Robert Willis (engineer)


The Reverend Robert Willis was an English academic. He was the first Cambridge professor to win widespread recognition as a mechanical engineer, and first to set the scientific study of vowels on a respectable foundation. He is now best remembered for his extensive writings on architectural history, including many studies of mediaeval cathedrals and a four-volume treatise on the architecture of the University of Cambridge. He was described by Pevsner as "the greatest English architectural historian of the 19th century".

Biography

Early life and first years in Cambridge

Willis was born in London on 27 February 1800. His father was Dr Robert Darling Willis, physician to King George III. He was a grandson of Francis Willis. His paternal uncle was Rear Admiral Richard Willis.
His health was delicate, which prevented him from going to school, and he was privately tutored. He showed talent in music, and as a draughtsman, and when he was 19 took out a patent on an improved pedal harp. In 1820 he went to a demonstration of Wolfgang von Kempelen's "Turk", a supposed automaton chess player, and the following year published An attempt to Analyze the Automaton Chess Player, in which he showed how a human player could be concealed within the chest housing the supposed machinery.
In 1821 he studied with the Rev. Thomas Kidd, a noted classical scholar, at King's Lynn. In this town, with its mediaeval churches and guildhalls, Willis's interest in architecture developed, and he made his first known architectural drawings. Buchanan reproduces some of these drawings, and comments on his ability not just to draw, but to show the underlying structural relationships of a building, especially remarkable as he had no known training in the craft. In 1822 he entered Gonville and Caius College, Cambridge, from which he received his B.A. in 1826. He was elected a Frankland Fellow of the College the same year and in 1827 he was ordained deacon and priest. He was promoted to a Foundation Fellow in 1829, and became Steward of the College, positions he held until his marriage, in 1832, to Mary Anne, daughter of Charles Humfrey of Cambridge. They were resident in Cambridge for the remainder of their lives, but also later had a London house.
Cambridge in the 1830s was a time in which science was becoming increasingly important, and was home to a group of scholars known as the "Cambridge Network". Two of these men were of particular importance, Charles Babbage and William Whewell. Babbage was building his difference engine at this time, a mechanical precursor of the digital computer. Willis drew detailed sketches of parts of the machinery. Whewell shared interests with Willis in science, history of architecture and mathematics, and was a lifelong colleague.

Phonetics

In 1828 and 1829, Willis presented two papers on the production of vowel sounds to the Cambridge Philosophical Society, which were published in 1830 as On vowel sounds, and on reed-organ pipes. In 1830 he was made a Fellow of the Royal Society, partly on the basis of that work. In his work on vowel sounds, following on from that of von Kempelen and Kratzenstein, he rejected too close an imitation of the human vocal apparatus, noting that the mouth has important functions other than speech, and that parrots, with very different mouth parts, can produce recognisable speech. His apparatus typically used a reed, driven by a flow of air to produce a note, and a tube whose length could be varied. At different lengths, different vowel sounds were produced. His theory that the vowel sound depended on a single harmonic frequency in addition to the principal pitch is today regarded as too simple, but his work was the first systematic investigation in the field, and provided a valuable basis for later studies. In 1833 he published a paper On the Mechanism of the Larynx. This work used both mechanical analogues and anatomical analysis of the larynx to provide a mechanical model of its operation. Willis noted that a leather or india-rubber band laid along a wooden surface could act as a reed, and that the pitch would change as the band was stretched. He argued that the vocal ligaments operated in this way. He correctly identified the muscles that acted to stretch and relax the vocal chords in sound production, and equally importantly those that opened and closed the airways, allowing either sound production or normal breathing, when air passes the vocal chords without producing a sound. A quarter of a century later, Gray used Willis's diagram of the Larynx in his Anatomy. Hart states that these observations are "basic to the laws of laryngeal physiology today".

Engineering

From 1837 to 1875 Willis served as Jacksonian Professor of Natural Philosophy at Cambridge, and from 1853 onward he was a lecturer in applied mechanics at the government school of mines. In 1837 he read a paper On the teeth of wheels, and in the following year published this in more detail, proposing the Odontagraph, a device to allow a craftsman to determine the proper shape of teeth on wheels of different diameters. This was widely used for many years. In 1841 he published his Principles of Mechanism, and in 1851 A System of Apparatus for the Use of Lecturers and Experimenters in Mechanical Philosophy.
Principles of Mechanism, Willis's major engineering work, provided a mathematical analysis of the "relations of motions". It contrasted with earlier approaches in that it was not concerned with utility – a crank is defined as a machine for converting reciprocating to circular motion, or vice versa, whether it is used for raising water, grinding flour or sawing timber. He classified machines in two ways, firstly in terms of the type of contact: rolling, sliding, wrapping, linking and reduplicating; and second on whether the relationship between the connected motions was fixed or variable. His examples were not confined to man-made machines. He showed that the joints of a crab's claw worked in the same way as Hooke's universal joint. Willis's classification was influential, being adopted by other writers, including William Whewell By 1870, thirteen works on mechanism had used Willis's scheme of classification.

