fbpx
Wikipedia

Passenger information system

October 22, 2023

Not to be confused with Passenger service system.

A passenger information system, or passenger information display system, is an automated system for supplying users of public transport with information about the nature and the state of a public transport service through visual, voice or other media. It is also known as a customer information system or an operational information system.[1] Among the information provided by such systems, a distinction can be drawn between:

  • Static or schedule information, which changes only occasionally and is typically used for journey planning prior to departure.
  • Real-time information, derived from automatic vehicle location systems and changes continuously as a result of real-world events, which is typically used during the course of a journey (primarily how close the service is running to time and when it is due at a stop, as well as incidents that affect service operations, platform changes, etc.).
Central Train Indicator at Hilversum railway station announcing the Intercity towards Deventer; probably because of a disruption, it today ends at Amersfoort.

Static information has traditionally been made available in printed form though route network maps and timetable booklets at transit stations. However, most transit operators now also use integrated passenger information systems that provide either schedule-based information through a journey planner application or schedule-based information in combination with real-time information.

Real-time information is an advance on schedule-only information, which recognises the fact that public transport services do not always operate exactly according to the published timetable. By providing real-time information to travellers, they are better able to conduct their journey confidently, including taking any necessary steps in the event of delays.[2] That helps to encourage greater use of public transport,[3][4] which for many countries is a political goal.

Real-time information is provided to passengers in a number of different ways, including mobile phone applications, platform-level signage, and automated public address systems.[5] It may include both predictions about arrival and departure times, as well as information on the nature and the cause of disruptions.

Issues with passenger information provision Edit

There are four principal considerations for the provision of passenger information (static or real time):

  • Data availability. Information can be provided only if it is available, and collecting information can be resource-intensive. Also, there may be difficulties with co-ordinating data sharing between multiple organisations.
  • Data accuracy. Collecting information is error-prone. Also, prediction algorithms are not perfect and so real-time announcements may be in error.
  • Getting information to the passenger. A variety of dissemination mechanisms may be used, but it is not always easy to ensure that the correct information reaches the passenger when it is most needed. Information overload must be avoided.
  • Latency or response time. Information provision must react quickly to a passenger request or a real-world update. There is little point in announcing a service three minutes after it has departed.

Real-time arrival prediction systems Edit

 
Bilingual real-time information is provided on every platform in the MTR passenger railway system in Hong Kong.
 
LED information display at Joanic station on the Barcelona Metro. The LED displays count down to the last second the time needed for a train to arrive at a station.

Current operational information on service running is collected from automatic vehicle location (AVL) systems and from control systems, including incident capture systems. The information can be compared algorithmically with the published service timetable to generate a prediction of how services will run in the next few minutes to hours. That may be informed by additional information. For instance, bus services are affected by congestion on the road network, and all services may be affected by adverse weather conditions.

Economic rationale Edit

The capital and revenue costs for traveller information systems can be calculated with reasonable accuracy. However, the derivation of tangible financial benefits is far more difficult to establish and as so there is very little research. That directs the business model for information systems towards the "softer" merits such as traveller confidence. It is worth noting that there must be an actual value, as individuals are willing to pay for systems that give them access to real-time data relating to their journey. The difficulty is establishing what that is for each individual person and perhaps each individual piece of roadside hardware. Even less is known about the long-term effects of access to these types of services. The only long-term study is from 2012.[6]

 
Information screen taken from the ceiling announcing delays on FGC line S1 at Sarrià station, Barcelona

Communication channels Edit

Information may be delivered via any electronic media, including:

Additional considerations include:

  • How the system presents information for disabled travellers
  • Whether the system provides information in multiple languages

Information Edit

 
Information display in a shelter at a TriMet bus stop in downtown Portland, Oregon

The information provided by a passenger information system depends on its location and the technical scope (e.g. the size of the display screen)

At a station or stop, it is normal to provide up-to-date predictions of:

  • Which service is operated by the next vehicle to arrive, including its route and destination.
  • When the vehicle will arrive.
  • How closely it is running to timetable.
  • Similar information for the following few services.
  • General advice on current travel disruptions that may be useful to the passenger in understanding the implications for their travel plans.

