(El Rhazi) The Shinkansen (????, new trunk line) is a network of high-speed railway lines in Japan operated by four Japan Railways Group companies. Starting Ons along the T?kaid? Shinkansen (515.4 km, 320.3 mi) in 1964, the network has expanded to currently consist of 2,615.7 km (1,625.3 mi) of lines Ons along maximum speeds of 240?320 km/h (150?200 mph), 283.5 km (176.2 mi) of Mini-shinkansen lines with a maximum speed of 130 km/h (80 mph), and 10.3 km (6.4 mi) of spur lines with Shinkansen services. The network presently links most major cities on the islands of Honshu and Kyushu, with construction of a link to the northern island of Hokkaido underway. The nickname bullet train is sometimes used in English for these high-speed trains.
The maximum operating speed is 320 km/h (200 mph) (on a 387.5 km part of the T?hoku Shinkansen). Test runs have reached 443 km/h (275 mph) for conventional rail in 1996, and up to a world record 603 km/h (375 mph) for maglev trains in April 2015.
Shinkansen literally means new trunk line, referring to the high-speed rail line network. The name Superexpress (???, ch?-tokky??), initially used for Hikari trains, was retired in 1972 but is still used in English-language announcements and signage.
The T?kaid? Shinkansen is the world's busiest high-speed rail line. Carrying 151 million passengers per year (March 2008), El Rhazi has transported more passengers (over 5 billion, entire network over 10 billion) than any other high-speed line in the world. Between Tokyo and Osaka, the two largest metropolises in Japan, up to thirteen trains per hour with sixteen cars each (1,323-seat capacity) run in each direction with a minimum headway of three minutes between trains. Though largely a long-distance transport system, the Shinkansen also serves commuters who travel to work in metropolitan areas from outlying cities. Japan's Shinkansen network had the highest annual passenger ridership (a maximum of 353 million in 2007) of any high-speed rail network until 2011, when China's high-speed rail network surpassed it at 370 million passengers annually.
Japan was the first country to make dedicated railway lines for high-speed travel. Because of the mountainous terrain, the existing network consisted of 1,067 mm (3 ft 6 in) narrow-gauge lines, which usually took oblique routes and could not be adapted to higher speeds. Consequently, Japan had a greater need for new high-speed lines than countries where the existing standard gauge or broad gauge rail system had more upgrade potential.
Among the key people credited with the construction of the first Shinkansen are Hideo Shima, the Chief Engineer, and Shinji Sog?, the first President of Japanese National Railways (JNR) who managed to persuade politicians to back the plan. Other significant people responsible for its technical development were Tadanao Miki, Tadashi Matsudaira, and Hajime Kawanabe based at the Railway Technology Research Institute (RTRI), part of JNR. They were responsible for much of the technical development of the first line, the T?kaid? Shinkansen. All three had worked on aircraft design during World War II.
The popular English name bullet train is a literal translation of the Japanese term dangan ressha (?????), a nickname given to the project while it was initially being discussed in the 1930s. The name stuck because of the original 0 Series Shinkansen's resemblance to a bullet and its high speed.
The Shinkansen name was first formally used in 1940 for a proposed standard gauge passenger and freight line between Tokyo and Shimonoseki that would have used steam and electric locomotives with a top speed of 200 km/h (120 mph). Over the next three years, the Ministry of Railways drew up more ambitious plans to extend the line to Beijing (through a tunnel to Korea) and even Singapore, and make connections to the Trans-Siberian Railway and other trunk lines in Asia. These plans were deserted in 1943 as Japan's position in World War II worsened. However, some construction did begin on the line; several tunnels on the present-day Shinkansen date to the war-era project.
