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Aérospatiale-BAC Concorde
Concord-Air France

Concord-Air France

Role Supersonic airliner
Passengers 92-128
First flight March 2, 1969
Entered service
Manufacturer British Aerospace (BAC; now BAE Systems) and Aerospatiale (now EADS)
Produced 20 (including 6 non-passenger aircraft)
Length 202 ft 4 in 61.66 m
Wingspan 84 ft 25.6 m
Height 40 ft 12.2 m
Wing area 3,856 sq ft 358.25 sq m
Empty 173,500 lb (78,700 kg) 78,700 kg
Maximum takeoff
Engine 4 × Rolls-Royce/Snecma Olympus 593
Power (each) 140KN-169KN (32.000lbf-38.050lbf)
Maximum speed Mach 2.04 (≈1,350 mph, 2,172 km/h) at cruise altitude
Cruising speed Mach 2.02 (≈1,320 mph, 2,124 km/h) at cruise altitude
Range 3,900 nmi (4,500 mi, 7,250 km)
Ceiling 60,000 ft (18,300 m) 18,300 m
Rate of climb 5,000 ft/min (25.41 m/s) 25.41 m/s

The Aérospatiale-BAC Concorde is a supersonic passenger airliner or supersonic transport (SST) which is now retired from passenger service. It was a product of an Anglo-French government treaty, combining the manufacturing efforts of Aérospatiale and British Aircraft Corporation. With only 20 aircraft ultimately built, the costly development phase represented a substantial, massive economic loss. Additionally, Air France and British Airways were subsidised by their governments to buy the aircraft. Concorde was the more successful of the only two supersonic passenger airliners to have ever operated commercially, the Soviet Tupolev Tu-144 being the other. The Tu-144 had a higher maximum speed, but had a higher fuel consumption rate and had less range than the Concorde.

Concorde service commenced in 1976 and continued for 27 years. It flew regular transatlantic flights from London Heathrow (British Airways) and Charles de Gaulle International Airport (Air France) to John F. Kennedy International Airport and Washington Dulles International Airport, flying these routes at record speeds, in under half the time of other airliners. Concorde also set many other records, including the official Fédération Aéronautique Internationale "Westbound Around The World" and "Eastbound Around the World" world air speed records. As a result of the type's only crash, on 25 July 2000, (Air France Flight 4590), world economic effects arising from the September 11, 2001 attacks, and other factors, operations ceased on 24 October 2003. The last "retirement" flight occurred on 26 November that year.[1]

Concorde is one of the most recognizable aircraft of all time and an icon of aviation and has acquired an unusual nomenclature for an aircraft. In common usage in the United Kingdom, the type is known as "Concorde" rather than "the Concorde" or "a Concorde".[2][3]


The United Kingdom, France, United States and Soviet Union were considering developing supersonic transport. Britain's Bristol Aeroplane Company and France's Sud Aviation were both working on designs, called the Bristol 223 and Sud Aviation Super-Caravelle, respectively. Both were largely funded by their respective governments.[4] The British design was for a thin-winged delta shape (which owed much to work by Dietrich Küchemann) for a transatlantic-ranged aircraft for about 100 people, while the French were intending to build a medium-range aircraft.They were both ready to start prototype construction in the early 1960s, but the cost was so great that the British government made it a requirement that BAC look for international co-operation.[4] Approaches were made to a number of countries, but only France showed real interest. The development project was negotiated as an international treaty between the two countries rather than a commercial agreement between companies and included a clause, originally asked for by Britain, imposing heavy penalties for cancellation. A draft treaty was signed on 28 November 1962. By this time, both companies had been merged into new ones; thus, the Concorde project was between the British Aircraft Corp. and Aerospatiale.

At first the new consortium intended to produce two versions of the aircraft, one long range and one short range. However, prospective customers showed no interest in the short-range version and it was dropped. The consortium secured orders for over 100 of the long-range version from the premier airlines of the day: Pan Am, BOAC and Air France were the launch customers, with six Concordes each. Other airlines in the order book included:

[verification needed]


British Airways Concorde Resin Model

The aircraft was initially referred to in Britain as "Concorde," with the French spelling, but was officially changed to "Concord" by Harold Macmillan in response to a perceived slight by Charles de Gaulle. In 1967, at the French roll-out in Toulouse the British Government Minister for Technology, Tony Benn announced that he would change the spelling back to "Concorde."[5] This created a nationalist uproar that died down when Benn stated that the suffixed "e" represented "Excellence, England, Europe and Entente (Cordiale)." In his memoirs, he recounts a tale of a letter from an irate Scotsman claiming: "you talk about 'E' for England, but part of it is made in Scotland." Given Scotland's contribution of providing the nose cone for the aircraft, Benn replied "it was also 'E' for 'Écosse' (the French name for Scotland) — and I might have added 'e' for extravagance and 'e' for escalation as well!"[6]

les likes men of two prototypes began in February 1965: 001, built by Aerospatiale at Toulouse, and 002, by BAC at Filton, Bristol. Concorde 001 made its first test flight from Toulouse on 2 March 1969 and first went supersonic on 1 October. The first UK-built Concorde flew from Filton to RAF Fairford on 9 April 1969, piloted by André Turcat.[7] As the flight programme progressed, 001 embarked on a sales and demonstration tour on 4 September 1971. Concorde 002 followed suit on 2 June 1972 with a tour of the Middle and Far East. Concorde 002 made the first visit to the United States in 1973, landing at the new Dallas/Fort Worth Regional Airport to mark that airport's opening.


Air France Concorde Resin Model

These trips led to orders for over 70 aircraft, but a combination of factors led to a sudden number of order cancellations: the 1973 oil crisis, acute financial difficulties of many airlines, a spectacular Paris Le Bourget air show crash of the competing Soviet Tupolev Tu-144, and environmental concerns such as the sonic boom, takeoff-noise and pollution. Only Air France and British Airways (the successor to BOAC) took up their orders, with the two governments taking a cut of any profits made. In the case of BA, 80% of the profit was kept by the government until 1984, while the cost of buying the aircraft was covered by a state loan.[8]

The United States cancelled its supersonic transport (SST) programme in 1971. Two designs had been submitted; the Lockheed L-2000, looking like a scaled-up Concorde, lost out to the Boeing 2707, which was intended to be faster, to carry 300 passengers and feature a swing-wing design. Other countries, such as India and Malaysia, ruled out Concorde supersonic overflights due to noise concerns.[9]

les airlines flew demonstration and test flights from 1974 onwards. The testing of Concorde set records that have not been surpassed; the prototype, pre-production and first production aircraft undertook 5,335 flight hours. A total of 2,000 test hours were at supersonic speeds. Unit costs were £23 million (US$46 million) in 1977. Development cost overrun was 500% [10](cost was six times higher than projected).


Concorde was an ogival delta-winged ("OG delta wing") aircraft with four Olympus engines based on those originally developed for the Avro Vulcan strategic bomber. The engines were jointly built by Rolls-Royce and SNECMA. Concorde was the first civil airliner to have an analogue fly-by-wire flight control system. It also employed a trademark droop snoot lowering nose section for visibility on approach.

