New York-New Haven Trains in an Hour

Devin Wilkins and I are still working on coming up with a coordinated timetable on the Northeast Corridor, north to south. Devin just shared with me the code she was running on both routes from New Haven to New York – to Grand Central and to Penn Station – and, taking into account the quality of the right-of-way and tunnels but not timetable padding and conservative curve speeds – it looks like intercity trains would do it in about an hour. The current code produces around 57 minutes with 7% timetable pad if I’m getting the Penn Station throat and tunnel slowdowns right – but that’s an if; but at this point, I’m confident about the figure of “about an hour” on the current right-of-way.

I bring this up to give updates on how the more accurate coding is changing the timetable compared to previous estimates, but also to talk about what this means for future investment priorities.

First, the curve radii I was assuming in posts I was writing last decade were consistently too optimistic. I wrote three months ago about how even within the highest speed zone in southern Rhode Island, there’s a curve with radius 1,746 meters (1 degree in American parlance), which corresponds to about 215 km/h with aggressive cant and cant deficiency. At this point we’ve found numbers coming straight from Amtrak, Metro-North, and MBTA, letting us cobble together speed zones for the entire system.

But second, conversely, I was being too conservative with how I was setting speed zones. My principle was that the tightest curve on a section sets the entire speed limit; when writing commuter rail timetables, I would usually have each interstation segment be a uniform speed zone, varying from this practice only when the interstation was atypically long and had long straight sections with a tight curve between them. When writing intercity timetables, I’d simplify by having the typical curves on a line set the speed limit and then have a handful of lower speed limits for tighter curves; for example, most curves on the New Haven Line are 873 meters, permitting 153 km/h with aggressive high-speed rail cant and cant deficiency, and 157 km/h with aggressive limits for slower trains, which can run at slightly higher cant deficiency, but those sections are punctuated by some sharper curves with lower limits. Devin, using better code than me, instead lets a train accelerate to higher speed on straight sections and then decelerate as soon as it needs to. Usually such aggressive driving is not preferred, and is used only when recovering from delays – but the timetable is already padded somewhat, so it might as well be padded relative to the fastest technical speed.

The upshot of all of this is that the speed gains from just being able to run at the maximum speed permitted by the right-of-way are massive. The trip time today is 1:37 on the fastest trains between New York and New Haven. Commuter trains take 2:10, making all stops from New Haven to Stamford and then running nonstop between Stamford and Manhattan; in our model, with a top speed of 150 km/h, high-performance regional trains like the FLIRT, Talent 3, or Mireo should do the trip in about 1:15-1:20, and while we didn’t model the current rolling stock, my suspicion is that it should be around six minutes longer. The small difference in trip time is partly because Penn Station’s approach is a few kilometers longer than Grand Central’s and the curves in Queens and on the Hell Gate Bridge are tight.

What this means is that the highest priority should be getting trains down to this speed. In the Swiss electronics-before-concrete schema, the benefits of electronics on the Northeast Corridor are massive; concrete has considerable benefits as well, especially on sections where the current right-of-way constrains not just speed but also reliability and capacity, like New Haven-Kingston, but the benefits of electronics are so large that it’s imperative to make targeted investments to allow for such clean schedules.

Those investments do include concrete, to be clear. But it’s concrete that aims to make the trains flow more smoothly, in support of a repetitive schedule with few variations in train stopping patterns, so that the trains can be timetabled in advance not to conflict. At this point, I believe that grade-separating the interlocking at New Rochelle, popularly called Shell Interlocking and technically called CP 216, is essential and must be prioritized over anything else between the city limits of New York and New Haven Union Station. Currently, there’s very high peak traffic through the interlocking, with a flat junction between trains to Penn Station and trains to Grand Central.

On the electronics side, the timetables must become more regular. There are currently 20 peak trains per hour on the New Haven Line into Grand Central; of those, four go to branches and 16 are on the main line, and among the 16, there are 13 different stopping patterns, on top of the intercity trains. It is not possible to timetable so many different trains on a complex system and be sure that everything is conflict-free, and as a result, delays abound, to which the response is to pad the schedules. But since the padded schedules still have conflicts, there is a ratchet of slowdowns and padding, to the point that a delayed train can recover 20 minutes on less than the entire line. Instead, every train should either be a local train to Stamford or an express train beyond Stamford, and there should only be a single express pattern on the inner line, which today is nonstop between Harlem and Stamford and in the future should include a stop at New Rochelle; this means that, not taking intercity trains into account, the main line should have at most four stopping patterns (local vs. express, and Penn Station vs. Grand Central), and probably just three, since express commuter trains should be going to Grand Central and not Penn Station, as passengers from Stamford to Penn Station can just ride intercity trains.

Also on the electronics side, the way the line is maintained currently is inefficient to an extent measured in orders of magnitude and not factors or percents. Track inspection is manual; Metro-North finally bought a track geometry machine but uses it extremely unproductively, with one report saying it gets one tenth as much work done as intended. Normally these machines can do about a track-mile in an overnight work window, which means the entire four-track line can be regraded and fixed in less than a year of overnights, but they apparently can’t achieve that. Whatever they’re doing isn’t working; the annual spending on track renewal in Connecticut is what Germany spends on once-in-a-generation renewal. The endless renewal work includes a plethora of ever-shifting slow zones, and at no point is the entire system from New York to New Haven clear for trains, even on weekdays. The excessively complex schedule, on tracks that constantly shift due to segment-by-segment daytime repairs, is turning a trip that should be doable on current rolling stock in perhaps 1:23 into one that takes 2:10.

The billions of dollars in the Bipartisan Infrastructure Law that are dedicated to the Northeast Corridor and have not yet been spent can reduce trip times further. But the baseline should be that the bucket of money is a few hundreds of millions smaller and the base case trip time from New York to New Haven is an hour and not 1:37; this is what the system should be compared with.