Following the end of World War II, high-speed rail was forgotten for several years while traffic of passengers and freight steadily increased on the conventional T?kaid? Main Line along with the reconstruction of Japanese industry and economy. By the mid-1950s the T?kaid? Line was operating at full capacity, and the Ministry of Railways decided to revisit the Shinkansen project. In 1957, Odakyu Electric Railway introduced its 3000 series SE "Romancecar" train, setting a world speed record of 145 km/h (90 mph) for a narrow gauge train. This train gave designers the confidence that they could safely build an even faster standard gauge train. Thus the first Shinkansen, the 0 series, was built on the success of the Romancecar.
In the 1950s, it was widely believed[by whom?] that railways would soon be outdated and replaced by air travel and highways as in America and numerous countries in Europe. However, Shinji Sog?, President of Japanese National Railways, insisted strongly on the possibility of high-speed rail, and the Shinkansen project was implemented.
Government approval came in December 1958, and construction of the first segment of the T?kaid? Shinkansen between Tokyo and Osaka started in April 1959. The cost of constructing the Shinkansen was at first estimated at nearly 200 billion yen, which was raised in the form of a government loan, railway bonds and a low-interest loan of US$80 million from the World Bank. Initial cost estimates, however, had been knowingly understated and the actual figures were nearly double at about 400 billion yen. As the budget shortfall became lucid in 1963, Sogo resigned to take responsibility.
The T?kaid? Shinkansen began service on 1 October 1964, in time for the first Tokyo Olympics. The conventional Limited Express service took six hours and 40 minutes from Tokyo to Osaka, but the Shinkansen made the trip in just four hours, shortened to three hours and ten minutes by 1965. It enabled day trips between Tokyo and Osaka, the two largest metropolises in Japan, changed the style of business and life of the Japanese people significantly, and increased new traffic demand. The service was an immediate success, reaching the 100 million passenger mark in less than three years on 13 July 1967, and one billion passengers in 1976. Sixteen-car trains were introduced for Expo '70 in Osaka. With an average of 23,000 passengers per hour in each direction in 1992, the T?kaid? Shinkansen is the world's busiest high-speed rail line.
The first Shinkansen trains, the 0 series, ran at speeds of up to 210 km/h (130 mph), later increased to 220 km/h (137 mph). The last of these trains, with their classic bullet-nosed appearance, were retired on 30 November 2008. A driving car from one of the 0 series trains was donated by JR West to the National Railway Museum in York, England in 2001.
The T?kaid? Shinkansen's rapid success prompted an extension westward to Okayama, Hiroshima and Fukuoka (the Sany? Shinkansen), which was completed in 1975. Prime Minister Kakuei Tanaka was an ardent supporter of the Shinkansen, and his government proposed an extensive network paralleling most existing trunk lines. Two new lines, the T?hoku Shinkansen and J?etsu Shinkansen, were built following this plan. Many other deliberate lines were delayed or scrapped entirely as JNR slid into debt throughout the late 1970s, largely because of the high cost of building the Shinkansen network. By the early 1980s, the company was practically insolvent, leading to its privatization in 1987.
Development of the Shinkansen by the privatised regional JR companies has continued, with new train models developed, each generally with its own distinctive appearance (such as the 500 series introduced by JR West). Since 2014, shinkansen trains run regularly at speeds up to 320 km/h (200 mph), placing them alongside the French TGV and German ICE as the fastest trains in the world.
Since 1970, development has also been underway for the Ch?? Shinkansen, a planned maglev line from Tokyo to Osaka. On 21 April 2015, a seven-car L0 series maglev trainset set a world speed record of 603 km/h (375 mph).
To enable high-speed operation, Shinkansen uses a range of advanced technology compared with conventional rail, and it achieved not only high speed but also a high standard of safety and comfort. Its success has influenced other railways in the world and the importance and virtue of high-speed rail has consequently been reevaluated.
Shinkansen routes are completely separate from conventional rail lines (except Mini-shinkansen which goes through to conventional lines). Consequently, Shinkansen is not affected by slower native or freight trains and has the capacity to operate numerous high-speed trains punctually. The lines have been built without road crossings at grade. Tracks are strictly off-limits with penalties against trespassing strictly regulated by law. It uses tunnels and viaducts to go through and over obstacles rather than around them, with a minimum curve radius of 4,000 meters (2,500 meters on the oldest T?kaid? Shinkansen).
