the British Navy

Navy Canvas

NAVY CANVAS

The flax canvas fabric made specially for His Majesty's Navy. There are eight classified numbers in 24-in. and must be made from the best long British, Irish, Riga or Reval flaxes, or from the best long white Dutch, Flemish or Friesland flax. The Royal Navy canvas is made from 25-in. to 28-in. wide and is required to pass a breaking test.

britanska ratna flota

• the british navy

britanska ratna mornarica

• the british navy

engleska pomorska sila

• the british navy

armada

f.

1 navy (marina).

la armada the Navy

la armada Invencible (history) the Spanish Armada

2 naval fleet, fleet, navy, armada.

past part.

past participle of spanish verb: armar.

* * *

armada

► nombre femenino

1 navy, naval forces plural

\

FRASEOLOGÍA

la Armada Invencible the Spanish Armada

* * *

1. f., (m. - armado) 2. noun f.

fleet, navy

* * *

SF

1) [nacional] navy; [escuadra] fleet

la Armada Británica — the British Navy

la Armada Invencible — the Spanish Armada

un oficial de la armada — a naval officer

2) Cono Sur (=lazo) lasso

* * *

femenino navy

la Armada Invencible — the (Spanish) Armada

* * *

femenino navy

la Armada Invencible — the (Spanish) Armada

* * *

armada

feminine

navy

la Armada Invencible the (Spanish) Armada

* * *

armada sustantivo femenino
navy
armado,-a adjetivo armed: iba armado hasta los dientes, he was armed to the teeth
atraco a mano armada, armed robbery
hormigón armado, reinforced concrete
armada sustantivo femenino navy
Hist la Armada Invencible, the Spanish Armada
' armada' also found in these entries:
Spanish:
armado
- atraco
- banda
- imputar
- mano
- asalto
- robo
English:
armed robbery
- RN
- armed
- fleet

* * *

armada nf

1. [marina] navy;

la Armada the Navy

Comp

Hist la Armada Invencible the Spanish Armada

2. [escuadra] fleet

* * *

armada

f

1 navy

2 HIST

:

la Armada the (Spanish) Armada

* * *

armada nf

: navy, fleet

* * *

armada n navy [pl. navies]

Brunel, Sir Marc Isambard

SUBJECT AREA: Civil engineering, Mining and extraction technology, Ports and shipping

[br]

b. 26 April 1769 Hacqueville, Normandy, France

d. 12 December 1849 London, England

[br]

French (naturalized American) engineer of the first Thames Tunnel.

[br]

His mother died when he was 7 years old, a year later he went to college in Gisors and later to the Seminary of Sainte-Nicaise at Rouen. From 1786 to 1792 he followed a career in the French navy as a junior officer. In Rouen he met Sophie Kingdom, daughter of a British Navy contractor, whom he was later to marry. In July 1793 Marc sailed for America from Le Havre. He was to remain there for six years, and became an American citizen, occupying himself as a land surveyor and as an architect. He became Chief Engineer to the City of New York. At General Hamilton's dinner table he learned that the British Navy used over 100,000 ship's blocks every year; this started him thinking how the manufacture of blocks could be mechanized. He roughed out a set of machines to do the job, resigned his post as Chief Engineer and sailed for England in February 1799.

In London he was shortly introduced to Henry Maudslay, to whom he showed the drawings of his proposed machines and with whom he placed an order for their manufacture. The first machines were completed by mid-1803. Altogether Maudslay produced twenty-one machines for preparing the shells, sixteen for preparing the sheaves and eight other machines.

In February 1809 he saw troops at Portsmouth returning from Corunna, the victors, with their lacerated feet bound in rags. He resolved to mechanize the production of boots for the Army and, within a few months, had twenty-four disabled soldiers working the machinery he had invented and installed near his Battersea sawmill. The plant could produce 400 pairs of boots and shoes a day, selling at between 9s. 6d. and 20s. a pair. One day in 1817 at Chatham dockyard he observed a piece of scrap keel timber, showing the ravages wrought by the shipworm, Teredo navalis, which, with its proboscis protected by two jagged concave triangular shells, consumes, digests and finally excretes the ship's timbers as it gnaws its way through them. The excreted material provided material for lining the walls of the tunnel the worm had drilled. Brunel decided to imitate the action of the shipworm on a large scale: the Thames Tunnel was to occupy Marc Brunel for most of the remainder of his life. Boring started in March 1825 and was completed by March 1843. The project lay dormant for long periods, but eventually the 1,200 ft (366 m)-long tunnel was completed. Marc Isambard Brunel died at the age of 80 and was buried at Kensal Green cemetery.

