The organ is one of the oldest instruments still used in European classical music. Its earliest predecessors were built in Ancient Greece in the 3rd century BCE. The word organ is derived from the Latin organum, an instrument similar to a portative organ used in ancient Roman circus games. Organum is derived in turn from the Greek (organon), a generic term for an instrument or a tool.
The Greek engineer Ctesibius of Alexandria is credited with inventing the organ in the 3rd century BC. He devised an instrument called the hydraulis, which delivered a wind supply maintained through water pressure to a set of pipes. The hydraulis was played in the arenas of the Roman Empire. The pumps and water regulators of the hydraulis were replaced by an inflated leather bag in the 2nd century AD, and true bellows began to appear in the 6th or 7th century AD.
Portable organs (the portative and the positive organ) were invented in the Middle Ages. Towards the middle of the 13th century, the portatives represented in the miniatures of illuminated manuscripts appear to have real keyboards with balanced keys, as in the Cantigas de Santa Maria. Its portability made the portative useful for the accompaniment of both sacred and secular music in a variety of settings.
Large organs such as the one installed in 1361 in Halberstadt, Germany, the first documented permanent organ installation, likely prompted Guillaume de Machaut to describe the organ as "the king of instruments", a characterization still frequently applied. The Halberstadt organ was the first instrument to use a chromatic key layout across its three manuals and pedalboard, although the keys were wider than on modern instruments. It had twenty bellows operated by ten men, and the wind pressure was so high that the player had to use the full power of his arm to hold down a key.
Until the mid-15th century, organs had no stop controls. Each manual controlled ranks at multiple pitches, known as the Blockwerk. Around 1450, controls were designed that allowed the ranks of the Blockwerk to be played individually. These devices were the forerunners of modern stop actions. The higher-pitched ranks of the Blockwerk remained grouped together under a single stop control; these stops developed into mixtures.
Renaissance and Baroque periods
During the Renaissance and Baroque periods, the organ's tonal colors became more varied. Organ builders fashioned stops that imitated various instruments, such as the krummhorn and the viola da gamba. The Baroque period is often thought of as organ building's "golden age," as virtually every important refinement was brought to a culminating art. Builders such as Arp Schnitger, Jasper Johannsen, Zacharias Hildebrandt and Gottfried Silbermann constructed instruments that were in themselves artistic masterpieces, displaying both exquisite craftsmanship and beautiful sound. These organs featured well-balanced mechanical key actions, giving the organist precise control over the pipe speech. Schnitger's organs featured particularly distinctive reed timbres and large Pedal and Ruckpositiv divisions.
Different national styles of organ building began to develop, often due to changing political climates. In the Netherlands, the organ became a large instrument with several divisions, doubled ranks, and mounted cornets. The organs of northern Germany also had more divisions, and independent pedal divisions became increasingly common. The divisions of the organ became visibly discernible from the case design. 20th-century musicologists labelled this the Werkprinzip.
In France, as in Italy, Spain and Portugal, organs were primarily designed to play alternatim verses rather than accompany congregational singing. The French Classical Organ, became remarkably consistent throughout France over the course of the Baroque era, more so than any other style of organ building in history, and standardized registrations developed. It was elaborately described by Dom Bedos de Celles in his treatise L'art du facteur d'orgues (The Art of Organ Building). For example, in France, the organ at Notre-Dame's (St. Etienne, Loire) was built by Joseph and Claude-Ignace Callinet in 1837, at a time when their career was at its apex.
In England, many pipe organs were taken out of churches during the English Reformation of the 16th century and the Commonwealth period. Often these were relocated to private homes. At the Restoration, organ builders such as Renatus Harris and "Father" Bernard Smith brought new organ-building ideas from continental Europe. English organs evolved from small one- or two-manual instruments into three or more divisions disposed in the French manner with grander reeds and mixtures. The Echo division began to be enclosed in the early 18th century, and in 1712 Abraham Jordan claimed his "swelling organ" at St Magnus-the-Martyr to be a new invention. The swell box and the independent pedal division appeared in English organs beginning in the 18th century.