On Worshiping Foreign Systems

Tucker Carlson has been wowed by Putin’s Russia as of late and is reporting about how great it is; I wouldn’t normally talk about it, except that among the things he crowed about was Kiyevskaya Station on the Moscow Metro. He described it as clean and drug-free, and showed videos that would not have looked out of place in present-day Paris or London, and all I could think about when I watched it was something that I read in Korean media, more than 11 years ago. The newspaper JoongAng criticized the construction of the infill station at Guryong, by comparing its extravagance with the much more spartan stations of the Washington Metro, without noticing how the Washington Metro’s above-ground infill stations cost substantially more than the underground infill at Guryong, the Potomac Yards station reaching four times the cost of Guryong. In both cases, and in some others, the foreign system is not really described as a real place, but as a tourist fantasy. Little learning can come from this.

In fact, there are many positive things one can learn from Russia about how to run rail transportation. Soviet metro planning was quite good, and Eastern Bloc successor states (including satellites, not just former USSR constituents) inherited it and have in some cases expanded on it even while rejecting central planning elsewhere, for example in thoroughly neoliberal Czechia. Good features of this planning tradition include all of the following:

  • Clean radial metro network design, with a distinction between city center and outlying areas.
  • Very high frequency on each line. Moscow peaks at 39 trains per hour, the highest number I know of on non-driverless metros. When I visited Prague, planned by the same tradition, I saw higher metro frequency than I do in Berlin, with its rigid five-minute headways.
  • Central planning of routes, with integration with where housing construction is permitted.

Of note, Carlson’s video doesn’t touch on any of this. He gets the history of the station wrong – he says it was built 70 years ago, when in fact the metro station opened in 1937, and it’s only the two later lines on this three-line transfer that opened in 1953 and 1954. He says he is “just asking questions” and then takes the watcher on a short video trip of the long escalator down to the platform, the ornate details of and art on the station, and the platforms and trains. That’s not Soviet metro design; that’s just metros. The New York City Subway is atypically dirty so that the mosaic art and sculptures there are surrounded by grime, but London and Paris are clean, and some of the stations in Paris have interesting art on the platforms. Stockholm has exposed gneiss rock, which forms a natural arch, and sculptures on some of its platforms. To me, as a regular urban rail rider, all of this looks extremely ordinary, which should not surprise, as good metro planning makes the ordinary last for generations.

Much of it is the excitement of a tourist. To the American visitor, the ornate finishes of Kiyevskaya are new, but the sculptures on the New York City Subway are so familiar that they go unremarkable. I see this in how Americans speak of Europe in general, especially on matters of urbanism; Marco Chitti pointed out that Italian farmers’ markets are for tourists and politicians, while most Italians do their shopping at car-oriented hypermarkets – tourists don’t see how auto-oriented Italy is, and this influences urbanist thinking about the greatness of traditional premodern city centers.

I don’t know what Carlson thinks about urbanism in general. I doubt he’s thought about it much. There are other American right-wing populists who have; their views are common enough among architectural traditionalists that The American Conservative publishes Strong Towns and that at one point the Trump administration passed an executive order requiring all new federal buildings to use traditional architectural styles rather than postwar ones like brutalism or postmodernism.

And Soviet-style metro planning is the exact opposite of that kind of urbanist tradition. It lives off of high-density housing, which are called projects in American parlance and microdistricts in the Soviet tradition, and are ideally placed right next to metro stations so that people can get to work efficiently. In Moscow, the city is large enough to support many radial metro lines, so that districts can be fairly close to metro stations far out of the center; in smaller cities, central planning is required to ensure alternation between high-density housing near the trains and parkland far from them, for which the best examples are Nordic rather than Eastern Bloc.

Traditional architecture critics loathe that kind of housing. In Sweden, one can find right-wingers who view Million Program housing as a socialist conspiracy to depress people into being pliable subjects. Chuck Marohn is not conspiratorial like this, but still opposes spiky density and prefers uniform density, with rules about how new housing on a street should be of similar size to existing buildings (no more than 50% taller) rather than much taller as is typical of either modern redevelopment projects or project-style housing.

Carlson himself is not that influential in urbanism, in the grand scheme of things. But urbanists who go on tourist trips abroad and conflate their travelogues for intellectual insights abound. Their views are often idiosyncratic, based on whatever they liked on a trip, which could be a high-speed rail trip, a neighborhood in a tourist trap, a kind of shopping that locals rarely do, or something similar. In all cases, this is fundamentally about leisure: the (usually New Left) tourist is in the city for purposes of leisure and experiences it as such, but the local rarely is. A glimpse of this can even be seen in the video from Kiyevskaya: the Moscow Metro is very crowded at rush hour, but the video does not depict overcrowding.

It’s possible to learn from abroad, but it does not involve travelogues. It involves interacting with locals in a position of equality rather than in that of a heavyweight who uses taxi drivers as sources. It involves reading what locals say; two years ago, around when Russia invaded Ukraine, I found a list of Russian dissidents and looked at the LiveJournal of an urbanist activist, who was talking about how Russian cities undermaintain public spaces. I think highly of Seung Y. Lee precisely because he demystifies Korean and Japanese urban rail for the Western reader; one can read his complaints about the Seoul subway’s accessibility and still recognize that its 92% wheelchair accessibility is by most global standards very good. It’s possible to, from a position of learning, inform oneself and conclude that a foreign system is superior in most aspects to the domestic one. But that’s not what so many urbanists who speak of their own tourists experience do, and Carlson happens to have provided one political example of this.

Costs Per Rider and Willingness to Build

At the Transit Costs Project, we study the costs of urban rail lines per kilometer. This, with our usual controls, is a rough indicator of how efficient a city’s infrastructure construction program is. However, cost-effectiveness is different from efficiency, and is better measured not by just the cost but also the benefits, which are measured by ridership. Thus, cost-effectiveness is best measured by the cost of each project per rider. So what does it mean to compare different cities by their costs per rider, rather than per kilometer?