[br]

Principal Honours and Distinctions

FRS 1814. Vice-President, Royal Society 1832.

Further Reading

P.Clements, 1970, Marc Isambard Brunel, London: Longmans Green.

IMcN

Bentham, Sir Samuel

SUBJECT AREA: Ports and shipping

[br]

b. 11 January 1757 England

d. 31 May 1831 London, England

[br]

English naval architect and engineer.

[br]

He was the son of Jeremiah Bentham, a lawyer. His mother died when he was an infant and his early education was at Westminster. At the age of 14 he was apprenticed to a master shipwright at Woolwich and later at Chatham Dockyard, where he made some small improvements in the fittings of ships. In 1778 he completed his apprenticeship and sailed on the Bienfaisant on a summer cruise of the Channel Fleet where he suggested and supervised several improvements to the steering gear and gun fittings.

Unable to find suitable employment at home, he sailed for Russia to study naval architecture and shipbuilding, arriving at St Petersburg in 1780, whence he travelled throughout Russia as far as the frontier of China, examining mines and methods of working metals. He settled in Kritchev in 1782 and there established a small shipyard with a motley work-force. In 1784 he was appointed to command a battalion. He set up a yard on the "Panopticon" principle, with all workshops radiating from his own central office. He increased the armament of his ships greatly by strengthening the hulls and fitting guns without recoil, which resulted in a great victory over the Turks at Liman in 1788. For this he was awarded the Cross of St George and promoted to Brigadier- General. Soon after, he was appointed to a command in Siberia, where he was responsible for opening up the resources of the country greatly by developing river navigation.

In 1791 he returned to England, where he was at first involved in the development of the Panopticon for his brother as well as with several other patents. In 1795 he was asked to look into the mechanization of the naval dockyards, and for the next eighteen years he was involved in improving methods of naval construction and machinery. He was responsible for the invention of the steam dredger, the caisson method of enclosing the entrances to docks, and the development of non-recoil cannonades of large calibre.

His intervention in the maladministration of the naval dockyards resulted in an enquiry that brought about the clearing-away of much corruption, making him very unpopular. As a result he was sent to St Petersburg to arrange for the building of a number of ships for the British navy, in which the Russians had no intention of co-operating. On his return to England after two years he was told that his office of Inspector-General of Navy Works had been abolished and he was appointed to the Navy Board; he had several disagreements with John Rennie and in 1812 was told that this office, too, had been abolished. He went to live in France, where he stayed for thirteen years, returning in 1827 to arrange for the publication of some of his papers.

There is some doubt about his use of his title: there is no record of his having received a knighthood in England, but it was assumed that he was authorized to use the title, granted to him in Russia, after his presentation to the Tsar in 1809.

[br]

Further Reading

Mary Sophia Bentham, Life of Brigadier-General Sir Samuel Bentham, K.S.G., Formerly Inspector of Naval Works (written by his wife, who died before completing it; completed by their daughter).

IMcN

британский подданный

1) General subject: British subject, Britisher

2) Politics: British passport-holder

3) American English: Limey (abbreviation of 'lime-juicer', from the former enforced consumption of lime-juice as an antiscorbutic in the British Navy)

commander

noun

1) a person who commands:

He was the commander of the expedition.

قائِد

2) in the British navy, an officer of the rank next below the captain.

رُتبة في البَحْرِيَّه البَريطانيه دون الكابتِن

Erste Offizier

der

(in the British navy, an officer of the rank next below the captain.) commander

Flottenadmiral

der

(in the British navy, (of) the rank next above captain.) commodore

Rogues' Yarn

ROGUES' YARN

A coloured strand of worsted twisted in the rope manufactured for the British Navy.

commodore

[ˈkɔmədɔː] noun

in the British navy, (of) the rank next above captain.

قائِد، عَميد بَحْري

Romal

ROMAL

A silk fabric made in India from native silk. Plain weave, about 72 ends and 72 picks per inch, and 120 to 150 denier yarns. Used for dress purposes and handkerchiefs. A bordered cotton handkerchief made from blue and white yarns about 48 ends and 48 picks per inch, 18's warp, 20's weft. In designs with blue predominating. The British Navy supplies this cloth to sailors.