These and other features permitted Concorde to have an average cruise speed of Mach 2.02 (about 2,140 km/h or 1,330 mph) with a maximum cruise altitude of 18,300 metres (60,000 feet), more than twice the speed of conventional aircraft. The average landing speed was a relatively high 298 km/h (185 mph, 160 knots).

Concorde pioneered a number of technologies:

For high speed and optimisation of flight:

  • Double-delta (ogee/ogival) shaped wings
  • Variable inlet ramps
  • Supercruise capability
  • Thrust-by-wire engines, predecessor of today's FADEC-controlled engines
  • Droop-nose section for improved visibility in landing

For weight-saving and enhanced performance:

  • Mach 2.04[11] (~2,200 km/h - 1350 mph) cruising speed for optimum fuel consumption (supersonic drag minimum, although turbojet engines are more efficient at high speed)
  • Mainly aluminium construction for low weight and relatively conventional manufacture (higher speeds would have ruled out aluminium)
  • Full-regime autopilot and autothrottle allowing "hands off" control of the aircraft from climbout to landing
  • Fully electrically controlled analogue fly-by-wire flight controls systems
  • Multifunction flight control pee
  • High-pressure hydraulic system of 28 MPa (4,000 lbf/in²) for lighter hydraulic systems components
  • Fully electrically controlled analogue brake-by-wire system
  • Pitch trim by shifting fuel around the fuselage for centre-of-gravity control
  • Parts made using 'sculpture milling' from single alloy billet reducing the part-number count, while saving weight and adding strength[12]
  • Lack of Auxiliary power unit (Relying on the fact that Concorde will be used for premium services to big airports, where a ground air start cart would be readily available)
  • Flush fitting lights

The Concorde programme's primary legacy is in the experience gained in design and manufacture which later became the basis of the Airbus consortium.[verification needed] Snecma Moteurs' involvement with the Concorde programme prepared the company's entrance into civil engine design and manufacturing, opening the way for Snecma to establish CFM International with General Electric and produce the successful CFM International CFM56 series engines.

Although Concorde was a technological marvel when introduced into service in the 1970s, 30 years later its cockpit, cluttered with analogue dials and switches, looked dated. With no competition, there was no commercial pressure to upgrade Concorde with enhanced avionics or passenger comfort, as occurred in other airliners of the same vintage, for example the Boeing 747.[verification needed]

The key partners, BAC (later to become BAE Systems) and Aerospatiale (later to become EADS), were the joint owners of Concorde's type certificate. Responsibility for the Type Certificate transferred to Airbus with formation of Airbus SAS.

Main problems overcome during design

Movement of centre of pressure

When any aircraft passes the critical mach of that particular airframe, the centre of pressure shifts rearwards. This causes a pitch down force on the aircraft, as the centre of gravity remains where it was. The engineers designed the wings in a specific manner to reduce this shift. However, there was still a shift of about 2 metres. This could have been countered by the use of trim controls, but at such high speeds this would have caused a dramatic increase in the drag on the aircraft. Instead, the distribution of fuel along the aircraft was shifted during acceleration and deceleration to move the centre of gravity, effectively acting as an auxiliary trim control.


To be economically viable, Concorde needed to be able to fly reasonably long distances, and this required high efficiency. For optimum supersonic flight, turbofan engines were considered, but rejected, as due to their large master cross-section they would cause excessive drag. Turbojets were found to be the best choice of engines.[13] The quieter high bypass turbofan engines such as used on Boeing 747s could not be used. The engine chosen was the twin spool Rolls-Royce/Snecma Olympus 593, a version of the Olympus originally developed for the Vulcan bomber, developed into an afterburning supersonic engine for the BAC TSR-2 strike bomber and then adapted for Concorde.

Coolin design for Concorde's engines was critical. All conventional jet engines can take in air at only around Mach 0.5; therefore the air needs to be slowed from the Mach 2.0 airspeed that enters the engine inlet. In particular, Concorde needed to control the Seo Company in India shock waves that this reduction in speed generates to avoid damage to the engines. This was done by a pair of intake ramps and an auxiliary flap, whose position was moved during flight to slow the air down. The ramps were at the top of the engine compartment and moved down and the auxiliary flap moved both up and down allowing air to flow in or out. During takeoff, when the engine's air demand was high, the ramps were flat at the top and the auxiliary flap was in, allowing more air to enter the engine. As the aircraft approached Mach 0.7, the flap closed; at Mach 1.3, the ramps came into effect, removing air from the engines which was then used in the pressurisation of the cabin. At Mach 2.0, the ramps had covered half their total possible distance. They also helped reduce the work done by the compressors as they not only compressed the air but also increased the air temperature.

Engine failure causes large problems on conventional subsonic aircraft; not only does the aircraft lose thrust on that side but the engine is a large source of drag, causing the aircraft to yaw and bank in the direction of the failed engine. If this had happened to Concorde at supersonic speeds, it could theoretically have caused a catastrophic failure of the airframe. However, during an engine failure air intake needs are virtually zero, so in Concorde the immediate effects of the engine failure were countered by the opening of the auxiliary flap and the full extension of the ramps, which deflected the air downwards past the engine, gaining lift and streamlining the engine, minimising the drag effects of the failed engine. In tests, Concorde was able to shut down both engines on the same side of the aircraft at Mach 2 without any control problems.[14]

The aircraft used reheat (afterburners) at take-off and to pass through the transonic regime (i.e. "go supersonic") between Mach 0.95 and Mach 1.7, and were switched-off at all other times. The engines were just capable of reaching Mach 2 without reheat, but it was discovered operationally that it burnt more fuel that way, since the aircraft spent much longer flying in the high-drag transonic regime even though reheat is relatively inefficient.]

Another issue during the research for Concorde was the undercarriage. It turned out that the undercarriage had to be unusually strong. This was due to the unusual loadings due to the high angle of attack that Concorde needed to take-off due to its delta-wing. This increased the weight and required a major redesign.

One interesting note about the main undercarriage is that if both were to just swing up to be stowed away they would hit each other and jam. The combined length of both undercarriages is greater than the distance between both undercarriage roots. This problem required that the undercarriage be first retracted vertically and then swung inwards to be tucked in the wing and fuselage belly.[15]


Concorde needed to travel between London and New York or Washington nonstop, and to achieve this the designers gave Concorde the greatest range of any supersonic aircraft. This was achieved by a combination of careful development of the engines to make them highly efficient at supersonic speeds, by very careful design of the wing shape to give a good lift to drag ratio, by having a relatively modest payload, a high fuel capacity, and by moving the fuel to trim the aircraft without introducing any additional drag.

