Form: Excerpt

  • Curt Doolittle updated his status.

    (FB 1544796513 Timestamp) THE CONDITION OF WHITE AMERICANS by Joseph Smith Average people don’t properly consider the philosophy of government, or spend the time they should on the cycles of history. What they do consider is that the average out of pocket cost for healthcare for a family is nearing $30k per year. They’ve robbed us, they’ve ignored us, they’ve slandered and belittled and demeaned us. They’ve flooded our cities with scabs to suppress wages, they’ve shipped our factories to third world slave states to knock a few pennies off the plastic junk at Walmart. They take our money and give it to the corporatists that collapse the global economy without any conditions, and then the conglomerates betray us anyway. We’re told we have no culture at all, that we’re uniquely evil in the historical scope. And worst of all portrayed as the winners in the system imposed on us, as if we’re head and shoulders gifted artificially by the unbearable aggression levied upon us. Demonized day and night in the press, patronized and pathologized in media, harassed in the streets and in every institution our ancestors have constructed. It’s so far beyond just a tax that to continue to exclaim it’s even the primary problem is to spit in our faces. Thank God the French have their yellow vests and their convictions. The Americans have nothing but their weed, video games, and muh constitution soliloquies.

  • Curt Doolittle updated his status.

    (FB 1544804133 Timestamp) by Robin Helweg-Larsen About 177 AD the Greek philosopher Celsus, in his book ‘The True Word’, expressed what appears to have been the consensus Jewish opinion about Jesus, that his father was a Roman soldier called Pantera. ‘Pantera’ means Panther and was a fairly common name among Roman soldiers. The rumor is repeated in the Talmud and in medieval Jewish writings where Jesus is referred to as “Yeshu ben Pantera”. In 1859 a gravestone surfaced in Germany for a Roman soldier called Tiberius Iulius Abdes Pantera, whose unit Cohors I Sagittariorum had served in Judea before Germany – romantic historians have hypothesized this to be Jesus’ father, especially as ‘Abdes’ (‘servant of God’) suggests a Jewish background. Tib(erius) Iul(ius) Abdes Pantera Sidonia ann(orum) LXII stipen(diorum) XXXX miles exs(ignifer?) coh(orte) I sagittariorum h(ic) s(itus) e(st) Tiberius Iulius Abdes Pantera from Sidon, aged 62 years served 40 years, former standard bearer (?) of the First Cohort of Archers lies here The gravestone is now in the Römerhalle museum in Bad Kreuznach, Germany. It appears this First Cohort of Archers moved from Palestine to Dalmatia in 6 AD, and to the Rhine in 9 AD. Pantera came from Sidon, on the coast of Phoenicia just west of Galilee, presumably enlisted locally. He served in the army for 40 years until some time in the reign of Tiberius. On discharge he would have been granted citizenship by the Emperor (and been granted freedom if he had formerly been a slave), and added the Emperor’s name to his own. Tiberius ruled from 14 AD to 37 AD. Pantera’s 40 years of service would therefore have started between 27 BC and 4 BC. As Pantera would probably have been about 18 when he enlisted, it means he was likely born between 45 BC and 22 BC. He could have been as old as 38 or as young as 15 at the time of Jesus’ conception in the summer of 7 BC. In 6 AD when Jesus was 12, Judas of Galilee led a popular uprising that captured Sepphoris, the capital of Galilee. The uprising was crushed by the Romans some four miles north of Nazareth. It is possible (and appealing to lovers of historical irony) that Pantera and Joseph fought on opposite sides. As Joseph is never heard of again he may well have been killed in the battle, or have been among the 2,000 Jewish rebels crucified afterwards. So Tiberius Iulius Abdes Pantera is indeed a possibility as Jesus’ father. The only thing we know for certain is that Mary’s husband Joseph wasn’t the father, and that Mary was already pregnant when they married. It could have been rape, or Mary may have been a wild young teen who fell for a handsome man in a uniform, even if he was part of an occupying army. It happens.

  • Curt Doolittle shared a link.

    (FB 1545541826 Timestamp) https://www.youtube.com/watch?v=sXiFcOozypc

  • Curt Doolittle shared a link.

    (FB 1545541826 Timestamp) https://www.youtube.com/watch?v=sXiFcOozypc

  • Curt Doolittle updated his status.

