Transport Engineering Quotes

If you are a pedestrian, you are not mechanical enough to be of priority to traffic engineers.

In literature, too, we admire prose in which a small and astutely arranged set of words has been constructed to carry a large consignment of ideas. 'We all have strength enough to bear the misfortunes of others,' writes La Rochefoucauld in an aphorism which transports us with an energy and exactitude comparable to that of Maillard bridge. The Swiss engineer reduces the number of supports just as the French writer compacts into a single line what lesser minds might have taken pages to express. We delight in complexity to which genius has lent an appearance of simplicity. (p 207)

A society sufficiently sophisticated to produce the internal combustion engine has not had the sophistication to develop cheap and efficient public transport?' ‘Yes, boss... it’s true. There’s hardly any buses, the trains are hopelessly underfunded, and hence the entire population is stuck in traffic

Now our world is at the present time firmly in the grip of a mechanical monster, whose head - if you want to call it that - is the World Engineer's Complex. That monster is opposed to us and can keep all too good a tab on us through every purchase we make with our credit numbers, every time we use the public transportation or eat a meal or rent a place to live.

After changing shape several times, the ball eventually turned into a huge face. It floated alongside the air-car. This time, time instead of sending him a mental message, the face spoke out aloud and the whole air-car vibrated with its intensity. “If you are foolish enough to renege on your contract, you will be severely punished. For your sake, I hope you wouldn’t do such a thing.” When Tarmy made no attempt to respond, the face turned and pressed itself against the millipede-free window. A moment later, Tarmy felt the fat slug entering his mind, the sign that the face was attempting to use its powers to obtain his response by other means. But as the slug dug deeper, Samantha’s cover stories began springing out of the corners of his mind. Instead of obtaining Tarmy’s agreement, all that the face saw was a burning army transporter surrounded by bodies. Undeterred, the face continued its assault. Samantha had anticipated that Tarmy might come up against an adept, so the mental images of death and destruction flowed unchecked. After failing to break Tarmy’s defences, the face removed the slug and tried reason. “You can’t win, Mr Tarleton, so why don’t you do yourself a favour and cooperate? It will be better for you in the long run. Now, where is the miniature pulse drive engine?” Tarmy realised why the millipedes hadn’t been allowed to attack. It was obvious that the Great Ones were hoping to retrieve the engine. When Tarmy didn’t respond, the face said, “I am prepared to overlook your desertion if you agree to tell us where the engine is and also honour your contract by showing us how to convert the engine into a bomb.

If you were transported 500 years back in time and told them about mobile phones, they would call you mad and kill you. Even if you are an engineer, you wouldn’t be able to prove to them that mobile phones are real. They only understand clay and fire. Today when people say they can see things that you can’t see, you call them mentally ill. Don’t disregard experiences of others no matter how different they are from yours. Space-Time is infinite. Even things you can’t imagine exist inside it.

The deep space transport uses a new type of propulsion system to send astronauts through space, called solar electric propulsion. The huge solar panels capture sunlight and convert it to electricity. This is used to strip away the electrons from a gas (like xenon), creating ions. An electric field then shoots these charged ions out one end of the engine, creating thrust. Unlike chemical engines, which can only fire for a few minutes, ion engines can slowly accelerate for months or even years.

In contrast to almost every major army in history, the Mongols traveled lightly, without a supply train. By waiting until the coldest months to make the desert crossing, men and horses required less water. Dew also formed during this season, thereby stimulating the growth of some grass that provided grazing for horses and attracted game that the men eagerly hunted for their own sustenance. Instead of transporting slow-moving siege engines and heavy equipment with them, the Mongols carried a faster-moving engineer corps that could build whatever was needed on the spot from available materials. When the Mongols came to the first trees after crossing the vast desert, they cut them down and made them into ladders, siege engines, and other instruments for their attack.

The next time you drive into a Walmart parking lot, pause for a second to note that this Walmart—like the more than five thousand other Walmarts across the country—costs taxpayers about $1 million in direct subsidies to the employees who don’t earn enough money to pay for an apartment, buy food, or get even the most basic health care for their children. In total, Walmart benefits from more than $7 billion in subsidies each year from taxpayers like you. Those “low, low prices” are made possible by low, low wages—and by the taxes you pay to keep those workers alive on their low, low pay. As I said earlier, I don’t think that anyone who works full-time should live in poverty. I also don’t think that bazillion-dollar companies like Walmart ought to funnel profits to shareholders while paying such low wages that taxpayers must pick up the ticket for their employees’ food, shelter, and medical care. I listen to right-wing loudmouths sound off about what an outrage welfare is and I think, “Yeah, it stinks that Walmart has been sucking up so much government assistance for so long.” But somehow I suspect that these guys aren’t talking about Walmart the Welfare Queen. Walmart isn’t alone. Every year, employers like retailers and fast-food outlets pay wages that are so low that the rest of America ponies up a collective $153 billion to subsidize their workers. That’s $153 billion every year. Anyone want to guess what we could do with that mountain of money? We could make every public college tuition-free and pay for preschool for every child—and still have tens of billions left over. We could almost double the amount we spend on services for veterans, such as disability, long-term care, and ending homelessness. We could double all federal research and development—everything: medical, scientific, engineering, climate science, behavioral health, chemistry, brain mapping, drug addiction, even defense research. Or we could more than double federal spending on transportation and water infrastructure—roads, bridges, airports, mass transit, dams and levees, water treatment plants, safe new water pipes. Yeah, the point I’m making is blindingly obvious. America could do a lot with the money taxpayers spend to keep afloat people who are working full-time but whose employers don’t pay a living wage. Of course, giant corporations know they have a sweet deal—and they plan to keep it, thank you very much. They have deployed armies of lobbyists and lawyers to fight off any efforts to give workers a chance to organize or fight for a higher wage. Giant corporations have used their mouthpiece, the national Chamber of Commerce, to oppose any increase in the minimum wage, calling it a “distraction” and a “cynical effort” to increase union membership. Lobbyists grow rich making sure that people like Gina don’t get paid more. The

the people who could author the mechanized death of our ghettos, the mass rape of private prisons, then engineer their own forgetting, must inevitably plunder much more. This is not a belief in prophecy but in the seductiveness of cheap gasoline. Once, the Dream’s parameters were caged by technology and by the limits of horsepower and wind. But the Dreamers have improved themselves, and the damming of seas for voltage, the extraction of coal, the transmuting of oil into food, have enabled an expansion in plunder with no known precedent. And this revolution has freed the Dreamers to plunder not just the bodies of humans but the body of the Earth itself. The Earth is not our creation. It has no respect for us. It has no use for us. And its vengeance is not the fire in the cities but the fire in the sky. Something more fierce than Marcus Garvey is riding on the whirlwind. Something more awful than all our African ancestors is rising with the seas. The two phenomena are known to each other. It was the cotton that passed through our chained hands that inaugurated this age. It is the flight from us that sent them sprawling into the subdivided woods. And the methods of transport through these new subdivisions, across the sprawl, is the automobile, the noose around the neck of the earth, and ultimately, the Dreamers themselves.

The principal reason for this limited mastery of materials was the energy constraint: for millennia our abilities to extract, process, and transport biomaterials and minerals were limited by the capacities of animate prime movers (human and animal muscles) aided by simple mechanical devices and by only slowly improving capabilities of the three ancient mechanical prime movers: sails, water wheels, and wind mills. Only the conversion of the chemical energy in fossil fuels to the inexpensive and universally deployable kinetic energy of mechanical prime movers (first by external combustion of coal to power steam engines, later by internal combustion of liquids and gases to energize gasoline and Diesel engines and, later still, gas turbines) brought a fundamental change and ushered in the second, rapidly ascending, phase of material consumption, an era further accelerated by generation of electricity and by the rise of commercial chemical syntheses producing an enormous variety of compounds ranging from fertilizers to plastics and drugs.

What this means in road (and bridge, and tunnel) building is not just obvious but as well documented as anything in transportation engineering: “If you build it, they will come.” If you build more lanes on the expressway, more cars and trucks will use it. If you’re lucky, congestion remains as bad as it was before you spent $50 million trying to relieve it; if you’re not, it gets worse.

Ireland, like Ukraine, is a largely rural country which suffers from its proximity to a more powerful industrialised neighbour. Ireland’s contribution to the history of tractors is the genius engineer Harry Ferguson, who was born in 1884, near Belfast. Ferguson was a clever and mischievous man, who also had a passion for aviation. It is said that he was the first man in Great Britain to build and fly his own aircraft in 1909. But he soon came to believe that improving efficiency of food production would be his unique service to mankind. Harry Ferguson’s first two-furrow plough was attached to the chassis of the Ford Model T car converted into a tractor, aptly named Eros. This plough was mounted on the rear of the tractor, and through ingenious use of balance springs it could be raised or lowered by the driver using a lever beside his seat. Ford, meanwhile, was developing its own tractors. The Ferguson design was more advanced, and made use of hydraulic linkage, but Ferguson knew that despite his engineering genius, he could not achieve his dream on his own. He needed a larger company to produce his design. So he made an informal agreement with Henry Ford, sealed only by a handshake. This Ford-Ferguson partnership gave to the world a new type of Fordson tractor far superior to any that had been known before, and the precursor of all modern-type tractors. However, this agreement by a handshake collapsed in 1947 when Henry Ford II took over the empire of his father, and started to produce a new Ford 8N tractor, using the Ferguson system. Ferguson’s open and cheerful nature was no match for the ruthless mentality of the American businessman. The matter was decided in court in 1951. Ferguson claimed $240 million, but was awarded only $9.25 million. Undaunted in spirit, Ferguson had a new idea. He approached the Standard Motor Company at Coventry with a plan, to adapt the Vanguard car for use as tractor. But this design had to be modified, because petrol was still rationed in the post-war period. The biggest challenge for Ferguson was the move from petrol-driven to diesel-driven engines and his success gave rise to the famous TE-20, of which more than half a million were built in the UK. Ferguson will be remembered for bringing together two great engineering stories of our time, the tractor and the family car, agriculture and transport, both of which have contributed so richly to the well-being of mankind.

London had had a subway system since 1863, but New York had not yet gone underground for at least two reasons. For one thing, New York was built on solid rock, and tunneling through the Manhattan schist presented enormous engineering obstacles. For another, during the years when “Boss” Tweed had the city in his grip, Tweed and his “ring” controlled the surface transportation lines and wanted no competition.

* Engineers have had to invent a new category for the commuter trains of Mumbai, whose Western Railway Line is the world's single most crowded public transport corridor. When fourteen or more people are standing per square meter - above 275 percent capacity - the train has attained "Super Dense Crush Load." In Mumbai, of course, this means people are actually sitting on the roof and hanging out the open doors.

Another inventor, J. B. McComber, representing the Chicago-Tower Spiral-Spring Ascension and Toboggan Transportation Company, proposed a tower with a height of 8,947 feet, nearly nine times the height of the Eiffel Tower, with a base one thousand feet in diameter sunk two thousand feet into the earth. Elevated rails would lead from the top of the tower all the way to New York, Boston, Baltimore, and other cities. Visitors ready to conclude their visit to the fair and daring enough to ride elevators to the top would then toboggan all the way back home. “As the cost of the tower and its slides is of secondary importance,” McComber noted, “I do not mention it here, but will furnish figures upon application.” A third proposal demanded even more courage from visitors. This inventor, who gave his initials as R. T. E., envisioned a tower four thousand feet tall from which he proposed to hang a two-thousand-foot cable of “best rubber.” Attached at the bottom end of this cable would be a car seating two hundred people. The car and its passengers would be shoved off a platform and fall without restraint to the end of the cable, where the car would snap back upward and continue bouncing until it came to a stop. The engineer urged that as a precaution the ground “be covered with eight feet of feather bedding.