On a vehicle, it is normal to provide up to date predictions of:

  • When the vehicle will arrive at the next station or stop (express or long-distance services).
  • Advice on connecting services.

Personalised channels (web, mobile device, or kiosk) is normally set up to mimic the view from a station or stop, but they may in addition be linked to journey planners. Using such systems, a passenger may (re)plan their journey to take into account current circumstances (such as cancelled services or excessive delays).

Examples Edit

France Edit

In Paris, France, SIEL indicator systems (abbreviated from Système d’information en ligne) are installed in the RER, the Paris Métro and on 250 bus routes on the RATP bus system.

On the RER, two types of indicators are used. The first-generation model indicates only the termini of trains stopping at a station through the use of square lights beside the words bearing the name of a terminus. The second-generation model includes an LED display above the square lights indicating the terminus and train service. The displays are used only on the RER line A, RER line B and at Gare de Châtelet – Les Halles station on RER line D. They can be inaccurate at times because of the lack of communication between SNCF and RATP, the two operators of the RER.

On the Paris Métro, there are two types of information display systems. The LED numerical display installed in all Métro lines (except line 14) has been in use since 1997. The television display is installed on all stations on line 14. The displays show the time needed for a train (and the subsequent train after it) to reach a particular station.

On the bus network in Paris, monochrome LCDs have been used since 1996 to indicate the time needed for a bus on a bus route to arrive at a bus stop, after a two-year trial period on a few bus routes.

  •  

    1st generation termini indicator on the RER line A

  •  

    2nd generation termini indicator on the RER line B

  •  

    LED indicator on the Paris Métro

  •  

    A variant of the Métro's LED indicator used on Paris Métro Line 13 utilizing a lighted arrow indicating the terminus of the next train

  •  

    TV screen used on Paris Métro Line 14

  •  

    LCD used on Paris's bus system

Germany Edit

 
Stadtbahn passenger information display in Düsseldorf's new station at Heinrich-Heine-Allee with greeting message "welcome to the new network..."

Deutsche Bahn AG offers a Travel Information System (German: Reiseinformationssystem (RIS)). It shows current train times compared to the published timetable, as well as known delays and expected arrival and departure times of the trains. The information is made available to the train conductor (via SMS) as well as to the passenger via loudspeaker in the train station or schedule boards on the internet.[7] The corresponding VRR[8] and VRS[9] information systems also process RIS data. The data can also be queried in real-time via mobile devices like mobile phones.

The RIS was started in 2003, and by 2007, it was planned to have 30,000 trains equipped with the necessary train describer (electronic train number).[10] In an accompanying program the older split-flap displays were replaced by electronic dot-matrix signage. Large stations have platform displays with multiple rows, but the Deutsche Bahn network operator developed the Dynamic Font Indicator (German: Dynamischer Schriftanzeiger (DSA)) standard system for smaller stations with a single row. In 2011, a federal funding was granted to equip 4500 additional stations with DSA signage, making for most of the 6500 DSAs by 2015.

 
DSA passenger information system

The federal grant came along with a Federal Railway Authority (German: Eisenbahn-Bundesamt (EBA)) order in 2010 to have all stations connected to the travel information system to announce delays with electronic signage or loudspeakers. The Deutsche Bahn operator tried to block that order legally for stations with a very low frequency but lost all lawsuits in 2015.[11] It was given 18 months to equip the remaining stations with DSAs. The DSA system has a GSM radio module to receive a text message to be displayed in a horizontally-moving news ticker style. A loudspeaker may optionally be mounted on top. When there is no delay, the current time is shown statically on its 96×8 LED dot-matrix display.