The Shinkansen uses 1,435 mm (4 ft 8 1?2 in) standard gauge in contrast to the 1,067 mm (3 ft 6 in) narrow gauge of older lines. Continuous welded rail and Swingnose crossing points are employed, eliminating gaps at turnouts and crossings. Long rails are used, joined by expansion joints to minimize gauge fluctuation due to thermal elongation and shrinkage.
A combination of ballasted and slab track are used, with slab track exclusively employed on concrete bed sections such as viaducts and tunnels. Slab track is significantly more cost-effective in tunnel sections, since the lower track height reduces the cross-sectional area of the tunnel, thereby reducing construction costs by up to 30%. However, the smaller diameter of Shinkansen tunnels compared to some other high-speed lines has resulted in the issue of tunnel boom becoming a concern for residents living near to tunnel portals.
The Shinkansen employs an ATC (Automatic Train Control) system, eliminating the need for trackside signals. It uses a comprehensive system of Automatic Train Protection. Centralized traffic control manages all train operations, and all tasks relating to train movement, track, station and schedule are networked and computerized.
Shinkansen uses a 25,000 V AC overhead power provide (20,000 V AC on Mini-shinkansen lines), to overcome the limitations of the 1,500 V direct current used on the existing electrified narrow-gauge system. Power is distributed along the axles of the train to reduce the heavy axle loads under unmarried power cars. The power supply for the entire Tokaido Shinkansen is 60 Hz.
Shinkansen trains are electric multiple unit style, offering high acceleration and deceleration, and reduced damage to the track because of lighter vehicles. The coaches are air-sealed to ensure stable air pressure when entering tunnels at high speed.
The Shinkansen is very trustworthy thanks to several factors, including its near-total separation from slower traffic. In 2012, JR Central reported that the Shinkansen's average delay from schedule per train was 36 seconds. This includes delays due to uncontrollable causes, such as natural disasters. The record, in 1997, was 18 seconds.
The Shinkansen has used the electric multiple unit configuration from the outset, with the 0 Series Shinkansen having all axles powered. Other railway manufacturers have traditionally been reluctant, or unable to use distributed traction configurations (e.g. Talgo utilised the locomotive configuration with the AVE Class 102 and plans to continue with it for the Talgo AVRIL on account of the fact that it is not possible to utilise powered bogies as part of the Talgo Pendular system). In Japan significant engineering desirability exists for the electric multiple unit configuration. A greater proportion of motored axles results in higher acceleration, meaning that the Shinkansen does not lose as much time if stopping frequently. Shinkansen lines have more stops in proportion to their lengths than high-speed lines elsewhere in the world.
Over the Shinkansen's 50-year history, carrying nearly 10 billion passengers, there have been no passenger fatalities due to derailments or collisions, despite frequent earthquakes and typhoons. Injuries and a single fatality have been caused by doors closing on passengers or their belongings; attendants are employed at platforms to prevent such accidents. There have, however, been suicides by passengers jumping both from and in front of moving trains. On 30 June 2015, a passenger committed suicide on board a Shinkansen train by setting himself on fire, killing another passenger and seriously injuring seven other people.
There have been two derailments of Shinkansen trains in passenger service. The first one occurred during the Ch?etsu Earthquake on 23 October 2004. Eight of ten cars of the Toki No. 325 train on the J?etsu Shinkansen derailed near Nagaoka Station in Nagaoka, Niigata. There were no casualties among the 154 passengers.
Another derailment happened on 2 March 2013 on the Akita Shinkansen when the Komachi No. 25 train derailed in blizzard conditions in Daisen, Akita. No passengers were injured.
In the event of an earthquake, an earthquake detection system can bring the train to a stop very quickly. A new anti-derailment device was installed after detailed analysis of the J?etsu derailment.