The moonlight was still floating on the waters, when men, looking from numberless decks towards the east, were able to hail the dawn. There was a summer breeze blowing fair from the land. At a quarter before five a gun from the Britannia gave the signal to weigh. The air was obscured by the busy smoke of the engines, and it was hard to see how and whence due order would come; but presently the Agamemnon moved through, and with signals at all her masts – for Lyons was on board her, and was governing and ordering the convoy. The French steamers of war went out with their transports in tow, and their great vessels formed the line. The French went out more quickly than the English, and in better order. Many of their transports were vessels of very small size; and of necessity they were a swarm. Our transports went out in five columns of only thirty each. Then – guard over all – the English war-fleet, in single column, moved slowly out of the bay.50

Equally, I learned that most people don’t really know exactly what they want, or if they do it’s only from what they know, what is available or possible at the time. As Henry Ford said, famously, if he had asked American farmers what they wanted in terms of future transport, they would have answered ‘faster horses’. You need to show them new possibilities, new ideas and new products and explain these as lucidly as possible. Dyson advertising focuses on how our products are engineered and how they work, rather than on gimmicks and snappy sales lines.

The Sons of Mary seldom bother, for they have inherited that good part; But the Sons of Martha favour their Mother of the careful soul and the troubled heart. And because she lost her temper once, and because she was rude to the Lord her Guest, Her Sons must wait upon Mary's Sons, world without end, reprieve, or rest. It is their care in all the ages to take the buffet and cushion the shock. It is their care that the gear engages; it is their care that the switches lock. It is their care that the wheels run truly; it is their care to embark and entrain, Tally, transport, and deliver duly the Sons of Mary by land and main.

Social entrepreneurs are among the most dynamic engines of the cooperative movement. Where corporate moguls work for personal enrichment, these civic-minded business leaders work for the cooperative equivalent, which is a desire to generate community self-reliance, abolish poverty, and enhance community economic well-being by improving housing, food, transportation, energy, health, finance, and a host of other products and services. Their motivations are not selfishly financial; they are far deeper, rooted in both the human spirit and the pervasive sense of community that human beings have striven to express throughout history. As the economist Jean Monnet once said, “Without community, there is crisis.

An exciting sense of rodina, ‘motherland,’ was for the first time organically mingled with the comfortably creaking snow, the deep footprints across it, the red gloss of the engine stack, the birch logs piled high, under their private layer of transportable snow, on the red tender. I was not quite six, but that year abroad, a year of difficult decisions and liberal hopes, had exposed a small Russian boy to grown-up conversations. He could not help being affected in some way of his own by a mother’s nostalgia and a father’s patriotism. In result, that particular return to Russia, my first conscious return, seems to me now, sixty years later, a rehearsal – not of the grand homecoming that will never take place, but of its constant dream in my long years of exile.

Standing on the left side of the runway was my battle-worn X-wing fighter. Parked on the right side was my DeLorean. Sitting on the runway itself was my most frequently used spacecraft, the Vonnegut. Max had already powered up the engines, and they emitted a low, steady roar that filled the hangar. The Vonnegut was a heavily modified Firefly-class transport vessel, modeled after the Serenity in the classic Firefly TV series. The ship had been named the Kaylee when I’d first obtained it, but I’d immediately rechristened it after one of my favorite twentieth-century novelists. Its new name was stenciled on the side of its battered gray hull. I’d looted the Vonnegut from a cadre of Oviraptor clansmen who had foolishly attempted to hijack my X-wing while I was cruising through a large group of worlds in Sector Eleven known as the Whedonverse. The

Do you really think that the Revolution is a ridiculous proposition? That we cannot engineer our own structures? What's ridiculous is the system we have now. If we were starting society anew, who among us would propose a monarchy, an aristocracy, a financial elite that exploits the earth and farms its population? If at one of the local or regional meetings that we have to govern our community someone proposed, instead of equality, that all of us, including the poorest among us, donated a percentage of our income to a super-rich family with a little old lady at its helm who would turn up annually in our parliament, draped in jewels and finery, to tell us that austerity had to continue, you'd tell them they were mental. If someone said that we should give 64 per cent of British land to 0.28 per cent of the population, we would not vote for it. If trade agreements were proposed that meant local businesses were shackled so that transnational corporations could create a farcical tyrannical economy where produce was needlessly transported around the world for their gain and to the detriment of everyone else, it would be forbidden. If energy companies said they wanted to be run for huge profit, without regulation, whilst harming the environment, we wouldn't allow it. That pharmaceutical and food companies could run their own governing bodies, flood the world with inferior and harmful products that damage and even kill the people that use them, we would not tolerate it. Here is the truth they fight so hard to suppress: to create a better world, the priority is not the implementation of new systems, though that is necessary, it is a refusal to cooperate with the obsolete and harmful structures that are already in place.

Coal smuts fly past and the train ploughs forwards, fire-bellied and smoke-spitting, a mystery of steam pressure and pistons, a miracle of gauges. The engine is a painted comet, its tail rattling behind with every class of passenger hanging on. Many undertake this mode of transportation with nervous trepidation, as well they might; it is well known that regular rail travel contributes to the premature ageing of passengers. Unnatural speed and the rapid travelling of distances have a baleful effect on the organs. Hurrying can prove fatal, notably when combined with suet-based meals, improving spirits and fine tobaccos. The worst offender: the new-built, gas-lit, steam-hauled carriages of Hades which will convey a passenger between Paddington and Farringdon under the very ground of the metropolis. According to reports miscellaneous, the passenger (smoke-blinded, nerve-rattled, near-suffocated) will emerge from the experience variously six months to five years older.

I number it among my blessings that my father had no car, while yet most of my friends had, and sometimes took me for a drive. This meant that all these distant objects could be visited just enough to clothe them with memories and not impossible desires, while yet they remained ordinarily as inaccessible as the Moon. The deadly power of rushing about wherever I pleased had not been given me. I measured distances by the standard of man, man walking on his two feet, not by the standard of the internal combustion engine. I had not been allowed to deflower the very idea of distance; in return I possessed ‘infinite riches’ in what would have been to motorists ‘a little room’. The truest and most horrible claim made for modern transport is that it ‘annihilates space’. It does. It annihilates one of the most glorious gifts we have been given. It is a vile inflation which lowers the value of distance, so that a modern boy travels a hundred miles with less sense of liberation and pilgrimage and adventure than his grandfather got from travelling ten. Of course if a man hates space and wants it to be annihilated, that is another matter. Why not creep into his coffin at once? There is little enough space there.

Clark Air base in Angeles City is a hub of commerce. The streets teem with industrious Filipinos hustling to make a living. Rusty cars and trucks clog narrow streets and honk their horns with abandon. Jeepneys ferry passengers around town for only a few pesos and serve as public transportation. The jeepney is the official vehicle of the Philippines. Jeepneys are long, open-sided jeeps and have bench seats for passengers. The best jeepneys are very ornate, their hoods festooned with a multitude of fancy chrome horses and ornaments, multihued streamers, and hand-operated rubber-bulb horns. Safety standards are third-world-relaxed in the PI, and jeepney drivers casually smoke cigarettes while they sit with plastic containers of gasoline nestled between their feet. The clear plastic jugs have a tube that connects to the engine and serves as the jeepney’s improvised gas tank, making it easier for the driver to monitor and conserve fuel. Jeepneys are not the only transportation available. Small, sidecar-equipped motorcycles called tricycles, also serve as cheap taxis, crowding the streets near popular establishments. The alleys are lined with side-by-side food stalls, and street vendors occupy every corner.

She spoke so passionately that some of the Historians believed her, even the ones like Dr. Karuna who had been passed over for promotion when Crome put Valentine in charge of their Guild. As for Bevis Pod, he watched her with shining eyes, filled with a feeling that he couldn’t even name; something that they had never taught him about in the Learning Labs. It made him shiver all over. Pomeroy was the first to speak. “I hope you’re right, Miss Valentine,” he said. “Because he is the only man who can hope to challenge the Lord Mayor. We must wait for his return.” “But …” “In the meantime, we have agreed to keep Mr. Pod safe, here at the Museum. He can sleep up in the old Transport Gallery, and help Dr. Nancarrow catalogue the art collection, and if the Engineers come hunting for him we’ll find a hiding place. It isn’t much of a blow against Crome, I know. But please understand, Katherine: We are old, and frightened, and there really is nothing more that we can do.” The world was changing. That was nothing new, of course; the first thing an Apprentice Historian learned was that the world was always changing, but now it was changing so fast that you could actually see it happening. Looking down from the flight deck of the Jenny Haniver, Tom saw the wide plains of the eastern Hunting Ground speckled with speeding towns, spurred into flight by whatever it was that had bruised the northern sky, heading away from it as fast as their tracks or wheels could carry them, too preoccupied to try and catch one another. “MEDUSA,” he heard Miss Fang whisper to herself, staring toward the far-off, flame-flecked smoke. “What is a MEDUSA?” asked Hester. “You know something, don’t you? About what my mum and dad were killed for?” “I’m afraid not,” the aviatrix replied. “I wish I did. But I heard the name once. Six years ago another League agent managed to get into London, posing as a crewman on a licensed airship. He had heard something that must have intrigued him, but we never learned what it was. The League had only one message from him, just two words: Beware MEDUSA. The Engineers caught him and killed him.” “How do you know?” asked Tom. “Because they sent us back his head,” said Miss Fang. “Cash on Delivery.” That evening she set the Jenny Haniver down on one of the fleeing towns, a respectable four-decker called Peripatetiapolis that was steering south to lair in the mountains beyond the Sea of Khazak. At the air-harbor there they heard more news of what had happened to Panzerstadt-Bayreuth. “I saw it!” said an aviator. “I was a hundred miles away, but I still saw it. A tongue of fire, reaching out from London’s Top Tier and bringing death to everything

RESISTANCE TO CHANGE? “The canal system of this country is being threatened by the spread of a new form of transportation known as ’railroads’ and the federal government must preserve the canals. . . . If canal boats are supplanted by ’railroads,’ serious unemployment will result. Captains, cooks, drivers, hostlers, repairmen, and lock tenders will be left without means of livelihood, not to mention the numerous farmers now employed growing hay for the horses. . . . As you may well know, Mr. President, ’railroad’ carriages are pulled at the enormous speed of 15 miles per hour by ’engines’ which, in addition to endanging life and limb of passengers, roar and snort their way through the countryside, setting fire to crops, scaring the livestock and frightening women and children. The Almighty certainly never intended that people should travel at such breakneck speed.” The above communication was from Martin Van Buren, then governor of New York, to President Andrew Jackson on January 21, 1829. In 1832 Van Buren was elected vice president of the United States under Andrew Jackson’s second term. In 1836 Van Buren was elected president of the United States. It is also interesting that the first railroad into Washington, DC, was completed in time to bring visitors from Philadelphia and New York to Van Buren’s inauguration. Sources: Janet E. Lapp, “Ride the Horse in the Direction It’s Going,” American Salesman, October 1998, pp. 26–29; and The World Book Encyclopedia, Volume 20 (Chicago: World Book—Childcraft International, Inc.), 1979, p. 214. 2

fulfill our mission with the Rational ApproachTM, a comprehensive softwareengineering solution consisting of three elements: • A configurable set of processes and techniques for the development of software, based on iterative development, object modeling, and an architectural approach to software reuse. • An integrated family of application construction tools that automate the Rational Approach throughout the software lifecycle. • Technical consulting services delivered by our worldwide field organization of software engineers and technical sales professionals. Our customers include businesses in the Asia/Pacific region, Europe, and North America that are leaders in leveraging semiconductor, communications, and software technologies to achieve their business objectives. We serve customers in a diverse range of industries, such as telecommunications, banking and financial services, manufacturing, transportation, aerospace, and defense.They construct software applications for a wide range of platforms, from microprocessors embedded in telephone switching systems to enterprisewide information systems running on company-specific intranets. Rational Software Corporation is traded on the NASDAQ system under the symbol RATL.1

What is Civil Engineering? Technology could be a skilled engineering regulation that chargeable for appearance, structure, and maintenance of the substantial surroundings. An Engineer, he is practices as an applied scientist and use the technology equipments throughout testing technique of foundation, for the period of this method engineer get appear at the actual a part of transportation. Civil engineering lab testing equipments square measured and utilized by civil engineers.