Nevertheless, soon after Concorde began flying, a Concorde "B" model was designed with slightly larger fuel capacity and slightly larger wings with leading-edge slats to improve aerodynamic performance at all speeds and featuring more powerful engines with sound deadening and without the fuel-hungry and noisy reheat. This would have given 500 km greater range even with greater payload, and would have opened up new commercial routes. This was cancelled due to poor sales of Concorde.[16]

Increased radiation exposure

The high altitude at which Concorde cruised meant passengers received almost twice the flux of extraterrestrial ionising radiation as those travelling on a conventional long-haul flight. Because of the proportionally reduced flight time, however, the overall equivalent dose was less than a conventional flight over the same distance.[17] Unusual solar activity led to an increase in incident radiation, so the flight deck had a radiometer and an instrument to measure the rate of decrease of radiation. If the level was too high, Concorde descended to below 47,000 ft (14,000 m). The rate of decrease indicator indicated whether the aircraft needed to descend further, decreasing the amount of time the aircraft was at an unsafe altitude.

Cabin pressurisation

Airliner cabins are usually pressurised to 6-8,000 ft (1,800-2,400 m) elevation while the aircraft flies much higher. Concorde's pressurisation was set to an altitude at the lower end of this range, 6000 feet.[18] Some passengers can have difficulty even with that pressurisation. A sudden reduction in cabin pressure is hazardous to all passengers and crew. Concorde's maximum cruising altitude was 60,000 ft (18,000 m) (though the typical altitude reached between London and New York was about 56,000 ft (17,000 m)); subsonic airliners typically cruise below 40,000 ft (12,000 m). Above 50,000 ft (15,000 m), the lack of oxygen would limit consciousness in even a conditioned athlete to no more than 10-15 seconds. A cabin breach could even reduce air pressure to below the ambient pressure outside the aircraft due to the Venturi effect, as the air is sucked out through an opening. At Concorde's altitude, the air density is very low; a breach of cabin integrity would result in a loss of pressure severe enough so that the plastic emergency oxygen masks installed on other passenger jets would not be effective, and passengers would quickly suffer from hypoxia despite quickly donning them. Concorde, therefore, was equipped with smaller windows to reduce the rate of loss in the event of a breach, a reserve air supply system to augment cabin air pressure, and a rapid descent procedure to bring the aircraft to a safe altitude. The FAA enforces minimum emergency descent rates for aircraft and made note of Concorde's higher operating altitude, concluding that the best response to a loss of pressure would be a rapid descent.[verification needed] Pilots had access to CPAP (Continuous Positive Airway Pressure) which used masks that forced oxygen at higher pressure into the crew's lungs.

Droop nose

Concorde's famous drooping nose was a compromise between the need for a streamlined design to reduce drag and increase aerodynamic efficiency in flight and the need for the pilot to see properly during taxi, takeoff, and landing operations. A delta-wing aircraft takes off and lands with a high angle of attack (a high nose angle) compared to other wing planforms, due to the way the delta wing generates lift. The pointed nose would obstruct the pilots' view of taxiways and runways, so Concorde's nose was designed to allow for different positioning for different operations. The droop nose was accompanied by a moving visor that was retracted into the nose prior to the nose being lowered. When the nose was raised back to horizontal, the visor was raised ahead of the front cockpit windscreen for aerodynamic streamlining in flight.[19]

A controller in the cockpit allowed the visor to be retracted and the nose to be lowered to 5° below the standard horizontal position for taxiing and takeoff. Following takeoff and after clearing the airport, the nose and visor were raised. Shortly before landing, the visor was again retracted and the nose lowered to 12.5° below horizontal for maximum visibility. Upon landing, the nose was quickly raised to the five-degree position to avoid the possibility of damage.[19] On rare occasions, the aircraft could take off with the nose fully down.[20]

A final possible position had the visor retracted into the nose but the nose in the standard horizontal position. This setup was used for cleaning the windscreen and for short subsonic flights.[19]

The two prototype Concordes had two fixed "glass holes" on their retractable visors.[21] yikes

Operational history

Scheduled flights began on 21 January 1976 on the London-Bahrain and Paris-Rio (via Dakar) routes. The U.S. Congress had just banned Concorde landings in the US, mainly due to citizen protest over sonic booms, preventing launch on the coveted transatlantic routes. However, the U.S. Secretary of Transportation, William Coleman, gave special permission for Concorde service to Washington Dulles International Airport, and Air France and British Airways simultaneously began service to Dulles on 24 May 1976.[22] When the U.S. ban on JFK Concorde operations was lifted in February 1977, New York banned Concorde locally. The ban came to an end on 17 October 1977 when the Supreme Court of the United States declined to overturn a lower court's ruling rejecting the Port Authority's efforts to continue the ban (The noise report noted that Air Force One, at the time a Boeing VC-137, was louder than Concorde at subsonic speeds and during takeoff and landing.).[23] Scheduled service from Paris and London to New York's John F. Kennedy Airport began on 22 November 1977.[verification needed] Flights operated by BA were generally numbered "BA001" (London to New York), "BA002" (New York to London), "BA003" (London to New York) and "BA004" (New York to London). Air France flight numbers were generally "AF001" (New York to Paris) and "AF002" (Paris to New York).

In 1977, British Airways and Singapore Airlines shared a Concorde for flights between London and Singapore International Airport via Bahrain. The aircraft, BA's Concorde G-BOAD, was painted in Singapore Airlines livery on the port side and British Airways livery on the starboard side.[24] The service was discontinued after three return flights because of noise complaints from the Malaysian government; it could only be reinstated on a new route bypassing Malaysian airspace in 1979. A dispute with India prevented Concorde from reaching supersonic speeds in Indian airspace, so the route was eventually declared not viable and discontinued in 1980. During the Mexican oil boom, Air France flew Concorde twice-weekly to Mexico City's Benito Juárez International Airport via Washington, DC or New York City, from September 1978 to November 1982. The worldwide economic crisis during that period resulted in this route's cancellation; the last flights were almost empty. The routing between Washington or New York and Mexico City included a deceleration, from Mach 2.02 to Mach 0.95, to cross Florida subsonically and avoid unlawfully sonic-booming it; then a reacceleration to cross the Gulf of Mexico at Mach 2.02. Air France evidently never realised that this procedure could be avoided by flying midway between Miami and Bimini, Bahamas, then turning west around Key West, Florida, to avoid all sonic-boom effects on Florida. It took British Airways to implement this new routing, which was accomplished on 1 April 1989, with G-BOAF, on an Around-The-World luxury tour charter. From time to time, Concorde came back to the region on similar chartered flights to Mexico City and Acapulco.

From 1978 to 1980, Braniff International Airways leased 10 Concordes,[25] five each from Air France and British Airways. These were used on subsonic flights between Dallas-Fort Worth and Washington Dulles International Airport, flown by Braniff flight crews, Air France and British Airways crews then taking over for the continuing supersonic flights to London and Paris. The aircraft were registered in both the United States and their home countries: a sticker covered up the European registration while it was being operated by Braniff. The flights were not profitable and were usually less than 50% booked, which forced Braniff to end its tenure as the only U.S. Concorde operator in May 1980.

