# Deutsche Bahn’s Meltdown and High-Speed Rail

A seven-hour rail trip from Munich to Berlin – four and a half on the timetable plus two and a half of sitting at and just outside Nuremberg – has forced me to think a lot more about the ongoing collapse of the German intercity rail network. Ridership has fully recovered to pre-corona levels – in May it was 5% above 2019 levels, and that was just before the nine-euro monthly ticket was introduced, encouraging people to shift their trips to June, July, and August to take advantage of what is, among other things, free transit outside one’s city of residence. But at the same time, punctuality has steadily eroded this year:

It’s notable that the June introduction of the 9€ ticket is invisible in the graphic for intercity rail; it did coincide with deterioration in regional rail punctuality, but the worst problems are for the intercity trains. My own train was delayed by a mechanical failure, and then after an hour of failed attempts to restart it we were put on a replacement train, which spent around an hour sitting just outside Nuremberg, and even though it skipped Leipzig (saving 40 minutes in the process), it arrived at Berlin an hour and a half behind its schedule and two and a half behind ours.

Sometimes, those delays cascade. It’s not that high ridership by itself produces delays. The ICEs are fairly good at access and egress, and even a full train unloads quickly. Rather, it’s that if a train is canceled, then the passengers can’t get on the next one because it’s full beyond standing capacity; standing tickets are permitted in Germany, but there are sensors to ensure the train’s mass does not exceed a maximum level, which can be reached on unusually crowded trains, and so a train’s ability to absorb passengers on canceled trains as standees is limited.

But it’s not the short-term delays that I’m most worried about. One bad summer does not destroy a rail network; riders can understand a few bad months provided the problem is relieved. The problem is that there isn’t enough investment, and what investment there is is severely mistargeted.

Within German discourse, it’s common to assert superiority to France and Southern Europe in every possible way. France is currently undergoing an energy crisis, because the heat wave is such that river water cannot safely cool down its nuclear power plants; German politicians have oscillated between using this to argue that nuclear power is unreliable and the three remaining German plants should be shut down and using this to argue that Germany should keep its plants open as a gesture of magnanimity to bail out France.

Rail transport features a similar set of problems. France has a connected network of high-speed lines, nearly all of which are used to get between Paris and secondary cities. Germany does not – it has high-speed lines but the longest connection between major cities allowing more than 200 km/h throughout is Cologne-Frankfurt, a distance of 180 km.

The natural response of most German rail advocates is to sneer at the idea of high-speed rail; France has genuine problems with punctuality, neglect of legacy rail lines, and poor interconnections between lines (it has nothing like the hourly or two-hour clockface timetables of German intercity rail), and those are all held as reasons why Germany has little to learn from France. Instead, those advocates argue, Germany should be investing in network-wide punctuality, because reliability matters more than speed.

The problem is that the sneering at France is completely unjustified. A French government investigation into punctuality in 2019-20 found that yes, French intercity trains suffered from extensive delays – but in 2019 intercity trains were on-time at the terminus 77.4% of the time, compared with 73.8% in Germany. Germany did better in 2020 when nobody was riding, but went back to 75% in 2021 as ridership began to recover. High-speed trains were the most punctual in Spain and the Netherlands, where they do not run on classical lines for significant stretches, unlike in France, Germany, or Italy.

Moreover, German trains are extremely padded. Der Spiegel has long been a critic of poor planning in German railways, and in 2019 it published a comparison of the TGV and ICE. The selected ICE connections were padded more than 20%; only Berlin-Munich was less, at 18%. The TGV comparisons were padded 11-14%; these are all lines running almost exclusively on LGVs, like Paris-Bordeaux, rather than the tardier lines running for significant distances on slow lines, like Paris-Nice. And even 11-14% is high; Swiss planning is 7% on congested urban approaches, with reliability as the center of the country’s design approach, while JR East suggested 4% for Shinkansen-style entirely dedicated track in its peer review of California High-Speed Rail.

Thus, completing a German high-speed rail network is not an opposed goal to reliability. Quite to the contrary, creating a separate network running only or almost only ICEs to connect Berlin, Hamburg, Hanover, Bremen, the main cities of the Rhine-Ruhr, Frankfurt, Munich, and Stuttgart means that there is less opportunity for delays to propagate. A delayed regional train would not slow down an intercity train, permitting not just running at high punctuality but also doing so while shrinking the pad from 25% to 7%, which offers free speed.

Cutting the pad to 7% interacts especially well with some of the individual lines Germany is planning. Hanover-Bielefeld, a distance of 100 km, can be so done in 27-28 minutes; this can be obtained from looking at the real performance specs of the Velaro Novo, but also from a Japanese sanity check, as the Nagoya-Kyoto distance is not much larger and taking the difference into account is easy. But the current plan is to do this in 31 minutes, just more than half an hour rather than just less, complicating the plan for regular timed connections on the half-hour.

German rail traffic is not collapsing – quite to the contrary. DB still expects to double intercity ridership by the mid-2030s. This requires investments in capacity, connectivity, speed, and reliability – and completing the high-speed network, far from prioritizing speed at the expense of the other needs, fulfills all needs at once. Half-hourly trains could ply every connection, averaging more than 200 km/h between major cities, and without cascading delays they would leave the ongoing summer of hell in the past. But this requires committing to building those lines rather than looking for excuses for why Germany should not have what France has.

