After drawing a map of an integrated timed transfer intercity rail network for the state of New York, people asked me to do other parts of the United States. Here is New England, with trains running every 30 minutes between major cities:
New England is a much friendlier environment for intercity rail growth than Upstate New York, but planning there is much more delicate. The map thus has unavoidable omissions and judgment calls, unlike the New York map, which straightforwardly follows the rule of depicting intercity lines but not suburban lines like the Long Island network. I ask that people not flame me about why I included X but not Y without reading the following explanations.
The tension between S-Bahn and ITT planning
The S-Bahn concept involves interlining suburban rail lines through city center to provide a high-frequency urban trunk line. For example, trains from a number of East Berlin neighborhoods and Brandenburg suburbs interline to form the Stadtbahn: in the suburbs, they run every 10 or 20 minutes, but within the Ring, they combine to form a diameter running regularly every 3:20 minutes.
The integrated transfer timetable concept instead involves connecting different nodes at regular intervals, typically half an hour or an hour, such that trains arrive at every node just before a common time and leave just after, to allow people to transfer. In a number of major Swiss cities, intercity trains arrive a few minutes before the hour every 30 minutes and depart a few minutes after, so that people can connect in a short amount of time.
S-Bahn and ITT planning are both crucial tools for good rail service, but they conflict in major cities. The ITT requires all trains to arrive in a city around the same time, and depart a few minutes later. This forces trains from different cities to have different approach tracks; if they share a trunk, they can still arrive spaced 2-3 minutes apart, but this lengthens the transfer window. The idea of an S-Bahn trunk involves trains serving the trunk evenly, which is not how one runs an ITT.
Normally, this is no problem – ITTs are for intercity trains, S-Bahns are for local service. But this becomes a problem if a city is so big that its S-Bahn network grows to encompass nearby city centers. In New York, the city is so big that its shadow reaches as far as Eastern Long Island, New Haven, Poughkeepsie, and Trenton. Boston is smaller but still casts shadows as far as southern New Hampshire and Cape Cod.
This is why I don’t depict anything on Long Island on my map: it has to be treated as the extension of an S-Bahn system, and cannot be the priority for any intercity ITT. This is also true of Danbury and Waterbury: both are excellent outer ends for an electrified half-hourly regional rail system, but setting up the timed transfers with the New Haven Line (which should be running every 10 minutes) and with high-speed rail (which has no reason to stop at the branch points with either Danbury or Waterbury) is infeasible. In Boston I do depict some lines – see below on the complications of the North-South Rail Link.
The issue of NSRL
The North-South Rail Link is a proposed north-south regional rail tunnel connecting Boston’s North and South Stations. Current plans call for a four-track tunnel extending across the river just north of North Station, about 4.5 km of route; it should cost $4 billion including stations, but Massachusetts is so intent on not building it lies that the cost is $12 billion in 2018 dollars.
In common American fashion, NSRL plans are vague about how service is to run through the tunnel. There are some promises of running intercity trains in addition to regional ones; Amtrak has expressed some interest in running trains through from the Northeast Corridor up to the northern suburbs and thence to Maine. However, we are not engaging in bad American planning for the purposes of this post, but in good Central European planning, and thus we must talk about what trains should run and design the tunnel appropriately.
The rub is that Boston’s location makes NSRL great for local traffic and terrible for intercity traffic. When it comes to local traffic, Boston is right in the middle of its metropolitan region, just offset to the east because of the coast. The populations of the North Side and South Side suburbs are fairly close, as are their commuter volumes into Boston. Current commuter rail ridership is about twice as high on the South Side, but that’s because South Station’s location is more central than North Station’s. NSRL really is a perfect S-Bahn trunk tunnel.
But when it comes to intercity traffic, Boston is in the northeast corner of the United States. There are no major cities north of Boston – the largest such city, Portland, is a metro area of 600,000. In contrast, going south, New York should not be much more than an hour and a half away by high-speed rail. Thus, high-speed rail has no business running through north of Boston – the demand mismatch south and north is too high.
Since NSRL is greatly useful for regional traffic but not intercity traffic, the physical infrastructure should be based on S-Bahn and not ITT principles, even though the regional network connects cities quite far away. For one, the tunnel should require all trains to make all stops (South Station, Aquarium, North Station) for maximum local connectivity. High-speed trains can keep feeding South Station on the surface, while all other traffic uses the tunnel.
But on the North Side, feeding North Station on the surface is not a good idea for intercity trains. The station is still awkwardly just outside city center. It also offers no opportunity to transfer to intercity trains to the most important city of all, New York.
The only resolution is to treat trains to Portland and New Hampshire as regional trains that just go farther than normal. The Nashua-Manchester-Concord corridor is already as economically linked to Boston as Providence and Worcester, and there are plans for commuter rail service there already, which were delayed due to political opposition to spending money on trains from New Hampshire Republicans after their 2010 election victory. Portland is more speculative, but electric trains could connect it with Boston in around an hour and a half to two hours. These trains would be making suburban stops north of Boston that an intercity train shouldn’t normally make, but it’s fine, the Lowell Line has wide stop spacing and the intermediate stops are pretty important post-industrial cities. At Portland, passengers can make a timed connection to trains to Bangor, on the same schedule but with shorter trainsets as the demand north of Portland is much weaker.
On the map, I also depict Boston-Cape Cod trains, which like Boston-Concord trains are really suburban trains but going farther. Potentially, the branch to Cape Cod – the Middleborough branch of the Old Colony Lines – could even run through with the Lowell Line, either the branch to Concord or the Wildcat Branch to Haverhill and Portland. Moreover, the sequencing of the branches should aim to give short connections to Boston-Albany high-speed trains as far as reasonable.
The issue of the Northeast Corridor
The Northeast Corridor wrecks the ITT plan in two ways, one substantial and one graphical.
The snag is that there should be service on legacy track running at a maximum speed of 160-200 km/h in addition to high-speed service on high-speed tracks. There may be some track sharing between New York and New Haven to reduce construction costs, using timed overtakes instead of full track segregation, but east of New Haven the high-speed trains should run on a new line near I-95 to bypass the Shore Line’s curves, and the Shore Line should be running electric regional trains to connect to the intermediate cities.
The graphical problem is that the distance between where the legacy route is and where the high-speed tracks should be is short, especially west of New Haven, and depicting a red line and a blue line together on the map is not easy. I will eventually post something at much higher resolution than 1 pixel = 500 meters. This also affects long-distance regional lines that I’d like to depict on the map but connect only to legacy trains on the Northeast Corridor, that is the Danbury and Waterbury Branches.
For planning purposes, figure that both run every half hour all day, are electric, run through to and beyond New York as branches of the New Haven Line, and are timed to have reasonable connections to high-speed trains to Albany and points north in New York. Figure the same for trains between New Haven and Providence, with some additional runs in the Providence suburbs giving 15-minute urban frequencies to such destinations as Olneyville and Cranston.
The substantial issue is that the Northeast Corridor is far too high-demand for a half-hourly ITT. Intercity trains run between New York and Boston better than hourly today, and that’s taking twice as long as a TGV and charging 2.5-4 times as much. My unspoken assumption when planning how everything should fit together is that there should be a 400-meter long train every 15 minutes on the corridor past New Haven, spaced evenly around Boston to overtake regional trains to Providence at consistent locations. Potentially, there should be more local trains taking around 1:50 and more express trains taking around 1:35, and then all timed transfers should be to the local trains.
On the New Haven Line, too, regional rail demand is much more than a train every half hour. Trains run mostly every half hour today, with management that is flagrantly indifferent to off-peak service, and trip times that are about 50% longer than they should be. Nonetheless, best practice is to set up timed transfers such that various branches all connect to the same train, so that passengers can connect between different branches. This mostly affects Waterbury; it’s useful to ensure that Waterbury trains arrive at Bridgeport with a short transfer to a train toward New Haven that offers a quick connection to trains to points north and east.
Planning HSR around timed connections
Not counting lines that are in the Boston sphere, or the lines around Albany, which I discussed two weeks ago, there are three lines proposed for timed connection to high-speed rail: New London-Norwich, Providence-Worcester-Fitchburg, Springfield-Greenfield.
All three are regional lines, not intercity lines. They are not optimized for intercity speed, but instead make a number of local urban and suburban stops. This is especially true of Springfield-Northampton-Greenfield, a line that Sandy Johnston and I have been talking about since 2014. A Springfield-Greenfield line with 1-2 intermediate stops might be able to do a one-way trip in around 39 minutes, at which point a 45-minute operator schedule may be feasible with a very tight turnaround regime – but there’s enough urban demand along the southern half of the route that adding stops to make it about 50 minutes with a one-hour operator schedule is better.
The Providence-Worcester line is likewise slower than it could be if it were just about Providence and Worcester. The reason is that high-speed rail compresses distances along its route. Providence-Boston by high-speed rail is about 22 minutes nonstop, including schedule contingency. Boston-Worcester is about the same – slower near Boston because of scheduling difficulties along the Turnpike and the inner Worcester Line, faster near the outer end because Worcester has no chance of getting a city center station but rather gets a highway station. Now, passengers have a range of transfer penalties, and to those who are averse to connections and have a high personal penalty, the trip between the two cities is more attractive directly than via Boston. But there are enough passengers who’d make the trip via Boston that the relative importance of intermediate points grows: Pawtucket, Woonsocket, Uxbridge, Millbury. In that situation, the importance of frequency grows (half-hourly is a must, not hourly) and that of raw speed diminishes.
The onward connection to Fitchburg is about three things. First, connecting Providence with Fitchburg. Second, connecting Worcester with Fitchburg. And third, connecting Fitchburg with the high-speed line. This makes investments into higher speed more valuable, since Fitchburg’s importance is high compared with that of points between Worcester and Fitchburg. The transfer between the line and high-speed rail should be timed in the direction of Fitchburg-to-Albany first of all, and Providence-to-Albany second of all, as the connections from the endpoints to Boston are slower than direct commuter trains.
The presence of this connection also forces the Worcester station to be at the intersection with the line to Providence. Without this connection, it may be better to site the station slightly to the west, at 290 rather than 146, as the area already has Auburn Mall.
Finally, the New London-Norwich line is a pure last-mile connector from the New London train station, which is forced to be right underneath the I-95 bridge over the river, to destinations to the north. The northern anchor is Norwich opposite the historic center, but the main destination is probably the Mohegan Sun casino complex. Already there are many buses connecting passengers from New York to the casino. The one-way trip time should be on the order of 21-22 minutes, but with a turnaround it’s a 30-minute schedule, and the extension south to the historic center of New London is for completeness; with a timed connection, trains could get between Penn Station and Norwich in around 1:20 counting connection time, and between Penn Station and Mohegan Sun in maybe 5 minutes less.
What about Vermont?
