''. Mechanical systems used for throwing ammunition in ancient warfare, also known as "
engines of war", like the
catapult,
onager,
trebuchet, and
ballista, are also referred to by military historians as artillery.
Medieval During medieval times, more types of artillery were developed, most notably the counterweight trebuchet. Traction trebuchets, using manpower to launch projectiles, have been used in ancient China since the 4th century as anti-personnel weapons. The much more powerful counterweight trebuchet was invented in the eastern Mediterranean region in the 12th century, with the earliest definite attestation in 1187.
Invention of gunpowder . These small, crude weapons diffused into the Middle East (the
madfaa) and reached Europe in the 13th century, in a very limited manner. In Asia,
Mongols adopted the Chinese artillery and used it effectively in the
great conquest. By the late 14th century, Chinese rebels used organized artillery and cavalry to push Mongols out. As small smooth-bore barrels, these were initially cast in iron or bronze around a core, with the first drilled bore ordnance recorded in operation near Seville in 1247. They fired lead, iron, or stone balls, sometimes large arrows and on occasions simply handfuls of whatever scrap came to hand. During the
Hundred Years' War, these weapons became more common, initially as the
bombard and later the
cannon. Cannons were always
muzzle-loaders. While there were many early attempts at
breech-loading designs, a lack of engineering knowledge rendered these even more dangerous to use than muzzle-loaders.
Expansion of use In 1415, the Portuguese invaded the Mediterranean port town of
Ceuta. While it is difficult to confirm the use of firearms in the siege of the city, it is known the Portuguese defended it thereafter with firearms, namely
bombardas,
colebratas, and
falconetes. In 1419, Sultan Abu Sa'id led an army to reconquer the fallen city, and Marinids brought cannons and used them in the assault on Ceuta. Finally, hand-held firearms and riflemen appear in Morocco, in 1437, in an expedition against the people of
Tangiers. It is clear these weapons had developed into several different forms, from small guns to large artillery pieces. The artillery revolution in Europe caught on during the
Hundred Years' War and changed the way that battles were fought. In the preceding decades, the English had even used a gunpowder-like weapon in military campaigns against the Scottish. However, at this time, the cannons used in battle were very small and not particularly powerful. Cannons were only useful for the defense of a
castle, as demonstrated at
Breteuil in 1356, when the besieged English used a cannon to destroy an attacking French assault tower. By the end of the 14th century, cannons were only powerful enough to knock in roofs, and could not penetrate castle walls. However, a major change occurred between 1420 and 1430, when artillery became much more powerful and could now batter strongholds and fortresses quite efficiently. The English, French, and Burgundians all advanced in military technology, and as a result the traditional advantage that went to the defense in a siege was lost. Cannons during this period were elongated, and the recipe for gunpowder was improved to make it three times as powerful as before. These changes led to the increased power in the artillery weapons of the time. , the earliest extant
large-calibre gun Joan of Arc encountered gunpowder weaponry several times. When she led the French against the English at the Battle of Tourelles, in 1430, she faced heavy gunpowder fortifications, and yet her troops prevailed in that battle. In addition, she led assaults against the English-held towns of Jargeau, Meung, and Beaugency, all with the support of large artillery units. When she led the assault on Paris, Joan faced stiff artillery fire, especially from the suburb of St. Denis, which ultimately led to her defeat in this battle. In April 1430, she went to battle against the Burgundians, whose support was purchased by the English. At this time, the Burgundians had the strongest and largest gunpowder arsenal among the European powers, and yet the French, under Joan of Arc's leadership, were able to beat back the Burgundians and defend themselves. As a result, most of the battles of the Hundred Years' War that Joan of Arc participated in were fought with gunpowder artillery. . Very heavy 15th-C bronze muzzle-loading cannon of type used by