# Quick Note: Why Not Fly?

I was asked a deceptively simple question on Twitter: why would people bother with taking a train when flying is available? In my (admittedly primitive) modeling for high-speed rail ridership in the US, I’m including some nontrivial ridership and revenue coming from cities at a distance that people do fly, like Boston-Washington, New York-Cleveland, and so on. What gives?

The simplest answer is that evidently people do take trains at such distances. Statista has some examples, all with more rail than air travel; an Air2Rail paper by Arie Bleijenberg has some numbers within Europe in Annex B. The main factor is rail travel time, with a malus for markets with poor rail connectivity (such as anything crossing the Channel). When trains take four hours, as on Paris-Toulon, they have a small majority of the travel market (source, p. 14 – look at the 2009 numbers, the 2023 numbers being a speculation); Paris-Nice manages to have respectable modal split even at 5.5 hours.

But that answer is frustrating. Why do people take trains for 4-5 hours when it’s possible to fly in an hour?

The first answer is door-to-door travel time. This includes all of the following features:

• Airports are far from city centers whereas train stations are almost universally within them; even taking into account that most people don’t live in city center, they tend to have easier access to the train station than to the airport, and then destinations are massively centralized in the city.
• Trains have no security theater to delay passengers, and passengers can get from the station entrance to the platform in 10 minutes if the station is exceptionally labyrinthine and they’re unfamiliar with its layout and two minutes if it’s not or they are.
• Passengers with luggage can take it on the train and don’t have to be further delayed for baggage claim.

All of these features work to make trains more pleasant than planes even when the door-to-door trip times are equal. The sequential queuing for security and then boarding on a plane is a hassle in addition to extra time; of note, in the Air2Rail link, the most glaring underperformance in high-speed rail modal split relative to trip times is for routes crossing the Channel, because they have such queuing courtesy of British paranoia about terrorism in the Chunnel and also charge higher fares.

The advantages of planes over trains are elsewhere. First, planes are faster airport-to-airport than trains are station-to-station, and as a result, a longer distances they are much faster door-to-door and therefore dominant. And second, trains travel in lines whereas planes travel point-to-point; it’s not hard to come up with city pairs that have no reason to have an even semi-direct high-speed railway between them even though they are at rail-appropriate range, for example Nice-Geneva (290 km) or Cincinnati-Charlotte (540 km).

But once the lines exist, they should get substantial passenger traffic – and the modal split with air is very well-documented in the literature and the overall traffic is still fairly well-modeled as well.

# How Many Tracks Do Train Stations Need?

A brief discussion on Reddit about my post criticizing Penn Station expansion plans led me to write a very long comment, which I’d like to hoist to a full post explaining how big an urban train station needs to be to serve regional and intercity rail traffic. The main principles are,

• Good operations can substitute for station size, and it’s always cheaper to get the system to be more reliable than to build more tracks in city center.
• Through-running reduces the required station footprint, and this is one of the reasons it is popular for urban commuter rail systems.
• The simpler and more local the system is, the fewer tracks are needed: an urban commuter rail system running on captive tracks with no sharing tracks with other traffic and with limited branching an get away with smaller stations than an intercity rail station featuring trains from hundreds of kilometers away in any direction.

On subways, where usually the rush hour crunches are the worst, trains in large cities run extremely frequently, brushing up against the physical limitation of the tracks. The limit is dictated by the brick wall rule, which states that the signal system must at any point assume that the train ahead can turn into a brick wall and stop moving and the current train must be able to brake in time before it reaches it. Cars, for that matter, follow the same rule, but their emergency braking rate is much faster, so on a freeway they can follow two seconds apart. A metro train in theory could do the same with headways of 15 seconds, but in practice there are stations on the tracks and dealing with them requires a different formula.

With metro-style stations, without extra tracks, the governing formula is,

$\mbox{headway } = \mbox{stopping time } + \mbox{dwell time } + \mbox{platform clearing time }$

Platform clearing time is how long it takes the train to clear its own length; the idea of the formula is that per the brick wall rule, the train we’re on needs to begin braking to enter the next station only after the train ahead of ours has cleared the station.

But all of this is in theory. In practice, there are uncertainties. The uncertainties are almost never in the stopping or platform clearing time, and even the dwell time is controllable. Rather, the schedule itself is uncertain: our train can be a minute late, which for our purpose as passengers may be unimportant, but for the scheduler and dispatcher on a congested line means that all the trains behind ours have to also be delayed by a minute.

What this means that more space is required between train slots to make schedules recoverable. Moreover, the more complex the line’s operations are, the more space is needed. On a metro train running on captive tracks, if all trains are delayed by a minute, it’s really not a big deal even to the control tower; all the trains substitute for one another, so the recovery can be done at the terminal. On a mainline train running on a national network in which our segment can host trains to Budapest, Vienna, Prague, Leipzig, Munich, Zurich, Stuttgart, Frankfurt, and Paris, trains cannot substitute for one another – and, moreover, a train can be easily delayed 15 minutes and need a later slot. Empty-looking space in the track timetable is unavoidable – if the schedule can’t survive contact with the passengers, it’s not a schedule but crayon.

How to improve operations

In one word: reliability.

In two words: more reliability.