Vermont’s situation is awkward. Burlington is too far north and too small to justify a connection to high-speed rail by itself. A low-speed connection might work, but the line from Burlington south points toward Rutland and not New York, and connecting it onward requires reversing direction. If Vermont had twice its actual population this might be viable, but it doesn’t.
But Vermont is right between New York and Montreal. I generally don’t show New York-Montreal high-speed rail on my maps. It’s a viable line, but people in both cities severely overrate it, especially compared with New York-Toronto; I have to remind readers this whenever I write about international high-speed trains. In the event such a line does open, Burlington is the only plausible location for a Vermont stop – everything else is too small, even towns that historically did have rail service, like Middlebury. Rutland could get a line running partly on high-speed track and partly on legacy track taking it down to Glens Falls or Saratoga Springs to transfer to onward destinations, or maybe Albany if trains run 2-3 minutes apart in pairs every 30 minutes.
Current plans for Vermont try to connect it directly to Boston via New Hampshire, and that is wrong. The Vermonter route is mountainous from Greenfield to Burlington; trains will never be competitive with driving there. Another route under occasional study going into Boston from the north was even included on a 2009 wishlist of high-speed rail routes, under the traditional American definition of high-speed rail as “train that is faster than a sports bicycle.” That route, crossing mountains in both New Hampshire and Vermont, is even worse. The north-south orientation of the mountains in both states forces east-west routes to either stick to the lowlands or consolidate to strong enough routes that high-speed rail tunnels are worthwhile.
How much does this cost?
As always, I am going to completely omit the Northeast Corridor from this cost analysis; an analysis of that will happen later, and suffice is to say, the benefit-cost ratio if there’s even semi-decent cost control is extremely high.
With that in mind, the central pieces of this program are high-speed lines from Boston to Albany and from New Haven to Springfield, in a T system. The 99 km New Haven-Springfield line, timetabled at 45 minutes including turnaround and maybe 36 minutes in motion, is on the slow side for high-speed rail, as it is short and has a crucial intermediate station in Hartford. It does not need any tunnels or complex viaducts, and property takings are nonzero but light; the cost should not be higher than about $2-2.5 billion, utilizing legacy track for much of the way.
The Boston-Albany line is much costlier. It’s 260 km, and crosses the aforementioned north-south mountains in Western Massachusetts. Tunnels are unavoidable, including a few kilometers of digging required just west of Springfield to avoid a slowdown on suburban curves. At the Boston end, tunneling may also be unavoidable next to the Turnpike. The alternative is sharing a two-track narrows with the MBTA Worcester Line in Newton; it’s possible if the trains run no more than every 15 minutes, which is a reasonable short-term imposition but may be too onerous in the longer term if better service builds up more demand for commuter rail frequency in Newton. My best guess is that without Newton, the line needs around 20 km of tunnel and can piggyback on 35 km of existing lines at both ends, for a total cost in the $6-8 billion range. This figure is sensitive to whether my 20 km estimate is correct, but not too sensitive – at 40 it grows to maybe $9 billion, at 0 it shrinks to $4.5 billion.
Estimating the costs of the blue lines on the map is harder. All of them are, by the standard of high-speed rail, very cheap per kilometer. A track renewal machine on a one-third-in-tunnel German high-speed line can do track rebuilding for about a million euros per single-track-kilometer. All of these lines would also need to be electrified from scratch, for $1.5-3 million per kilometer. Stations would need to be built, for a few million apiece. My first-order estimate is $1 billion for the three blue connector lines and about the same for Boston-Portland-Bangor; the Hyannis and Concord lines would go in a regional rail basket. The NSRL tunnel should be $4 billion or not much more, and not what Massachusetts wants voters to believe it is to justify its decision not to build it.
The reason for the relatively limited map (e.g. no Montreal service) is that these lines are not such slam dunks that they’re worth it at any price. Cost control is paramount, subject to the bare minimum of good service (e.g. electrification and level boarding). For what I think a fair cost is, those lines are still good, providing fast connectivity across New England from most places to most other places. Moreover, the locations of the major nodes, like Worcester and Springfield, allow timing bus interchanges as well, providing further connections to various suburbs and city neighborhoods.
The red high-speed lines are flashy, but the blue ones are important too. That’s the key takeaway from planning in Switzerland, Austria, and the Netherlands, all of which have high rail usage without great geography for intercity rail. Trains should be planned coherently as a network, with all parts designed in tandem to maximize connectivity. This isn’t just about going between Boston and Springfield or Boston and Albany or New Haven and Springfield, but also the long tail of weaker markets using timed connections, like New Haven-Amherst, Brockton-Worcester, Dover-Providence, Stamford-Mohegan Sun, and so on. A robust rail network based on ITT design principles could make all of these and many more connections at reasonable cost and speed.
The TGV network put France at the forefront of European intercity rail technology for decades. Early investments, starting in 1981 with high-speed tracks between Paris and Lyon, led to explosive growth in ridership throughout the 1980s, 90s, and 2000s. But since then, usage has stagnated. Domestic ridership in 2009 and 2010 was 100 million; so was domestic ridership in 2016, on a larger network. There was a 10% increase in 2017 when the line to Bordeaux opened, but in 2018 ridership stagnated again. In the late 2000s, there was more ridership on the TGV than on the intercity trains in Germany; now, German intercity trains approach 150 million annual riders, and are not far behind the TGV in passenger-kilometers, Germany running slower trains and thus averaging shorter trips.
I’ve heard a number of different explanations for why TGV ridership has not increased in the last ten years, many of which involve management; I, too, complain about managers who are recruited from the airline industry. But I submit that there’s a deeper, conceptual reason: the TGV is only workable for thick markets, mostly connecting Paris with a major provincial city. Trains run mostly nonstop, and there is no seat turnover. From the 1980s to the late 2000s, ridership rose as more cities were connected to Paris, but then those markets were mostly saturated, and new markets cannot be served adequately.
The TGV hit a wall about ten years ago. This is important, because as the busiest high-speed rail network outside of China and Japan, it has a lot of cachet. Politicians and rail planners propose programs that look much like the TGV network. This is of especial importance in the United Kingdom, which is replicating the TGV’s operating paradigm with the under-construction High-Speed 2 project; in the United States, the geography of the Northeast Corridor has meant that plans look more like the Japanese paradigm, which works better both in general and in the Northeast’s specific context.
In Japan, Germany, and the United States (by which I mean the Northeast Corridor), trains stop at many major cities on one route.
The fastest Shinkansen trains between Tokyo and Shin-Osaka have always stopped at Nagoya and Kyoto. Tokyo-Osaka passengers ride end to end, but many riders go between Tokyo or Osaka and Nagoya, so the seat turns over. Some of these trains continue west to Hakata, with such intermediate stops as Okayama and Hiroshima. The upshot is that the trains don’t just connect these cities to Tokyo, but also to one another. The size of Tokyo means there is demand for very high frequency to Shin-Osaka and decent frequency to Hakata; passengers on intermediate city pairs like Nagoya-Okayama or Kyoto-Hiroshima benefit from infrastructure that those city pairs could never justify on their own.
In Germany, intercity trains generally serve more than two major cities too. Like in France and unlike in Japan and the US, some major cities have stub-end stations, most notably Frankfurt; trains do not skip these cities, but rather serve them, reverse direction in about 5 minutes, and continue. Passengers may reserve seats but do not have to do so, so each seat has an electronic display showing for which portion of the trip it is free for the use of any passenger with an unreserved ticket.
France works by a different principle. Paris, Lyon, and Marseille are collinear, but trains do not serve all three cities. Trains from Paris to Lyon do not continue to Marseille; trains from Paris to Marseille rarely stop at the Lyon airport and never stop at Lyon Part-Dieu, which is on a branch from the Paris-Marseille mainline. There are separate trains between Lyon and Marseille, running generally hourly. Hourly frequency is workable on a line that takes about 1:40 end to end, but is not great.
At least Lyon and Marseille are on the same line coming out of Paris. Trains between Lyon and Lille, 3-3.5 hours apart on opposite sides of Paris, have service gaps of 2-2.5 hours most of the day. Lyon-Strasbourg trains on the LGV Rhin-Rhône lose money – the two cities alone do not have the ridership to fill trains, and there are no transfers with other cities nor larger intermediate cities than Mulhouse.
It’s too late for Paris 21
Berlin Hauptbahnhof is a through-station with service to cities all over Germany; every intercity train to Berlin serves Hauptbahnhof, regardless of which direction it comes from. This is common elsewhere in Germany, too. The second most important stub-end station, Stuttgart, is currently being replaced with an underground through-station at great cost, in a controversial project called Stuttgart 21. The most important, Frankfurt, long had plans for a similar through-station dubbed Frankfurt 21, and recently the federal government announced new plans for such a project.
Paris could have built a Paris 21, or Paris Hauptbahnhof, in the 1970s or 80s. When the city designed the RER, it ripped up Les Halles to build the Chatelet-Les Halles transfer point. The station is palatial: 25 meters underground, with 7 tracks and 4 platforms, 2 of which are 17 meters wide. This was so expensive that the Auber-Nation segment of the RER A, consisting of 6 km of tunnel and the Chatelet-Les Halles and Gare de Lyon RER stations, cost in today’s money around $750 million per km, a record that is yet to be surpassed in a non-English-speaking country.
Planning for the TGV only began in earnest in the late 1970s; the RER was constructed in the late 1960s and 70s, Les Halles opening in 1977. Perhaps the initial omission of intercity tracks was understandable. But the RER D opened in the early 1990s, and by then SNCF should have known it would have a national TGV network. It could have at the very least spent some money on having 2 platforms and 4 tracks at Les Halles dedicated to intercity trains, running through from Gare du Nord to Gare de Lyon. But it didn’t, and now there’s so much regional traffic that repurposing any part of Les Halles for intercity trains is impossible. Moreover, given the cost of the station in the 1970s, a future Paris 21 project would be unaffordable.
The TGV has to live with infrastructure decisions made 30 years ago. Given this reality, some of the kludges of the system today are understandable. And yet, even in outlying areas, there are no scheduled connections with either other TGVs or regional trains. Paris-Nice TGVs are timed to just miss TERs to Monaco and Ventimiglia. The Mâcon TGV station is located at just the wrong place for a transfer to a future extension of the LGV Rhin-Rhône south to Lyon. Other than Part-Dieu and Lille-Europe, major secondary cities do not have urban stations designed for through-service.
The contrast here is partly with German or Japanese practice: Japan built Shin-Osaka to enable through-service from east to west of Osaka without spending too much money tunneling into city center, and Germany serves Kassel at Wilhelmshöhe instead of at Hauptbahnhof since Hauptbahnhof is a stub-end station.