Imagine trying to jerry-rig a Volkswagen Beetle to travel at speeds of 150 miles per hour. In 1933, Adolf Hitler commissioned Dr. Ferdinand Porsche to develop a cheap car that could get 40 miles per gallon of gas and provide a reliable form of transportation for the average German family. The result was the VW Beetle. This history, Hitler’s plan, places constraints on the ways we can modify the Beetle today; the engineering can be tweaked only so far before major problems arise and the car reaches its limit. In many ways, we humans are the fish equivalent of a hot-rod Beetle. Take the body plan of a fish, dress it up to be a mammal, then tweak and twist that mammal until it walks on two legs, talks, thinks, and has superfine control of its fingers—and you have a recipe for problems. We can dress up a fish only so much without paying a price. In a perfectly designed world—one with no history—we would not have to suffer everything from hemorrhoids to cancer.

Not lightly should you transport aluminum trays of oily Pakistani food in the back of your mother’s car. This is one of many lessons I learned as part of the Muslim Students Association (MSA) in university. Through tragically not reflected in catering, a glorious diversity has generally characterized attendance at MSA events across the varied campuses of North America’s colleges and universities: the second-generation children of Hyderabadi physicians suffering toward medical school themselves, well-heeled scions of Syrian engineers from the Midwest on break from serial brunching, African-American Muslims bemused by immigrant angst, occasional pompously coiffed upper-crust Pakistanis expiating sins incurred while clubbing and the odd Saudi exchange student committed to bringing order to this religious soup.

o n o f R a t i o n a l S o f t w a r e C o r p o r a t i o n i s t o e n s u r e t h e s u c c e s s o f c u s t o m e r s c o n s t r u c t i n g t h e s o f t w a r e s y s t e m s t h a t t h e y d e p e n d o n . We enable our customers to achieve their business objectives by turning software into a source of competitive advantage, speeding time-to-market, reducing the risk of failure, and improving software quality. We fulfill our mission with the Rational ApproachTM, a comprehensive softwareengineering solution consisting of three elements: • A configurable set of processes and techniques for the development of software, based on iterative development, object modeling, and an architectural approach to software reuse. • An integrated family of application construction tools that automate the Rational Approach throughout the software lifecycle. • Technical consulting services delivered by our worldwide field organization of software engineers and technical sales professionals. Our customers include businesses in the Asia/Pacific region, Europe, and North America that are leaders in leveraging semiconductor, communications, and software technologies to achieve their business objectives. We serve customers in a diverse range of industries, such as telecommunications, banking and financial services, manufacturing, transportation, aerospace, and defense.They construct software applications for a wide range of platforms, from microprocessors embedded in telephone switching systems to enterprisewide information systems running on company-specific intranets. Rational Software Corporation is traded on the NASDAQ system under the symbol RATL.1

Tracked Vehicles "Each war proves anew to those who may have had their doubts, the primacy of the main battle tank. Between wars, the tank is always a target for cuts. But in wartime, everyone remembers why we need it, in its most advanced, upgraded versions and in militarily significant numbers." - IDF Brigadier General Yahuda Admon (retired) Since their first appearance in the latter part of World War I, tanks have increasingly dominated military thinking. Armies became progressively more mechanised during World War II, with many infantry being carried in armoured carriers by the end of the war. The armoured personnel carrier (APC) evolved into the infantry fighting vehicle (IFV), which is able to support the infantry as well as simply transport them. Modern IFVs have a similar level of battlefield mobility to the tanks, allowing tanks and infantry to operate together and provide mutual support. Abrams Mission Provide heavy armour superiority on the battlefield. Entered Army Service 1980 Description and Specifications The Abrams tank closes with and destroys enemy forces on the integrated battlefield using mobility, firepower, and shock effect. There are three variants in service: M1A1, M1A2 and M1A2 SEP. The 120mm main gun, combined with the powerful 1,500 HP turbine engine and special armour, make the Abrams tank particularly suitable for attacking or defending against large concentrations of heavy armour forces on a highly lethal battlefield. Features of the M1A1 modernisation program include increased armour protection; suspension improvements; and an improved nuclear, biological and chemical (NBC) protection system that increases survivability in a contaminated environment. The M1A1D modification consists of an M1A1 with integrated computer and a far-target-designation capability. The M1A2 modernisation program includes a commander's independent thermal viewer, an improved commander's weapon station, position navigation equipment, a distributed data and power architecture, an embedded diagnostic system and improved fire control systems.

M113 Family of Vehicles Mission Provide a highly mobile, survivable, and reliable tracked-vehicle platform that is able to keep pace with Abrams- and Bradley-equipped units and that is adaptable to a wide range of current and future battlefield tasks through the integration of specialised mission modules at minimum operational and support cost. Entered Army Service 1960 Description and Specifications After more than four decades, the M113 family of vehicles (FOV) is still in service in the U.S. Army (and in many foreign armies). The original M113 Armoured Personnel Carrier (APC) helped to revolutionise mobile military operations. These vehicles carried 11 soldiers plus a driver and track commander under armour protection across hostile battlefield environments. More importantly, these vehicles were air transportable, air-droppable, and swimmable, allowing planners to incorporate APCs in a much wider range of combat situations, including many "rapid deployment" scenarios. The M113s were so successful that they were quickly identified as the foundation for a family of vehicles. Early derivatives included both command post (M577) and mortar carrier (M106) configurations. Over the years, the M113 FOV has undergone numerous upgrades. In 1964, the M113A1 package replaced the original gasoline engine with a 212 horsepower diesel package, significantly improving survivability by eliminating the possibility of catastrophic loss from fuel tank explosions. Several new derivatives were produced, some based on the armoured M113 chassis (e.g., the M125A1 mortar carrier and M741 "Vulcan" air defence vehicle) and some based on the unarmoured version of the chassis (e.g., the M548 cargo carrier, M667 "Lance" missile carrier, and M730 "Chaparral" missile carrier). In 1979, the A2 package of suspension and cooling enhancements was introduced. Today's M113 fleet includes a mix of these A2 variants, together with other derivatives equipped with the most recent A3 RISE (Reliability Improvements for Selected Equipment) package. The standard RISE package includes an upgraded propulsion system (turbocharged engine and new transmission), greatly improved driver controls (new power brakes and conventional steering controls), external fuel tanks, and 200-amp alternator with four batteries. Additional A3 improvements include incorporation of spall liners and provisions for mounting external armour. The future M113A3 fleet will include a number of vehicles that will have high speed digital networks and data transfer systems. The M113A3 digitisation program includes applying hardware, software, and installation kits and hosting them in the M113 FOV. Current variants: Mechanised Smoke Obscurant System M548A1/A3 Cargo Carrier M577A2/A3 Command Post Carrier M901A1 Improved TOW Vehicle M981 Fire Support Team Vehicle M1059/A3 Smoke Generator Carrier M1064/A3 Mortar Carrier M1068/A3 Standard Integrated Command Post System Carrier OPFOR Surrogate Vehicle (OSV) Manufacturer Anniston Army Depot (Anniston, AL) United Defense, L.P. (Anniston, AL)

Either Vance had engineered a prank of colossally stupid magnitude or he was dreaming. And though Cormac was almost certain it was the latter, part of him kind of hoped Vance had pulled it off. The ocean was over five hours away from the Harrrington campus. If Vance had somehow managed to transport him here, it would mean he was an actual supervillain.

The Model S also offered a way to fix issues in a manner that people had never before encountered with a mass-produced car. Some of the early owners complained about glitches like the door handles not popping out quite right or their windshield wipers operating at funky speeds. These were inexcusable flaws for such a costly vehicle, but Tesla typically moved with clever efficiency to address them. While the owner slept, Tesla’s engineers tapped into the car via the Internet connection and downloaded software updates. When the customer took the car out for a spin in the morning and found it working right, he was left feeling as if magical elves had done the work. Tesla soon began showing off its software skills for jobs other than making up for mistakes. It put out a smartphone app that let people turn on their air-conditioning or heating from afar and to see where the car was parked on a map. Tesla also began installing software updates that imbued the Model S with new features. Overnight, the Model S sometimes got new traction controls for hilly and highway driving or could suddenly recharge much faster than before or possess a new range of voice controls. Tesla had transformed the car into a gadget—a device that actually got better after you bought it. As Craig Venter, one of the earliest Model S owners and the famed scientist who first decoded man’s DNA, put it, “It changes everything about transportation. It’s a computer on wheels.” The

Rooms For Rent Atlanta That Cater To Your Personal Growth Are you looking for just the right room to rent? Maybe you have the resources you need to find it yourself. After all, this is the age of the search engine, and plenty of information is available to anyone who seriously looks for it. There is a wide variety of choice, so you can concentrate only on those homes that might potentially be for you. There are plenty of advantages to occupying rooms for rent atlanta. You save a lot of money paying only part of the expenses you would normally pay for when you have a house of your own. This is because you only have to pay your share of the rent, water, electricity and heat bills. But there are disadvantages to house share too. Conflicts can arise when you live in house that is not yours, especially if you rent a room in a house where the other residents are from a different background than yours. Having a nice place to stay can even help your physical health, and it surely affects your mental health. You may find a place also that comes with furniture already in it. This would allow you to get by with spending less on not only the furniture but the transportation too. Sometimes you can actually save money finding rooms for rent atlanta in the country. This depends on how often you plan to visit the city. If you have a job you can do from home, or if you are retired and collecting benefits, then there is no real reason for you to pay the extra money to live in the city. Of course there are many choices you need to make while you are searching for a room. Some people just do not enjoy living alone. Renting an entire apartment to oneself can, indeed, be a lonely experience. For those who want an easy opportunity to socialize, then, renting a room is a great option. It is little wonder that so many houses on campuses around the country are full of young students renting rooms - its partly for convenience, and definitely partly for the chance to be among others their own age. Renting a room provides the chance to be among one’s peers. There are many more benefits, but perhaps the biggest and best is the advantage of not being locked into something for life. Room rentals can be very appealing, and they can complement the kind of lifestyle you want and deserve. If you want to find the spirit or soul of a city, move right in with its inhabitants. You may benefit socially by taking a couple of classes at the local college. You might try looking for rooms for rent atlanta where there are games, indoor or outdoor. This is a great way to meet people and get started in your new life. Depending on the weather, you might want a pool or access to a gym or tennis courts. Maybe you are attracted to the kind of community that has stunning architecture and green trees and plants. There may be a certain type of street design that appeals to you.