Angehörige der britischen Marine

members of the British Navy

Anglo-Portuguese Alliance

   The world's oldest diplomatic connection and alliance, an enduring arrangement between two very different nations and peoples, with important practical consequences in the domestic and foreign affairs of both Great Britain (England before 1707) and Portugal. The history of this remarkable alliance, which has had commercial and trade, political, foreign policy, cultural, and imperial aspects, can be outlined in part with a list of the main alliance treaties after the first treaty of commerce and friendship signed between the monarchs of England and Portugal in 1373. This was followed in 1386 by the Treaty of Windsor; then in 1654, 1661, 1703, the Methuen Treaty; and in 1810 and 1899 another treaty also signed at Windsor.

   Common interests in the defense of the nation and its overseas empire (in the case of Portugal, after 1415; in the case of England, after 1650) were partly based on characteristics and common enemies both countries shared. Even in the late Middle Ages, England and Portugal faced common enemies: large continental countries that threatened the interests and sovereignty of both, especially France and Spain. In this sense, the Anglo-Portuguese Alliance has always been a defensive alliance in which each ally would assist the other when necessary against its enemies. In the case of Portugal, that enemy invariably was Spain (or component states thereof, such as Castile and Leon) and sometimes France (i.e., when Napoleon's armies invaded and conquered Portugal as of late 1807). In the case of England, that foe was often France and sometimes Spain as well.

   Beginning in the late 14th century, England and Portugal forged this unusual relationship, formalized with several treaties that came into direct use during a series of dynastic, imperial, naval, and commercial conflicts between 1373 and 1961, the historic period when the Anglo-Portuguese Alliance had its most practical political significance. The relative world power and importance of each ally has varied over the centuries. During the period 1373-1580, the allies were similar in respective ranking in European affairs, and during the period 1480-1550, if anything, Portugal was a greater world power with a more important navy than England. During 1580-1810, Portugal fell to the status of a third-rank European power and, during 1810-1914, England was perhaps the premier world power. During 1914-61, England's world position slipped while Portugal made a slow recovery but remained a third- or fourth-rank power.

   The commercial elements of the alliance have always involved an exchange of goods between two seafaring, maritime peoples with different religions and political systems but complementary economies. The 1703 Methuen Treaty establ ished a trade link that endured for centuries and bore greater advantages for England than for Portugal, although Portugal derived benefits: English woolens for Portuguese wines, especially port, other agricultural produce, and fish. Since the signing of the Methuen Treaty, there has been a vigorous debate both in politics and in historical scholarship as to how much each nation benefited economically from the arrangement in which Portugal eventually became dependent upon England and the extent to which Portugal became a kind of economic colony of Britain during the period from 1703 to 1910.

   There is a vast literature on the Alliance, much of it in Portuguese and by Portuguese writers, which is one expression of the development of modern Portuguese nationalism. During the most active phase of the alliance, from 1650 to 1945, there is no doubt but that the core of the mutual interests of the allies amounted to the proposition that Portugal's independence as a nation in Iberia and the integrity of its overseas empire, the third largest among the colonial powers as of 1914, were defended by England, who in turn benefited from the use by the Royal Navy of Portugal's home and colonial ports in times of war and peace. A curious impact on Portuguese and popular usage had also come about and endured through the impact of dealings with the English allies. The idiom in Portuguese, "é para inglês ver," means literally "it is for the Englishman to see," but figuratively it really means, "it is merely for show."

   The practical defense side of the alliance was effectively dead by the end of World War II, but perhaps the most definitive indication of the end of the political significance of an alliance that still continues in other spheres occurred in December 1961, when the army of the Indian Union invaded Portugal's colonial enclaves in western India, Goa, Damão, and Diu. While both nations were now North Atlantic Treaty Organization allies, their interests clashed when it came to imperial and Commonwealth conflicts and policies. Portugal asked Britain for military assistance in the use of British bases against the army of Britain's largest former colony, India. But Portugal was, in effect, refused assistance by her oldest ally. If the alliance continues into the 21st century, its essence is historical, nostalgic, commercial, and cultural.

    See also Catherine of Braganza.

