Amazing New Light Field Camera: Adjust Focus After You Take the Picture

The cool Lytro light field camera lets you adjust the focus after the picture is taken. Wow what a surprise the company is located in Mountain View, California. Oh wait, no that isn’t a surprise. Those of us in the USA should thank our lucky stars for having Silicon Valley in our country.

The Lytro will be available in early 2012 starting at $399 (a 8 GB model able to hold up to 350 images) and $499 for a $499 16 GB model able to hold 750 images.

The camera does take 3d images. That feature will be enabled via a software update after the initial release.

Engineers are the new Currency

Silicon Vally investor discusses keys to good investment companies: “Engineers are the new currency… having the right engineers that can innovate and deliver is absolutely vital to success… It takes a great team to help the entrepreneur develop”

The video also makes the point that what separates Silicon Valley is the engineering talent.

Get Your Own Siftable Modular Computers

I posted about Siftable Modular Computers early last year. Recently I have seen ads for them on my management blog, so I decided to see what progress had been made.

The price is a steep but they do seem cool. A Sifteo pack of 3 cubes, plus software, 2 games… is $149. They also require Mac or Windows software. no straight Linux 🙁 Each extra cube costs $45. They started shipping (at least in the USA) on September 30th.

Even though it doesn’t say it is available for Android or Linux here is a video from the recent Android open conference by David Merrill

I do agree that the idea of using these cubes that are in our physical space that we manipulate is very cool. And the idea of intelligent play I very much support. But they need to reduce the price and make them available on the best operating system (Linux/Ubuntu) – which is also open and free. They have also released a software development kit for those interested in creating games for the device. I wish them well.

I Always Wanted to be Some Sort of Scientist

A nice simple post by a soon to be Dr. of Genetics and Molecular Biology on what being a scientist is like for her. I like her take, which I think is much more accurate than some of the generalities people use. The main reason people (men or women) become scientists because they want to be scientists.

Photo the almost-Dr. Caitlin

The truth is science requires you to be social. We share ideas, techniques, and equipment. A good scientist knows her limitations and uses someone else’s expertise when her own is not enough. The modern scientist communicates not only through conferences and journals, but also through blogging and Facebook.
…
When a non-scientist (usually my parents or some other close relative) asks me about what I do, they inevitably want to tie it back to how I’m curing a disease and saving the world. I am not curing a disease or saving the world.

I study science because it’s cool. I study basic science — asking questions for the purpose of learning the answer. That doesn’t mean what I do isn’t important. Lots of ground-breaking medical advances have been made just because someone asked a question no one else thought to ask.
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To all you ladies fighting the good fight in other fields, keep at it, because the numbers are going up for women with advanced degrees.

I’ve always wanted to be some sort of scientist. When I was in elementary school I wanted to be a paleontologist because dinosaurs are awesome (and so was “Jurassic Park”). When I was 11, I read the Hot Zone and knew I wanted to be a biologist. Though there were times that I flirted with the Dark Side, i.e., medical school, but mostly only because when my teachers figured out I was good at science they said go to medical school. No one even suggested becoming a scientist.

Great stuff. Good Luck, Caitlin.

A Possible Explanation for the Faster Than Light Result Anomaly

Faster-than-Light Neutrino Puzzle Claimed Solved by Special Relativity

So what is the satellites’ motion with respect to the OPERA experiment? These probes orbit from West to East in a plane inclined at 55 degrees to the equator. Significantly, that’s roughly in line with the neutrino flight path. Their relative motion is then easy to calculate.

So from the point of view of a clock on board a GPS satellite, the positions of the neutrino source and detector are changing. “From the perspective of the clock, the detector is moving towards the source and consequently the distance travelled by the particles as observed from the clock is shorter,” says van Elburg.

By this he means shorter than the distance measured in the reference frame on the ground.

The OPERA team overlooks this because it thinks of the clocks as on the ground not in orbit.

How big is this effect? Van Elburg calculates that it should cause the neutrinos to arrive 32 nanoseconds early. But this must be doubled because the same error occurs at each end of the experiment. So the total correction is 64 nanoseconds, almost exactly what the OPERA team observes.

It is great to see the scientific process at work. Those is support of the scientific method support open access science and this explanation is available via arxiv: Times Of Flight Between A Source And A Detector Observed From A GPS Satellite.

Periodic Table for Kids

Poster of the periodic table with some illustrations and explanations for kids.

Check out this previous post with a New Visualization of the Periodic Table and see the link in the comment to another variation.

2011 Nobel Prize in Chemistry

Dan Shechtman, Israel Institute of Technology, 2011 Nobel Laurette in Chemistry

The Royal Swedish Academy of Sciences has decided to award the Nobel Prize in Chemistry for 2011 to Dan Shechtman, Technion – Israel Institute of Technology, Haifa, Israel for the discovery of quasicrystals.

