Tag Archives: Engineering

Science and Engineering Fiction

cover of The Ice Limit

We always hear of science fiction. But what about engineering fiction? Well I finished reading a book this weekend that was at least as much engineering fiction as science fiction: The Ice Limit by Douglas Preston and Lincoln Child. It was a fun read. I enjoy the books those two collaborate on.

I also finished reading another book recently. I recommend Panic in Level 4 by Richard Preston. He wrote The Hot Zone, which is also great. He writes what “literary nonfiction” or “creative nonfiction.” The book includes 2 stories on math, about the Chudnovsky brothers, and 4 on biological science stories. I believe they were all previously stories in the New Yorker.

Douglas Preston and Richard Preston are brothers. It is just a happy co-incidence I happened to read them both recently. I just noticed the last names were the same so I looked online to see if they were related. Here is a nice bit from Douglas Preston’s web site:

As they grew up, Doug, Richard, and their little brother David roamed the quiet suburbs of Wellesley, terrorizing the natives with home-made rockets and incendiary devices mail-ordered from the backs of comic books or concocted from chemistry sets.

After unaccountably being rejected by Stanford University (a pox on it), Preston attended Pomona College in Claremont, California, where he studied mathematics, biology, physics, anthropology, chemistry, geology, and astronomy before settling down to English literature.

Also I read Tyrannosaur Canyon by Douglas Preston a few months ago. I preferred it to Ice Limit actually (but it didn’t have the engineering fiction angle) just a fun thriller with some science fiction thrown in.

Related: Ebola Outbreak in Ugandascience booksWaterloo’s wizards of game theoryThe Best Science BooksMy favorite science fiction author Orson Scott Card

Post 2009

My first post in 2009 is the 2009th post for the blog. Here are some highlights from 2008:

High School Students to Intern in Engineering

Pasco high school students to work as interns in engineering

Five area manufacturers announced Tuesday that they will join forces with River Ridge High’s new engineering career academy, which opens in fall 2009, to provide students work opportunities while they are still in school.

“The idea is to start a program of internships starting in the 10th grade,” said Wahnish, who presents the idea to the Florida Engineering Society today.

By the time graduation rolls around, students will have had three six-week apprenticeships and received industry certifications in computer-assisted design and other applications. They also will be ready to go to work or enroll in a university program. Even those who go to work still would attend college at least two days a week.

Related: Engineering Internship OpeningsSummer Jobs for Smart Young MindsToyota Cultivating Engineering TalentInternships Increasingly Popularcareers in science and engineering

Appropriate Technology: Self Adjusting Glasses

Self Adjusting Glasses for 1 billion of the world’s poorest see better

What if it were possible, he thought, to make a pair of glasses which, instead of requiring an optician, could be “tuned” by the wearer to correct his or her own vision? Might it be possible to bring affordable spectacles to millions who would never otherwise have them?

More than two decades after posing that question, Josh Silver [a physics professor at Oxford] now feels he has the answer. The British inventor has embarked on a quest that is breathtakingly ambitious, but which he insists is achievable – to offer glasses to a billion of the world’s poorest people by 2020.

Some 30,000 pairs of his spectacles have already been distributed in 15 countries, but to Silver that is very small beer. Within the next year the now-retired professor and his team plan to launch a trial in India which will, they hope, distribute 1 million pairs of glasses. The target, within a few years, is 100 million pairs annually.

Silver has devised a pair of glasses which rely on the principle that the fatter a lens the more powerful it becomes. Inside the device’s tough plastic lenses are two clear circular sacs filled with fluid, each of which is connected to a small syringe attached to either arm of the spectacles.

The wearer adjusts a dial on the syringe to add or reduce amount of fluid in the membrane, thus changing the power of the lens. When the wearer is happy with the strength of each lens the membrane is sealed by twisting a small screw, and the syringes removed. The principle is so simple, the team has discovered, that with very little guidance people are perfectly capable of creating glasses to their own prescription.

Oxford University, at his instigation, has agreed to host a Centre for Vision in the Developing World, which is about to begin working on a World Bank-funded project with scientists from the US, China, Hong Kong and South Africa. “Things are never simple. But I will solve this problem if I can. And I won’t really let people stand in my way.”

Cool. A couple points I would like to make:

1) this professor is making a much bigger difference in the “real world” than most people ever will. The idea that professors are all lost in insignificant “ivory towers” is a very inaccurate view of what really happens.
2) Spending money on this kind of thing seems much more important for the human race than spending trillions to bail out poor moves by bankers, financiers… It sure seems odd that we can’t find a few billion to help out people across the globe that are without basic necessities yet we can find trillions to bail out the actions of few thousand bad actors.