Because the main limit to rail frequency on congested track comes from the variation in the schedule, the best way to increase capacity is to reduce the variation in the schedule. This, in turn, has two aspects: reducing the likelihood of a delay, and reducing the ability of a delay to propagate.

Reducing delays

The central insight about delays is that they may occur anywhere on the line, roughly in proportion to either trip time or ridership. This means that on a branched mainline railway network, delays almost never originate at the city center train station or its approaches, not because that part of the system is uniquely reliable, but because the train might spend five minutes there out of a one-hour trip. The upshot is that to make a congested central segment more reliable, it is necessary to invest in reliability on the entire network, most of which consists of branch segments that by themselves do not have capacity crunches.

The biggest required investments for this are electrification and level boarding. Both have many benefits other than schedule reliability, and are underrated in Europe and even more underrated in the United States.

Electrification is the subject of a TransitMatters report from last year. As far as reliability is concerned, the LIRR and Metro-North’s diesel locomotives average about 20 times the mechanical failure rate of electric multiple units (source, PDF-pp. 36 and 151). It is bad enough that Germany is keeping some outer regional rail branches in the exurbs of Berlin and Munich unwired; that New York has not fully electrified is unconscionable.

Level boarding is comparable in its importance. It not only reduces dwell time, but also reduces variability in dwell time. With about a meter of vertical gap between platform and train floor, Mansfield has four-minute rush hour dwell times; this is the busiest suburban Boston commuter rail station at rush hour, but it’s still just about 2,000 weekday boardings, whereas RER and S-Bahn stations with 10 time the traffic hold to a 30-second standard. This also interacts positively with accessibility: it permits passengers in wheelchairs to board unaided, which both improves accessibility and ensures that a wheelchair user doesn’t delay the entire train by a minute. It is fortunate that the LIRR and (with one peripheral exception) Metro-North are entirely high-platform, and unfortunate that New Jersey Transit is not.

Reducing delay propagation

Even with reliable mechanical and civil engineering, delays are inevitable. The real innovations in Switzerland giving it Europe’s most reliable and highest-use railway network are not about preventing delays from happening (it is fully electrified but a laggard on level boarding). They’re about ensuring delays do not propagate across the network. This is especially notable as the network relies on timed connections and overtakes, both of which require schedule discipline. Achieving such discipline requires the following operations and capital treatments:

• Uniform timetable padding of about 7%, applied throughout the line roughly on a one minute in 15 basis.
• Clear, non-discriminatory rules about train priority, including a rule that a train that’s more than 30 minutes loses all priority and may not delay other trains at junctions or on shared tracks.
• A rigid clockface schedule or Takt, where the problem sections (overtakes, meets, etc.) are predictable and can receive investment. With the Takt system, even urban commuter lines can be left partly single-track, as long as the timetable is such that trains in opposite directions meet away from the bottleneck.
• Data-oriented planning that focuses on tracing the sources of major delays and feeding the information to capital planning so that problem sections can, again, receive capital investment.
• Especial concern for railway junctions, which are to be grade-separated or consistently scheduled around. In sensitive cases where traffic is heavy and grade separation is too expensive, Switzerland builds pocket tracks at-grade, so that a late train can wait for a slot without delaying cross-traffic.

So, how big do train stations need to be?

A multi-station urban commuter rail trunk can get away with metro-style operations, with a single station track per approach track. However, the limiting factor to capacity will be station dwell times. In cases with an unusually busy city center station, or on a highly-interlinked regional or intercity network, this may force compromises on capacity.

In contrast, with good operations, a train station with through-running should never need more than two station tracks per approach track. Moreover, the two station tracks that each approach track splits into should serve the same platform, so that if there is an unplanned rescheduling of the train, passengers should be able to use the usual platform at least. Berlin Hauptbahnhof’s deep tracks are organized this way, and so is the under-construction Stuttgart 21.

Why two? First, because it is the maximum number that can serve the same platform; if they serve different platforms, it may require lengthening dwell times during unscheduled diversions to deal with passenger confusion. And second, because every additional platform track permits, in theory, an increase in the dwell time equal to the minimum headway. The minimum headway in practice is going to be about 120 seconds; at rush hour Paris pushes 32 trains per hour on the shared RER B and D trunk, which is not quite mainline but is extensively branched, but the reliability is legendarily poor. With a two-minute headway, the two-platform track system permits a straightforward 2.5-minute dwell time, which is more than any regional railway needs; the Zurich S-Bahn has 60-second dwells at Hauptbahnhof, and the Paris RER’s single-level trains keep to about 60 seconds at rush hour in city center as well.

All of this is more complicated at a terminal. In theory the required number of tracks is the minimum turn time divided by the headway, but in practice the turn time has a variance. Tokyo has been able to push station footprint to a minimum, with two tracks at Tokyo Station on the Chuo Line (with 28 peak trains per hour) and, before the through-line opened, four tracks on the Tokaido Main Line (with 24). But elsewhere the results are less optimistic; Paris is limited to 16-18 trains per hour at the four-track RER E terminal at Saint-Lazare.

At Paris’s levels of efficiency, which are well below global best practices, an unexpanded Penn Station without through-running would still need two permanent tracks for Amtrak, leaving 19 tracks for commuter traffic. With the Gateway tunnel built, there would be four two-track approaches, two from each direction. The approaches that share tracks with Amtrak (North River Tunnels, southern pair of East River Tunnels) would get four tracks each, enough to terminate around 18 trains per hour at rush hour, and the approaches that don’t would get five, enough for maybe 20 or 22. The worst bottleneck in the system, the New Jersey approach, would be improved from today’s 21 trains per hour to 38-40.

