Let's say you're a giant biotech company in sunny California, and you have a big ranch where you keep thousands of goats. You use the goats to produce all kinds of antibodies that you then extract and sell to biological researchers all over the world. You are, in fact, one of the world's biggest suppliers of these antibodies--a true industry leader.

Anyway, everything is going quite well for you, except that the USDA keeps poking their big government nose into your operations, sending inspectors over to your ranch to have a look around, and the inspectors are not liking what they're finding. They keep telling you that you need to provide "adequate veterinary care" for your goats and that the animals' facilities must be "maintained in good care," and soon enough, they're filing a complaint that lists 17 of these little violations and alleges that you have "willfully violated the Animal Welfare Act."

What are you going to do? You could go through all the trouble of hiring a couple extra people to look the animals over and treat them when they're sick, etc, etc, OR you could get really clever and outsmart the big government outfit by, I don't know, failing to mention that you've got a barn down the road with 841 goats inside of it--give 'em one less place to make trouble.

When the real-life company Santa Cruz Biotechnology found themselves in this position, they went with option number two. And it worked!--for a little while. But then, late last October, the USDA received a tip about the barn, and an inspector went down there and found it, along with the 841 goats, 12 of which were not, technically speaking, in good shape.

To make matters worse, the inspector could tell that the barn had been used for a while, which made it obvious to everyone that the staff on the Santa Cruz Biotechnology ranch had been blatantly lying when they claimed--as they had, on multiple occasions--that the building didn't exist, and that there weren't any animals inside it.

The company may face fines or a suspended license for their violations of animal welfare and for lying to the USDA, but an even bigger problem (for Santa Cruz Biotechnology) may come from the NIH, who currently exempts off-the-shelf antibodies from the set of animal treatment rules that governs NIH-funded research.

If the NIH decides to change that rule, Santa Cruz Biotechnology may soon long for the simple days of USDA oversight.

[via Nature]

When it comes time for an aging skyscraper to be put out to pasture, it's best to do so slowly. For buildings higher than 100 meters tall, there's no easy path to demolition. Sure, you could blow it up, but the cleanup would be brutal. You could slam it with a wrecking ball, but that's a little heavy-handed, don't you think?

Taisei Corporation, a Japanese construction company, is doing things a little more subtly, and making skyscraper deconstruction a more eco-friendly endeavor in the process.

Through their Ecological Reproduction System (Tecorep), rather than using cranes to take the building apart from the outside, they start from the inside, taking the structure apart floor by floor from the top down. A crane inside the building lowers materials harvested from each floor to ground level, generating electricity to power other equipment in the process. So with Tecorep, higher buildings are actually an advantage, since the crane can generate more electricity lowering materials over longer distances.

When a floor is completely stripped, the temporary columns and jacks holding it up are lowered, giving the building the outside appearance of shrinking into itself. Between salvaging reusable material and powering the project with clean energy, Tecorep reduces carbon emissions by 85 percent, according to the company. And because the demolition takes place within the building, it reduces noise and dust.

The method successfully brought down the Grand Prince Hotel Akasaka in Tokyo, the tallest building torn down in Japan to date. Hideki Ichihara, who runs Taisei's construction technology development, told the Japan Times that most skyscrapers over 100 meters are torn down after 30 or 40 years, and with 99 Japanese buildings set to fit that bill in the next 10 years, innovative deconstruction technology is an emerging field. Other corporations have been developing their own methods, such as the Kajima Corporation, which dismantles and lowers the building from the bottom up.

You can see Tecorep in action below.

[Wired]

We've seen lots of hydrophobic materials before, but these water- and liquid-repelling materials often work within constraints. Some liquids bounce or wick away, while others--based on properties like viscosity or surface tension, or whether the substance in questions is organic or inorganic--are not affected by the hydrophobic qualities of the material. But a team of University of Michigan materials science is reporting a breakthrough that could have big implications for everything from stain-free clothing to protective surface coatings and chemical resistant protective suits: a superomniphobic coating that is resistant to pretty much any liquid we know of.

The coating is derived from an electrospun coating that is carefully structured in a cross-linked pattern that essentially makes it impervious to attack from any contact angle, and that's really the critical piece to this. We've seen superhydrophobic surfaces before that are extremely adept at repelling high surface tension liquids like water. And we've seen what are known as superoleophobic materials that are repellant toward low surface tension liquids.

But superomniphobic surfaces have been more elusive. In laboratory settings they've been developed for resistance to Newtonian fluids, but the U. of Michigan teams claim that their material is the first that is truly supermniphobic in the sense that any liquid you throw at it--organic or inorganic, high surface tension or low surface tension, Newtonian or non-Newtonian (repellant to ketchup!)--will bounce or roll off.

Which is pretty crazy. In a paper submitted to the Journal of the American Chemical Society, the team describes dropping aluminum sheets coated in their superomniphobic material in vats of concentrated hydrochloric acid and concentrated sodium hydroxide (that's a highly caustic metallic base) and anxiously watching absolutely nothing happen. Even when examined microscopically after several minutes of immersion, the aluminum showed no damage.

That, of course, is big news for chemical shielding. Textiles coated in the stuff could make for pretty serious all-purpose hazmat suits, and coatings could be used for everything from corrosion-resistance to drag reduction for maritime vessels.

[JACS]

President Obama issued 23 executive actions on gun control today, including provisions encouraging research into the causes and prevention of gun violence. He also challenged the private sector to develop innovations in gun safety.

