Manufacturing Technology Quotes

I have a foreboding of an America in my children's or grandchildren's time -- when the United States is a service and information economy; when nearly all the manufacturing industries have slipped away to other countries; when awesome technological powers are in the hands of a very few, and no one representing the public interest can even grasp the issues; when the people have lost the ability to set their own agendas or knowledgeably question those in authority; when, clutching our crystals and nervously consulting our horoscopes, our critical faculties in decline, unable to distinguish between what feels good and what's true, we slide, almost without noticing, back into superstition and darkness... The dumbing down of American is most evident in the slow decay of substantive content in the enormously influential media, the 30 second sound bites (now down to 10 seconds or less), lowest common denominator programming, credulous presentations on pseudoscience and superstition, but especially a kind of celebration of ignorance

I have a foreboding of America in my children’s or grandchildren’s time–when the United States is a service and information economy; when nearly all of the manufacturing industries have slipped away to other countries; when awesome technological powers are in the hands of a very few, and no one representing the public interest can even grasp the issues; when the people have lost the ability to set their own agendas or knowledgeably question those in authority; with our critical faculties in decline, unable to distinguish between what feels good and what’s true, we slide almost without noticing, back into superstition and darkness. And when the dumbing down of America is most evident in the slow decay of substantive content in the enormously influential media, the 30-second sound bites now down to 10 seconds or less, lowest-common-denominator programming, credulous presentations on pseudoscience and superstition, but especially a kind of celebration of ignorance.

For the first time in architectural history, we're approaching the resolution and complexity of the natural world by creating new technologies that will ultimately enable us to design a beam as if it were a branch or an HVAC and waste removal system as if it were a photosynthetic GI tract engineered to convert carbon into biofuel.

At the root of Japanese manufacturing lies a feminine delicacy and shyness as well as a childlike curiosity and fantasy-filled worldview.

Suddenly, those trusted institutions seemed to be acting in concert to generate fear, promote obedience, discourage critical thinking, and herd seven billion people to march to a single tune, culminating in mass public health experiments with a novel, shoddily tested and improperly licensed technology so risky that manufacturers refused to produce it unless every government on Earth shielded them from liability

An Urban Indian belongs to the city, and cities belong to the earth. Everything here is formed in relation to every other living and nonliving thing from the earth. All our relations. The process that brings anything to its current form—chemical, synthetic, technological, or otherwise—doesn’t make the product not a product of the living earth. Buildings, freeways, cars—are these not of the earth? Were they shipped in from Mars, the moon? Is it because they’re processed, manufactured, or that we handle them? Are we so different? Were we at one time not something else entirely, Homo sapiens, single-celled organisms, space dust, unidentifiable pre-bang quantum theory? Cities form in the same way as galaxies.

When we're able to communicate in nature's language; when we're able to transcend the view that nature is a boundless entity; even transcending the building as the kernel of the architectural project; when we invite scientific inquiry and technological innovation, fusing atoms with bits and bits with genes - only then will the art of building enable new forms of interaction between humans and their environment. Only then will we be able to design, construct and evolve as equals.

The difference between successful and unsuccessful people is that successful ones know that the most unprofitable thing ever manufactured is an excuse.

Humans are the reproductive organs of technology. We multiply manufactured artifacts and spread ideas and memes.

But technology is simply the making of things and the making of things can't by its own nature be ugly or there would be no possibility for beauty in the arts, which also include the making of things. Actually a root word of technology, techne, originally meant "art." The ancient Greeks never separated art from manufacture in their minds, and so never developed separate words for them.

Unfortunately robots capable of manufacturing robots do not exist. That would be the philosopher's stone, the squaring of the circle.

Consider all tabulation systems infected by bad actors until a third party, not affiliated with the manufacturer or election officials, proves they are secure.

The value we provide at Mayflower-Plymouth exists at the convergence of various technologies and studies including Blockchain, cryptography, quantum computing, permaculture design principles, artificial intelligence, stigmergy, forestry, economics, additive manufacturing, big data, advanced logistics and more.

Suddenly, those trusted institutions seemed to be acting in concert to generate fear, promote obedience, discourage critical thinking, and herd seven billion people to march to a single tune, culminating in mass public health experiments with a novel, shoddily tested and improperly licensed technology so risky that manufacturers refused to produce it unless every government on Earth shielded them from liability.

The value we provide at Mayflower exists at the convergence of various new technologies and studies including Blockchain, cryptography, quantum computing, artificial intelligence, stigmergy, additive manufacturing, big data, advanced logistics and more.

Everything he knew was a result of artificial intelligence. Manufactured data and memories. Programmed technology. A created life.

The essential difference between rich societies and poor societies does not stem from any greater effort the former devote to work, nor even from any greater technological knowledge the former hold. Instead it arises mainly from the fact that rich nations possess a more extensive network of capital goods wisely invested from an entrepreneurial standpoint. These goods consists of machines, tools, computers, buildings, semi-manufactured goods, software, etc., and they exist due to prior savings of the nation's citizens. In other words, comparatively rich societies possess more wealth because they have more time accumulated in the form of capital goods, which places them closer in time to the achievement of much more valuable goals.

Companies with new technologies are free to disrupt almost any industry they choose—journalism, television, music, manufacturing—so long as they don’t disrupt the financial operating system churning beneath it all. Hell,

Such an AI might also be able to produce a detailed blueprint for how to bootstrap from existing technology (such as biotechnology and protein engineering) to the constructor capabilities needed for high-throughput atomically precise manufacturing that would allow inexpensive fabrication of a much wider range of nanomechanical structures.

The Donbas was a heavily populated and productive manufacturing area, with Donetsk alone accounting for about 12 percent of Ukraine’s gross domestic product. The area nearby also accounted for something near 90 percent of Ukraine’s oil and gas production, and fracking technology promised to open new fields. Grabbing the Donbas was a twofer. Russia could cripple the teetering economy of Ukraine and scoop up a healthy supply of oil and gas. Novorossiya!

One of the great challenges in healthcare technology is that medicine is at once an enormous business and an exquisitely human endeavor; it requires the ruthless efficiency of the modern manufacturing plant and the gentle hand-holding of the parish priest; it is about science, but also about art; it is eminently quantifiable and yet stubbornly not.

It is an irony of history that the first and greatest success of scientists in persuading governments of the indispensability of modern scientific theory to society was in the war against fascism. It is an even greater and more tragic irony that it was anti-fascist scientists who convinced the American government of the feasibility and necessity of manufacturing nuclear arms, which were then constructed by an international team of largely anti-fascist scientists.

I have a foreboding of an America in my children’s or grandchildren’s time—when the United States is a service and information economy; when nearly all the key manufacturing industries have slipped away to other countries; when awesome technological powers are in the hands of a very few, and no one representing the public interest can even grasp the issues; when the people have lost the ability to set their own agendas or knowledgeably question those in authority; when, clutching our crystals and nervously consulting our horoscopes, our critical faculties in decline, unable to distinguish between what feels good and what’s true, we slide, almost without noticing, back into superstition and darkness.

I find these comparisons particularly poignant: life versus death, hope versus fear. Space exploration and the highly mechanized destruction of people use similar technology and manufacturers, and similar human qualities of organization and daring. Can we not make the transition from automated aerospace killing to automated aerospace exploration of the solar system in which we live?

Most persons are surprised, and many distressed, to learn that essentially the same objections commonly urged today against computers were urged by Plato in the Phaedrus (274–7) and in the Seventh Letter against writing. Writing, Plato has Socrates say in the Phaedrus, is inhuman, pretending to establish outside the mind what in reality can be only in the mind. It is a thing, a manufactured product. The same of course is said of computers. Secondly, Plato's Socrates urges, writing destroys memory. Those who use writing will become forgetful, relying on an external resource for what they lack in internal resources. Writing weakens the mind.

A Nation State or Cyber-Mercenary won’t hack e-voting machines one by one. This takes too long and will have minimal impact. Instead, they’ll take an easier approach like spear phishing the manufacturer with malware and poison the voting machine update pre-election and allow the manufacturer to update each individual machine with a self-deleting payload that will target the tabulation process.

Hacking a national election is simple. Exploit a vulnerability in the manufacturer's network, poison the tabulation software update with self-deleting malware and let the manufacturer send to their field reps and election consultants who update the election systems.

I don't know where the idea of Vikings having horns on their helmets came from, but it's a brilliant one. In every possible way, other than the literal truth, they totally had horns on their helmets. Horned helmets was absolutely their vibe and I feel we all have a right to that deeper artistic truth. They had limited technology and manufacturing helmets was pretty tricky for them, I imagine, so putting horns on them wouldn't have been workable, and wouldn't ave increased the functionality of the helmets, but I swear they'd have given it a go if they'd thought of it.