Related: Adaptive EyecareBringing Eye Care to Thousands in IndiaRiver Blindness Worm Develops Resistance to DrugsStrawjet: Invention of the Year (2006)Fixing the World on $2 a DayAppropriate Technology

Undersea Cables Cut Again – Reducing India’s Capacity by 65%

Once again a severed underwater cable has disrupted web access

Internet and phone communications between Europe, the Middle East, and Asia have been seriously disrupted after submarine cables were severed. It is thought the FLAG FEA, SMW4, and SMW3 lines, near the Alexandria cable station in Egypt, have all been cut.

A fault was also reported on the GO submarine cable 130km off Sicily. Experts warned that it may be days before the fault is fixed and said the knock on effect could have serious repercussions on regional economies.

It is thought that 65% of traffic to India was down, while services to Singapore, Malaysia, Saudi Arabia, Egypt, Taiwan and Pakistan have also been severely affected.

Earlier this year, the same line was damaged in the same area – off the Egyptian coast – although only two lines were snapped then. “We’ve lost three out of four lines. If the fourth cable breaks, we’re looking at a total blackout in the Middle East,” said Mr Wright.

“These three circuits account for 90% of the traffic and we’re going to see more international phone calls dropping and a huge degradation in the quality of local internet,” he added.

“Normally you would expect to see one major break per cable per year. With four you should have an insurance policy. For this to happen twice in one year, on the same cable, is a serious cause for concern.”

Related: How Do You Fix an Undersea Cable?Internet Undersea CablesInternet Underwater Fiber

BCS Title Game, Live in 3D

BCS title game to be available live in 3-D

Thanks to an impressive — though not glitch-free — test broadcast of an NFL game two weeks ago, Burbank, Calif.-based 3Ality Digital said Tuesday it had won the contract to shoot the Jan. 8 BCS National Championship game in 3-D.

The game between Florida and Oklahoma will be broadcast live in 3-D to 80 to 100 movie theaters in about 30 U.S. cities, said 3Ality Chairman David Modell. Tickets are expected to cost $18 to $22, said Cinedigm Digital Cinema Corp., which is working with 3Ality to deliver the broadcasts to theaters.

“The live broadcast to the Paris Hotel and to movie theaters across the nation is the latest example of how we can deliver our programming to audiences in new and exciting ways,” said Jerry Steinberg, senior vice president of field operations and engineering for FOX Sports. “3D technology holds unlimited potential for the future of both sports broadcasting and live event production.”

Cool, though not quite the holographic TV I am still waiting for.

Related: Video Goggles (like a portable 50″ TV screen)Magnetic MovieRandomization in Sports

Perceptions v. Objective Reality

User Interface Matters by Colleen Dick:

the earliest Hewlett Packard programmable calculators in the early 80’s. When engaging in lengthy number crunching, the calculator would print “crunching” (or processing, or something) on the display, and every few seconds it would add a dot, so the user would know something was happening.

HP engineers discovered that if they completely decoupled the display while serious crunching was going on, they could make the computations run 30-40% faster. Naturally they assumed the users would appreciate such a significant speed increase, so on their next revision, they just shut the screen down on lengthy computations.

Users complained about the slowdown! These are HP early adopters, mind you, mostly “rational” scientists and engineers. Remember, when objectively measured, the computations were measurably and significantly faster when the screen was decoupled!

In subjective time, the computations seemed slower without the feedback, even though in objective time we know they were faster.

There are times when objective improvement is most important, but there are also plenty of times when subjective improvement is more important. Often this difference is ignored.

Related: Packaging Improves Foot “Taste”The Psychology of Too Much Choice

Engineers and Scientists in Congress

I started maintaining a list of Congressmen with PhDs and graduate degrees in science, engineering and math awhile back.

Please comment with any additions that you know of.

The following were re-elected:
Vernon Ehlers, Michigan, physics PhD; Rush Holt, New Jersey, physics PhD; John Olver, Massachusetts, chemistry PhD; Brian Baird, Washington, psychology PhD; Bill Foster, Illinois, physics PhD.

Other scientists, engineers and mathematicians that were reelected include: Ron Paul, Texas, biology BS, MD; Jerry McNerney, California, mathematics PhD; Dan Lipinski, Illinois, mechanical engineering BS, engineering-economic systems MS; Todd Akin, Mississippi, management engineering BS;Cliff Stearns, Florida, electrical engineering BS; Louise Slaughter, New York, microbiology BS; Joe Barton, Texas, industrial engineering BS, Pete Stark, California, engineering BS, Mike Honda, California.

Lost: Nancy Boyda, Kansas (BS chemistry).