    (FB 1547468764 Timestamp) WORDS IN RUSSIAN BUT NOT IN ENGLISH TELL US A LOT ABOUT RUSSIAN EMOTIONAL NORMATIVITY

    1. Poshlost
      Russian-American writer Vladimir Nabokov, who lectured on Slavic Studies to students in America, admitted that he couldn’t translate this word, which every Russian easily understands.
    2. Nadryv
      German Wikipedia has an entire article dedicated to the word nadryv (надрыв). This is a key concept in the writings of Russian writer Fyodor Dostoevsky. The word describes an uncontrollable emotional outburst, when a person releases intimate, deeply hidden feelings.
    3. Khamstvo
      Soviet émigré writer Sergei Dovlatov wrote about this phenomenon in the article “This Untranslatable Khamstvo,” commenting that “Khamstvo is nothing other than rudeness, arrogance and insolence multiplied by impunity.”

    What is poshlost (пошлость)? Nabokov gives the following example: “Open any magazine and you’ll certainly find something like this – a family just bought a radio (a car, a refrigerator, silverware, it doesn’t matter), and the mother is clapping her hands, mad with joy, the children gathered around her with their mouths agape; the baby and the dog are leaning towards the table on which the `idol’ has been hoisted… a bit to the side victoriously stands the father, the proud breadwinner. The intense “poshlosity” of such a scene comes not from the false exaggeration of the dignity of a particular useful object, but from the assumption that the greatest joy can be bought and that such a purchase ennobles the buyer.” “This word includes triviality, vulgarity, sexual promiscuity and soullessness,” added the late Professor Svetlana Boym from Harvard University. Moreover, Dostoevsky’s nadryv implies a situation in which the protagonist indulges in the thought that he can find in his soul something that may not even exist. That’s why the nadryv often expressed imaginary, excessively exaggerated and distorted feelings. One part of the novel, Brothers Karamazov, is called “Nadryvs.” In Dovlatov’s view, it’s with impunity that khamstvo (хамство) outright kills us. It’s impossible to fight it; you can only resign yourself to it. “I’ve lived in this mad, wonderful, horrifying New York for ten years and am amazed by the absence of khamstvo. Anything can happen to you here, but there’s no khamstvo. You can be robbed but no one will shut the door in your face,” added the writer.

    1. Stushevatsya
      Some linguists believe stushevatsya (стушеваться) was introduced by Fyodor Dostoevsky, who used it for the first time in a figurative sense in his novella, The Double. This word means to be less noticeable, go to the background, lose an important role, noticeably leave the scene, become confused in an awkward or unexpected situation, become meek.
    2. Toska
      This Russian word can be translated as “emotional pain,” or “melancholy,” but this does not transmit all of its depth. Vladimir Nabokov wrote that, “Not one word in English can transmit all the nuances of toska (тоска). This is a feeling of spiritual suffering without any particular reason. On a less dolorous level, it’s the indistinct pain of the soul…vague anxiety, nostalgia, amorous longing.”

    3. Bytie
      This word comes from the Russian byt'(to exist). In Russian-English dictionaries this philosophical concept is translated as “being.” However, bytie (бытие) is not just life or existence, it’s the existence of an objective reality that is independent of human consciousness (cosmos, nature, matter).

    4. Bespredel
      Eliot Borenstein, professor of Slavic Studies at New York University, explains that bespredel (беспредел) literally means “without restrictions or limits.” Translators often use “lawlessness” (bezzakonie). In Russian, however, the meaning of bespredel is much broader, and refers to the behavior of a person who violates not only the law, but also moral and social norms.

    5. Avos’
      It’s rather difficult to explain to people of other nationalities what this means. Interestingly, many people believe that avos’ (авось) is the main Russian national trait. Hoping for the avos’ means doing something without planning, without putting in much effort, counting on success.

    6. Yurodivy

    Yurodivy: Russian ‘Umberto Eco’ demystifies the Holy Fool Yurodivys (юродивые) in ancient Rus’ were people who voluntarily renounced earthly pleasures in the name of Christ. Such people looked like madmen, and led a wandering lifestyle with the aim of obtaining inner peace and defeating the root of all sin – pride. They were valued and were considered close to God. Their opinions and prophecies were taken into consideration and they were even feared.

    1. Podvig
      This word is often translated into English as “feat” or “achievement,” but it has other meanings. Podvig (подвиг) is not just a result, or the achievement of an objective; it’s a brave and heroic act, an action performed in difficult circumstances. Russian literature often mentions military, civilian podvigs and even scientific podvigs. Moreover, this word is a synonym for selfless acts, for example, a podvig in the name of love.
  • Curt Doolittle updated his status.