I’d be hard-pressed to find a better start to a brand story than the one that chronicles the birth of “the people’s car,” the Tata Nano. The story goes that Ratan Tata, chairman of the well-respected Tata Group, was travelling along in the pouring rain behind a family who was precariously perched on a scooter weaving in and out of traffic on the slick wet roads of Bangalore. Tata thought that surely this was a problem he and his company could solve. He wanted to bring safe, affordable transport to the poor—to design, build, and sell a family car that could replace the scooter for a price that was less than $2,500. It was a business idea born from a high ideal and coming from a man with a track record in the industry, someone with the capability to innovate, design, and produce a high-quality product. People were captivated by the idea of what would be the world’s cheapest car. The media and the world watched to see how delivering on this seemingly impossible promise might pan out. Ratan Tata did deliver on his promise when he unveiled the Nano at the New Delhi Auto Expo in 2009, six years after having the idea. The hype around the new “people’s car” and the media attention it received meant that any mistakes were very public (several production challenges and safety problems were reported along the way). And while the general public seemed to be behind the idea of a new and fun Indian-led innovation, the number of Facebook likes (almost 4 million to date) didn’t convert to actual sales. It seemed that while Tata Motors was telling a story about affordability and innovating with frugal engineering (perhaps “lean engineering” might have worked better for them), the story prospective customers were hearing was one about a car that was cheap. The positioning of the car was at odds with the buying public’s perception of it. In a country where a car is an aspirational purchase, the Nano became symbolic of the car to buy if you couldn’t afford anything else. Since its launch in 2009, just over 200,000 Nanos have sold. The factory has the capacity to produce 21,000 cars a month. It turns out that the modest numbers of people buying the Nano are not the scooter drivers but middle-class Indians who are looking for a second car, or a car for their parents or children. The car that was billed as a “game changer” hasn’t lived up to the hype in the hearts of the people who were expected to line up and buy it in the tens of thousands. Despite winning design and innovation awards, the Nano’s reputation amongst consumers—and the story they have come to believe—has been the thing that’s held it back.

Age: 11 Height: 5’5 Favourite animal: Wolf   Chris loves to learn. When he’s not reading books explaining how planes work or discovering what lives at the bottom of the ocean, he’s watching the Discovery Channel on TV to learn about all the world’s animal and plant life. How things work is one of Chris’ main interests, and for this reason he has a special appreciation for electrical and mechanical things, everything from computers to trains. He considers himself a train expert and one day dreams of riding on famous trains, such as the Orient Express and the Trans-Siberian Railway.   Chris dreams of one day being a great engineer, like Isambard Kingdom Brunel. He knows this will involve going to university, so he studies hard at school. Beatrix is his study partner, and when they aren’t solving mysteries in the Cluefinders Club they can be found in the garden poring over text books. Like Ben, he loves to read comic books, and his favourite super-hero is Iron Man, who is a genius engineer and businessman. Chris says, “One day I’ll invent a new form of transport that will revolutionise world travel!”    

Regardless of whether you think the industrial era has been good or bad, three profoundly fundamental shifts underlie this revolution. The first is that industrialists harnessed new sources of energy, primarily to produce things. Preindustrial people occasionally used wind or water to generate power, but they mostly relied on muscles—human and animal—to generate force. Industrial pioneers such as James Watt (who invented the modern steam engine) figured out how to transform energy from fossil fuels such as coal, oil, and gas into steam, electricity, and other kinds of power to run machines. The first of these machines were designed to make textiles, but within decades others were invented to make iron, mill wood, plow fields, transport things, and do just about everything else one can manufacture and sell (including beer)7. A second major component of the Industrial Revolution was a reorganization of economies and social institutions. As industrialization gathered steam, capitalism, in which individuals compete to produce goods and services for profit, became the world’s dominant economic system, spurring the development of further industrialization and social change. As workers changed their locus of activity from the farm to factories and companies, more people had to work together even as they needed to perform more specialized activities. Factories required more coordination and regulation. In

Life expectancy rose only modestly between the Neolithic era of 8500 to 3500 BC and the Victorian era of 1850 to 1900.13 An American born in the late nineteenth century had an average life expectancy of around forty-five years, with a large share never making it past their first birthdays.14 Then something remarkable happened. In countries on the frontier of economic development, human health began to improve rapidly, education levels shot up, and standards of living began to grow and grow. Within a century, life expectancies had increased by two-thirds, average years of schooling had gone from single to double digits, and the productivity of workers and the pay they took home had doubled and doubled and then doubled again. With the United States leading the way, the rich world crossed a Great Divide—a divide separating centuries of slow growth, poor health, and anemic technical progress from one of hitherto undreamed-of material comfort and seemingly limitless economic potential. For the first time, rich countries experienced economic development that was both broad and deep, reaching all major segments of society and producing not just greater material comfort but also fundamental transformations in the health and life horizons of those it touched. As the French economist Thomas Piketty points out in his magisterial study of inequality, “It was not until the twentieth century that economic growth became a tangible, unmistakable reality for everyone.”15 The mixed economy was at the heart of this success—in the United States no less than in other Western nations. Capitalism played an essential role. But capitalism was not the new entrant on the economic stage. Effective governance was. Public health measures made cities engines of innovation rather than incubators of illness.16 The meteoric expansion of public education increased not only individual opportunity but also the economic potential of entire societies. Investments in science, higher education, and defense spearheaded breakthroughs in medicine, transportation, infrastructure, and technology. Overarching rules and institutions tamed and transformed unstable financial markets and turned boom-bust cycles into more manageable ups and downs. Protections against excessive insecurity and abject destitution encouraged the forward-looking investments and social integration that sustained growth required. At every level of society, the gains in health, education, income, and capacity were breathtaking. The mixed economy was a spectacularly positive-sum bargain: It redistributed power and resources, but as its impacts broadened and diffused, virtually everyone was made massively better off.

is clear that neither countries nor regions can flourish if their cities (innovation ecosystems) are not being continually nourished. Cities have been the engines of economic growth, prosperity and social progress throughout history, and will be essential to the future competitiveness of nations and regions. Today, more than half of the world’s population lives in urban areas, ranging from mid-size cities to megacities, and the number of city dwellers worldwide keeps rising. Many factors that affect the competitiveness of countries and regions – from innovation and education to infrastructure and public administration – are under the purview of cities. The speed and breadth by which cities absorb and deploy technology, supported by agile policy frameworks, will determine their ability to compete in attracting talent. Possessing a superfast broadband, putting into place digital technologies in transportation, energy consumption, waste recycling and so on help make a city more efficient and liveable, and therefore more attractive than others. It is therefore critical that cities and countries around the world focus on ensuring access to and use of the information and communication technologies on which much of the fourth industrial revolution depends. Unfortunately, as the World Economic Forum’s Global Information Technology Report 2015 points out, ICT infrastructures are neither as prevalent nor diffusing as fast as many people believe. “Half of the world’s population does not have mobile phones and 450 million people still live out of reach of a mobile signal. Some 90% of the population of low-income countries and over 60% globally are not online yet. Finally, most mobile phones are of an older generation.”45

Or consider the modern traffic roundabout, with its clear yield requirements, that was designed by British transport engineers in the 1960s and implemented throughout the U.K. It took another thirty years full of oblivion and resistance until this obvious traffic decongestant found its way in the U.S. and continental Europe. Today France alone has more than 30,000 roundabouts – which the French now probably falsely attribute to the designer of the Place de l’Étoile.

Once again, infrastructure had set a limit on the pace of development of a new technology. But by the second decade of the nineteenth century, malleable-iron rails were beginning to replace brittle cast iron on the wagonways of England, and stone or wooden sleepers strengthened the roadbeds for heavy locomotives. With such improvements, Trevithick’s circular track on vacant land in London would open out into a network of fast, reliable transportation—but not before its inventors and engineers endured a final long haul of challenges and trials.

Horses increased in number after the commercialization of the steam engine because horsepower filled the niche below steam power. A horse stood ready to pull a cart or plow a field on command, without the delay of building up a head of steam. Energy transitions are seldom so complete that they drive out every competitor. Much of the world still relies on animals for farm work and transportation: horses, oxen, camels, llamas, water buffalo, elephants, even fellow humans.

The real change away from horse-drawn transportation came with the advent in the late 1880s of the electric streetcar. Frank Julian Sprague, a West Point–trained electrical engineer, installed the first commercial electric streetcar system in Richmond, Virginia, in 1887.

By the turn of the century, the electric streetcar had largely replaced the use of horses in public transportation. The animals continued to serve for general hauling, merchandise delivery, and small-scale energy generation. In fact, their urban numbers actually increased.32 Only the development of the internal combustion engine and its application to power the truck and the automobile across the years 1900 to 1915 replaced the city horse with mechanical transportation.

He was riding a train one day, full of his new idea, when George Westinghouse’s younger brother, Herman, happened to sit down next to him. They began talking; soon Stanley told Herman about his idea for a self-regulating alternating-current generator.24 Herman knew a good idea when he heard one. He connected Stanley with George, the successful developer of the air brake and other railroad machinery that made long trains and long-distance transportation practical. George was just then considering entering the electric-lighting field, pursuing alternating-current technology rather than direct current. He had recruited a team of young engineers to build a knowledge base for him, but he wasn’t yet fully committed. Stanley’s work won him over. Early in 1884 he hired the twenty-five-year-old to develop a complete AC system, from generators to motors and lighting.