Ottomans in
siege of Constantinople (1453), showing ornate decoration. Taken by The Land Feb 07 at
Fort Nelson, Hampshire. The army of
Mehmet the Conqueror, which conquered
Constantinople in 1453, included both artillery and foot soldiers armed with gunpowder weapons. The
Ottomans brought to the siege sixty-nine guns in fifteen separate
batteries and trained them at the walls of the city. The barrage of Ottoman cannon fire lasted forty days, and they are estimated to have fired 19,320 times. Artillery also played a decisive role in the
Battle of St. Jakob an der Birs of 1444. Early cannon were not always reliable; King
James II of Scotland was killed by the accidental explosion of one of his own cannon, imported from Flanders, at the siege of Roxburgh Castle in 1460. The able use of artillery supported to a large measure the expansion and defense of the
Portuguese Empire, as it was a necessary tool that allowed the Portuguese to face overwhelming odds both on land and sea from
Morocco to Asia. An especially noticeable division between siege guns and anti-personnel guns enhanced the use and effectiveness of Portuguese firearms above contemporary powers, making cannon the most essential element in the Portuguese arsenal. The most popular in Portuguese arsenals was the
berço, a 5 cm, one pounder bronze breech-loading cannon that weighted 150 kg with an effective range of 600 meters. in the Jinju National Museum. These cannons were made in the mid 16th century. The closest is a "Cheonja chongtong"(천자총통, 天字銃筒), the second is a "Jija chongtong"(지자총통, 地字銃筒), and the third is a "Hyeonja chongtong"(현자총통, 玄字銃筒). The new
Ming Dynasty established the "Divine Engine Battalion" (神机营), which specialized in various types of artillery. Light cannons and cannons with multiple volleys were developed. In a campaign to suppress a local minority rebellion near today's Burmese border, "the Ming army used a 3-line method of arquebuses/muskets to destroy an elephant formation". When the Portuguese and Spanish arrived at Southeast Asia, they found that the local kingdoms were already using cannons. Portuguese and Spanish invaders were unpleasantly surprised and even outgunned on occasion. Duarte Barbosa ca. 1514 said that the inhabitants of Java were great masters in casting artillery and very good artillerymen. They made many one-pounder cannons (cetbang or
rentaka), long muskets,
spingarde (arquebus),
schioppi (hand cannon),
Greek fire, guns (cannons), and other fire-works. In all aspects the Javanese were considered excellent in casting artillery, and in the knowledge of using it. In 1513, the
Javanese fleet led by Pati Unus sailed to attack
Portuguese Malacca "with much artillery made in Java, for the Javanese are skilled in founding and casting, and in all works in
iron, over and above what they have in
India". By the early 16th century, the
Javanese had already started locally-producing large guns, which were dubbed "sacred cannon[s]" or "holy cannon[s]" and have survived up to the present day – though in limited numbers. These cannons varied between 180 and 260-pounders, weighing anywhere between 3–8 tons, measuring between 3–6 m. Between 1593 and 1597, about 200,000 Korean and Chinese troops which
fought against Japan in Korea actively used heavy artillery in both siege and field combat. Korean forces mounted artillery
in ships as
naval guns, providing an advantage against Japanese navy which used
Kunikuzushi (国崩し – Japanese
breech-loading swivel gun) and
Ōzutsu (大筒 – large size
Tanegashima) as their largest firearms. In the 16th century Ottoman Empire,
Humbaracıs were founded.