    (FB 1547468764 Timestamp) WORDS IN RUSSIAN BUT NOT IN ENGLISH TELL US A LOT ABOUT RUSSIAN EMOTIONAL NORMATIVITY

    1. Poshlost
      Russian-American writer Vladimir Nabokov, who lectured on Slavic Studies to students in America, admitted that he couldn’t translate this word, which every Russian easily understands.
    2. Nadryv
      German Wikipedia has an entire article dedicated to the word nadryv (надрыв). This is a key concept in the writings of Russian writer Fyodor Dostoevsky. The word describes an uncontrollable emotional outburst, when a person releases intimate, deeply hidden feelings.
    3. Khamstvo
      Soviet émigré writer Sergei Dovlatov wrote about this phenomenon in the article “This Untranslatable Khamstvo,” commenting that “Khamstvo is nothing other than rudeness, arrogance and insolence multiplied by impunity.”

    What is poshlost (пошлость)? Nabokov gives the following example: “Open any magazine and you’ll certainly find something like this – a family just bought a radio (a car, a refrigerator, silverware, it doesn’t matter), and the mother is clapping her hands, mad with joy, the children gathered around her with their mouths agape; the baby and the dog are leaning towards the table on which the `idol’ has been hoisted… a bit to the side victoriously stands the father, the proud breadwinner. The intense “poshlosity” of such a scene comes not from the false exaggeration of the dignity of a particular useful object, but from the assumption that the greatest joy can be bought and that such a purchase ennobles the buyer.” “This word includes triviality, vulgarity, sexual promiscuity and soullessness,” added the late Professor Svetlana Boym from Harvard University. Moreover, Dostoevsky’s nadryv implies a situation in which the protagonist indulges in the thought that he can find in his soul something that may not even exist. That’s why the nadryv often expressed imaginary, excessively exaggerated and distorted feelings. One part of the novel, Brothers Karamazov, is called “Nadryvs.” In Dovlatov’s view, it’s with impunity that khamstvo (хамство) outright kills us. It’s impossible to fight it; you can only resign yourself to it. “I’ve lived in this mad, wonderful, horrifying New York for ten years and am amazed by the absence of khamstvo. Anything can happen to you here, but there’s no khamstvo. You can be robbed but no one will shut the door in your face,” added the writer.

    1. Stushevatsya
      Some linguists believe stushevatsya (стушеваться) was introduced by Fyodor Dostoevsky, who used it for the first time in a figurative sense in his novella, The Double. This word means to be less noticeable, go to the background, lose an important role, noticeably leave the scene, become confused in an awkward or unexpected situation, become meek.
    2. Toska
      This Russian word can be translated as “emotional pain,” or “melancholy,” but this does not transmit all of its depth. Vladimir Nabokov wrote that, “Not one word in English can transmit all the nuances of toska (тоска). This is a feeling of spiritual suffering without any particular reason. On a less dolorous level, it’s the indistinct pain of the soul…vague anxiety, nostalgia, amorous longing.”

    3. Bytie
      This word comes from the Russian byt'(to exist). In Russian-English dictionaries this philosophical concept is translated as “being.” However, bytie (бытие) is not just life or existence, it’s the existence of an objective reality that is independent of human consciousness (cosmos, nature, matter).

    4. Bespredel
      Eliot Borenstein, professor of Slavic Studies at New York University, explains that bespredel (беспредел) literally means “without restrictions or limits.” Translators often use “lawlessness” (bezzakonie). In Russian, however, the meaning of bespredel is much broader, and refers to the behavior of a person who violates not only the law, but also moral and social norms.

    5. Avos’
      It’s rather difficult to explain to people of other nationalities what this means. Interestingly, many people believe that avos’ (авось) is the main Russian national trait. Hoping for the avos’ means doing something without planning, without putting in much effort, counting on success.

    6. Yurodivy

    Yurodivy: Russian ‘Umberto Eco’ demystifies the Holy Fool Yurodivys (юродивые) in ancient Rus’ were people who voluntarily renounced earthly pleasures in the name of Christ. Such people looked like madmen, and led a wandering lifestyle with the aim of obtaining inner peace and defeating the root of all sin – pride. They were valued and were considered close to God. Their opinions and prophecies were taken into consideration and they were even feared.

    1. Podvig
      This word is often translated into English as “feat” or “achievement,” but it has other meanings. Podvig (подвиг) is not just a result, or the achievement of an objective; it’s a brave and heroic act, an action performed in difficult circumstances. Russian literature often mentions military, civilian podvigs and even scientific podvigs. Moreover, this word is a synonym for selfless acts, for example, a podvig in the name of love.
  • Curt Doolittle updated his status.