The answer is, “not much,” at least not as far as efficiency or good decisionmaking. In fact, while some projects persistently have costs per rider that are too high to be cost-effective (for example, it’s endemic to airport extensions), some cities have costs per rider that are too low, such as Berlin. The issue here is that if municipal or state decisionmaking is healthy, it will build cost-effective lines; if a line under discussion has a very high benefit-cost ratio, or equivalently a very low cost per rider, it means it should have been built long ago, and it speaks poorly to the local decisionmaking that it hasn’t been built already, as is unfortunately the case in Berlin.

Cost per rider and cost-effectiveness

As always, let’s start with Second Avenue Subway Phase 1, the project that launched my interest in construction costs and the Transit Costs Project writ large. The projected daily ridership is 202,000; the line came close to it in 2019, reaching about 163,000 (see data here; I’m taking boardings for the three new stations, adding the growth in ridership at Lexington/63rd, and multiplying by two to account for disembarkings), and would have likely reached projection by now but for the pandemic. The cost, in 2023 dollars, was $6.23 billion, or about $31,000 per projected weekday trip.

For another anchoring number, let’s use the Stockholm Metro’s entire construction from the 1940s to the 1970s. This is useful because in addition to costs per rider, there is a published ex post benefit-cost ratio, thanks to the work of Maria Börjesson. The cost of that system, in 2023 PPP dollars, was $3.7 billion, with a ridership of 1,265,900 per workday in 2019, or $2,900/rider, while the benefit-cost ratio is 6 without taking agglomeration into account, or 8.5 with. This does not mean that the value of a rider is only about $24,900; this was the value in the economic situation of postwar Sweden, a country that was substantially poorer than the Sweden of today. In 2023 PPP terms, Sweden’s GDP per capita in 1965, about midway through the opening of the original system, was about $19,400; today, Sweden is 3.5 times richer, and the US is 17% richer than Sweden.

The benefits of urban travel are largely proportional to GDP per capita. The economic benefits of agglomeration are proportional to the value of the economy writ large, and so are the benefits of reduced travel time, which in benefit-cost analyses are usually taken to be proportional to the average hourly wage. Conversely, the ability of a government to spend money on desired outcomes is proportional to its tax base, i.e. the size of its economy. All of this is approximate, but all we’re doing is first-order approximate analysis anyway, and so correcting for GDP per capita is valuable.

As it is, the difference between American and Swedish GDP per capita boils down entirely to working hours. Swedes work shorter hours than Americans, as they, like nearly everyone else in Europe, get much longer vacation time; as of 2022, Sweden’s GDP per hour worked was, by a rounding error, slightly higher than the US’s. However, at the same time, the daily ridership numbers for Sweden are specifically drawn from winter workday ridership, to avoid reporting figures from when ridership is lower during the summer vacation season, and the same is true for daily ridership counts in France. If we give Sweden and France credit by looking at ridership when people aren’t on vacation, we must compare the cost per rider with GDP per capita and not GDP per hour.

The upshot is that countries should be building metros up to a maximum capital cost per rider that’s about as large as their GDP per capita. The $24,900 computation for 1960s’ Sweden is ex post, and usually the ex ante benefit-cost ratio must be at least 1.2 or 1.3 for the project to go ahead due to risk. For light rail the allowable cost should be lower, and for bus projects it should be lower still, due to the higher lifetime operating costs; but for metros and metro-like urban rail projects (such as largely grade-separated light rail, or commuter rail tunnels like Citybanan), this analysis should hold. Second Avenue Subway Phase 1, which opened in a United States with a GDP of $73,300/capita in 2023 prices, is thus very cost-effective; Phase 2, budgeted at something like $70,000/rider in today’s prices, is marginal but makes it (in 2022, US GDP per capita in 2023 prices was $80,300).

Some more costs per rider

Our database of construction costs per km is largely complete, but we don’t have much ridership data. Worse, the costs per rider we do have have some biases. We have better information for the US and Canada than elsewhere, and for Europe than the rest of the non-North American world. Costs are also likeliest to be reported for megaprojects with notable delays or cost overruns and thus an incomplete database will be biased upward; large, international cities have better reporting in English than the rest and this introduces another upward bias in incomplete data (these are typically wealthy and therefore capable of affording a high cost per rider).

With that in mind, here are some (again, incomplete) examples:

  • Crossrail cost $24 billion in 2023 PPP terms; ridership in late 2023 was 4.3 million a week, which is usually about 700,000/weekday, said to be above projections, with long-term projections rising to a million/weekday; on current ridership it’s $34,000/rider, and on future projections it’s $24,000.
  • Paris Métro Line 14’s original section, opened by 2007, cost $2.44 billion in 2023 PPP terms; ridership in 2019, before more recent extensions and before corona, was 92 million, so around 320,000 per workday, which is $7,600/rider.
  • Grand Paris Express was projected in 2021 to cost (in 2023 PPP dollars) around $65 billion, with a ridership projection of 2 million/day from 2022, and 2.3-2.4 million/day from 2012, for around $32,000/rider, or $28,000 if the older ridership projection is used.
  • Milan Metro Line 5 cost $2.2 billion in 2023 PPP terms to date, and was said to carry 180,000 daily passengers in 2019, for $12,000/rider.
  • Milan Metro Line 4 cost $2.63 billion, and was expected to carry 235,000 riders per day when complete, which would be $11,000/rider; it will be completed this year, but ridership so far is for only the half of the line that has opened so far ans is also still somewhat suffering from corona.
  • The U-Bahn extensions in Berlin that are currently in development hell include U8 to Märkisches Viertel projected at 13,160€/rider (around $21,000 in 2023 PPP terms), a U6 extension to the former Tegel Airport projected at 27,200€/rider (around $43,000), and a U7 extension to the current BER airport projected at 23,000€/rider (around $36,000), among others brought up by the new coalition.

Willingness to build and Berlin’s problem

The above numbers should not be taken to mean that Italy and Germany are more cost-effective about metro construction. To the contrary, they indicate that they are leaving value on the table by not building.