A Penn Station with through-running does not have the 38-40 trains per hour limit. Rather, the approach tracks would become the primary bottleneck, and it would take an expansion to eight approach tracks on each side for the station itself to be at all a limit.

# Intercity Rail Frequency and the Perils of Market Segmentation

SNCF loves market segmentation. Run by airline execs, the company loves to create different trains for different classes of people. Not only do individual trains have opaque pricing run on the basis of yield management, in which similar seats on the same train at the same time of day and day of week may have different fares, but also there are separately-branded trains for separate fare classes, the higher-fare InOui and the lower-fare OuiGo. On international trains, SNCF takes it to the limit and thus Eurostar and Thalys charge premium fares (both about twice as high as domestic TGVs per passenger-km) and don’t through-ticket with domestic TGVs. This has gotten so bad that in Belgium, some advocates have proposed a lower-priced service on the legacy Paris-Brussels line, which would have to be subsidized owing to the high cost of low-speed intercity rail service.

But why is market segmentation on rail so bad? The answer has to do with frequency and cost structures that differ from those of airlines. Both ensure that the deadweight loss from market segmentation exceed any gains that could be made from extracting consumer surplus.

The issue of frequency

A segmented market like that of domestic TGVs reduces frequency on each segment. To maintain segmentation, SNCF has to make the segments as difficult to substitute for each other as possible. OuiGo serves Marne-la-Vallée instead of Gare de Lyon and forcing passengers onto a 20-minute RER connection, or even longer if they’re arriving in Paris and the wave of 1,000 TGV riders creates long lines at the ticketing machines; on other LGVs it serves the traditional Parisian station and thus the segments are more substitutable.

The situation of Eurostar and Thalys reduces frequency as well: the high fares discourage ridership and send much of it to intercity buses or suppress travel. Fewer riders, or fewer riders per segment as in the case of domestic TGVs, lead to fewer trains. What’s the impact of this on ridership?

The literature on high-speed rail ridership elasticities has some frequency estimates. In Couto’s thesis (PDF-p. 225), it is stated that passenger rail ridership has an elasticity of 0.53 with respective to overall service provision. There are also multiple papers estimating the elasticity with respect to travel time: in Cascetta-Coppola the elasticity ranges from -1.6 to -2.2, in Börjesson it is -1.12, and in a Civity report it is stated based on other work that it is -0.8 to -2. The lowest values in Börjesson are associated with the premium-fare AVE, while the range for the original TGV, priced at the same level as the slower trains it replaced, is -1.3 to -1.6. The upshot is that halving frequency through market segmentation reduces ridership by a factor of 2^0.53 = 1.44, which is far more than the benefit yield management is claimed to have, which is a 4% increase in revenue per SNCF’s American proposals from 2009.

Why are trains different?

Planes and buses happily use yield management. High-speed trains do not, except for those run by SNCF or RENFE – and ridership in France isn’t really higher than in fixed-fare Northern Europe or East Asia while ridership in Spain is much lower. Why the difference?

The reason has to do with the ratio of waiting time to trip time. Thalys connects Paris and Brussels in 1.5 hours, every half hour at rush hour and every 2 hours midday. At rush hour, frequency is sort of noticeable; off-peak, it dominates travel time. This is nothing like planes – even short-distance trips involve hours of access, waiting, and egress time, and therefore trips are not usually spontaneous, and day trips are rare except for business travelers.

Buses, finally, are so small that a market like New York-Philadelphia supports multiple competitors each running frequently, and passenger behavior is such that different companies are substitutable, so that the effective frequency is multiple buses per hour.

It’s typical to price high-speed rail higher than legacy rail, even when otherwise there is no yield management. This is bad practice. The operating costs of high-speed rail are lower than those of slow trains. The crew is paid per hour; electricity costs are in theory higher at higher speed but in practice greenfield high-speed lines are constant 300 km/h cruises whereas legacy lines have many acceleration and deceleration cycles; high-speed trainsets cost much more than conventional ones (by a factor of about 2 in Europe) but also depreciate by the hour and not by the km and therefore are somewhat cheaper per seat-km.

This is comparable to the bad practice, common in the United States and in developing and newly-industrialized countries, of pricing urban rail higher than a bus. The metro is nicer for consumers than a bus, but it also has far lower operating costs and therefore a wise transit agency will avoid incentivizing passengers to take buses and instead use integrated fares. The same is true for slow and fast trains: the solution proposed by the Belgian advocates is to incentivize passengers to take a high-cost, low-price train over a low-cost, high-price one, and therefore is no solution at all.

Moreover, the cost structure of trains is different from that of planes. Planes don’t pay much for fixed infrastructure; in effect, every plane trip costs money, and then the challenge is to fill all the seats. High-speed railways instead pay a lot for infrastructure, while their above-the-rails costs are a few cents per passenger-km (€0.06/seat-km on the TGV, including trainset costs and a lot of labor inefficiency). Their challenge is how to fill the tracks with trains, not how to fill the trains with passengers. This is why the fixed clockface frequency common in Germany, Switzerland, Austria, and the Netherlands is so powerful: the off-peak trains are less full, but that’s fine, as the marginal operating cost of an off-peak train is low.