 
A typical British passenger information display found on a station platform

United Kingdom Edit

National Rail stations are equipped with visual platform displays and audio announcements, which indicate the next service or services from the platform and warn passengers to stand clear of trains that are not scheduled to stop, not in use or are about to depart. Additionally, concourses and ticket offices have large screen displays that show all of the services available at the station for the next hour or more and, at major stations, the full route of the service and any restrictions applicable (e.g. ticket types, catering services, bicycle carriage). Many smaller and less well-used railway stations have, instead of such systems, "passenger help points", which connect the user by telephone to a control room by pressing an "Information" button.

The information is available online at National Rail[12] and on mobile devices.

Most London Underground stations have "countdown" displays on each platform. They are simpler than the national rail displays since most platforms serves only a single line, and there are few or no variations in carriage restrictions and destinations served. Audio announcements are also made regularly.

Local authorities and some transport operators provide electronic versions of the bus timetables to the Traveline[13] information service, which covers all public transport modes, and from there to other information services such as Transport Direct,[14] and Google Transit.[15]

The deployment of real-time bus information systems is a gradual process and currently extends to around half of the national fleet and a high proportion of town-centre stops but relatively few suburban and rural locations. The first use of such systems was in Brighton and Hove. The Traveline NextBuses[16] information service provides the next departures from any bus stop in the UK, and some trams as well. The information has the real-time feed that has been connected in; otherwise, the scheduled times are given.

The government-sponsored Transport Direct project provided journey planning across all transport modes (including private car) and was increasingly linked to real-time information systems prior to its discontinuation in 2014.

United States Edit

 
A PIDS at the King Street–Old Town station of the Washington Metro
 
A PIDS at the Lorimer Street station of the New York City Subway

Real-time passenger information was brought to riders in the US by NextBus corporation, a small start-up, in 1999. The first systems were installed in Emeryville, California, and later in San Francisco, California. As of 2012, both initial systems are still in operation.

The Washington Metro installed a passenger information display system (PIDS) in all of its stations in 2000. The system provides real-time information on next train arrivals, delayed trains, emergency announcements, and related information.[17] Metro also provides current train and related information to customers with conventional web browsers, as well as users of smartphones and other mobile devices.[18] In 2010, Metro began sharing its PIDS data with outside software developers for use in creating additional real-time applications for mobile devices. Free apps are available to the public on major mobile device software platforms (iPhone/iPad, Android, Windows Phone, Palm).[19][20] The system also began providing real-time train information by phone in 2010.[21]

The New York City Subway began installing its public address/customer information screens, commonly known as "countdown clocks", in its stations in 2007. In 2012, the system began offering SubTime, a website and iPhone app for real-time train arrival estimates for several of its subway services,[22] and the arrival data are shared with outside software developers to support creation of additional apps.[23] There are also PIDS installed on some MTA Regional Bus Operations routes over the years, but mostly, the MTA offers real-time bus tracking through another website/app called MTA Bus Time.[24][25]

The Boston MBTA Red, Orange, and Blue Lines introduced countdown locks in early 2014, and the Green Line introduced them the following year.[26][27] The eastern end of the Green Line introduced clocks in early 2016. They reflect how many "stops away" the train is, rather than how many minutes it will take to arrive.[28] Amtrak has deployed PIDS throughout the Northeast Corridor.

As of 2010, PIDS are being deployed with unified messaging, which can include information streamed to mobile devices, phones and translated directly to voice announcements. Text to Speech products have been designed to convert PIDS data to speech in a choice of over 20 languages.