The scientific networks that produced EUV spanned the world, bringing together scientists from countries as diverse as America, Japan, Slovenia, and Greece. However, the manufacturing of EUV wasn’t globalized, it was monopolized. A single supply chain managed by a single company would control the future of lithography.

Your son is more likely to seek a job in a sector that is being increasingly outsourced overseas- as with computer technology and manufacturing, as well as online jobs. Your daughter is more likely to hold jobs in stable sectors that are more recession proof, like health and education, both of which are 75 percent women.

Right now we think of manufacturing as happening in China. But as manufacturing costs sink because of robots, the costs of transportation become a far greater factor than the cost of production. Nearby will be cheap. So we’ll get this network of locally franchised factories, where most things will be made within five miles of where they are needed.

The growing importance of technology and manufactured output reduced the impact of the weather on economic cycles.

Manufacturing jobs in the United States currently account for well under 10 percent of total employment.

Microchip manufactures, similarly, cannot make their transistors too thin, or the performance of these devices will suffer from electon leakage due to tunneling effects.

Most improved things can be improved.

However, one intriguing shift that suggests there are limits to automation was the recent decision by Toyota to systematically put working humans back into the manufacturing process. In quality and manufacturing on a mass scale, Toyota has been a global leader in automation technologies based on the corporate philosophy of kaizen (Japanese for “good change”) or continuous improvement. After pushing its automation processes toward lights-out manufacturing, the company realized that automated factories do not improve themselves. Once Toyota had extraordinary craftsmen that were known as Kami-sama, or “gods” who had the ability to make anything, according to Toyota president Akio Toyoda.49 The craftsmen also had the human ability to act creatively and thus improve the manufacturing process. Now, to add flexibility and creativity back into their factories, Toyota chose to restore a hundred “manual-intensive” workspaces.

Actually, a root word of technology, techne, originally meant "art". The ancient Greeks never separated art from manufacture in their minds, and so never developed separate words for them.

Science is more than a body of knowledge; it is a way of thinking. I have a foreboding of an America in my children’s or grandchildren’s time—when the United States is a service and information economy; when nearly all the key manufacturing industries have slipped away to other countries; when awesome technological powers are in the hands of a very few, and no one representing the public interest can even grasp the issues; when the people have lost the ability to set their own agendas or knowledgeably question those in authority; when, clutching our crystals and nervously consulting our horoscopes, our critical faculties in decline, unable to distinguish between what feels good and what’s true, we slide, almost without noticing, back into superstition and darkness.

In fact, advancing technology has already had a dramatic impact on Chinese factory jobs; between 1995 and 2002 China lost about 15 percent of its manufacturing workforce, or about 16 million jobs.9

However, interrupting technology workers is easy, because the consequences are invisible to almost everyone, even though the negative impact to productivity may be far greater than in manufacturing.

Fabricating and miniaturizing semiconductors has been the greatest engineering challenge of our time. Today, no firm fabricates chips with more precision than the Taiwan Semiconductor Manufacturing Company, better known as TSMC.

Perhaps the most powerful and appealing aspect of another's words, however, is simply their convenience. Whether distilled in the briefest apophthegm, or spread out across some voluminous tome, the thought is ready-made, the heavy lifting done. It's there to be used like a weapon or tool, and as time wanders on, seemingly leaving us fewer and fewer new things to say, it becomes ever more useful. As technology moves forward, as well, it also becomes much easier. Indeed, in this "information age" where so much is available to so many so quickly that enlightenment nearly verges on light pollution, it can sometimes appear that expression has been reduced to nothing more than a mad race to unearth and claim references. As such, the citation is also there to be donned, like some article of fashion from which we may reap the praise of discriminating taste without ever exerting ourself in the actual toil of manufacture.

The computer may be incompetent in itself--that is, unable to do the work for which it was designed. This kind of incompetence can never be eliminated, because the Peter Principle applies in the plants where computers are designed and manufactured.

the consequences of scientific illiteracy are far more dangerous in our time than in any that has come before. It’s perilous and foolhardy for the average citizen to remain ignorant about global warming, say, or ozone depletion, air pollution, toxic and radioactive wastes, acid rain, topsoil erosion, tropical deforestation, exponential population growth. Jobs and wages depend on science and technology. If our nation can’t manufacture, at high quality and low price, products people want to buy, then industries will continue to drift away and transfer a little more prosperity to other parts of the world. Consider the social ramifications of fission and fusion power, supercomputers, data “highways,” abortion, radon, massive reductions in strategic weapons, addiction, government eavesdropping on the lives of its citizens, high-resolution TV, airline and airport safety, fetal tissue transplants, health costs, food additives, drugs to ameliorate mania or depression or schizophrenia, animal rights, superconductivity, morning-after pills, alleged hereditary antisocial predispositions, space stations, going to Mars, finding cures for AIDS and cancer. How can we affect national policy—or even make intelligent decisions in our own lives—if we don’t grasp the underlying issues?

I believe that sociable technology will always disappoint because it promises what it can’t deliver,” Turkle writes. “It promises friendship but can only deliver ‘performances.’ Do we really want to be in the business of manufacturing friends that will never be friends?

Synthetic biology56 is built around the idea that DNA is essentially software—nothing more than a four-letter code arranged in a specific order. Much like with computers, the code drives the machine. In biology, the order of the code governs the cell’s manufacturing processes, instructing it to make specific proteins and such. But, as with all software, DNA can be reprogrammed. Nature’s original code can be swapped out for new, human-written code. We can co-opt the machinery of life, telling it to produce—well, whatever we can think of.

The collaboration between secretaries of state, election officials and the voting system manufacturers on the matter of enforcing this black box proprietary code secrecy with election systems, is nothing less than the commoditization and monetization of American Democracy

The intellectual ethic of a technology is rarely recognized by its inventors. They are usually so intent on solving a particular problem or untangling some thorny scientific or engineering dilemma that they don't see the broader implications of their work. The users of the technology are also usually oblivious to its ethic. They, too, are concerned with the practical benefits they gain from employing the tool. Our ancestors didn't develop or use maps in order to enhance their capacity for conceptual thinking or to bring the world's hidden structures to light. Nor did they manufacture mechanical clocks to spur the adoption of a more scientific mode of thinking. These were by-products of the technologies. But what by-products! Ultimately, it's an invention's intellectual work ethic that has the most profound effect on us.

Everyone has a time machine. Everyone is a time machine. It's just that most people's machines are broken. The strangest and hardest kind of time travel is the unaided kind. People get stuck, people get looped. People get trapped. But we are all time machines. We are all perfectly engineered time machines, technologically equipped to allow the inside user, the traveler riding inside each of us, to experience time travel, and loss, and understanding. We are universal time machines manufactured to the most exacting specifications possible. Every single one of us.

There can be no question that the loss of TV manufacture in the United States was a disruption, but the loss had not been brought about by a disruptive technology or disruptive innovation. The key factor in disruption was the Asian approach to innovation, based primarily on process improvement and optimal design.

. I have a foreboding of an America in my children’s or grandchildren’s time—when the United States is a service and information economy; when nearly all the key manufacturing industries have slipped away to other countries; when awesome technological powers are in the hands of a very few, and no one representing

Breakthroughs in information and communications technology are leading to forms of dematerialization unimaginable just a decade ago. Consider smartphones. They require more energy to manufacture and operate than older cell phones. But by obviating the need for separate, physical newspapers, books, magazines, cameras, watches, alarm clocks, GPS systems, maps, letters, calendars, address books, and stereos, they will likely significantly reduce humanity’s use of energy and materials over the next century. Such examples suggest that holding technological progress back could do far more environmental damage than accelerating it.

