Clock-face scheduling

A clock-face schedule or cyclic schedule is a timetable system under which public transport services run at consistent intervals, as opposed to a timetable that is purely driven by demand and has irregular headways. The name derives from the fact that departures take place at the same time or times during the day. For example, services with a half-hourly frequency might leave at 5:15, 5:45, 6:15, 6:45, 7:15, 7:45 etc.

Example of integrated timetables between interregional and regional services on the Swiss network. The two trains are programmed to meet in the hub of Geneva around 15:30 and also share a platform to minimise transfer times.

The goal is to enhance the attractiveness and versatility of public transport. Clock-face schedules are easy for passengers to memorise because departure and arrival times occur at consistent intervals, repeating during the day. A regular repeating schedule over the whole day can also improve services during off-peak hours. Clock-face timetables can be attractive for transport operators because the repeating pattern can allow the more efficient use of personnel, infrastructure and vehicles, and also make resource-planning easier.

Repeating timetables were first developed at the end of the 19th century, for local public transport, such as trams, rapid transit, and trains in the vicinity of large cities like New York City. A clock-face schedule is used currently for the New York City Subway system, the London Underground, and Merseyrail's Northern and Wirral lines.

Line-based

Individual lines can have a regular schedule, even without connections to other lines. Nevertheless, it could be necessary to co-ordinate the schedules of different modes of transport if links are made between them, such as at the terminal stop of a tram network if a journey can be continued by bus, so that passengers do not have to wait long at transfer point until the next service arrives.

Clock-face timetables can be attractive even if services provide no connections to other public transport because they allow a continuous use of vehicles and personnel.

Line-bound regular timetables are especially useful for lines with high service frequencies. If vehicles with the same destination follow each other in short intervals, transfer times are short even if there are delays. However, if the service intervals are 20 minutes or longer, it is important for schedules on each line to be officially co-ordinated. One simple way of doing that is to shift the departure times of one of the lines to match the other.

Network-based

Buses meet in Herford, Alter Markt

An integrated schedule is a clock-face schedule that covers not individual lines but all public transport services in a given area. A characteristic of integrated clock-face timetables is that there is more than one central hub. A hub-and-spoke approach is then applied to the whole transport network.

Having several services meet at hubs where all of them arrive and leave at the same time is the most effective way of connecting multiple routes and modes. The goal is to reduce transfer times to a few minutes, with a default time of no more than five minutes. In actual operation, the time span can be longer because of services running early or late, high passenger volume (such as rush hour), or the need to assist passengers with disabilities. Efficient operation is even more essential than normal with integrated clock-face timetabling. If the policy is to hold connecting services to ensure a connection with a late-running service, waiting times at interchange stops can become unattractive, and other services will run late as a consequence.

Examples of such networks are often night and city bus networks. The connections might be optimized only within the network but not for transfers to rail or intercity bus lines. Such concepts need purpose-built stations, which can handle high passenger volumes. The space constraints within cities can be a reason to use other concepts.

An integrated regular timetable with half-hourly or hourly headways requires routes on which a service takes 28 or 58 minutes to make it from one hub to another. A service that takes 40 minutes would be bad because passengers and vehicles have to wait uselessly for their connections, and it generates nearly the same cost as a route that takes 58 minutes because vehicles and personnel cannot be used during the remaining 20 minutes. Therefore, when an integrated timetable is introduced running times might be cut or extended to meet the ideal duration.

Emergence of integrated timetables

The first integrated regular timetables were developed for railways. After the successful introduction of a line-bound regular timetable on one line in Switzerland in 1968,[1] the development continued in the Netherlands. In 1970 and 1971, Nederlandse Spoorwegen introduced a regular timetable with multiple hubs. In Germany, the first large-scale use of regular timetables was the InterCity network of 1979, which provided hourly long-distance services between cities. In 1982, a nationwide integrated regular timetable was introduced in Switzerland, which covered all but a few railway and bus lines. The base frequency was once an hour. The system was improved every two years and resulted in the Rail 2000 project of Swiss Federal Railways.