But the contrast is even more with the practice of smaller European countries. Switzerland and the Netherlands do not have anything as voluminous as Paris-Lyon, so they had to design their intercity rail networks around everywhere-to-everywhere travel from the start. Switzerland, too, had much less growth in the 2010s than in the 2000s, but ridership and p-km both grew, and are continuing to grow. What’s more, Switzerland has not tapped out its strongest markets: Lausanne, Luzern, and Geneva are still poorly integrated into the national timed transfer plan.
Getting it right from the start
France boxed itself into a corner. Its high-speed rail infrastructure is designed to connect provincial cities to Paris but not to one another. In some places, it’s possible to retrofit something more usable with the construction of new transfer points and the planning of better timetables. But elsewhere, as in Paris, it is too hard. This suggests that other countries that look to France as a model learn not only from the success of the TGV but also its more recent failures, and get it right from the start.
Any of the following lessons are useful to Britain and to other countries that are building large high-speed rail networks:
- Try to limit branching, to make sure city pairs have adequate frequency. This is especially important on shorter city pairs, such as London-Birmingham, planned to take 38 minutes, and Birmingham-Manchester, planned to take 40 minutes. Adding a few minutes to the trip time of through-trains is fine if it makes the difference between hourly and half-hourly frequencies, or even half-hourly and quarter-hourly frequencies.
- Place stations at good points for transfers to other trains. This includes trains on the same network, for which the best locations are branch points, and legacy trains, for which the best locations are major legacy stations and junctions. For example, the largest cities of the East Midlands – Nottingham, Derby, and Leicester – lie on a Y-shaped system, so it would be valuable to place a hub station at the node of the Y; the currently planned East Midlands Hub is 3.5 km north of the node, not on the leg of any of the three main cities.
- If there is a major city with service going in multiple directions, make sure it has a single through-station, even if constructing one requires a new tunnel. This is less relevant to Britain, since London is at the south end of the network, but is relevant to Italy, which needs to convert multiple urban terminals into through-stations, and Spain, which is doing so at Madrid and Barcelona already, at a fraction of the cost of Stuttgart 21.
- At short range, run trains as fast as necessary – that is, spend a lot of resources on getting trip times between major nodes to be just less than an hour, half an hour, or an hour and a half, but don’t worry too much about 55 vs. 40 minutes in most circumstances. This way, passengers can interchange at major nodes in a short time.
For a generation, the TGV was the envy of the rest of Europe. But it tapped out the strong markets that it was designed around, and now SNCF has its work cut out for it adapting to the needs of other city-to-city travel markets. Other big countries had better take heed and do it right from the start to avoid boxing themselves the way France did.
If Swiss planners were hired to design an intercity rail network for New York State, they might propose something that looks like this:
The trip times depicted on the map are a few minutes longer than intended, especially next to a terminus station like Niagara Falls, Watertown, and Ithaca. The depicted times are inclusive of turnaround time: the 45-minute Buffalo-Niagara Falls line is intended to take around 35 minutes in actual service, with 10-minute turnarounds.
Swiss planning is based on hourly and half-hourly timetables repeating all day on a clockface pattern: if a train leaves your station at 8:24 am, a train will leave your station at xx:24 all day, and if the line runs every half hour then also at xx:54. Moreover, at major nodes, trains are timetabled to arrive a few minutes before the hour and depart a few minutes after, letting passengers connect between different trains with minimal wait. To minimize transfer time and turn time, trains run as fast as necessary – that is, the state invests in higher-speed lines to ensure connections between major cities take a few minutes less than an hour. The Bahn 2000 program set up connections between Zurich, Basel, and Bern taking just less than an hour, with a few further connections elsewhere taking just less than an integer number of half-hours; the Bahn 2030 program aims to do the same with more cities all over the country.
The above map is an adaptation of the concept to New York State. I hope the explanation of how to adapt Switzerland to New York will be of interest to rail advocates elsewhere – the differences between the two geographies matter elsewhere, for example in Germany, France, or Sweden, or for that matter in California or New England.
There is no high-speed rail in Switzerland, unless one counts the mixed passenger and freight rail tunnels through the Alps, which allow 250 km/h passenger trains. The Bahn 2030 planning calls for a 2-hour trip time between Zurich and Lugano, a distance of about 170 km, even with heavy tunneling under all significant mountains; with so much tunneling, 1.5-hour trips are easy and even 1-hour trips are feasible with a bypass around Zug. Clearly, even when higher speeds are allowed, Swiss planning sticks to low- and medium-speed rail, targeting an average speed of about 120 km/h.
This works for Switzerland, a small country in which even Geneva is only 2:45 from Zurich. In New York, it does not. At the speed of upgraded legacy rail, comparable to the Northeast Corridor, the links on the above map along the high-speed spine would take 2 hours each rather than an hour. New York-Buffalo trains would take 6 hours, too long for most travelers, and New York-Rochester would take 5 hours, which is marginal at best. Trains doing New York-Albany in 2 hours could get fairly popular, but even that is long enough that cutting it to just less than an hour is feasible.
Trains are to run every half hour, with the exception of urban lines, namely Buffalo-Niagara Falls, Albany-Troy-Mechanicsville, and Utica-Rome, which run every 15 minutes. The reason for the half-hourly frequency is that all lines need it for either capacity or ridership. The lines either run to New York, which is so big it can easily fill a train every half hour and perhaps even every 15 minutes, or are quite short, so that running only every hour reduces ridership and it’s better to run shorter trains every 30 minutes.
With half-hourly timetables, a stub-end line can take an integer number of quarter-hours and not just half-hours. For example, Syracuse and Albany should have a pulse at :00 and :30 every hour. This in turn means that trains from Albany to Glens Falls can take 1:15, departing Albany just after :00 and :30, arriving at Glens Falls just before :15 and :45, turning back toward Albany just after :15 and :45, and then returning to Albany just before :00 and :30.
The only worry with quarter-hour trip times is that every cycle must sum up to an integer number of half-hours, not quarter-hours. Otherwise, some connections are broken, offset by 15 minutes. Thankfully, the only cycle on this map is New York-Albany-Syracuse-Binghamton-New York, which takes 7 hours.
Syracuse regional rail
Syracuse is depicted as having the most expansive regional rail network in the state, despite being the smallest of Upstate New York’s four major metropolitan areas. The reason is that the goal of the planned network is to provide intercity rather than local service. Rochester has some useful urban lines, for example to Freeport or northwest to the lakefront, but they are so short that they should run every 10 or 15 minutes and not every half hour. However, Rochester has no significant independent towns within an hour or so by rail, and thus there are no timed connections there. In contrast, Syracuse is located right between Watertown, Oswego, Auburn, and Cortland with its connection onward to Ithaca.
The Syracuse system is intended to be fully on the RegionalBahn side of the S-Bahn vs. RegionalBahn divide. The shared segment between Syracuse and the split between the lines to Oswego and Watertown is not meant to overlay to run frequent urban service. Instead, trains should tailgate, followed by a gap of nearly half an hour. Syracuse-bound trains may well call at Liverpool at :20 and :22, arriving at Syracuse at :25 and :27 to exchange passengers with other trains and then continue south, one of Oswego and Watertown paired with Cortland and Binghamton and the other terminating. If north-south S-Bahn service is desired, trains should be slotted in between the intercity trains.
The map depicts greenfield alignments for the high-speed line except on the approaches to New York and Toronto, and legacy alignments for the low-speed lines.
As in Switzerland, the low-speed lines do not necessarily slavishly adhere to legacy alignments. However, the deviations are not the same. Switzerland uses bypasses and tunnels to speed lines up. In New York, the main mechanisms to speed up lines are electrification, track renewal, and higher superelevation. Tunnels are too expensive for the population density of Upstate New York. I can see some bypasses, potentially getting Syracuse-Cortland and Cortland-Binghamton down to 30 minutes each, but none of the Upstate cities off the high-speed line is big enough to justify major civil works.
The one depicted bypass on a blue-colored line is the use of the Boonton Branch in New Jersey to offer an express bypass around the Morristown Line with its dense station spacing. This requires some additional tracks on busy urban regional lines as well as a short tunnel in Paterson, but New York is big enough that investing in faster service to Dover, Delaware Water Gap, and Scranton is worth it.
Upstate, the important deviations involve restoring old tracks, including between Cortland and Ithaca and within some town centers. Corning and Glens Falls both have disused rail alignments serving their centers better than the existing freight lines. But most importantly, Syracuse has an underused freeway running east-west through its center, which I am assuming replaced with a rail line. This is not a new idea – Syracuse is already removing a branch of the freeway, which should be used for a rail connection toward Binghamton, and even the mainline is a vestige of when midcentury planners thought Upstate cities would keep growing. The current Syracuse station is at an inconvenient location, making rail realignment a good use of the right-of-way.
New York State is much more integrated with its neighbors than Switzerland – it’s all the same country. There is extensive interstate travel, and rail planning must accommodate this. Forget the Deutschlandtakt – an Americatakt would be the most complex rail plan in a developed country out of sheer size. Thankfully, the connections depicted on the New York State plan accommodate interstate travel fairly well.
Going east, there are connections to Vermont, Massachusetts, and Connecticut. Albany-Boston can be done in around an hour, which makes for a half-hour takt connection between Albany and Springfield and 45 minutes minus turnaround between Springfield and Boston. Springfield-New Haven is 30 minutes by high-speed rail or 45 minutes by fast legacy rail, both with a stop at Hartford and few to no others; Springfield can then get its own small regional rail line toward Northampton (with some urban overlays for an S-Bahn) and Greenfield. Vermont can get a slow line to Rutland, and/or a fast line to Burlington continuing to Montreal; thence New York-Montreal and Boston-Toronto trains can be timed to connect at Albany, with New York-Toronto trains slotted in between, timed to connect only to the more frequent urban lines like Buffalo-Niagara Falls.
Going south, New York is separated from Pennsylvania by the northern reach of the Appalachians, called the Southern Tier in New York and the Northern Tier in Pennsylvania. This area had many coal mines in the 19th century and as a result has many legacy rail lines, but they are curvy and connect villages. But Scranton is a significant city on a nice line with Allentown and Philadelphia; unfortunately, the Philadelphia-Allentown line stretches via Reading and the Allentown-Scranton line is hilly and curvy, justifying some greenfield construction with some tunneling near the northern end.
Finally, going west, the I-90 route serves Erie and the Midwest. But this is a plausible high-speed rail connection toward Chicago, and so no low-speed interface is needed within the state. Erie could get a line to Youngstown and Pittsburgh, but it would be slower than connecting between high-speed trains in Cleveland; the largest city between Erie and Youngstown is Meadsville, population 13,000.
The cost of the high-speed spine is considerable, but if New York can keep it to the level of France (around $25 million/km), or even Germany (around $35 million/km), the benefits should exceed the costs. New York is huge, and even though nothing in Upstate New York is, the combined populations of Syracuse, Rochester, and Buffalo would add up to a big French or German city. And then there is Toronto at the other end, anchoring everything.