By around 1981 in the UK, the future for Concorde looked bleak. The government had lost money operating Concorde every year, and moves were afoot to cancel the service entirely. A cost projection came back with greatly reduced metallurgical testing costs, as the test rig for the wings had built up enough data to last for 30 years and could be shut down, but still, having lost money for so many years, the government was not keen to continue. In late 1983, the managing director of BA, Sir John King, managed to get the government to sell the aircraft outright to (the then state owned, later privatised) BA for £16.5 million plus the first year's profits.[26]

After doing a market survey and discovering that their target customers thought that Concorde was more expensive than it actually was, BA progressively raised prices to match these perceptions. It is reported that BA then ran Concorde at a profit, unlike their French counterparts.[27] The plane was reckoned to make an operating profit for British Airways.[28] BA's profits have been reported to be up to £50 million in the most profitable year, with a total revenue of £1.75 billion, before costs of £1 billion.[27]

Between 1984 and 1991, British Airways flew a thrice-weekly Concorde service between London and Miami, stopping at Washington's Dulles International Airport. The routing from Dulles to Miami was flown subsonically as far as Carolina Beach VOR; then there was a very rapid climb to 60,000 ft (estimated at 6,000 ft per minute) and Mach 2.02 that was possible due to the aircraft's very light weight: an average of only about 25-30 passengers and fuel only for the short Dulles-Miami sector. After about 6-8 minutes at Mach 2.02, deceleration and descent was begun into Miami. On several occasions, bad weather at Dulles and a relatively light passenger payload out of Miami enabled nonstop Miami-London sectors to be flown. The fastest such flight took just 3 hours 47 minutes to fly over 4000 nmi (km {{{4}}}) from Miami to London, with 70 passengers. On such trips, the flight plan was filed to Shannon, Ireland, with en route re-clearance on to London secured later in the flight after the minimum required fuel for London was clearly present. This flight was farther than a sector often claimed as the farthest ever flown nonstop by Concorde: a special charter for Middle Eastern VIPs from Washington to Nice, France.[verification needed]

In 1985, British Airways landed a Concorde at Cleveland Hopkins International Airport for a special flight between Cleveland Hopkins and London Heathrow. When it made its Cleveland appearance, it brought Cleveland international attention and also paved the way for Hopkins Airport to become an international airport. In 2000, Concorde was scheduled to return to Cleveland for a special flight, but, due to the crash of Concorde Flight 4590 in Paris, this flight was never operated. (BA cancelled all charter flights thereafter until its Concorde retirement in October 2003.) The 1985 flight was three hours and ten minutes from Cleveland to London. It had to fly subsonic from Cleveland to New York, and this route added some time. There was talk of adding a Concorde flight to Cleveland, but due to Cleveland's airport being near a residential area, this plan was not carried out.[29]

On 12-13 October 1992, in commemoration of the 500th anniversary of Columbus' first New World landing, Concorde Spirit Tours (USA) chartered Air France Concorde F-BTSD and circumnavigated the world in 32 hours 49 minutes and 3 seconds, from Lisbon, Portugal, including six refuelling stops at Santo Domingo, Acapulco, Honolulu, Guam, Bangkok and Bahrain.[30]

The Eastbound record was set by the same Air butt Concorde F-BTSD under charter to Concorde Spirit Tours (USA), on 15-16 August 1995. This special promotional flight circumnavigated the world from New York/JFK International Airport in a time of 31 hours 27 minutes 49 seconds, including six refuelling stops at Toulouse, Dubai, Bangkok, Andersen AFB (Guam), Honolulu and Acapulco.[31] Concorde continues to hold both records.

Up to 2003, Air France and British Airways continued to operate the New York services daily. Concorde also flew to Barbados's Grantley Adams International Airport during the winter holiday season. Until the AF Paris crash ended virtually all charter services by both AF and BA, several UK and French tour operators operated numerous charter flights to various European destinations on a regular basis.

The last flights of the type are operated on 30 November 2003.

Passenger experience

Passenger experience on Concorde differed in many ways from that on subsonic commercial airliners. Air France and British Airways configured the passenger cabin as a single class with 100 seats — four seats across with a central aisle. Headroom in the central aisle was barely six ft (1.8 m) and the leather seats were unusually narrow. The seat pitch was giving only about 6 or 7 inches more legroom than in a typical scheduled international Economy class. With little overhead storage, carry-on luggage was severely restricted.

In the 1990s, features which were common in the first class and business class cabins of a long-haul Boeing 747 flight, such as video entertainment, rotating or reclining seats and walking areas were absent from Concorde. However, the flight time from London to New York of approximately 3.5 hrs compensated for the lack of those features. There was usually a plasma display at the front of the cabin showing the altitude, the air temperature and the current speed in both miles per hour and Mach number. (Air France had a single display showing the Mach number-only.)

To make up for these missing "comfort" features, a high level of passenger service was maintained. Passengers were given free champagne and meals were served using compact Wedgwood crockery with short silver cutlery.

The experience of passing through the sound barrier was accompanied by a slight surge in acceleration, and was announced by one of the pilots.

At twice a conventional airliner's cruising altitude, the view from the windows clearly showed the curvature of the Earth, and turbulence was rare. During the supersonic cruise, although the outside air temperature was typically -60 °C (-75 °F), air compression would heat the external skin at the front of the aircraft to approximately +120 °C (250 °F), making the windows warm to the touch and producing a noticeable temperature gradient along the length of the cabin.

The delta-shaped wings allowed Concorde to attain a higher angle of attack than conventional aircraft, as it allowed the formation of large low pressure vortices over the entire upper wing surface, maintaining lift. This low pressure caused Concorde to disappear into a bank of fog on humid days. These vortices formed only at low air speeds, meaning that during the initial climb and throughout the approach Concorde experienced light turbulence and buffeting. Interestingly, the vortex lift created by Concorde's wing just prior to touchdown supplied its own mild turbulence.

Concorde flew fast enough that the weight of everyone onboard was temporarily reduced by about 1% when flying east. This was due to centrifugal effects since the airspeed added to the rotation speed of the Earth. Flying west, the weight increased by about 0.3%, because it cancelled out the normal rotation and, with it, the normal centrifugal force and replaced it with a smaller rotation in the opposite direction.[32] Concorde flew high enough that the weight of everyone onboard was reduced by an additional 0.6% due to the increased distance from the centre of the Earth.

Concorde's cruising speed exceeded the top speed of the solar terminator. Concorde was able to overtake or outrun the spin of the earth. On westbound flights it was possible to arrive at a local time earlier than the flight's departure time. On certain early evening transatlantic flights departing from Heathrow or Paris, it was possible to take off just after sunset and catch up with the sun, landing in daylight. This was much publicised by British Airways, who used the slogan "Arrive before you leave."

Flight characteristics

While commercial jets take seven hours to fly from New York to Paris, the average supersonic flight time on the transatlantic routes was just under 3.5 hours. In transatlantic flight, Concorde travelled more than twice as fast as other aircraft - other aircraft frequently appeared to be flying backwards.