Just lower the fares

Bear in mind that frequency is not exogenous – it is set based on demand. This means that anything that affects ridership has its impact magnified by the frequency-ridership spiral. An exogenous shock, such as improvement in trip time or fare reduction, is magnified through the spiral, by a factor of 1/(1-0.53) = 2.13. In other words, every elasticity estimated in isolation must be multiplied by a factor of about 2.

And once this is understood, suddenly the optima for service look very different from what Thalys has settled on. The optimum is to charge fares to pay infrastructure costs but not much more – especially if you’re SNCF and the railway workers’ union will extract all further profit through strikes, as it did 10 years ago. And this means making sure that except at very busy times, known in advance, Paris-Brussels tickets should be 30€, not 50-100€.

# The Northeastern United States Wants to Set Tens of Billions on Fire Again

The prospect of federal funds from the Bipartisan Infrastructure Bill is getting every agency salivating with desires for outside money for both useful and useless priorities. Northeastern mainline rail, unfortunately, tilts heavily toward the useless, per a deep dive into documents by New York-area activists, for example here and here.

Amtrak is already hiring project management for Penn Station redevelopment. This is a project with no transportation value whatsoever: this is not the Gateway tunnels, which stand to double capacity across the Hudson, but rather a rebuild of Penn Station to add more tracks, which are not necessary. Amtrak’s current claim is that the cost just for renovating the existing station is \$6.5 billion and that of adding tracks is \$10.5 billion; the latter project has ballooned from seven tracks to 9-12 tracks, to be built on two levels.

This is complete overkill. New train stations in big cities are uncommon, but they do exist, and where tracks are tunneled, the standard is two platform tracks per approach tracks. This is how Berlin Hauptbahnhof’s deep section goes: the North-South Main Line is four tracks, and the station has eight, on four platforms. Stuttgart 21 is planned in the same way. In the best case, each of the approach track splits into two tracks and the two tracks serve the same platform. Penn Station has 21 tracks and, with the maximal post-Gateway scenario, six approach tracks on each side; therefore, extra tracks are not needed. What’s more, bundling 12 platform tracks into a project that adds just two approach tracks is pointless.

This is a combined \$17 billion that Amtrak wants to spend with no benefit whatsoever; this budget by itself could build high-speed rail from Boston to Washington.

Or at least it could if any of the railroads on the Northeast Corridor were both interested and expert in high-speed rail construction. Connecticut is planning on \$8-10 billion just to do track repairs aiming at cutting 25-30 minutes from the New York-New Haven trip times; as I wrote last year when these plans were first released, the reconstruction required to cut around 40 minutes and also upgrade the branches is similar in scope to ongoing renovations of Germany’s oldest and longest high-speed line, which cost 640M€ as a once in a generation project.

In addition to spending about an order of magnitude too much on a smaller project, Connecticut also thinks the New Haven Line needs a dedicated freight track. The extent of freight traffic on the line is unclear, since the consultant report‘s stated numbers are self-contradictory and look like a typo, but it looks like there are 11 trains on the line every day. With some constraints, this traffic fits in the evening off-peak without the need for nighttime operations. With no constraints, it fits on a single track at night, and because the corridor has four tracks, it’s possible to isolate one local track for freight while maintenance is done (with a track renewal machine, which US passenger railroads do not use) on the two tracks not adjacent to it. The cost of the extra freight track and the other order-of-magnitude-too-costly state of good repair elements, including about 100% extra for procurement extras (force account, contingency, etc.), is \$300 million for 5.4 km.

I would counsel the federal government not to fund any of this. The costs are too high, the benefits are at best minimal and at worst worse than nothing, and the agencies in question have shown time and time again that they are incurious of best practices. There is no path forward with those agencies and their leadership staying in place; removal of senior management at the state DOTs, agencies, and Amtrak and their replacement with people with experience of executing successful mainline rail projects is necessary. Those people, moreover, are mid-level European and Asian engineers working as civil servants, and not consultants or political appointees. The role of the top political layer is to insulate those engineers from pressure by anti-modern interest groups such as petty local politicians and traditional railroaders who for whatever reasons could not just be removed.

If federal agencies are interested in building something useful with the tens of billions of BIL money, they should instead demand the same results seen in countries where the main language is not English, and staff up permanent civil service run by people with experience in those countries. Following best industry practices, \$17 billion is enough to renovate the parts of the Northeast Corridor that require renovation and bypass those that require greenfield bypasses; even without Gateway, Amtrak can squeeze a 16-car train every 15 minutes, providing 4,400 seats into Penn Station in an hour, compared with around 1,700 today – and Gateway itself is doable for low single-digit billions given better planning and engineering.

# German Rail Traffic Surges

DB announced today that it had 500,000 riders across the two days of last weekend. This is a record weekend traffic; May is so far 5% above 2019 levels, representing full recovery from corona. This is especially notable because of Germany’s upcoming 9-euro ticket: as a measure to curb high fuel price from the Russian war in Ukraine, during the months of June, July, and August, Germany is both slashing fuel taxes by 0.30€/liter and instituting a national 9€/month public transport ticket valid not just in one’s city of domicile but everywhere. In practice, rail riders respond by planning domestic rail trips for the upcoming three months; intercity trains are not covered by the 9€ monthly pass, but city transit in destination cities is, so Berliners I know are planning to travel to other parts of Germany during the window when local and regional transit is free, displacing trips that might be undertaken in May.