The low-speed lines should be quite cheap. Track renewal in Germany is around $1 million per single-track kilometer; at the frequency envisioned, all the low-speed lines can stay single-track with passing segments. Electrification is maybe $1.5 million per kilometer in Israel, despite a lawsuit that delayed the project by three years.
Is this feasible?
Technically, all of this is feasible. Good transit advocates in the Northeastern United States should push elected officials at the federal and state levels to quickly plan such a system and aim to begin construction early this decade. Bahn 2000 was supposed to take the 1990s to be built, but was delayed to 2004; this is a bigger program but can still happen by 2030 or so.
The trip times, frequencies, and coverage chosen for the map are deliberately conservative. It’s possible to squeeze higher speed at places, and add more branches to smaller towns, like Rochester-Niagara Falls or Buffalo-Jamestown. Bahn 2000 is followed up with Bahn 2030 or Bahn 2035, and likewise rail improvements can accrete in the United States. But as a starter system, this is a solid network connecting all large and nearly all small cities in New York State to one another with maximum convenience and minimum hassle. I hope state planners take heed and plan to invest soon.
New York City Transit has just released its draft redesign for the Queens bus network. It’s a further-reaching reform than what was planned for the Bronx. I’m still seriously skeptical about a number of aspects, but this redesign is genuinely a step forward. The required changes are for the most part tweaks, with just one big change in concept.
What’s in the redesign?
The redesign goes over the local and express bus routes in Queens. I am not going to look at the changes to the express buses, which are not an important part of the network anyway; Queens has a total of 674,000 local bus passengers per weekday and only 15,000 express passengers.
The changes to the local buses include a from-scratch redesign of the network; four new color-coded brands for the local buses; stop consolidation depending on color coding, of which the tightest spacing proposed is 400 meters; and a list of priority corridors where buses are to get dedicated lanes. The scope is only the Queens buses, but there are some new Brooklyn connections: the Metropolitan and Flushing Avenue routes (the new QT3, QT4) keep running through, as they do today, but the Myrtle Avenue route, the current Q55 and new QT55, stops at Ridgewood with a forced transfer to the Brooklyn Myrtle Avenue route.
The four color-coded brands are an unusual, though not unheard of, system. There are four distinct brands among the redesigned Queens buses: blue, red, purple, green. Blue is essentially select bus service, retaining the long stop spacing (“over a mile”), potentially intersecting some bus routes without a transfer; the point is to connect high-demand areas like Flushing with Jamaica. The other three are for various regular local routes. Red routes are distinguished exclusively in having slightly wider stop spacing, 660 meters versus 450 for purple and 400 for green, but otherwise look similar on the network map. Purple and green routes are distinguished in that purple routes are branded for neighborhoods far from the subway and intended to get people from outlying points to subway stations.
What’s good about it?
Stop consolidation is important and I’m glad to see it get play in New York. The choice of interstation across the non-blue routes is solid and close enough to the theoretical optimum that the exact value should depend on ensuring every intersection has an interchange rather than on squeezing a few extra seconds of door-to-door trip time for non-transfer passengers.
The same goes for the decision to designate 21 corridors as top priorities for dedicated bus lanes. The plan does not promise bus lanes on all of them, since the ultimate decision is in the hands of NYCDOT and not the state-owned MTA/NYCT. But it does the best it can, by putting the proposal front and center and announcing that these corridors should be studied as candidates for bus priority. Most of the important streets in Queens are on the list; the only glaring omissions are Union Turnpike, Myrtle, and Metropolitan.
The above two points are not strictly about the redesign. This is fine. When Eric Goldwyn and I tried estimating the benefits of our Brooklyn bus redesign plan, we found that, taking speed, access time, and frequency into account, the redesign itself only contributed 30% of the overall improvement. Stop consolidation and bus lanes contributed 30% each, and off-board fare collection 10%. The Queens plan at the very least has stop consolidation, off-board fare collection as planned when the OMNY smartcard is fully rolled out, and partial use of bus lanes.
But the bus network as redesigned has notable positive features as well. There’s greater reliance on the full network, for one. The JFK AirTrain is free for passengers boarding at Lefferts Avenue or Federal Circle rather than at the subway connection points at Jamaica and Howard Beach, and so the Lefferts Avenue route to JFK, the current Q10 and future QT14, stops at the AirTrain station instead of going all the way to the terminals.
Elsewhere, the bus network is more regular, with fewer bends. The network does not assume away the borough’s important nodes: you can still figure out where Flushing and Jamaica are purely from looking at the map. But it does offer some routes that bypass these nodes for crosstown traffic, for example the redesigned QT65, straightening the current Q65.
What’s bad about it?
The four-color system is just bad. The blue routes are understandable but still bad: they split frequency, so that passengers living next to the local stations on shared routes like Main Street get poor service. The red-purple-green distinction is superfluous – the map really does not make it clear how a red route differs from the others, and the purple and green routes are really the same kind of local bus, just one with a distinguished node at a subway stop and one where there may be multiple distinguished nodes.
The frequencies offered are also weak. Some routes are proposed to run every 8 minutes all day, namely QT route numbers 6, 10, 11, 14, 15, 16, 17, 19, 20, 32, 52, 55, 58, 66, 69, 70. Exactly one is proposed to run more frequently, the QT44 every 5 minutes. The rest run every 10-12 minutes or worse. On weekends, even the 8-minute routes drop to 10-15 minutes. Many routes are quite peaky and there’s no easy distinction between routes for which the report proposes an all-day headway (including all the 8-minute ones above) and ones for which the report proposes separate peak and base headways; the purple routes in general look somewhat peakier than the others, but it’s not a consistent distinction.
If the frequencies are weak, then it means that either the buses are too slow, or there are too many route-km to split a fixed service-hours budget across. NYCT mistakenly thinks that bus costs scale with service-km rather than service-hours, so the planned speedups can in fact be spent on more frequency, but it’s not enough to create a vigorous frequent network. Some pruning is needed; overall the network seems very dense to me, even in areas with decent subway coverage.
A few individual routes are weak too – I don’t think the QT1 idea, paralleling the Astoria Line on 21st Street and then the G train to Downtown Brooklyn, is a good idea. There are two more north-south routes running through to Williamsburg, where the relevant buses are pretty weak and pruning is advisable in order to redeploy service-hours to areas with more demand. If there’s somehow money that can only be spent on north-south service through Williamsburg, it’s better to increase frequency on the G train, which is faster than any bus could ever be.
Is this redesign valuable, then?
Yes! Between the stop consolidation, partial installation of bus lanes, and some of the aspects of the new network, the proposal looks like a two-thirds measure, at worst. It can’t be a full measure because there are serious drawbacks to the plan, not just on the level of details (i.e. too much service to Williamsburg) but also on the conceptual level of the four distinct brands. But it is a noticeable improvement over the current system, and I expect that if it is implemented, even with its many current flaws, then Queens will see a serious increase in bus patronage.
Moreover, the flaws in the plan are not inherent to it. If someone showed me the bus map without the color coding, just with stops and frequencies, I would not even notice the red-green-purple distinction. The blue routes I would notice, and suggest be reduced to the usual stop spacing of everything else; but the others, I wouldn’t. So even the most fundamentally bad part of the plan can be jettisoned while retaining all the good. Everything else is a tweak, and I expect that tweaks will happen one way or another.
Right now comes the community meetings stage, in which existing riders who have too much time will yell, and potential riders who don’t currently take the bus because it’s too slow don’t show up at all. The plan will be tweaked, and the tweaks may well make it worse rather than better. But what good transit activists in New York say matters, and so far the reaction should be positive, demanding certain changes but keeping the gist of the redesign.
There’s a thread on Twitter by Stephen Smith bringing up Zurich’s S-Bahn as an alternative to extensive metro tunneling. It reminded me of something I’d been meaning to write about for a long time, about how S-Bahn tunnels, in Zurich and elsewhere, include not just the bare minimum for through-running but also strategic tunneling elsewhere to reach various destinations not on the mainline. Zurich’s S-Bahn includes about 19 km of tunnel built since the 1960s, which is similar per capita to the amount of tunneling built for the Washington Metro.
Such tunneling is important to ensure a regional rail network reaches destinations off the mainlines. Even cities with metro systems need to understand this as long as they have some mainline rail serving suburban destinations. For example, in the Center of Israel, Tel Aviv is getting a subway-surface light rail network, but outside the urban core rail transport will remain dominated by Israel Railways service; as Israel Railways avoids many city centers, such as Netanya, short strategic tunnels are critical.
Tunnels in Zurich
The core of the Zurich S-Bahn is three city center tunnels: the 2 km Käferberg Tunnel from Oerlikon to Hardbrücke, the 7 km combination of the Hirschengraben Tunnel and the Zürichberg Tunnel from Hauptbahnhof to the Right Bank of Lake Zurich and points northeast, and the 5 km Weinberg Tunnel from Hauptbahnhof to Oerlikon and points north. The Käferberg Tunnel is from the 1960s, the Hirschengraben and Zürichberg Tunnel opened in 1989-1990 as the core of the Zurich S-Bahn, and the Weinberg Tunnel opened in 2014 as a second S-Bahn route to add more capacity.
These 14 km of tunnel look like any standard picture of regional rail tunneling. However, Zurich has in addition built a 5 km tunnel for a loop to the airport. Without this tunnel, no regional or intercity rail service to the airport would have been possible, as the airport was at a distance from the mainline; only trams could have served the airport then.
In addition to these 19 km, there is some talk of building an additional tunnel of 7-10 km on the Zurich-Winterthur Line, called the Brüttener Tunnel, to speed up service between these two cities.
Tunnels on other regional rail systems
In Paris, the RER consists not just of legacy rail track and city center tunnels, but also outlying tunnels reaching new destinations. The RER B connection to Charles de Gaulle Airport is new construction, opening in 1976 as a commuter line just before the RER opened and incorporated it as a branch. It’s a mix of above- and underground construction, totaling 5.5 km of tunnel. Two more key RER lines, at both ends of the RER A, are new: the branch to Cergy, which opened between 1979 and 1994 and has 3 km of tunnel, and the branch to Marne-la-Vallée, which opened in stages starting on the same day as the RER A’s central tunnel and continuing until reaching its terminus in 1992.
All three new RER branches are busy. They have to be – if there weren’t so much demand for them, it would have been financially infeasible to build them and those areas would have had to make do with a bus connection to the existing mainlines. The Marne-la-Vallée branch carries about two thirds of the eastern branch ridership of the RER A, making it most likely the busiest single rail branch in Europe.