I had heard such predictions all my life from Malcolm and all his posthumous followers who hollered that the Dreamers must reap what they sow. I saw the same prediction in the words of Marcus Garvey who promised to return in a whirlwind of vengeful ancestors, an army of Middle Passage undead. No. I left The Mecca knowing that this was all too pat, knowing that should the Dreamers reap what they had sown, we would reap it right with them. Plunder has matured into habit and addiction; the people who could author the mechanized death of our ghettos, the mass rape of private prisons, then engineer their own forgetting, must inevitably plunder much more. This is not a belief in prophecy but in the seductiveness of cheap gasoline. Once, the Dream's parameters were caged by technology and by the limits of horsepower and wind. But the Dreamers have improved themselves, and the damming of seas for voltage, the extraction of coal, the transmuting of oil into food, have enabled an expansion in plunder with no known precedent. And this revolution has freed the Dreamers to plunder not just the bodies of humans but the body of the Earth itself. The Earth is not our creation. It has no respect for us. It has no use for us. And its vengeance is not the fire in the cities but the fire in the sky. Something more fierce than Marcus Garvey is riding on the whirlwind. Something more awful than all our African ancestors is rising with the seas. The two phenomena are known to each other. It was the cotton that passed through our chained hands that inaugurated this age. It is the flight from us that went them sprawling into the subdivided woods. And the methods of transport through these new subdivisions, across the sprawl, is the automobile, the noose around the neck of the earth, and ultimately, the Dreamers themselves. I drove away from the house of Mable Jones thinking of all of this. I drove away, as always, thinking of you. I do not believe that we can stop them, Samori, because they must ultimately stop themselves. And still I urge you to struggle. Struggle for the memory of your ancestors. Struggle for wisdom. Struggle for the warmth of The Mecca. Struggle for your grandmother and grandfather, for your name. But do not struggle for the Dreamers. Hope for them. Pray for them, if you are so moved. But do not pin your struggle on their conversion. The Dreamers will have to learn to struggle themselves, to understand that the field for their Dream, the stage where they have painted themselves white, is the deathbed of us all. The Dream is the same habit that endangers the planet, the same habit that sees our bodies stowed away in prisons and ghettos. I saw these ghettos driving back from Dr. Jones' home. They were the same ghettos I had seen in Chicago all those years ago, the same ghettos where my mother was raised, where my father was raised. Through the windshield I saw the mark of these ghettos - the abundance of beauty shops, churches, liquor stores, and crumbling housing - and I felt the old fear. Through the windshield I saw the rain coming down in sheets.

The Mortuary Committee would be burdened with many unenviable tasks, but the first was straightforward: instead of storing the corpses at a half dozen locations around town, which made it more difficult for soldiers to transport the bodies and record-keepers and families to find them, they needed to select a single building to house an official, temporary morgue. They quickly settled on the Chebucto Road School, which, despite its broken windows, had a lot to recommend it: it was large, it could be quickly cleared out and converted to its new purpose, and it was close to Pier 6, minimizing the transport of corpses and travel for their relatives. The committee also needed a place that could keep bodies for as long as possible, giving them the best chance of being identified. They designated the upper floors for offices and the wide-open, cooler basement for the bodies, which they planned to lay in rows and cover with sheets. The Royal Engineers quickly fixed up the damaged school, covered its windows, and cleaned the space. As soon as people learned of the location, bodies began to pile up outside the building, stacked two and three high until morgue workers could retrieve them. The Relief Committee also dispatched crews of volunteers to put out fires and turn off water mains, faucets, and spigots, and to pick up the dead—tagging their names, when they knew them, to the victims’ wrists, or simply attaching a number when they didn’t—loading them onto rudimentary flat wagons dozens at a time. They soon learned to conduct this dispiriting job late at night so as not to offend the friends and relatives of the deceased. But because everyone could hear the horses’ hooves each night, the rolling midnight morgue was a poorly kept secret, one that woke many Haligonians whose homes still lacked windows.

Though it's often considered insulting to note, women in the aggregate have different preferences: we tend to put "people jobs" over "things jobs", as someone once put it to me. This has caused feminists a great deal of consternation. Pricked by the embarassment of natural differences between men and women, they blame society and insist women need to be taught to adopt different preferences. But behind this insistence lies the idea that women's preferences are inferior. Young girls are left to conclude that they must strive to be more like men- they must close the novel they were enjoying and take up coding. They must want things men want because men want them. The talking point about the dearth of women CEOs is a classic. The fact of this disparity might just as easily be understood differently: CEOs lead fairly unbalanced lives. They make a lot of money and have very little time. Their relationships suffer. They have high rates of divorce. Women might recognize this difference and assume that men are the ones to be pitied. We might just as easily say: Women are so much better adjusted, so much wiser for preferring relationships to dollars. We might as easily say: Of course women prefer literature to software engineering! It's far more interesting. It has the power to transport, to move hearts and minds. Literature is the story one generaton tells to the next. So many women study, teach and produce great literature. Who is the wiser sex? Instead we presume that if men dominate the STEM departments, they must be occupying the university's Arcadia. If CEOs are overwhelmingly male, then women are being unfairly excluded- by men who outfox them, a system that diminishes them, preferences that lead them astray. We want to have it both ways: acknowledging sotto voce that Sumner Redstone, Rupert Murdoch, and Jeff Bezos have not enjoyed enviable personal lives, while insisting every woman should or would stand in their shoes, given half a chance. [...] We must stop. It's a dumb habit, thoughtless and base. It reflects an unflattering insecurity we shouldn't indulge. The jealousy at its heart suggests that either we believe women aren't truly capable, or they have somehow be duped, made victims by a "system" that, generation after generation, locks us out and shuts us in with so many glass ceilings and walls. It's an exhausting set of untruths. Worst of all, girls are listening.

The notion of Panspermia as a valid theory is definitely preposterous if the presenter is not offering along with it an explanation for the trajectory of the transporting object - through the Solar System at least. Hitting Earth and giving it life therewith is after all a unique event a responsible Scientist ought not to label as a 'coincidence', and resorting to construct an incomplete framework with holes in it, is not even an undertaking an Engineer would fantasize about - let alone to be a valid practice in any scientific method.

Also today when you sit down to eat your meal, no matter where you are, try to think about the many people who have made the meal possible.  See if you can engage in this activity while you eat slowly.  Let appreciation well up from within you as your taste buds are activated.  Think of the people who built your car with all of its complex components that work together to provide transportation.  Or think of the bus driver or train engineers.  Think of those who laid the roads or rails.  Think of the cashier who stands on their feet all day long ringing up purchases.  Think of the truck driver who delivered the merchandise to the store.  Think of the packagers.  Think of the farm laborers who make the food possible.  Think of those in oil producing countries who provide their natural resources and labor.  The list is almost endless.  I can imagine that by the end of the meal you still have not thought of all the countless labors, big and small, that made that meal possible.  Don’t forget to include your own labors as well.

Between 1931 and 1946, Pan American Airways had 28 flying boats known as “Clippers,” These four radial engine aircraft were S-40’s and 42’s built in 1934, later replaced by Boeing 314 Clippers, that became the familiar symbol of the company. Following the war, Pan American Airways flew land based airliners such as the Boeing 377 Stratocruiser, developed from the C-97, Stratofreighter, and a military derivative of the B-29 Superfortress, used as a troop transport, and the DC-4 series, converted from the blueprints of the C-54 Skymaster. Both of these airliners were originally developed for the United States Army Air Corps, during World War II. On January 1950 Pan American Airways Corporation adopted the name it had been unofficially called since 1943, and formally became “Pan American World Airways, Inc.” That September Pan American bought out American Airlines’ overseas division and simultaneously placed an order for 45 DC-6Bs, replacing their DC-4’s. Throughout Pan-American was known simply as Pan-Am. The Douglas DC-6 is a four engine “Double Wasp” radial piston-powered airliner manufactured for long flights. It was built by the Douglas Aircraft Company from 1946 until 1958. More than 700 were built between those years and some are still flying today. The rugged, reliable DC-6B, was regarded as the ultimate piston-engine airliner, from the perspective of having excellent handling qualities and relatively economical operations.

Castine is a quiet town with a population of about 1,500 people in Western Hancock County, Maine, named after John Hancock, when Maine was a part of the Commonwealth of Massachusetts. He was the famous statesman, merchant and smuggler who signed the “Declaration of Independence” with a signature large enough so that the English monarch, King George, could read it without glasses. Every child in New England knows that John Hancock was a prominent activist and patriot during the colonial history of the United States and not just the name of a well-known Insurance Company. Just below the earthen remains of Fort George, on both sides of Pleasant Street, lays the campus of Maine Maritime Academy. Prior to World War II, this location was the home of the Eastern State Normal School, whose purpose was to train grade school teachers. Maine Maritime Academy has significantly grown over the years and is now a four-year college that graduates officers and engineers for the United States Merchant Marine, as well as educating students in marine-related industries such as yacht and small craft management. Bachelor Degrees are offered in Engineering, International Business and Logistics, Marine Transportation, and Ocean Studies. Graduate studies are offered in Global Logistics and Maritime Management, as well as in International Logistics Management. Presently there are approximately 1,030 students enrolled at the Academy. Maine Maritime Academy's ranking was 7th in the 2016 edition of Best Northern Regional Colleges by U.S. News and World Report. The school was named the Number One public college in the United States by Money Magazine. Photo Caption: Castine, Maine

Armorers wheeled bombs out to the Tu-4 on carts made of steel tubing with rubber tires. Watching them, Boris Gribkov remembered that the groundcrew men at airstrips during the Great Patriotic War hadn’t had such elegant transportation for their high explosives and incendiaries. They’d used whatever they could, sometimes panje wagons, sometimes raw muscle, to get bombs to the bombers. Anton Presnyakov was thinking along with him. “I’ve seen pictures of carts like that at American airstrips in England,” the copilot said. “Now that you mention it, so have I,” Boris replied. “Well, if we can borrow the design for the bomber, no reason we can’t borrow the design for the cart that feeds it, eh?” “We didn’t borrow. We invented,” Lev Vaksman said. “Comrade Reguspatoff is a very clever fellow.” “Reguspatoff?” Boris echoed, puzzled. It sounded as if it ought to be a Russian name, but it wasn’t one he’d ever heard before. “Of course.” The flight engineer’s eyes twinkled. “It’s the abbreviation the Americans put on things they make. It stands for Registered—U.S. Patent Office.

Tesla Motors was created to accelerate the advent of sustainable transport. If we clear a path to the creation of compelling electric vehicles, but then lay intellectual property landmines behind us to inhibit others, we are acting in a manner contrary to that goal. Tesla will not initiate patent lawsuits against anyone who, in good faith, wants to use our technology. When I started out with my first company, Zip2, I thought patents were a good thing and worked hard to obtain them. And maybe they were good long ago, but too often these days they serve merely to stifle progress, entrench the positions of giant corporations and enrich those in the legal profession, rather than the actual inventors. After Zip2, when I realized that receiving a patent really just meant that you bought a lottery ticket to a lawsuit, I avoided them whenever possible. At Tesla, however, we felt compelled to create patents out of concern that the big car companies would copy our technology and then use their massive manufacturing, sales and marketing power to overwhelm Tesla. We couldn’t have been more wrong. The unfortunate reality is the opposite: electric car programs (or programs for any vehicle that doesn’t burn hydrocarbons) at the major manufacturers are small to non-existent, constituting an average of far less than 1% of their total vehicle sales. Given that annual new vehicle production is approaching 100 million per year and the global fleet is approximately 2 billion cars, it is impossible for Tesla to build electric cars fast enough to address the carbon crisis. By the same token, it means the market is enormous. Our true competition is not the small trickle of non-Tesla electric cars being produced, but rather the enormous flood of gasoline cars pouring out of the world’s factories every day. We believe that Tesla, other companies making electric cars, and the world would all benefit from a common, rapidly-evolving technology platform. Technology leadership is not defined by patents, which history has repeatedly shown to be small protection indeed against a determined competitor, but rather by the ability of a company to attract and motivate the world’s most talented engineers. We believe that applying the open source philosophy to our patents will strengthen rather than diminish Tesla’s position in this regard.[431]

Synthetics diminished the great powers' need for strategic raw materials by offering substitutes. Aviation, cryptography, radio, and satellites, meanwhile, enabled those powers to run secure transportation and communication networks without worrying about contiguous territorial access. Innovations in medicine and engineering - such as DDT, antimalarials, plastic-based packaging, and "world-proofed" electronic equipment - further reduced the need for territorial control. They allowed objects and humans to safely travel to hostile terrains, meaning that colonizers didn't have to soften the ground beforehand. Standardization, similarly, made foreign places more accessible. (Page 314, 315)

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Colonial regimes, particularly late colonial regimes, have often been sites of extensive experiments in social engineering.34 An ideology of “welfare colonialism” combined with the authoritarian power inherent in colonial rule have encouraged ambitious schemes to remake native societies. If one were required to pinpoint the “birth” of twentieth-century high modernism, specifying a particular time, place, and individual—in what is admittedly a rather arbitrary exercise, given high modernism’s many intellectual wellsprings—a strong case can be made for German mobilization during World War I and the figure most closely associated with it, Walther Rathenau. German economic mobilization was the technocratic wonder of the war. That Germany kept its armies in the field and adequately supplied long after most observers had predicted its collapse was largely due to Rathenau’s planning.35 An industrial engineer and head of the great electrical firm A.E.G (Allgemeine Elektricitäts-Gesellschaft), which had been founded by his father, Rathenau was placed in charge of the Office of War Raw Materials (Kriegsrohstoffabteilung).36 He realized that the planned rationing of raw materials and transport was the key to sustaining the war effort. Inventing a planned economy step by step, as it were, Germany achieved feats—in industrial production, munitions and armament supply, transportation and traffic control, price controls, and civilian rationing—that had never before been attempted.