In quasicrystals, we find the fascinating mosaics reproduced at the level of atoms: regular patterns that never repeat themselves. However, the configuration found in quasicrystals was considered impossible, and Dan Shechtman had to fight a fierce battle against established science. The Nobel Prize in Chemistry 2011 has fundamentally altered how chemists conceive of solid matter.

On the morning of 8 April 1982, an image counter to the laws of nature appeared in Dan Shechtman’s electron microscope. In all solid matter, atoms were believed to be packed inside crystals in symmetrical patterns that were repeated periodically over and over again. For scientists, this repetition was required in order to obtain a crystal.

Shechtman’s image, however, showed that the atoms in his crystal were packed in a pattern that could not be repeated. Such a pattern was considered just as impossible as creating a football using only six-cornered polygons, when a sphere needs both five- and six-cornered polygons. His discovery was extremely controversial. In the course of defending his findings, he was asked to leave his research group. However, his battle eventually forced scientists to reconsider their conception of the very nature of matter.

Aperiodic mosaics, such as those found in the medieval Islamic mosaics of the Alhambra Palace in Spain and the Darb-i Imam Shrine in Iran, have helped scientists understand what quasicrystals look like at the atomic level. In those mosaics, as in quasicrystals, the patterns are regular – they follow mathematical rules – but they never repeat themselves.

When scientists describe Shechtman’s quasicrystals, they use a concept that comes from mathematics and art: the golden ratio. This number had already caught the interest of mathematicians in Ancient Greece, as it often appeared in geometry. In quasicrystals, for instance, the ratio of various distances between atoms is related to the golden mean.

Following Shechtman’s discovery, scientists have produced other kinds of quasicrystals in the lab and discovered naturally occurring quasicrystals in mineral samples from a Russian river. A Swedish company has also found quasicrystals in a certain form of steel, where the crystals reinforce the material like armor. Scientists are currently experimenting with using quasicrystals in different products such as frying pans and diesel engines.

Read more on the science he has worked on. Our understanding of science is built on the discoveries of our predecessors and on the discoveries that counter what we thought we knew.
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Driving Via Direct Signals from the Brain

Last year we learned of Google’s Self Driving Car, which is actually making great progress in the real world (cool). And a few years ago I wrote about Toyota’s wheelchair you control with your mind. Now Nissan is looking at cars that you drive aided by accessing brain signals.

This idea is a bit scary to me, the self driving car is less so. But it is great to see us pushing the engineering boundaries forward. It is such a shame that the huge economic failures in the USA, Europe and Japan are rightly grabbing much of the attention these days. If we just reduced the waste and corruption in the political and financial systems it would allow us to take more joy is the great time we do for awesome engineering breakthroughs. Still, if we can try to block out those painful economic realities, these types of breakthroughs are really cool.

The webcast shows the work of the Artificial Intelligence Group of the Freie UniversitÃ¤t Berlin in Germany (BrainDriver).

And Nissan is collaborating with the Ã‰cole Polytechnique FÃ©dÃ©rale de Lausanne in Switzerland (EPFL) on a car that uses your brain signals (along with signals the computer gets via its own sensors) to aid in driving.
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2011 Nobel Prize in Physics

Photos of the 2011 Physics Nobel Prize Winners.

The Royal Swedish Academy of Sciences has decided to award the Nobel Prize in Physics for 2011 with one half to

Saul Perlmutter
The Supernova Cosmology Project, Lawrence Berkeley National Laboratory and University of California, Berkeley, CA, USA

and the other half jointly to

Brian P. Schmidt
The High-z Supernova Search Team, Australian National University, Weston Creek, Australia

and

Adam G. Riess
The High-z Supernova Search Team, Johns Hopkins University and Space Telescope Science Institute, Baltimore, MD, USA

“for the discovery of the accelerating expansion of the Universe through observations of distant supernovae”

Once again the USA dominates the physics category, Brian Schmidt is a USA and Australian citizen. It will be interesting to see if this starts to change in the next decade. I believe it will at some point fairly soon, the question is at what point.

“Some say the world will end in fire, some say in ice…” Robert Frost, Fire and Ice, 1920

What will be the final destiny of the Universe? Probably it will end in ice, if we are to believe this year’s Nobel Laureates in Physics. They have studied several dozen exploding stars, called supernovae, and discovered that the Universe is expanding at an ever-accelerating rate. The discovery came as a complete surprise even to the Laureates themselves.