Over the years I have read many, many books about the future, my ‘we’re all doomed’ books, as Connie liked to call them. ‘All the books you read are either about how grim the past was or how gruesome the future will be. It might not be that way, Douglas. Things might turn out all right.’ But these were well-researched, plausible studies, their conclusions highly persuasive, and I could become quite voluble on the subject. Take, for instance, the fate of the middle-class, into which Albie and I were born and to which Connie now belongs, albeit with some protest. In book after book I read that the middle-class are doomed. Globalisation and technology have already cut a swathe through previously secure professions, and 3D printing technology will soon wipe out the last of the manufacturing industries. The internet won’t replace those jobs, and what place for the middle-classes if twelve people can run a giant corporation? I’m no communist firebrand, but even the most rabid free-marketeer would concede that market-forces capitalism, instead of spreading wealth and security throughout the population, has grotesquely magnified the gulf between rich and poor, forcing a global workforce into dangerous, unregulated, insecure low-paid labour while rewarding only a tiny elite of businessmen and technocrats. So-called ‘secure’ professions seem less and less so; first it was the miners and the ship- and steel-workers, soon it will be the bank clerks, the librarians, the teachers, the shop-owners, the supermarket check-out staff. The scientists might survive if it’s the right type of science, but where do all the taxi-drivers in the world go when the taxis drive themselves? How do they feed their children or heat their homes and what happens when frustration turns to anger? Throw in terrorism, the seemingly insoluble problem of religious fundamentalism, the rise of the extreme right-wing, under-employed youth and the under-pensioned elderly, fragile and corrupt banking systems, the inadequacy of the health and care systems to cope with vast numbers of the sick and old, the environmental repercussions of unprecedented factory-farming, the battle for finite resources of food, water, gas and oil, the changing course of the Gulf Stream, destruction of the biosphere and the statistical probability of a global pandemic, and there really is no reason why anyone should sleep soundly ever again. By the time Albie is my age I will be long gone, or, best-case scenario, barricaded into my living module with enough rations to see out my days. But outside, I imagine vast, unregulated factories where workers count themselves lucky to toil through eighteen-hour days for less than a living wage before pulling on their gas masks to fight their way through the unemployed masses who are bartering with the mutated chickens and old tin-cans that they use for currency, those lucky workers returning to tiny, overcrowded shacks in a vast megalopolis where a tree is never seen, the air is thick with police drones, where car-bomb explosions, typhoons and freak hailstorms are so commonplace as to barely be remarked upon. Meanwhile, in literally gilded towers miles above the carcinogenic smog, the privileged 1 per cent of businessmen, celebrities and entrepreneurs look down through bullet-proof windows, accept cocktails in strange glasses from the robot waiters hovering nearby and laugh their tinkling laughs and somewhere, down there in that hellish, stewing mess of violence, poverty and desperation, is my son, Albie Petersen, a wandering minstrel with his guitar and his keen interest in photography, still refusing to wear a decent coat.

I have a foreboding of an America in my children's or grandchildren's time -- when the United States is a service and information economy; when nearly all the manufacturing industries have slipped away to other countries; when awesome technological powers are in the hands of a very few, and no one representing the public interest can even grasp the issues; when the people have lost the ability to set their own agendas or knowledgeably question those in authority; when, clutching our crystals and nervously consulting our horoscopes, our critical faculties in decline, unable to distinguish between what feels good and what's true, we slide, almost without noticing, back into superstition and darkness...

The ever more complete penetration of public spaces by attention-getting technologies exploits the orienting response in a way that preempts sociability, directing us away from one another and toward a manufactured reality, the content of which is determined from afar by private parties that have a material interest in doing so. There is no conspiracy here, it’s just the way things go.

But there’s another reason: Science is more than a body of knowledge; it is a way of thinking. I have a foreboding of an America in my children’s or grandchildren’s time—when the United States is a service and information economy; when nearly all the key manufacturing industries have slipped away to other countries; when awesome technological powers are in the hands of a very few, and no one representing the public interest can even grasp the issues; when the people have lost the ability to set their own agendas or knowledgeably question those in authority; when, clutching our crystals and nervously consulting our horoscopes, our critical faculties in decline, unable to distinguish between what feels good and what’s true, we slide, almost without noticing, back into superstition and darkness.

Because of this false idea, they devised an aesthetic belief in making the exterior of an object a reflection of the practical functions of the interior and of the constructive idea. Yet these analyses of utility and necessity that, according to their beliefs, should be the basis for the construction of any object created by humanity become immediately absurd once we analyze all the object being manufactured today. A fork or a bed cannot come to be considered necessary for humanity's life and health, and yet retain a relative value. They are 'learned necessities.' Modern human beings are suffocating under necessities like televisions, refrigerators, etc. And in the process making it impossible to live their real lives. Obviously we are not against modern technology, but we are against any notion of the absolute necessity of objects, to the point even of doubting their real utility.' Asger Jorn

The Philippines has no indigenous, value-added manufacturing capacity. At the end of the Second World War only Japan and Malaysia had higher incomes per capita in Asia. Then Korea and Taiwan overtook the Philippines in the 1950s. The country slid down past Thailand in the 1980s, and Indonesia more recently. From having been in a position near the top of the Asian pile, the Philippines today is an authentic, technology-less Third World state with poverty rates to match.

Printers are like that,’ I say. ‘It’s in their nature. They print when you don’t need anything. And when you really need something printed out, the ink cartridge is empty or there’s a sheet of paper jammed inside, the printer tells you it’s lost its internet connection or that it doesn’t recognise the computer you’re trying to print from. If you ask me, the whole idea of a digital, paperless future is down to the fact that printers have driven so many people to despair and insanity. Paper is a good thing; it’s beautiful. There’s nothing wrong with paper: it feels pleasant in your hand and it’s the best way to read something. The only problem is getting those little black marks onto the surface of the paper in the first place. Even with all the modern technology at our disposal it’s all but impossible. I suspect – no, I’m absolutely convinced – that the printer companies and the antidepressant manufacturers of this world are in cahoots.

Fittingly, Harald's name today is ubiquitous as a technology that unites disparate devices. Begun in 1994 by the Swedish company Ericsson, Bluetooth passes information wirelessly between phones and computers regardless of operating system or manufacturer. Just as the tenth century Viking king united fierce rivals, a Samsung phone will now communicate with an Apple computer. The two runes that make up the modern symbol for Bluetooth technology are the king's initials. 176.

As lighting manufacturers developed new, more energy-efficient technologies, such as LEDs and fluorescents, suddenly a light bulb was not just a light bulb anymore. But no one told us light-bulb buyers. “People don’t know they should be looking for three thousand degrees Kelvin, or what we call warm light, so instead they come home with four thousand or five thousand degrees Kelvin, which is cool light.” This information is printed on packages, but most people don’t know to look for it.

The spread of semiconductors was enabled as much by clever manufacturing techniques as academic physics. Universities like MIT and Stanford played a crucial role in developing knowledge about semiconductors, but the chip industry only took off because graduates of these institutions spent years tweaking production processes to make mass manufacturing possible. It was engineering and intuition, as much as scientific theorizing, that turned a Bell Labs patent into a world-changing industry

So identified has the State become in the public mind with the provision of these services that an attack on State financing appears to many people as an attack on the service itself. Thus if one maintains that the State should not supply court services, and that private enterprise on the market could supply such service more efficiently as well as more morally, people tend to think of this as denying the importance of courts themselves. The libertarian who wants to replace government by private enterprises in the above areas is thus treated in the same way as he would be if the government had, for various reasons, been supplying shoes as a tax-financed monopoly from time immemorial. If the government and only the government had had a monopoly of the shoe manufacturing and retailing business, how would most of the public treat the libertarian who now came along to advocate that the government get out of the shoe business and throw it open to private enterprise? He would undoubtedly be treated as follows: people would cry, “How could you? You are opposed to the public, and to poor people, wearing shoes! And who would supply shoes to the public if the government got out of the business? Tell us that! Be constructive! It’s easy to be negative and smart-alecky about government; but tell us who would supply shoes? Which people? How many shoe stores would be available in each city and town? How would the shoe firms be capitalized? How many brands would there be? What material would they use? What lasts? What would be the pricing arrangements for shoes? Wouldn’t regulation of the shoe industry be needed to see to it that the product is sound? And who would supply the poor with shoes? Suppose a poor person didn’t have the money to buy a pair?” These questions, ridiculous as they seem to be and are with regard to the shoe business, are just as absurd when applied to the libertarian who advocates a free market in fire, police, postal service, or any other government operation. The point is that the advocate of a free market in anything cannot provide a “constructive” blueprint of such a market in advance. The essence and the glory of the free market is that individual firms and businesses, competing on the market, provide an ever-changing orchestration of efficient and progressive goods and services: continually improving products and markets, advancing technology, cutting costs, and meeting changing consumer demands as swiftly and as efficiently as possible.

The essential point is that a worker is also a consumer (and may support other consumers). These people drive final demand. When a worker is replaced by a machine, that machine does not go out and consume. The machine may use energy and spare parts and require maintenance, but again, those are business inputs, not final demand. If there is no one to buy what the machine is producing, it will ultimately be shut down. An industrial robot in an auto manufacturing plant will not continue running if no one is buying the cars it is assembling.