In London, the regional rail network is less modern than in Paris, Zurich, and other cities with extensive development of new tunnels. Nonetheless, the Crossrail plans do include a short outlying tunnel reaching Heathrow Airport. Moreover, one of the two eastern branches of the mainline has the characteristics of an outlying tunnel, namely the branch to Canary Wharf. Canary Wharf is only 5 km from the City of London and the tunnel connecting to it is contiguous with the central tunnel, but the branch is not really about improving connections to onward suburbs. Where La Défense was always on the way to western suburbs on the RER, Canary Wharf is only on the way to Abbey Wood. There are proposals among area railfans to extend this branch much farther to the east, but no official plans that I know of. In the currently planned paradigm for Crossrail, Canary Wharf is purely a destination.
In Munich, there is a new line toward the airport, with some tunneling on airport grounds as well as at two intermediate suburban stations. There is also a short above-ground spur connecting the airport to the western side of the S-Bahn, giving it two different routes to city center. Finally, there is a short tunnel slightly to the west of the main trunk tunnel to better connect S7 to the mainline.
Why are airports so prominent on this list?
The concept of using strategic tunnels to build new spurs and loops to connect mainlines to new destinations has nothing to do with airports. And yet, so many of these spurs connect to airports: Charles de Gaulle, Heathrow, Zurich, Munich. There are many more such examples, on regional or intercity lines: Schiphol, Arlanda, Ben-Gurion, soon-to-be Berlin-Brandenburg, Barajas. Why is that?
The answer is that the purpose of a spur or loop is to connect to a destination off the mainline. European cities for the most part developed around the railway or metro line. Virtually every important destination in London is on a legacy railway because during the city’s 19th and early 20th century growth period, the railway was the only way to get to Central London. Airports are consistent exceptions because they’re so land-intensive that it’s hard to site them near existing railways.
Where non-airport destinations somehow had to be developed away from the mainline, they’re attractive targets for spurs as well. Canary Wharf sits on the site of a disused dock, which generated some freight rail traffic but little demand for passenger rail. Cergy is one of several new towns built around Paris to act as suburban growth nodes, together with Marne-la-Vallée and Évry (served on a loop of the RER D).
In smaller cities than Paris and London, suburban growth often came together with a metro line. In Stockholm, the Metro was planned together with public housing projects, so many of the Million Program projects are right next to stations, facilitating high public transportation usage. There’s usually no need to build many new regional rail spurs, because such sites are close enough to the center for metro service to be quick enough.
The situation of regional rail in Israel
In Israel, urban development has ignored the railway almost entirely. The colonial network was weak and barely served the state’s travel needs. Investment was minimal, as the state’s political goals were population dispersal and Judaization of peripheral areas rather than efficient transportation. Towns were built around the road network, connected to one another by bus since people were too poor to afford cars.
Rail revival began in the early 1990s with the opening of the Ayalon Railway, providing through-service between points north and south of Tel Aviv. In the generation since, ridership has grown prodigiously, albeit from low initial levels, and the state has built new lines, with an ongoing project to electrify most of the passenger network. However, since the cities came first and the trains second, the new lines do not enter city centers, but rather serve them peripherally near the highway, often surrounded by parking.
Thus, Netanya’s train station is located to the east of the city’s built-up area, on the wrong side of the Route 2 freeway. Ashdod’s train station is on the periphery at a highway interchange, well to the east of city center. Ashkelon’s station is on the eastern margin. The under-construction line through Kfar Saba and Ra’anana passes just south of the built-up area.
In all of these cases, doing it right would require, or would have required, just short, strategic elevated or underground lines:
- Netanya is at the northern end of the Tel Aviv commuter rail network, and so it can easily be served by a spur. The existing station can be retained as a junction for intercity rail service, but building a commuter rail spur would not compromise frequency. Such a spur would require no more than 2 km of tunnel.
- In Ashdod and Ashkelon, there are north-south arterials that are so wide, 50-60 meters, that they could host cut-and-cover subways, effectively moving the line to the west to serve those cities better. In Ashdod there is a decision between going under B’nai Brith, which offers a more convenient through-route, and Herzl, which is more central but requires some boring at the southern end of the city.
- In Kfar Saba and Ra’anana, about 8 km of tunnel under Weizmann and Ahuza are needed, and could potentially be done cut-and-cover as well, but these streets are 30 meters rather than 50 meters wide. Such a route would replace the under-construction combination of a freeway and railway.
- In Rishon LeZion, a 6km route, not all underground, is needed to connect Rishonim with Moshe Dayan via city center and the College of Management rather than via the under construction freeway route avoiding these destinations.
Unfortunately, so far the state’s investment plans keep skirting city centers. It serves them with a cars-and-trains paradigm, which assumes the rail passenger is driving or riding a bus to the train station, never mind that in that case it’s more convenient to drive all the way to one’s destination. This suppresses ridership; not for nothing, the busiest station outside metropolitan centers is Rehovot, with 2.1 million annual entries, and not Ashdod, which is second with 1.9 million. Ashdod is a city of 220,000 and Rehovot one of 140,000, but Rehovot’s station is far more walkable. Were Ashdod not poor, few people would use the station at all – they’d all just drive.
In England and Wales, 15.9% of workers get to work on public transport, and in France, 14.9% do. In Canada, the figure is close: 12.4%, and this is without a London or Paris to run up the score in. Vancouver is a metro region of 2.5 million people and 1.2 million workers, comparable in size to the metropolitan counties in England and to the metro area of Lyon; at 20.4%, it has a higher public transport modal share than all of them, though it is barely higher than Lyon with its 19.9% share. Calgary, Ottawa, Edmonton, and Winnipeg are likewise collectively respectable by the standards of similar-size French regions, such as the departments of Bouches-du-Rhône (Marseille), Alpes-Maritimes (Nice), Gironde (Bordeaux), Haute-Garonne (Toulouse), and Bas-Rhin (Strasbourg).
As a result, Jarrett Walker likes telling American cities and transit agencies to stop envying Europe and start envying Canada instead. Canada is nearby, speaks the same language, and has similar street layout, all of which contribute to its familiarity to Americans. If Europe has the exotic mystique of the foreign, let alone East Asia, Canada is familiar enough to Americans that the noticeable differences are a cultural uncanny valley.
And yet, I am of two minds on this. The most consistent transit revival in Canada has been in Vancouver, whose modal share went from 14.3% in 1996 to 20.4% in 2016 – and the 2016 census was taken before the Evergreen extension of the Millennium Line opened. TransLink has certainly been doing a lot of good things to get to this point. And yet, there’s a serious risk to Canadian public transport in the future: construction costs have exploded, going from Continental European 15 years ago to American today.
The five legs of good transit
I was asked earlier today what a good political agenda for public transportation would be. I gave four answers, like the four legs of a chair, and later realized that I missed a fifth point.
- Fuel taxes and other traffic suppression measures (such as Singapore and Israel’s car taxes). Petrol costs about €1.40/liter in Germany and France; diesel is cheaper but being phased out because of its outsize impact on pollution.
- Investment in new urban and intercity lines, such as the Madrid Metro expansion program since the 1990s or Grand Paris Express. This is measured in kilometers and not euros, so lower construction costs generally translate to more investment, hence Madrid’s huge metro network.
- Interagency cooperation within metropolitan regions and on intercity rail lines where appropriate. This includes fare integration, schedule integration, and timetable-infrastructure integration.
- Urban upzoning, including both residential densification in urban neighborhoods and commercialization in and around city center.
- Street space reallocation from cars toward pedestrians, bikes, and buses.
We can rate how Canada (by which I really mean Vancouver) does on this rubric:
- The fuel tax in Canada is much lower than in Europe, contributing to high driving rates. In Toronto, gasoline currently costs $1.19/liter, which is about €0.85/l. But Vancouver fuel taxes are higher, raising the price to about $1.53/l, around €1.06/l.
- Canadian construction costs are so high that investment in new lines is limited. Vancouver has been procrastinating building the Broadway subway to UBC until costs rose to the point that the budget is only enough to build the line halfway there.
- Vancouver and Toronto both have good bus-rapid transit integration, but there is no integration with commuter rail; Montreal even severed a key commuter line to build a private driverless rapid transit line. In Vancouver, bus and SkyTrain fares have decoupled due to political fallout from the botched smartcard implementation.
- Vancouver is arguably the YIMBYest Western city, building around 10 housing units per 1,000 people every year in the last few years. Toronto’s housing construction rate is lower but still respectable by European standards, let alone American ones.
- There are bike lanes but not on the major streets. If there are bus lanes, I didn’t see any of them when I lived in Vancouver, and I traveled a lot in the city as well as the suburbs.
Vancouver’s transit past and future
Looking at the above legs of what makes for good public transport, there is only one thing about Canada that truly shines: urban redevelopment. Toronto, a metro area of 6 million people, has two subway mainlines, and Montreal, with 4 million people, has 2.5. Vancouver has 1.5 lines – its three SkyTrain mainlines are one-tailed. By the same calculation, Berlin has 6.5 U- and 3 S-Bahn mainlines, and Madrid has 2 Cercanías lines and 7 metro lines. Moreover, high construction costs and political resistance from various GO Transit interests make it difficult for Canadian cities to add more rapid transit.
To the extent Vancouver has a sizable SkyTrain network, it’s that it was able to build elevated and cut-and-cover lines in the past. This is no longer possible for future expansion, except possibly toward Langley. The merchant lawsuits over the Canada Line’s construction impacts have ensured that the Broadway subway will be bored. Furthermore, the region’s politics make it impossible to just build Broadway all the way to the end: Surrey has insisted on some construction within its municipal area, so the region has had to pair half the Broadway subway with a SkyTrain extension to the Langley sprawl.
Put in other words, the growth in Vancouver transit ridership is not so much about building more of a network, but about adding housing and jobs around the network that has been around since the 1980s. The ridership on the Millennium and Canada Lines is growing but remains far below that on the Expo Line. There is potential for further increase in ridership as the neighborhoods along the Canada Line have finally been rezoned, but even that will hit a limit pretty quickly – the Canada Line was built with low capacity, and the Millennium Line doesn’t enter Downtown and will only serve near-Downtown job centers.
Potemkin bus networks
When Jarrett tells American cities to envy Canada, he generally talks about the urban bus networks. Toronto and Vancouver have strong bus grids, with buses coming at worst every 8 minutes during the daytime off-peak. Both cities have grids of major streets, as is normal for so many North American cities, and copying the apparent features of these grids is attractive to American transit managers.
And yet, trying to just set up a bus grid in your average American city yields Potemkin buses. Vancouver and Toronto have bus grids that rely on connections to rapid transit lines. In both cities, transit usage is disproportionately about commutes either to or from a city core defined by a 5 kilometer radius from city hall. Moreover, the growth in public transport commuting in both cities since 1996 has been almost exclusively about such commutes, and not about everywhere-to-everywhere commutes from outside this radius. Within this radius, public transportation is dominated by rail, not buses.
The buses in Toronto and Vancouver have several key roles to play. First, as noted above, they connect to rapid transit nodes or to SeaBus in North Vancouver. Second, they connect to job centers that exist because of rapid transit, for example Metrotown at the eastern end of Vancouver’s 49. And third, there is the sui generis case of UBC. All of these roles create strong ridership, supporting high enough frequency that people make untimed transfers.