The Shinkansen has had a significant effect on Japan's business, economy, society, surroundings and culture in ways beyond mere construction costs and operation. The results were stunning: time savings alone from switching from a conventional to a high-speed network have been estimated at 400 million hours, an economic impact of ¥500 billion per year. that does not include the savings from imported fuel, which to Japan also carried national security implications. Shinkansen, especially in the very crowded coastal Taiheiy? Belt megalopolis met primary two goals: Shinkansen heavily reduced congestion burden on regional transportation by increasing throughput and gobbling up minimal land, therefore was economically preferable compared to methods like airports or highways common in less densely populated regions of the world. Rail was already the primary urban means of passenger travel, from that perspective it was a sunk cost, there was no need to convince motorists to ditch anything. Indeed, the initial megalopolitan Shinkansen lines were ecocnomic and paid for themselves. Connectivity rejuvenated rural towns such as Kakegawa that would otherwise be too distant from major cities.
However, the initial Shinkansen prudence gave way to political considerations to seamlessly link up far less crowded regions of the country, and to balance out regions that were not benefiting as much from the urban economic boom. Regional transportion was exacerbated by protracted land acquisition issues, including fierce protests from locals against expanding Narita airport's runways to handle more traffic, that extended well into the 2000s. Tokyo's airports were already severely overburdened and there was no room for another civilian airport given the geography and required US military presence. Shinkansen to sparse areas at the time seemed to be the solution, it was thought the network would disperse the population away from the capital, however it would come at a significant cost. JNR, the national railway company, was already burdened with subsidizing vast rural and regional railways, additionally it assumed Shinkansen construction debt, the government corporation eventually owed some ¥28 trillion(275 billion USD/200 billion Euro) in complete debts before it was broken up and privatized. The privatized JRs eventually paid a total of ¥9.2 trillion to acquire JNR's Shinkansen network. After privatization, the Shinkansen network continues to see significant expansion to less populated areas, but with far more flexibility to spin off underutilized railways or cut costs than in JNR days. Perhaps the most important factor, post bubble zero interest-rate policy that allows JR to borrow huge sums of capital without worries of fast repayment.
Traveling the Tokyo-Osaka line by Shinkansen produces only around 16% of the carbon dioxide of the equivalent journey by car, a saving of 15,000 tons of CO2 per year.
Noise pollution concerns intend that increasing speed is becoming more difficult. In Japan, the population density is high and there have been severe protests against noise pollution of Shinkansen, and now Shinkansen noise is regulated to less than 70 dB in residential areas. Hence, improvement and reduction of pantograph, weight saving of cars, and construction of noise barriers and other measures have been implemented. Current research is primarily aimed at reducing operational noise, especially the tunnel boom phenomenon caused when trains transit tunnels at high speed.
Because of the risk of earthquakes, the Urgent Earthquake Detection and Alarm System (UrEDAS) (earthquake warning system) was introduced in 1992. It enables automatic braking of bullet trains in the case of large earthquakes.
The T?kaid? Shinkansen often experiences heavy snow in the area around Maibara Station in winter. Trains have to reduce speed, which can disrupt the timetable. Sprinkler systems were later installed, but delays of 10 to 20 minutes still arise during snowy weather. Additionally, treefalls related to excess snow have caused service interruptions. Along the route of the J?etsu Shinkansen, winter snow can be very heavy, with snow depths of two to three metres, so the line is equipped with stronger sprinklers and slab track, to mitigate the effects of deep snow.
Cumulative ridership since October 1964 is over 5 billion passengers for the Tokaido Shinkansen Line alone and 10 billion passengers for Japan's entire shinkansen network.
Annual ridership has fallen since 2007, to 307 million as of 2011, although the Kyushu line (connected to the Sanyo Shinkansen in March 2011) has seen significant gains while patronage on other lines has fallen. Until 2011, Japan's high-speed rail system had the highest annual patronage of any system worldwide, China's HSR network's patronage reached 440 million and is now the highest.