Smoothbores fortification Bombards were of value mainly in
sieges. A famous
Ottoman example, the "
Basilic", used at the
siege of Constantinople in 1453, that weighed around 19 tonnes. It could fire a stone ball of more than , but could only fire seven or eight times a day. The gun took two hundred men and sixty oxen to move, with a further 250 labourers to improve the road in front of it, travelling at little more than per day. It formed part of a battery of 70 bronze guns, of which 19 were very large; together they fired 4,000 balls over 53 days and breached the walls in several places, although the final assault was enabled by a traitor opening a
postern gate. The Fall of Constantinople was perhaps "the first event of supreme importance whose result was determined by the use of artillery" when the successful siege ended the
Byzantine Empire, according to Sir
Charles Oman, The difficulty of moving such huge pieces led the Ottomans to cast very large guns in several sections that were screwed together before firing, such as the
Dardanelles Gun. These guns were sometimes cast at the site of the siege itself. Bombards developed in Europe were massive
smoothbore weapons distinguished by their lack of a field carriage, immobility once emplaced, highly individual design, and noted unreliability (in 1460
James II, King of Scots, was killed when one exploded at the siege of Roxburgh). Their large size precluded the barrels being cast and they were constructed out of metal staves or rods bound together with hoops like a barrel, giving their name to the
gun barrel. The use of the word "cannon" marks the introduction in the 15th century of a dedicated field carriage with axle, trail and animal-drawn limber—this produced mobile field pieces that could move and support an army in action, rather than being found only in the siege and static defenses. The reduction in the size of the barrel was due to improvements in both iron technology and gunpowder manufacture, while the development of
trunnions—projections at the side of the cannon as an integral part of the cast—allowed the barrel to be fixed to a more movable base, and also made raising or lowering the barrel much easier. The development of specialized pieces—shipboard artillery, howitzers and
mortars—was also begun in this period. More esoteric designs, like the multi-barrel
ribauldequin (known as "organ guns"), were also produced. The 1650 book by
Kazimierz Siemienowicz Artis Magnae Artilleriae pars prima was one of the most important contemporary publications on the subject of artillery. For over two centuries this work was used in Europe as a basic artillery manual. during the
Thirty Years' War, 1628 One of the most significant effects of artillery during this period was however somewhat more indirect—by easily reducing to rubble any medieval-type fortification or city wall (some which had stood since Roman times), it abolished millennia of siege-warfare strategies and styles of fortification building. After the wars, several Mysore rockets were sent to England, but experiments with heavier payloads were unsuccessful. In 1804 William Congreve, considering the Mysorian rockets to have too short a range (less than 1,000 yards) developed rockets in numerous sizes with ranges up to 3,000 yards and eventually utilizing iron casing as the
Congreve rocket which were used effectively during the
Napoleonic Wars and the
War of 1812.
Napoleonic to commemorate the city's resistance to the
1799 siege by
Napoleon's troops. With the Napoleonic Wars, artillery experienced changes in both physical design and operation. Rather than being overseen by "mechanics", artillery was viewed as its own service branch with the capability of dominating the battlefield. The success of the French artillery companies was at least in part due to the presence of specially trained artillery officers leading and coordinating during the chaos of battle.
Napoleon, himself a former artillery officer, perfected the tactic of massed artillery batteries unleashed upon a critical point in his enemies' line as a prelude to a decisive infantry and cavalry assault. Physically, cannons continued to become smaller and lighter. During the Seven Years War,
King Frederick II of Prussia used these advances to deploy horse artillery that could move throughout the battlefield. Frederick also introduced the reversible iron ramrod, which was much more resistant to breakage than older wooden designs. The reversibility aspect also helped increase the rate of fire, since a soldier would no longer have to worry about what end of the ramrod they were using.
Jean-Baptiste de Gribeauval, a French artillery engineer, introduced the standardization of cannon design in the mid-18th century. He developed a 6-inch (150 mm) field howitzer whose gun barrel, carriage assembly and ammunition specifications were made uniform for all French cannons. The standardized interchangeable parts of these cannons down to the nuts, bolts and screws made their mass production and repair much easier. While the Gribeauval system made for more efficient production and assembly, the carriages used were heavy and the gunners were forced to march on foot (instead of riding on the
limber and gun as in the British system). Each cannon was named for the weight of its projectiles, giving us variants such as 4, 8, and 12, indicating the weight in pounds. The projectiles themselves included solid balls or canister containing lead bullets or other material. These canister shots acted as massive shotguns, peppering the target with hundreds of projectiles at close range. The solid balls, known as
round shot, was most effective when fired at shoulder-height across a flat, open area. The ball would tear through the ranks of the enemy or bounce along the ground breaking legs and ankles.
Modern n artillery at the
Battle of Langensalza (1866) The development of modern artillery occurred in the mid to late 19th century as a result of the convergence of various improvements in the underlying technology. Advances in metallurgy allowed for the construction of
breech-loading rifled guns that could fire at a much greater
muzzle velocity. After the British artillery was shown up in the
Crimean War as having barely changed since the
Napoleonic Wars, the industrialist
William Armstrong was awarded a contract by the government to design a new piece of artillery. Production started in 1855 at the
Elswick Ordnance Company and the
Royal Arsenal at
Woolwich, and the outcome was the revolutionary
Armstrong Gun, which marked the birth of modern artillery. Three of its features particularly stand out. (1868–69)|left First, the piece was rifled, which allowed for a much more accurate and powerful action. Although rifling had been tried on small arms since the 15th century, the necessary machinery to accurately rifle artillery was not available until the mid-19th century.