This is excellent news, with just one problem: Germany has not invested in its rail network enough to deal with the surge in traffic. Current traffic is already reaching projections made in the 2010s for 2030, when most of the Deutschlandtakt is supposed to go into effect, with higher speed and higher capacity than the network has today. Travel websites are already warning of capacity crunches in the upcoming three months of effectively free regional travel (chaining regional trains between cities is possible and those are covered by the 9€ monthly pass). Investment in capacity is urgent.

Sadly, such investment is still lagging. Germany’s intercity rail network rarely builds complete high-speed lines between major cities. The longest all-high-speed connection is between Cologne and Frankfurt, 180 km apart. Longer connections always have significant slow sections: Hamburg-Hanover remains slow due to local NIMBY opposition to a high-speed line, Munich’s lines to both Ingolstadt and Augsburg are slow, Berlin’s line toward Leipzig is upgraded to 200 km/h but not to full high-speed standards.

Moreover, plans to build high-speed rail in Germany remain compromised in two ways. First, they still avoid building completely high-speed lines between major cities. For example, the line from Hanover to the Rhine-Ruhr is slow, leading to plans for a high-speed line between Hanover and Bielefeld, and potentially also from Bielefeld to Hamm; but Hamm is a city of 180,000 people at the eastern margin of the Ruhr, 30 km from Dortmund and 60 from Essen. And second, the design standards are often too slow as well – Hanover-Bielefeld, a distance that the newest Velaro Novo trains could cover in about 28 minutes, is planned to be 31, compromising the half-hourly and hourly connections in the D-Takt. Both of these compromises create a network that 15 years from now is planned to have substantially lower average speeds than those achieved by France 20 years ago and by Spain 10 years ago.

But this isn’t just speed, but also capacity. An incomplete high-speed rail network overloads the remaining shared sections. A complete one removes fast trains from the legacy network except in legacy rail terminals where there are many tracks and average speeds are never high anyway; Berlin, for example, has four north-south tracks feeding Hauptbahnhof with just six trains per hour per direction. In China, very high throughput of both passenger rail (more p-km per route-km than anywhere in Europe) and freight rail (more ton-km per route-km than the United States) through the removal of intercity trains from the legacy network to the high-speed one, whose lines are called passenger-dedicated lines.

So to deal with the traffic surge, Germany needs to make sure it invests in intercity rail capacity immediately. This means all of the following items:

• Building all the currently discussed high-speed lines, like Frankfurt-Mannheim, Ulm-Augsburg (Stuttgart-Ulm is already under construction), and Hanover-Bielefeld.
• Completing the network by building high-speed lines even where average speeds today are respectable, like Berlin-Halle/Leipzig and Munich-Ingolstadt, and making sure they are built as close to city center as possible, that is to Dortmund and not just Hamm, to Frankfurt and not just Hanau, etc.
• Purchasing 300 km/h trains and not just 250 km/h ones; the trains cost more but the travel time reduction is noticeable and certain key connections work out for a higher-speed D-Takt only at 300, not 250.
• Designing high-speed lines for the exclusive use of passenger trains, rather than mixed lines with gentler freight-friendly grades and more tunnels. Germany has far more high-speed tunneling than France, not because its geography is more rugged, but because it builds mixed lines.
• Accelerating construction and reducing costs through removal of NIMBY veto points. Groups should have only two months to object, as in Spain; current practice is that groups have two months to say that they will object but do not need to say what the grounds for those objections are, and subsequently they have all the time they need to come up with excuses.

# Trains are not Planes

Trains and planes are both scheduled modes of intercity travel running large vehicles. Virgin runs both kinds of services, and this leads some systems to treat trains as if they are planes. France and Spain are at the forefront of trying to imitate low-cost airlines, with separately branded trains for different classes of passengers and yield management systems for pricing; France is even sending the low-cost OuiGo brand to peripheral train stations rather than the traditional Parisian terminals. This has not worked well, and unfortunately the growing belief throughout Europe is that airline-style competition on tracks is an example of private-sector innovation to be nourished. I’d like to explain why this has failed, in the context of trains not being planes.

How do trains and planes differ?

All of the following features of trains and planes are relevant to service planning:

Taken together, these features lead to differences in planning and pricing. Plane and train seats are perishable – once the vehicle leaves, an unsold seat is dead revenue and cannot be packaged for later. But trains have low enough variable costs that they do not need 100% seat occupancy to turn a profit – the increase in cost from running bigger trains is small enough that it is justified on other grounds. Conversely, trains can be precisely scheduled so as to provide timed connections, whereas planes cannot. This means the loci of innovation are different for these two technologies, and not always compatible.

What are the main innovations of LCCs?

European low-cost carriers reduce cost per seat-km to around 0.05€ (source: the Spinetta report). They do so using a variety of strategies:

• Using peripheral, low-amenity airports located farther from the city, for lower landing fees (and often local subsidies).
• Eliminating such on-board services as free meals.
• Using crew for multiple purposes, as both boarding agents and air crew.
• Flying for longer hours, including early in the morning and later at night, to increase equipment utilization, charging lower fares at undesirable times.
• Running a single class of airplane (either all 737 or all 320) to simplify maintenance.