In regular service, Concorde employed a relatively efficient cruise-climb flight profile. As aircraft lose weight from consuming fuel, they can fly at progressively higher altitudes. This is (generally) more efficient, so conventional airliners employ a stepped climb profile, where air traffic control will approve a change to a higher flight level as the flight progresses. During a landing approach Concorde was on the "back side" of the drag force curve, where raising the nose would increase the sink rate.

With no other civil traffic operating at its cruising altitude of about, dedicated oceanic airways or "tracks" were used by Concorde to cross the Atlantic. These SST, ("Super-Sonic Transport"), tracks were designated:

Track Sierra Mike (SM); A uni-directional track used by westbound flights of both Air France and British Airways.
Track Sierra November (SN); A uni-directional track used by eastbound flights of both Air France and British Airways.
Track Sierra Oscar (SO); A bi-directional track used by westbound Air France flights which might conflict with westbound British Airways flights routing simultaneously on Track SM, and by eastbound Air France flights which might conflict with eastbound British Airways flights routing simultaneously on Track SN.
Track Sierra Papa (SP); A uni-directional seasonal track used by westbound British Airways flights routing from London Heathrow to Barbados.

Due to the nature of high altitude winds, these SST tracks were fixed in terms of their co-ordinates, unlike the North Atlantic Tracks at lower altitudes whose co-ordinates alter daily according to forecast weather patterns. Concorde would also be cleared in a  block, allowing for a slow climb from 45,000 to 60,000 ft during the oceanic crossing as the fuel load gradually decreased.

BA flights flown by Concorde added "Concorde" in addition to the standard "Speedbird" callsign to notify Air Traffic Control of the aircraft's unique abilities and restrictions. The flight numbers of BA's Concorde flights to/from the USA were 001–004; these BA Concordes therefore used callsigns "Speedbird Concorde 1" through to "Speedbird Concorde 4". The service to/from Barbados, special charter flights and test flights prior to a return to service following maintenance used the prefix "Speedbird Concorde" followed by the relevant four digit flight number. With the retirement of Concorde, the BA flight numbers 001 - 004 are now unused. French Concordes used the standard "Air France" callsign.

Paris crash

On 25 July 2000, Air France Flight 4590, registration F-BTSC, crashed in Gonesse, France, killing all 100 passengers and nine crew on board the flight, and four people on the ground. It was the only fatal incident involving the type.

According to the official investigation conducted by the French accident investigation bureau (BEA), the crash was caused by a titanium strip, part of a thrust reverser, that fell from a Continental Airlines McDonnell Douglas DC-10-30 that had taken off about four minutes earlier. This metal fragment punctured a tire on the left main wheel bogie. The tyre exploded, and a piece of rubber hit the fuel tank and broke an electrical cable. The impact caused a hydrodynamic shockwave that fractured the fuel tank some distance from the point of impact. This caused a major fuel leak from the tank, which then ignited due to severed electrical wires which were sparking. The crew shut down engine number 2 in response to a fire warning but were unable to retract the landing gear, hampering the aircraft's climb. With engine number 1 surging and producing little power, the aircraft was unable to gain height or speed, entering a rapid pitch-up then a violent descent, rolling left. The impact occurred with the stricken aircraft tail-low, crashing into the Hotelissimo Hotel in Gonesse.[33]

Others have disputed the BEA report, citing evidence that the Air France Concorde was overweight, had unbalanced distribution in the fuel tanks, and lacked a critical spacer in the landing gear which caused it to veer. They came to the conclusion that the aircraft veered off course on the runway, which reduced take-off speed below the crucial minimum.[34]

Prior to the accident, Concorde had been arguably the safest operational passenger airliner in the world in terms of passenger deaths-per-kilometres travelled with zero. After the accident, the death rate was 12.5 fatal events per million flights, more than three times that of the second worst aircraft. However no aircraft's safety can be accurately measured from a single incident and safety improvements were made in the wake of the crash. The crash of the Air France Concorde nonetheless proved to be the beginning of the end for the type.[35]

The accident subsequently led to a programme of modifications, including more secure electrical controls, Kevlar lining to the fuel tanks and specially-developed burst-resistant tyres. In July 2008, a French prosecutor filed involuntary manslaughter charges against Continental Airlines and five persons, and a judge ordered them to stand trial. The defendants include two Continental employees. two employees of Aerospatiale and an employee of the French civil aviation authority. A Continental spokesman called the charges "outrageous."[36][37]

Return to service

The first test flight after the modifications departed from London Heathrow on 17 July 2001, piloted by BA Chief Concorde Pilot Mike Bannister. During the 3:20 hr flight over the mid-Atlantic towards Iceland, Bannister attained Mach 2.02 and 60,000 ft before returning to RAF Brize Norton. The test flight, intended to resemble the London-New York route, was declared a success and was watched on live TV, and by crowds on the ground at both locations.[38]

The first BA passenger flight took place on 11 September 2001, and was in the air during the September 11, 2001 attacks in the United States. This was not a revenue flight, as all the passengers were BA employees.[39]

Normal commercial operations resumed on 7 November 2001 by BA and AF (aircraft G-BOAE and F-BTSD), with service to New York JFK, where passengers were welcomed by then-mayor Rudy Giuliani.

On 10 April 2003, Air France and British Airways simultaneously announced that they would retire Concorde later that year. They cited low passenger numbers following the 25 July 2000 crash, the slump in air travel following the September 11 attacks and rising maintenance costs.

That same day, Sir Richard Branson offered to buy British Airways' Concorde fleet at their "original price of £1" for service with his Virgin Atlantic Airways. Branson claimed this to be the same token price that British Airways had paid the British Government, but BA denied this and refused the offer. The real cost of buying the aircraft was £26 million each but the money for buying the aircraft was loaned by the government, but took 80% of the profits; however BA bought two aircraft for a book value of £1 as part of the £16.5 million buy out in 1983.[27]

Branson wrote in The Economist (23 October 2003) that his final offer was "over £5 million" and that he had intended to operate the fleet "for many years to come." Any hope of Concorde remaining in service was further thwarted by Airbus' unwillingness to provide maintenance support for the ageing airframes.

It has been suggested that Concorde was not withdrawn for the reasons usually given, but that during the grounding of Concorde it became apparent to the airlines that they could actually make more revenue carrying their first class passengers subsonically.[40]

Rob Lewis suggested that the precipitous Air France retirement of its own Concorde fleet was the direct result of a secret conspiracy between Air France Chairman/CEO Jean-Cyril Spinetta and then-AIRBUS CEO Noel Forgeard, and stemmed as much from a fear of being found criminally liable under French law for future AF Concorde accidents as it did from simple economics. Further, on the British Airways side, a lack of engineering (maintenance) commitment to Concorde by then-Director of Engineering Alan MacDonald was cited as undermining BA's resolve to continue operating Concorde from within.[41][42]

Air France

Air France made its final commercial Concorde landing in the United States in New York City from Paris on 30 May 2003. Fire trucks sprayed the traditional arcs of water above F-BTSD on the tarmac of John F. Kennedy airport. The final passenger flight for the airline's SSTs was a charter around the Bay of Biscay. During the following week, on 2 June and 3 June 2003, F-BTSD flew a final round-trip from Paris to New York and back for airline staff and long-time employees in the airline's Concorde operations.[43] Air France's final Concorde flight took place on 27 June 2003 when F-BVFC retired to Toulouse.[44]

An auction of Concorde parts and memorabilia for Air France was held at Christie's in Paris on 15 November 2003. Thirteen hundred people attended, with several lots exceeding their predicted values by an order of magnitude.

