The tendency to synchronize may be the most mysterious and pervasive drive in all of nature. It has intrigued some of the most brilliant minds of the 20th century, including Albert Einstein, Richard Feynman, Norbert Wiener, Brian Josephson, and Arthur Winfree.

At once elegant and riveting, Sync tells the story of the dawn of a new science. Steven Strogatz, a leading mathematician in the fields of chaos and complexity theory, explains how enormous systems can synchronize themselves, from the electrons in a superconductor to the pacemaker cells in our hearts. He shows that although these phenomena might seem unrelated on the surface, at a deeper level there is a connection, forged by the unifying power of mathematics.

Customer Rating:
Summary: Great read
Comment: Nutshell review - This is a great read, eloquently written and provides a very exciting, layman's overview of the fascinating world of order, chaos and synchronization - where it comes from and how it plays a role in our life and our world. Strogatz is one of the original researchers into this interesting field and gives us lots of food for thought! Excellent.

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Customer Rating:
Summary: not great...
Comment: It covers a lot of topics and some of them are entertaining. But seems unfocused and hard to get a big picture.

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Customer Rating:
Summary: A disappointment
Comment: Author Steve Strogatz's book "Sync" ostensibly concerns the spontaneous synchronization of oscillators, where an "oscillator" is anything that exhibits periodic behavior -- be it a clock, a flashing firefly, or an electron in a superconductor.

The book is clearly modeled on James Gleick's book "Chaos": both books follow various researchers who originally work in isolation but who gradually recognize that they are investigating different aspects of the same phenomenon. As Gleick did for chaos, Strogatz tries to portray spontaneous synchronization as a fundamental, unifying phenomenon in nature. However, many of Strogatz's examples are unimpressive: sleep patterns, the coordinated flashing of lightning bugs, etc. In the more important cases -- the heart's pacemaker cells, phase transitions -- the mechanisms' details haven't been elucidated, so it's not clear how synchronization actually operates. Gradually Strogatz wanders: He argues that in order to progress, science should abandon its traditional analytic approach of investigating the bits of a system and instead should investigate the interactions between the bits; in this connection, he discusses the game "6-degrees of separation," in which very different people are "linked" by chains of acquaintances.

(Strogatz also follows Gleick's footnote format, which is a nuisance.)

In reading this book, I had hoped to find deep insights from a principal investigator in the field; instead, I found entertainment for the math-phobic.

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Customer Rating:
Summary: Resonance
Comment: What I found most interesting about Strogatz's sync theory was the position that it did not require an extensive measure of complexity in order to achieve synchronization. It merely required a critical mass or critical repetition in order to effectuate a phase transformation. The phenomenon of resonance performs similarly. Synchronization may be a form of resonance which has been overlooked, thus far, in our reality (biosphere).

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Customer Rating:
Summary: Heavy Science for Light Readers
Comment: What a fun book. Strogatz has managed to talk about the leading edge of mathematical modeling without a single equation! He uses a comfortable prose and never strays too far from the story of his research. The reader is treated to a view of the way that the world network of scientists organizes itself within areas of research and finds unions where research from one speciality can contribute to another. Who would have thought that the western power grid, the Internet Movie Database and the nervous system of a worm called C. elegans could be effectively modeled with the same operational principles.

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