But even then, there are problems common to all North American buses. The stop spacing is too tight – 200 meters rather than 400-500, with frequency-splitting rapid buses on a handful of very strong routes like 4th Avenue and Broadway. There is no all-door boarding except on a handful of specially-branded B-line buses. There are no bus lanes.
One American city has similar characteristics to Toronto and Vancouver when it comes to buses: Chicago. Elsewhere, just copying the bus grid of Vancouver will yield nothing, because ultimately nobody is going to connect between two mixed-traffic buses that run every 15 minutes, untimed, if they can afford any better. In Chicago, the situation is different, but what the city most needs is integration between Metra and CTA services, which requires looking at European rather than Canadian models.
Is Canada hopeless?
I don’t know. The meteoric rise in Canadian subway construction costs in the last 15 years has ensured expansion will soon grind to a halt. Much of this rise comes from reforms that the Anglosphere has convinced itself improve outcomes, like design-build and reliance on outside consultants; in that sense, the US hasn’t been copying Canada, but instead Canada has been copying the US and getting American results.
That said, two positive aspects are notable. The first is very high housing and commercial growth in the most desirable cities, if not in their most exclusive neighborhoods. Vancouver probably has another 10-20 years before its developable housing reserves near existing SkyTrain run out and it is forced to figure out how to affordably expand the network. Nowhere in Europe is housing growth as fast as in Metro Vancouver; among the cities for which I have data, only Stockholm comes close, growing at 7-8 net units per 1,000 people annually.
Moreover, with Downtown Vancouver increasingly built out, Vancouver seems to be successfully expanding the CBD outward: Central Broadway already has many jobs and will most likely have further commercial growth as the Millennium Line is extended there. Thus, employers that don’t fit into the Downtown Vancouver peninsula should find a home close enough for SkyTrain, rather than hopping to suburban office parks as in the US. Right now, the central blob of 100 km^2 – a metric I use purely because of limitations on French and Canadian data granularity – has a little more than 30% of area jobs in Vancouver, comparable to Paris, Lyon, New York, Boston, and San Francisco, and ahead of other American cities.
The second aspect is that Canadians are collectively a somewhat more internationally curious nation than Americans. They are more American than European, but the experience of living in a different country from the United States makes it easier for them to absorb foreign knowledge. The reaction to my and Jonathan English’s August article about Canadian costs has been sympathetic, with serious people with some power in Toronto contacting Jonathan to figure out how Canada can improve. The reaction I have received within the United States runs the gamut – some agencies are genuinely helpful and realize that they’ll be better off if we can come up with a recipe for reducing costs, others prefer to obstruct and stonewall.
My perception of Canadian politics is that even right-populists like Doug Ford are more serious about this than most American electeds. In that sense, Ford is much like Boris Johnson, who could move to Massachusetts to be viceroy and far improve governance in both Britain and Massachusetts. My suspicion is that this is linked to Canada’s relatively transit-oriented past and present: broad swaths of the Ontarian middle class ride trains, as is the case in Outer London and the suburbs of Paris. A large bloc of present-day swing voters who use public transport is a good political guarantee of positive attention to public transport in the future. American cities don’t have that – there are no competitive partisan elections anywhere with some semblance of public transportation.
These two points of hope are solid but still run against powerful currents. Toronto really is botching the RER project because of insider obstruction and timidity, and without a strong RER project there is no way to extend public transportation to the suburbs. Vancouver is incapable of concentrating resources where they do the most good. And all Canadian cities have seen an explosion in costs. Canadians increasingly understand the cost problem, but it remains to be seen whether they can fix it.
Marron just published my and Eric Goldwyn’s Brooklyn bus redesign proposal (with many thanks to Juliet Eldred for doing the graphics and design). The substance isn’t really changed from what we discussed last year. The delay in publication has had a few causes, of which I believe the biggest is that I completely missed that the links to many of the references in the lit review were dead and thus could not be typeset.
Instead of retyping an old blog post, I want to emphasize a few things that have come up in the last year. Some are specific to New York, others more general within the US. The idea of a bus redesign, introduced to the American discourse by Jarrett at the beginning of this decade, has gotten steadily more popular, and New York is beginning its own process, starting with the Bronx; in that context, it’s worthwhile pointing out specifics that Eric and I have learned from the Brooklyn process.
The redesign is a process, not a one-and-done program
Cities change. The point of a bus redesign is to let the bus network reflect the city of today and not that of when bus routes were set, typically when the streetcars were removed in the postwar era. The upshot is that the city can expect to change in the future, which means further bus redesigns may be necessary.
Instead of letting bus networks drift away from serving the city as is and doing a big redesign once in a generation, cities should change buses on an ongoing basis. American transit agencies are learning the principles of bus redesign this decade. They can and should use these principles for forward planning, tweaking bus routes as needed. Any of the following changes can trigger small changes in bus service:
- New development
- Shifts in commuting patterns even without new development
- Changes in traffic patterns
- Changes in the urban rail network
- Long-term changes in driver labor, maintenance, etc.
- Changes in bus technology, such as ride quality, dispatching, or pollution levels
In New York, the biggest ongoing change is probably the urban rail network. There are no subway extensions planned for Brooklyn, but there is expansion of subway accessibility, which changes the optimal bus network since some buses, like the B25 and B63, have no reason to exist if the subway lines they parallel are made accessible. There has been extensive activism about priorities here. To its credit, the MTA is accelerating accessibility retrofits, even though construction costs are extremely high.
New York’s current redesign process is flawed
Eric and I have heard negative feedback from various people involved in the process. Some are planners. One is a community activist, enough of a railfan and busfan not to NIMBY changes for the sake of NIMBYism, but nonetheless disaffected with how the Bronx redesign went.
As far as I can tell, the problem with the current process is that it’s too timid. In the Bronx, this timidity is understandable. The borough’s bus network is mostly good enough. The most important change in the Bronx is to speed up the buses through off-board fare collection, stop consolidation, bus lanes on main streets, and conditional signal priority, and plug the extra speed into higher frequency.
The MTA treats it as part of a separate process – select bus service (“SBS”) – and even though planning these two aspects separately is workable, the MTA does not understand that they are related and that speedups provide crucial resources for higher frequency. The problem here is with operating cost estimation. Like the other American agencies where I’ve asked, the MTA assumes bus costs scale with service-km, and thus higher speeds don’t change frequency. In reality, bus costs, dominated by driver wages, scale with service-hours. Higher speeds can be plugged one-to-one into higher frequency. In Brooklyn, only 30% of the benefits we estimate come from changing the network, and the other 70% come from speeding up the buses.
But Brooklyn is not the Bronx. The Bronx is largely good enough, in ways Brooklyn isn’t. Brooklyn is not terrible, but the bus network has too many circuitous or duplicative routes. Eric and I have consolidated about 530 km of bus route down to 350, without any of the coverage vs. ridership tradeoffs common to areas with less isotropic population density than Brooklyn. The MTA needs to be bolder in Brooklyn, and even bolder than that in Queens, if the redesign is to succeed.
The 14th Street bus lane
Eric and I encountered some political resistance to the idea of mass installation of bus lanes. Local interests listen to people with local connections, who are usually drivers. Transit riders are disproportionately riding to city center jobs, and have citywide rather than local political identities. When I went to an Open New York meeting, people began with a round of introductions in which people say their names and where they live, and the about 20 attendees represented maybe 15 different city neighborhoods. The upshot is that like Open New York’s mission of building more housing, the mission of diverting scarce street space from drivers to bus riders is best done on a citywide rather than street-by-street basis.
There is some hope of such a transformation happening. The bus lane on 14th Street survived a nuisance lawsuit, and ridership rose 17% almost immediately after it opened. The success is stark enough that a citywide increase in installation is plausible. City council speaker Corey Johnson promised to install 48 km of bus lane per year were he to be elected mayor, which is too passive but could do some good on the busiest routes.
When you ride a subway train, and the train decelerates to its station, you feel your body pulled forward, and your muscles tense to adjust, but then when the train reaches a sudden stop, you are suddenly flung backward, since you are no longer decelerating, but your muscles take time to relax and stop fighting a braking that no longer exist. This effect is called jerk, and is defined to be change in acceleration, just as acceleration is change in speed and speed is change in position. Controlling jerk is crucial for a smooth railway ride. Unfortunately, American mainline rail is not good at this, leading to noticeable jolts by passengers even though speed limits on curves and acceleration rates are very conservative.
This is particularly important for speeding up mainline trains around New York and other legacy cities in the US, like Boston. Speeding up the slowest segments is more important than speeding up the fastest ones; my schedules for New York-New Haven trains, cutting trip times from 2:09 to 1:24, save 4 minutes between Grand Central and 59th Street just through avoiding slowdowns in the interlocking. The interlocking is slow because the switches have very conservative speed limits relative to curve radius (that is, lateral acceleration), which in turn is because they are not designed with good lateral jerk control. The good news is that replacing the necessary infrastructure is not so onerous, provided the railroads know what they need to do and avoid running heavy diesel locomotives on delicate infrastructure.
Spirals and jerk
In practice, the worst jerk is usually not forward or backward, except in the last fraction of a second at the end of acceleration. This is because it takes about a second for train motors to rev up, which controls jerk during acceleration. Rather, the worst is sideways, because it is possible to design curves that transition abruptly from straight track, on which there is no lateral acceleration, to curved track, on which there is, in the form of centrifugal force centripetal force.
To reduce jerk, the transition from straight track to a circular arc is done gradually. There are a number of usable transition curve (see Romain Bosquet’s thesis, PDF-p. 36), but the most common by far is called the clothoid, which has the property of having constant change in curvature per unit of arc length – that is, constant jerk. Different countries have different standards for how long the clothoid should be, that is what the maximum lateral jerk is. Per Martin Lindahl’s thesis, the limit in Sweden is 55 mm/s (PDF-p. 30) and that in Germany is 69.44 mm/s (PDF-p. 38), both measured in units of cant deficiency; in SI units, this is 0.367 m/s^3 and 0.463 m/s^3 respectively. In France, the regular limit is 50 mm/s (Bosquet’s thesis, PDF-p. 35), that is 0.333 m/s^2, but it is specifically waived in turnouts.
Track switches are somehow accepted as sites of very high jerk. A presentation about various technical limits in France notes on p. 106 that in switches (“appareils de voie” or “aiguilles” or “aiguillages,” depending on source, just like “switch” vs. “turnout” in English), the jerk can be increased to 100 and even 125 mm/s. On p. 107 it even asserts that in exceptional circumstances, abrupt change in cant deficiency of up to 50 mm on main track and 100 on the diverging direction on a switch is allowed; see also PDF-pp. 13-15 of a pan-European presentation. Abrupt changes are not good for passengers, but will not derail a train.