Science is more than a body of knowledge; it is a way of thinking. I have a foreboding of an America in my children’s or grandchildren’s time—when the United States is a service and information economy; when nearly all the key manufacturing industries have slipped away to other countries; when awesome technological powers are in the hands of a very few, and no one representing the public interest can even grasp the issues; when the people have lost the ability to set their own agendas or knowledgeably question those in authority; when, clutching our crystals and nervously consulting our horoscopes, our critical faculties in decline, unable to distinguish between what feels good and what’s true, we slide, almost without noticing, back into superstition and darkness. The dumbing down of America is most evident in the slow decay of substantive content in the enormously influential media, the 30-second sound bites (now down to 10 seconds or less), lowest common denominator programming, credulous presentations on pseudoscience and superstition, but especially a kind of celebration of ignorance.

The great majority of those who, like Frankl, were liberated from Nazi concentration camps chose to leave for other countries rather than return to their former homes, where far too many neighbors had turned murderous. But Viktor Frankl chose to stay in his native Vienna after being freed and became head of neurology at a main hospital in Vienna. The Austrians he lived among often perplexed Frankl by saying they did not know a thing about the horrors of the camps he had barely survived. For Frankl, though, this alibi seemed flimsy. These people, he felt, had chosen not to know. Another survivor of the Nazis, the social psychologist Ervin Staub, was saved from a certain death by Raoul Wallenberg, the diplomat who made Swedish passports for thousands of desperate Hungarians, keeping them safe from the Nazis. Staub studied cruelty and hatred, and he found one of the roots of such evil to be the turning away, choosing not to see or know, of bystanders. That not-knowing was read by perpetrators as a tacit approval. But if instead witnesses spoke up in protest of evil, Staub saw, it made such acts more difficult for the evildoers. For Frankl, the “not-knowing” he encountered in postwar Vienna was regarding the Nazi death camps scattered throughout that short-lived empire, and the obliviousness of Viennese citizens to the fate of their own neighbors who were imprisoned and died in those camps. The underlying motive for not-knowing, he points out, is to escape any sense of responsibility or guilt for those crimes. People in general, he saw, had been encouraged by their authoritarian rulers not to know—a fact of life today as well. That same plea of innocence, I had no idea, has contemporary resonance in the emergence of an intergenerational tension. Young people around the world are angry at older generations for leaving as a legacy to them a ruined planet, one where the momentum of environmental destruction will go on for decades, if not centuries. This environmental not-knowing has gone on for centuries, since the Industrial Revolution. Since then we have seen the invention of countless manufacturing platforms and processes, most all of which came to be in an era when we had no idea of their ecological impacts. Advances in science and technology are making ecological impacts more transparent, and so creating options that address the climate crisis and, hopefully, will be pursued across the globe and over generations. Such disruptive, truly “green” alternatives are one way to lessen the bleakness of Earth 2.0—the planet in future decades—a compelling fact of life for today’s young. Were Frankl with us today (he died in 1997), he would no doubt be pleased that so many of today’s younger people are choosing to know and are finding purpose and meaning in surfacing environmental facts and acting on them.

Some technologies take several decades to reach mainstream adaptation because they were waiting on many other things to reach a certain level of maturity or accessibility. For example, in order for video conferencing technologies like Facetime and Zoom to reach mainstream adaptation, it needed the following things to reach greater maturity and accessibility — camera technology, smartphone popularity, computer chip manufacturing, silica mining, copper mining, fiber optic cable distribution, 4G communication technology and more. The magic happens in the convergence.

In power, eternity politicians manufacture crisis and manipulate the resultant emotion. To distract from their inability or unwillingness to reform, eternity politicians instruct their citizens to experience elation and outrage at short intervals, drowning the future in the present. In foreign policy, eternity politicians belittle and undo the achievements of countries that might seem like models to their own citizens. Using technology to transmit political fiction, both at home and abroad, eternity politicians deny truth and seek to reduce life to spectacle and feeling.

Elbit, the biggest private arms manufacturer in Israel today. Established in 1966, it quickly became an essential supplier of equipment for Israeli tanks and aircraft. Years later it had become a major exporter of weapons to both democracies and despots, working closely with the US military and a host of other nations to develop a range of equipment, from drones to night vision googles and land surveillance systems to deadly high-tech munitions. Elbit is still today intimately tied to the Israeli security establishment, and has even moved into the book publishing industry.

Professor Sutton proves conclusively in his three volume history of Soviet technological development that the Soviet Union was almost literally manufactured by the U.S.A. Sutton quotes a report by Averell Harriman to the State Department in June, 1944 as stating:   -> "Stalin paid tribute to the assistance rendered by the United States to Soviet industry before and during the war. He said that about two-thirds of all the large industrial enterprise in the Soviet Union had been built with United States help or technical assistance." (Sutton, op. cit., Vol. II, p. 3.) <-   Remember that this

Total available Calories divided by Population equals Artistic-Technological Style. When the ratio Calories-to-Population is large—say, five thousand or more, five thousand daily calories for every living person—then the Artistic-Technological Style is big. People carve Mount Rushmore; they build great foundries; they manufacture enormous automobiles to carry one housewife half a mile for the purchase of one lipstick. Life is coarse and rich where C:P is large. At the other extreme, where C:P is too small, life does not exist at all. It has starved out. Experimentally, add little increments to C:P and it will be some time before the right-hand side of the equation becomes significant. But at last, in the 1,000 to 1,500 calorie range, Artistic-Technological Style firmly appears in self-perpetuating form. C:P in that range produces the small arts, the appreciations, the peaceful arrangements of necessities into subtle relationships of traditionally agreed-upon virtue. Think of Japan, locked into its Shogunate prison, with a hungry population scrabbling food out of mountainsides and beauty out of arrangements of lichens. The small, inexpensive sub-sub-arts are characteristic of the 1,000 to 1,500 calorie range.

Technology is important to Art because it connects creativity with innovation and the spirit of inventiveness. Whether we are using technology to create our art, or to share our art, it challenges artists to explore new realms of aesthetic experience and cultural relevance. But, on the other hand, Art is important to Technology for the most important reason of all. Art gives Technology its humanity. And our humanity is the driving force behind every new technology we design and every product we manufacture. We are all makers. Without creativity, we don’t make anything. If we don’t make anything, we don’t progress.

I don’t know to what extent ignorance of science and mathematics contributed to the decline of ancient Athens, but I know that the consequences of scientific illiteracy are far more dangerous in our time than in any that has come before. It’s perilous and foolhardy for the average citizen to remain ignorant about global warming, say, or ozone depletion, air pollution, toxic and radioactive wastes, acid rain, topsoil erosion, tropical deforestation, exponential population growth. Jobs and wages depend on science and technology. If our nation can’t manufacture, at high quality and low price, products people want to buy, then industries will continue to drift away and transfer a little more prosperity to other parts of the world. Consider the social ramifications of fission and fusion power, supercomputers, data “highways,” abortion, radon, massive reductions in strategic weapons, addiction, government eavesdropping on the lives of its citizens, high-resolution TV, airline and airport safety, fetal tissue transplants, health costs, food additives, drugs to ameliorate mania or depression or schizophrenia, animal rights, superconductivity, morning-after pills, alleged hereditary antisocial predispositions, space stations, going to Mars, finding cures for AIDS and cancer.

We have no certainty we’ll contact extraterrestrial beings from one of the billion earthlike planets in the sky in the next 200 years, but we have almost 100 percent certainty that we’ll manufacture an alien intelligence by then. When we face these synthetic aliens, we’ll encounter the same benefits and challenges that we expect from contact with ET. They will force us to reevaluate our roles, our beliefs, our goals, our identity. What are humans for? I believe our first answer will be: Humans are for inventing new kinds of intelligences that biology could not evolve. Our job is to make machines that think different—to create alien intelligences.

Science is more than a body of knowledge; it is a way of thinking. I have a foreboding of an America in my children’s or grandchildren’s time—when the United States is a service and information economy; when nearly all the key manufacturing industries have slipped away to other countries; when awesome technological powers are in the hands of a very few, and no one representing the public interest can even grasp the issues; when the people have lost the ability to set their own agendas or knowledgeably question those in authority; when, clutching our crystals and nervously consulting our horoscopes, our critical faculties in decline, unable to distinguish between what feels good and what’s true, we slide, almost without noticing, back into superstition and darkness. The dumbing down of America is most evident in the slow decay of substantive content in the enormously influential media, the 30-second sound bites (now down to 10 seconds or less), lowest common denominator programming, credulous presentations on pseudoscience and superstition, but especially a kind of celebration of ignorance. As I write, the number-one videocassette rental in America is the movie Dumb and Dumber. “Beavis and Butthead” remain popular (and influential) with young TV viewers. The plain lesson is that study and learning—not just of science, but of anything—are avoidable, even undesirable.

have a foreboding of an America in my children’s or grandchildren’s time—when the United States is a service and information economy; when nearly all the key manufacturing industries have slipped away to other countries; when awesome technological powers are in the hands of a very few, and no one representing the public interest can even grasp the issues; when the people have lost the ability to set their own agendas or knowledgeably question those in authority; when, clutching our crystals and nervously consulting our horoscopes, our critical faculties in decline, unable to distinguish between what feels good and what’s true, we slide, almost without noticing, back into superstition and darkness.