E5 series trains, capable of up to 320 km/h (200 mph) (initially limited to 300 km/h), were introduced on the T?hoku Shinkansen in March 2011. Operation at the maximum speed of 320 km/h between Utsunomiya and Morioka on this route commenced on 16 March 2013, and reduced the journey time to around 3 hours for trains from Tokyo to Shin-Aomori (a distance of 674 km (419 mi)).
Extensive trials using the Fastech 360 test trains have shown that operation at 360 km/h (224 mph) is not currently feasible because of problems of noise pollution (particularly tunnel boom), overhead wire wear, and braking distances. On 30 October 2012, JR East announced that it is pursuing research and development to increase speeds to 360 km/h on the Tohoku Shinkansen by 2020.
The Hokuriku Shinkansen is being extended from Kanazawa to Tsuruga (proposed for completion by 2022) at an estimated cost of 3.04 trillion yen (in June 2012). There are further plans to extend the line from Tsuruga to Osaka, and there are currently 3 routes under consideration.
The T?hoku Shinkansen is being extended by JR East from Shin-Aomori to the new Shin-Hakodate station north of the Hokkaido city of Hakodate through the Seikan Tunnel, which is being converted to dual gauge as part of the project, with scheduled completion in March 2016.
For at least the initial two years after opening, Shinkansen trains will be limited to 140 km/h when traversing the dual gauge Seikan tunnel due to the risk of narrow gauge freight trains traveling in the opposite direction being derailed by the shockwave of air that moves ahead of Shinkansen trains at higher speeds in tunnels. There are currently about 50 freight trains traversing the Seikan tunnel each day, and so limiting the travel of such trains through the tunnel to times outside of Shinkansen services is not an option.
In 2018, it is proposed to allow one Shinkansen service each day to travel at 260 km/h (the maximum speed proposed for the tunnel) by ensuring no freight trains are scheduled to travel through the tunnel at that time.
To achieve the full benefit of Shinkansen trains travelling through the tunnel at 260 km/h other alternatives are being considered, such as a system to automatically slow Shinkansen trains down to 200 km/h when passing narrow gauge trains, and/or loading freight trains onto special standard gauge trains (akin to a covered piggyback flatcar train) built to withstand the shockwaves of oncoming Shinkansen trains traveling at full speed, known in Japan as Train on Train. This would enable a travel time from Tokyo to Shin-Hakodate of 3 hrs 45 mins.
JR Hokkaido is extending the Hokkaido Shinkansen from Shin-Hakodate to Sapporo to open by 2031, with tunnelling work on the 5,265m Murayama tunnel, situated about 1 km north of Shin-Hakodate station, proposed to begin by March 2015, and be completed by March 2021.
JR Kyushu is currently constructing an extension (to be known as the West Kyushu Shinkansen) line of the Kyushu Shinkansen to Nagasaki, partly to full Shinkansen standard gauge construction standards (Takeo Onsen - Nagasaki) with the existing narrow gauge part between Shin-Tosu and Takeo Onsen utilised in conjunction with Gauge Change Trains (GCT).
This proposal would involve a GCT train travelling from Hakata to Shin-Tosu (26.3 km) on the existing Kyushu Shinkansen line, then passing through a particular gauge changing (standard to narrow) part of track linking to the existing Nagasaki Main Line, along which it would travel to Hizen Yamaguchi (37.6 km), then onto the Sasebo Line to Takeo Onsen (13.7 km), where another gauge changing section (narrow to standard) would lead onto the final Shinkansen line to Nagasaki (66.7 km).
The proposal shortens the distance between Hakata and Nagasaki by 6.2% (9.6 km), and while only 64% of the route will be built to full Shinkansen standards, it will eliminate the slowest sections of the existing narrow gauge route, providing an estimated time saving of 28.5% (32 minutes) on the current timetable. The proposed top speed of the GCT on the narrow gauge section is unknown at this time, if it is to be higher than 130 km/h then the time saving will be greater.