Germany has a GDP per capita of $66,000 in PPP terms. The benefit-cost ratios of the U-Bahn extensions in Berlin that are being discussed but not actually brought forward and built are very high, and the U8 extension to Märkisches Viertel is scratching a ratio of 4. It is irresponsible that there isn’t a massive construction plan not just under discussion but in design and soon physical construction. This must include not just those lines but also others to be added until the benefit-cost ratio of the marginal line falls to slightly more than the minimum that deserves funding.

Italy has the same problem. No matter how pessimistic one’s view of the future of the economy of Italy is, the metro lines it is currently building, at least in Milan, are so cost-effective that there have to be more of them. In the 2010s, Italy was in a budget crunch and ended up using public-private partnerships to keep debt off-books, at very high implied interest rate based on the rate of payment to the concessionaire, about 8%. Today, fundamentally, even a stagnant economy with a GDP per capita of $55,000, which may finally overtake its 2007 peak this year, should be building more if the current extensive margin of Milan Metro construction is not even in the teens of thousands of dollars. Perhaps the benefit-cost ratios for Sweden rely not just on Sweden’s GDP per capita of the 1960s but on that of today, after 60 years of growth; but then even absent any of this growth, 55/3.5 > 12.

Paris showcases a healthier situation: the success of M14 endeared the region to driverless metros with longer interstations than the older metro lines but shorter ones than the RER, and with further growth in the region, the state decided to build the 200 km Grand Paris Express to improve circumferential rail service and add more fast radial connections from the suburbs to the city not along the RER. France’s GDP per capita is around $58,000 in PPP dollars; some elements of GPE may be marginal, but the project writ large has a solid benefit-cost-ratio starting with a 2.

Spain is like France in that when it can build, as it could before the Great Recession and as it can now after having recovered, it does. This is the right way to do it: low costs per km should translate to massive subway expansion. If you’re Madrid, you can build lines that would be completely ridiculous anywhere else in terms of land use, like MetroSur, because it’s cheap.

A Paris or Berlin cannot be so profligate as Madrid. Building a line like MetroSur here, which in the Spanish context looks silly but does pass cost-effectiveness muster, would be an economic albatross. But medium-cost cities can still cover most of the built-up area with subway and commuter rail lines; Paris is doing so but Berlin is not.

The problem for Berlin is not quite austerity, which afflicted Southern Europe last decade, producing negative economic growth. In the last coalition, it was the two most left-wing parties, the Greens and Die Linke, which opposed U-Bahn construction. In their view, trams are preferable; they complain about the high construction costs of subways, but don’t meaningfully engage with why they’re still necessary for fast urban transport beyond the range of the handful of inner neighborhoods where people vote for the Greens.

That said, in the current coalition, there’s no real political left. SPD is in it, but under an atypically conservative leader in Franziska Giffey, and the more left-wing faction in the party, including the youth league Jusos, is sidelined. Both parties in the coalition, CDU and SPD, are committed to building those U-Bahn extensions. But then nothing is happening; Giffey is not competent enough to do it, and CDU is too wrapped up in anti-environmental populism to do something that pisses off some environmentalists but makes others happy.

This way, the low costs per rider projected for Berlin U-Bahn expansion are not a testimony to cost-effectiveness. They’re a testimony to political unwillingness to build, for largely petty reasons. It is wasteful to build a subway line with a very high projected cost per rider relative to the country’s wealth, but it is equally wasteful not to build one with a low projected cost per rider, and the latter is what is happening in Berlin, unfortunately.

Public Transit Subsidies and Efficiency

A few days ago, Streetsblog covered a new study about the impact of transit subsidies on efficiency. Transportation economics research is skeptical of operating subsidies to public transit, arguing that it incentivizes waste. In contrast, the new study argues, the opposite is the case: systems with more subsidies are more efficient. In reality, this is a bad study – trivially and uninterestingly wrong. The real question of interest is not whether it is saying something – it isn’t – but why it is getting any positive press among transit advocates. The context here is important: non-technical advocates, having given up on building good transit, instead just want more subsidies for operations, as the costs rise (bus service being labor-intensive), with scant interest in outcomes like ridership.

What’s in the study?

The study, by Funk, Higgins, and Newmark, is a regression among the top 15 American metro areas, using data from 2016-9. Among those regions, higher subsidies to public transit correlate with higher efficiency. Efficiency is measured as average vehicle occupancy, regardless of whether the vehicle is a train or bus (but trains are calculated on a per-car basis, following NTD norms). Subsidies are measured per capita.

By Funk-Higgins-Newmark, New York has by far the most transit subsidies in the United States: the region subsidized public transit operations across all agencies by $444.50/capita in 2019 dollars. In contrast, regions that have rounding-error ridership were stingier: Dallas averaged $124.20/capita, and Phoenix $97.20. New York has much higher efficiency measured by vehicle occupancy, and secondary transit cities like Boston and San Francisco have lower efficiency than New York and higher than the no-transit Sunbelt cities.

Except that all they’re proving is that cities with higher transit ridership have both higher vehicle occupancy (partly due to higher crowding, partly due to real efficiency, because they run more trains and not just buses) and higher subsidies per capita. To switch to raw 2019 NTD data just because it’s easier to explain: the MTA, across all sub-agencies recorded in the NTD’s top 50 database linked above, spent $12.381 billion on operations in 2019 and earned just $6.359 billion from fares, which works out to somewhat more than $400 per capita in the MTA service region – but those $6 billion of subsidies covered something like 30 billion p-km and 4.6 billion unlinked trips, working out to $1.3 per trip. Even taking into account that unlinked trips are fake news (they double-count people who transfer between subway lines, even within the system), the subsidy per ride is on the on the order of $2/trip. Dallas, in contrast, spent $568 million on operations, got $66 million in fare revenue, and carried 69 million unlinked trips and 706 million p-km. Far from stingy, Dallas spent $7.28 on subsidizing each unlinked bus or rail trip. Houston likewise spent $5.65/trip and Phoenix (buses only) $4.33.