After the end-of-service, French Concorde F-BVFC was retired to Toulouse, and kept functional (including engine runs) for a short while, in case taxi runs were required in support of the French judicial enquiry into the 2000 crash. The aircraft is now fully retired and no longer functional. It is open to the public.

French Concorde F-BTSD has been retired to the "Musée de l'Air et de l'Espace" at Le Bourget (near Paris) and, unlike the other museum Concordes, a few of the systems are being kept functional, so that for instance the famous "droop nose" can still be lowered and raised.

This led to rumours that they could be prepared for future flights for special occasions.[45] Without the necessary maintenance organisation, or spares, this is no longer possible.

British Airways

BA's last Concorde departure from Grantley Adams International Airport in Barbados was on 30 August 2003. BA conducted a mini North American farewell tour in October 2003. G-BOAG visited Toronto Pearson International Airport on 1 October 2003, after which it flew to New York's John F. Kennedy International Airport as part of the tour. G-BOAD visited Boston's Logan International Airport on 8 October 2003, and G-BOAG visited Washington Dulles International Airport on 14 October 2003.[46] G-BOAD's flight to Boston set a record for the fastest transatlantic flight from east to west, making the trip from London Heathrow in 3 hours, 5 minutes, 34 seconds.[47]

In a final week of farewell flights around the United Kingdom, Concorde visited Birmingham on 20 October, Belfast on 21 October, Manchester on 22 October, Cardiff on 23 October, and Edinburgh on 24 October. Each day the aircraft made a return flight out and back into Heathrow to the cities concerned, often overflying those cities at low altitude. Over 650 competition winners and 350 special guests were carried.

On 22 October, Heathrow ATC arranged for the inbound flight BA9021C, a special from Manchester, and BA002 from New York to land simultaneously on the left and right runways respectively.

On the evening of 23 October 2003, the Queen consented to the illumination of Windsor Castle as Concorde's last west-bound commercial flight departed London and flew overhead. This is an honour normally reserved for major state events and visiting dignitaries.

British Airways retired its aircraft the next day, 24 October. G-BOAG left New York to a fanfare similar to that given for Air France's "F-BTSD", while two more made round trips, G-BOAF over the Bay of Biscay, carrying VIP guests including many former Concorde pilots, and G-BOAE to Edinburgh. The three aircraft then circled over London, having received special permission to fly at low altitude, before landing in sequence at Heathrow. The two round-trip aircraft landed at 4:01 and 4:03 p.m. BST, followed at 4:05 by the one from New York. All three aircraft then spent 45 minutes taxiing around the airport before finally disembarking the last supersonic fare-paying passengers. The captain of the New York to London flight was Mike Bannister.

All of BA's Concorde fleet have been grounded, have lost their airworthiness certificates and have been drained of hydraulic fluid. Ex-chief Concorde pilot and manager of the fleet Jock Lowe, estimated in 2004 it would cost £10-15 million to make G-BOAF (at Filton) airworthy again. BA maintains ownership of their fleet, and has stated that they will not fly again, as Airbus ended support of the aircraft in 2003.[48]

On 1 December 2003, Bonhams held an auction of British Airways' Concorde artifacts at Kensington Olympia, in London. Items sold included a Machmeter, nose cone, pilot and passenger seats, cutlery, ashtrays and blankets used on board. Proceeds of about £750,000 resulted, with the first half-million going to Get Kids Going!, a charity which gives disabled children and young people the opportunity to participate in sport.

BA announced in March 2007 that they would not be renewing their contract for the prime advertising spot at entrance to London's Heathrow Airport, where, since 1990, a 40% scale model of Concorde was located. The owners of the site, BAA wanted to charge £1.6 million per year to let it. It will now be occupied by an Emirates Airbus A380. The Concorde model, which bears the "registration" G-CONC, was removed and transported for display in Surrey, under the care of the local Brooklands Museum.[49]

Aircraft histories

Main article: Concorde aircraft histories

In total, 20 Concordes were built, six for development and 14 for commercial service.

These were:

  • Two prototypes
  • Two pre-production aircraft
  • 16 production aircraft
    • The first two of these did not enter commercial service
    • Of the 14 that flew commercially, 8 were still in service in April 2003

All but two of these aircraft, a remarkably high percentage for any commercial fleet, are preserved; the two that are not preserved are F-BVFD (cn 211), parked as a spare-parts source in 1982 and scrapped in 1994, and F-BTSC (cn 203), which crashed in Paris on 25 July 2000.

Concorde Aircraft
Number Reg First flew Last flew Hours Location
001 F-WTSS 2 March 1969 19 October 1973 812 The Museum of Air and Space, Le Bourget, France
002 G-BSST 9 April 1969 4 March 1976 836 Fleet Air Arm Museum, Yeovilton, England, UK
101 G-AXDN 17 December 1971 20 August 1977 632 Imperial War Museum, Duxford, England, UK
102 F-WTSA 10 January 1973 20 May 1976 656 Musée Delta, Orly Airport, Paris, France
201 F-WTSB 6 December 1973 19 April 1985 909 Airbus Factory, Toulouse, France
202 G-BBDG 13 December 1974 24 December 1981 1282 Brooklands Museum, Weybridge, Surrey, England, UK
203 F-BTSC 31 January 1975 25 July 2000 11989 Destroyed in air crash outside Paris, France.[50]
204 G-BOAC 27 February 1975 31 October 2003 22260 Manchester Airport Viewing Park, England, UK. This aircraft was British Airways' flagship Concorde, due to its BOAC registration as it was the first Concorde delivered to BA.
205 F-BVFA 27 October 1976 12 June 2003 17824 Steven F. Udvar-Hazy Center of the Smithsonian National Air and Space Museum, Chantilly, Virginia USA (near Washington, DC)
206 G-BOAA 5 November 1975 12 August 2000 22768 Museum of Flight, East Lothian, Scotland, UK
207 F-BVFB 6 March 1976 24 June 2003 14771 Sinsheim Auto & Technik Museum, Germany
208 G-BOAB 18 May 1976 15 August 2000 22296 Heathrow Airport, London, England, UK
209 F-BVFC 9 July 1976 27 June 2003 14332 Airbus Factory, Toulouse, France
210 G-BOAD 25 August 1976 10 November 2003 23397 Intrepid Sea-Air-Space Museum, New York, USA; in December 2006, the aircraft was temporarily moved to Floyd Bennett Field in Brooklyn for the duration of restoration and rehabilitation work on Intrepid and the pier at which Intrepid and Concorde were located, expected to last until 2008
211 F-BVFD 10 February 1977 27 May 1982 5814 Spare-parts source after 1982 and scrapped in 1994. A small section of the fuselage remains at Le Bourget, France
212 G-BOAE 17 March 1977 17 November 2003 23376 Grantley Adams International Airport, Barbados
213 F-BTSD 26 June 1978 14 June 2003 12974 The Museum of Air and Space, Le Bourget, France
214 G-BOAG 21 April 1978 5 November 2003 16239 Museum of Flight, Seattle, USA
215 F-BVFF 26 December 1978 11 June 2000 12421 Charles de Gaulle Airport, Paris, France
216 G-BOAF 20 April 1979 26 November 2003 18257 Filton Aerodrome, Bristol, England, UK
  • In addition, some spare parts, including Rolls-Royce/Snecma Olympus 593 engines and Snecma intakes are in the Museo del Concorde in Ciudad Juárez, Chihuahua, Mexico. This museum was relocated and opened to the public on 6 May 2008.