Holland, John Philip

SUBJECT AREA: Ports and shipping

[br]

b. 29 February 1840 Liscanor, Co. Clare, Ireland

d. 12 August 1915 Newark, New Jersey, USA

[br]

Irish/American inventor of the successful modern submarine

[br]

Holland was educated first in his native town and later in Limerick, a seaport bustling with coastal trade ships. His first job was that of schoolteacher, and as such he worked in various parts of Ireland until he was about 32 years old. A combination of his burning patriotic zeal for Ireland and his interest in undersea technology (then in its infancy) made him consider designs for underwater warships for use against the British Royal Navy in the fight for Irish independence. He studied all known works on the subject and commenced drawing plans, but he was unable to make real headway owing to a lack of finance.

In 1873 he travelled to the United States, ultimately settling in New Jersey and continuing in the profession of teaching. His work on submarine design continued, but in 1875 he suffered a grave setback when the United States Navy turned down his designs. Help came from an unexpected source, the Irish Republican Brotherhood, or Fenian Society, which had been founded in Dublin and New York in 1858. Financial help enabled Holland to build a 4 m (13 ft) one-person craft, which was tested in 1878, and then a larger boat of 19 tonnes' displacement that was tested with a crew of three to depths of 20 m (65 ft) in New York's harbour in 1883. Known as the Fenian Ram, it embodied most of the principles of modern submarines, including weight compensation. The Fenians commandeered this boat, but they were unable to operate it satisfactorily and it was relegated to history.

Holland continued work, at times independently and sometimes with others, and continuously advocated submarines to the United States Navy. In 1895 he was successful in winning a contract for US$150,000 to build the US Submarine Plunger at Baltimore. With too much outside interference, this proved an unsatisfactory venture. However, with only US$5,000 of his capital left, Holland started again and in 1898 he launched the Holland at Elizabeth, New Jersey. This 16 m (52 ft) vessel was successful, and in 1900 it was purchased by the United States Government.

Six more boats were ordered by the Americans, and then some by the Russians and the Japanese. The British Royal Navy ordered five, which were built by Vickers Son and Maxim (now VSEL) at Barrow-in-Furness in the years up to 1903, commencing their long run of submarine building. They were licensed by another well-known name, the Electric Boat Company, which had formerly been the J.P.Holland Torpedo Boat Company.

Holland now had some wealth and was well known. He continued to work, trying his hand at aeronautical research, and in 1904 he invented a respirator for use in submarine rescue work. It is pleasing to record that one of his ships can be seen to this day at the Royal Navy Submarine Museum, Gosport: HM Submarine Holland No. 1, which was lost under tow in 1913 but salvaged and restored in the 1980s.

[br]

Principal Honours and Distinctions

Order of the Rising Sun, Japan, 1910.

Bibliography

1900, "The submarine boat and its future", North American Review (December). Holland wrote several other articles of a similar nature.

Further Reading

R.K.Morris, 1966 John P.Holland 1841–1914, Inventor of the Modern Submarine, Annapolis, MD: US Naval Institute.

F.W.Lipscomb, 1975, The British Submarine, London: Conway Maritime Press. A.N.Harrison, 1979, The Development of HM Submarines from Holland No. 1 (1901) to

Porpoise (1930), Bath: MoD Ships Department (internal publication).

FMW

Taylor, David Watson

SUBJECT AREA: Ports and shipping

[br]

b. 4 March 1864 Louisa County, Virginia, USA

d. 29 July 1940 Washington, DC, USA

[br]

American hydrodynamicist and Rear Admiral in the United States Navy Construction Corps.

[br]

Taylor's first years were spent on a farm in Virginia, but at the age of 13 he went to RandolphMacon College, graduating in 1881, and from there to the US Naval Academy, Annapolis. He graduated at the head of his class, had some sea time, and then went to the Royal Naval College in Greenwich, England, where in 1888 he again came top of the class with the highest-ever marks of any student, British or overseas.

On his return to the United States he held various posts as a constructor, ending this period at the Mare Island Navy Yard in California. In 1894 he was transferred to Washington, where he joined the Bureau of Construction and started to interest the Navy in ship model testing. Under his direction, the first ship model tank in the United States was built at Washington and for fourteen years operated under his control. The work of this establishment gave him the necessary information to write the highly acclaimed text The Speed and Power of Ships, which with revisions is still in use. By the outbreak of the First World War he was one of the world's most respected naval architects, and had been retained as a consultant by the British Government in the celebrated case of the collision between the White Star Liner Olympic and HMS Hawke.