Newly elected: Bill Cassidy, Louisiana (BS Biochemistry, MD); Pete Olson, Texas (BA computer science); Kurt Schrader, Oregon (Doctor of Veterinary Medicine); Martin Heinrich, New Mexico (BS engineering), Gregg Harper, Mississippi (BS chemistry), Joseph Cao, Mississippi (BA physics); Brett Guthrie, Virginia (BS mathematical economics); Erik Paulsen, Minnesota, mathematics BA; Parker Griffith, Alabama (BS chemistry, MD); Cynthia Lummis, Wyoming (BS animal science and biology).

Before you leap to the conclusion that scientists are taking over Congress, remember 2 things: 1) I have probably been missing plenty that were in congress already and 2) this is still a total of less than 10% with even a BS in science, math or engineering. I attempted to determine the status of all those newly elected this year.

Please comment, if you know of others in Congress with science and engineering backgrounds. If we get this list to be relative close to accurate then we can start tracking the total representation in congress and see if it is increasing, decreasing or randomly fluctuating over time.

Related: Scientists and Engineers in CongressChina’s Technology Savvy LeadershipScience and Engineering in PoliticsThe A to Z Guide to Political Interference in Science

von Neumann Architecture and Bottleneck

We each use computers a great deal (like to write this blog and read this blog) but often have little understanding of how a computer actually works. This post gives some details on the inner workings of your computer.
What Your Computer Does While You Wait

People refer to the bottleneck between CPU and memory as the von Neumann bottleneck. Now, the front side bus bandwidth, ~10GB/s, actually looks decent. At that rate, you could read all of 8GB of system memory in less than one second or read 100 bytes in 10ns. Sadly this throughput is a theoretical maximum (unlike most others in the diagram) and cannot be achieved due to delays in the main RAM circuitry.

Sadly the southbridge hosts some truly sluggish performers, for even main memory is blazing fast compared to hard drives. Keeping with the office analogy, waiting for a hard drive seek is like leaving the building to roam the earth for one year and three months. This is why so many workloads are dominated by disk I/O and why database performance can drive off a cliff once the in-memory buffers are exhausted. It is also why plentiful RAM (for buffering) and fast hard drives are so important for overall system performance.

Related: Free Harvard Online Course (MP3s) Understanding Computers and the InternetHow Computers Boot UpThe von Neumann Architecture of Computer SystemsFive Scientists Who Made the Modern World (including John von Neumann)

Rat Brain Cells, in a Dish, Flying a Plane

Adaptive Flight Control With Living Neuronal Networks on Microelectrode Arrays (open access paper) by Thomas B. DeMarse and Karl P. Dockendorf Department of Biomedical Engineering, University of Florida

investigating the ability of living neurons to act as a set of neuronal weights which were used to control the flight of a simulated aircraft. These weights were manipulated via high frequency stimulation inputs to produce a system in which a living neuronal network would “learn” to control an aircraft for straight and level flight.

A system was created in which a network of living rat cortical neurons were slowly adapted to control an aircraft’s flight trajectory. This was accomplished by using high frequency stimulation pulses delivered to two independent channels, one for pitch, and one for roll. This relatively simple system was able to control the pitch and roll of a simulated aircraft.

When Dr. Thomas DeMarse first puts the neurons in the dish, they look like little more than grains of sand sprinkled in water. However, individual neurons soon begin to extend microscopic lines toward each other, making connections that represent neural processes. “You see one extend a process, pull it back, extend it out — and it may do that a couple of times, just sampling who’s next to it, until over time the connectivity starts to establish itself,” he said. “(The brain is) getting its network to the point where it’s a live computation device.”

To control the simulated aircraft, the neurons first receive information from the computer about flight conditions: whether the plane is flying straight and level or is tilted to the left or to the right. The neurons then analyze the data and respond by sending signals to the plane’s controls. Those signals alter the flight path and new information is sent to the neurons, creating a feedback system.

“Initially when we hook up this brain to a flight simulator, it doesn’t know how to control the aircraft,” DeMarse said. “So you hook it up and the aircraft simply drifts randomly. And as the data come in, it slowly modifies the (neural) network so over time, the network gradually learns to fly the aircraft.”

Although the brain currently is able to control the pitch and roll of the simulated aircraft in weather conditions ranging from blue skies to stormy, hurricane-force winds, the underlying goal is a more fundamental understanding of how neurons interact as a network, DeMarse said.

Related: Neural & Hybrid Computing Laboratory @ University of Florida – UF Scientist: “Brain” In A Dish Acts As Autopilot, Living ComputerRoachbot: Cockroach Controlled RobotNew Neurons in Old Brainsposts on brain researchViruses and What is LifeGreat Self Portrait of Astronaut Engineer