    (FB 1548826120 Timestamp) more… —“In order to understand why silicon engines have had such astounding energy-efficiency gains compared to combustion engines — and why Jevons Paradox has a long way to go yet — one has to look to the difference in the nature of the tasks the two kinds of engines perform. One produces information that consumes power, and the other produces power. All engines convert energy – effectively ‘refine’ it — from a chaotic form into a more highly ordered form. Combustion engines (and mechanical ones) are designed to effect a physical action. Efficiency is constrained by the immutable laws of thermodynamics, and things like friction, inertia and gravity. Logic engines, on the other hand, don’t produce physical action but are designed to manipulate the idea of the numbers zero and one. A logic engine’s purpose is rooted in simply knowing and storing the fact of the binary state of a switch; i.e., whether it is on or off. There is no useful information in the ‘size’ of the on or off state. It was obvious from early days that more and faster logic would require shrinking the size of the switch representing the binary state, chasing the physics that allows faster flips using less energy per flip. To be simplistic, it’s like choosing to use a grain of sand instead of a bowling ball to represent the number one. And, unlike other engines, logic engines can be accelerated through the clever applications of mathematics, i.e.,“software.” It’s no coincidence that this year also marks the 60th anniversary of the creation of that new term, coined by an American statistician. With software one can, for example, employ a trick equivalent to ignoring how much space lies between the grains of sand. This is what a compression algorithm does to digitally represent a picture using far less data, and thus energy. No such options exist in the world of normal engines. Tracing progress from 1971 when the first widely used integrated circuit was introduced by Intel, its vaunted 4004 with 2,300 transistors, we’ve seen the size of the transistor drop so much that a Central Processing Unit (CPU) today has billions of transistors, each able to operate 10,000-fold faster. That combination has yielded the billion-fold gains in computing power we’ve witnessed per chip. If combustion engines had achieved that kind of scaling efficiency, a car engine today would generate a thousand-fold more horsepower and have shrunk to the size of an ant: with such an engine, a car could actually fly, very fast. But only in comic books does the physics of propulsion scale that way. In our universe, power scales the other way. An ant-sized engine – which can be built — produces roughly a million times less power than a Prius. One consequence of the trajectory of making logic engines both cheaper and more powerful is that overall spending on such engines has soared (a related variant of Jevons Paradox). Each year the world’s manufacturers now purchase some $300 billion worth of semiconductor engines in order to build and sell computing machines. That total is some 20% to 50% more than global spending on the piston engines used to build all the world’s wheeled transportation machines. And the former is growing faster than the latter. The scaling ‘law’ of transistor-based engines was first codified by Intel co-founder Gordon Moore in an April 1965 article. There he wrote that advances in the techniques of silicon etching allowed transistor dimensions to shrink so fast that the number of them per integrated circuit doubled every two years. That also constituted a doubling in energy efficiency. And while Moore’s observation has been enshrined as a “law,” it’s not a law of nature but a consequence of the nature of logic engines. Thus, back to Jevons and his paradox. Quite obviously the market’s appetite for logic engines – data – has grown far faster than the efficiency improvements of those engines, so far. What next for Moore’s Law? If logic engines continue the trajectory of recent decades, we should expect to see a lot more surprises in both economic and business domains, never mind energy. Much scholarship has been devoted to the question of the future of Moore’s Law. Some pundits have been claiming that more efficient logic engines are now needed in order to constrain potential runaway energy use by the digital infrastructure. (That’s a constituency that has clearly not accepted the reality of the Jevons Paradox.) Meanwhile, other pundits have declared that the end of Moore’s Law is in sight. Because of Moore’s Law, CPUs now run so hot – a direct consequence of speed — that heat removal is an existential challenge. Inside the CPU itself, chip designers now build heat management software that can even throttle speed back to cool things down. Some datacenter operators have tackled the challenge, for example, by turning to water-cooled logic engines – a solution combustion engineers have long been familiar with. Even more challenging, logic switches have become so fast that moving the data around on the CPU’s silicon surface is actually constrained by the speed of light. And the logic switches are so small that conventional materials and tools are indeed maxing out. (For a lucid summary of all this, see this recent essay by Rodney Brooks, emeritus professor at MIT.) But it’s important to keep in mind that Moore’s Law is, as we’ve noted, fundamentally about finding ways to create ever tinier on-off states. In that regard, in the words of one the great physicists of the 20th century, Richard Feynman, “there’s plenty of room at the bottom” when it comes to logic engines. To appreciate how far away we still are from a “bottom,” consider the Holy Grail of computing, the human brain, which is at least 100 million times more energy efficient than the best silicon logic engine available. Engineers today are deploying a suite of techniques in the pursuit of ‘logic’ density and speed that can be grouped into three buckets: clever designs, embedding software, and using new materials to make transistors still smaller. The basic design of the transistor itself is no longer just the original planar, two-dimensional structures, but has gone 3D. The density from going vertical (think microscopic skyscrapers) buys another decade of Moore’s Law progress. Another design innovation is the “multi-core” microprocessor, which integrates dozens of CPUs onto a single silicon chip, each with billions of transistors. And now there are also entirely different engine types, much as aerospace engineers used to break the sound barrier, going from propellers to jet and then rocket engines. The equivalent with logic engines are Graphics Processing Units (GPUs) and Neural Processing Units (NPUs). For specialized tasks GPUs and NPUs outperform CPUs. GPUs were pioneered for gaming to render realistic video, i.e. “graphics,” (a subset of artificial reality) where the measure-of-merit is in imagines rather than logic operations processed per second. Then the NPUs don’t even use a CPU’s linear logic, but emulate instead a non-linear neural brain structure and offer “artificial intelligence” capabilities for such things as voice recognition, navigation and diagnostics. Computers that integrate CPUs, GPUs and NPUs are the equivalent of a vehicle with an SUV’s utility, a Ferrari’s speed, and a semitrailer’s carrying capacity. And, in no small irony, software is increasingly deployed within the CPU to manage traffic and power, and optimize the precious resources on the silicon “real estate.” Such software is the microscopic equivalent of blending AirBnB with Uber and Waze, at hyper-speed. Logic engines can, in effect, literally pull themselves up by their own bootstraps. Then there are new materials and the associated specialized machines for using them to fabricate even smaller transistors for all classes of digital engine. Here the automotive analog is in using better lubricants, or switching to aluminum and carbon-fiber bodies, or replacing carburetors with fuel injection. While there is an ultimate limit to a silicon transistor’s dimension – no smaller than the width of a half-dozen atoms – the distance to that limit represents as much progress as has occurred from 1998 to date. ‘Merely’ achieving, over the coming two decades, as much progress as has happened with Moore’s Law since 1998 will be world changing. Perhaps Moore’s Law, though, is no longer the best metric for the next 60 years of logic engine progress. Transistors have evolved from being viewed as components in isolated machines to become ubiquitous in markets, more common than grains of wheat. Logically, we should move beyond just counting them. Cost is the metric that matters in every market and application: in this case the cost of processing power. As we briefly illustrated above, in addition to size there are a variety of ways (e.g., designs, software) to advance the effect of Moore’s Law, which is the increase of processing power at declining costs. In fact, since the year 2000, the increase in logic operations purchasable per dollar has grown some 10-fold more than the increase in ‘raw’ logic operations generated per watt, Ray Kurzweil, widely known for his book The Singularity Is Near, may have been the first to document this cost reality. Kurzweil’s map shows that in the 1960s mainframe era, $1,000 dollars bought about one calculation per second. By the year 2000, a single dollar bought 10,000 calculations per second. Today a dollar buys one billion calculations per second. (All in constant dollar terms.) And that’s only half the story. The cloud, accelerating the cost declines of processing power through utility-class economies of scale (see Part 1 in this series), now combines with ever-cheaper ubiquitous high-speed wireless networks (Part 2 in this series). The integration of all these trends radically reduces costs and democratizes access to both data and the logic engines that process it. We don’t yet have a metric to quantify the effect of this economically incendiary combination. How much processing power might society ultimately consume? Data and information constitute a feature of our universe that is, like the universe itself, essentially infinite. There is no limit to our appetite to acquire data in order to gain greater knowledge and control of our world. So, finally, on this 60th anniversary of the logic engine, one more transportation analogy: the 60th anniversary of the invention of the internal combustion engine was 1936. We know now that 1936 was early days in the rise in consumption of road-miles. When it comes to consumption of processing power, it’s the equivalent of 1936. By now the energy implications of what we might call the Jevons digital Paradox should be obvious. But far more important are the implications of all the innovations yet to appear from the full flowering of the era of digital engines. “—