Turnout design in the advanced world
Second derivative control, that is acceleration and cant deficiency, can be done using calculus and trigonometry tools. Third derivative control, that is clothoids and jerk, requires numerical calculations, but fortunately they are approximated well by pretending the clothoid is half straight line, half circular arc, with the length determined by the maximum jerk. Working from first principles, it’s possible to figure out that at typical turnout needs – e.g. move a train from one track to a parallel track 4 meters away – the clothoid is far longer than the curve itself, and at 50 mm/s jerk and 150 mm cant deficiency it’s not even possible to hit a curve radius of 250 meters.
Turnouts are inherently compromises. The question is just where to compromise. Here, for example, is a French turnout design, in two forms: 0.11 and 0.085. The numbers denoting the tangent of the angle at the frog, and the radius is proportional to the inverse square of the number, thus the speed is proportional to the inverse of the number. The sharper turnout, the 0.11, has a radius of 281 meters, a maximum speed of 50 km/h, and a total length of 26 meters from point to frog (“lead” in US usage), of which the clothoid curve (“point”) takes up 11, to limit jerk to 125 mm/s at a cant deficiency of 100 mm. The 0.085 turnout has a radius of 485 meters, a maximum speed of 65 km/h, a lead of about 38 meters, and a point of about 14.5 meters.
In Germany, turnouts have somewhat independent numbers and radii – some have shorter leads than others. The numbers are the inverse of those of France, so what France calls 0.11, Germany calls 1:9, but at the end of the day, the curve radius is the important part, with a cant deficiency of 100 mm. A higher cant deficiency may be desirable, but lengthening the point requires almost as much space as just increasing the curve radius, so might as well stick with the more comfortable limits.
Turnout design in the United States
American turnouts look similar to French or German ones, at first glance. I’ve seen a number of different designs; here’s one by CSX, on PDF-pp. 22 (#8) and 24 (#10), the numbers being very roughly comparable to German ones and inverses of French ones. CSX’s #10 has a curve radius of 779.39′, or 238 meters, and a lead of 24 meters, both numbers slightly tighter than the French 0.11. The radius is proportional to the square of the number, and so speed is proportional to the number.
However, the cant deficiency is just 50 mm. The point is not always curved; Amtrak’s low-number switches are not, so the change in cant deficiency is abrupt. Judging by what I experience every time I take a train between New York and New Haven, Metro-North’s switches have abrupt change in cant deficiency even on the mainline. The recommended standards by AREMA involve a curved point, but the point is still much shorter than in France (19.5′, or just under 6 meters, on a #12), so a 125 mm/s jerk only gets one up to about 62 mm cant deficiency.
The reason for this is that European turnouts are curved through the frog, whereas American ones are always straight at the frog. Extremely heavy American freight trains do not interact well with curved frogs and long points.
One might ask, why bother with such turnout design on rail segments that never see a heavy freight locomotive or 130-ton freight car? And on segments that do see the odd freight locomotive, like the approaches to Grand Central and Penn Station with the rare dual-mode locomotive, why not kick out anything that doesn’t interact well with advanced track design? Making a handful of passengers transfer would save around 4 minutes of trip time on the last mile into Grand Central alone for everyone else, not to mention time savings farther up the line.
There’s a moralistic discourse in the United States about fare evasion on public transport that makes it about every issue other than public transport or fares. It’s a proxy for lawlessness, for police racism, for public safety, for poverty. In lieu of treating it as a big intra-urban culture war, I am going to talk about best practices from the perspective of limiting revenue loss to a minimum.
This is an issue where my main methodology for making recommendations for Americans – looking at peer developed countries – is especially useful. The reason is that Americans practically never look at other countries on hot-button culture war issues, even less than (say) the lip service the center-left pays to foreign universal health care systems. Americans who support immigration liberalization practically never listen when I try bringing up the liberal work visa, asylum, and naturalization policies of Germany or Sweden. Knowing stuff about the rest of the world is a type of competence, and competence is not a factor in a culture war. The upshot is that successful policies regarding fare collection in (for example) Germany are obscure in the United States even more than policies regarding wonkier transportation issues like train frequency.
The current situation in New York
In the summer, Governor Cuomo announced a new initiative to hire 500 cops to patrol the subway. The justification for this scheme has varied depending on who was asking, but the primary goal appears to be to defeat fare evasion. Per Cuomo’s office, fare evasion costs $240 million a year on the subway and buses, about 5% of total revenue. The MTA has also mentioned a higher figure, $300 million; I do not know if the higher figure includes just urban transit or also commuter rail, where conductors routinely miss inspections, giving people free rides.
But New York fare evasion is mostly a bus problem: the rate on buses is 22%. On the subway the rate is only 4%, and there is somewhat more revenue loss on buses than on subways. This, in turn, is because bus fares are enforced by drivers, who for years have complained that fare disputes lead to assaults on them and proposed off-board fare collection as an alternative. On many buses, drivers just let it go and let passengers board without paying, especially if nearly all passengers are connecting from the subway and therefore have already paid, as on the B1 between the Brighton Beach subway station and Kingsborough Community College or on the buses to LaGuardia.
So realistically the subway fare evasion level is closer to $110 million a year. The total cost of the new patrol program is $56 million in the first year, escalating by 8% annually thanks to a pre-agreed pay hike scale. Whereas today the program is a net revenue generator if it halves subway fare evasion, a level that already seems strained, within ten years, assuming normal fare escalation, it will need to cut fare evasion by about 90%, which is a complete fantasy. A sizable proportion of riders who do not pay would just stop riding altogether, for one. The governor is proposing to spend more on fare enforcement than the MTA can ever hope to extract.
The American moral panic about fare evasion regrettably goes far beyond New York. Two years ago, BART announced that it would supplement its fare barriers with proof-of-payment inspections, done by armed cops, and lied to the public about the prevalence of such a belts-and-suspenders system. More recently, it trialed a new turnstile design that would hit passengers in the face, but thankfully scrapped it after public outcry. Boston, too, has its moral panic about fare evasion, in the form of campaigns like the Keolis Ring of Steel on commuter rail or Fare is Fair.
There is another way
In talking to Americans about fare evasion, I have found that they are generally receptive to the idea of minimizing revenue loss net of collection costs. However, what I’ve encountered more resistance about is the idea that people should just be able to walk onto a bus or train.
In the urban German-speaking world, everyone with a valid fare can walk onto a bus, tram, or train without crossing fare barriers or having to pay a driver. This system has been copied to American light rail networks, but implementation on buses and subways lags (except on San Francisco buses). In New York, the SBS system uses proof of payment (POP), but passengers still have to validate fares at bus stops, even if they already have paid, for example if they have a valid monthly pass.
In the vast majority of cities, no excuse exists to have any kind of overt fare control. Tear down these faregates. They are hostile to passengers with disabilities, they cost money to maintain, they constrain passenger flow at busy times, and they don’t really save money – evidently, New York’s subway fare evasion rate is within the range of Berlin, Munich, and Zurich. Fare enforcement should be done with POP alone, by unarmed civilian inspectors, as in Berlin. Some people will learn to dodge the inspectors, as is the case in Berlin, and that’s fine; the point is not to get fare evasion to 0%, but to the minimum level net of enforcement costs.
New York itself may have an excuse to keep the faregates: its trains are very crowded, so peak-hour inspections may not be feasible. The question boils down to how New York crowding levels compare with those on the busiest urban POP line, the Munich S-Bahn trunk. But no other American city has that excuse. Tear down these faregates.
What’s more, the fare inspection should be a low-key affair. The fine in Berlin is €60. In Paris on the RER I can’t tell – I believe it’s three figures of which the first is a 1. Inspectors who can’t make a citation without using physical violence should not work as inspectors.
Make it easy to follow the law
The most important maxim when addressing a low-level crime is to make it easy to follow the law. Mistakes happen; I’ve accidentally fare-dodged in Berlin twice, only realizing the error at the end of the trip. This is much more like parking violations or routine mistakes in tax filing.
The turnstile acts as a reminder to everyone to pay their fare, since it’s not possible to fare-dodge without actively jumping it. (I did turnstile-jump in Paris once, with a valid transfer ticket that the turnstile rejected, I think because Paris’s turnstile and magnetic ticket technology is antediluvian.) However, turnstiles are not necessary for this. A better method is to ensure most passengers have prepaid already, by offering generous monthly discounts. My fare dodges in Berlin happened once before I got monthlies and once on my way to the airport on my current trip, in a month when I didn’t get a monthly since I was only in Berlin 6 days.
New York does poorly on the metric of encouraging monthlies. Passengers need to swipe 46 times in a 30-day period to justify getting a monthly pass rather than a pay-per-ride. This is bad practice, especially for passengers who prefer to refill at a ticketing machine rather than at home or on their phone with an app, since it means passengers visit the ticketing machines more often, requiring the agency to buy more to avoid long lines. In Berlin, the breakeven point is 36 trips. In Zurich, it’s 20 trips; ZVV does whatever it can to discourage people from buying single tickets. In both cities, there are further discounts for annual tickets.
Unfortunately, the problem of indifference to monthlies on urban rail is common around the Anglosphere. Singapore has no season passes at all. In Vancouver, Cubic lobbying and a New Right campaign about fare evasion forced TransLink to install faregates on SkyTrain, and when the faregate project had predictable cost overruns, the campaigners took that as evidence the agency shouldn’t get further funding. London’s fare capping system is weekly rather than monthly – there are no monthly passes, and all fares are set at very high levels. Britain generally overuses faregates, for example on the commuter trains in London. London generally gives off an impression of treating everyone who is not a Daily Mail manager as a criminal. Paris is better, but not by much. The German-speaking world, as irrational as Britain and France about urban crime rates that are far lower than they were a generation ago, still treats the train and bus rider as a law-abiding customer unless proven otherwise.
American transit agencies and activists resist calls for large monthly discounts, on a variety of excuses. The most common excuse is revenue loss, which is weird since realistically New York would transition to a large discount through holding the monthly fare constant and hiking the single-ride fare. It’s the second most common excuse that I wish to deal with here: social fares, namely the fact that many low-income riders don’t have the savings to prepay for an entire month.
On social fares, as on many other socioeconomic issues, it is useful for Americans to see how things work in countries with high income compression and low inequality under the aegis of center-left governments. In Paris, various classes of low-income riders, such as the unemployed, benefit from a solidarity fare discount of 50-75%. In both Paris and Stockholm, the monthly pass is flat regionwide, an intentional program of subsidizing regular riders in the suburbs, which are on average poorer than the city.
The flat fare is not really applicable to American cities, except possibly the Bay Area on BART. However, the large fare reductions to qualifying low-income riders are: a number of cities have used the same definition, namely Medicaid eligibility, and give steep discounts for bikeshare systems. On the same principle, cities and states can discount fares on buses and trains.