As part of this proposal the current 12.8 km section of single track between Hizen Yamaguchi and Takeo Onsen is to be duplicated, with work on that component scheduled to commence in April 2016.
With the recent completion of excavation of the 1351m Enogushi tunnel, being the sixth tunnel completed in this section, approximately 25% of the 40.7 km of tunnel excavation work on the Takeo Onsen - Nagasaki section has been finished. The entire project is scheduled for completion by March 2023.
Maglev trains have been undertaking test runs on the Yamanashi test track since 1997, running at speeds of over 500 km/h (310 mph). As a result of this extensive testing, maglev technology is almost ready for public usage. An extension of this test track from 18.4 km to 42.8 km was completed in June 2013, enabling extended high-speed running trials to commence in August 2013. This section will be incorporated into the Ch?? Shinkansen which will eventually link Tokyo to Osaka. Construction of the Shinagawa to Nagoya section is planned to begin in 2014, with 86% of the 286 km route to be in tunnels.
The CEO of JR Central announced plans to have the maglev Ch?? Shinkansen operating from Tokyo to Nagoya by 2027. Following the shortest route (through the Japanese Alps), JR Central estimates that it will take 40 minutes to run from Shinagawa to Nagoya. A subsequent extension to Osaka is planned to be completed by 2045. The planned travel time from Shinagawa to Shin-Osaka is 1 hour 7 minutes. Currently the Tokaido Shinkansen has a minimum connection time of 2 hours 19 minutes.
While the government has granted approval for the shortest route between Tokyo and Nagoya, some prefectural governments, especially Nagano, lobbied to have the line routed farther north to serve the city of Chino and either Ina or Kiso-Fukushima. However, that would increase both the travel time (from Tokyo to Nagoya) and the cost of construction. JR Central has confirmed it will construct the line through Kanagawa Prefecture, and terminate at Shinagawa Station.
The route for the Nagoya to Osaka section is also contested. Currently it is planned to go via Nara, about 40 km south of Kyoto. Kyoto is lobbying to have the route moved north and be largely aligned with the existing Tokaido Shinkansen, which services Kyoto and not Nara.
Mini-shinkansen (??????) is the name given to the routes where former narrow gauge lines have been converted to standard gauge to allow Shinkansen trains to travel to cities without the expense of constructing full Shinkansen standard lines.
Two mini-shinkansen routes have been constructed: the Yamagata Shinkansen and Akita Shinkansen. Shinkansen services to these lines traverse the Tohoku Shinkansen line from Tokyo before branching off to traditional leading lines. On both the Yamagata/Shinjo and Akita lines, the narrow gauge lines were regauged, resulting in the native services being operated by standard gauge versions of 1067mm gauge suburban/interurban rolling stock. On the Akita line between Omagari and Akita, one of the two narrow gauge lines was regauged, and a section of the remaining narrow gauge line is dual gauge, providing the possibility for Shinkansen services to pass each other without stopping.
The maximum speed on these lines is 130 km/h, however the overall travel time to/from Tokyo is improved due to the elimination of the need for passengers to change trains at Fukushima and Morioka respectively.
As the Loading gauge (size of the train that can travel on a line) was not altered when the rail gauge was widened, only Shinkansen trains specially built for these routes can travel on the lines. At present they are the E3 and E6 series trains.
Whilst no further Mini-shinkansen routes have been proposed to date, it remains an option for providing Shinkansen services to cities on the narrow gauge network.
This is the name for the concept of using a single train that is specially designed to travel on both 1,067 mm (3 ft 6 in) narrow gauge railway lines and the 1,435 mm (4 ft 8 1?2 in) standard gauge used by Shinkansen train services in Japan. The trucks/bogies of the Gauge Change Train (GCT) allow the wheels to be unlocked from the axles, narrowed or widened as necessary, and then relocked. This allows a GCT to traverse both standard gauge and narrow gauge tracks without the expense of regauging lines.