  • Curt Doolittle updated his status.

    (FB 1548826120 Timestamp) more… —“In order to understand why silicon engines have had such astounding energy-efficiency gains compared to combustion engines — and why Jevons Paradox has a long way to go yet — one has to look to the difference in the nature of the tasks the two kinds of engines perform. One produces information that consumes power, and the other produces power. All engines convert energy – effectively ‘refine’ it — from a chaotic form into a more highly ordered form. Combustion engines (and mechanical ones) are designed to effect a physical action. Efficiency is constrained by the immutable laws of thermodynamics, and things like friction, inertia and gravity. Logic engines, on the other hand, don’t produce physical action but are designed to manipulate the idea of the numbers zero and one. A logic engine’s purpose is rooted in simply knowing and storing the fact of the binary state of a switch; i.e., whether it is on or off. There is no useful information in the ‘size’ of the on or off state. It was obvious from early days that more and faster logic would require shrinking the size of the switch representing the binary state, chasing the physics that allows faster flips using less energy per flip. To be simplistic, it’s like choosing to use a grain of sand instead of a bowling ball to represent the number one. And, unlike other engines, logic engines can be accelerated through the clever applications of mathematics, i.e.,“software.” It’s no coincidence that this year also marks the 60th anniversary of the creation of that new term, coined by an American statistician. With software one can, for example, employ a trick equivalent to ignoring how much space lies between the grains of sand. This is what a compression algorithm does to digitally represent a picture using far less data, and thus energy. No such options exist in the world of normal engines. Tracing progress from 1971 when the first widely used integrated circuit was introduced by Intel, its vaunted 4004 with 2,300 transistors, we’ve seen the size of the transistor drop so much that a Central Processing Unit (CPU) today has billions of transistors, each able to operate 10,000-fold faster. That combination has yielded the billion-fold gains in computing power we’ve witnessed per chip. If combustion engines had achieved that kind of scaling efficiency, a car engine today would generate a thousand-fold more horsepower and have shrunk to the size of an ant: with such an engine, a car could actually fly, very fast. But only in comic books does the physics of propulsion scale that way. In our universe, power scales the other way. An ant-sized engine – which can be built — produces roughly a million times less power than a Prius. One consequence of the trajectory of making logic engines both cheaper and more powerful is that overall spending on such engines has soared (a related variant of Jevons Paradox). Each year the world’s manufacturers now purchase some $300 billion worth of semiconductor engines in order to build and sell computing machines. That total is some 20% to 50% more than global spending on the piston engines used to build all the world’s wheeled transportation machines. And the former is growing faster than the latter. The scaling ‘law’ of transistor-based engines was first codified by Intel co-founder Gordon Moore in an April 1965 article. There he wrote that advances in the techniques of silicon etching allowed transistor dimensions to shrink so fast that the number of them per integrated circuit doubled every two years. That also constituted a doubling in energy efficiency. And while Moore’s observation has been enshrined as a “law,” it’s not a law of nature but a consequence of the nature of logic engines. Thus, back to Jevons and his paradox. Quite obviously the market’s appetite for logic engines – data – has grown far faster than the efficiency improvements of those engines, so far. What next for Moore’s Law? If logic engines continue the trajectory of recent decades, we should expect to see a lot more surprises in both economic and business domains, never mind energy. Much scholarship has been devoted to the question of the future of Moore’s Law. Some pundits have been claiming that more efficient logic engines are now needed in order to constrain potential runaway energy use by the digital infrastructure. (That’s a constituency that has clearly not accepted the reality of the Jevons Paradox.) Meanwhile, other pundits have declared that the end of Moore’s Law is in sight. Because of Moore’s Law, CPUs now run so hot – a direct consequence of speed — that heat removal is an existential challenge. Inside the CPU itself, chip designers now build heat management software that can even throttle speed back to cool things down. Some datacenter operators have tackled the challenge, for example, by turning to water-cooled logic engines – a solution combustion engineers have long been familiar with. Even more challenging, logic switches have become so fast that moving the data around on the CPU’s silicon surface is actually constrained by the speed of light. And the logic switches are so small that conventional materials and tools are indeed maxing out. (For a lucid summary of all this, see this recent essay by Rodney Brooks, emeritus professor at MIT.) But it’s important to keep in mind that Moore’s Law is, as we’ve noted, fundamentally about finding ways to