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This book examines the application of the principle of layering in architecture, its mechanics, possible application and meaning. Layering is widely used in the discussions of the 20th and 21st centuries architecture but rarely defined or examined. Layering bridges the tectonics of structure and skin, offers a system for the creation of different architectural spaces over time and functions as a design principle without hierarchy. Three types of layering are identified: a chronological sedimentation of planes materializing changes over time (temporal layering), the additive sequence of spaces (spatial layering), and the stratification of individual planes (material layering).
The Fabric of the Cosmos: Space, Time, and the Texture of Reality offers an insightful journey into the depths of cosmology, providing an in-depth exploration of the fundamental concepts and theories that shape our understanding of the universe. This captivating book takes readers on a captivating odyssey, unraveling the mysteries of space, time, and the intricate texture of reality. From the very beginning, the book sets the stage with an Introduction to Cosmology, presenting an overview of the Big Bang Theory and the theoretical frameworks that underpin cosmological studies. Understanding the origins of the universe becomes a fascinating endeavor as the book delves into the early universe, discussing concepts such as inflation theory and the formation of cosmic structures. Observational methods in cosmology take center stage in Chapter 2, where readers are introduced to telescopes and observatories, along with the significance of cosmic microwave background radiation. As the exploration continues, the book covers topics such as redshift and Hubble's Law, as well as the intriguing measurements and implications of dark matter and dark energy. The Cosmic Microwave Background is thoroughly examined in Chapter 4, highlighting its discovery and importance. Exploring cosmic microwave background anisotropy and the cosmological implications of polarization brings readers closer to comprehending the intricate fabric of the universe. Another captivating topic covered in the book is the formation of structures in the universe. Chapter 5 unveils the large-scale structure of the universe, shedding light on galaxy clusters, superclusters, and the fascinating birth of galaxies. Expanding the scope of inquiry, Chapter 6 delves into the evolution of stars and galaxies, offering an enthralling examination of stellar evolution, galactic morphology and evolution, as well as the captivating world of active galactic nuclei. Dark matter and dark energy, the enigmatic components that shape our universe, take the spotlight in Chapter 7. Readers are immersed in a comprehensive exploration of the nature, properties, and implications of dark matter and dark energy, unraveling their roles in the expansion of the universe and the development of cosmological models. The book takes a mind-bending turn in Chapter 8, where the concept of parallel universes and multiple dimensions is explored. Through the lens of multiverse theories, readers are invited to contemplate the mind-boggling possibilities presented by string theory, the Many Worlds Interpretation, and the Anthropic Principle. Chapter 9 delves into cosmological models and theories, presenting the standard cosmological model (ΛCDM), alternative models, and modifications, as well as the intriguing realm of quantum cosmology. Finally, the book concludes with Chapter 10, providing thought-provoking insights into the fate of the universe. Will it experience a Big Freeze, a Big Crunch, or a Big Rip? Multiverse scenarios and the ultimate destiny of the universe offer captivating perspectives that will leave readers pondering the awe-inspiring nature of existence. The Fabric of the Cosmos: Space, Time, and the Texture of Reality is a must-read for anyone seeking a comprehensive understanding of the cosmos. With its engaging narrative and in-depth exploration of cosmological concepts, this book is an invaluable resource for both novice and seasoned enthusiasts. Embark on an enlightening journey through the depths of the cosmos, and unlock the secrets of the universe's fabric.
This volume emphasizes one aspect of scientific method: units of measure and their construction as applied to archaeology. Attributes, artifact classes, locational designations, temporal periods, sampling universes, culture stages, and geographic regions are all examples of constructed units.
The study of mathematical cognition and the ways in which the ideas of space, time and number are encoded in brain circuitry has become a fundamental issue for neuroscience. How such encoding differs across cultures and educational level is of further interest in education and neuropsychology. This rapidly expanding field of research is overdue for an interdisciplinary volume such as this, which deals with the neurological and psychological foundations of human numeric capacity. A uniquely integrative work, this volume provides a much needed compilation of primary source material to researchers from basic neuroscience, psychology, developmental science, neuroimaging, neuropsychology and theoretical biology. The first comprehensive and authoritative volume dealing with neurological and psychological foundations of mathematical cognition Uniquely integrative volume at the frontier of a rapidly expanding interdisciplinary field Features outstanding and truly international scholarship, with chapters written by leading experts in a variety of fields
"This new edition ensures that the book will continue to be internationally acknowledged as the standard work on the development of modern architecture." -Walter Gropius "A remarkable accomplishment. . . one of the most valuable reference books for students and professionals concerned with the reshaping of our environment. " -José Luis Sert A milestone in modern thought, Space, Time and Architecture has been reissued many times since its first publication in 1941 and translated into half a dozen languages. In this revised edition of Sigfried Giedion’s classic work, major sections have been added and there are 81 new illustrations. The chapters on leading contemporary architects have been greatly expanded. There is new material on the later development of Frank Lloyd Wright and the more recent buildings of Walter Gropius, particularly his American Embassy in Athens. In his discussion of Le Corbusier, Mr. Giedion provides detailed analyses of the Carpenter Center at Harvard University, Le Corbusier’s only building in the United States, and his Priory of La Tourette near Lyons. There is a section on his relations with his clients and an assessment of his influence on contemporary architecture, including a description of the Le Corbusier Center in Zurich (designed just before his death), which houses his works of art. The chapters on Mies van der Rohe and Alvar Aalto have been brought up to date with examples of their buildings in the sixties. There is an entirely new chapter on the Danish architect Jørn Utzon, whose work, as exemplified in his design for the Sydney Opera House, Mr. Giedion considers representative of post–World War II architectural concepts. A new essay, “Changing Notions of the City,” traces the evolution of the structure of the city throughout history and examines current attempts to deal with urban growth, as shown in the work of such architects as José Luis Sert, Kenzo Tange, and Fumihiko Maki. Mr. Sert’s Peabody Terrace is discussed as an example of the interlocking of the collective and individual spheres. Finally, the conclusion has been enlarged to include a survey of the limits of the organic in architecture.