Anyone who was, say, sixty years old in Manchester, England, would have witnessed in his or her lifetime a revolution in the manufacturing of cotton and wool textiles, the growth of the factory system, the application of steam power and other astounding new mechanical devices to production, remarkable breakthroughs in metallurgy and transportation (especially railroads), and the appearance of cheap mass-produced commodities. Given the stunning advances in chemistry, physics, medicine, math, and engineering, anyone even slightly attentive to the world of science would have almost come to expect a continuing stream of new marvels (such as the internal combustion engine and electricity). The unprecedented transformations of the nineteenth century may have impoverished and marginalized many, but even the victims recognized that something revolutionary was afoot. All this sounds rather naive today, when we are far more sober about the limits and costs of technological progress and have acquired a postmodern skepticism about any totalizing discourse. Still, this new sensibility ignores both the degree to which modernist assumptions prevail in our lives and, especially, the great enthusiasm and revolutionary hubris that were part and parcel of high modernism.

The underlying values of the transportation system are not the American public's values. They are not even human values. They are values unique to a profession that has been empowered with reshaping an entire continent around a new, experimental idea of how to build human habitat.

2011, I led the Department of Energy’s Quadrennial Technology Review to develop strategies for government support of emerging clean energy technologies. In one town hall meeting, I faced advocates for four different vehicle technologies—internal combustion engines powered by biofuels, compressed natural gas, hydrogen-powered fuel cells, and battery-powered plug-ins. Each of them believed that their technology was the optimal vision for the future, and that all the government had to do was support the development of the appropriate fueling infrastructure. When I reminded them that the country could probably deploy no more than two new fueling technologies at scale, a squabble ensued. There are several reasons I believe that electricity will fuel the passenger vehicles of the future, but one of them is that the existing electrical grid is a good start on the fueling infrastructure. If a widespread transition to plug-in electric cars does come about, systems thinking will be even more important as the electrical and transportation systems would have to work together to accommodate charging millions of vehicles.

She burrowed beneath the covers in Romania in 1987, but soon she was whisked to Britain in the 1940s, transported through an enchanted wardrobe into the snowy and timeless world of Narnia. The wardrobe led her away from her boring engineering-student life and opened a wide vista, filled with adventure. Filled with possibilities. She could never go back to how things were before. Her world had shifted forever.

Therefore, we must invest in research that allows us to grow more healthy food and transport it more effectively. And please make no mistake: that includes accepting genetically modified crops, those engineered to include a trait in the plant that doesn’t occur in its wild form, such as resistance to insects, tolerance to drought, greater vitamin A production, or more efficient use of sunlight to convert CO2 to sugar—as an absolutely necessary part of our food future. With more efficient plants, we could feed up to 200 million additional people, just from plants grown in the US Midwest. 33 These crops have gotten a bad rap for being “unnatural,” although many people who hold this view don’t recognize that most of the food we think of as “natural” has already been subject to significant genetic manipulation. The ears of corn you see at the grocery store look nothing like the wild plant from which modern corn came; over the course of nine thousand years, the spindly finger-length grass known as teosinte was cultivated to evolve larger cobs and more rows of plump, soft, sugary kernels, a process of modification that significantly altered the plant’s genome.34 The apples we’ve grown accustomed to eating have a bit more resemblance to their small, wild ancestors, but good luck finding one of those ancestors; they have been nearly wiped off the planet, and that’s no great loss to our diet, since the biggest genetic contributor to modern apples, Malus sylvestris, is so tart it’s darn near inedible.

Our main problem over the past few days and weeks,’ he said, ‘has lain in trying to connect the various phenomena. In fact, there wasn’t any obvious connection until a jelly-like substance started to crop up. Sometimes it appeared in small quantities, sometimes in larger amounts, but always with the distinguishing characteristic that it disintegrated rapidly on contact with air. Unfortunately the discovery of the jelly only added to the mystery, given its presence in crustaceans, mussels and whales - three types of organism that could hardly be more different. Of course, it might have been some kind of fungus, a jellified version of rabies, an infectious disease like BSE or swine fever. But, if so, why would ships be disappearing or crabs transporting killer algae? There was no sign of the jelly on the worms that infested the slope. They were carrying a different kind of cargo - bacteria that break down hydrates and cause methane gas to rise. Hence the landslide and the tsunami. And what about the mutated species that have been emerging all over the world? Even fish have been behaving oddly. None of it adds up. In that respect, Jack Vanderbilt was right to discern an intelligent mind behind the chaos. But he overestimated our ability - no scientist knows anything like enough about marine ecology to be capable of manipulating it to that extent. People are fond of saying that we know more about space than we do about the oceans. It’s perfectly true, but there’s a simple reason why: we can’t see or move as well in the water as we can in outer space. The Hubble telescope peers effortlessly into different galaxies, but the world’s strongest floodlight only illuminates a dozen square metres of seabed. An astronaut in a spacesuit can move with almost total freedom, but even the most sophisticated divesuit won’t stop you being crushed to death beyond a certain depth. AUVs and ROVs are only operational if the conditions are right. We don’t have the physical constitution or the technology to deposit billions of worms on underwater hydrates, let alone the requisite knowledge to engineer them for a habitat that we barely understand. Besides, there are all the other phenomena: deep-sea cables being destroyed at the bottom of the ocean by forces other than the underwater slide; plagues of jellyfish and mussels rising from the abyssal plains. The simplest explanation would be to see these developments as part of a plan, but such a plan could only be the work of a species that knows the ocean as intimately as we do the land - a species that lives in the depths and plays the dominant role in that particular universe.

When a licensed engineer references Level of Service for a local street, especially one at the very core of their community, it is a tell. It is an indication of a broad misunderstanding of the difference between a road and street, of deep confusion over what it means to build a place and how that is at odds with a driver's level of comfort. We would expect such professionals, if they are intellectually consistent, to live in a home built almost exclusively of hallways.

Their owners returned to Philadelphia each fall, leaving the resort a ghost town. Samuel Richards realized that mass-oriented facilities had to be developed before Atlantic City could become a major resort and a permanent community. From Richards’ perspective, more working-class visitors from Philadelphia were needed to spur growth. These visitors would only come if railroad fares cost less. For several years Samuel Richards tried, without success, to sell his ideas to the other shareholders of the Camden-Atlantic Railroad. He believed that greater profits could be made by reducing fares, which would increase the volume of patrons. A majority of the board of directors disagreed. Finally in 1875, Richards lost patience with his fellow directors. Together with three allies, Richards resigned from the board of directors of the Camden-Atlantic Railroad and formed a second railway company of his own. Richards’ railroad was to be an efficient and cheaper narrow gauge line. The roadbed for the narrow gauge was easier to build than that of the first railroad. It had a 3½-foot gauge instead of the standard 4 feet 8½ inches, so labor and material would cost less. The prospect of a second railroad into Atlantic City divided the town. Jonathan Pitney had died six years earlier, but his dream of an exclusive watering hole persisted. Many didn’t want to see the type of development that Samuel Richards was encouraging, nor did they want to rub elbows with the working class of Philadelphia. A heated debate raged for months. Most of the residents were content with their island remaining a sleepy little beach village and wanted nothing to do with Philadelphia’s blue-collar tourists. But their opinions were irrelevant to Samuel Richards. As he had done 24 years earlier, Richards went to the state legislature and obtained another railroad charter. The Philadelphia-Atlantic City Railway Company was chartered in March 1876. The directors of the Camden-Atlantic were bitter at the loss of their monopoly and put every possible obstacle in Richards’ path. When he began construction in April 1877—simultaneously from both ends—the Camden-Atlantic directors refused to allow the construction machinery to be transported over its tracks or its cars to be used for shipment of supplies. The Baldwin Locomotive Works was forced to send its construction engine by water, around Cape May and up the seacoast; railroad ties were brought in by ships from Baltimore. Richards permitted nothing to stand in his way. He was determined to have his train running that summer. Construction was at a fever pitch, with crews of laborers working double shifts seven days a week. Fifty-four miles of railroad were completed in just 90 days. With the exception of rail lines built during a war, there had never been a railroad constructed at such speed. The first train of the Philadelphia-Atlantic City Railway Company arrived in the resort on July 7, 1877. Prior to Richards’ railroad,

Although a new highway program was politically very contentious, President Eisenhower appointed an advisory committee of executives linked to General Motors, Bechtel engineering, the trucking lobby, and the Teamsters Union (to which truckers belonged) to negotiate the various special interests involved.In 1956 Eisenhower signed the Interstate Highway Act providing for 42,500 miles of a 'National System of Interstate and Defense Highways' across the country at an estimated cost of $27 billion. . . . Journalist Helen Leavitt thought that Congress had been bought and bullied. In her brilliant book Superhighway--Superhoax, she noted that there was no real concern for national defense, since overpasses designed for fourteen-foot vertical clearance were too low to permit the passage of many Army, Navy, and Air Force weapons loaded on transporters, including Atlas missiles. The highway builds had never even consulted the Defense Department.

The image of the locomotive and these signs of industry were closely linked, of course, in that construction of the railroad lines lowered transportation costs, stimulated economic growth, and led to the development of modern coal, iron, and engineering industries. It should be noted, however, that while progressive industrialization may have been a defining characteristic of economic life during the July Monarchy, few painters actually dealt with this aspect of contemporary reality in a direct way. This points up the fact that while Vernet’s mural may have been most representative of its time, it was not typical of the art of his contemporaries. This should caution us against making easy generalizations about the relations between art and society, or believing that art necessarily reflects its social context in a direct and unmediated way.