create ever tinier on-off states. In that regard, in the words of one the great physicists of the 20th century, Richard Feynman, “there’s plenty of room at the bottom” when it comes to logic engines. To appreciate how far away we still are from a “bottom,” consider the Holy Grail of computing, the human brain, which is at least 100 million times more energy efficient than the best silicon logic engine available. Engineers today are deploying a suite of techniques in the pursuit of ‘logic’ density and speed that can be grouped into three buckets: clever designs, embedding software, and using new materials to make transistors still smaller. The basic design of the transistor itself is no longer just the original planar, two-dimensional structures, but has gone 3D. The density from going vertical (think microscopic skyscrapers) buys another decade of Moore’s Law progress. Another design innovation is the “multi-core” microprocessor, which integrates dozens of CPUs onto a single silicon chip, each with billions of transistors. And now there are also entirely different engine types, much as aerospace engineers used to break the sound barrier, going from propellers to jet and then rocket engines. The equivalent with logic engines are Graphics Processing Units (GPUs) and Neural Processing Units (NPUs). For specialized tasks GPUs and NPUs outperform CPUs. GPUs were pioneered for gaming to render realistic video, i.e. “graphics,” (a subset of artificial reality) where the measure-of-merit is in imagines rather than logic operations processed per second. Then the NPUs don’t even use a CPU’s linear logic, but emulate instead a non-linear neural brain structure and offer “artificial intelligence” capabilities for such things as voice recognition, navigation and diagnostics. Computers that integrate CPUs, GPUs and NPUs are the equivalent of a vehicle with an SUV’s utility, a Ferrari’s speed, and a semitrailer’s carrying capacity. And, in no small irony, software is increasingly deployed within the CPU to manage traffic and power, and optimize the precious resources on the silicon “real estate.” Such software is the microscopic equivalent of blending AirBnB with Uber and Waze, at hyper-speed. Logic engines can, in effect, literally pull themselves up by their own bootstraps. Then there are new materials and the associated specialized machines for using them to fabricate even smaller transistors for all classes of digital engine. Here the automotive analog is in using better lubricants, or switching to aluminum and carbon-fiber bodies, or replacing carburetors with fuel injection. While there is an ultimate limit to a silicon transistor’s dimension – no smaller than the width of a half-dozen atoms – the distance to that limit represents as much progress as has occurred from 1998 to date. ‘Merely’ achieving, over the coming two decades, as much progress as has happened with Moore’s Law since 1998 will be world changing. Perhaps Moore’s Law, though, is no longer the best metric for the next 60 years of logic engine progress. Transistors have evolved from being viewed as components in isolated machines to become ubiquitous in markets, more common than grains of wheat. Logically, we should move beyond just counting them. Cost is the metric that matters in every market and application: in this case the cost of processing power. As we briefly illustrated above, in addition to size there are a variety of ways (e.g., designs, software) to advance the effect of Moore’s Law, which is the increase of processing power at declining costs. In fact, since the year 2000, the increase in logic operations purchasable per dollar has grown some 10-fold more than the increase in ‘raw’ logic operations generated per watt, Ray Kurzweil, widely known for his book The Singularity Is Near, may have been the first to document this cost reality. Kurzweil’s map shows that in the 1960s mainframe era, $1,000 dollars bought about one calculation per second. By the year 2000, a single dollar bought 10,000 calculations per second. Today a dollar buys one billion calculations per second. (All in constant dollar terms.) And that’s only half the story. The cloud, accelerating the cost declines of processing power through utility-class economies of scale (see Part 1 in this series), now combines with ever-cheaper ubiquitous high-speed wireless networks (Part 2 in this series). The integration of all these trends radically reduces costs and democratizes access to both data and the logic engines that process it. We don’t yet have a metric to quantify the effect of this economically incendiary combination. How much processing power might society ultimately consume? Data and information constitute a feature of our universe that is, like the universe itself, essentially infinite. There is no limit to our appetite to acquire data in order to gain greater knowledge and control of our world. So, finally, on this 60th anniversary of the logic engine, one more transportation analogy: the 60th anniversary of the invention of the internal combustion engine was 1936. We know now that 1936 was early days in the rise in consumption of road-miles. When it comes to consumption of processing power, it’s the equivalent of 1936. By now the energy implications of what we might call the Jevons digital Paradox should be obvious. But far more important are the implications of all the innovations yet to appear from the full flowering of the era of digital engines. “—