During the Romantic period, the organ became more symphonic, capable of creating a gradual crescendo. New technologies and the work of organ builders such as Eberhard Friedrich Walcker, Aristide Cavaille-Coll, and Henry Willis made it possible to build larger organs with more stops, more variation in sound and timbre, and more divisions. Enclosed divisions became common, and registration aids were developed to make it easier for the organist to manage the great number of stops. The desire for louder, grander organs required that the stops be voiced on a higher wind pressure than before. As a result, a greater force was required to overcome the wind pressure and depress the keys. To solve this problem, Cavaille-Coll configured the English "Barker lever" to assist in operating the key action.
Organ builders began to lean towards specifications with fewer mixtures and high-pitched stops. They preferred to use more 8' and 16' stops in their specifications and wider pipe scales. These practices created a warmer, richer sound than was common in the 18th century. Organs began to be built in concert halls (such as the organ at the Palais du Trocadero in Paris), and composers such as Camille Saint-Saens and Gustav Mahler used the organ in their orchestral works.
The development of pneumatic and electro-pneumatic key actions in the late 19th century made it possible to locate the console independently of the pipes, greatly expanding the possibilities in organ design. Electric stop actions were also developed, which allowed sophisticated combination actions to be created.
In the mid-20th century, organ builders began to build historically inspired instruments modelled on Baroque organs. They returned to building mechanical key actions, voicing with lower wind pressures and thinner pipe scales, and designing specifications with more mixture stops. This became known as the Organ reform movement.
In the late 20th century, organ builders began to incorporate digital components into their key, stop, and combination actions. Besides making these mechanisms simpler and more reliable, this also makes it possible to record and play back an organist's performance via the MIDI protocol. In addition, some organ builders have incorporated digital stops into their pipe organs.
The electronic organ developed throughout the 20th century. Some pipe organs were replaced by digital organs because of their lower purchase price, smaller physical size, and minimal maintenance requirements. In the early 1970s, Rodgers Instruments pioneered the hybrid organ, an electronic instrument that incorporates real pipes; other builders such as Allen Organs and Johannus Orgelbouw have since built hybrid organs.
One US firm Estey Organ Co. of Brattleboro, VT developed a small pipe organ for homes that used the traditional way of producing music. The entire organ, pipes, bellows, keyboard and foot pedals was enclosed in what appeared to be a baby grand piano. This came in both a standard grand piano shape as well as an upright grand piano case. It was called the Estey "Grand Minuette."
The main development of organ repertoire has progressed along with that of the organ itself, leading to distinctive national styles of composition. Because organs are commonly found in churches and synagogues, the organ repertoire includes a large amount of sacred music, which is accompanimental (choral anthems, congregational hymns, liturgical elements, etc.) as well as solo in nature (chorale preludes, hymn versets designed for alternatim use, etc.). The organ's secular repertoire includes preludes, fugues, sonatas, organ symphonies, suites, and transcriptions of orchestral works.Although most countries whose music falls into the Western tradition have contributed to the organ repertoire, France and Germany in particular have produced exceptionally large amounts of organ music. There is also an extensive repertoire from the Netherlands, England, and the United States.
Before the Baroque era, keyboard music generally was not written for one instrument or another, but rather was written to be played on any keyboard instrument. For this reason, much of the organ's repertoire through the Renaissance period is the same as that of the harpsichord. Pre-Renaissance keyboard music is found in compiled manuscripts that may include compositions from a variety of regions. The oldest of these sources is the Robertsbridge Codex, dating from about 1360. The Buxheimer Orgelbuch, which dates from about 1470 and was compiled in Germany, includes intabulations of vocal music by the English composer John Dunstaple. The earliest Italian organ music is found in the Faenza Codex, dating from 1420.
In the Renaissance period, Netherlandish composers such as Jan Pieterszoon Sweelinck composed both fantasias and psalm settings. Sweelinck in particular developed a rich collection of keyboard figuration that influenced subsequent composers. The Italian composer Claudio Merulo wrote in the typical Italian genres of the toccata, the canzona, and the ricercar. In Spain, the works of Antonio de Cabezon began the most prolific period of Spanish organ composition, which culminated with Juan Cabanilles.
