I am making my way through the UCICS

I have just realized the breadth of what UCICS is: it stands for the Unified Computer Information and Communication System. More than a system, it is also an FCC-like authority that regulates all things technical in TV, telephony, radio, mobile phones, cable TV, satellite communications, data over electric lines, and data over other media.

Usually shortened to U6, the system sets standards and requirements for programming languages by specifying these 5 core languages:

LUICS ( or Linguistic User Interface Command System) Logic-code Uniform Interface Command System is an U6 uniform (OS) language that incorporates the following languages:
AIPL – Artificial Intelligence Programming Language - real-time adaptive, scripting, self-writing program, also used as a development tool.
ICICL – Information and Computer Interface Command Language – incorporates a network OS and related functions; it is the primary interface with other network formats.
SLATRAN – Symbol-to-Logic Array Translator- used by the OEM to make changes in processing and memory of optronic (Photonics) and electronic interfaces, i.e., translation of databases and other operating systems, debugging, and seamless interfacing with the Photonic environment.
MACOL – Machine Access Object Language - an engineering language that is used to upgrade an I/O, thin client type of Luxon computers up to a full PC or even a server. Also the standard OS for mobile phones authorized for use in Attland. Coincidentally, MACOL is also the language (sometimes referred to as MacOL) used on iPhones and iPods manufactured by Koborg Photonics jointly with Apple. The lnaguage also controls and provides for smooth interface and easy upgrades between the U6connect uniform standard with international mobile system standards and generation versions.

Foreign manufacturers are stuck in a Catch 22: like everyone lese, they can't have the LUICS code embedded into their electronic devices, and to have the code they need to purchase ready made photonic hardware, for which they can never get the license.

The U6 headquarters and the central operations center are located in the thick of the square blocks of Brunnholn giant city of the Miklasgard megacity.

King Yarl was the first to conceive such a unified standard system which became U6net, an ADSL-like country-wide internet in 1979. The same year it created a compact information, reference and commercial information network that used telephones equipped with video displays as terminals.

The U6 also was the first system that regulated the pioneering, GSM-like mobile phone system in 1975. 1983 U6 ushered in telephony and U6net transmission over electrical power supply.

Turbocharged fanprop

The unique turbofan prop engine illustrated below is a product of King Yarl's incessant work on many projects. The projects always overlapped. The King also saw the engine applied in his country's own aircraft designed from scratch. (Unlike the Vandal aircraft, which use structural concepts developed jointly with US manufacturers) These indigenous aircraft comprised unusually fast and maneuverable Coast Guard patrol-gunship planes, a large attack gunship plane and a utility heavy lifter plane.

The engines are unique because they preserve efficiency of a turboprop at any speed and altitude, allowing for controlling individual speeds of turbines, propellers, and propeller pitch. Another unique feature of the engine is having an equivalent of a turbocharger and a variable afterburner.

How the MHD (Plasma) propulsion works

The MHD (Magnetohydrodynamic, or Plasma) propulsion employs a very simple construction with minimal moving parts. The only moving parts are less than 20 valves needed to occasionally control auxiliary power compressor, or the flow of cold gas to the engine jacket.

The propulsion is used solely on the Vandal project aircraft. The gas is usually xenon. The liquefied gas flows under its own expansion-generated pressure through the chamber jacket, where it undergoes heating and further expansion, and enters the electric ionizer, whose function is very similar to the conventional fluorescent light. The ionized gas is then split into symmetrical injectors and fed into the chamber head (the bulbous cavity). There the gas is ionized further by the X-ray ionizer into a complete plasma state.

The extremely large AC voltage gradient of specific field characteristics and frequency is continuously applied between the chamber head and the chamber nozzle, and this results in simultaneously pinching and pumping the plasma into an extremely narrow, tubular flow path. The Electromagnetic ionizer conditions the plasma, pinching and accelerating it further, imparting speeds over 3-4 Mach.

The aircraft's power is generated by channeling of some of the jacket-heated gas into a turbogenerator, and returning the gas into the injector feeds. During the cold starts the aircraft uses a dedicated storage battery to power the ionizers. Hot start is possible after the chamber standby, wherein the chamber has not received gas flow, is flooded with cooler gas and the electric ionizer is at low power.