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    (FB 1549303424 Timestamp) Jurisprudence or legal theory is the theoretical study of law, principally by philosophers but, from the twentieth century, also by social scientists. Scholars of jurisprudence, (jurists or legal theorists), seek to obtain a deeper understanding of legal reasoning, legal systems, legal institutions, and the role of law in society. ROMAN LAW ORIGIN Jurisprudence in Ancient Rome had its origins with the (periti)—experts in the jus mos maiorum (traditional law), a body of oral laws and customs. DEVELOPMENT he sentences of the iudex were supposed to be simple interpretations of the traditional customs, but—apart from considering what traditional customs applied in each case—soon developed a more equitable interpretation, coherently adapting the law to newer social exigencies. The law was then adjusted with evolving institutiones (legal concepts), while remaining in the traditional mode. Praetors were replaced in the 3rd century BC by a laical body of prudentes. Admission to this body was conditional upon proof of competence or experience. FORMALIZATION Under the Roman Empire, schools of law were created, and practice of the law became more academic. From the early Roman Empire to the 3rd century, a relevant body of literature was produced by groups of scholars, including the Proculians and Sabinians. The scientific nature of the studies was unprecedented in ancient times. INSTITUTIONALIZATION After the 3rd century, juris prudentia became a more bureaucratic activity, with few notable authors. It was during the Eastern Roman Empire (5th century) that legal studies were once again undertaken in depth, and it is from this cultural movement that Justinian’s Corpus Juris Civilis was born. EUROPEAN LAW : ORIGIN: NATURAL LAW Begins with Aristotle In its general sense, natural law may be compared to both state-of-nature law and analogous to the laws of physical science. natural-law jurisprudence generally asserts that human law must be in response to compelling reasons for action. There are two readings of the natural-law jurisprudential stance. The Strong Natural Law Thesis holds that if a human law fails to be in response to compelling reasons, then it is not properly a “law” at all. This is captured, imperfectly, in the famous maxim: lex iniusta non est lex (an unjust law is no law at all). WEAK LAW (DEVELOPMENT) The Weak Natural Law Thesis holds that if a human law fails to be in response to compelling reasons, then it can still be called a “law”, but it must be recognised as a defective law. POSITIVE LAW (FORMALIZATION) Natural law is often contrasted to positive law which asserts law as the product of human activity and human volition. Positive law is not law per se, but regulation, contract, or command. LEGAL REALISM (INSTITUTIONALIZATION) Legal realism was a view popular with some Scandinavian and American writers. Skeptical in tone, it held that the law should be understood as, and would be determined by, the actual practices of courts, law offices, and police stations, rather than as the rules and doctrines set forth in statutes or learned treatises. The essential tenet of legal realism is that all law is made by human beings and, thus, is subject to human foibles, frailties, and imperfections. CRITICAL RATIONALISM AND THE LAW (REFORMATION) Karl Popper originated the theory of critical rationalism. According to Reinhold Zippelius many advances in law and jurisprudence take place by operations of critical rationalism. He writes, “daß die Suche nach dem Begriff des Rechts, nach seinen Bezügen zur Wirklichkeit und nach der Gerechtigkeit experimentierend voranschreitet, indem wir Problemlösungen versuchsweise entwerfen, überprüfen und verbessern” (that we empirically search for solutions to problems, which harmonise fairly with reality, by projecting, testing and improving the solutions). LEGAL INTERPRETIVISM (“RELATIVISM”) (DECLINE) Contemporary philosopher of law Ronald Dworkin has advocated a more constructivist theory of jurisprudence that can be characterized as a middle path between natural law theories and positivist theories of general jurisprudence.[37] In his book Law’s Empire,[38] Dworkin attacked Hart and the positivists for their refusal to treat law as a moral issue. He argued that law is an “interpretive” concept that requires barristers to find the best-fitting and most just solution to a legal dispute, given their constitutional traditions. According to him, law is not entirely based on social facts, but includes the best moral justification for the institutional facts and practices that we intuitively regard as legal. It follows from Dworkin’s view that one cannot know whether a society has a legal system in force, or what any of its laws are, until one knows some truths about the moral justifications of the social and political practices of that society. It is consistent with Dworkin’s view—in contrast with the views of legal positivists or legal realists—that no-one in a society may know what its laws are, because no-one may know the best moral justification for its practices.