Architecture and the Cathedral Histories

Willis's earliest published work on architecture was the Remarks on the architecture of the middle ages, especially of Italy based on material collected during the 1832-3 honeymoon trip, and published in 1835. The book was as much an analysis of the gothic style in general as a work on Italian buildings in particular. His approach to architectural style recognised a difference between the real and the apparent structure of a building, which he referred to as the mechanical and the decorative aspects, respectively. In a Greek temple, the weight of the entablature is borne by the columns – both force and column are vertical and there is no difference between the real and apparent structure. With arched structures such as vaults and arcades, this no longer the case. An arch appears to be supported by the capital from which is springs, but the actual forces may be exerted at a different point, as illustrated in the figure to the right. The ribs of a vault are often continued down on separate shafts of a clustered column, which appear to bear the individual loads of the ribs. In reality the structure is the entire column, supplemented by the lateral buttressing that is needed to take the transverse thrust of the vault. For the result to be aesthetically pleasing, it is the apparent structure that must satisfy the eye as to the stability and harmony of the building Willis also considered the origin of the pointed arch. Whewell had supported the idea that pointed forms derived from techniques for cross-vaulting rectangular spaces. Willis disagreed, arguing that the arch itself was a key stylistic feature, and that gothic introduced several related innovations, including the pointed arch, foliation, and tracery.
Willis's historical and descriptive work on architecture included works on individual buildings, including as well as analyses of vaulting and the Flamboyant style. Most of his cathedral studies were initially presented as lectures, often accompanied by guided tours of the buildings. Many, but not all, were subsequently written up for publication.
Willis's analyses used both documentary evidence and a detailed examination of the building. As he put it in his Architectural history of Canterbury Cathedral: "My plan therefore has been, first to collect all the written evidence, and then by a close comparison of it with the building itself, to make the best identification of one with the other that I have been able." He was noted for his ability to discriminate different periods of building both on stylistic grounds, and using discontinuities in the structure. His 1845 publication on Canterbury was, as noted by Buchanan, the first work in the English language to be entitled an "architectural history"". Canterbury is the best documented of all the mediaeval Cathedrals in England, with two detailed contemporary accounts by Edmer and Gervase, both monks of Canterbury. Willis quotes extensively from the sources, including his own complete translation of Gervase's account, which covers the fire of 1174 and the subsequent rebuilding. The fire destroyed the norman choir, but not the crypt, which remains to the present day. So differences in the layout of the new work of the late 12th-Century could be traced. Willis pointed out visible consequences, in particular columns that had been inserted into the crypt to provide support for those in the upper structure, that no longer corresponded to the old layout.
Willis's 1860 and 1861 lectures to the Archaeological Institute on Gloucester and Peterborough Cathedrals were not published. For Gloucester, Freeman gives a historical description of the cathedral based on Willis's lecture, and Buchanan has summarised Willis's manuscript notes on the topic. In the work on Gloucester, Willis for the first time initiated excavation, investigating possible Saxon work in the crypt. His examination of the later 14th-Century work, particularly of the south transept, showed that Gloucester represented the earliest use of the perpendicular style. Willis had earlier identified the vaults of the Gloucester cloister as the earliest example of fan vaulting in England. In the case of Peterborough, Willis gives descriptions of several of the vaults, and illustrations of the fan vaulting, in On the Construction of the Vaults of the Middle Ages. Buchanan gives an account of the 1861 Peterborough meeting, contrasting the roles of local antiquarians and national experts such as Willis.
The last of the historical studies to appear in Willis's lifetime was the work on the monastic buildings at Canterbury. It was published in 1868, although based on examination of the buildings 20 years earlier. Christ Church Canterbury was the largest monastery in England, with around 150 monks. Monastic buildings raised a rather different set of problems from churches. While there have been changes in the way churches have been used over the centuries, the main functions continued, and the various parts of a church are easily identified. The monasteries were suppressed in the 16th century, which involved considerable destruction. What remained was adapted to new functions often with much structural change. Thus identifying the various parts of the monastic complex was an important task. For Canterbury, again, the documentation was unusually full. In particular the famous "waterworks plan" shows the system of pipes and cisterns installed in the 12th century. But equally important for the historian, it also shows the buildings that existed at the time. Willis reproduces a 17th-Century engraving of the plan, and also his own version which aligns the plan to the positions of known existing structures. He shows his usual skill in explicating the various stages of the buildings he examines, but also pays more attention to aspects of everyday life. For example in discussing the building known as the necessarium, i.e. latrine, he cites the instructions give by Archbishop Lanfrance to the watchman to examine all the sedilia at night in case any of the monks have fallen asleep. Willis suggests that this might have been the origin of the other name for this facility, the "Third Dormitory".
As an aid to his descriptive work he invented the Cymagraph to copy the shapes of architectural mouldings.