The plasma generation characteristics of the engine dictate that speeds below 300-400 are unsustainable. There is a moderate difference between fuel usage at cruise or maximum speed. In order to maintain low speed, only one chamber is used, and the remaining chambers ( 1, 2 of 3 in Vandal T-22, 3 of 4 in Vandal XB-70) are shut down, or put into a standby state.

More specific details are never disclosed by the DOD and Koborg Turbomotors Propulsion Research Center in Kingstad. The Koborg Corporation and the MHD engine are the creations of King Yarl.

Interesting Koborg lawsuits

Throughout the last 10 years Koborg Corporation has also made good money through winning or settling several lawsuits. One of these is the famous Microsoft lawsuit, where Koborg has ascertained that the Microsoft server-router traffic that is usually handled by Koborg Photonics Network Solutions' indexing servers at ICANN, rerouted connections to Microsoft Exchange and .net servers, SQL servers, causing revenue loss, congestion, and longer response time throughout Internet, and especially e-mail. Koborg won more than $23 billion settlement.

In a similar lawsuit, Koborg sued Google for using ad, search servers, and performing active and archived URL hashing, agreement to use Koborg Photonics' Network Solutions servers for search and hashing. Koborg and Google reached an agreement, wherein the oonly specified details are that Google will employ Koborg Photonics servers for serving Adsense, Adwords, and Webtrends.


It is virtually unknown why Koborg sued Apple, inc., but the good guess is that the touch controls and display lighting and wiring somehow infringed on Koborg Photonics technology. Apple settled by paying unspecified license fees, n addition to agreeing to use Koborg technology in high-end iPod and iPhone touch pads and displays.

I bought a Luxon and I am learning UCICS

I am buying an incredible laptop. It is about an inch thin, very lightweight, and it is not electronic. Though it is Photonic, or quantum. Finally, I shelled out 2 royal crowns and 230 darlings, (2.23x$1210) almost $2698 for Luxon F-YON. It has a two way monitor, and a keyboard area made of the same kryptonite-embedded polymer interactive surface, that is turned into the third screen.

The keys can luminesce into any 4 of Attland's writing system character sets, Japan's Katakana, Hiragana and Kanji, as well as English, Hebrew, Korean, all Germanic languages, but not Chinese, Arabic or Cyrillic. I love downloading the whole newspaper in a fraction of a second, and then read it at a coffee shop, propping it up on the table just like above.

Graet thing about it that there is no need for backups - quantum computers don't crash or lose data.The biggest minus is that it is impossible to enjoy the Photonics system on other PC platforms. Photonics can support Windows with all its applications, but not the other way around. The UCICS system and the Photonics have set up and programmed the PC so it cannot be activated outside the market area - that is why it is nearly meaningless to buy and resell the Photonics PCs in countries that are not on the Attland's preferred trading partner list.

My Luxon has only one type of PC interface - three USB sockets. All other sockets are coherent Photonics outlets. I can designate a part of my 140 GB memory for my favorite XP Home edition, a part for Linux, so I can learn and practice, and still have tons of memory left for movies, presentations, and Wall Street Journals.

I understand that Photonics PCs have no conventional CPUs. There is a block of kryptonite-precision impregnated metal-organic polymer, which is zapped with 24 volts, oscillates at 3-4 Gigahertz, and becomes a 5- or 8 dimensional simultaneous RAM-ROM-CPUs, each processing or storing data in instantly created arrays. The only other photonic materials are the I/O interactive surfaces - the thin sheet that is the screen, and the keyboard. The screen is also a touch sensor, and a video sensor of dimensions designatable by the user.

The quantum system requires no machine language, scripts or plugins. The photonic CPU comes embedded with the 5 Koborg Photonics languages that comply with the Attland's UCICS (The Unified Communication, Information and Computing System)

LUICS ( or Linguistic User Interface Command System) Logic-code Uniform Interface Command System is an U6 uniform (OS) language that incorporates the following sublanguages:
AIPL – Artificial Intelligence Programming Language - real-time adaptive, scripting, self-writing program, also used as a development tool.
ICICL – Information and Computer Interface Command Language – incorporates a network OS and netbios functions, it is the primary interface with other network formats
SLATRAN – Symbol-to-Logic Array Translator- used by the OEM to make changes in processing and memory of optronic (Photonics) and electronic interfaces, i.e., translation of databases and other operating systems, debugging, and seamless interfacing with the Photonic environment.
MACOL – Machine Access Object Language - an engineering language that is used to upgrade a I/O, thin client type of Luxon computers up to a full PC or even a server.