Early Baroque organ music in Germany was highly contrapuntal. Sacred organ music was based on chorales: composers such as Samuel Scheidt and Heinrich Scheidemann wrote chorale preludes, chorale fantasias, and chorale motets. Towards the end of the Baroque era, the chorale prelude and the partita became mixed, forming the chorale partita. This genre was developed by Georg Bohm, Johann Pachelbel, and Dieterich Buxtehude. The primary type of free-form piece in this period was the praeludium, as exemplified in the works of Matthias Weckmann, Nicolaus Bruhns, Bohm, and Buxtehude. The organ music of Johann Sebastian Bach fused characteristics of every national tradition and historical style in his large-scale preludes and fugues and chorale-based works. Towards the end of the Baroque era, George Frideric Handel composed the first organ concertos.
In France, organ music developed during the Baroque era through the music of Jean Titelouze, Francois Couperin, and Nicolas de Grigny. Because the French organ of the 17th and early 18th centuries was very standardized, a conventional set of registrations developed for its repertoire. The music of French composers (and Italian composers such as Girolamo Frescobaldi) was written for use during the Mass. Very little secular organ music was composed in France and Italy during the Baroque period; the written repertoire is almost exclusively intended for liturgical use. In England, composers such as John Blow and John Stanley wrote multi-sectional free works for liturgical use called voluntaries through the 19th century.
Organ music was seldom written in the Classical era, as composers preferred the piano with its ability to create dynamics. In Germany, the six sonatas op. 65 of Felix Mendelssohn (published 1845) marked the beginning of a renewed interest in composing for the organ. Inspired by the newly built Cavaille-Coll organs, the French organist-composers Cesar Franck, Alexandre Guilmant and Charles-Marie Widor led organ music into the symphonic realm. The development of symphonic organ music continued with Louis Vierne and Charles Tournemire. Widor and Vierne wrote large-scale, multi-movement works called organ symphonies that exploited the full possibilities of the symphonic organ. Max Reger and Sigfrid Karg-Elert's symphonic works made use of the abilities of the large Romantic organs being built in Germany at the time.
In the 19th and 20th centuries, organ builders began to build instruments in concert halls and other large secular venues, allowing the organ to be used as part of an orchestra, as in Saint-Saens' Symphony No. 3. Frequently the organ is given a soloistic part, such as in Joseph Jongen's Symphonie Concertante for Organ & Orchestra, Francis Poulenc's Concerto for Organ, Strings and Tympani, and Frigyes Hidas' Organ Concerto.
Other composers who have used the organ prominently in orchestral music include Gustav Holst, Richard Strauss, Ottorino Respighi, Gustav Mahler, Anton Bruckner, and Ralph Vaughan Williams. Because these concert hall instruments could approximate the sounds of symphony orchestras, transcriptions of orchestral works found a place in the organ repertoire. As silent films became popular, theatre organs were installed in theatres to provide accompaniment for the films.
In the 20th-century symphonic repertoire, both sacred and secular, continued to progress through the music of Marcel Dupre, Maurice Durufle, and Herbert Howells. Other composers, such as Olivier Messiaen, Gyorgy Ligeti, Jehan Alain, Jean Langlais, and Petr Eben, wrote post-tonal organ music. Messiaen's music in particular redefined many of the traditional notions of organ registration and technique.
The pipe organ is a musical instrument commonly used in churches or cathedrals that produces sound by driving pressurized air (called wind) through pipes selected via a keyboard. Because each organ pipe produces a single pitch, the pipes are provided in sets called ranks, each of which has a common timbre and volume throughout the keyboard compass. Most organs have multiple ranks of pipes of differing timbre, pitch and loudness that the player can employ singly or in combination through the use of controls called stops.
A pipe organ has one or more keyboards (called manuals) played by the hands, and a pedalboard played by the feet, each of which has its own group of stops. The organ's continuous supply of wind allows it to sustain notes for as long as the corresponding keys are depressed, unlike the piano and harpsichord whose sound begins to decay immediately after attack. The smallest portable pipe organs may have only one or two dozen pipes and one manual; the largest may have over 20,000 pipes and seven manuals. A list of the some of the most notable and largest pipe organs in the world can be viewed at List of pipe organs.
The origins of the pipe organ can be traced back to the hydraulis in Ancient Greece in the 3rd century BC, in which the wind supply was created with water pressure. By the 6th or 7th century AD, bellows were used to supply organs with wind. Beginning in the 12th century, the organ began to evolve into a complex instrument capable of producing different timbres. By the 17th century, most of the sounds available on the modern classical organ had been developed. From that time, the pipe organ was the most complex man-made device, a distinction it retained until it was displaced by the telephone exchange in the late 19th century.