We have considered the problem of mental fragmentation and arbitrariness that results when our contact with the world is mediated by representations: representations collapse the basic axis of proximity and distance by which an embodied being orients in the world and draws a horizon of relevance around itself. We noted the prominence of a design philosophy that severs the bonds between action and perception, as in contemporary automobiles that insulate us from the sensorimotor contingencies by which an embodied being normally grasps reality. The case of machine gambling gave us a heightened example of this kind of abstraction, and made clear how such a design philosophy can be turned to especially disturbing purposes in the darker precincts of “affective capitalism,” where our experiences are manufactured for us. We saw that the point of these experiences is often to provide a quasi-autistic escape from the frustrations of life, and that they are especially attractive in a world that lacks a basic intelligibility because it seems to be ordered by “vast impersonal forces” that are difficult to bring within view on a first-person, human scale. I argued that all of this tends to sculpt a certain kind of contemporary self, a fragile one whose freedom and dignity depend on its being insulated from contingency, and who tends to view technology as magic for accomplishing this. For such a self, choosing from a menu of options replaces the kind of adult agency that grapples with things in an unfiltered way.

Science is more than a body of knowledge; it is a way of thinking. I have a foreboding of an America in my children’s or grandchildren’s time—when the United States is a service and information economy; when nearly all the key manufacturing industries have slipped away to other countries; when awesome technological powers are in the hands of a very few, and no one representing the public interest can even grasp the issues; when the people have lost the ability to set their own agendas or knowledgeably question those in authority; when, clutching our crystals and nervously consulting our horoscopes, our critical faculties in decline, unable to distinguish between what feels good and what’s true, we slide, almost without noticing, back into superstition and darkness

Science is more than a body of knowledge; it is a way of thinking. I have a foreboding of an America in my children’s or grandchildren’s time—when the United States is a service and information economy; when nearly all the key manufacturing industries have slipped away to other countries; when awesome technological powers are in the hands of a very few, and no one representing the public interest can even grasp the issues; when the people have lost the ability to set their own agendas or knowledgeably question those in authority; when, clutching our crystals and nervously consulting our horoscopes, our critical faculties in decline, unable to distinguish between what feels good and what’s true, we slide, almost without noticing, back into superstition and darkness. The

The human race will possess the technology to create God. Why not build this being? Emerging technologies such as nanotechnological molecular manufacturers will likely be so powerful and potentially destructive that it will take God to master them. God may turn out to be inevitable simply in order for the human race to save itself. If virtue as excellence is ultimately identical with evolutionary perfection, then virtue is ultimately identical to whatever leads evolution towards a higher state of perfection. Virtue as excellence is thus ultimately inseparable from evolutionary ethics. Evolutionary ethics ties or morality with whatever is conductive to evolutionary progress. If politics is control over evolution, then is virtue the values that best steer political control over evolution?

RENEWABLE ENERGY REVOLUTION: SOLAR + WIND + BATTERIES In addition to AI, we are on the cusp of another important technological revolution—renewable energy. Together, solar photovoltaic, wind power, and lithium-ion battery storage technologies will create the capability of replacing most if not all of our energy infrastructure with renewable clean energy. By 2041, much of the developed world and some developing countries will be primarily powered by solar and wind. The cost of solar energy dropped 82 percent from 2010 to 2020, while the cost of wind energy dropped 46 percent. Solar and onshore wind are now the cheapest sources of electricity. In addition, lithium-ion battery storage cost has dropped 87 percent from 2010 to 2020. It will drop further thanks to the massive production of batteries for electrical vehicles. This rapid drop in the price of battery storage will make it possible to store the solar/wind energy from sunny and windy days for future use. Think tank RethinkX estimates that with a $2 trillion investment through 2030, the cost of energy in the United States will drop to 3 cents per kilowatt-hour, less than one-quarter of today’s cost. By 2041, it should be even lower, as the prices of these three components continue to descend. What happens on days when a given area’s battery energy storage is full—will any generated energy left unused be wasted? RethinkX predicts that these circumstances will create a new class of energy called “super power” at essentially zero cost, usually during the sunniest or most windy days. With intelligent scheduling, this “super power” can be used for non-time-sensitive applications such as charging batteries of idle cars, water desalination and treatment, waste recycling, metal refining, carbon removal, blockchain consensus algorithms, AI drug discovery, and manufacturing activities whose costs are energy-driven. Such a system would not only dramatically decrease energy cost, but also power new applications and inventions that were previously too expensive to pursue. As the cost of energy plummets, the cost of water, materials, manufacturing, computation, and anything that has a major energy component will drop, too. The solar + wind + batteries approach to new energy will also be 100-percent clean energy. Switching to this form of energy can eliminate more than 50 percent of all greenhouse gas emissions, which is by far the largest culprit of climate change.

A classic LBO works this way: An investor decides to buy a company by putting up equity, similar to the down payment on a house, and borrowing the rest, the leverage. Once acquired, the company, if public, is delisted, and its shares are taken private, the “private” in the term “private equity.” The company pays the interest on its debt from its own cash flow while the investor improves various areas of a business’s operations in an attempt to grow the company. The investor collects a management fee and eventually a share of the profits earned whenever the investment in monetized. The operational improvements that are implemented can range from greater efficiencies in manufacturing, energy utilization, and procurement; to new product lines and expansion into new markets; to upgraded technology; and even leadership development of the company’s management team.

Conceive a world-society developed materially far beyond the wildest dreams of America. Unlimited power, derived partly from the artificial disintegration of atoms, partly from the actual annihilation of matter through the union of electrons and protons to form radiation, completely abolished the whole grotesque burden of drudgery which hitherto had seemed the inescapable price of civilization, nay of life itself. The vast economic routine of the world-community was carried on by the mere touching of appropriate buttons. Transport, mining, manufacture, and even agriculture were performed in this manner. And indeed in most cases the systematic co-ordination of these activities was itself the work of self-regulating machinery. Thus, not only was there no longer need for any human beings to spend their lives in unskilled monotonous labour, but further, much that earlier races would have regarded as highly skilled though stereotyped work, was now carried on by machinery. Only the pioneering of industry, the endless exhilarating research, invention, design and reorganization, which is incurred by an ever-changing society, still engaged the minds of men and women. And though this work was of course immense, it could not occupy the whole attention of a great world-community. Thus very much of the energy of the race was free to occupy itself with other no less difficult and exacting matters, or to seek recreation in its many admirable sports and arts. Materially every individual was a multi-millionaire, in that he had at his beck and call a great diversity of powerful mechanisms; but also he was a penniless friar, for he had no vestige of economic control over any other human being. He could fly through the upper air to the ends of the earth in an hour, or hang idle among the clouds all day long. His flying machine was no cumbersome aeroplane, but either a wingless aerial boat, or a mere suit of overalls in which he could disport himself with the freedom of a bird. Not only in the air, but in the sea also, he was free. He could stroll about the ocean bed, or gambol with the deep-sea fishes. And for habitation he could make his home, as he willed, either in a shack in the wilderness or in one of the great pylons which dwarfed the architecture even of the American age. He could possess this huge palace in loneliness and fill it with his possessions, to be automatically cared for without human service; or he could join with others and create a hive of social life. All these amenities he took for granted as the savage takes for granted the air which he breathes. And because they were as universally available as air, no one craved them in excess, and no one grudged another the use of them.