In 1998, cosmology was shaken at its foundations as two research teams presented their findings. Headed by Saul Perlmutter, one of the teams had set to work in 1988. Brian Schmidt headed another team, launched at the end of 1994, where Adam Riess was to play a crucial role.

The research teams raced to map the Universe by locating the most distant supernovae. More sophisticated telescopes on the ground and in space, as well as more powerful computers and new digital imaging sensors (CCD, Nobel Prize in Physics in 2009), opened the possibility in the 1990s to add more pieces to the cosmological puzzle.

The teams used a particular kind of supernova, called type Ia supernova. It is an explosion of an old compact star that is as heavy as the Sun but as small as the Earth. A single such supernova can emit as much light as a whole galaxy. All in all, the two research teams found over 50 distant supernovae whose light was weaker than expected – this was a sign that the expansion of the Universe was accelerating. The potential pitfalls had been numerous, and the scientists found reassurance in the fact that both groups had reached the same astonishing conclusion.

For almost a century, the Universe has been known to be expanding as a consequence of the Big Bang about 14 billion years ago. However, the discovery that this expansion is accelerating is astounding. If the expansion will continue to speed up the Universe will end in ice.

The acceleration is thought to be driven by dark energy, but what that dark energy is remains an enigma – perhaps the greatest in physics today. What is known is that dark energy constitutes about three quarters of the Universe. Therefore the findings of the 2011 Nobel Laureates in Physics have helped to unveil a Universe that to a large extent is unknown to science. And everything is possible again.

As usually the Nobel committee does a great job of providing the public open scientific information. Others that claim to promote science can learn from them. They do a great job of making the science understandable to a lay person.

The discovery came as a complete surprise even to the Nobel Laureates themselves. What they saw would be like throwing a ball up in the air, and instead of having it come back down, watching as it disappears more and more rapidly into the sky, as if gravity could not manage to reverse the ball’s trajectory. Something similar seemed to be happening across the entire Universe.

The growing rate of the expansion implies that the Universe is being pushed apart by an unknown form of energy embedded in the fabric of space. This dark energy makes up a large part of the Universe, more than 70 %, and it is an enigma, perhaps the greatest in physics today. No wonder, then, that cosmology was shaken at its foundations when two different research groups presented similar results in 1998.
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2011 Nobel Prize in Physiology or Medicine

The Nobel Assembly at Karolinska Institutet has today decided that The Nobel Prize in Physiology or Medicine 2011 shall be divided, with one half jointly to Bruce A. Beutler and Jules A. Hoffmann for their discoveries concerning the activation of innate immunity and the other half to Ralph M. Steinman for his discovery of the dendritic cell and its role in adaptive immunity.

This year’s Nobel Laureates have revolutionized our understanding of the immune system by discovering key principles for its activation.

Scientists have long been searching for the gatekeepers of the immune response by which man and other animals defend themselves against attack by bacteria and other microorganisms. Bruce Beutler and Jules Hoffmann discovered receptor proteins that can recognize such microorganisms and activate innate immunity, the first step in the body’s immune response. Ralph Steinman discovered the dendritic cells of the immune system and their unique capacity to activate and regulate adaptive immunity, the later stage of the immune response during which microorganisms are cleared from the body.

The discoveries of the three Nobel Laureates have revealed how the innate and adaptive phases of the immune response are activated and thereby provided novel insights into disease mechanisms. Their work has opened up new avenues for the development of prevention and therapy against infections, cancer, and inflammatory diseases.

We live in a dangerous world. Pathogenic microorganisms (bacteria, virus, fungi, and parasites) threaten us continuously but we are equipped with powerful defense mechanisms (please see image below). The first line of defense, innate immunity, can destroy invading microorganisms and trigger inflammation that contributes to blocking their assault. If microorganisms break through this defense line, adaptive immunity is called into action. With its T and B cells, it produces antibodies and killer cells that destroy infected cells. After successfully combating the infectious assault, our adaptive immune system maintains an immunologic memory that allows a more rapid and powerful mobilization of defense forces next time the same microorganism attacks. These two defense lines of the immune system provide good protection against infections but they also pose a risk. If the activation threshold is too low, or if endogenous molecules can activate the system, inflammatory disease may follow.

The components of the immune system have been identified step by step during the 20th century. Thanks to a series of discoveries awarded the Nobel Prize, we know, for instance, how antibodies are constructed and how T cells recognize foreign substances. However, until the work of Beutler, Hoffmann and Steinman, the mechanisms triggering the activation of innate immunity and mediating the communication between innate and adaptive immunity remained enigmatic.

Ralph Steinman was awarded the Nobel Prize for his discovery of the dendritic cell and its role in adaptive immunity. He was born in Canada and was a professor at Rockefeller University at the end of his career.

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