Koborg's Luxon ($1,300 for D-YON, the cheapest model), as well as its crystal-embedded polymer display technology licensed to Optar, and which has been marketed as Optar Raylynd ($1379) are uncomfortably expensive, but, hey, what other monitor would let you see through it, or display a different screen on its flip side, or have a perfectly placed control panel buttons on its face just the way you like it, or have the 3-D clicking, or , which you might only dream of - assign a section of the screen to serve as a web cam (Luxon E-, F-, and G-YON)?

Or this projection computer - it's great for presentations, and it fit into a pocket. Everything in it is Koborg Photonics - from touch-sensor projector keyboard, to a coherent laser display.

I am buying an already used alternative NRG car

It has been less than a year since last September when the government ordered the whole country to switch all passenger-carrying cars from internal combustion to either hybrid, electric or biopower (synthetic muscle) power.

Half the cars switched to hybrid, using the synthetic esterol (ester-alcohol) fuels. Some, probably municipal and corporate pools went plugin-electrical all the way, and good 20% are driven by the synthetic muscle engine.

Given that Citroen C series car look has been regarded as one of the most attractive of cars, Attland's remanufacturers and custom makers have been purchasing Citroens from the French manufacturers and installing engines according to a customer's specifications.

I needed a car, right away. I could not afford to buy a brand new car. Or wait for a custom car to be put together. So I bought a sued one, It already has the synmuscle engine in it.
The car is very simple to operate. Simpler than a plugin electrical. In the electrical controller 1, the battery supplies current to the programmed pulse generator, which contract or expand the individual synthetic muscles by sending pulses of specific polarity, current and duration. Each muscle is made of a proprietary crystal-impregnated polymer invented by King Yarl.

The concept is not so new. My interior decorator girlfriend from Russia says that long time ago, in the Russian children's story The Adventures of Neznaika and his Friends (Приключения Незнайки и его друзей, 1954) Nikolai Nosov had the cute idea of a contracting muscle-powered car, described jokingly as a single-muscle engine that has a cylinder filled with soda drink. Very Jules-Verne-like prophecy, I'd say. Some time later, Toyota cam up on the idea of electrically sensitive gel (Tohru Shiga Toyota Central Research and Development Laboratories, Japan)

As long as I stay in Attland, with its weather between 60-90 deg F, it means the motor will need no warming and minimal cooling by its electrolyte conditioner.

There is no huge bank of batteries, as in other electrical cars. Instead, in the trunk there is a large battery the size of a microwave. The engine itself is rather small, since the bionic muscle produces power during contracting and expanding. There is no large fluid storage tanks. Half of the electrolyte is always in the electrolyte conditioner ( see 4 in the drawing above). The engine is also light since the camshaft has no flywheel, because the engine cycles have no dead spot - due to the electrical-stimulated contracting and expanding. There are no pumps. The electrolyte is recirculated by the bionic muscles' action. The two-cylinder bionic muscle engine is rated for 120 HP.

When idle, no current is used. If the weather is very hot, the 4 conditioner automatically sends electrolyte to an external loop ( I guess it is not shown on the diagram).

The downside? The bionic muscle has a limited optimal performance period, something like 1000 hours. I didn't see the replacement prices, but as a new technology, it seems that the specific bionic muscle that is sued in my car would cost around 700 gold crown ounces to replace. The battery needs to be recharged every two weeks or so, for a normal 2 hour everyday highway-street driving.

A slightly improved conventional bomb comes out of the closet

The Attland Government has just come out (www.attlandonweb.gov/press_release_2009.asp and presskit@secretary@nationalgovt) and plain revealed the use of the noise bombs in its Namibian (see the FLIGHT HOME operation) and Sothern Iraq operations. The tactic appears to use smoke and noise bombs, before exercising the option to drop the electron discharge -lightning bombs.