I know that the consequences of scientific illiteracy are far more dangerous in our time than in any that has come before. It’s perilous and foolhardy for the average citizen to remain ignorant about global warming, say, or ozone depletion, air pollution, toxic and radioactive wastes, acid rain, topsoil erosion, tropical deforestation, exponential population growth. Jobs and wages depend on science and technology. If our nation can’t manufacture, at high quality and low price, products people want to buy, then industries will continue to drift away and transfer a little more prosperity to other parts of the world. Consider the social ramifications of fission and fusion power, supercomputers, data “highways,” abortion, radon, massive reductions in strategic weapons, addiction, government eavesdropping on the lives of its citizens, high-resolution TV, airline and airport safety, fetal tissue transplants, health costs, food additives, drugs to ameliorate mania or depression or schizophrenia, animal rights, superconductivity, morning-after pills, alleged hereditary antisocial predispositions, space stations, going to Mars, finding cures for AIDS and cancer. How can we affect national policy—or even make intelligent decisions in our own lives—if we don’t grasp the underlying issues? As I write, Congress is dissolving its own Office of Technology Assessment—the only organization specifically tasked to provide advice to the House and Senate on science and technology. Its competence and integrity over the years have been exemplary. Of the 535 members of the U.S. Congress, rarely in the twentieth century have as many as one percent had any significant background in science. The last scientifically literate President may have been Thomas Jefferson.* So how do Americans decide these matters? How do they instruct their representatives? Who in fact makes these decisions, and on what basis? —

Rivera’s admiration for Stalin was equaled only by his admiration for Henry Ford. By the 1920s and ‘30s, nearly every industrial country in Europe and Latin America, as well as the Soviet Union, had adopted Ford’s engineering and manufacturing methods: his highly efficient assembly line to increase production and reduce the cost of automobiles, so that the working class could at least afford to own a car; his total control over all the manufacturing and production processes by concentrating them all in one place, from the gathering of raw materials to orchestrating the final assembly; and his integration, training, and absolute control of the workforce. Kahn, the architect of Ford’s factories, subsequently constructed hundreds of factories on the model of the Rouge complex in Dearborn, Michigan, which was the epicenter of Ford’s industrial acumen as well as a world-wide symbol of future technology. Such achievements led Rivera to regard Detroit’s industry as the means of transforming the proletariat to take the reins of economic production.

By the end of the 1970s, a clear majority of the employed population of Britain, Germany, France, the Benelux countries, Scandinavia and the Alpine countries worked in the service sector—communications, transport, banking, public administration and the like. Italy, Spain and Ireland were very close behind. In Communist Eastern Europe, by contrast, the overwhelming majority of former peasants were directed into labour-intensive and technologically retarded mining and industrial manufacture; in Czechoslovakia, employment in the tertiary, service sector actually declined during the course of the 1950s. Just as the output of coal and iron-ore was tailing off in mid-1950s Belgium, France, West Germany and the UK, so it continued to increase in Poland, Czechoslovakia and the GDR. The Communists’ dogmatic emphasis on raw material extraction and primary goods production did generate rapid initial growth in gross output and per capita GDP. In the short run the industrial emphasis of the Communist command economies thus appeared impressive (not least to many Western observers). But it boded ill for the region’s future.

There was nothing pretty or elegant about their robot. Compared to the gleaming machines other teams had constructed, Stinky was a study in simplicity. The PVC, the balloon, the tape measure—in each case they had chosen the most straightforward solution to a problem. It was an approach that grew naturally out of watching family members fix cars, manufacture mattresses, and lay irrigation piping. To a large swath of the population, driveway mechanics, box-frame builders, and gardeners did not represent the cutting edge of engineering know-how. They were low-skilled laborers who didn’t have access to real technology. Stinky represented this low-tech approach to engineering. But that was exactly what had impressed the judges. Lisa Spence, the NASA judge, believed that there was no reason to come up with a complex solution when an elementary one would suffice. She felt that Carl Hayden’s robot was “conceptually similar” to the machines she encountered at NASA. The guys were in shock. They marched back up to the stage and looked out at the audience with dazed smiles. Lorenzo felt a rush of emotion. The judges’ Special Prize wasn’t a consolation award. These people were giving them real recognition.

One of those was Gary Bradski, an expert in machine vision at Intel Labs in Santa Clara. The company was the world’s largest chipmaker and had developed a manufacturing strategy called “copy exact,” a way of developing next-generation manufacturing techniques to make ever-smaller chips. Intel would develop a new technology at a prototype facility and then export that process to wherever it planned to produce the denser chips in volume. It was a system that required discipline, and Bradski was a bit of a “Wild Duck”—a term that IBM originally used to describe employees who refused to fly in formation—compared to typical engineers in Intel’s regimented semiconductor manufacturing culture. A refugee from the high-flying finance world of “quants” on the East Coast, Bradski arrived at Intel in 1996 and was forced to spend a year doing boring grunt work, like developing an image-processing software library for factory automation applications. After paying his dues, he was moved to the chipmaker’s research laboratory and started researching interesting projects. Bradski had grown up in Palo Alto before leaving to study physics and artificial intelligence at Berkeley and Boston University. He returned because he had been bitten by the Silicon Valley entrepreneurial bug.

We know nothing about how those earliest known surface glazes themselves were developed. Nevertheless, we can infer the methods of prehistoric invention by watching technologically “primitive” people today, such as the New Guineans with whom I work. I already mentioned their knowledge of hundreds of local plant and animal species and each species’ edibility, medical value, and other uses. New Guineans told me similarly about dozens of rock types in their environment and each type’s hardness, color, behavior when struck or flaked, and uses. All of that knowledge is acquired by observation and by trial and error. I see that process of “invention” going on whenever I take New Guineans to work with me in an area away from their homes. They constantly pick up unfamiliar things in the forest, tinker with them, and occasionally find them useful enough to bring home. I see the same process when I am abandoning a campsite, and local people come to scavenge what is left. They play with my discarded objects and try to figure out whether they might be useful in New Guinea society. Discarded tin cans are easy: they end up reused as containers. Other objects are tested for purposes very different from the one for which they were manufactured. How would that yellow number 2 pencil look as an ornament, inserted through a pierced ear-lobe or nasal septum? Is that piece of broken glass sufficiently sharp and strong to be useful as a knife? Eureka!

Humanitarian Industrialization Fourth industrial revolution my eye! We haven't yet recovered from the disparities produced by the first, second and third industrial revolutions. Morons keep peddling cold and pompous dreams devoid of humanity, and morons keep consuming them like good little backboneless vermin. Grow a backbone already! We always look at the glorious aspects of industrialization and overlook all those countless lives that are ruined by it. But it's okay! As long as we are not struck by a catastrophe ourselves, our sleep of moronity never breaks - so long as our comfort is unchallenged, and enhanced rather, it's okay if millions keep falling through the cracks. So long as you can afford a smartphone that runs smooth like butter, it doesn't matter if it is produced by modern day slave labors who can't even afford the basic essentials of living. With all the revenue the tech companies earn by charging you a thousand dollar for a hundred dollar smartphone, they can't even pay decent wages to the people working their butt off to manufacture their assets - because apparently, it is more important for the people at the top to afford private jets and trips to space, than the factory workers to afford healthcare, housing and a couple of square meals a day. And this you call industrialization - well done - you just figured out the secret to glory without being bothered by something so boring as basic humanity. I say to you here and now, listen well - stop abusing revolutionary scientific discoveries in the making of a cold, mechanistic, disparity infested world - use science and technology to wipe out the disparities, not cause them. Break free from your modern savagery of inhuman industrialization, and focus your mind on humanitarian industrialization.

Lucid Motors was started under the name Atieva (which stood for “advanced technologies in electric vehicle applications” and was pronounced “ah-tee-va”) in Mountain View in 2008 (or December 31, 2007, to be precise) by Bernard Tse, who was a vice president at Tesla before it launched the Roadster. Hong Kong–born Tse had studied engineering at the University of Illinois, where he met his wife, Grace. In the early 1980s, the couple had started a computer manufacturing company called Wyse, which at its peak in the early 1990s registered sales of more than $480 million a year. Tse joined Tesla’s board of directors in 2003 at the request of his close friend Martin Eberhard, the company’s original CEO, who sought Tse’s expertise in engineering, manufacturing, and supply chain. Tse would eventually step off the board to lead a division called the Tesla Energy Group. The group planned to make electric power trains for other manufacturers, who needed them for their electric car programs. Tse, who didn’t respond to my requests to be interviewed, left Tesla around the time of Eberhard’s departure and decided to start Atieva, his own electric car company. Atieva’s plan was to start by focusing on the power train, with the aim of eventually producing a car. The company pitched itself to investors as a power train supplier and won deals to power some city buses in China, through which it could further develop and improve its technology. Within a few years, the company had raised about $40 million, much of it from the Silicon Valley–based venture capital firm Venrock, and employed thirty people, mostly power train engineers, in the United States, as well as the same number of factory workers in Asia. By 2014, it was ready to start work on a sedan, which it planned to sell in the United States and China. That year, it raised about $200 million from Chinese investors, according to sources close to the company.