They additionally extract revenue from passengers through hidden fees only revealed at the last moment of purchase, aggressive marketing of on-board sales for ancillary revenue, and an opaque yield management system. But these are not cost cutting, just deceptive marketing – and the yield management system is in turn a legacy carrier response to the threat of competition from LCCs, which offer simpler one-way fares.

How are LCC innovations relevant to trains?

On many of the LCC vs. legacy carrier distinctions, daytime intercity trains have always been like LCCs. Trains sell meals at on-board cafes rather than providing complimentary food and drinks; high-speed rail carriers aim at fleet uniformity as much as practical, using scale to reduce unit maintenance costs; trains have high utilization rates using their low variable operating costs.

On others, it’s not even possible to implement the LCC feature on a railroad. SNCF is trying to make peripheral stations work on some OuiGo services, sending trains from Lyon and Marseille to Marne-la-Vallée and reserving Gare de Lyon for the premium-branded InOui trains. It doesn’t work: the introduction of OuiGo led to a fall in revenue but no increase in ridership, which on the eve of corona was barely higher than on the eve of the financial crisis despite the opening of three new lines. The extra access and egress times at Marne-la-Vallée and the inconvenience imposed by the extra transfer with long lines at the ticketing machines for passengers arriving in Paris are high enough compared with the base trip time so as to frustrate ridership. This is not the same as with air travel, whose origins are often fairly diffuse because people closer to city center can more easily take trains.

What innovations does intercity rail use?

Good intercity train operating paradigms, which exist in East Asia and Northern Europe but not France or Southern Europe, are based on treating trains as trains and not as planes (East Asia treats them more like subways, Northern Europe more like regional trains). This leads to the following innovations:

• Integration of timetable and infrastructure planning, taking advantage of the fact that the infrastructure is built by the state and the operations are either by the state or by a company that is so tightly linked it might as well be the state (such as the Shinkansen operators). Northern European planning is based on repeating hourly or two-hourly clockface timetables.
• Timed connections and overtakes, taking advantage of precise timetabling.
• Very fast turnaround times, measured in minutes; Germany turns trains at terminal stations in 3-4 minutes when they go onward, such as from north of Frankfurt or Leipzig to south of them with a reversal of the train direction, and Japan turns trains at the end of the line in 12 minutes when it needs to.
• Short dwell times at intermediate stops – Shinkansen trains have 1-minute dwell times when they’re not sitting still at a local station waiting to be overtaken by an express train.
• A knot system in which trips are sped up so as to fit into neat slots with multiway timed connections at major stations – in Switzerland, trains arrive at Zurich, Basel, and Bern just before the hour every half hour and depart just after.
• Fare systems that reinforce spontaneous trips, with relatively simple fares such that passengers don’t need to plan trips weeks in advance. East Asia does no yield management whatsoever; Germany does it but only mildly.

All of these innovations require public planning and integration of timetable, equipment, and infrastructure. These are also the exact opposite of the creeping privatization of railways in Europe, born of a failed British ideological experiment and a French railway that was overtaken by airline executives bringing their own biases into the system. On a plane, my door-to-door time is so long that trips are never spontaneous, so there’s no need for a memorable takt or interchangeable itineraries; on a train, it’s the exact opposite.

# EU Reaches Deal for Eastern European Infrastructure Investment

EU Commission President Ursula von der Leyen announced this morning that the EU will proceed with a coordinated investment plan for Ukraine, whose EU membership is a foregone conclusion at this point, as well as for surrounding EU member states. This will include a cohesion fund for both war reconstruction and long-term investment, which will have a component marked for Belarus’s incorporation into the Union as well subject to the replacement of its current regime with a democratic government.

To handle the infrastructure component of the plan, an EU-wide rail agency, to be branded Eurail, will take over the TEN-T plan and extend it toward Ukraine. Sources close to all four major pro-European parties in the EU Parliament confirm that the current situation calls for a European solution, focusing on international connections both internally to the established member states and externally to newer members.

The office of French President Emmanuel Macron says that just as SNCF has built modern France around the TGV, so will Eurail build modern Europe around the TEN-T network, with Paris acting as the center of a continental-scale high-speed rail network. An anonymous source close to the president spoke more candidly, saying that Brussels will soon be the political capital of an ever closer economic and now infrastructural union, but Paris will be its economic capital, just as the largest city and financial center in the United States is not Washington but New York and that of Canada is not Ottawa but Toronto.

In Eastern Europe, the plan is to construct what German planners have affectionately called the Europatakt. High-speed rail lines, running at top speeds ranging between 200 and 320 km/h, are to connect the region as far east as Donetsk and as far northeast as Tallinn, providing international as well as domestic connections. Regional trains at smaller scale will be upgraded, and under the Europatakt they will be designed to connect to one another as well as to long-distance trains at regular intervals.

For example, the main east-west corridor is to connect Berlin with Kyiv via Poznań, Łódź, Warsaw, Lublin, Lutsk, and Zhytomyr. Berlin-Warsaw trips are expected to take 2.5 hours and Warsaw-Kyiv trips 3.5 hours, arranged so that trains on the main axis will serve Warsaw in both directions on the hour every hour, timing a connection with trains from Warsaw to Kaunas, Riga, Tallinn, and Helsinki and with domestic intercity and regional trains with Poland. In Ukraine, too, a connection will be set up in Poltava, 1.5 hours east of Kyiv, every hour on the hour as in Warsaw, permitting passengers to interchange between Kyiv, Kharkiv, Dnipro, and Donetsk.