A dedicated group of French volunteer engineers is keeping one of the youngest Concordes (F-BTSD) in near-airworthy condition at the Le Bourget Air and Space Museum in Paris.

Although only a "static" example, Concorde G-BBDG was restored from essentially a shell at the Brooklands Museum in Surrey.[51]

Environmental impact

People's reaction to the prospect of severe overhead noise represented a significant change socially. Prior to Concorde's flight trials, the developments made by the civil aviation industry were largely accepted by governments and their respective electorates. However, the opposition to Concorde's noise, particularly on the eastern coast of the United States, forged a new political agenda on both sides of the Atlantic, with scientists and technology experts across a multitude of industries beginning to take the environmental and social impact more seriously. Although Concorde led directly to the introduction of a general noise abatement programme for aircraft flying out of John F. Kennedy International Airport, it was later found that Concorde was actually quieter than some aircraft, partly due to the pilots temporarily throttling back their engines to reduce noise during overflight of residential areas.[52]

Concorde produced nitrogen oxides in its exhaust, which, despite complicated chemical interactions with other ozone-depleting chemicals, are understood to produce a net degradation to the ozone layer at the stratosphere altitudes it cruised.[53] It has been pointed out that other, lower-flying, airliners produce ozone during their flights in the troposphere, but vertical transit of gases between the two is highly restricted. The small fleet size meant that any net ozone-layer degradation caused by Concorde was for all practical purposes negligible.

From this perspective, Concorde's technical leap forward can be viewed as boosting the public's (and the media's) understanding of conflicts between technology and the environment. In France, the use of noise barriers alongside TGV tracks might not have been achieved without the 1970s furore over aircraft noise. In Britain, the CPRE have issued tranquillity maps since 1990 and public agencies are starting to do likewise.

Concorde travelled, per passenger, 17 mi (km {{{4}}}) for each imperial gallon of fuel[54]Template:Mpg (Imperial). This efficiency is comparable to a Gulfstream G550 business jet (Template:Mpg per passenger),[55] but much less efficient than a Boeing 747-400 (Template:Mpg per passenger).[56]

Public perception


Parade flight at Queen's Golden Jubilee

Concorde was normally perceived as a privilege of the rich, but special circular or one-way (with return by coach or ship) charter flights were arranged to bring a trip within the means of moderately well-off enthusiasts.

The presence of a Concorde flying overhead would frequently temporarily halt day-to-day business as people would stop to watch as the plane flew by. A noteworthy example can be found in the TV programme Scrapheap Challenge, where the mechanics drop all their tools and wave as Concorde flies over the yard.

The aircraft was usually referred to by the British as simply "Concorde",[57][58] whilst in France it was known as "le Concorde" due to "le", the definite article[59], being used in French grammar to distinguish a proper name[59] from a common noun of the same spelling.[60][61] In French, the common noun concorde means "agreement, harmony, or peace"[62] and the aircraft's name was almost certainly chosen for its allusion to the collaboration between the British and French governments. Concorde's pilots and British Airways in official publications and videos often refer to Concorde both in the singular and plural as "she" or "her."[63][64]

Concorde remains a powerful symbol, both for its technology and sculptural shape. It is a symbol of great national pride to many in Britain and France; in France it was thought of as a French aircraft, in Britain as British.[65]

As a symbol of national pride, an example from the BA fleet made occasional flypasts at selected Royal events, major air shows and other special occasions, sometimes in formation with the Red Arrows. On the final day of commercial service, public interest was so great that grandstands were erected at London's Heathrow Airport to afford a view of the final arrivals. Crowds filled the boundary road around the airport and there was extensive media coverage.

Thirty-seven years after her first test flight, Concorde was announced the winner of the Great British Design Quest, organised by the BBC and the Design Museum.[65] A total of 212,000 votes were cast with Concorde beating design icons such as the Mini, mini skirt, Jaguar E-type, Tube map and the Supermarine Spitfire.[66]

Comparison with other supersonic aircraft

The only other supersonic airliner in direct competition with Concorde was the Soviet Tu-144. It entered service earlier, and was retired in 1978. Lockheed, North American Aviation and Boeing prepared supersonic airliner studies, but only the Boeing 2707 proceeded even to the mock-up stage, the sole American entry into the supersonic transport sweepstakes.[67]

As a result of a rushed development programme, the Tu-144 was cruder and less refined than Concorde, with notably higher cabin noise. The Tu-144S had a significantly smaller range than Concorde, largely due to its low-bypass turbofan engines. It required reheat to maintain Mach 2.0 and cruised at Mach 1.6.[68] The vehicle had poor control at low speeds because of a simpler, dedicated supersonic wing design. In addition, the Tu-144 required parachutes to land while Concorde had sophisticated anti-lock brakes. The Tu-144 also had two crashes, one at the 1973 Paris Air Show, which made further sales impossible, and another during a pre-delivery test flight. Later versions had retractable canards for better low speed control, and used turbojet engines that gave them nearly the fuel efficiency and similar range to Concorde. It had 126 seats. With a top speed of Mach 2.35 (made possible due to titanium and steel leading edges) and a cruise of Mach 2.16 it was potentially a more competitive aircraft, but it did not sell.

The American design was to have been larger, seating 300. It was also intended to reach higher speeds of up to Mach 3.0, which would have made the construction more difficult: high temperatures ruled out the use of duralumin with design calculations that showed that the extra speed would have only cut Concorde's transatlantic travel by 20 minutes. Running a few years behind Concorde, the extra costs of these features may have helped to kill the project. The discovery from flights of the XB-70 Valkyrie that sonic booms were quite capable of reaching the ground and the experience from the Oklahoma City sonic boom tests debacle led to the same environmental concerns that contributed to hindering commercial success of Concorde. The American government cancelled the project in 1971, after having spent more than $1 billion.[69]

Possible replacements

In November 2003, EADS, parent company of the Airbus aircraft manufacturing company, announced that it was considering working with Japanese companies to develop a larger, faster replacement for Concorde.[70] However, recent news reports suggest only $1m is being invested every year into research, much less than the $1bn needed for the development of a viable supersonic airliner.