One order calls for the issue of "a presidential memorandum directing the Centers for Disease Control to research the causes and prevention of gun violence." Federally funded science agencies have been prohibited from using their funds to "advocate or promote gun control," something critics say has stymied research into the causes of gun violence. "Public health research on gun violence is not advocacy," the White House plan clarifies.

Obama is additionally asking Congress to provide the CDC $10 million to conduct research into the relationship between video games, violence and media images.

The president also wants to encourage the creation of new gun violence-combating technologies and called on the attorney general to "issue a report on the availability and most effective use of new gun safety technologies and challenge the private sector to develop innovative technologies." As part of a national responsible ownership campaign, the White House wants to encourage the development of technology improving safe use and storage of guns. The plan also directs the Consumer Product Safety Commission to assess the adequacy of current safety standards for gun locks and safes.

"We don't benefit from ignorance," Obama said. "We don't benefit from not knowing the science of this epidemic of violence."

[Slate]

So, you've gotten yourself a flu shot. Good thinking, since this flu season is especially rough. A shot's not always going to save you--even the best batches are only about 70 percent effective--but there's a simple way to improve your odds: exercise.

The strength of a flu shot depends on how many antibodies it helps develop, which varies from person to person. But people in one group, the physically fit, generally have a better response to the shots, and thus a reduced chance of catching the bug every winter. Even the elderly, who usually don't respond very well to inoculation, improved their odds when they exercised more often, the New York Times points out. And a single workout after getting the shot resulted in twice the response from antibodies, according to one study.

How that translates into what an inoculated or to-be-inoculated person should do is a little murkier. If you're doing aerobic exercise, 90 minutes after the shot seems to be the best amount of time. Another study found that weight-lifting before being vaccinated would help, too, but should be done for about 20 minutes, lifting with the arm that's getting the shot.

That conflicting advice probably tells you how much we know about the exercise-antibody connection. It's still early in studies, but some moderate exercise on the day you get your flu shot probably won't hurt, and could even give you a little help.

Just, you know, go ahead and wash your hands anyway.

[New York Times]

Call it an instance of science fiction begetting science fiction. Physicist Adam Weigold wants to build a laser weapon that he believes might change the face of warfare should the U.S. find itself tangling militarily with a certain people's republic across the Pacific at some point in the near future. And to fund the research for said weapon, Weigold is releasing a science fiction novel about--wait for it--the U.S. tangling militarily with a certain people's republic across the Pacific in the near future.

Dragon Empire, set in 2025, is a creative telling of the real-world impact that various technologies--including hypersonic missiles, satellite weapons, drones, and stealth aircraft--would likely have on a future war between two modern military powers like China and the United States. But beyond that, Weigold is funneling the book's proceeds into his defense startup Lightning Gun Inc. which aims to produce a laser weapon that can swat guided missiles and other electronically-augmented weapons from the sky--and thus change the playing field for modern warfare.

How? Well, as Weigold told TechNewsDaily, guided missiles and bombs are a huge battlefield technology piece. Without them, militaries would have to completely shift their strategies and tactics. And Weigold thinks the way to do this is with a defensive laser EMP weapon capable of knocking out guidance systems aboard incoming munitions. All Lightning Gun has to do now is succeed where everyone who has tried before has failed.

The idea behind laser electromagnetic pulse weapons is pretty simple. A high-powered laser can strip electrons from air molecules and create an ionized ball of charged plasma in the sky. Pulsing said laser can create a kind of charged ripple from this effect--in other words, an EMP. If the EMP is generate close enough and powerfully enough in the path of an incoming electronically guided munition, its electronics will be fried. No more guidance.

But as with all laser weapons, there are complications here. For one, high-energy lasers are a huge power suck with lots of delicate components--not exactly ideal for a military that likes to be light on its feet and pack equipment that can take a beating. Then, lasers are finicky. Everything from humidity to clouds to air pressure can alter a laser's beam path and intensity. As the DoD can attest, you can spend billions on a laser weapon and still end up with nothing.

Weigold and Lightning Gun claim to have solutions on the drawing board, and if the company can raise something like half a million dollars to get experiments set up it could possibly ask the DoD to help cover the rest of its funding needs, which are roughly $2 million (Weigold is only looking to raise $20,000 of that from his book). If he can do that, he thinks he can produce a weapon in three to four years.

That would be pretty amazing turnaround for a laser weapons program, and it's not completely unfeasible. Laser weapons, for all of their impracticalities, are quite real. Germany's Rheinmetall Defense recently blasted two drones out of the sky from over a mile away with its new 50-kilowatt laser system, and everyone from the U.S. Navy to the American Missile Defense Agency is toying with laser tech these days. The real question is whether they can have the impact Weigold imagines. Guided missiles are a threat, yes, but so are ballistic ones--including the one U.S. Pacific planners are most worried about, the so-called DF-21 "carrier-killer." And if there's one thing we know about arms races, it's that for every defensive countermeasure you can dream up the enemy can generally think up a way around it.

[TechNewsDaily]

The increasingly vast suite of surveillance tools available to state authorities has certainly given privacy advocates something to bristle at. In an exhibition launching this week, NYC-based artist Adam Harvey and fashion designer Johanna Bloomfield are demonstrating fashion's potential to thwart surveillance by state actors via accessories like a heat-cloaking anti-drone hoodie and scarf.

The exhibition will show off several garments designed to either stymie or protect against various privacy-probing surveillance technologies, including a shirt with an X-ray-deflecting patch over the heart, an "off pocket" that zeroes out your phone's signal when it's inside, and the aforementioned hoodie and scarf, both engineered to conceal the body's thermal signature that can be picked up by the IR sensors built into many surveillance cameras and drones.

