or mobile-phone centric) will fall behind. Winners System on a Chip (SoC) Vendors: Robotics hardware will more likely be implemented as "System on a Chip" (SoC) as this provides the greatest functionality with lowest cost and power consumption. SoCs generally consist of a variety of Intellectual Property (IP) "cores" which may be licensed from third parties. Typically, IP cores consist of a microprocessor and various specialized subsystems, depending on the application. Robotics SoCs are likely to include Digital Signal Processing (DSP) or Image Processing cores to process sensor data. SoC vendors who target or encourage robot development, such as Overweight-rated Texas Instruments, are likely to be favored by early movers in the space.15 We believe it is a matter of time before Graphics Processors (GPUs) currently used in AI/Deep Learning are replaced by processors specifically designed for AI, which will be cheaper and more power efficient.16 This is one of the reasons for our Underweight rating on Nvidia. Semiconductor Foundries, Mixed Signal and Automotive Semiconductor Vendors: This environment will favor the merchant semiconductor foundries which manufacture most SoCs. In addition, firms with "mixed signal" expertise will experience increased demand for motor controls, sensor interfaces, etc. As robotics features are added to automobiles, demand for automotive semiconductors should outpace that in other sectors. A significant degree of commonality in the parts and systems used in advanced automobiles will be used in other mobile robots, so "automotive" semiconductor demand should significantly outpace automobile sales. Sensor Vendors: Robots need a variety of sensors, depending on the application. Unlike factory floor robots which can make do with cameras, mobile robots will require advanced radar, ultrasound, laser scanning and other sensor types in order to provide redundancy and cope with weather and other related issues. Important sensors on prototype AVs are currently made in low volumes and are extremely expensive. Due to the number of sensors involved, we believe there is significant opportunity for companies offering aggressive cost reduction in sensor technology. Wireless Equipment and Service Providers: Most robotic systems will include some degree of wireless connectivity and participate in the "Internet of Things" (IoT). This will present challenges and opportunities for wireless equipment and service providers,17, 18 as networks will have to adapt to increased upload bandwidth (from robot to carrier) as well as novel billing schemes. Coverage will also have to be expanded to accommodate AVs as it is non-existent or spotty in large stretches of North American roadways. Not being able to check Facebook between two cities is one thing, losing your robot driver is much more serious. Our recent downgrade of Cisco to Underweight19 may appear inconsistent with the analysis above. However, the company's valuation is extremely elevated and revenues are declining (Chart 6). Any benefit Cisco will derive from investment into wireless infrastructure is several years out, and open-source hardware initiatives are gaining momentum.20 For that reason, we see the risks as outweighing the opportunities at the moment for the company. Chart 5Long Replacement Cycles Mean Slower ##br##Semiconductor Sales Long Replacement Cycles Mean Slower Semiconductor Sales Long Replacement Cycles Mean Slower Semiconductor Sales Chart 6Cisco's Stock Price Is Close To Tech Bubble##br## Levels Despite Declining Revenue Cisco's Stock Price Is Close To Tech Bubble Levels Despite Declining Revenue Cisco's Stock Price Is Close To Tech Bubble Levels Despite Declining Revenue Cloud Service Providers: Most robots will be on line and some will likely use cloud services to offload computational effort and minimize cost. A relatively "dumb" robotic lawnmower which offloads control to a shared computational resource in the cloud would probably be cheaper than a much more capable fully autonomous system. This will increase demand for cloud services, however the challenge of declining margins (due to increased competition in the space) will offset cloud services revenue growth somewhat in the long term. On balance, Overweight-rated Microsoft and Alphabet/Google, as well as Amazon, stand to benefit. Chart 7Eastman Kodak Tried To Ignore The Shift ##br##To Digital Cameras Eastman Kodak Tried To Ignore The Shift To Digital Cameras Eastman Kodak Tried To Ignore The Shift