See also Edit

References Edit

  1. ^ "Passenger Information Systems at Railway Stations" (PDF). AWS Amazon. November 2014. Retrieved 20 December 2017.
  2. ^ Ferris, Brian; Watkins, Kari; Borning, Alan (2010-01-01). "OneBusAway: Results from providing real-time arrival information for public transit". Proceedings of the SIGCHI Conference on Human Factors in Computing Systems. CHI '10. New York, NY, USA: ACM. pp. 1807–1816. doi:10.1145/1753326.1753597. ISBN 9781605589299. S2CID 8813050.
  3. ^ Brakewood, Candace; Macfarlane, Gregory S.; Watkins, Kari (2015-04-01). "The impact of real-time information on bus ridership in New York City". Transportation Research Part C: Emerging Technologies. 53: 59–75. doi:10.1016/j.trc.2015.01.021.
  4. ^ Tang, Lei; Thakuriah, Piyushimita (Vonu) (2012-06-01). "Ridership effects of real-time bus information system: A case study in the City of Chicago". Transportation Research Part C: Emerging Technologies. 22: 146–161. doi:10.1016/j.trc.2012.01.001.
  5. ^ Schweiger, Carol L.; Program, Transit Cooperative Research (2003-01-01). Real-time Bus Arrival Information Systems. Transportation Research Board. ISBN 9780309069656.
  6. ^ Skoglund, Tor (2012). Investigating the impacts of ICT - mediated services The case of public transport traveller information (PDF). Department of Product and Production Development Division Design & Human Factors Chalmers University of Technology.
  7. ^ "DB BAHN - Abfahrt und Ankunft". Bahn.de. Retrieved 2014-06-28.
  8. ^ "Verkehrsverbund Rhein-Ruhr - Fahrten planen". Vrr.de. Retrieved 2014-06-28.
  9. ^ . Archived from the original on 2006-07-05. Retrieved 2006-10-06.
  10. ^ "Schneller wissen, was los ist". Der Spiegel. 2003-04-10.
  11. ^ "Deutsche Bahn muss an Haltestellen über Verspätungen informieren". Die Zeit. 2015-09-09.
  12. ^ "nationalrail.co.uk". nationalrail.co.uk. Retrieved 2014-06-28.
  13. ^ "traveline.info". traveline.info. Retrieved 2014-06-28.
  14. ^ . transportdirect.info. Archived from the original on 2012-09-29. Retrieved 2014-06-28.
  15. ^ "Transit – Google Maps". Retrieved 2014-06-28.
  16. ^ "Traveline - mobile phone services". Traveline.info. Retrieved 2014-06-28.[permanent dead link]
  17. ^ Washington Metropolitan Area Transit Authority (WMATA) (2004-03-26). "Metro offers enhancements for the passenger information display monitors." 2016-08-20 at the Wayback Machine News release.
  18. ^ WMATA. "Mobile Services." 2008-12-08 at the Wayback Machine Accessed 2012-11-19.
  19. ^ WMATA (2010-08-06). "Metro invites software developers to discuss new transit data feed." 2016-08-20 at the Wayback Machine News release.
  20. ^ WMATA. "Developer Resources." 2016-11-18 at the Wayback Machine Accessed 2012-11-19.
  21. ^ WMATA (2010-08-31). "Real-time next train arrival information now available by phone." 2016-08-20 at the Wayback Machine News release.
  22. ^ http://apps.mta.info/traintime/
  23. ^ Metropolitan Transportation Authority, New York (2014-01-13). "MTA Adds Real-Time Arrival Estimates on L Line." MTA News.
  24. ^ "MTA Real-Time Bus Tracking Arriving in Brooklyn and Queens in March". Metropolitan Transportation Authority. February 24, 2014. Retrieved November 9, 2015.
  25. ^ Whitford, Emma (June 5, 2015). . Gothamist. Archived from the original on November 13, 2015. Retrieved November 9, 2015.
  26. ^ Meyers, Alyssa (9 October 2015). "More countdown clocks come to MBTA Green Line". The Daily Free Press - The Independent Student Newspaper at Boston University. Retrieved 2021-08-03.
  27. ^ Randall, Eric (11 May 2015). "Why Those Green Line Countdown Clocks Make Your Commute So Much Better". Boston Magazine. Retrieved 3 August 2021.
  28. ^ Levenson, Eric (20 January 2016). "Why the Green Line's new countdown clocks measure 'stops away' instead of time". Boston.com. Retrieved 3 August 2021.