Though both Harvey and Bloomfield are NYC-based, the exhibit will show in London--appropriate considering London's legion of public surveillance cameras. If you're local, it runs January 18 through the end of the month. Details via the link below.

[Adam Harvey]

Facebook just let loose with a new update to the Messenger app for iPhone, which until now was restricted to text messaging, sort of like AOL Instant Messenger or GChat. Now it's something totally different: it's a Skype competitor, except you know all of your friends already use it.

The new feature lets you make phone calls using VoIP, with either a Wi-Fi connection or over your phone's 3G/4G connection, for free. Yep, Skype can already do this, but there's a very good chance more people you know use Facebook than Skype--the Facebook branding and built-in network of people could mean a boost for VoIP like it's never seen before. The only downside might be that calling someone over Messenger doesn't trigger your phone's ringer--instead, it pops up with a notification, just like you've gotten an email or text message.

This also, critically, is a major step backwards for the wireless carriers like Verizon and AT&T, who have been wildly overcharging for voice service and text messaging for, well, pretty much ever. But if you can text by using data--like on iMessage, or BlackBerry Messenger, or GChat or Facebook Chat--and now make phone calls with Facebook? That's a huge knock for the carriers, who could find themselves turning quickly into mere flat-rate data providers. The way you pay Verizon or Comcast or Time Warner for your home internet, that could well be the way you pay for your phone service in the near future. Who needs minutes?

Messenger is available in the App Store for iPhone now, for free. No word on an Android or Windows Phone version yet.

News of impending fatherhood affects men in different ways. Some guys pump their fists. Others light cigars. A few flee. When 33-year-old Colin Furze learned that his girlfriend was pregnant, he channeled his paternal excitement into building the world's fastest baby stroller. The twin-exhaust, 10-horsepower, gasoline-fueled pram can accelerate to speeds nearly fast enough for the highway in less than 30 seconds.

Furze, a plumber in Stamford, England, rode BMX bikes as a kid and missed the adrenaline rush as an adult. So in his twenties, he sought new thrills. "For some reason, I thought building a nice big fire was the answer," he says of his first project. Furze's 50,000-square-foot inferno, which he lit by launching a rocket into a mountain of wood, earned him a spot in the 2006 Guinness World Records book. Once Furze saw his name in print, he was addicted. Every two years he strives for a new mark. He holds the record for the fastest mobility scooter and, until recently, the world's longest bike. 2012 became the year of the stroller.

The build began with a baby carriage that Furze and his girlfriend, Charlotte, bought. He carefully measured every piece to construct a motorized look-alike. Thanks to a previous experiment, Furze had a steel roll cage lying around, which he cut and welded into the new stroller's skeleton.

Accelerating and braking via foot pedals could send Furze off course on rough roads, so he set all controls into a handlebar (see "How It Works," below) and built a stable platform for the driver to stand on. His first test-drive melted a set of skateboard wheels he'd attached to the platform. "It was quite pathetic," Furze says. A few days later, he tried again with plastic caster wheels; that time, road vibration rattled his feet numb. Furze eventually achieved a cushy ride with thick tires from an old mobility scooter.

His son, Jake, was born in September 2012, and a month later Furze cleared 50 mph while riding his stroller on a nearby drag strip-the first world record of its kind. He's quick to note that he has no intention of putting Jake in the speeding carriage. But that hasn't stopped him from spooking onlookers with a convincing stand-in: a baby doll wrapped patriotically in a Union Jack.

(Get the specifics of the project and a video on the next page)

MAD MAX STROLLER

Time: 4 Weeks
Cost: $750

CONTROLS

The stroller's four-stroke, 125-cubic-centimeter engine was meant for a motorbike. But Furze planned to stand, not sit, so he couldn't use the built-in pedals. Instead, he positioned the controls within reach of his hands. Two motorbike levers beneath the stroller's handlebar manipulate the brake and accelerator. Four buttons on a crossbar, meanwhile, allow Furze to quickly shift gears and turn the engine off and on.

STEERING

He can make minor steering adjustments, although not full turns, by twisting a handlebar linked to two bicycle brake cables. Each cable runs through the carriage's frame and tugs at one side of the pram's single front wheel.

HANDLING

Furze welded a quarter-inch-thick steel plate to the frame's base to give his stroller a lower center of gravity and more stability at high speeds. Yet he won't be using the pram to commute to plumbing jobs around town. "A little [stretch of] bumpy road, and it would throw you off," he says.

AESTHETICS

Furze cut and bent several aluminum panels into the shape of a stroller canopy. He planned to drape cloth around them in a play for realism, but in the end he stuck with rough, unadorned metal. "It looks a bit more Mad Max," he says.

WARNING: We review all our projects before publishing them, but ultimately your safety is your responsibility. Always wear protective gear, take proper safety precautions, and follow all laws and regulations.

After smoke was found pouring into one of its Boeing 787 "Dreamliner" planes yesterday, forcing an emergency landing, Japan's All Nippon Airways grounded its entire fleet of 787s. Japan's Transport Ministry referred to this as a "major incident." Today, the Federal Aviation Administration has decided to ground all 787s in the US--that'd be six of them, all operated by United. The FAA had already begun a full-scale investigation into the safety of the much-maligned 787, which has had more than its share of issues since introduction, but this is a huge move. The problem seems to be with the plane's lithium ion batteries. We'll let you know more as soon as we know. [via The Verge]

The evening of January 5, 2005, was dry and cool in Graniteville, South Carolina. At 6:10, a 12-car Norfolk Southern freight train pulled up to the Avondale Mills textile plant, and Jim Thornton, a conductor with 18 years' experience, climbed down from the locomotive to open a switch and let the train roll onto a siding. It was getting close to the hour by which, according to law, the crew had to quit for the day and rest. After the workers had shut down the train, Thornton called a taxi to take him, the engineer, and the brakeman to a nearby motel. It never occurred to him that, for the first time in his life, he'd failed to check the position of a switch that he'd opened. All he thought, as the crew piled into the taxi was, "Lord, mission accomplished."