The climate for relationships within an innovation group is shaped by the climate outside it. Having a negative instead of a positive culture can cost a company real money. During Seagate Technology’s troubled period in the mid-to-late 1990s, the company, a large manufacturer of disk drives for personal computers, had seven different design centers working on innovation, yet it had the lowest R&D productivity in the industry because the centers competed rather than cooperated. Attempts to bring them together merely led people to advocate for their own groups rather than find common ground. Not only did Seagate’s engineers and managers lack positive norms for group interaction, but they had the opposite in place: People who yelled in executive meetings received “Dog’s Head” awards for the worst conduct. Lack of product and process innovation was reflected in loss of market share, disgruntled customers, and declining sales. Seagate, with its dwindling PC sales and fading customer base, was threatening to become a commodity producer in a changing technology environment. Under a new CEO and COO, Steve Luczo and Bill Watkins, who operated as partners, Seagate developed new norms for how people should treat one another, starting with the executive group. Their raised consciousness led to a systemic process for forming and running “core teams” (cross-functional innovation groups), and Seagate employees were trained in common methodologies for team building, both in conventional training programs and through participation in difficult outdoor activities in New Zealand and other remote locations. To lead core teams, Seagate promoted people who were known for strong relationship skills above others with greater technical skills. Unlike the antagonistic committees convened during the years of decline, the core teams created dramatic process and product innovations that brought the company back to market leadership. The new Seagate was able to create innovations embedded in a wide range of new electronic devices, such as iPods and cell phones.

Tim Tigner began his career in Soviet Counterintelligence with the US Army Special Forces, the Green Berets. That was back in the Cold War days when, “We learned Russian so you didn't have to,” something he did at the Presidio of Monterey alongside Recon Marines and Navy SEALs. With the fall of the Berlin Wall, Tim switched from espionage to arbitrage. Armed with a Wharton MBA rather than a Colt M16, he moved to Moscow in the midst of Perestroika. There, he led prominent multinational medical companies, worked with cosmonauts on the MIR Space Station (from Earth, alas), chaired the Association of International Pharmaceutical Manufacturers, and helped write Russia’s first law on healthcare. Moving to Brussels during the formation of the EU, Tim ran Europe, Middle East, and Africa for a Johnson & Johnson company and traveled like a character in a Robert Ludlum novel. He eventually landed in Silicon Valley, where he launched new medical technologies as a startup CEO. In his free time, Tim has climbed the peaks of Mount Olympus, hang glided from the cliffs of Rio de Janeiro, and ballooned over Belgium. He earned scuba certification in Turkey, learned to ski in Slovenia, and ran the Serengeti with a Maasai warrior. He acted on stage in Portugal, taught negotiations in Germany, and chaired a healthcare conference in Holland. Tim studied psychology in France, radiology in England, and philosophy in Greece. He has enjoyed ballet at the Bolshoi, the opera on Lake Como, and the symphony in Vienna. He’s been a marathoner, paratrooper, triathlete, and yogi.  Intent on combining his creativity with his experience, Tim began writing thrillers in 1996 from an apartment overlooking Moscow’s Gorky Park. Decades later, his passion for creative writing continues to grow every day. His home office now overlooks a vineyard in Northern California, where he lives with his wife Elena and their two daughters. Tim grew up in the Midwest, and graduated from Hanover College with a BA in Philosophy and Mathematics. After military service and work as a financial analyst and foreign-exchange trader, he earned an MBA in Finance and an MA in International Studies from the University of Pennsylvania’s Wharton and Lauder Schools.  Thank you for taking the time to read about the author. Tim is most grateful for his loyal fans, and loves to correspond with readers like you. You are welcome to reach him directly at tim@timtigner.com.

YouTube: Dr. Samuel T. Francis — “Equality Unmasked" (American Renaissance Conference, 1996) In the second place, understanding egalitarianism as the ideology of the system and the elites that run it ought to alter our view of how the system and its elites actually operate. Most elites in history have always had a vested interest in preserving the societies they rule and that is why most elites have been conservative. ... But the elite that has come to power in the United States in the Western World in this century actually has a vested interest in managing and manipulating social change--the destruction of the society it rules. Political analyst Kevin Phillips pointed this out in his 1975 book "Mediacracy," which is a study of the emergence of what he calls the new knowledge elite, the members of which approach society from a new vantage point. Change does not threaten the affluent intelligentsia of the postindustrial society the way it threatened the land owners and industrialists of the New Deal. On the contrary, change is as essential to the knowledge sector as inventory turnover is to a merchant or a manufacturer. Change keeps up demand for the product: research, news, theory and technology. Post industrialism, a knowledge elite and accelerated social change appear to go hand in hand. The new knowledge elite does not preserve and protect existing traditions and institutions. On the contrary, far more than previous new classes, the knowledge elite has sought to modify or replace traditional institutions with new relationships and power centers. Egalitarianism and environmentalism serve this need to manage social change perfectly. Traditional institutions can be depicted not only as unequal and oppressive, but also as pathological, requiring the social and economic therapy that only the knowledge elite is skilled enough to design and apply. The interests of the knowledge elite in managing social change happen to be entirely consistent, not only with the agendas of the hard left, but also with the grievances and demands of various racial and ethnic groups that view racism and prejudice as obstacles to their own advancement. So that what we see as an alliance between the new elites and organized racial and ethnic minorities to undermine and displace the traditional institutions and beliefs of white, Euro-american society, which just happen to the power centers of older elites based on wealth, land and status. This process of displacement or dispossession is always described as progressive, liberating or diversifying, when in fact it merely helps consolidate the dominance of a new class and weaken the power and interests of its rivals.

The US traded its manufacturing sector’s health for its entertainment industry, hoping that Police Academy sequels could take the place of the rustbelt. The US bet wrong. But like a losing gambler who keeps on doubling down, the US doesn’t know when to quit. It keeps meeting with its entertainment giants, asking how US foreign and domestic policy can preserve its business-model. Criminalize 70 million American file-sharers? Check. Turn the world’s copyright laws upside down? Check. Cream the IT industry by criminalizing attempted infringement? Check. It’ll never work. It can never work. There will always be an entertainment industry, but not one based on excluding access to published digital works. Once it’s in the world, it’ll be copied. This is why I give away digital copies of my books and make money on the printed editions: I’m not going to stop people from copying the electronic editions, so I might as well treat them as an enticement to buy the printed objects. But there is an information economy. You don’t even need a computer to participate. My barber, an avowed technophobe who rebuilds antique motorcycles and doesn’t own a PC, benefited from the information economy when I found him by googling for barbershops in my neighborhood. Teachers benefit from the information economy when they share lesson plans with their colleagues around the world by email. Doctors benefit from the information economy when they move their patient files to efficient digital formats. Insurance companies benefit from the information economy through better access to fresh data used in the preparation of actuarial tables. Marinas benefit from the information economy when office-slaves look up the weekend’s weather online and decide to skip out on Friday for a weekend’s sailing. Families of migrant workers benefit from the information economy when their sons and daughters wire cash home from a convenience store Western Union terminal. This stuff generates wealth for those who practice it. It enriches the country and improves our lives. And it can peacefully co-exist with movies, music and microcode, but not if Hollywood gets to call the shots. Where IT managers are expected to police their networks and systems for unauthorized copying – no matter what that does to productivity – they cannot co-exist. Where our operating systems are rendered inoperable by “copy protection,” they cannot co-exist. Where our educational institutions are turned into conscript enforcers for the record industry, they cannot co-exist. The information economy is all around us. The countries that embrace it will emerge as global economic superpowers. The countries that stubbornly hold to the simplistic idea that the information economy is about selling information will end up at the bottom of the pile. What country do you want to live in?