October 22, 2023
passenger, information, system, confused, with, passenger, service, system, this, article, uses, bare, urls, which, uninformative, vulnerable, link, please, consider, converting, them, full, citations, ensure, article, remains, verifiable, maintains, consisten. Not to be confused with Passenger service system This article uses bare URLs which are uninformative and vulnerable to link rot Please consider converting them to full citations to ensure the article remains verifiable and maintains a consistent citation style Several templates and tools are available to assist in formatting such as reFill documentation and Citation bot documentation August 2022 Learn how and when to remove this template message A passenger information system or passenger information display system is an automated system for supplying users of public transport with information about the nature and the state of a public transport service through visual voice or other media It is also known as a customer information system or an operational information system 1 Among the information provided by such systems a distinction can be drawn between Static or schedule information which changes only occasionally and is typically used for journey planning prior to departure Real time information derived from automatic vehicle location systems and changes continuously as a result of real world events which is typically used during the course of a journey primarily how close the service is running to time and when it is due at a stop as well as incidents that affect service operations platform changes etc Central Train Indicator at Hilversum railway station announcing the Intercity towards Deventer probably because of a disruption it today ends at Amersfoort Static information has traditionally been made available in printed form though route network maps and timetable booklets at transit stations However most transit operators now also use integrated passenger information systems that provide either schedule based information through a journey planner application or schedule based information in combination with real time information Real time information is an advance on schedule only information which recognises the fact that public transport services do not always operate exactly according to the published timetable By providing real time information to travellers they are better able to conduct their journey confidently including taking any necessary steps in the event of delays 2 That helps to encourage greater use of public transport 3 4 which for many countries is a political goal Real time information is provided to passengers in a number of different ways including mobile phone applications platform level signage and automated public address systems 5 It may include both predictions about arrival and departure times as well as information on the nature and the cause of disruptions Contents 1 Issues with passenger information provision 2 Real time arrival prediction systems 2 1 Economic rationale 2 2 Communication channels 2 3 Information 3 Examples 3 1 France 3 2 Germany 3 3 United Kingdom 3 4 United States 4 See also 5 ReferencesIssues with passenger information provision EditThere are four principal considerations for the provision of passenger information static or real time Data availability Information can be provided only if it is available and collecting information can be resource intensive Also there may be difficulties with co ordinating data sharing between multiple organisations Data accuracy Collecting information is error prone Also prediction algorithms are not perfect and so real time announcements may be in error Getting information to the passenger A variety of dissemination mechanisms may be used but it is not always easy to ensure that the correct information reaches the passenger when it is most needed Information overload must be avoided Latency or response time Information provision must react quickly to a passenger request or a real world update There is little point in announcing a service three minutes after it has departed Real time arrival prediction systems Edit nbsp Bilingual real time information is provided on every platform in the MTR passenger railway system in Hong Kong nbsp LED information display at Joanic station on the Barcelona Metro The LED displays count down to the last second the time needed for a train to arrive at a station Current operational information on service running is collected from automatic vehicle location AVL systems and from control systems including incident capture systems The information can be compared algorithmically with the published service timetable to generate a prediction of how services will run in the next few minutes to hours That may be informed by additional information For instance bus services are affected by congestion on the road network and all services may be affected by adverse weather conditions Economic rationale EditThe capital