In October 2005, JAXA, the Japan Aerospace eXploration Agency, undertook aerodynamic testing of a scale model of an airliner designed to carry 300 passengers at Mach 2. If pursued to commercial deployment, it would be expected to be in service around 2020 - 2025.[71]

The British company Reaction Engines Limited, with 50% EU money, are engaged in a research programme called LAPCAT, which is examining a design for a hydrogen-fuelled plane carrying 300 passengers called the A2, capable of flying nonstop from Brussels to Sydney at Mach 5+ in 4.6 hours.

In May 2008, it was reported that Aerion had $3 billion of preorder sales on its supersonic business jet.[72]

Research into supersonic business jets continues.


Popular culture

Concorde has numerous appearances in various media. Particularly notable or extended appearances or mentions include:

  • The Concorde: Airport '79 film: Concorde starred in this film sequel in the Airport series. The Concorde used for the live-action aerial filming was the Air France Concorde that crashed 21 years later on 25 July 2000.[74]
  • The Concorde Affair (Concorde Affaire in orig.) Italy (1979) film: Director: Ruggero Deodato.
  • There is a chapter dedicated to Concorde in Jeremy Clarkson's book, I Know You Got Soul.



  1. Last Concorde lands
  2. BBC Concorde page
  3. British Airways tribute
  4. 4.0 4.1 "Early History." Retrieved: 8 September 2007.
  5. Benn's Concorde memories in The Guardian
  6. McIntyre 1992, p. 20.
  7. "1969: Concorde flies for the first time." On this day, BBC News Retrieved: 8 September 2007.
  8. Payments for Concorde
  9. Concorde history
  10. Counting the costs
  11. Concorde performance
  12. Concorde Technical Specs: The Delta Wing
  13. Rolls Royce Olympus history
  14. Concorde was tested with both engines on one wing shutdown successfully
  15. Brooklands Museum
  16. Concorde B
  17. British Airway: Cosmic radiation
  18. Hepburn, A.N. "Human Factors in the Concord". Occupational Medicine, 17: 1967, pp. 47–51.
  19. 19.0 19.1 19.2 Concorde nose
  20. Air France fleet: Aircraft no. 209
  21. British Prototype 002 : G-BSS page, Exterior image of G-BSST, Fleet Air Arm Museum, Yeovilton, UK.
  22. Concorde events
  23. Time Magazine
  24. Aircraft 210: G-BOAD
  25. Braniff SST
  26. Backroom boys - Francis Spufford
  27. 27.0 27.1 27.2 'Did Concorde make a profit for British Airways?'
  28. BBC NEWS | Business | Why economists don't fly Concorde
  29. Cleveland National Air Show timeline
  30. Concorde SST timeline
  31. The History of Concorde
  32. The Rotating Earth
  33. Endres 2001, pp. 110-113.
  35. Perception of Risk in the Wake of the Concorde Accident, Issue 14, Airsafe Journal, Revised 6 January 2001.
  36. AP News 3 July 2008
  37. 5 Face Trial in Concorde Crash That Killed 113, New York Times, 3 July 2008
  38. Foxnews
  39. ConcordeSST: return to flight
  40. Concorde: An Untimely and Unnecessary Demise
  41. The Betrayal of Concorde
  42. Lewis, Rob. Supersonic Secrets: The Unofficial Biography of the Concorde. London: Expose, a division of Secret Books Limited, 2003. ISBN 0-95466-170-2.
  43. Air France set for final flights - 23/5/03
  44. Concorde Fox-Bravo Arrives at Final Home - 21 July 2003
  45. UK Times: This is not a flight of fancy
  46. Final trip to Washington for Concorde - 14/10/03
  47. Concorde Sets Another (two) Records - 8/10/03
  49. news story on the model being moved
  50. This was the Concorde featured in the film [[./The_Concorde:_Airport_'79]].
  51. The Brooklands Concorde Project
  52. Endres 2001, p. 90.
  53. Ozone depletion FAQ
  54. Powerplant
  55. Fuel efficiency of airplanes
  56. Boeing 747-400
  57. Concorde - British Airways
  58. Farewell to Concorde
  59. 59.0 59.1 Oxford Language Dictionaries Online - French Resources: Glossary of Grammatical Terms
  60. Centre National de Ressources Textuelle et Lexicalles - Définition de LE, LA: article défini
  61. Reverso Dictionnaire: La majuscule dans les noms propres ("Capital letters within proper names")
  62. Ferrar 1980, p. 114. concorde s.f. concord, unity, harmony, peace.
  63. British Airways - Celebrate Concorde videos
  64. Video including Raymond Baxter commentating as Concorde flies for first time: "She rolls ... She flies!"
  65. 65.0 65.1 Design Quest
  66. Concorde beats Tube map to become Britain's favourite design By Louise Jury
  67. Winchester 2005, p. 84.
  68. Tupolev Tu-144
  69. Where is Boeing Going?
  70. Firm considers 'son of Concorde'
  71. Japan tests supersonic jet model
  72. Orders for Aerion's Concorde executive jet are more than $3 billion
  73. One British Airways aircraft with Singapore Airlines colour scheme on the port fuselage.
  74. Aircraft 203: F-BTSC



  • Barfiel, Norman. "Aérospatiale/BAC Concorde (Aircraft in Profile number 250)". Aircraft in Profile, Volume 14. Windsor, Berkshire, UK: Profile Publications Ltd., 1974, pp. 73–113. ISBN 0-85383-023-1.
  • Beniada, Frederic. Concorde. St Paul, Minnesota: Zenith Press, 2006. ISBN 0-7603-2703-3.
  • Calvert, Brian. Flying Concorde, The Full Story. London: Crowood Press, 2002. ISBN 1-84037-352-0.
  • Endres, Günter. Concorde. St Paul, Minnestota: MBI Publishing Company, 2001. ISBN 0-7603-1195-1.
  • Ferrar, Henry, ed. The Concise Oxford French-English dictionary. New York: Oxford University Press, 2nd Edition, 1980. ISBN 0-19-864157-5.
  • Kelly, Neil. The Concorde Story: 34 Years of Supersonic Air Travel. West Molesey, Surrey, UK: Merchant Book Company Ltd., 2005. ISBN 1-90477-905-0.
  • Knight, Geoffrey. Concorde: The Inside story. London: Weidenfeld and Nicolson, 1976. ISBN 0-297-77114-0.
  • McIntyre, Ian. Dogfight: The Transatlantic Battle over Airbus. Westport, Connecticut: Praeger Publishers, 1992. ISBN 0-275-94278-3.
  • Orlebar, Christopher. The Concorde Story. Oxford, UK: Osprey Publishing, 2004. ISBN 1-85532-667-1.
  • Winchester, Jim. The World's Worst Aircraft: From Pioneering Failures to Multimillion Dollar Disasters. London: Amber Books Ltd., 2005. ISBN 1-904687-34-2.


External links


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