So the Formula One driver has a dual status: he is both an automatic terminal of the most refined technical machinery, a technical operator, and he is the symbolic operator of crowd passions and the risk of death. The paradox is the same for the motor companies, caught as they are between investment and potlatch. Is all this a calculated — and hence rational — investment (marketing and advertising)? Have we here a mighty commercial operation, or is the company spending inordinate sums, far beyond what is commercially viable, to assuage a passion for prestige and charisma (there is also a manufacturers' world championship)? In this confrontation between manufacturers, isn't there an excessive upping of the stakes, a dizzying passion, a delirium? This is certainly the aspect which appeals, in the first instance, to the millions of viewers. In the end, the average TV viewer has doubtless never been aware that McLaren is a flagship for Honda. And I am not sure he or she is tempted to play the Formula One driver in ordinary life. The impact of Formula One lies, then, in the exceptional and mythic character of the event of the race and the figure of the driver, and not in the technical or commercial spin-offs. It is not clear why speed would be both severely limited and morally condemned in the public domain and, at the same time, celebrated in Formula One as never before, unless there is an effect of sublime compensation going on here. Formula One certainly serves to popularize the cult of the car and its use, but it does much more to maintain the passion for absolute difference — a fundamental illusion for all, and one which justifies all the excesses. In the end, however, hasn't it gone about as far as it can? Isn't it close to a final state, a final perfection, in which all the cars and drivers, given the colossal resources deployed, would, in a repetitive scenario, achieve the same maximum performance and produce the same pattern in each race? If Formula One were merely a rational, industrial performance, a test-bed for technical possibilities, we should have to predict that it would simply burn itself out. On the other hand, if Formula One is a spectacle, a collective, passionate (thoug h perfectly artificial) event, embracing the multiple screens of technological research, the living prosthesis of the driver, and the television screens into which the viewers project themselves, then it certainly has a very fine future. In a word, Formula One is a monster. Such a concentration of technology, money, ambition and prestige is a monster (as is the world of haute couture, which is equally abstract, and as far removed from real clothing as Formula One is from road traffic). Now, monsters are doomed to disappear, and we are afraid they might be disappearing. But we are not keen, either, to see them survive in a domesticated, routinized form. In an era of daily insignificance — including the insignificance of the car and all its constraints — we want at least to save the passion of a pure event, and exceptional beings who are permitted to do absolutely anything.

The Western medical model — and I don't mean the science of it, I mean the practice of it, because the science is completely at odds with the practice — makes two devastating separations. First of all we separate the mind from the body, we separate the emotions from the physiology. So we don't see how the physiology of people reflects their lifelong emotional experience. So we separate the mind from the body, which is not something that traditional medicine has done, I mean, Ayuverdic or Chinese medicine or shamanic tribal cultures and medicinal practices throughout the world have always recognized that mind and body are inseparable. They intuitively knew it. Many Western practitioners have known this and even taught it, but in practice we ignore it. And then we separate the individual from the environment. The studies are clear, for example, that when people are emotionally isolated they tend to get sick more quickly and they succumb more rapidly to their disease. Why? Because people's physiology is completely related to their psychological, social environment and when people are isolated and alone their stress levels are much higher because there's nothing there to help them moderate their stress. And physiologically it is straightforward, you know, it takes a five-year-old kid to understand it. However because in practice we separate them... when somebody shows up with an inflamed joint, all we do is we give them an anti-inflammatory or because the immune system is hyperactive and is attacking them we give them a medication to suppress their immune system or we give them a stress hormone like cortisol or one of its analogues, to suppress the inflammation. But we never ask: "What does this manifest about your life?", "What does this say about your relationships?", "How stressful is your job?", "To what extent do you lack control in your life?", "Where are you not authentic?", "How are you trying to work so hard to meet your attachment needs by suppressing yourself?" (because that is what you learn to do as a kid). Then we do all this research that has to do with cell biology, so we keep looking for the cause of cancer in the cell. Now there's a wonderful quote in the New York Times a couple of years ago they did a series on cancer and somebody said: "Looking for the cause of cancer inside the individual cell is like trying to understand a traffic jam by studying the internal combustion engine." We will never understand it, but we spend hundreds of billions of dollars a year looking for the cause of cancer inside the cell, not recognizing that the cell exists in interaction with the environment and that the genes are modulated by the environment, they are turned on and off by the environment. So the impact of not understanding the unity of emotions and physiology on one hand and in the other hand the relationship between the individual and the environment.. in other words.. having a strictly biological model as opposed to what has been called a bio-psycho-social, that recognizes that the biology is important, but it also reflects our psychological and social relationships. And therefore trying to understand the biology in isolation from the psychological and social environment is futile. The result is that we are treating people purely through pharmaceuticals or physical interventions, greatly to the profit of companies that manufacture pharmaceuticals and which fund the research, but it leaves us very much in the dark about a) the causes and b) the treatment, the holistic treatment of most conditions. So that for all our amazing interventions and technological marvels, we are still far short of doing what we could do, were we more mindful of that unity. So the consequences are devastating economically, they are devastating emotionally, they are devastating medically.

In the past decade, the historically consistent division in the United States between the share of total national income going to labor and that going to physical capital seems to have changed significantly. As the economists Susan Fleck, John Glaser, and Shawn Sprague noted in the U.S. Bureau of Labor Statistics’ Monthly Labor Review in 2011, “Labor share averaged 64.3 percent from 1947 to 2000. Labor share has declined over the past decade, falling to its lowest point in the third quarter of 2010, 57.8 percent.” Recent moves to “re-shore” production from overseas, including Apple’s decision to produce its new Mac Pro computer in Texas, will do little to reverse this trend. For in order to be economically viable, these new domestic manufacturing facilities will need to be highly automated. Other countries are witnessing similar trends. The economists Loukas Karabarbounis and Brent Neiman have documented significant declines in labor’s share of GDP in 42 of the 59 countries they studied, including China, India, and Mexico. In describing their findings, Karabarbounis and Neiman are explicit that progress in digital technologies is an important driver of this phenomenon: “The decrease in the relative price of investment goods, often attributed to advances in information technology and the computer age, induced firms to shift away from labor and toward capital. The lower price of investment goods explains roughly half of the observed decline in the labor share.

The fascination with automation in part reflected the country’s mood in the immediate postwar period, including a solid ideological commitment to technological progress. Representatives of industry (along with their counterparts in science and engineering) captured this mood by championing automation as the next step in the development of new production machinery and American industrial prowess. These boosters quickly built up automation into “a new gospel of postwar economics,” lauding it as “a universal ideal” that would “revolutionize every area of industry.” 98 For example, the November 1946 issue of Fortune magazine focused on the prospects for “The Automatic Factory.” The issue included an article titled “Machines without Men” that envisioned a completely automated factory where virtually no human labor would be needed. 99 With visions of “transforming the entire manufacturing sector into a virtually labor-free enterprise,” factory owners in a range of industries began to introduce automation in the postwar period. 100 The auto industry moved with particular haste. After the massive wave of strikes in 1945–46, automakers seized on automation as a way to replace workers with machines. 101 As they converted back to civilian auto production after World War II, they took the opportunity to install new labor-saving automatic production equipment. The two largest automakers, Ford and General Motors, set the pace. General Motors introduced the first successful automated transfer line at its Buick engine plant in Flint in 1946 (shortly after a 113-day strike, the longest in the industry’s history). The next year Ford established an automation department (a Ford executive, Del S. Harder, is credited with coining the word “automation”). By October 1948 the department had approved $ 3 million in spending on 500 automated devices, with early company estimates predicting that these devices would result in a 20 percent productivity increase and the elimination of 1,000 jobs. Through the late 1940s and 1950s Ford led the way in what became known as “Detroit automation,” undertaking an expensive automation program, which it carried out in concert with the company’s plans to decentralize operations away from the city. A major component of this effort was the Ford plant in the Cleveland suburb of Brook Park, a $ 2 billion engine-making complex that attracted visitors from government, industry, and labor and became a national symbol of automation in the 1950s. 102

It was possible to look at actual smartphones and tablets and laptops that had been manufactured on Old Earth. They did not work anymore, but their technical capabilities were described on little placards. And they were impressive compared to what Kath Two and other modern people carried around in their pockets. This ran contrary to most people's intuition, since in other areas the achievements of the modern world - the habitat ring, the Eye, and all the rest - were so vastly greater than what the people of Old Earth had ever accomplished. It boiled down to Amistics [the choices that different cultures made as to which technologies they would, and would not, make part of their lives]. In the decades before Zero, the Old Earthers had focused their intelligence on the small and the soft, not the big and the hard, and built a civilization that was puny and crumbling where physical infrastructure was concerned, but astonishingly sophisticated when it came to networked communications and software. The density with which they'd been able to pack transistors onto chips still had not been matched by any fabrication plant now in existence. Their devices could hold more data than anything you could buy today. Their ability to communicate through all sorts of wireless schemes was only now being matched - and that only in densely populated, affluent places like the Great Chain... Anyone who bothered to learn the history of the developed world in the years just before Zero understood perfectly well that Tavistock Prowse had been squarely in the middle of the normal range, as far as his social media habits and attention span had been concerned. But nevertheless, Blues called it Tav's Mistake. They didn't want to make it again. Any efforts made by modern consumer-goods manufacturers to produce the kinds of devices and apps that had disordered the brain of Tav were met with the same instinctive pushback as Victorian clergy might have directed against the inventor of a masturbation machine. To the extent the Blue's engineers could build electronics of comparable sophistication to those that Tav had used, they tended to put them into devices such as robots...