Martin von Wahrendorff, and
Joseph Whitworth independently produced rifled cannon in the 1840s, but it was Armstrong's gun that was first to see widespread use during the Crimean War. The
cast iron shell of the Armstrong gun was similar in shape to a
Minié ball and had a thin lead coating which made it fractionally larger than the gun's
bore and which engaged with the gun's rifling grooves to impart spin to the shell. This spin, together with the elimination of
windage as a result of the tight fit, enabled the gun to achieve greater range and accuracy than existing smooth-bore muzzle-loaders with a smaller powder charge. ,
Fort Fisher, 1865 His gun was also a breech-loader. Although attempts at breech-loading mechanisms had been made since medieval times, the essential engineering problem was that the mechanism could not withstand the explosive charge. It was only with the advances in
metallurgy and
precision engineering capabilities during the
Industrial Revolution that Armstrong was able to construct a viable solution. The gun combined all the properties that make up an effective artillery piece. The gun was mounted on a carriage in such a way as to return the gun to firing position after the
recoil. , the first modern artillery piece What made the gun really revolutionary lay in the technique of the construction of the gun barrel that allowed it to withstand much more powerful explosive forces. The "
built-up" method involved assembling the barrel with
wrought-iron (later
mild steel was used) tubes of successively smaller diameter. The tube would then be heated to allow it to expand and fit over the previous tube. When it cooled the gun would contract although not back to its original size, which allowed an even pressure along the walls of the gun which was directed inward against the outward forces that the gun's firing exerted on the barrel. Another innovative feature, more usually associated with 20th-century guns, was what Armstrong called its "grip", which was essentially a squeeze bore; the 6 inches of the bore at the muzzle end was of slightly smaller diameter, which centered the shell before it left the barrel and at the same time slightly
swaged down its lead coating, reducing its diameter and slightly improving its ballistic qualities. Armstrong's system was adopted in 1858, initially for "special service in the field" and initially he produced only smaller artillery pieces, 6-pounder (2.5 in/64 mm) mountain or light field guns, 9-pounder (3 in/76 mm) guns for
horse artillery, and
12-pounder (3 inches /76 mm) field guns. The first cannon to contain all 'modern' features is generally considered to be the
French 75 of 1897. The gun used cased ammunition, was breech-loading, had modern sights, and a self-contained firing mechanism. It was the first
field gun to include a
hydro-pneumatic recoil mechanism, which kept the gun's trail and wheels perfectly still during the firing sequence. Since it did not need to be re-aimed after each shot, the crew could fire as soon as the barrel returned to its resting position. In typical use, the French 75 could deliver fifteen rounds per minute on its target, either
shrapnel or
melinite high-explosive, up to about 5 miles (8,500 m) away. Its firing rate could even reach close to 30 rounds per minute, albeit only for a very short time and with a highly experienced crew. These were rates that contemporary
bolt action rifles could not match.