Seven hours later, a second Norfolk Southern freight train-two locomotives, 25 loaded cars, and 17 empties-approached Graniteville at 49 miles an hour. The engineer expected to pass through at full speed. Instead, the open switch shot him onto the siding. He saw the parked train and tried to stop, but it was hopeless. Both locomotives and the first 16 cars of his train derailed; the engineer was killed. Three of the cars contained chlorine, a common industrial chemical; one of them sheared open.

A dense white cloud of chlorine gas billowed through Graniteville. At 2:40 in the morning, police rousted 5,400 people from their beds and evacuated them. Eight more died; 72 sickened. The disaster helped push the Avondale Mills plant, which had been making cloth in Graniteville for 161 years, out of business. Four thousand people, some of them fifth-generation Avondale employees, lost their jobs. Seven years after the wreck, people in Graniteville are still sick.

Trains carry 40 percent of America's freight as well as 650 million passengers a year, and in general, their safety record is good and getting better. Most of the 2,000 accidents a year are minor. But when trains collide or derail, the results can be spectacularly ugly. Last June, two Union Pacific trains somehow ended up on the same Oklahoma track and collided head-on with such force that the locomotives almost fused. Three crewmembers died. Three weeks later, 17 cars of a 98-car Norfolk Southern train went off the rails in Columbus, Ohio, busting open three cars of denatured alcohol and igniting a fire that forced the evacuation of about 100 people. A CSX coal train jumped the track in Ellicott City, Maryland, in August; six of its 21 cars tumbled into a parking lot, killing two young women bystanders. In November, a Union Pacific train plowed into a Veterans Day parade float in Midland, Texas, killing four. Later that month, a CSX train derailed on a bridge near Philadelphia International Airport, tearing open a tanker filled with 25,000 gallons of vinyl chloride and sending 71 people to the hospital.

Although the railroad keeps our 21st-century economy running, it's essentially a 19th-century technology.Most worrisome are the 75,000 carloads of breathable poisons that trundle around the nation's tracks every year at speeds of up to 50 miles an hour. The two most common are chlorine-the Graniteville chemical-and anhydrous ammonia, both of which can kill in particularly grisly ways if inhaled. Graniteville was the country's worst rail accident involving breathable toxins, but there have been two others in the first decade of the 21st century: Minot, North Dakota, in 2002 (anhydrous ammonia; one dead), and Macdona, Texas, in 2004 (chlorine; three dead). At Minot, the problem was poorly inspected rails and inadequate tank-car construction, but at Macdona, the cause was as simple as at Graniteville: The engineer failed to notice a slow-down signal and blew past.
Could happen to anybody.

As bad as these accidents were, they could someday be remembered the way we recall the 1993 World Trade Center bombing-as a harbinger of worse to come. Imagine a railcar full of chlorine bursting on the CSX tracks less than a mile away from a big public event on the Capitol Mall in Washington, D.C.-an inauguration, say, or a concert. The resulting cloud could kill 100,000 people. Al Qaeda might do it, but it's more likely that a $55,000-a-year engineer, in the 10th hour of his shift, would simply nod off at the controls. Human factors cause more than a third of all rail accidents.

Although the railroad keeps our 21st-century economy running, it's essentially a 19th-century technology. Rail operators have known for decades that technological fixes could prevent rail disasters caused by the kind of human errors committed at Macdona and Graniteville, but they have been dragging their feet because those fixes are expensive and complicated. Congress is now making them get it done. But the railroads could also cheaply and humanely achieve big safety leaps simply by improving the working conditions of engineers-something they're even less enthusiastic about doing. />

Forty years ago, the National Transportation Safety Board began urging railroads to design a way for a train to stop itself if the engineer "loses situational awareness"-that is, has a heart attack, falls asleep, gets distracted, or makes an all-too-human mistake. It wasn't like NTSB was asking railroads to find a cure for cancer. As early as the 1920s, the Santa Fe rail line between Kinsley and Dodge City, Kansas, used a rudimentary system to stop a train if it passed a red signal. In the mid-1980s, in the Minnesota iron range, Burlington Northern successfully operated the first GPS-based system to stop a train automatically if the engineer made a mistake; it dropped it within the decade, to save money.

Railroaders call such technology-systems that slow or stop a train without human intervention when the engineer makes a dangerous mistake-positive train control (PTC). The modern version requires the train to be "aware" both of what it is doing and what is happening on the tracks ahead, using a combination of data radios, GPS, and cellular networks. If a discrepancy arises-a switch is open that shouldn't be or the locomotive is passing a red signal-and the engineer doesn't respond, the system takes control of the train, applying the air-brakes and shutting down the locomotive.

In 1990, the NTSB put positive train control on its list of most-wanted transportation-safety improvements. The NTSB, though, has no regulatory authority, so the five U.S. Class I freight railroads-Burlington-Northern Santa Fe, CSX, Union Pacific, Norfolk Southern, and Kansas City Southern, all of which have annual operating revenues of hundreds of millions of dollars-simply ignored the agency. Only Amtrak responded, installing a type of positive train control on its Northeast Corridor trains in 2000 and a different version on some of its trains in the Midwest a year later. The Federal Railroad Administration, the railroads' regulator, had the power to make the Class I's fall in line behind Amtrak, but instead, the agency agreed with the Class I's: Positive train control was too expensive.

