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As Charles Garnier prepared the design for the Paris Opera House in 1861, the lack of acoustical design information and the contradictory nature of the information that he found forced him to leave the acoustic quality to chance and hope for the best. With few exceptions, this was the condition of architectural acoustics at the beginning of the 20th century. In 1900, with the pioneering work of Wallace Clement Sabine, the dark mysteries of “good acoustics” began to be illuminated. In his efforts to remedy the poor acoustics in the Fogg Art Museum Lecture Hall (1895–1973) at Harvard University, Sabine began experiments that revealed the relationship among the architectural materials of a space, the physical volume of the space, and the time that sound would persist in the space after a source was stopped (the reverberation time). Predicting the reverberation time of a room provided the first scientific foundation for reliable acoustic design in architecture. This method is still regularly used as a benchmark to design a range of listening environments, from concert halls to school classrooms.

The first application of this new acoustical knowledge occurred during the design of the Boston Symphony Hall (1906) by McKim, Mead and White. Original plans for the hall called for an enlarged version of the Leipzig Neues Gewandhaus (1884), a classical Greek Revival theater. The increased size would have been acoustically inappropriate, as it doubled the room volume, leading to excessive reverberation. Sabine worked with the architects to develop a scheme with a smaller room volume in the traditional “shoe box” concert hall shape. The Boston Symphony Hall remains one of the best in the world. Adler and Sullivan’s Auditorium Building (1889) in Chicago was praised for its architectural and engineering achievements as well as for the theater’s superb acoustics. As the profession of acoustical consulting emerged in the design of listening spaces, the firm of Bolt, Beranek and Newman made a significant impact on the development of architectural acoustics in the 20th century. Their work with architects Harrison and Abramovitz on Avery Fisher Hall (1962) in New York City represented a legitimate attempt to incorporate new scientific principles of acoustical design rather than merely copying previous halls that were known to be good. Although it presented several failures, one key acoustic point gleaned from a study of European halls for Avery Fisher Hall was that the room should hold 1,400 to 1,800 seats. Yielding to economic pressures, the architect increased seating to almost 3,000.

A more successful implementation of modern acoustical theories is the Berlin Philharmonic (1963). Architect Hans Scharoun’s vision of a hall in the round blurs the traditional distinction between performer and audience. The approach posed quite an acoustical challenge, given the directionality of many orchestral instruments; it required an extremely unconventional acoustical design. The resulting “vineyard terrace” seating arrangement resolved many potential acoustical difficulties while creating a spatial vitality that resonates outward to form the profile of the building. This collaboration between Scharoun and the acoustic consultant Lothar Cremer engendered a truly inspired architectural design.

A more successful implementation of modern acoustical theories is the Berlin Philharmonic (1963). Architect Hans Scharoun’s vision of a hall in the round blurs the traditional distinction between performer and audience. The approach posed quite an acoustical challenge, given the directionality of many orchestral instruments; it required an extremely unconventional acoustical design. The resulting “vineyard terrace” seating arrangement resolved many potential acoustical difficulties while creating a spatial vitality that resonates outward to form the profile of the building. This collaboration between Scharoun and the acoustic consultant Lothar Cremer engendered a truly inspired architectural design.

New techniques for improved acoustic environments are applied in many building types, including school classrooms, music practice rooms, church sanctuaries, movie heaters, transportation hubs, and industrial facilities. Simultaneously, with more and more exposure to digital-quality sound, clients have become keenly aware of their sonic environment and expect high levels of performance. Speech intelligibility in classrooms has been related to learning, with efforts to reduce excessive background noise from mechanical equipment. The issue has become the focus of a U.S. federal government assessment and proposal for a nationwide acoustical standard for schools. Additionally, careful selection of materials, their quantities, and their locations in classrooms are important to enhance speech intelligibility. Music practice spaces require adequate room volume with both soundabsorbent and sound-diffusing materials to control loudness and reduce the risk of noise-induced hearing loss to musicians and teachers. Religious liturgy relies more heavily on intimate spoken sermons, cathedral-like choir singing, and high-powered amplified music in many denominations. These trends, coupled with a prevailing increase in sanctuary size and the desire for more congregational interaction, have demanded sophisticated sound reinforcement systems and carefully configured room acoustic design strategies to strike a balance among divergent sonic criteria. Digital surround sound, the new standard in movie theater entertainment, incorporates the environmental acoustic character as part of the movie sound track, which should not be colored by the theater space. This requires very low reverberance, low background noise levels from mechanical equipment, and exceptional sound isolation from adjacent theaters. Unintelligible announcements, the bane of transportation hubs, have been the focus of many recent acoustical studies, affirming the need to consider room geometry, size, and material selection as they play as great a role as the actual announcement system itself in the success of these spaces.

Many meaningful advances in acoustic knowledge were made in the 20th century. The application and integration of this information within architectural design leaves much room for advancement. Alvar Aalto’s famous acoustical ray tracing diagrams for the lecture room of the Viipuri Public Library (1933–35) in Viipuri, Finland, represent acoustical thinking in the earliest phases of design. Developing sophisticated methods to assimilate newer acoustical knowledge as part of the architectural design process is the work at hand in the 21st century.