Let me take you back in time a little,” says Anumita Roychowdhury, an elegant woman in a beige and pale blue wrap. She’s the director of the Center for Science and Environment, a group that’s played a leading role in the years of battles over air quality. In the 1990s, she tells me, Delhi’s air was so bad “you couldn’t go out in the city without your eyes watering.” India had no regulations on vehicles or fuel, so despite advances elsewhere in the world, engines here hadn’t improved for 40 years, and fuel quality was abysmal. It was the activist Supreme Court that changed that. Its judges started issuing orders, and from 1998 to about 2003, a series of important new rules came into force. Polluting industries were pushed out of the city, auto-rickshaws and buses were converted to CNG, and emission limits for vehicles were introduced, then tightened. “These were pretty big steps,” Roychowdhury says, and they brought results. “If you plot the graph of particulate matter in Delhi, you will see after 2002 the levels actually coming down.” The public noticed. “I still remember the 2004 Assembly elections in Delhi, where the political parties were actually fighting with each other to take credit for the cleaner air. It had become an electoral issue.” So how did things go so wrong? The burst of activity petered out, and rapid growth in car ownership erased the improvements that had been won. “If you look at the pollution levels again from 2008 and ’09 onwards, you now see a steady increase,” Roychowdhury says. “We could not keep the momentum going.” Indeed, particulate levels jumped 75 percent in just a few years.14 Even the action that was taken, she believes, “was too little. We had to do a lot more, more aggressively.” Part of the reason government stopped pushing, Roychowdhury believes, is that the moves needed next would have had to address Delhiites’ growing fondness for cars, so would surely have prompted public anger. “There is a hidden subsidy for all of us who use cars today,” she says. “We barely pay anything in terms of parking charges, we barely pay anything in terms of road taxes. It is so easy to buy a car because of easy loans. So there is absolutely no disincentive.” About 80 percent of transportation spending is focused on drivers, even though they’re only about 15 percent of Delhiites. “The entire infrastructure of the city is getting redesigned to facilitate car movement, but not people’s movement.

The world of 1800 was closer to the world of 1500 than it was to the mundane realities of 1900.50 By 1900, half of the world’s fuel production came from coal and oil, electricity generation was rapidly expanding, and new prime movers—steam engines, internal combustion engines, steam and water turbines, and electric motors—were creating new industries and transportation capabilities.

the scaling of piston aircraft engines is also nearly isometrical. Data for more than 50 engines, from the one powering a 1.5-kilogram micro air vehicle to the four turboprops of the Antonov An-22 (an old Soviet heavy transporter weighing 250 tons) showed that their power is proportional to the 0.9th power of mass and 0.8th power of speed.

Eddie,” she said, “will you make a note on this and send it to the press? My plane developed engine trouble while I was flying over the Rocky Mountains to the Taggart Tunnel. I lost my way, looking for an emergency landing, and crashed in an uninhabited mountain section—of Wyoming. I was found by an old sheepherder and his wife, who took me to their cabin, deep in the wilderness, fifty miles away from the nearest settlement. I was badly injured and remained unconscious for most of two weeks. The old couple had no telephone, no radio, no means of communication or transportation, except an old truck that broke down when they attempted to use it. I had to remain with them until I recovered sufficient strength to walk. I walked the fifty miles to the foothills, then hitch-hiked my way to a Taggart station in Nebraska.

Since about one-fourth of CO2 emissions are created by vehicles with internal combustion engines, the expansion of battery-powered transportation provides the only solution.

By the early 1950s, BPR engineers had seemingly lost interest in the broader implications of highway building and focused instead on facilitating automobile and truck transportation.

Tom,” he said to his son, “you have done a wonderful thing. Not only have you completed a marvelous invention and gained thereby a lot of money, and more in prospect, but you have aided in the world’s progress to no small degree. “Speed in transportation is the big problem before the world of commerce today. To move goods from point to point safely and cheaply, as well as rapidly, is the great task of this age. We are entering the Age of Speed. The railroads must solve the problem to compete with motor-truck traffic and fast boats on the lakes and rivers of our land. “You have, by your invention, shoved the clock of progress forward. I am proud of you, my boy. I know now that, no matter what may happen to me, you will make an enviable mark in the world of invention. “You have done much before for the Government in time of stress. But war engines of any kind are not worthy examples of inventive genius beside such a thing as this. “It is the inventions of peace, rather than those of war, that stand for human progress.

Q: What can ordinary people with busy lives and not a lot of political access do to address this stuff? You can try to address it in your own life. You can try to set up your life so you have to drive as little as possible. In so doing, you vote with your feet and your wallet. When more people bike, walk and use public transit, there is greater pressure on elected officials and government agencies to improve these modes of transportation. It thus increases the profitability of public transit and makes cities more desirable places to live. It also helps reduce your carbon footprint and reduces the amount of money going to automobile manufacturers, oil companies and highway agencies. In a globally connected capitalist world, cities and countries are competing for highly skilled labor—programmers, engineers, scientists, etc. To some degree, these people can live anywhere they want. So San Francisco or my current city in Minnesota aren’t just competing with other U.S. cities but are competing with cities in Europe for the best and brightest talent. Polls and statistics show that more and more skilled people want to live in cities that are walkable, bikeable and have good public transit. Also our population is aging and realizing that they don’t want to be trapped in automobile-oriented retirement communities in Florida or the southwest USA. They also want improved walkability and transit. Finally, there’s been an explosion of obesity in the USA with resulting increases in healthcare costs. Many factors contribute to this but increased amounts of driving and a lack of daily exercise are major factors. City, state and business leaders in the US are increasingly aware of all this. It is part of Gil Peñalosa’s “8-80” message (the former parks commissioner of Bogotá, Colombia) and many other leaders. (2015 interview with Microcosm Publishing)

Every time we sit down to breakfast, we are likely to be benefiting from a dozen such prehistoric inventions. Who was the first person to figure out that you could make bread rise by the addition of those microorganisms we call yeasts? We have no idea, but we can be almost certain she was a woman and would most likely not be considered ‘white’ if she tried to immigrate to a European country today; and we definitely know her achievement continues to enrich the lives of billions of people. What we also know is that such discoveries were, again, based on centuries of accumulated knowledge and experimentation – recall how the basic principles of agriculture were known long before anyone applied them systematically – and that the results of such experiments were often preserved and transmitted through ritual, games and forms of play (or even more, perhaps, at the point where ritual, games and play shade into each other). ‘Gardens of Adonis’ are a fitting symbol here. Knowledge about the nutritious properties and growth cycles of what would later become staple crops, feeding vast populations – wheat, rice, corn – was initially maintained through ritual play farming of exactly this sort. Nor was this pattern of discovery limited to crops. Ceramics were first invented, long before the Neolithic, to make figurines, miniature models of animals and other subjects, and only later cooking and storage vessels. Mining is first attested as a way of obtaining minerals to be used as pigments, with the extraction of metals for industrial use coming only much later. Mesoamerican societies never employed wheeled transport; but we know they were familiar with spokes, wheels and axles since they made toy versions of them for children. Greek scientists famously came up with the principle of the steam engine, but only employed it to make temple doors that appeared to open of their own accord, or similar theatrical illusions. Chinese scientists, equally famously, first employed gunpowder for fireworks.

Knowledge about the nutritious properties and growth cycles of what would later become staple crops, feeding vast populations – wheat, rice, corn – was initially maintained through ritual play farming of exactly this sort. Nor was this pattern of discovery limited to crops. Ceramics were first invented, long before the Neolithic, to make figurines, miniature models of animals and other subjects, and only later cooking and storage vessels. Mining is first attested as a way of obtaining minerals to be used as pigments, with the extraction of metals for industrial use coming only much later. Mesoamerican societies never employed wheeled transport; but we know they were familiar with spokes, wheels and axles since they made toy versions of them for children. Greek scientists famously came up with the principle of the steam engine, but only employed it to make temple doors that appeared to open of their own accord, or similar theatrical illusions. Chinese scientists, equally famously, first employed gunpowder for fireworks.

More important, that much-admired post-1970 ascent of electronic architecture and performance has no counterpart in nearly all other aspects of our lives: rapid exponential growth has not marked the advances in either fundamental economic activities on which modern civilization depends for its survival—ranging from crop yields to efficiency gains in energy uses, from transportation speeds to the ability to design and complete large engineering projects—or the critical determinants of health and quality of life, including the rate of new drug discoveries and gains in longevity.

The engineers were constantly baffled by what Musk would fund and what he wouldn’t. Back at headquarters, someone would ask to buy a $200,000 machine or a pricey part that they deemed essential to Falcon 1’s success, and Musk would deny the request. And yet he was totally comfortable paying a similar amount to put a shiny surface on the factory floor to make it look nice. On Omelek, the workers wanted to pave a two-hundred-yard pathway between the hangar and the launchpad to make it easier to transport the rocket. Musk refused. This left the engineers moving the rocket and its wheeled support structure in the fashion of the ancient Egyptians. They laid down a series of wooden planks and rolled the rocket across them, grabbing the last piece of wood from the back and running it forward in a continuous cycle. The whole situation was ludicrous. A start-up rocket company had ended up in the middle of nowhere trying to pull off one of the most difficult feats known to man, and, truth be told, only a

It is scarcely an exaggeration to say that mechanical invention until the thirteenth century A.D. owed a greater debt to warfare than to the arts of peace. This holds over long stretches of history. The Bronze Age chariot preceded the general use of wagons for transportation, burning oil was used to repel enemies besieging a city before it was employed for powering engines or heating buildings: so, too, inflated life preservers were used by Assyrian armies to cross rivers thousands of years before 'water-wings' were invented for civilian swimming. Metallurgical applications, too, developed more rapidly in the military than in the civilian arts: the scythe was attached to chariots for mowing down men before it was attached to agricultural mowing machines; while Archimedes' knowledge of mechanics and optics was applied to destroying the Roman fleet attacking Syracuse before it was put to any more constructive industrial use. From Greek fire to atom bombs, from ballistas to rockets, warfare was the chief source of those mechanical inventions that demanded a metallurgical and chemical background.

One day in 1885, the twenty-three-year old Henry Ford got his first look at the gas-powered engine, and it was instant love. Ford had apprenticed as a machinist and had worked on every conceivable device, but nothing could compare to his fascination with this new type of engine, one that created its own power. He envisioned a whole new kind of horseless carriage that would revolutionize transportation. He made it his Life’s Task to be the pioneer in developing such an automobile. Working the night shift at the Edison Illuminating Company as an engineer, during the day he would tinker with the new internal-combustion engine he was developing. He built a workshop in a shed behind his home and started constructing the engine from pieces of scrap metal he salvaged from anywhere he could find them. By 1896, working with friends who helped him build a carriage, he completed his first prototype, which he called the Quadricycle, and debuted it on the streets of Detroit. At the time there were many others working on automobiles with gas-powered engines. It was a ruthlessly competitive environment in which new companies died by the day. Ford’s Quadricycle looked nice and ran well, but it was too small and incomplete for large-scale production. And so he began work on a second automobile, thinking ahead to the production end of the process. A year later he completed it, and it was a marvel of design. Everything was geared toward simplicity and compactness. It was easy to drive and maintain. All that he needed was financial backing and sufficient capital to mass-produce it. To manufacture automobiles in the late 1890s was a daunting venture. It required a tremendous amount of capital and a complex business structure, considering all of the parts that went into production. Ford quickly found the perfect backer: William H. Murphy, one of the most prominent businessmen in Detroit. The new company was dubbed the Detroit Automobile Company, and all who were involved had high hopes. But problems soon arose. The car Ford had designed as a prototype needed to be reworked—the parts came from different places; some of them were deficient and far too heavy for his liking. He kept trying to refine the design to come closer to his ideal. But it was taking far too long, and Murphy and the stockholders were getting restless. In 1901, a year and a half after it had started operation, the board of directors dissolved the company. They had lost faith in Henry Ford.