To Digital Cameras Losers We believe companies who ignore the robotics revolution will find themselves at a significant competitive disadvantage. This is not unprecedented in the technology sector: Digital Equipment Corporation (DEC) and Kodak vanished because their business models could not accommodate an obvious shift in their core markets (Chart 7). Similarly Intel and Microsoft completely missed the smartphone revolution. As we noted in our April 8, 2016 Special Report on AVs, the frequency and severity of crashes will decrease dramatically which will lead to reduced insurance rates, fewer repairs, and less money spent on accident related healthcare and rehabilitation. The economic losses of automobile crashes were estimated $871 billion in the US in 201021 and even a modest reduction in the frequency and severity of collisions due to partial automation would have a significant economic impact. "Dumb" Auto Parts Manufacturers: Fewer collisions will result in fewer repairs to people or vehicles. Auto parts manufacturers will fall into two camps: those with significant expertise in robotics will prosper, while those without such expertise will fall behind as the demand for replacement components (fenders, bumpers, doors, windshields, etc.) will decline. AVs are also likely to include advanced diagnostic and service reminder systems which will result in more timely service, reducing wear and tear on internal components as well. The Auto Insurance Industry: While it is doubtful robotics will ever eliminate auto accidents, the rate might be reduced to such a level that the auto-insurance industry, worth $157 billion in the US alone,22 will be much smaller in 20 years than it is today. This will be offset to a degree by greater demands for product liability insurance for AVs and robots in general. Brian Piccioni, Vice President Technology Sector Strategy brianp@bcaresearch.com Paul Kantorovich, Research Analyst paulk@bcaresearch.com 1 http://www.merriam-webster.com/dictionary/robot 2 http://www.computersciencelab.com/ComputerHistory/HistoryPt2.htm 3 https://www.agclassroom.org/gan/timeline/farm_tech.htm 4 Please see European Investment Strategy Special Report, "Female Participation: Another Mega-Trend," dated April 6, 2017, available at eis.bcaresearch.com. 5 http://www.tomsguide.com/us/Forth-Valley-Royal-Robots-Serco-Medicine,news-7124.html 6 http://modernfarmer.com/2013/04/this-tractor-drives-itself/ 7 http://www.asirobots.com/mining/ 8 http://www.theaustralian.com.au/business/powering-australia/rio-rolls-out-the-robot-trucks/story-fnnnpqpy-1227090421535 9 http://www.bloomberg.com/news/articles/2014-02-25/rolls-royce-drone-ships-challenge-375-billion-industry-freight 10 http://techon.nikkeibp.co.jp/english/NEWS_EN/20141210/393619/ 11 http://www.golfcourseindustry.com/article/do-robotic-mowers-dream-of-electric-turf/ 12 http://www.iihs.org/iihs/topics/t/crash-avoidance-technologies/topicoverview 13 http://gbr.pepperdine.edu/2010/08/preparing-for-a-future-labor-shortage/ 14 http://www.imf.org/external/pubs/ft/fandd/2013/06/das.htm 15 http://www.ti.com/corp/docs/engineeringChange/robotics.html 16 Please see Technology Sector Strategy Weekly Report, "Google - AI And Cloud Strategy," dated April 25, 2017, available at tech.bcaresearch.com. 17 http://www.fiercemobileit.com/press-releases/gartner-says-internet-things-will-transform-data-center 18 http://www.computerworld.com/article/2886316/mobile-networks-prep-for-the-internet-of-things.html 19 Please see Technology Sector Strategy Weekly Report, "Networking Equipment Update ," dated March 28, 2017, available at tech.bcaresearch.com. 20 http://www.businessinsider.com/att-white-box-test-should-scare-cisco-juniper-2017-4 21 http://www.nhtsa.gov/About+NHTSA/Press+Releases/2014/NHTSA-study-shows-vehicle-crashes-have-$871-billion-impact-on-U.S.-economy,-society 22 http://www.bloomberg.c/bw/articles/2014-09-10/why-self-driving-cars-could-doom-the-auto-insurance-industry

The self-driving car, or Autonomous Vehicle (AV), will have a profound impact on a variety of industries. However, expectations for the timeframe of commercial AV availability are too optimistic. The greatest near-term impact is likely to be from advanced safety technologies developed on the path to full autonomy. In today's <i>Special Report</i>, we discuss our expectations for the timeframe of AV development, and the effect of advanced safety technologies on the Insurance, Health Care, Semiconductors, and Automotive industries.