Pipe organs are installed in churches, synagogues, concert halls, and other public buildings and are used for the performance of classical music, sacred music, and secular music. In the early 20th century, pipe organs were installed in theaters to accompany films during the silent movie era, in municipal auditoria, where orchestral transcriptions were popular, and in the homes of the wealthy, equipped with player mechanisms. The beginning of the 21st century has seen a resurgence in installations in concert halls. The organ boasts a substantial repertoire, which spans over 500 years.
A pipe organ contains one or more sets of pipes, a wind system, and one or more keyboards. The pipes produce sound when pressurized air produced by the wind system is driven through them. An action connects the keyboards to the pipes. Stops allow the organist to control which ranks of pipes sound at a given time. The organist operates the stops and the keyboards from the console.
Organ pipes are made from either wood, metal, or glass and produce sound ("speak") when air under pressure ("wind") is directed through them. As one pipe produces a single pitch, multiple pipes are necessary to accommodate the musical scale. The greater the length of the pipe, the lower its resulting pitch will be. The timbre and volume of the sound produced by a pipe depends on the volume of air delivered to the pipe and the manner in which it is constructed and voiced, the latter adjusted by the builder to produce the desired tone and volume. Hence a pipe's volume cannot be readily changed while playing.
Organ pipes are divided into flue pipes and reed pipes according to their design and timbre. Flue pipes produce sound by forcing air through a fipple, like that of a recorder, whereas reed pipes produce sound via a beating reed, like that of a clarinet or saxophone.
Pipes are arranged by timbre and pitch into ranks. A rank is a row of pipes mounted vertically onto a windchest. The stop mechanism admits air to each rank. For a given pipe to sound, the stop governing the pipe's rank must be engaged, and the key corresponding to its pitch must be depressed. Ranks of pipes are organized into groups called divisions. Each division generally is played from its own keyboard and conceptually comprises an individual instrument within the organ.
An organ contains two actions, or systems of moving parts. When a key is depressed, the key action admits wind into a pipe. The stop action allows the organist to control which ranks are engaged. An action may be mechanical, pneumatic, or electrical (or some combination of these, such as electro-pneumatic action). The key action is independent of the stop action, allowing an organ to feature a mechanical key action along with an electric stop action.
A key action which physically connects the keys and the windchests is a mechanical or tracker action. Connection is achieved through a series of rods called trackers. When the organist depresses a key, the corresponding tracker moves, allowing wind to enter the pipe. In a mechanical stop action, each stop control is physically connected to a rank of pipes. When the organist activates the stop control, the action allows wind to flow into the selected rank. This control is usually a stop knob, which the organist activates by pulling (or drawing) towards himself. This is the origin of the idiom "to pull out all the stops". Tracker action has been used from antiquity to modern times. Despite the extra effort needed in playing, many organists prefer tracker action because of a feel and a control of the pipe valve operation.
A later development was the tubular-pneumatic action, which uses changes of pressure within lead tubing to affect pneumatics to produce valve action throughout the instrument. This allowed a lighter touch, and more flexibility in the location of the console, within a 50-foot (15-m) limit. This type of construction was used in the late 19th century to early 20th century, and has had only rare application since the 1920s.
The most recent development is the electric action which uses electrical current to control the key and/or stop mechanisms. Electricity may control the action indirectly through air pressure valves (pneumatics), in which case the action is electro-pneumatic. When electricity operates the action directly without the assistance of pneumatics, it is commonly referred to as direct electric action.
When electrical wiring alone is used to connect the console to the windchest, electric actions allow the console to be separated at any distance from the rest of the organ, and to be movable. Electric stop actions can be controlled at the console by stop knobs, or by tilting tablets or rocker tabs which sit on a hinge, and activate or deactivate an electrical circuit, depending on the direction in which they are pressed.