At no point does the study try to establish that if Dallas quadruples its transit subsidies, it will be able to raise its transit ridership by the factor of 67 required to match New York per capita. A snapshot regression of 15 metro areas has no chance of having enough statistical power to establish anything on the margin. The literature review is negative on transit subsidies, finding that they are associated with higher labor spending (for example, through reluctance to innovate in labor-saving technology) and with spreading service-hours too thinly at too low a frequency. To the contrary, all available research suggests that an increase in Dallas’s transit subsidy to match New York will just get wasted; ridership will increase, but so far below the increase in subsidy that the per trip subsidy will skyrocket even more.

In other words, the higher subsidy in New York per capita just showcases that a larger share of people in the New York region ride public transit, and therefore even a relatively low per-rider subsidy can amount to a hefty subsidy per resident. This is not at all surprising; by the same token, polities with larger numbers of schoolchildren spend a larger proportion of their economy on education, which says nothing about how well-funded the schools are (for example, Israel has a rather high education spending as a percentage of GDP, but low spending per student). Thus the study is not just wrong but also boringly so.

So why is it getting any positive press?

American advocacy and subsidies

For years, American transit advocates have been looking into the idea of federal subsidies to transit operations. Traditionally, these are not allowed, except in very small cities with even less relevant public transit than the systems of Dallas or Phoenix; instead, federal funding only goes to capital construction. In the Streetsblog piece, Kea Wilson writes about this connection to advocacy for federal subsidies; I’ve seen it from talking to advocates, who kept complaining, essentially, that federal subsidies require some clear piece of infrastructure to be built and that’s too constraining.

As corona hit, these efforts grew dramatically, since in an emergency it was valuable to inject cash into the systems to prevent long-term closures; then, as ridership hasn’t quite returned (it looks like 70% of pre-pandemic levels as of late 2023; in Berlin, with large reductions in fares, it was 95%), advocates started agitating for more subsidies, without much of a clear goal, certainly nothing related to outcomes. Instead, the demand is to have buses and trains run just so that cities can say that they’re running them. When such advocates say what they’d like to do with the money, it’s, in my experience, always about inputs, never outputs; one said that light rail trains should have a second crew member working as a train attendant just to make passengers feel safer.

In contrast, when I see advocates demand subsidies for concrete ridership-related improvements, it’s not really connected to any demand for federal subsidies. I don’t know what Riders Alliance thinks about federal subsidies to operations, but in its Six-Minute Service campaign, which in its opinion requires some additional state subsidies (and in mine and in that of ETA pays for itself on the subway), it talks about how it’s such a small increase in subsidy relative to existing ones, and doesn’t directly ask for federal subsidies. When it’s for something this specific, advocacy organizations feel confident asking for money directly.

So the belief that subsidies to operations help efficiency, based on a boringly wrong regression, is there in support of something different – in support of wanting subsidies with no clear goal, other than “fund transit.” It’s not really about frequent service, the most valid use of additional operating funds. It’s certainly not about capital extensions that reduce future operating costs, which are favored under the current regime. It’s about spending for its own sake.

Security Theater on Metros

In comments, Sarapen asked me about security on urban rail. It’s common in developing Asia to require people to go through metal detectors to get to the platforms; I’ve seen this in Bangkok, she mentions this in the context of Manila, and it’s also the case on Indian metros and Chinese ones. Seung Y. Lee, a BART digital media worker and indispensable commentator on American and Asian metro history who sadly doesn’t blog enough, has an excellent post about it, talking about the use of security as a tool of social control, for example in Hong Kong.

But Sarapen is asking about the need for security to deter terrorism and violence, which do exist in the Philippines.

For this, I naturally went to the country facing terrorism and violence that I know most intimately. I haven’t visited in more than 11 years, and so I’ve never taken the light rail in either Tel Aviv or Jerusalem (which was open on my last visit but I didn’t visit the city then). So I went ahead and asked on my Discord server, and got this:

The person covered up by the two shorter white rectangles also posted a picture of a platform in Tel Aviv, with a vault for bomb disposal:

Israel Railways does have security theater – one has to open one’s bags in front of a security guard and go through a metal detector, and this being Israel, there is extensive racial profililng. But the light rail, including the underground portions in Tel Aviv, do not. There’s a lot of visible security presence, including cameras, security personnel, and K-9 units, but no metal detectors. This is in a country that, in the 1990s and early 2000s, underwent a wave of suicide bombings on buses, and still didn’t put metal detectors on them, because it’s infeasible to install such technology on surface transit, and too expensive and frankly not too useful on metros (a security line is an attractive bombing target).

This shouldn’t be too surprising, in a way. Western Europe did not install security theater on trains in response to far-left terrorism in the 1970s and 80s. Israel’s way of building and running public transportation is intended as a pan-European medley, using consultants who have done work in Europe, and with media discourse that looks up to Europe’s urban transportation systems (on other matters Israel looks up to the United States, but Israelis understand American public transportation is not good). If nobody in Europe (or at least Western Europe) does something, it’s unlikely Israel will do it, not on civilian public infrastructure.

Worthless Canadian Initiative

Canada just announced a few days ago that it is capping the number of international student visas; the Times Higher Education and BBC both point out that the main argument used in favor of the cap is that there’s a housing shortage in Canada. Indeed, the way immigration politics plays out in Canada is such that the cap is hard to justify by other means: traditionally, the system there prioritized high-skill workers, to the point that there has been conservative criticism of the Trudeau cabinet for greatly expanding low-skill (namely, refugee) migration; capping student visas is not how one responds to such criticism.

The issue is that Canada builds a fair amount of housing, but not enough for population growth; the solution is to build more – in a fast-growing country like Canada, the finance sector expects housing demand to grow and therefore will readily build more if it is allowed to.

Vancouver deserves credit for the quality of its transit-oriented development and to a large extent also for the amount of absolute development it permits (about 10 units per 1,000 residents annually); but its ability to build is much greater than that, precisely because rapid immigration means that more housing is profitable, even at higher interest rates. The population growth coming from immigration sends a signal to the market, invest in long-term tangible goods like housing. Thus, Vancouver deserves less credit for its permissiveness of development – large swaths of the city are zoned for single-family housing with granny flats allowed, including in-demand West Side neighborhoods with good access to UBC and Downtown jobs by current buses and future SkyTrain.