A regional bus service meets an interregional train service at Leuk (Switzerland) train station

Switzerland

Services on the Swiss railway network are integrated with one another and with other forms of public transport. Unlike its larger European neighbors, compact Switzerland has not developed a comprehensive high-speed rail network,[2] with the running speed on its few stretches[3] of relatively high-speed line being 200 km/h (124 mph).[4] Instead, the priority is not so much the speeding up of trains between cities but the reduction of connection times throughout the nodal system.[5] Swiss Federal Railways have adapted their infrastructure in such a way that journey times on main lines between hubs are multiples of 30 minutes so that on the hour or half-hour, all trains stand in the main stations at the same time, thus minimising connection times. Indeed, the above-mentioned Mattstetten–Rothrist line reduces journey times from Bern to Zurich from 72 minutes to 56 minutes[6] in keeping with the clock-face scheduling.[7]

However, on some single tracked lines the timetables may be 30/30 or 60/60 minutes, with the actual timetables being asymmetrical (such as 20/40 minutes), because passing loops are not positioned ideally, or alternate connections at either ends have to be reached.

Germany

Since 1990, most of the states of Germany have introduced integrated timetables, running hourly or every two hours, for short-distance public transport such as Allgäu-Schwaben-Takt (commencing in 1993), Rheinland-Pfalz-Takt (1994) and NRW-Takt (1998). Transport associations have introduced regular timetables with base frequencies of 20 or 30 minutes, which are partially changed to 10 or 5 or even 15 or 7.5 minutes when locations are served by overlapping multiple lines. In some areas, local buses are also integrated, such as RegioTakt in Northrhine-Westphalia and in parts of Lower Saxony.

These developments have led to "integrated timetable islands", which all adhere to the Germany-wide symmetry minute (58½), which is used also in Switzerland and in other European countries. Major problems exist in regions where transport associations of different states interact (like in Osnabrück). In order to introduce a Germany-wide integrated regular timetable, the alliance "Deutschland-Takt" was founded in 2008. Its goal is to start a discussion about a better system for public transport in Germany and to highlight aspects needing improvement.[8] In 2015, the Federal Ministry of Transport had a feasibility study conducted for a Germany-wide integrated timetable[9][10]

References

  1. "Der Einzug der Bahn in die Schweiz". ned.gschieder.ch (in German). 6 March 2008. Archived from the original on 6 March 2008. Retrieved 1 January 2019.
  2. "Railway upgrades include no fast track". swissinfo.ch. Retrieved 21 April 2018.
  3. Mattstetten - Rothrist line, Lötschberg Base Tunnel and Gotthard Base Tunnel (to open in 2016)
  4. European Railway Review (3): 98. 2007. Missing or empty |title= (help)
  5. p3. "Archived copy" (PDF). Archived from the original (PDF) on 2013-10-12. Retrieved 2015-04-17.CS1 maint: archived copy as title (link)
  6. "Timetable Olten - Zürich (field 650)" (PDF). www.fahrplanfelder.ch. Federal Office of Transport SBB, The Swiss Railway. Retrieved 5 October 2014.
  7. Alonso Martínez, Lydia. "LEARNING FROM SWISS TRANSPORT POLICY" (PDF). www.upc.edu. UPC. Universitat Politècnica de Catalunya. BarcelonaTech. Retrieved 5 October 2014.
  8. "deutschland-takt.de". deutschland-takt.de. Archived from the original on 11 October 2016. Retrieved 21 April 2018.
  9. "Infrastruktur für einen Deutschland-Takt im Schienenverkehr" (in German). Federal Ministry of Transport and Digital Infrastructure. Retrieved 10 August 2018.
  10. ARGE IGES Institut GmbH; Institut für Verkehrswesen, Eisenbahnbau und ‐betrieb der Technischen Universität Carolo‐Wilhelmina zu Braunschweig (IVE) (30 March 2015). Machbarkeitsstudie zur Prüfung eines Deutschland‐Takts im Schienenverkehr (PDF) (Report) (in German). Federal Ministry of Transport and Digital Infrastructure.
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