The wind system consists of the parts that produce, store, and deliver wind to the pipes. Pipe organ wind pressures are on the order of 0.1 psi (0.69 kPa). Organ builders often measure organ wind using a U-tube manometer containing water, so commonly give its magnitude as the difference in water levels in the two legs of the manometer, rather than in units of pressure. The difference in water level is proportional to the difference in pressure between the wind being measured and the atmosphere. The 0.10 psi above would register as 2-3/4 inches of water (70 mmAq). An Italian organ from the Renaissance period may be on only 2.2 inches (56 mm), while (in the extreme) solo stops in some large 20th-century organs require 100 inches (2,500 mm).
Playing the organ before electricity required at least one person to operate the bellows. When signaled by the organist, a calcant would operate a set of bellows, supplying the organ with air. Because calcants were expensive, organists would usually practice on other instruments such as the clavichord or harpsichord. By the mid-19th-century bellows were also being operated by water engines, steam engines or gasoline engines. Starting in the 1860s bellows were gradually replaced by wind turbines which were later directly connected to electrical motors. This made it possible for organists to practice regularly on the organ. Most organs, both new and historic, have electric blowers, although others can still be operated manually. The wind supplied is stored in one or more regulators to maintain a constant pressure in the windchests until the action allows it to flow into the pipes.
Each stop usually controls one rank of pipes, although mixtures and undulating stops (such as the Voix celeste) control multiple ranks. The name of the stop reflects not only the stop's timbre and construction, but also the style of the organ in which it resides. For example, the names on an organ built in the north German Baroque style generally will be derived from the German language, while the names of similar stops on an organ in the French Romantic style will usually be French. Most countries tend to use only their own languages for stop nomenclature. English-speaking nations as well as Japan are more receptive to foreign nomenclature. Stop names are not standardized: two otherwise identical stops from different organs may have different names.
To facilitate a large range of timbres, organ stops exist at different pitch levels. A stop that sounds at unison pitch when a key is depressed is referred to as being at 8' (pronounced "eight-foot") pitch. This refers to the length of the lowest-sounding pipe in that rank, which is approximately eight feet. For the same reason, a stop that sounds an octave higher is at 4' pitch, and one that sounds two octaves higher is at 2' pitch. Likewise, a stop that sounds an octave lower than unison pitch is at 16' pitch, and one that sounds two octaves lower is at 32' pitch. Stops of different pitch levels are designed to be played simultaneously.
The label on a stop knob or rocker tab indicates the stop's name and its pitch in feet. Stops that control multiple ranks display a Roman numeral indicating the number of ranks present, instead of its pitch. Thus, a stop labelled "Open Diapason 8' " is a single-rank diapason stop sounding at 8' pitch. A stop labelled "Mixture V" is a five-rank mixture.
Sometimes, a single rank of pipes may be able to be controlled by several stops, allowing the rank to be played at multiple pitches or on multiple manuals. Such a rank is said to be unified or borrowed. For example, an 8' Diapason rank may also be made available as a 4' Octave. When both of these stops are selected and a key (for example, c') is pressed, two pipes of the same rank will sound: the pipe normally corresponding to the key played (c'), and the pipe one octave above that (c''). Because the 8' rank does not have enough pipes to sound the top octave of the keyboard at 4' pitch, it is common for an extra octave of pipes used only for the borrowed 4' stop to be added. In this case, the full rank of pipes (now an extended rank) is one octave longer than the keyboard.
Special unpitched stops also appear in some organs. Among these are the Zimbelstern (a wheel of rotating bells), the nightingale (a pipe submerged in a small pool of water, creating the sound of a bird warbling when wind is admitted), and the effet d'orage ("thunder effect", a device that sounds the lowest bass pipes simultaneously). Standard orchestral percussion instruments such as the drum, chimes, celesta, and harp have also been imitated in organ building.
The controls available to the organist, including the keyboards, couplers, expression pedals, stops, and registration aids are accessed from the console. The console is either built into the organ case or detached from it.
Keyboards played by the hands are known as manuals (from the Latin manus, meaning "hand"). The keyboard played by the feet is a pedalboard. Every organ has at least one manual (most have two or more), and most have a pedalboard. Each keyboard is named for a particular division of the organ (a group of ranks) and generally controls only the stops from that division. The range of the keyboards has varied widely across time and between countries. Most current specifications call for two or more manuals with sixty-one notes (five octaves, from C to c"") and a pedalboard with thirty or thirty-two notes (two and a half octaves, from C to f' or g').