The rub is that restricting student immigration is probably the worst possible way to deal with a housing shortage. Students live at high levels of crowding, and the marginal students, who the visa cap is excluding, live at higher levels of crowding than the rest because they tend to be at poorer universities and from poorer backgrounds. The reduction in present-day demand is limited. In Vancouver, an empty nester couple with 250 square meters of single-family housing in Shaughnessy is consuming far more housing, and sitting on far more land that could be redeveloped at high density, than four immigrants sharing a two-bedroom apartment in East Vancouver.

In contrast, the reduction in future demand is substantial, because those students then graduate and get work, and many of them get high-skill, high-wage jobs (the Canadian university graduate premium is declining but still large; the American one is larger, but the US is also a higher-inequality society in general); having fewer students, even fewer marginal students who might take jobs below their skill level, is still a reduction in both future population and future productivity. What this means is that capital owners deciding where to allocate assets are less likely to be financing construction.

The limiting factor on housing production is to a large extent NIMBYism, and there, in theory, immigration restrictions are neutral. (In practice, they can come out of a sense of national greatness developmental conservatism that wants to build a lot but restrict who can come in, or out of anti-developmental NIMBYism that feels empowered to build less as fewer people are coming; this situation is the latter.) However, it’s not entirely NIMBYism – private developmental still has to be profitable, and judging by the discourse I’m seeing on Canadian high-rise housing construction costs in Toronto and Vancouver, it’s not entirely a matter of permits. Even in an environment with extensive NIMBYism like the single-family areas of Vancouver and Toronto, costs and future profits matter.

The Need for Ample Zoning Capacity

An article by Vishaan Chakrabarti in last month’s New York Times about how to make room for a million more people in New York reminded me of something that YIMBY blogs a decade ago were talking about, regarding zoning capacity. Chakrabarti has an outline of where it’s possible to add housing under the constraints that it must be within walking distance of the subway, commuter rail, or Staten Island Railway, and that it must be of similar height to the preexisting character of the neighborhood. With these constraints, it’s possible to find empty lots, parking lots, disused industrial sites, and (in near-Midtown Manhattan) office buildings for conversion, allowing adding about half a million dwellings in the city. It’s a good exercise – and it’s a great explanation for why those constraints, together, make it impossible to add a meaningful quantity of housing. Transit-oriented development successes go far beyond these constraints and build to much higher density than is typical in their local areas, which can be mid-rise (in Europe) or high-rise (in Canada and Asia).

The issue with the proposal is that in practice, not all developable sites get developed. The reasons for this can include any of the following:

  • The parcel owner can’t secure capital because of market conditions or because of the owner’s particular situation.
  • The parcel is underdeveloped but not empty, and the owner chooses not to redevelop, for a personal or other reason.
  • The area is not in demand, as is likely the case near the Staten Island Railway or commuter rail stations in Eastern Queens, or in much of the Bronx.
  • The area is so auto-oriented, even if it is technically near a station, that prospective buyers (and banks) demand parking, reducing density.

New York has, on 2020 census numbers, 8.8 million people; 1 million additional New Yorkers is 11% more people. Cities that permit a lot of housing have an envelope for much more than 11% extra population. In New York’s history, it was computed in 1956 that under the then-current 1916 zoning code, the city’s zoned capacity was 55 million people, but under the proposed code that would be enacted in 1961, the zoned capacity would fall to 12 million. In Los Angeles, The Homeowner Revolution makes the point (on PDF-page 19) that in 1960, zoned capacity was 10 million in the city proper, four times the city’s population, but by 1990 it fell to 3.9 million, 11% more than the city’s population.

Technically, the same extra zoned capacity that Chakrabarti finds for New York has existed in Los Angeles for a generation. In practice, for all the above reasons why development never reaches 100% of capacity even in expensive areas, Los Angeles builds very little housing, and rents are very high, perhaps comparable to those of New York even as wages are much lower.

What this means is that the way forward for any transit-oriented development plan has to get out of the mentality that the buildings need to be of similar size to the existing character of the neighborhood. This constraint is too strict, and not at all observed in any successful example that I know of.

To Americans, the most accessible example of transit-oriented development success is Vancouver; some sections of the Washington suburbs (especially Arlington) qualify as well, but the extent there is much less than in Canada, and consequently ridership on Washington Metro has lagged that of its Canadian counterparts. In Vancouver, the rule that Chakrabarti imposes that the preexisting parcels must be empty or nonresidential is largely observed – as far as I can tell, the city has not upzoned low-density residential areas near SkyTrain, and even in Burnaby, the bulk of redevelopment has been in nonresidential areas.

The redevelopment in Vancouver proper looks like this:

And here is Metrotown, Burnaby:

The surface parking may look obnoxious to urbanists, but the area has more jobs, retail, and housing than the parking lots can admit, and the modal split is very high.

European transit-oriented development is squatter – the buildings are generally less tall, and they’re spread over a larger contiguous area, so that beyond the resolution of a few blocks the density is high as well. But it, too, often grows well beyond tradition. For example, here is Bercy, a redevelopment of the steam-era railyards at Gare de Lyon, no longer necessary with modern rail technology:

In the future, a New York that wants to make more room will need to do what Vancouver and Paris did. There is no other way.

Quick Note: Different Anti-Growth Green Advocacies

Jerusalem Demsas has been on a roll in the last two years, and her reporting on housing advocacy in Minneapolis (gift link) is a great example of how to combine original reporting with analysis coming from understanding of the issue at hand. In short, she talks to pro- and anti-development people in the area, both of which groups identify with environmentalism and environmental advocacy, and hears out their concerns. She has a long quote by Jake Anbinder, who wrote his thesis on postwar American left-NIMBYism and its origins, which are a lot more good-faith than mid-2010s YIMBYs assumed; he points out how they were reacting to postwar growth by embracing what today would be called degrowth ideology.