Overall, the network through Poland, Ukraine, and the Baltic states, including onward connections to Berlin, Czechia, Bucharest, and Helsinki, is expected to be 6,000 km long, giving these countries comparable networks to those of France and Spain. The expected cost of the program is 150 billion euros plus another 50 billion euros for connections.

# How High-Speed and Regional Rail are Intertwined

The Transit Costs Project will wrap up soon with the report on construction cost differences, and we’re already looking at a report on high-speed rail. This post should be read as some early scoping on how this can be designed for the Northeast Corridor. In particular, integration of planning with regional rail is obligatory due to the extensive track sharing at both ends of the corridor as well as in the middle. This means that the project has to include some vision of what regional rail should look like in Boston, New York, Philadelphia, and Washington. This vision is not a full crayon, but should have different options for different likely investment levels and how they fit into an intercity vision, within the existing budget, which is tens of billions thanks to the Bipartisan Infrastructure Framework.

Boston

In Boston, commuter rail and intercity rail interact via the Providence Line, which is double-track. The Providence Line shares the same trunk line into Boston with the Franklin Line and the Stoughton Line, and eventually with South Coast Rail services.

The good news is that the MBTA is seriously looking at electrifying the trains to a substantial if insufficient extent. The Providence Line is already wired, except for a few siding and yard tracks, and the MBTA is currently planning to complete electrification and purchase EMUs on the main line, and possibly also on the Stoughton Line; South Coast Rail is required to be electrified when it is connected to this system anyway, for environmental reasons. If there is no further electrification, then it signals severe incompetence in Massachusetts but is still workable to a large extent.

Options for scheduling depend on how much further the state invests. The timetables I’ve written in the past (for an aggressive example, see here) assume electrification of everything that needs to be electrified but no North-South Rail Link tunnel. An NSRL timetable requires planning high-speed rail in conjunction with the entirety of the regional rail system; this is true even though intercity trains should terminate on the surface and not use the NSRL tunnel.

Philadelphia is the easiest case. Trenton-Philadelphia is four-track, and has sufficiently little commuter traffic that the commuter trains can be put on the local tracks permanently. In the presence of high-speed rail, there is no need for express commuter trains – passengers can buy standing tickets on Trenton-Philadelphia, and those are not going to create a capacity crunch because train volumes need to be sized for the larger peak market into New York anyway.

On the Wilmington side, the outer end of the line is only triple-track. But it’s a short segment, largely peripheral to the network – the line is four-track from Philadelphia almost all the way to Wilmington, and beyond Wilmington ridership is very low. Moreover, Wilmington itself is so slow that it may be valuable to bypass it roughly along I-95 anyway.

The railway junctions are a more serious interface. Zoo Interlocking controls everything heading into Philadelphia from points north, and needs some facelifts (mainly, more modern turnouts) speeding up trains of all classes. Thankfully, there is no regional-intercity rail conflict here.

Washington

In some ways, the Washington-Baltimore Penn Line is a lot like the Boston-Providence line. It connects two historic city centers, but one is much larger than the other and so commuter demand is asymmetric. It has a tail behind the secondary city with very low ridership. It runs diesel under catenary, thanks to MARC’s recent choice to deelectrify service (it used to run electric locomotives).

But the Penn Line has significant sections of triple- and quad-track, courtesy of a bad investment plan that adds tracks without any schedule coordination. The quad-track segment can be used to simplify the interface; the triple-track segment, consisting of most of the line’s length, is unfortunately not useful for a symmetric timetable and requires some strategic quad-track overtakes. The Penn Line must be reelectrified, with high-performance EMUs minimizing the speed difference between regional and intercity trains. There are only five stations on the double- and triple-track narrows – BWI, Odenton, Bowie State, Seabrook, New Carrollton – and even figuring differences in average speed, this looks like a trip time difference between 160 km/h regional rail and 360 km/h HSR of about 15 minutes, which is doable with a single overtake.

New York

New York is the real pain point. Unlike in Boston and Washington, it’s difficult to isolate different parts of the commuter rail network from one another. Boston can more or less treat the Worcester, Providence+Stoughton, Fairmount, and Old Colony Lines as four different, non-interacting systems, and then slot Franklin into either Providence or Fairmount, whichever it prefers. New York can, with current and under-construction infrastructure, plausibly separate out some LIRR lines, but this is the part of the system with the least interaction with intercity rail.

Gateway could make things easier, but it would require consciously treating it as total separation between the Northeast Corridor and Morris and Essex systems, which would be a big mismatch in demand. (NEC demand is around twice M&E demand, but intercity trains would be sharing tracks with the NEC commuter trains, not the M&E ones; improving urban commuter rail service reduces this mismatch by loading the trains more within Newark but does not eliminate it.)

It’s so intertwined that the schedules have to be done de novo on both systems – intercity and regional – combined. This isn’t as in Boston and Washington, where the entire timetable can be done to fit one or two overtakes. This isn’t impossible – there are big gains to be had from train speedups all over and there. But it requires cutting-edge systems for timetabling and a lot of infrastructure investment, often in places that were left for later on official plans.