The American Richard Buckminster Fuller has been variously labeled architect, engineer, author, designer-inventor, educator, poet, cartographer, ecologist, philosopher, teacher, and mathematician throughout his career. Although not trained professionally as an architect, Fuller has been accepted within the architectural profession, receiving numerous awards and honorary degrees. He thought of himself as a comprehensive human in the universe, implementing research for the good of humanity. Born in Milton, Massachusetts, on 12 July 1895, he was the son of Richard Buckminster Fuller, Sr., and Caroline Wolcott (Andrews) Fuller. His father, who worked as a leather and tea merchant with offices in Boston, died when Fuller was 15 years of age. Fuller’s first design revelation came to him when, in kindergarten in 1899, he built his first flat-space frame, an octet truss constructed of dried peas and toothpicks. As a boy, vacationing at his family’s summerhouse on Bear Island, Maine, he became an adequate seaman and developed an appreciation of nature’s provision of principles of efficient design. He followed the philosophy of Pythagoras and Newton, that the universe comprises signs, or patterns of energy relationships, that have an order to them. Fuller used the term “valving” for the transformation of these patterns into usable forms. According to Fuller, these patterns in nature were comprehensive and universal. “Synergy” was the name that Fuller gave to the integrated behavior patterns discovered in nature.

Fuller attended the Milton Academy (1904–06) and Harvard University (1913–15) and was expelled twice while at Harvard. He worked in a few industries and then enlisted for two years of service in the U.S. Navy (1917–19). This experience in industry and with the Navy helped him gain knowledge of technical engineering processes, materials, and methods of manufacturing, which he would apply this knowledge to future inventions. When one of his two daughters, Alexandra, died of influenza at age four (1922), Fuller became obsessed with her death. Five years later, on the brink of suicide, he decided instead to devote the rest of his life to helping humanity by converting ideas and technology designed for weaponry into ideas for “livingry.” At the age of 32, he started an experiment, Guinea Pig B (the “B” stood for “Bucky,” his nickname), to discover how an individual with a moral commitment and limited financial means could apply his knowledge to improve humanity’s living conditions by technological determinism. This experiment continued until his death at age 88. Thus, his technological and economical resources belonged to society. He believed in the same moralistic drive to develop better housing for the masses through mass production that many of the European modernists did, but Fuller’s forms and design principles were quite different.

Among the proliferation of books that Fuller published during his life, the first, (1928), propagated his lifetime philosophy. The term “4D” meant “fourth-dimensional” thinking, adding time to the dimensions of space to ensure gains for humanity instead of personal gains only. The first patent of the 4D designs was a mass-production house, first known as 4D and later as the Dymaxion House (1927 model; 1928 patent). A hexagonal structure supported on a mast, the house was to be air deliverable and based on his strategy of “design science,” which sought to obtain maximum human advantage from minimum use of energy and materials. Using the analogy of airplane technology, he chose materials such as steel- alloy cables and the Duralumin mast. After developing the Dymaxion House, Fuller was to engage in developing prototypes of the Dymaxion Vehicles (1937) and the Dymaxion Bathroom (1940). Later he developed the Dymaxion Deployment Unit (1944), a lightweight corrugated-steel shelter made from modified grain bins. Thousands of these units were bought by the U.S. Army Air Corps for use as flight crew quarters. The Dymaxion Deployment Unit became the basis for Fuller’s Wichita House (1946). These houses were built to be used as full-size family dwellings, weighing four tons each, and were to be assembled on aircraft production lines built during the war. Another of Fuller’s Dymaxion inventions was the Dymaxion Airocean World Map (1946). This map transferred the spherical data of a globe onto a two dimensional surface.

Construction plan of the geodesic dome

Fuller, however, is best known for inventing the geodesic dome (1954), a triangulated space-enclosing technology. According to Fuller, this type of structure encloses the maximum internal volume with the least surface area. Designs such as the domes were based on synergy and its connection with mathematics, using such forms as the tetrahedron, octahedron, and icosahedron. Fuller brought into the dome structure ideas concerning the dome’s tensile ability by introducing a new structural geometry and advancing mechanics into the dome form. He tried to emulate in this structure the atom’s form, including the compound curvature trussing of its dynamic structure. Although this domical design was not new in its elementary form, it was new in its manner of employing these principles in a human-made structure. Numerous domes have appeared all over the world for domestic as well as large-scale industrial use, including the Union Tank Car Company (1958), Baton Rouge, Louisiana; the Climatron Botanical Garden (1961), St. Louis, Missouri; the U.S. Pavilion (1967) at Expo ‘67, the World’s Fair,  Montreal, Canada; and the Spruce Goose Hangar (1982), Long Beach, California.

As noted by architectural historian Kenneth Frampton in his book, (1980), Fuller has influenced future generations of architects, most notably the Japanese group the Metabolists, the British group Archigram, Moshe Safdie, Alfred Neuman, Cedric Price, and Norman Foster. A few semiotician scholars liken him to Joyce, but whereas Joyce sought to obscure language intentionally, Fuller sought to emphasize a precise meaning. Often he would invent words for this purpose, as displayed in his numerous writings and lectures. Later in life, he entered into partnership with Shoji Sadao in New York and Sadao and Zung Architects in Cleveland, Ohio (1979–83). Fuller died on 1 July 1983 in Los Angeles, California, from a massive heart attack; his wife died three days later.