In 2007, Congress finally got involved, passing a law mandating positive train control, but President George W. Bush refused to sign it. Then came Chatsworth.

As a passenger-rail engineer, Robert Sanchez was, quite literally, a train wreck waiting to happen. Clinically obese, with high blood pressure, enlarged heart valves, diabetes, and HIV, he may also have had sleep apnea, which can leave sufferers perpetually sleep-deprived. To make matters worse, his work schedule at Metrolink, the commuter rail service for the Los Angeles basin, seemed designed to leave a man exhausted. Sanchez started at six in the morning, drove trains until 9:30 in the morning, then started again at two in the afternoon and worked until nine at night-a 15-hour split shift.

Yet the issue on September 12, 2008, was neither his health nor his exhaustion. As he drove his three-car train loaded with passengers west from Chatsworth, Sanchez was busy swapping text messages with a teenage train buff about the supercool world of locomotives-a huge violation of company policy. Four days before, he'd had this text exchange with the teenager, whom the NTSB calls "Person A":

Sanchez: Yea....but I'm REALLY looking forward to getting you in the cab and showing you how to run a locomotive.

Person A: Omg dude me too. Running a locomotive. Having all of that in the palms of my hands. Its a great feeling. And ill do it so good from all my practice on the simulator.
Sanchez: I'm gonna do all the radio talkin'...ur gonna run the locomotive & I'm gonna tell u how to do it.

Later texts suggest that Sanchez had indeed illegally let the teenager operate the train-two days before the accident-with passengers aboard.

On the afternoon of September 12, in the last 69 minutes of his life, Sanchez exchanged 35 text messages with the teenager. Focused on his smartphone, he missed a red signal that should have held him back from a single track shared by freight lines. At 4:22 p.m., the engineer of a westbound Union Pacific train looked up and saw Sanchez's train coming at him at a combined speed of 80 miles an hour. The engineer hit his air brakes. Sanchez, texting until 22 seconds before impact, never touched his.

The collision drove Sanchez's locomotive 52 feet into the first passenger rail car, killing Sanchez and all 22 people in the car. Two more passengers also died; 101 were injured. On the freight train, the engineer, conductor, and brakeman somehow all survived.

Television crews arrived fast, and the Chatsworth crash became, for the issue of rail safety, what 9/11 was to aviation security. It escaped nobody's attention that had positive train control been in place at Chatsworth, Sanchez never would have reached the freight track; the system would have stopped his train at the red signal. Congress hastily revived the 2007 mandate and folded it into the Rail Safety Improvement Act of 2008, which flew through Congress in just 34 days. The president signed it late at night with no ceremony. The nation's railroads were given until 2015 to install positive train control on the 70,000 miles of track on which passengers or toxic-by-inhalation chemicals moved. In the emotional aftermath of Chatsworth, neither the railroads nor the Federal Railroad Administration objected.

That came later. />

If I lose my iPhone, Apple's Find My iPhone feature will pinpoint its location anywhere in the world within a few feet. Railroads, though, have only a very rough idea, at any given moment, of where their 18,000-ton freight trains are and what they're doing. Although each railroad operates vast control rooms that look like they belong on the set of Dr. Strangelove-with enormous electronic schematics of their tracks displayed across the walls-the information that controllers receive is amazingly crude.

Railroads have only a very rough idea, at any given moment, of where their 18,000-ton freight trains are and what they're doing.First, about half the nation's trackage is "dark territory," devoid of signals and invisible to controllers. Out there, it's 1850. Conductors operate by written instructions and their watches, stopping their trains and climbing down to open and close switches by throwing big iron bars. While it's true that the vast majority of freight traffic and all passenger traffic travels on tracks with signals, even there, controllers can't see their trains the way I can "see" my lost iPhone. They know only when a train has passed a given point-a switch or a signal that is wired into the grid. Those points are anywhere from one and a half to three miles apart, creating "blocks" of track. Controllers know when a train's locomotive has entered or left a block, but not how fast it's moving. They can talk to engineers by radio, but if they notice that a train has passed a red signal, all they can do is shout into the radio, and often they're too late even for that.

Positive train control, as conceived today, is intended not to replace control rooms and signals but to supplement them. The railroad farthest along in post-Chatsworth implementation is, not surprisingly, Metrolink, which lost 24 passengers and an engineer on September 12, 2008.

At six o'clock one recent morning, Darrell Maxey, who's in charge of building Metrolink's PTC system, picked me up at my hotel at the far eastern end of the L.A. basin and drove immediately to a doughnut shop. In his mid-fifties, with a bristle-gray moustache and glasses, Maxey exudes a Midwestern-style bemusement at the breathtaking convolutions of his job. He's an old railroader, a systems engineer by training, but installing positive train control at Metrolink is making him an IT guy as well. "This is the most complicated project I've ever worked on," he said. "Two, three hundred pages of documents at a time! For a guy who's made his career piecing railroad systems together, this is heaven."

We drove to Metrolink's maintenance yard, a sprawling, sun-blasted expanse of concrete where Maxey issued me a hard hat and reflective vest, hoisted himself aboard one of Metrolink's test trains' passenger cars, and ushered me up after him. Slumped on every seat and scattered across the floor were hefty sandbags, simulating the weight of a full load of passengers. We walked forward, and Maxey opened a door to the back of the locomotive. We threaded our way through the length of its interior, which felt like the engine room of a U-boat: hot, noisy, and diesel-pungent. We emerged into the sunlit engineer's cab, and Maxey motioned me into the engineer's seat.