In December 1914 Taylor became a Rear-Admiral and was appointed Chief Constructor of the US Navy. His term of office was extremely stressful, with over 1,000 ships constructed for the war effort and with the work of the fledgling Bureau for Aeronautics also under his control. The problems were not over in 1918 as the Washington Treaty required drastic pruning of the Navy and a careful reshaping of the defence force.

Admiral Taylor retired from active service at the beginning of 1923 but retained several consultancies in aeronautics, shipping and naval architecture. For many years he served as consultant to the ship-design company now known as Gibbs and Cox. Many honours came his way, but the most singular must be the perpetuation of his name in the David Taylor Medal, the highest award of the Society of Naval Architects and Marine Engineers in the United States. Similarly, the Navy named its ship test tank facility, which was opened in Maryland in 1937, the David W. Taylor Model Basin.

[br]

Principal Honours and Distinctions

President, Society of Naval Architects and Marine Engineers 1925–7. United States Distinguished Service Medal. American Society of Civil Engineers John Fritz Medal. Institution of Naval Architects Gold Medal 1894 (the first American citizen to receive it). Society of Naval Architects and Marine Engineers David W.Taylor Medal 1936 (the first occasion of this award).

Bibliography

Resistance of Ships and Screw Propulsion. 1911, The Speed and Power of Ships, New York: Wiley.

Taylor gave many papers to the Maritime Institutions of both the United States and the United Kingdom.

FMW

Chapman, Frederik Henrik af

SUBJECT AREA: Ports and shipping

[br]

b. 9 September 1721 Gothenburg, Sweden

d. 19 August 1808 Karlskrona, Sweden

[br]

Swedish naval architect and shipbuilder; one of the foremost ship designers of all time.

[br]

Chapman was born on the west coast of Sweden and was the son of a British naval officer serving in the Swedish Navy. In 1738 he followed in his father's footsteps by joining the naval dockyards as a shipbuilding apprentice. Subsequent experience was gained in other shipyards and by two years (1741–3) in London. His assiduous note taking and study of British shipbuilding were noticed and he was offered appointments in England, but these were refused and he returned to Sweden in 1744 and for a while operated as a ship repairer in partnership with a man called Bagge. In 1749 he started out on his own. He began with a period of study in Stockholm and in London, where he worked for a while under Thomas Simpson, and then went on to France and the Netherlands. During his time in England he learned the art of copper etching, a skill that later stood him in good stead. After some years he was appointed Deputy Master Shipwright to the Swedish Navy, and in 1760 he became Master Shipwright at Sveaborg (now Suomenlinna), the fortress island of Helsinki. There Chapman excelled by designing the coastal defence or skerry fleet that to this day is accepted as beautiful and fit for purpose. He understood the limitations of ship design and throughout his life strove to improve shipbuilding by using the advances in mathematics and science that were then being made. His contribution to the rationalization of thought in ship theory cannot be overemphasized.

In 1764 he became Chief Shipbuilder to the Swedish Navy, with particular responsibility for Karlskrona and for Stockholm. He assisted in the new rules for the classification of warships and later introduced standardization to the naval dockyards. He continued to rise in rank and reputation until his retirement in 1793, but to the end his judgement was sought on many matters concerning not only ship design but also the administration of the then powerful Swedish Navy.

His most important bequest to his profession is the great book Architectura Navalis Mercatoria, first published in 1768. Later editions were larger and contained additional material. This volume remains one of the most significant works on shipbuilding.

[br]

Principal Honours and Distinctions

Knighted 1772. Rear Admiral 1783, Vice-Admiral 1791.

Bibliography

1768, Architecture Navalis Mercatoria; 1975, pub. in English, trans. Adlard Coles. 1775, Tractat om Skepps-Buggeriet.

Further Reading

D.G.Harris, 1989, F.H.Chapman, the First Naval Architect and His Work, London: Conway (an excellent biography).

FMW

Sopwith, Sir Thomas (Tommy) Octave Murdoch

SUBJECT AREA: Aerospace

[br]

b. 18 January 1888 London, England

d. 27 January 1989 Stockbridge, Hampshire, England

[br]

English aeronautical engineer and industrialist.

[br]

Son of a successful mining engineer, Sopwith did not shine at school and, having been turned down by the Royal Navy as a result, attended an engineering college. His first interest was motor cars and, while still in his teens, he set up a business in London with a friend in order to sell them; he also took part in races and rallies.

