Stephen F Bush Quotes

Another advantage is the existence of an exercise section at the end of each chapter which enables the reader to verify understanding and, when needed, to go back to the right section and reread desired fragments.

No prior knowledge regarding quantum mechanics is expected, so one can find a really good introduction covering quantum states, measurement, entanglement together with other aspects of quantum networking, including such issues as security, teleportation, and channel swapping.

Contrary to popular opinion, innovation without some standardized conceptual framework is tantamount to chaos.

Nanotechnology has been a very promising research topic in recent years, leading to successful practical implementations. The achievements in this area have led to a growing interest in nanoscale networks. Nanoscale Communication Networks is a kind of primer which prepares the reader for the convergence of Nanotechnology and networking, providing the necessary information for further reading or self-research.

Let us think of standards as a way to move from publication to innovation, to move from trying to increase a meaningless impact factor to actually having an impact and fostering new ideas that people can build upon.

The advantage of molecular messaging over other sorts of communication, he says, is its ability to be deployed in hard-to-reach places, such as providing in-body communications for medical applications. The body's cellular signalling pathways have already been mapped, so these could serve as "communications channels", says Dr Bush. Digital signals could be sent, say, to the vagal system to help moderate a patient's blood pressure or heart rate. Data transmitted molecularly might also enable blood-sugar levels to be monitored without invasive pinpricks.

Often it seems the more ‘scholarship’ one has, the less innovative one becomes. One can increasingly rest upon their knowledge of prior art to solve what looks like a new problem.

Conceptually, we would like a `Maxwell's demon' to exist within the power grid capable of capturing the geomagnetic storm energy. This could someday be a new feature of the `smart grid.'

...Nanoscale Communication Networks is a very good and valuable book.

Having presented all the relevant nanoscale mechanisms, thus laying down a firm background for the readers' understanding, the author moves to the topic of architectural challenges in Chapter 7. This field is claimed still to be an unsolved problem so the author gives examples of currently used technologies and points out potential architectural solutions such as self-assembly, carbon nanotubes, or quantum systems. That is why it makes the book even more valuable for those who intend to involve nanonetworks in their research.

Academics tend to think they are each the next Einstein whose 'creativity' will finally be uncovered a hundred years from now. That's when society should deliver their project funding.

A Streptichron (from the Classical Greek meaning to 'bend time') is an active packet facilitating prediction that implements any of the active mechanisms... The Streptichron can use this capability to refine its prediction as it travels through the network.

Richard Feynman presciently stated... that 'There's Plenty of Room at the Bottom'. ...within this vast room … there will be a requirement for communication.

...understanding information entropy in the power grid per kilowatt of power delivered or the radio frequency communication power expended within the power grid per kilowatt of power delivered will be more valuable than understanding the detailed packet structure of a half-dozen supervisory control and data acquisition protocols.

There is a gap between industry and academia. Industry views academia as publication-focused: self-centered, lacking innovation, unaware of IP. Academia views industry as money-focused: driven by the bottom-line, innovating too quickly, product-focused. I would like to see more input from industry and emphasis on understanding 'innovation' to close this gap.