Transforming railroads from a 19th- to a 21st-century mode of transportation means making the train itself responsible for its actions. Were I this train's engineer, I'd start my day by downloading into the train's onboard computer a program about that day's run: the weight and length of the train, as well as everything the system needs to know about the upcoming length of track, such as speed restrictions, grade, curves, signals, switches, and stops. If I were using track owned by other railroads, I'd download a separate program for each, because every railroad has its own way of signaling and communicating. Another download would alert me to temporary issues, such as workmen on the tracks. I could watch these downloads on an LCD screen mounted on the engine's dash; after that, I wouldn't have to look at the screen again, and, in fact, Metrolink is hoping I won't. It wants my eyes straight ahead.

As I start down the track, the onboard computer is constantly comparing the train's progress to the downloaded programs. Doing this means communicating wirelessly with every switch and signal along the way. If I fail to slow when I should or if the computer thinks I'm about to run a red signal, the system warns me. If I don't respond, it applies the air brakes and shuts down the train. It is designed never to let my locomotive pass a red signal, so it is constantly looking six miles-three signals-ahead. It measures the speed and weight of the train along with the steepness of the grade. A heavy train going downhill will get an earlier warning than a light train going uphill, but as a rule of thumb, it takes about a mile, or 90 seconds, to stop a three-car Metrolink train.

The onboard electronics that make positive train control work on Metrolink's test train are stuffed into a tiny compartment down in the nose of the locomotive, where, were this a freight train, the engineer's toilet might be. I peered in at an incomprehensible tangle of wires surrounding a rank of plastic and aluminum boxes: a cellular modem, data radios that communicate with signals and the control room, a train management computer containing the downloads, and a big orange "black box" that the NTSB looks for after a crash. It goes by the polite euphemism "event recorder."

For an industry that operates in much of the country as though it's in a western, this looked like a jump to Prometheus. We made our way back through the locomotive and stepped off, and Maxey pointed to the new adornments on the locomotive's roof. Up where a light and maybe a radio antenna used to sit, a forest of aerials sprouted: two 220MHz antennas for the data radios, two cellular antennas for redundancy, a GPS antenna, and the Wi-Fi antenna through which the train downloads its instructions prior to departure. "What all this is for, basically, is to make it impossible for you to speed or run a red light," Maxey said. It sounded simple. />

To disabuse me of that notion, Maxey drove us to a wayside signal being outfitted for positive train control. Until now, such signals were nothing but big traffic lights-red, yellow, green-on steel posts. "Dumb" is the technical term; all they could do was change color. Maxey took a key from his pocket and unlocked the steel door on a small, windowless concrete shed that stood beside the signal. "Each of these has its own IP address now," he said. "As the train goes along, it pings each signal, and if it doesn't get a response, it shuts down the train because the unresponsive signal might be red." He opened the shed door to a blast of cold air. "Got to be air-conditioned," he said. "Some little switch houses are 170 degrees inside." The shed was as stuffed with electronic gear as the nose of the train. "This all has to stand up to vibration, dirt, and rain," Maxey said, and in case the air-conditioning fails, "it's got to spec to 70 degrees Celsius, which is 158 Fahrenheit."

Metrolink has 217 such wayside signals; modifying each one will cost $50,000. "The Class I's have as many as 38,000 of these," Maxey said, "which helps explain their lack of enthusiasm."

Metrolink used to be an organization of railroaders-men accustomed to mechanical challenges wrought in iron. But with the move to positive train control, the railroad is acquiring a corps of IT types; they fill one of the biggest buildings I've ever seen. It's an old General Dynamics cruise-missile factory a quarter-mile long that Metrolink slicked up with a big glass atrium, potted trees, and interior floor-to-ceiling windows. As Maxey walked me through, he kept buttonholing people and asking them to describe their résumés. I met electrical engineers, systems engineers, IT specialists, software developers. "See?" Maxey said. "See who we are here? This is the new face of railroading. Building the system is not the only challenge; it's maintaining it for years to come. We're just incredibly excited."

By "we," Maxey meant Metrolink. Maxey and his colleagues are convinced that positive train control will put an end to the kind of engineer-caused disasters that occurred at Graniteville and Chatsworth. The major freight railroads, though, sound like 15-year-old boys being asked to mow the lawn.

The Class I's knew better than to object when Congress was passing the law mandating positive train control in the wake of the Chatsworth wreck. Bellyaching at such an emotional moment would have looked insensitive. Not a single interest group took a position on the law as it was being debated in 2008. Three years later, though, when four Republican senators introduced a bill to delay the 2015 deadline for implementing positive train control, railroads suddenly became interested in congressional politics; they gave a total of almost $3.6 million to all but four members of the Senate, including $16,500 to Diane Feinstein and $47,800 to Barbara Boxer, two of the biggest proponents of positive train control when the original law was passed in 2008. Despite the shower of money, the bill to extend the deadline died without a vote, but that doesn't mean the railroads have given up the fight. They'll tell anybody who will listen that positive train control will cost too much, isn't worth the money, places an undue burden on railroads and their customers, will make rail shipping less, instead of more, efficient, and is being forced upon them too quickly.

The Federal Railroad Administration says that building positive train control could end up costing $10 billion. Even at a time when the Class I's are doing well-profit margins ran from 17 to 45 percent last year-$10 billion is a lot of money, roughly equal to everything the railroad industry spent on buildings and equipment in 2010. Maintaining the intricate system will cost the industry an additional $850 million a year.