Indirect fire Indirect fire, the firing of a projectile without relying on direct line of sight between the gun and the target, possibly dates back to the 16th century. Early battlefield use of indirect fire may have occurred at
Paltzig in July 1759, when the Russian artillery fired over the tops of trees, and at the
Battle of Waterloo, where a battery of the
Royal Horse Artillery fired shrapnel indirectly against advancing French troops. In 1882, Russian Lieutenant Colonel KG Guk published
Indirect Fire for Field Artillery, which provided a practical method of using
aiming points for indirect fire by describing, "all the essentials of aiming points, crest clearance, and corrections to fire by an observer". A few years later, the Richtfläche (lining-plane) sight was invented in Germany and provided a means of indirect laying in azimuth, complementing the clinometers for indirect laying in elevation which already existed. Despite conservative opposition within the
German army, indirect fire was adopted as doctrine by the 1890s. In the early 1900s, Goertz in Germany developed an optical sight for azimuth laying. It quickly replaced the lining-plane; in English, it became the 'Dial Sight' (UK) or 'Panoramic Telescope' (US). The British halfheartedly experimented with indirect fire techniques since the 1890s, but with the onset of the
Boer War, they were the first to apply the theory in practice in 1899, although they had to improvise without a lining-plane sight. In the next 15 years leading up to
World War I, the techniques of indirect fire became available for all types of artillery. Indirect fire was the defining characteristic of 20th-century artillery and led to undreamt of changes in the amount of artillery, its tactics, organisation, and techniques, most of which occurred during World War I. An implication of indirect fire and improving guns was increasing range between gun and target, this increased the time of flight and the vertex of the trajectory. The result was decreasing accuracy (the increasing distance between the target and the mean point of impact of the shells aimed at it) caused by the increasing effects of non-standard conditions. Indirect firing data was based on standard conditions including a specific muzzle velocity, zero wind, air temperature and density, and propellant temperature. In practice, this standard combination of conditions almost never existed, they varied throughout the day and day to day, and the greater the time of flight, the greater the inaccuracy. An added complication was the need for survey to accurately fix the coordinates of the gun position and provide accurate orientation for the guns. Of course, targets had to be accurately located, but by 1916, air photo interpretation techniques enabled this, and ground survey techniques could sometimes be used. during
World War I In 1914, the methods of correcting firing data for the actual conditions were often convoluted, and the availability of data about actual conditions was rudimentary or non-existent, the assumption was that fire would always be ranged (adjusted). British heavy artillery worked energetically to progressively solve all these problems from late 1914 onwards, and by early 1918, had effective processes in place for both field and heavy artillery. These processes enabled 'map-shooting', later called 'predicted fire'; it meant that effective fire could be delivered against an accurately located target without ranging. Nevertheless, the mean point of impact was still some tens of yards from the target-centre aiming point. It was not precision fire, but it was good enough for concentrations and barrages. These processes remain in use into the 21st century with refinements to calculations enabled by computers and improved data capture about non-standard conditions. The British
Major General Henry Hugh Tudor pioneered armour and artillery cooperation at the breakthrough
Battle of Cambrai. The improvements in providing and using data for non-standard conditions (propellant temperature, muzzle velocity, wind, air temperature, and barometric pressure) were developed by the major combatants throughout the war and enabled effective predicted fire. The effectiveness of this was demonstrated by the British in 1917 (at Cambrai) and by Germany the following year (
Operation Michael). Major General J.B.A. Bailey, British Army (retired) wrote: An estimated 75,000 French soldiers were casualties of friendly artillery fire in the four years of World War I.
Precision-guidance guided artillery shell
Modern artillery is most obviously distinguished by its long range, firing an
explosive shell or
rocket and a mobile carriage for firing and transport. However, its most important characteristic is the use of indirect fire, whereby the firing equipment is aimed without seeing the target through its sights. Indirect fire emerged at the beginning of the 20th century and was greatly enhanced by the development of
predicted fire methods in World War I. However, indirect fire was area fire; it was and is not suitable for destroying point targets; its primary purpose is area suppression. Nevertheless, by the late 1970s precision-guided munitions started to appear, notably the US 155 mm Copperhead and its Soviet 152 mm
Krasnopol equivalent that had success in Indian service. These relied on laser designation to 'illuminate' the target that the shell homed onto. However, in the early 21st century, the
Global Positioning System (GPS) enabled relatively cheap and accurate guidance for shells and missiles, notably the US 155 mm Excalibur and the 227 mm GMLRS rocket. The introduction of these led to a new issue, the need for very accurate three dimensional target coordinates—the mensuration process. can be added to unguided projectiles Weapons covered by the term 'modern artillery' include "
cannon" artillery (such as
howitzer,
mortar, and
field gun) and
rocket artillery. Certain smaller-caliber mortars are more properly designated small arms rather than artillery, albeit indirect-fire small arms. This term also came to include
coastal artillery which traditionally defended coastal areas against seaborne attack and controlled the passage of ships. With the advent of powered flight at the start of the 20th century, artillery also included ground-based
anti-aircraft batteries. The term "artillery" has traditionally not been used for projectiles with internal
guidance systems, preferring the term "missilery", though some modern artillery units employ surface-to-surface
missiles. Advances in terminal guidance systems for small munitions has allowed large-caliber guided projectiles to be developed, blurring this distinction.
See Long Range Precision Fires (LRPF), Joint terminal attack controller ==Ammunition==