and revenue costs for traveller information systems can be calculated with reasonable accuracy However the derivation of tangible financial benefits is far more difficult to establish and as so there is very little research That directs the business model for information systems towards the softer merits such as traveller confidence It is worth noting that there must be an actual value as individuals are willing to pay for systems that give them access to real time data relating to their journey The difficulty is establishing what that is for each individual person and perhaps each individual piece of roadside hardware Even less is known about the long term effects of access to these types of services The only long term study is from 2012 6 nbsp Information screen taken from the ceiling announcing delays on FGC line S1 at Sarria station BarcelonaCommunication channels Edit Information may be delivered via any electronic media including Mobile phone application LED displays and screens inside stations E paper displays and screens at bus stops and shelters Internet through a website Telephone either a staffed bureau service or an automated answering system Touch screen kiosks for self service e g in customer offices Additional considerations include How the system presents information for disabled travellers Whether the system provides information in multiple languagesInformation Edit nbsp Information display in a shelter at a TriMet bus stop in downtown Portland OregonThe information provided by a passenger information system depends on its location and the technical scope e g the size of the display screen At a station or stop it is normal to provide up to date predictions of Which service is operated by the next vehicle to arrive including its route and destination When the vehicle will arrive How closely it is running to timetable Similar information for the following few services General advice on current travel disruptions that may be useful to the passenger in understanding the implications for their travel plans On a vehicle it is normal to provide up to date predictions of When the vehicle will arrive at the next station or stop express or long distance services Advice on connecting services Personalised channels web mobile device or kiosk is normally set up to mimic the view from a station or stop but they may in addition be linked to journey planners Using such systems a passenger may re plan their journey to take into account current circumstances such as cancelled services or excessive delays Examples EditFrance Edit In Paris France SIEL indicator systems abbreviated from Systeme d information en ligne are installed in the RER the Paris Metro and on 250 bus routes on the RATP bus system On the RER two types of indicators are used The first generation model indicates only the termini of trains stopping at a station through the use of square lights beside the words bearing the name of a terminus The second generation model includes an LED display above the square lights indicating the terminus and train service The displays are used only on the RER line A RER line B and at Gare de Chatelet Les Halles station on RER line D They can be inaccurate at times because of the lack of communication between SNCF and RATP the two operators of the RER On the Paris Metro there are two types of information display systems The LED numerical display installed in all Metro lines except line 14 has been in use since 1997 The television display is installed on all stations on line 14 The displays show the time needed for a train and the subsequent train after it to reach a particular station On the bus network in Paris monochrome LCDs have been used since 1996 to indicate the time needed for a bus on a bus route to arrive at a bus stop after a two year trial period on a few bus routes nbsp 1st generation termini indicator on the RER line A nbsp 2nd generation termini indicator on the RER line B nbsp LED indicator on the Paris Metro nbsp A variant of the Metro s LED indicator used on Paris Metro Line 13 utilizing a lighted arrow indicating the terminus of the next train nbsp TV screen used on Paris Metro Line 14 nbsp LCD used on Paris s bus systemGermany Edit nbsp Stadtbahn passenger information display in Dusseldorf s new station at Heinrich Heine Allee with greeting message welcome to the new network Deutsche Bahn AG offers a Travel Information System German Reiseinformationssystem RIS It shows current train times compared to the published timetable as well as known delays and expected arrival and departure times of the trains The information is made available to the train conductor via SMS as well as to the passenger via loudspeaker in the train station or schedule boards on the internet 7 The corresponding VRR 8 and VRS 9 information systems also process RIS data The data can also be queried in real time via mobile devices like mobile phones The RIS was started in 2003 and by 2007 it was planned to have 