For that, the railroads will get a system that would have prevented the marquee Chatsworth, Red Oak, and Graniteville wrecks but would do nothing to prevent 98 percent of train accidents, including the types that cause the most deaths: knuckleheads walking on tracks or trying to zip across road crossings ahead of speeding trains.

And even that 2 percent of collisions will be prevented only if the system works well. The GPS used in positive train control doesn't work in tunnels or urban canyons. And the cellular backup will have to have a reliability rate of one failure in every hundred million tries. "Compare that to dropped cellphone calls," says George Bibel, author of Train Wreck: The Forensics of Rail Disasters.

The industry is going to have to acquire 58,000 digital radios of a type never built before, and because trains travel on other railroads' tracks, each radio must be able to communicate with those of every other railroad. Several railroads, particularly in big cities, are having trouble getting enough bandwidth in the crowded radio spectrum to launch the system. Ask a railroader to describe the technical challenges of implementing positive train control, and you can expect to listen for a while.

In 1977, Mother Jones magazine broke the story that the Ford Motor Company had concluded, when its Pinto was blowing up with frightening regularity, that it was cheaper to pay the widows and orphans than it was to recall the cars and fix the problem. That cold-blooded cost-benefit analysis caused a scandal. Yet for the past three decades, since President Ronald Reagan ordered cabinet departments and independent agencies to conduct cost-benefit analyses before issuing new regulations, such computations have been national policy.

In the case of positive train control, the Federal Railroad Administration needed to weigh the benefits of avoiding the tiny category of accidents that the system would prevent against the projected costs. Totaling up the cost of wrecked equipment was fairly easy-and so, it turns out, was computing the value of the human lives that positive train control would save. The Federal Railroad Administration's parent agency, the Department of Transportation, had already done the math, concluding in 2008 that "the best present estimate of the economic value of preventing a human fatality is $5.8 million."

When the Federal Railroad Administration counted the average seven annual deaths and 22 injuries positive train control would prevent in a year and added the cost of the property damage and evacuations that positive train control would obviate, it concluded that positive train control would save the industry just $90 million a year. That's just a tenth of the system's annual maintenance costs, and a wretched cost-benefit prospect-unless you or somebody you love is one of the seven people saved.

Every freight railroad to which I spoke, as well as the industry group the Association of American Railroads, inveighed against being forced to implement positive train control, especially by the end of 2015. Some even claim it will make their lines less safe. In an e-mail, Kansas City Southern warned me darkly: "The inflexibility of the statutory mandate and its deadline is likely to result in previously unforeseen operating consequences if not modified"; Union Pacific told me it would rather spend the money on "proven safety alternatives"; and Luther Diggs of Philadelphia's commuter line SEPTA told the local Inquirer, "We won't have one bridge or substation or station until we get this paid for. It just means we don't do a lot of other things." In other words, if a train rolls off a poorly maintained track, blame Congress for rushing the railroads to implement positive train control.

But it's hard to sympathize with the railroads. The 2 percent of accidents that PTC could prevent includes the most catastrophic possibilities-the black-swan big ones, like tankers of chlorine bursting open within a mile of the National Mall. Call it the tyranny of technology in a litigious age: If a technological fix that may save lives is available, you're pretty well obliged to apply it./>

Of course, there also exists a very cheap way to help prevent train crashes: Let engineers sleep. The Federal Railroad Administration sets limits on how many consecutive hours an engineer can work but nonetheless lets railroads treat freight engineers, in the words of one, "like plug-in flashlights." Engineers never know exactly when they're going to be called to work, so they never know when they should sleep. A 56-year-old Midwestern engineer for a Class I, who asked me to withhold his name because he would be fired for talking to a reporter, described a typical, Catch-22 dialogue with his employer: "‘When do you want me to work?' ‘I don't know; I'll call you.' ‘Okay, should I go to bed now or stay up and watch TV?' ‘That's up to you; but I want you to be rested.' "

"You never know when you're going to get a day off," he told me. "There's no lunch break. You have to eat at the controls. If you have to go to the bathroom, you wait until you're going up a long hill and you know the train isn't going to run away, and you open the back door and you pee off the walkway. You're in a mode where you're at 20 percent of your abilities. I've been dreaming at the switch."

He and his union-the Brotherhood of Locomotive Engineers-have mixed feelings about positive train control, though, because they worry that it could make it easier for Class I freight lines to further reduce the size of a train's crew. "In 1974, we had five guys on a crew: fireman, head brakeman, an engineer in the cab, and, in the caboose, a conductor and a rear brakeman," he said. "Now we have two": an engineer and a conductor in the cab. What positive train control will do, he fears, is "eliminate the conductor. If we have this PTC, there's no reason we can't run a train with one man."

Much as they revile the 2015 deadline for implementing positive train control, neither the individual railroads, the Association of American Railroads, nor the Federal Railroad Administration want to discuss adjusting working conditions as a means of improving safety. "You're going down a whole path that is about labor negotiations and not about PTC," said Union Pacific's Jeff Young. "That's not what I'm here to talk about."

In general, companies would much rather buy equipment than meddle with their employees' working conditions. Capital investment is deductible, predictable, and finite. Start making concessions to employees, and it can go anywhere-and the company will be living with the changes forever. For its part, Congress would much rather order companies to buy stuff than to poke its nose into employee relations. Every dollar the railroads spend on positive train control boosts the economy. 