I bring this up because Germany is full of anti-growth left-NIMBYism, with similar ideology to what she describes from her reporting in Minneapolis, but it has different transportation politics, in ways that matter. The positioning of German left-NIMBYs is not pro-car; it has pro-car outcomes, but superficially they generally support transportation alternatives, and in some cases they do in substance as well.

In the US, the left-NIMBYs are drivers. Jerusalem cites them opposing bike lanes, complaining that bike lanes are only for young childless white gentrifiers, and saying that soon electric cars will solve all of the problems of decarbonizing transportation anyway. I saw some of this myself while advocating for rail improvements in certain quarters in New England: people who are every stereotype of traditional environmental left-NIMBYism were asking us about parking at train stations and were indifferent to any operating improvements, because they don’t even visit the city enough to think about train frequency and speed.

In Germany, many are drivers, especially outside the cities, but they don’t have pro-car politics. The Berlin Greens, a thoroughly NIMBY party, are best known in the city for supporting removal of parking and moving lanes to make room for bike lanes. This is not unique to Berlin or even to Germany – the same New Left urban mayors who do little to build more housing implement extensive road diets and dedicated lanes for buses, streetcars, and bikes.

These same European left-NIMBYs are not at all pro-public transportation in general. They generally oppose high-speed rail: the French greens, EELV, oppose the construction of new high-speed lines and call for reducing the speed on existing ones to 200 km/h, on the grounds that higher speeds require higher electricity consumption. In Germany, they usually also oppose the construction of new subway and S-Bahn tunnels. Their reasons include the embedded carbon emissions of tunneling, a belief that the public transport belongs on the street (where it also takes room away from cars) and not away from the street, and the undesirability (to them) of improving job access in city center in preference to the rest of the city. However, they usually consistently support more traditional forms of rail, especially the streetcar and improvements to regional rail outside major cities. For example, the NIMBYs in Munich who unsuccessfully fought the second S-Bahn trunk line, whence the expression Organisation vor Elektronic vor Beton (the Swiss original omits Organisation and also is very much “before” and not “instead of”), called for improvements in frequency on lines going around city center, in preference to more capacity toward city center.

I’m not sure why this difference works like this. I suspect it’s that American boomer middle-class environmental NIMBYism is rooted in people who suburbanized in the postwar era or grew up in postwar suburbs, and find the idea of driving natural. The same ideology in Europe centers urban neighborhood-scale activism more, perhaps because European cities retained the middle class much better than their American ones, perhaps because mass motorization came to Europe slightly later. It also centers small towns and cities, connected to one another by regional rail; the underlying quality of public transportation here is that environmentalists who can afford better do rely on it even when it’s not very good, which hourly regional trains are not, whereas in the United States it’s so far gone that public transportation ridership comprises New Yorkers, commuters bound for downtown jobs in various secondary cities, and paupers.

Eurostar Security Theater and French Station Size

Jon Worth has been doing a lot of good work lately pouring cold water on various press releases of new rail service in Europe. Yesterday he wrote a long post, reacting to some German rail discourse about the possibility of Eurostar service between London and Germany; he explained the difficulties of connecting Eurostar to new cities, discussing track and station capacity, signaling, and rolling stock.

Jon, whose background is in EU politics, wastes no time in identifying the ultimate problem: the UK demands passport controls, and this demand is unlikely to be waived in the near future due to concerns over Brexit and the need to have visible border control theater. In turn, the passport control and the accompanying security theater (not strictly required, but the UK insists for Channel Tunnel security) mean that boarding trains is a slow process since platforms must be kept sterile; thus, a Eurostar station requires dedicated platforms, and if it has significant rail traffic then it requires many of them, with low throughput per track. This particularly impacts the prospects of Eurostar service to Germany, because it would go via Belgium and Cologne, which has far from enough platforms for this operation.

What I’d like to add to this analysis is that Eurostar made a choice to engage in such controlled operations in the 1990s. The politics of Brexit can explain why there’s no reform that is acceptable to the British political system now; it cannot explain why this was chosen in the 1990s. The norm in Europe before Schengen was that border control officers would perform on-board checks while the train traveled between the last station in the origin country and the first station in the destination country; long nonstop trains between Paris and London or even Lille and London are ideal for such a system. Britain insists on the current system of border control before boarding because this way it can deny entry to people who otherwise would enjoy non-refoulement protections – but in the 2000s the politics in Britain was not significantly more anti-immigration than in, for example, Germany, or France.

Rather, the issue is that Britain insisted on some nebulous notion of separateness, and this interacted poorly with train station design in France compared with in Germany. Parisian train stations are huge, and have a large number of terminating tracks. Dedicating a few terminal tracks to sterile operations is possible at Gare du Nord, and would be possible at other Parisian terminals like Gare de Lyon if they pointed in the direction of a place that demanded them. SNCF has conceived of its operations, especially internationally, as airline-like, and this contributed to complacency about how the train stations are being treated like airports.

Germany developed different (and better) ways of conceiving of train operations. More to the point, Germany doesn’t really have Paris’s terminals with their surplus of tracks, except for Frankfurt and Munich. Cologne, the easiest place to get to London from, doesn’t have enough tracks for sterile operations. This is fine, because German domestic trains do not imitate airlines, even where there is room (instead, the surplus of tracks is used for timed connections between regional trains); this also cascades to international trains connecting to Germany, whether from countries that have more punctual rail networks like Switzerland or from countries that work by a completely different paradigm like Belgium or France.

And now Eurostar politically froze a system that was only workable at low throughput, at a handful of stations with more room for sterile operations than is typical. The system is still below its ridership projections from before opening; it was supposed to be part of a broader international rail network, but that never materialized, because of the burden of security theater, the high fares, and the indifference of Belgium to extending high-speed rail so that it would be useful for international travelers (the average speeds between Brussels-Midi and the German border are within the upper end of the range for upgraded classical lines, even though HSL 2 and 3 are new high-speed lines).

And now, with the knowledge of the 2010s, it’s clear that any future expansion of Eurostar requires forgoing the airline-like paradigm that led SNCF to stagnation in the same decade. This clashes with British political theater now, but there’s no other way forward.