Sopwith's interest in aviation came initially through ballooning, and in 1906 he purchased his own balloon. Four years later, inspired by the recent flights across the Channel to France and after a joy-ride at Brooklands, he bought an Avis monoplane, followed by a larger biplane, and taught himself to fly. He was awarded the Royal Aero Society's Aviator Certificate No. 31 on 21 November 1910, and he quickly distinguished himself in flying competitions on both sides of the Atlantic and started his own flying school. In his races he was ably supported by his friend Fred Sigrist, a former motor engineer. Among the people Sopwith taught to fly were an Australian, Harry Hawker, and Major Hugh Trenchard, who later became the "father" of the RAF.

In 1912, depressed by the poor quality of the aircraft on trial for the British Army, Sopwith, in conjunction with Hawker and Sigrist, bought a skating rink in Kingston-upon-Thames and, assisted by Fred Sigrist, started to design and build his first aircraft, the Sopwith Hybrid. He sold this to the Royal Navy in 1913, and the following year his aviation manufacturing company became the Sopwith Aviation Company Ltd. That year a seaplane version of his Sopwith Tabloid won the Schneider Trophy in the second running of this speed competition. During 1914–18, Sopwith concentrated on producing fighters (or "scouts" as they were then called), with the Pup, the Camel, the 1½ Strutter, the Snipe and the Sopwith Triplane proving among the best in the war. He also pioneered several ideas to make flying easier for the pilot, and in 1915 he patented his adjustable tailplane and his 1 ½ Strutter was the first aircraft to be fitted with air brakes. During the four years of the First World War, Sopwith Aviation designed thirty-two different aircraft types and produced over 16,000 aircraft.

The end of the First World War brought recession to the aircraft industry and in 1920 Sopwith, like many others, put his company into receivership; none the less, he immediately launched a new, smaller company with Hawker, Sigrist and V.W.Eyre, which they called the H.G. Hawker Engineering Company Ltd to avoid any confusion with the former company. He began by producing cars and motor cycles under licence, but was determined to resume aircraft production. He suffered an early blow with the death of Hawker in an air crash in 1921, but soon began supplying aircraft to the Royal Air Force again. In this he was much helped by taking on a new designer, Sydney Camm, in 1923, and during the next decade they produced a number of military aircraft types, of which the Hart light bomber and the Fury fighter, the first to exceed 200 mph (322 km/h), were the best known. In the mid-1930s Sopwith began to build a large aviation empire, acquiring first the Gloster Aircraft Company and then, in quick succession, Armstrong-Whitworth, Armstrong-Siddeley Motors Ltd and its aero-engine counterpart, and A.V.Roe, which produced Avro aircraft. Under the umbrella of the Hawker Siddeley Aircraft Company (set up in 1935) these companies produced a series of outstanding aircraft, ranging from the Hawker Hurricane, through the Avro Lancaster to the Gloster Meteor, Britain's first in-service jet aircraft, and the Hawker Typhoon, Tempest and Hunter. When Sopwith retired as Chairman of the Hawker Siddeley Group in 1963 at the age of 75, a prototype jump-jet (the P-1127) was being tested, later to become the Harrier, a for cry from the fragile biplanes of 1910.

Sopwith also had a passion for yachting and came close to wresting the America's Cup from the USA in 1934 when sailing his yacht Endeavour, which incorporated a number of features years ahead of their time; his greatest regret was that he failed in his attempts to win this famous yachting trophy for Britain. After his retirement as Chairman of the Hawker Siddeley Group, he remained on the Board until 1978. The British aviation industry had been nationalized in April 1977, and Hawker Siddeley's aircraft interests merged with the British Aircraft Corporation to become British Aerospace (BAe). Nevertheless, by then the Group had built up a wide range of companies in the field of mechanical and electrical engineering, and its board conferred on Sopwith the title Founder and Life President.

[br]

Principal Honours and Distinctions

Knighted 1953. CBE 1918.

Bibliography

1961, "My first ten years in aviation", Journal of the Royal Aeronautical Society (April) (a very informative and amusing paper).

Further Reading

A.Bramson, 1990, Pure Luck: The Authorized Biography of Sir Thomas Sopwith, 1888– 1989, Wellingborough: Patrick Stephens.

B.Robertson, 1970, Sopwith. The Man and His Aircraft, London (a detailed publication giving plans of all the Sopwith aircraft).

CM / JDS