  • Curt Doolittle updated his status.

    (FB 1549416707 Timestamp) UNDERSTANDING 4GW – REALLY by Trey Lindsey The key to understanding 4GW is to not be too distracted by the mainstream definition that is reliant upon the blending of war and politics. Since politics is simply the science of gaining and holding power, war and politics have always gone hand in hand. Even Clausewitz understood this clearly and he recognized that two nationally levied armies in pitched combat were still conducting a political act. Instead, focus on the civilian and asymmetric components without committing the sin of ignoring thousands of years of history. Civilians have been fighting states from the beginning of the human historical record, and it is a scientific certainty that no two armies or forces of exactly equal capability have ever encountered each other in battle. The common misnomer of asymmetric threats as being those of unequal combat power is ahistorical and, even worse, useless. The only useful definition of an asymmetric threat is that of C.A. Primmerman, who in 2000 recognized that analyzing asymmetry on the battlefield is ultimately a mathematical formula and thus used a geometric projection to settle on a three-part definition of “(1) a weapon/tactic/strategy that an enemy could and would use against the United States, (2) a weapon/tactic/strategy that the United States would not employ, and (3) a weapon/tactic/strategy that, if not countered (and this not countered by systems currently in place), could have serious consequences.” This can be reduced down to an asymmetry in “willingness.” Because willingness to conduct an action plays a central role in 4GW, ethics becomes a central component of understanding it. Likewise, because the action must satisfy the aforementioned criteria, the scientific method is critical to making the aforementioned assessment. Thus the only population that can emerge victorious in a 4GW environment on either side is one that is capable of processing and calculating both philosophical and scientific variables.