30 000 trains equipped with the necessary train describer electronic train number 10 In an accompanying program the older split flap displays were replaced by electronic dot matrix signage Large stations have platform displays with multiple rows but the Deutsche Bahn network operator developed the Dynamic Font Indicator German Dynamischer Schriftanzeiger DSA standard system for smaller stations with a single row In 2011 a federal funding was granted to equip 4500 additional stations with DSA signage making for most of the 6500 DSAs by 2015 nbsp DSA passenger information systemThe federal grant came along with a Federal Railway Authority German Eisenbahn Bundesamt EBA order in 2010 to have all stations connected to the travel information system to announce delays with electronic signage or loudspeakers The Deutsche Bahn operator tried to block that order legally for stations with a very low frequency but lost all lawsuits in 2015 11 It was given 18 months to equip the remaining stations with DSAs The DSA system has a GSM radio module to receive a text message to be displayed in a horizontally moving news ticker style A loudspeaker may optionally be mounted on top When there is no delay the current time is shown statically on its 96 8 LED dot matrix display nbsp A typical British passenger information display found on a station platformUnited Kingdom Edit National Rail stations are equipped with visual platform displays and audio announcements which indicate the next service or services from the platform and warn passengers to stand clear of trains that are not scheduled to stop not in use or are about to depart Additionally concourses and ticket offices have large screen displays that show all of the services available at the station for the next hour or more and at major stations the full route of the service and any restrictions applicable e g ticket types catering services bicycle carriage Many smaller and less well used railway stations have instead of such systems passenger help points which connect the user by telephone to a control room by pressing an Information button The information is available online at National Rail 12 and on mobile devices Most London Underground stations have countdown displays on each platform They are simpler than the national rail displays since most platforms serves only a single line and there are few or no variations in carriage restrictions and destinations served Audio announcements are also made regularly Local authorities and some transport operators provide electronic versions of the bus timetables to the Traveline 13 information service which covers all public transport modes and from there to other information services such as Transport Direct 14 and Google Transit 15 The deployment of real time bus information systems is a gradual process and currently extends to around half of the national fleet and a high proportion of town centre stops but relatively few suburban and rural locations The first use of such systems was in Brighton and Hove The Traveline NextBuses 16 information service provides the next departures from any bus stop in the UK and some trams as well The information has the real time feed that has been connected in otherwise the scheduled times are given The government sponsored Transport Direct project provided journey planning across all transport modes including private car and was increasingly linked to real time information systems prior to its discontinuation in 2014 United States Edit nbsp A PIDS at the King Street Old Town station of the Washington Metro nbsp A PIDS at the Lorimer Street station of the New York City SubwayReal time passenger information was brought to riders in the US by NextBus corporation a small start up in 1999 The first systems were installed in Emeryville California and later in San Francisco California As of 2012 update both initial systems are still in operation The Washington Metro installed a passenger information display system PIDS in all of its stations in 2000 The system provides real time information on next train arrivals delayed trains emergency announcements and related information 17 Metro also provides current train and related information to customers with conventional web browsers as well as users of smartphones and other mobile devices 18 In 2010 Metro began sharing its PIDS data with outside software developers for use in creating additional real time applications for mobile devices Free apps are available to the public on major mobile device software platforms iPhone iPad Android Windows Phone Palm 19 20 The system also began providing real time train information by phone in 2010 21 The New York City Subway began installing its public address customer information screens commonly known as countdown clocks in its stations in 2007 In 2012 the system began offering SubTime a website and iPhone app for real time train arrival estimates for several of its subway services 22 and the arrival data