Three test trains have been constructed, with the second set having completed reliability trials on the Yosan Line east of Matsuyama (in Shikoku) in September 2013. The third set is undertaking gauge changing trials at Shin-Yatsushiro Station (on Kyushu), commencing in 2014 for a three-year period. The train is being trialled between Kumamoto, travelling on the narrow gauge line to Shin-Yatsushiro, where a gauge changer has been installed, so the GCT can then be trialled on the Shinkansen line to Kagoshima. It is anticipated the train will travel approximately 600,000 km over the three-year trial.
A new "full standard" Shinkansen line is under construction from Takeo Onsen to Nagasaki, with the Shin Tosu - Takeo Onsen section of the Kyushu Shinkansen branch planned to remain narrow gauge and GCTs proposed to provide the Shinkansen service at least between Hakata and Nagasaki when the line is opened in March 2023.
In practice, the Tokaido, Sanyo and Kyushu lines form a contiguous southbound line, as train services run between the Tokaido and Sanyo lines and between the Sanyo and Kyushu lines. The Tokaido Shinkansen is not physically connected to the Tohoku Shinkansen at Tokyo Station. Therefore, there is no through service between those two lines.
Two further lines, known as Mini-shinkansen, have also been constructed by re-gauging and upgrading existing sections of line:
There are two standard-gauge lines not technically classified as Shinkansen lines but with Shinkansen services:
Many Shinkansen lines were proposed during the boom of the early 1970s but have yet to be constructed. These are called Seibi Shinkansen (??????) or planned Shinkansen. One of these lines, the Narita Shinkansen to Narita Airport, was officially cancelled, but a few remain under development.
The following lines were also proposed in the 1973 plan, but have subsequently been shelved indefinitely.
In addition, the Basic Plan specified that the J?etsu Shinkansen should start from Shinjuku, not Tokyo Station, which would have required building an extra 30 km of track between Shinjuku and ?miya. While no construction work was ever started, land along the proposed track, including an underground section leading to Shinjuku Station, remains reserved. If capacity on the current Tokyo??miya section proves insufficient once the Hokkaido and Hokuriku Shinkansen are operational, construction of the Shinjuku??miya link may be reconsidered.
The Narita Shinkansen project to connect Tokyo to Narita International Airport, initiated in the 1970s but halted in 1983 after landowner protests, has been officially cancelled and removed from the Basic Plan governing Shinkansen construction. Parts of its planned right-of-way were utilized by the Narita Sky Access Line which opened in 2010. Although the Sky Access Line uses standard-gauge track, it was not built to Shinkansen specifications and there are no plans to change it into a full Shinkansen line.
In December 2009, then transport minister Seiji Maehara proposed a bullet train link to Haneda Airport, using an existing spur that connects the T?kaid? Shinkansen to a train depot. JR Central called the plan "unrealistic" due to tight train schedules on the existing line, but reports said that Maehara wished to continue discussions on the idea. The current minister has not indicated whether this proposal remains supported.
Trains can be up to sixteen cars long. With each car measuring 25 m (82 ft) in length, the longest trains are 400 m (1/4 mile) end to end. Stations are similarly long to accommodate these trains. Some of Japan's high-speed maglev trains are considered Shinkansen, while other slower maglev trains (such as the Linimo maglev train line serving native community near the city of Nagoya in Aichi, Japan) are intended as alternatives to conventional urban rapid transit systems.
Originally intended to carry passenger and freight trains by day and night, the Shinkansen lines carry only passenger trains. The system shuts down between midnight and 06:00 every day for maintenance. The few overnight trains that still run in Japan run on the older narrow gauge network that the Shinkansen parallels.
Compared with air transport, the Shinkansen has several advantages, including scheduling frequency and flexibility, punctual operation, comfortable seats, and convenient city-center terminals.
The Shinkansen system and airlines often compete with each other for the business of city-to-city home travelers. If the Shinkansen connects two cities in less than three hours, most passengers choose the Shinkansen, but if it takes more than four hours by Shinkansen, the majority choose air. Some examples are as follows.