The Association sidestepped the issue of unpredictable sleep schedules in a written response, saying only that positive train control "was never intended to solve the problem of a locomotive engineer falling asleep," an odd comment, as that is a big part of what it is intended to do. "The individual employee is responsible for managing their personal sleep and rest habits within the federally mandated rest periods." In other words, if engineers are sleepy, blame them.

The Federal Railroad Administration says it lacks the authority to order railroads to give engineers regular hours (the way things are done, say, in Britain). Only Congress can do that, the FRA's communication director Kevin Thompson told me. What the agency does in the meantime, Thompson said, is offer engineers "a website with techniques and tips to better manage their sleep issues."

Now that they've tried and failed to get Congress to push back the 2015 deadline, the railroads are grudgingly committing to it. "You can argue it so long," said Patti Reilly of the Association of American Railroads. "At a certain point, we want to do it, we want to do it well, and we want to do it so it doesn't negatively affect our operation." But by now they've spent so long fighting the 2015 deadline that it's hard to see how they'll meet it. Beyond 2015? Between the railroads' institutional resistance and the technical challenges they face, don't hold your breath.

On the other hand, given the lethality of the chemicals trundling around the nation's rail lines 24/7 and the exhausted state of the engineers hauling them, maybe you should.

Dan Baum's book Gun Guys: A Road Trip comes out in March. He lives in Boulder, Colorado. This article originally appeared in the February 2013 issue of the magazine.

When moving terabytes of data from one computer to another, cut out the external drive-an expensive, sluggish middle man-by cutting up an Ethernet cable. Rearranging the small internal wires on one end allows near-instant data transfer between computers via their network cards. Here's how to do it.

Time: 10 minutes
Cost: About $10

1) Cut off one end of an Ethernet cable, strip an inch of its outer sheath, and untwist the four pairs of colored wires inside.

2) Rearrange the wires in this order: green-striped/green, orange-striped/blue, blue-striped/orange, brown-striped/brown. (This links one computer's outputs to the other computer's inputs, and vice-versa.)

3) Evenly insert the wires into a new cable head (clip facing down) and secure them in place with an RJ45 crimp tool. Connect two computers with your new crossover cable, square away your sharing permissions, and start moving mountains of data.

For instructions on changing a computer's sharing permissions (to allow crossover cable file transfers), download this PDF.

The dawn of agriculture is often cited as the beginning of modern civilization, since it allowed people to live for a long time in one place and build large societies, but one thing it didn't change was our species' propensity for migration: as of 2010, more than 215 million people--about 3 percent of the world's population--were living in countries outside of their own.

Using data from the World Bank, information designer Carlo Zapponi created an elegant visualization showing the flow of people to and from every country in the world. Line thickness represents the relative proportion of people coming from, or going to, each country.

Check out the visualization here.

Just how far has Curiosity traveled since landing on Mars in August? We could tell you, but it turns out you can see for yourself. Curiosity's tracks are visible from Mars orbit, and new images from the HiRISE camera aboard the Mars Reconnaissance Orbiter show the wending path of the rolling space lab from its touchdown site at "Bradbury Landing" almost all the way to its current position in "Yellowknife Bay."

The newly released images are actually a couple of weeks old, but it doesn't much matter for our purposes. Curiosity is now rolling on lighter-toned, harder ground on which its tracks aren't easily visible anyhow. But for the first 100 or so Sols (that's a Martian day) Curiosity was making serious tracks. In the image above, Bradbury Landing is basically the dark smudge at left. The tracks weave across the lower half of the image over to the boundary where you can see the terrain changing. That's where the rover is now, and it's here we lose visual on the tracks.

A closeup of the landing site below was taken back on September 8 when Curiosity hadn't yet made it quite so far. You can clearly see the rover at below and right of center.

Curiosity is currently exploring Yellowknife Bay and preparing to drill into its first rock. Oh, and in case you were curious, with movements in the last day or so discounted Curiosity has traveled 2,312 feet from where it landed August 5.

[PhysOrg]

Reddit, the sometimes-controversial "front page of the internet," is a powerhouse for traffic and prestige--within the Reddit community, having stories listed on the front page (meaning, what you see when you go to Reddit.com) is a major credibility boost, and for content creators (writers, photographers, artists), a front-page Reddit link can result in hundreds of thousands of hits.

So there's a lot to gain in figuring out Reddit's algorithm, which is used to decide what gets on the front page. And Reddit has been harder to trick than other, similar sites, most notably the old version of Digg, which was notoriously easy to fool. (I used to work for Gizmodo, one of Gawker Media's sites, and we had a system to get just about any story on the front page of Digg with a single email. It was shifty.) But now a new blog post has laid out the algorithm, along with some tips and explanation for what gets on the front page and why.

It's not going to let anyone game Reddit's system, really, but it's definitely helpful for people wanting more exposure for their links. Notable conclusions include that new links are weighted more heavily than older stories, controversial stories are not as successful (Reddit has both negative and positive votes, which can cancel each other out), and the first few votes are the most important. So, the ideal Reddit post might be a new, non-controversial picture that accrues a few crucial votes very quickly. Easy! So, um, can I get on the front page please? Here's a good picture:

[Amix]

Our friends over at Popular Photography focused the full brunt of their expertise on Sony's 24.3MP Cyber-shot RX1, the world's first full-frame digital compact--basically, it's a DSLR the size of a compact (with a price higher than either). With a full-frame CMOS sensor, high pixel count and fast purpose-built lens, it impressed in the lab with extremely high overall image quality. It can also capture 14-bit RAW images, giving you more flexibility to control highlights and shadows. It's definitely one of the most exciting dream-cameras we've seen recently--head over to Pop Photo to read more about it.