Modern biomimicry is far more than just copying nature's shapes. It includes systematic design and problem-solving processes, which are now being refined by scientists and engineers in universities and institutes worldwide. The first step in any of these processes is to clearly define the challenge we're trying to solve. Then we can determine whether the problem is related to form, function, or ecosystem. Next, we ask what plant, animal, or natural process solves a similar problem most effectively. For example, engineers trying to design a camera lens with the widest viewing angle possible found inspiration in the eyes of bees, which can see an incredible five-sixths of the way, or three hundred degrees, around their heads. The process can also work in reverse, where the exceptional strategies of a plant, animal, or ecosystem are recognized and reverse engineered. De Mestral's study of the tenacious grip of burrs on his socks is an early example of reverse engineering a natural winner, while researchers' fascination at the way geckos can hang upside down from the ceiling or climb vertical windows has now resulted in innovative adhesives and bandages. Designs based on biomimicry offer a range of economic benefits. Because nature has carried out trillions of parallel, competitive experiments for millions of years, its successful designs are dramatically more energy efficient than the inventions we've created in the past couple of hundred years. Nature builds only with locally derived materials, so it uses little transport energy. Its designs can be less expensive to manufacture than traditional approaches, because nature doesn't waste materials. For example, the exciting new engineering frontier of nanotechnology mirrors nature's manufacturing principles by building devices one molecule at a time. This means no offcuts or excess. Nature can't afford to poison itself either, so it creates and combines chemicals in a way that is nontoxic to its ecosystems. Green chemistry is a branch of biomimicry that uses this do-no-harm principle, to develop everything from medicines to cleaning products to industrial molecules that are safe by design. Learning from the way nature handles materials also allows one of our companies, PaxFan, to build fans that are smaller and lighter while giving higher performance. Finally, nature has methods to recycle absolutely everything it creates. In natures' closed loop of survival on this planet, everything is a resource and everything is recycled-one of the most fundamental components of sustainability. For all these reasons, as I hear one prominent venture capitalist declare, biomimicry will be the business of the twenty-first century. The global force of this emerging and fascinating field is undeniable and building on all societal levels.

trained and ready to fight. “I now have a really intensive faith in the First Division. They are 1,000 percent better than they were…. They are young but are hard and fit. Please remember that I am thinking of you and Sonny all the time.” He swung a leg over the side of the Reina del Pacifico and with a gymnast’s grace scrambled down the net to the waiting boat below.   Chaos awaited him on the beaches near Arzew. An unanticipated westerly set had pushed the transports and landing craft off course. Dozens of confused coxswains tacked up and down the coast in the dark, looking for the right beaches. Most of the soldiers carried more than 100 pounds of equipment; one likened himself to a medieval knight in armor who had to be winched into the saddle. Once ashore, feeling the effect of weeks aboard ship with a poor diet and little exercise, they staggered into the dunes, shedding gas capes, goggles, wool undershirts, and grenades. Landing craft stranded by an ebb tide so jammed the beaches that bulldozers had to push them off, ruining their propellers and rudders. The flat-bottomed oil tankers that were supposed to haul light tanks onto the beach instead ran aground 300 feet from shore; engineers spent hours building a causeway through the surf.

It did occur to him that perhaps he’d gone to the wrong Academy – the guys in the Space Fleet always had more interesting stories to tell at the spaceport bars. You know, tales about the dude who got vaporized in a plasma accident in the engineering section, or the fella who got turned into a blob of weird space jelly by some alien virus – or the time someone flew a starship into an astor-field at warp four by mistake (they were still trying to find the black box on that one). The Imperial Space Fleet’s recruiting office sure didn’t go around advertising ‘Join up, see the universe, meet interesting aliens and die screaming’, but it was known there were risks involved. It was part of the job after all, and yet somehow, they still got recruits signing up in droves. Yes, indeedy – the stories were far more interesting than his – took a load of ore to Gorda, took a load of mining equipment back to Tordrazil. Took a load of Florpavian Flame-birds to a zoo on Deanna, took a load of machinery to Salus. Picked up and dropped off a few passengers on the way. Still, Florpavian Flame-birds were a risky cargo… and damned tricky to transport – which is probably the only reason he’d had any entertainment at all on the last trip.

Travel in Italy has always been difficult because of the hills and mountains. The Romans of ancient Italy were great engineers, and about 2,000 years ago they laid out a system of roads across the country to improve transport. Some of their routes are still in use today.

After showing them the blast furnaces, rolling mills and armour-plate works, Hitler and Ribbentrop took Mussolini alone into a hall where Krupp engineers took the tarpaulins off Hitler's proudest possession – a gun barrel so huge that it had to be transported on two parallel railroad tracks. Mussolini stroked it and congratulated the Führer, clearly astonished at the weapon's size.

if we were to build a Great Pyramid today, we would need a lot of patience. In preparation for his book "5/5/2000 Ice: The Ultimate Disaster", Richard Noone asked Merle Booker, technical director of the Indiana Limestone Institute of America, to prepare a time study of what it would take to quarry, fabricate, and ship enough limestone to duplicate the Great Pyramid. Using the most modern quarrying equipment available for cutting, lifting, and transporting the stone, Booker estimated that the present-day Indiana limestone industry would need to triple its output, and it would take the entire industry, which as I have said includes thirty-three quarries, twenty-seven years to fill the order for 131,467,940 cubic feet of stone. These estimates were based on the assumption that production would proceed without problems. Then we would be faced with the task of putting the limestone blocks in place. The level of accuracy in the base of the Great Pyramid is astounding, and is not demanded, or even expected, by building codes today. Civil engineer Roland Dove, of Roland P. Dove & Associates, explained that .02 inch per foot variance was acceptable in modern building foundations. When I informed him of the minute variation in the foundation of the Great Pyramid, he expressed disbelief and agreed with me that in this particular phase of construction, the builders of the pyramid exhibited a state of the art that would be considered advanced by modern standards.

It now remains for those who are absolutely convinced that the ancient Egyptians constructed the pyramids using primitive techniques to build a pyramid themselves, using those same techniques that they propose the Egyptians used. As part of such an attempt, it would help if they cut out just one seventy-ton block of granite from the Aswan quarry, which is located five hundred miles away, using their hardened copper chisels or dolerite balls and then transported the block to the Giza Plateau with their barges, ropes, and manpower. If the proponents of traditional theories of constructing the pyramids are able to accomplish this feat, then we should give serious consideration to their proposals about pyramid construction.

I was expecting to find a scooter company. One of those trendy, battery-powered skateboard or Segway-like rolling transporters used in place of walking. What I found was something entirely more audacious.  PPS was developing a jetpack. An actual jetpack. One of those James Bond, Buck Rogers, Rocket Man-style engines you strapped to your back and flew with. I supposed the Space Coast location should have been a tipoff, but I missed that clue. The PPS website was just a Work In Progress placeholder, but I did find a few other companies in the niche, and one had a very impressive video. It showed a man flying over rivers and lakes using a device that looked exactly like what the comic books predicted. At first I thought it was faked, but it proved to be real. USA Today confirmed it in a front page story on November 11, 2015 titled “Man on jetpack flies around Statue of Liberty.”  That meant the core Iron Man technology had existed for years. If a fatal flaw hadn’t been found, it would now be in the refinement and regulatory approval stage. It occurred to me that between jetpacks and drones and hover boards and self-driving cars, the Department of Transportation had to be hopelessly swamped. The world was evolving at an incredible pace. It was no wonder that so many people

Mike was all over the Douglas DC-3 transport. The 1936 version that Jimmy bought could seat 21 passengers. The low-wing monoplane was powered by two 1,200-horsepower Pratt & Whitney radial engines and was equipped with a retractable main landing gear.

Artificial reefs create significant breeding grounds for a diverse group of fish; the Delaware reefs have seen a 400 percent increase in biomass since the first cars were sunk. (Artificial reefs also have the secondary effect of preventing beach erosion.) No longer needed for mass transportation, the abandoned subway cars have taken on a new occupation in their retirement years. They are now ecosystem engineers.

FOOD FOR THOUGHT: Once upon a time our politicians did not tend to apologize for our country’s prior actions! Here’s a refresher on how some of our former patriots handled negative comments about our great country. These are quite good JFK’S Secretary of State, Dean Rusk, was in France in the early 60’s when De Gaulle decided to pull out of NATO. De Gaulle said he wanted all US military out of France as soon as possible. Rusk’s response: “Does that include those who are buried here?” De Gaulle did not respond. You could have heard a pin drop. When in England, at a fairly large conference, Colin Powell was asked by the Archbishop of Canterbury if our plans for Iraq were just an example of ‘empire building’ by George Bush. He answered by saying, “Over the years, the United States has sent many of its fine young men and women into great peril to fight for freedom beyond our borders. The only amount of land we have ever asked for in return is enough to bury those that did not return.” You could have heard a pin drop. There was a conference in France where a number of international engineers were taking part, including French and American. During a break, one of the French engineers came back into the room saying, “Have you heard the latest dumb stunt Bush has done? He has sent an aircraft carrier to Indonesia to help the tsunami victims. What does he intend to do, bomb them?” A Boeing engineer stood up and replied quietly: “Our carriers have three hospitals on board that can treat several hundred people; they are nuclear powered and can supply emergency electrical power to shore facilities; they have three cafeterias with the capacity to feed 3,000 people three meals a day, they can produce several thousand gallons of fresh water from sea water each day, and they carry half a dozen helicopters for use in transporting victims and injured to and from their flight deck. We have eleven such ships; how many does France have?” You could have heard a pin drop. A U.S. Navy Admiral was attending a naval conference that included Admirals from the U.S., English, Canadian, Germany and France. At morning tea the Frenchman complained that the conference should be conducted in French since it was being held in Paris. The German replied that, so far as he could see, the reason that it was being held in English was as a mark of respect to the other attendees, since their troops had shed so much blood so that the Frenchman wouldn’t be speaking German.

Under Tyson, all these businesses have been drawn onto one property. The company controls every step of meat production, with each aspect being centrally directed from the company’s headquarters in Springdale. The company’s control spans the lifetime of the animals it raises. Before there is a chicken or an egg, there is Tyson. The company’s geneticists select which kinds of birds will be grown. They breed and crossbreed the avian bloodlines to engineer meaty breasts and rapid metabolism in the same way automobiles are first cut from clay, then engineered on a drafting board before they’re built. The birds begin their brief life at the Tyson plant, within the heated hive of its industrial hatchery. The company produces more than two billion eggs a year, but none of them are sold to consumers. They are all hatched inside the company’s buildings and the chicks are transported in Tyson trucks to Tyson farms. The Tyson trucks retrieve the birds six weeks later, bringing them back to the plant, where the chickens are funneled into chutes in the side of the slaughterhouses