A coupler allows the stops of one division to be played from the keyboard of another division. For example, a coupler labelled "Swell to Great" allows the stops drawn in the Swell division to be played on the Great manual. This coupler is a unison coupler, because it causes the pipes of the Swell division to sound at the same pitch as the keys played on the Great manual. Coupling allows stops from different divisions to be combined to create various tonal effects. It also allows every stop of the organ to be played simultaneously from one manual.
Octave couplers, which add the pipes an octave above (super-octave) or below (sub-octave) each note that is played, may operate on one division only (for example, the Swell super octave, which adds the octave above what is being played on the Swell to itself), or act as a coupler to another keyboard (for example, the Swell super-octave to Great, which adds to the Great manual the ranks of the Swell division an octave above what is being played).
In addition, larger organs may use unison off couplers, which prevent the stops pulled in a particular division from sounding at their normal pitch. These can be used in combination with octave couplers to create innovative aural effects, and can also be used to rearrange the order of the manuals to make specific pieces easier to play.
Enclosure and expression pedals
Enclosure refers to a system that allows for the control of volume without requiring the addition or subtraction of stops. In a two-manual organ with Great and Swell divisions, the Swell will be enclosed. In larger organs, parts or all of the Choir and Solo divisions may also be enclosed. The pipes of an enclosed division are placed in a chamber generally called the swell box. At least one side of the box is constructed from horizontal or vertical palettes known as swell shades, which operate in a similar way to Venetian blinds; their position can be adjusted from the console. When the swell shades are open, more sound is heard than when they are closed. Sometimes the shades are exposed, but they are often concealed behind a row of facade-pipes or a grill.
The most common method of controlling the louvers is the balanced swell pedal. This device is usually placed above the centre of the pedalboard and is configured to rotate away from the organist from a near-vertical position (in which the shades are closed) to a near-horizontal position (in which the shades are open). An organ may also have a similar-looking crescendo pedal, found alongside any expression pedals. Pressing the crescendo pedal forward cumulatively activates the stops of the organ, starting with the softest and ending with the loudest; pressing it backwards reverses this process.
Organ stops can be combined in countless permutations, resulting in a great variety of sounds. A combination action can be used to switch instantly from one combination of stops (called a registration) to another. Combination actions feature small buttons called pistons that can be pressed by the organist, generally located beneath the keys of each manual (thumb pistons) or above the pedalboard (toe pistons). The pistons may be divisional (affecting only a single division) or general (affecting all the divisions), and are either preset by the organ builder or can be altered by the organist. Modern combination actions operate via computer memory, and can store several channels of registrations.
The pipes, action, and wind system are almost always contained in a case, the design of which also may incorporate the console. The case blends the organ's sound and aids in projecting it into the room. The case often is designed to complement the building's architectural style and it may contain ornamental carvings and other decorations. The visible portion of the case, called the facade, will most often contain pipes, which may be either sounding pipes or dummy pipes solely for decoration. The facade pipes may be plain, burnished, gilded, or painted and are usually referred to as (en) montre within the context of the French organ school.
Organ cases occasionally feature a few ranks of pipes protruding horizontally from the case in the manner of a row of trumpets. These are referred to as pipes en chamade and are particularly common in organs of the Iberian peninsula and large 20th-century instruments.
Many organs, particularly those built in the early 20th century, are contained in one or more rooms called organ chambers. Because sound does not project from a chamber into the room as clearly as from a freestanding organ case, enchambered organs may sound muffled and distant. For this reason, some modern builders, particularly those building instruments specializing in polyphony rather than Romantic compositions, avoid this unless the architecture of the room makes it necessary.
Tuning and regulation
The goal of tuning a pipe organ is to adjust the pitch of each pipe so that they all sound in tune with each other. How the pitch of each pipe is adjusted depends on the type and construction of that pipe.
Regulation adjusts the action so that all pipes sound correctly. If the regulation is wrongly set, the keys may be at different heights, some pipes may sound when the keys are not pressed, or pipes may not sound when a key is pressed. Tracker action, for example in the organ of Cradley Heath Baptist Church, includes adjustment nuts on the wire ends of the wooden trackers, which have the effect of changing the effective length of each tracker.
There is no agent so powerful in giving us real rest as true music… It does for heart and mind, and also for the body, what sleep does for the body alone.