A Science journalist reveals the existence of the world's first quantum computer--created by a team of Silicon Valley researchers and able to simultaneously compute all possible solutions to a problem, making it the most powerful computer in the world.
Is there a mechanism through which some people can see the future? How can a life in this universe be predetermined? Where might information about the future exist? If we are to have faith in our grasp of physics and cosmological principles, it must exist outside this universe. How can we structure a multiverse so that it broadly accommodates precognition? In Time and the Multiverse, author Dr. Gerald Holdsworth addresses these questions and more and discusses phenomena that cannot be explained by the principles of established physics. Holdsworth accepted the challenge of explaining the basis behind the common experience of precognition, the easiest phenomena to verify but the hardest to explain. He tells how he built a looped version of the serial, time-zoned multiverse which exhibits time zoning within the regular clock time system as well as revealing what can be termed a timing system, which coordinates the processes within the multiverses Cosmic quantum computer. This second time is in practice represented by a fixed frequency of time pips occurring within the computer. Author notes What I present in chapter 2 of this book concerning the dynamics of the multiverse cannot be described by mathematical equations because the physics isnt available. I have relied entirely on logical statements and geometry to produce the Cosmic Blueprint and, from a special case of it, the Cosmological model. Arthur Eddington and Wolfgang Pauli knew that to achieve a complete understanding of our existence one has to include all the unexplained anomalies (like precognition) along with established physics: quantum mechanics, particle physics and Einsteins gravity theory. Eddington and John W Dunne realized that time would play a major role in tying together all the evidence. Dunnes attempts ending in 1955 were invalid due to his deliberate exclusion of the existence of multiple universes. He did at least finally confess his spiritual experiences.
Critical acclaim for John Gribbin "The master of popular science." —Sunday Times (London) "Gribbin explains things very well indeed, and there's not an equation in sight." —David Goodstein, The New York Times Book Review (on Almost Everyone's Guide to Science) "Gribbin breathes life into the core ideas of complexity science, and argues convincingly that the basic laws, even in biology, will ultimately turn out to be simple." —Nature magazine (on Deep Simplicity) "Gribbin takes us through the basics [of chaos theory] with his customary talent for accessibility and clarity. [His] arguments are driven not by impersonal equations but by a sense of wonder at the presence in the universe and in nature of simple, self-organizing harmonies underpinning all structures, whether they are stars or flowers." —Sunday Times (London) (on Deep Simplicity) "In the true quantum realm, Gribbin remains the premier expositor of the latest developments." —Booklist (on Schrödinger's Kittens and the Search for Reality)
The imminent arrival of the quantum computer, millions of times faster than today's computers, promises to launch a scientific gold rush of the new millennium. After consulting with both the computer's debunkers and the leading minds behind the breakthrough, Brown explains the quantum computer's development thus far.
The big bang or God debate never quite satisfied you? Lingering doubts about what it all means and how there got to be anything in the first place? Take a whirlwind tour from a network administrator's perspective.
George Gilder's groundbreaking "Telecosm" announced the reality of the bandwidth revolution. Now David Nolte explains the technology behind the revolution and reveals the future of artificial intelligence.
Today we hear renewed calls for a dialogue between science and religion: why has the old question of the relations between science and religion now returned to the public domain and what is at stake in this debate? To answer these questions, historian and sociologist of science Yves Gingras retraces the long history of the troubled relationship between science and religion, from the condemnation of Galileo for heresy in 1633 until his rehabilitation by John Paul II in 1992. He reconstructs the process of the gradual separation of science from theology and religion, showing how God and natural theology became marginalized in the scientific field in the eighteenth and nineteenth centuries. In contrast to the dominant trend among historians of science, Gingras argues that science and religion are social institutions that give rise to incompatible ways of knowing, rooted in different methodologies and forms of knowledge, and that there never was, and cannot be, a genuine dialogue between them. Wide-ranging and authoritative, this new book on one of the fundamental questions of Western thought will be of great interest to students and scholars of the history of science and of religion as well as to general readers who are intrigued by the new and much-publicized conversations about the alleged links between science and religion.
In this remarkably illustrative and thoroughly accessible look at one of the most intriguing frontiers in science and computers, award-winning New York Times writer George Johnson reveals the fascinating world of quantum computing—the holy grail of super computers where the computing power of single atoms is harnassed to create machines capable of almost unimaginable calculations in the blink of an eye. As computer chips continue to shrink in size, scientists anticipate the end of the road: A computer in which each switch is comprised of a single atom. Such a device would operate under a different set of physical laws: The laws of quantum mechanics. Johnson gently leads the curious outsider through the surprisingly simple ideas needed to understand this dream, discussing the current state of the revolution, and ultimately assessing the awesome power these machines could have to change our world.
This publication features an interdisciplinary group of contributors which questions aspects of today's worldviews and science that are often taken for granted and tacitly determine the boundaries of what is generally conceived of as the 'world' and 'science'. Some authors stress that existing demarcations are obsolete and often prevent new insights. Others show how they influence the way people perceive themselves and believe the world ontologically to be, determining people's actions and the social fabric. There are yet others who point out how a redemarcation may stimulate the development of knowledge acquisition and social well-being. Examples of how bridging knowledge between different fields leads to new crucial insights, while identifying the pattern of too strict a demarcation preventing such insights, are also analyzed in this volume.
The quantum computer is no longer the stuff of science fiction. Pioneering physicists are on the brink of unlocking a new quantum universe which provides a better representation of reality than our everyday experiences and common sense ever could. The birth of quantum computers - which, like Schrödinger's famous "dead and alive" cat, rely on entities like electrons, photons, or atoms existing in two states at the same time - is set to turn the computing world on its head. In his fascinating study of this cutting-edge technology, and featuring a new introduction, John Gribbin explores the nature of quantum reality, arguing for a universe of many parallel worlds where "everything is real." Looking back to Alan Turing's work on the Enigma machine and the first electronic computer, Gribbin explains how quantum theory developed to make quantum computers work in practice as well as in principle. He takes us beyond the arena of theoretical physics to explore their practical applications - from machines which learn through "intuition" and trial and error to unhackable laptops and smartphones. And he investigates the potential for this extraordinary science to create a world where communication occurs faster than light and teleportation is possible. This is an exciting insider's look at the new frontier of computer science and its revolutionary implications.