are shared with outside software developers to support creation of additional apps 23 There are also PIDS installed on some MTA Regional Bus Operations routes over the years but mostly the MTA offers real time bus tracking through another website app called MTA Bus Time 24 25 The Boston MBTA Red Orange and Blue Lines introduced countdown locks in early 2014 and the Green Line introduced them the following year 26 27 The eastern end of the Green Line introduced clocks in early 2016 They reflect how many stops away the train is rather than how many minutes it will take to arrive 28 Amtrak has deployed PIDS throughout the Northeast Corridor As of 2010 update PIDS are being deployed with unified messaging which can include information streamed to mobile devices phones and translated directly to voice announcements Text to Speech products have been designed to convert PIDS data to speech in a choice of over 20 languages See also EditGeneral Transit Feed Specification Identification of Fixed Objects in Public Transport IFOPT IEEE Intelligent Transportation Systems Society Journey planner Platform display Real Time Information Group RTIG UK organisation Service Interface for Real Time Information SIRI technical specifications and standards Transmodel CEN European Reference Data ModelReferences Edit Passenger Information Systems at Railway Stations PDF AWS Amazon November 2014 Retrieved 20 December 2017 Ferris Brian Watkins Kari Borning Alan 2010 01 01 OneBusAway Results from providing real time arrival information for public transit Proceedings of the SIGCHI Conference on Human Factors in Computing Systems CHI 10 New York NY USA ACM pp 1807 1816 doi 10 1145 1753326 1753597 ISBN 9781605589299 S2CID 8813050 Brakewood Candace Macfarlane Gregory S Watkins Kari 2015 04 01 The impact of real time information on bus ridership in New York City Transportation Research Part C Emerging Technologies 53 59 75 doi 10 1016 j trc 2015 01 021 Tang Lei Thakuriah Piyushimita Vonu 2012 06 01 Ridership effects of real time bus information system A case study in the City of Chicago Transportation Research Part C Emerging Technologies 22 146 161 doi 10 1016 j trc 2012 01 001 Schweiger Carol L Program Transit Cooperative Research 2003 01 01 Real time Bus Arrival Information Systems Transportation Research Board ISBN 9780309069656 Skoglund Tor 2012 Investigating the impacts of ICT mediated services The case of public transport traveller information PDF Department of Product and Production Development Division Design amp Human Factors Chalmers University of Technology DB BAHN Abfahrt und Ankunft Bahn de Retrieved 2014 06 28 Verkehrsverbund Rhein Ruhr Fahrten planen Vrr de Retrieved 2014 06 28 VRS ONLINE Fahrplan Netz Fahrplanauskunft Archived from the original on 2006 07 05 Retrieved 2006 10 06 Schneller wissen was los ist Der Spiegel 2003 04 10 Deutsche Bahn muss an Haltestellen uber Verspatungen informieren Die Zeit 2015 09 09 nationalrail co uk nationalrail co uk Retrieved 2014 06 28 traveline info traveline info Retrieved 2014 06 28 transportdirect info transportdirect info Archived from the original on 2012 09 29 Retrieved 2014 06 28 Transit Google Maps Retrieved 2014 06 28 Traveline mobile phone services Traveline info Retrieved 2014 06 28 permanent dead link Washington Metropolitan Area Transit Authority WMATA 2004 03 26 Metro offers enhancements for the passenger information display monitors Archived 2016 08 20 at the Wayback Machine News release WMATA Mobile Services Archived 2008 12 08 at the Wayback Machine Accessed 2012 11 19 WMATA 2010 08 06 Metro invites software developers to discuss new transit data feed Archived 2016 08 20 at the Wayback Machine News release WMATA Developer Resources Archived 2016 11 18 at the Wayback Machine Accessed 2012 11 19 WMATA 2010 08 31 Real time next train arrival information now available by phone Archived 2016 08 20 at the Wayback Machine News release http apps mta info traintime Metropolitan Transportation Authority New York 2014 01 13 MTA Adds Real Time Arrival Estimates on L Line MTA News MTA Real Time Bus Tracking Arriving in Brooklyn and Queens in March Metropolitan Transportation Authority February 24 2014 Retrieved November 9 2015 Whitford Emma June 5 2015 MTA s Bus Tracker Is Now Available As An App Gothamist Archived from the original on November 13 2015 Retrieved November 9 2015 Meyers Alyssa 9 October 2015 More countdown clocks come to MBTA Green Line The Daily Free Press The Independent Student Newspaper at Boston University Retrieved 2021 08 03 Randall Eric 11 May 2015 Why Those Green Line Countdown Clocks Make Your Commute So Much Better Boston Magazine Retrieved 3 August 2021 Levenson Eric 20 January 2016 Why the Green Line s new countdown clocks measure stops away instead of time Boston com Retrieved 3 August 2021 Retrieved from https en wikipedia org w index php title Passenger information system amp oldid 1177268092, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.