The red-tipped noise bomb with the red programming socket on the bomb's side. The next bomb is a smoke bomb, and behind it, a grey-tipped, modified FAE.

Each of the noise bomb is individually pre-programmed to delay the explosion after parachuting to the point of impact, in order to produce the loudest and most unnerving and chaotic jumble of shrieks, screams and screeches, with unpredictable pauses. The bombs explode either at the programmed time, or when touched. Smoke bombs are very similar in their operations, producing copious amount of smoke before their programmed explosion. All these bombs used together totally disorient the civilians and military personnel.

The Kingstad University gave me the map of the National Accelerator Complex

Besides the Business Communications course I teach at a school for permanent residents in Miklasgard, I also teach scientific report writing

One of the students arranged for me to take a tour of a part of the National Accelerator Complex, which was founded by King Yarl. University of Kingstad Institute of High Energy Physics (another of King's brainchild ideas) operates many of scientific projects throughout the complex.

The schematic layout is not to scale nor is geographically correct.

I visited the J7-JS2 facility, which is outside Karolinga, right next to the airport (and what seems to be one fo the well-secured military aircraft manufacturing plant), and the T1/J1 facility seems right next to it, if you look at the map. The T1 facility, actually, is more than 40 miles away at the Lievingbron Air Force Base and Space Center. The other terminus (T3/J5) of the A2 Linac is at the Soderstrand Space Center. It is very convenient for the military, since it can control all of the operations of the Linac.

The original portion of the complex that King Yarl had envisioned and built is the A1 and A3 linacs, where A1 was originally reached from T2 to C. The C installation now is a dedicated collider facility.

I don't know where the rest of the injector, T2 and T4 sites are. Most of them have no geographical names attached.

I was told that the Plutonium-238 which was in such short supply for space mission's power generators (see this Space article) is made at the A3 T1 and T3 facilities, and since the article's release, Attland has already produced more than 5 pounds of the isotope. What has worried international nuclear watchdog organizations is that Attland has never signed any nuclear treaties, because it has a certified, non-breeder reactor facilities, but it can now manufacture any strategic isotope and metal at any of the National Accelerator Complex target facilities. The T1 and T3 facilities are also the locations where slugs for the electron resonance weapon are made. (Alternative names for the weapon is plasma cascade, electron discharge cascade, the lightning bomb, etc)

What must be a feasibility and demonstration project, using the NAC facilities the University of Kingstad has synthesized over 11 pounds of gold, 25 pounds of thorium pounds of uranium and 5 pound quantities of other rare metals.

King's Plasma Cascade Discharge Bomb

Both USA and USSR have been working on EMP weapons, and they all come up with wither conventional (coil, capacitor, electric discharge) or nuclear methods of producing an EMP. King Yarl has used his Adiabatic Cannon at his own High Energy Physics Institute to process krypton-containing kleistonite, aluminum and carbon to produce an explosive that is at least 5-10 times more powerful than TNT, produces hellish shock wave, an incredible EMP, and zero nuclides or radiation.

From what I found out on U6 web (education@public@kshepi), is this 2-shot process:

Shot 1: a target of pure dry ice (carbon dioxide) is shot with a slug of Aluminum Hydroxide, in the adiabatic cannon using a 2 to 5 ton high explosive charge, producing a solid Aluminum Carbide (Al4C3), just the kind that is found in cyalith.

Shot 2: At the National Accelerator Complex, a target of finely powdered cyalith, especially the kind that is high in deuterium, is bombarded with a series of particle beams ( of unknown sequence) of D2O deuterium water, xenon, lead, and magnesium alloy, resulting in a stressed latticed dispersion of xenon, and lead deuteroxide.



The two targets are kept well-separated from each other, and in a well-grounded container.

The principle behind the explosive potential is unlike the critical mass that is necessary for nuclear fission of isotopes.