The right way to view fares
Fares are an important component of public transport revenue; the taxes required to eliminate fares are significant enough that there are probably better uses for the money. By the same token, the issue of fare evasion should be viewed from the lens of revenue loss, rather than that of crime and disorder. The transit agency is not an individual who is broken by being mugged of $100; it should think in terms of its own finances, not in terms of deterrence.
Nor is making it easier to follow the law going to encourage more crime – to the contrary. Transit agencies should aim at a fare system, including enforcement, that allows passengers to get on and off trains quickly, with minimum friction. Turnstiles do not belong in any city smaller than about 10 million people. The fare structure should then encourage long-term season passes, including annual passes, so that nearly all residents who take public transport have already paid. Random inspections with moderate fines are the layer of enforcement, but the point is to make enforcement largely unneeded.
And tear down the faregates.
In a number of large cities with both radial and circumferential urban rail service, there is a curious observation: there is express service on the radial lines, but not the circumferential ones. These cities include New York, Paris, and Berlin, and to some extent London and Seoul. Understanding why this is the case is useful in general: it highlights guidelines for urban public transport design that have implications even outside the distinction between radial and circumferential service. In brief, circumferential lines are used for shorter trips than radial lines, and in large cities connect many different spokes so that an express trip would either skip important stations or not save much time.
Berlin has three S-Bahn trunk lines: the Ringbahn, the east-west Stadtbahn, and the North-South Tunnel. The first two have four tracks. The last is a two-track tunnel, but has recently been supplemented with a parallel four-track North-South Main Line tunnel, used by regional and intercity trains.
The Stadtbahn has a straightforward local-express arrangement: the S-Bahn uses the local tracks at very high frequency, whereas the express tracks host less frequent regional trains making about half as many stops as well as a few intercity trains only making two stops. The north-south system likewise features very frequent local trains on the S-Bahn, and a combination of somewhat less frequent regional trains making a few stops on the main line and many intercity trains making fewer stops. In contrast, the Ringbahn has no systemic express service: the S-Bahn includes trains running on the entire Ring frequently as well as trains running along segments of it stopping at every station on the way, but the only express services are regional trains that only serve small slivers on their way somewhere else and only come once or twice an hour.
This arrangement is mirrored in other cities. In Paris, the entire Metro network except Line 14 is very local, with the shortest interstations and lowest average speeds among major world metro systems. For faster service, there is Line 14 as well as the RER system, tying the suburbs together with the city. Those lines are exclusively radial. The busiest single RER line, the RER A, was from the start designed as an express line parallel to Line 1, the Metro’s busiest, and the second busiest, the RER B, is to a large extent an express version of the Metro’s second busiest line, Line 4. However, there is no RER version of the next busiest local lines, the ring formed by Lines 2 and 6. For non-Metro circumferential service, the region went down the speed/cost tradeoff and built tramways, which have been a total success and have high ridership even though they’re slow.
In New York, the subway was built with four-track main lines from the start to enable express service. Five four-track lines run north-south in Manhattan, providing local and express service. Outside the Manhattan core, they branch and recombine into a number of three- and four-track lines in Brooklyn, Queens, and the Bronx. Not every radial line in New York has express service, but most do. In contrast, the circumferential Crosstown Line, carrying the G train, is entirely local.
In Seoul, most lines have no express service. However, Lines 1, 3, and 4 interline with longer-range commuter rail services, and Lines 1 and 4 have express trains on the commuter rail segments. They are all radial; the circumferential Line 2 has no express trains.
Finally, in London, the Underground has few express segments (all radial), but in addition to the Underground the city has or will soon have express commuter lines, including Thameslink and Crossrail. There are no plans for express service parallel to the Overground.
Is Tokyo really an exception?
Tokyo has express trains on many lines. On the JR East network, there are lines with four or six tracks all the way to Central Tokyo, with local and express service. The private railroads usually have local and express services on their own lines, which feed into the local Tokyo subway. But not all express services go through the primary city center: the Ikebukuro-Shibuya corridor has the four-track JR Yamanote Line, with both local services (called the Yamanote Line too, running as a ring to Tokyo Station) and express services (called the Saikyo or Shonan-Shinjuku Line, continuing north and south of the city); Tokyo Metro’s Fukutoshin Line, serving the same corridor, has a timed passing segment for express trains as well.
However, in three ways, the area around Ikebukuro, Shinjuku, and Shibuya behaves as a secondary city center rather than a circumferential corridor. The job density around all three stations is very high, for one. They have extensive retail as well, as the private railroads that terminated there before they interlined with the subway developed the areas to encourage more people to use their trains. This situation is also true of some secondary clusters elsewhere in Tokyo, like Tobu’s Asakusa terminal, but Asakusa is in a historically working-class area, whereas the Yamanote area was historically and still is wealthier, making it easier for it to attract corporate jobs.
Second, from the perspective of the transportation network, they are central enough that railroads that have the option to serve them do so, even at the expense of service to Central Tokyo. When the Fukutoshin Line opened, Tokyu shifted one of its two mainlines, the Toyoko Line, to connect to it and serve this secondary center, where it previously interlined with the Hibiya Line to Central Tokyo; Tokyu serves Central Tokyo via its other line, the Den-en-Toshi Line, which connects to the Hanzomon Line of the subway. JR East, too, prioritizes serving Shinjuku from the northern and southern suburbs: the Shonan-Shinjuku Line is a reverse-branch of core commuter rail lines both north and south, as direct fast service from the suburbs to Shibuya, Shinjuku, and Ikebukuro is important enough to JR East that it will sacrifice some reliability and capacity to Tokyo Station for it.
Third, as we will discuss below, the Yamanote Line has a special feature missing from circumferential corridors in Berlin and Paris: it has distinguished stations. A foreigner looking at satellite photos of land use and at a map of the region’s rail network without the stations labeled would have an easy time deciding where an express train on the line should stop: Ikebukuro, Shinjuku, and Shibuya eclipse other stations along the line, like Yoyogi and Takadanobaba. Moreover, since these three centers were established to some extent before the subway was built, the subway lines were routed to serve them; there are 11 subway lines coming from the east as well as the east-west Chuo Line, and of these, all but the Tozai and Chiyoda Lines intersect it at one of the three main stations.
Interstations and trip length
The optimal stop spacing depends on how long passenger trips are on the line: keeping all else equal, it is proportional to the square root of the average unlinked trip. The best formula is somewhat more delicate: widening the stop spacing encourages people to take longer trips as they become faster with fewer intermediate stops and discourages people from taking shorter ones as they become slower with longer walk distances to the station. However, to a first-order approximation, the square root rule remains valid.
The relevance is that not all lines have the same average trip length. Longer lines have longer trips than short lines. Moreover, circular lines have shorter average trips than straight lines of the same length, because people have no reason to ride the entire way. The Ringbahn is a 37-kilometer line on which trains take an hour to complete the circuit. But nobody has a reason to ride more than half the circle – they can just as well ride the shorter way in the other direction. Nor do passengers really have a reason to ride over exactly half the circle, because they can often take the Stadtbahn, North-South Tunnel, or U-Bahn and be at their destinations faster.
Circumferential lines are frequently used to connect to radial lines if the radial-radial connection in city center is inconvenient – maybe it’s missing entirely, maybe it’s congested, maybe it involves too much walking between platforms, maybe happens to be on the far side of city center. In all such cases, people are more likely to use the circumferential line for shorter trips than for longer ones: the more acute the angle, the more direct and thus more valuable the circle is for travel.
The relevance of this discussion to express service is that there’s more demand for express service in situations with longer optimum stop spacing. For example, the optimum stop spacing for the subway in New York based on current travel patterns is the same as that proposed for Second Avenue Subway, to within measurement error of parameters like walking speed; on the other trunk lines, the local trains have denser stop spacing and the express trains have wider stop spacing. On a line with very short optimum spacing, there is not much of a case for express service at all.
Distinguished stops versus isotropy
The formula for optimal stop spacing depends on the isotropy of travel demand. If origins and destinations are distributed uniformly along the line, then the optimal stop spacing is minimized: passengers are equally likely to live and work right on top of a station, which eliminates walk time, as they are to live and work exactly in the middle between two stations, which maximizes walk time. If the densities of origins and destinations are spiky around distinguished nodes, then the optimal stop spacing widens, because planners can place stations at key locations to minimize the number of passengers who have to walk longer. If origins are assumed to be perfectly isotropic but destinations are assumed to be perfectly clustered at such distinguished locations as city center, the optimum stop spacing is larger than if both are perfectly isotropic by a factor of .
Circumferential lines in large cities do not have isotropic demand. However, they have a great many distinguished stops, one at every intersection with a radial rail service. Out of 27 Ringbahn stops, 21 have a connection to the U-Bahn, a tramway, or a radial S-Bahn line. Express service would be pointless – the money would be better spent increasing local frequency, as ridership on short-hop trips like the Ringbahn’s is especially sensitive to wait time.
On the M2/M6 ring in Paris, there are 49 stops, of which 21 have connections to other Metro lines or the RER, one more doesn’t but really should (Rome, with a missed connection to an M14 extension), and one may connect to a future extension of M10. Express service is not completely pointless parallel to M2/M6, but still not too valuable. Even farther out, where the Paris region is building the M15 ring of Grand Paris Express, there are 35 stops in 69 kilometers of the main ring, practically all connecting to a radial line or located at a dense suburban city center.
The situation in New York is dicier, because the G train does have a distinguished stop location between Long Island City and Downtown Brooklyn, namely the connection to the L train at Bedford Avenue. However, the average trip length remains very short – the G misses so many transfers at both ends that end-to-end riders mostly stay on the radials and go through Manhattan, so the main use case is taking it a few stops to the connection to the L or to the Long Island City end.
A large urban rail network should be predominantly radial, with circumferential lines in dense areas providing additional connectivity between inner neighborhoods and decongesting the central transfer points. However, that the radial and circumferential lines are depicted together on the same metro or regional rail map does not mean that people use them in the same way. City center lies ideally on all radials but not on the circumferentials, so the tidal wave of morning commuters going from far away to the center is relevant only to the radials.
This difference between radials and circumferentials is not just about service planning, but also about infrastructure planning. Passengers make longer trips on radial lines, and disproportionately travel to one of not many distinguished central locations; this encourages longer stop spacing, which may include express service in the largest cities. On circumferential lines, they make shorter trips to one of many different connection points; this encourages shorter stop spacing and no express service, but rather higher local frequency whenever possible.
Different countries build rapid transit in radically different ways, and yet big cities in a number of different countries have converged on the same pattern: express service on the strongest radial corridors, local-only service on circumferential ones no matter how busy they are. There is a reason. Transportation planners in poorer cities that are just starting to build their rapid transit networks as well in mature cities that are adding to their existing service should take heed and design infrastructure accordingly.