And this even affects domestic British rail planning. London planners are fixated on Paris as their main comparison. This way, they are certain trains must turn slowly at city terminals, requiring additional tracks at Euston and other stations that are or until recently were part of High Speed 2, at a total cost of several billion pounds. In Germany and the Netherlands (at Utrecht) trains can move faster, down to turns of seven to eight minutes on German regional trains and four to five minutes on intercity trains pinching at terminal stations like Frankfurt. But planners in large cities look down on smaller cities; it’s no different from how planners in New York assume that because New York is bigger than Stockholm, Second Avenue Subway’s stations have higher ridership than the stations of Citybanan (in fact, Citybanan’s two stations, located in city center, are significantly busier).

This way, a particular feature of historic Parisian stations – they have a lot of tracks – got turned into something that every city’s train station is assumed to have. It means Eurostar can’t operate into other stations, because there is no surplus of platforms allowing segregating service to the UK away from all other traffic; it also means that planners in the UK that are trying to engineer stations assume British stations must be overbuilt to Parisian specs.

Small Metros Aren’t Lean, They’re Underbuilt

Reece Martin does very good vlogs on public transportation, and has begun text-blogging more regularly, which I appreciate greatly. But a post of his from six days ago, talking about lean metros, misses a key aspect of short metro systems. He compares old legacy systems like Paris or New York or Berlin’s with newer ones, like Hong Kong’s, and points out that the newer ones are rather short relative to city size, saying that it’s a leaner, lower-cost way of doing things. But in fact, the reason we see such short metros relative to city size is not efficiency, but underbuilding, leading to overcrowding.

What’s a lean metro?

Reece divides leanness into two kinds. The first is the ability of some cities to build driverless metros with very short trains at very high frequencies, to save money on station construction. He gives the examples of Copenhagen and Vancouver. This is particularly common in Italy: Milan Metro Lines 4 and 5 have 50 meter long trains, the Turin Metro has 55 meter long trains, the Brescia Metro has 40 meter long trains. With this setup and with the generally low construction costs of Italy, even Brescia can afford a metro, in a city proper of 200,000 with a built-up urban area of 673,000 (and rising) as of 2011.

The second kind of leanness is just building fewer lines. He talks about Toronto’s system, with two main trunk lines, one branch line with a transfer to a main line, and a total of 70 km of length. He also brings up Hong Kong, which has, counting both proper metro lines and the two inherited commuter lines, around 212 route-km, with very high ridership. This can be supported through transit-oriented development, for which Hong Kong is famous. It can also come from strong bus-rail connections as in Toronto: a blog post from last decade that I can no longer find points out that York Mills has what looks like 14,000 weekday boardings on pre-corona numbers, despite low-density land use immediately surrounding it, because of the strong connecting buses on the Toronto grid, favorably comparing it with American metros like Washington’s.

Small station metros

I don’t want to criticize the Italian trend too much, but I do want to separate it from the other systems Reece calls lean. The issue with the style of construction used in Brescia is that it’s really good, if your city is the size of Brescia. Small-station, partly cut-and-cover driverless metros should be in the toolkit of metro areas of about a million people, in order to save money. Other tools should be heavily relying on legacy commuter lines (as in Zurich) and using trams if they’re available (as in Bratislava or Brno), and likely combining all three solutions when feasible (in fact Zurich has a large tramway network in addition to the S-Bahn).

In a larger city, such light metro lines are only useful in a very restricted set of circumstances. Singapore has short trains on the Circle Line – but the Circle Line has not been cheap to build, and its last section has been extraordinarily expensive. On a radial line, it’s a nonstarter. A large city needs the very high throughput of a driverless metro but also larger trains; those can be medium-length trains, like the 90 meter trains of Paris Métro Line 1, or longer, like the 138 meter long trains of the now-driverless legacy lines in Singapore, or the 200 meter long platforms of the Shinbundang Line in Seoul. If the line is too short, the city may find it needs to build another just for relief, as the area that was once thought peripheral develops.

Short metros

If a metro system is short, even if its trains are long, it’s not generally a sign of efficient construction in the city. It’s a sign of underbuilding and overcrowding.

Hong Kong has very high crowding levels, even with a system length that, counted properly, is not that unreasonable: the MTR’s total route-length is almost the same as that of the Paris Métro, which has 227 km, and its ridership is, on pre-corona numbers, slightly higher, 1.7 billion a year compared with 1.5 billion. Now, to be clear, Paris has very high ridership for the system’s size. I suspect the reason I’ve never seen overcrowding on the Métro is that the nature of Parisian job concentration is such that the lines that get overcrowded are ones connecting the suburbs with the city, that is, the RER and M13, rather than predominantly intra-city lines like M1. But the situation in Hong Kong is overall less one of leanness and more one of not being to expand as fast as it would like due to extreme construction costs, which are a strong contender for the world’s second worst, after New York’s. (Toronto is an even stronger contender.)

Then there are the developing-world metros that are just far too short for their city size. Hong Kong is a city of 7 million with a little more than 200 km of metro and commuter rail. Cairo is a metro area of 22 million with 100 km of metro. Cairene construction costs are high, but when, depending on how much one trusts dead links from 10 years ago, the city has the world’s highest rail ridership per km, it needs a lot more; that Cairo has 100 km of metro rather than 800 like Shanghai, a similar-size city in a country that, during its peak expansion, was about as rich as Egypt, is not about leanness but about the Egyptian government’s spending priorities.

For a middle-income country that wants to get out of the middle-income trap that Egypt is stuck in (or Brazil, home to the almost as underbuilt São Paulo Metro), China is a decent benchmark. So is Paris – France is rich but also, precisely because it’s rich, rather motorized by any developing country standards, leading to a modal split of about 43% public transit, 43% cars for work trips in Ile-de-France. Using these benchmarks, your city should have on the order of 30 km of metro and new commuter rail per million residents. If you have 4.5 like Cairo, it’s not efficiency, it’s total disinterest in the living standards of the urban population.