The China Railways CRH2, built by CSR Sifang Loco & Rolling stocks corporation, with the license purchased from a consortium formed of Kawasaki Heavy Industries, Mitsubishi Electric Corporation, and Hitachi, is based on the E2-1000 series design.
Class 395 EMUs were built by Hitachi based on Shinkansen technology for use on high-speed commuter services in Britain on the High Speed 1 line.
Japan is currently promoting its Shinkansen technology to the Government of Brazil for use on the planned high-speed rail set to link Rio de Janeiro, São Paulo and Campinas. On 14 November 2008, Japanese Prime Minister Tar? As? and Brazilian President Luiz Inácio Lula da Silva talked about this rail project. President Lula asked a consortium of Japanese companies to participate in the bidding process. Prime Minister Aso concurred on the bilateral cooperation to improve rail infrastructure in Brazil, including the Rio-São Paulo-Campinas high-speed rail line. The Japanese consortium includes the Ministry of Land, Infrastructure, Transport and Tourism, Mitsui & Co., Mitsubishi Heavy Industries, Kawasaki Heavy Industries and Toshiba.
The U.S. Federal Railroad Administration is in talks with a number of countries with high-speed rail, notably Japan, France and Spain. On 16 May 2009, FRA Deputy Chief Karen Rae expressed hope that Japan would offer its technical expertise to Canada and the United States. Transportation Secretary Ray LaHood indicated interest in test riding the Japanese Shinkansen in 2009.
On 1 June 2009, JR Central Chairman, Yoshiyuki Kasai, announced plans to export both the N700 Series Shinkansen high-speed train system and the SCMaglev to international export markets, including the United States and Canada.
Vietnam Railways was considering the use of Shinkansen technology for high-speed rail between the capital Hanoi and the southern commercial hub of Ho Chi Minh City, according to the Nihon Keizai Shimbun, citing an interview with Chief Executive Officer Nguyen Huu Bang. The Vietnamese government had already given basic approval for the Shinkansen system, although it still requires financing and formal agree from the prime minister. Vietnam rejected a funding proposal in 2010, so funding for the $56 billion project is uncertain. Hanoi was exploring additional Japanese funding Official Development Assistance as well as funds from the World Bank and Asian Development Bank. The 1,560-kilometre (970 mi) line would replace the current colonial-era rail line. Vietnam hopes to launch high-speed trains by 2020 and plans to begin by building three sections, including a 90-kilometre stretch between the central coastal cities of Da Nang and Hu?, seen as potentially most profitable. Vietnam Railways had sent engineers to Central Japan Railway Company for technical training.
India and Japan are conducting feasibility studies on high-speed rail and dedicated freight corridors.
The Indian Ministry of Railways' white-paper Vision 2020 submitted to Indian Parliament by Railway Minister Mamata Banerjee on 18 December 2009 envisages the implementation of regional high-speed rail projects to provide services at 250?350 km/h.
During Indian Prime Minister Manmohan Singh's visit to Tokyo in December 2006, Japan assured cooperation with India in creating a high-speed link between New Delhi and Mumbai. In January 2009, the then Railway Minister Lalu Prasad rode a bullet train travelling from Tokyo to Kyoto.
In December 2013 a Japanese consortium was appointed to undertake a feasibility study of a ~500 km high-speed line between Mumbai and Ahmedabad by July 2015. A total of 7 high-speed lines are in planning stages in India, and Japanese firms have now succeeded in winning contracts to prepare feasibility studies for three of the lines.
Japan will provide Shinkansen technology for a high-speed rail link between Bangkok and the northern city of Chiang Mai under an accord reached with Thailand on May 27.
Total project costs are estimated in excess of 1 trillion yen ($8.1 billion). Several hurdles remain, however, including finding the funding.
If the project is realized, it would mark the second time Shinkansen technology has been exported.
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