A novel and unified presentation of the elements of mechanics in material space or configurational mechanics, with applications to fracture and defect mechanics. The level is kept accessible for any engineer, scientist or graduate possessing some knowledge of calculus and partial differential equations, and working in the various areas where rational use of materials is essential.
Originally published in 1962. The central aim of this book is to discuss the development of Alfred North Whitehead's thought and to underscore how it is unique. Understanding Whitehead collects nine essays written by Victor Lowe originally published between 1941 and 1961. The essays have been revised for inclusion in this volume.
INSTANT NEW YORK TIMES BESTSELLER “Most appealing... technical accuracy and lightness of tone... Impeccable.”—Wall Street Journal “A porthole into another world.”—Scientific American “Brings science dissemination to a new level.”—Science The most trusted explainer of the most mind-boggling concepts pulls back the veil of mystery that has too long cloaked the most valuable building blocks of modern science. Sean Carroll, with his genius for making complex notions entertaining, presents in his uniquely lucid voice the fundamental ideas informing the modern physics of reality. Physics offers deep insights into the workings of the universe but those insights come in the form of equations that often look like gobbledygook. Sean Carroll shows that they are really like meaningful poems that can help us fly over sierras to discover a miraculous multidimensional landscape alive with radiant giants, warped space-time, and bewilderingly powerful forces. High school calculus is itself a centuries-old marvel as worthy of our gaze as the Mona Lisa. And it may come as a surprise the extent to which all our most cutting-edge ideas about black holes are built on the math calculus enables. No one else could so smoothly guide readers toward grasping the very equation Einstein used to describe his theory of general relativity. In the tradition of the legendary Richard Feynman lectures presented sixty years ago, this book is an inspiring, dazzling introduction to a way of seeing that will resonate across cultural and generational boundaries for many years to come.
Henri Lefebvre has considerable claims to be the greatest living philosopher. His work spans some sixty years and includes original work on a diverse range of subjects, from dialectical materialism to architecture, urbanism and the experience of everyday life. The Production of Space is his major philosophical work and its translation has been long awaited by scholars in many different fields. The book is a search for a reconciliation between mental space (the space of the philosophers) and real space (the physical and social spheres in which we all live). In the course of his exploration, Henri Lefebvre moves from metaphysical and ideological considerations of the meaning of space to its experience in the everyday life of home and city. He seeks, in other words, to bridge the gap between the realms of theory and practice, between the mental and the social, and between philosophy and reality. In doing so, he ranges through art, literature, architecture and economics, and further provides a powerful antidote to the sterile and obfuscatory methods and theories characteristic of much recent continental philosophy. This is a work of great vision and incisiveness. It is also characterized by its author's wit and by anecdote, as well as by a deftness of style which Donald Nicholson-Smith's sensitive translation precisely captures.
This small book started a profound revolution in the development of mathematical physics, one which has reached many working physicists already, and which stands poised to bring about far-reaching change in the future. At its heart is the use of Clifford algebra to unify otherwise disparate mathematical languages, particularly those of spinors, quaternions, tensors and differential forms. It provides a unified approach covering all these areas and thus leads to a very efficient ‘toolkit’ for use in physical problems including quantum mechanics, classical mechanics, electromagnetism and relativity (both special and general) – only one mathematical system needs to be learned and understood, and one can use it at levels which extend right through to current research topics in each of these areas. These same techniques, in the form of the ‘Geometric Algebra’, can be applied in many areas of engineering, robotics and computer science, with no changes necessary – it is the same underlying mathematics, and enables physicists to understand topics in engineering, and engineers to understand topics in physics (including aspects in frontier areas), in a way which no other single mathematical system could hope to make possible. There is another aspect to Geometric Algebra, which is less tangible, and goes beyond questions of mathematical power and range. This is the remarkable insight it gives to physical problems, and the way it constantly suggests new features of the physics itself, not just the mathematics. Examples of this are peppered throughout ‘Space-Time Algebra’, despite its short length, and some of them are effectively still research topics for the future. From the Foreward by Anthony Lasenby