What causes the explosion of hellish electric discharge is the third shot, when the two targets are fired at each other as quickly and snugly as possible. The Electron-rich xenon, packed too close for comfort into the cyalith homogeneous lattice, exerts repulsive interatomic pressure on lead and Aluminum Carbide, both in a structured but superstressed unstable lattice state. Further lattice formation is impossible, causing a massive oscillation of electrons that hit against deuterium and lead, and, soon thereafter, all these atoms become jarred till they start shedding their electrons, becoming ionized to a plasma state, and attempting to recapture any electrons around. The electrons have been expelled by deuterium into the surroundings, forming an electron cloud, destabilizing atoms of nitrogen, carbon and oxygen in the air, short-circuiting the air and ground, and in the result producing a flash, then a positive lightning of one stroke(in weapons over 600 kg (approximately 7 KT TNT equivalent), and a third, large flash.

Understandably, when shot out of a military weapon, the two targets cannot be juxtaposed, since it would lead to an immediate detonation inside the barrel. Instead, the targets are microencapsulated and dispersed with high explosive powder.

In missiles and dropped ammunition the targets are juxtaposed just like in a gun-type nuclear device.

The extremely destructive explosion produces little or no mushroom cloud, and low amounts of clouds of dust and debris.

When exploded in a rainy, wet weather, the device produces a more powerful first flash, and a weaker third flash.
Exploded underground, the device produces a lightning bolt, and a destructive third flash that excavates a deep crater.
Exploded in midair the weapon causes a minimal first flash, a powerful lightning strike, and an extremely powerful large flash.
Underwater explosions create a extreme energy discharge in the form of a shock wave.

Characteristics of this EMP (plasma cascade discharge, particle-discharge, Ударно-волновой излучатель) explosive:


Peak electric field of the first flash 100,000-1 million volts/meter
Peak electric field of the lightning 50,000-100,000 volts/meter
Peak electric field of the large flash 12-30 billion volts/meter

Speed of the first flash 50-100 km/s
speed of lightning 300-400 km/s
speed of the large flash 60-90 km/s

temperature of the large flash 4-6 billion Cenigrade
lightning current - at least 400-500 kA
voltage, depending on terrain, air and detonation height - 1-3 teravolts
pressure towards the end of the last flash 2-3 billion atm

King Yarl's Biography

King Yarl (Kjoning Gyarl) was a true renaissance man and polymath: he was a statesman, a politician, a scientist, a national leader, a physicist, a chemist, a geologist, an archeologist, an engineer and an inventor.

He was also a highly organized hobbyist who had time to enjoy collecting coins, gems, stamps, and growing flowers. King Yarl is also one of the most socially connected persons, having met prominent personalities from almost four generations, many countries, most professions and political activities, and members of same families throughout different time periods.

He was also a hyperglot, speaking fluently 4 Attlandian languages, English, German, French, Spanish, Italian, Swedish, Norwegian, Icelandic, Danish, Esperanto, Japanese and Hebrew. He also was proficient in reading and writing Russian, Polish, Portuguese, Greek, Latin and Chinese.

His father's death coincided with the death of the late Prince Gustav Adolf, Duke of Västerbotten and Princess Sibylla of Saxe-Coburg and Gotha (family line unrelated to the King Yarl’s lineage), the father of the present king of Sweden, in an airplane crash outside Copenhagen, Denmark, on 26 January 1947.

Formative years and education

King Yarl was born Yarl Hrothgar in his parents’ royal apartments in the Koningsborg Fortress. His parents, King Ethelgar and Queen Feyli, enjoyed their status as the richest individuals in the world, owning wealth amassed throughout the last 3 centuries that was well invested and grew to over $20 billion, the exact amount is unknown due to the very private status of royal affairs and businesses.

His father was the administrator of the family’s fortunes through running a gold and currency bank which used to be the Attland’s Central Bank, and has been relegated to be his own private enterprise. He generously gave to philanthropic causes and arts, in partnership the help of his wife, who was an art lover and critic, and together they built up quite an impressive collection of sculptures and paintings, as well as attracting top talent opera singers and ballet stars. The couple owned and bequeathed to their son their collection of art and precious objects which includes 8 Faberge eggs, the original prepublication manuscript of Eugene Onegin that has the famous lost chapter,

The parents spared no money and resources on their son. The most gifted and professional tutors were employed to raise prince Yarl. Since 5 years of age he already enjoyed stories of adventure and science, especially that of US President Franklin, who had become one of his ideals.


His father loved to take his family on vacation in US and Europe, where he owned several residences (New York, Snowmass in Colorado, Paris, London, Berlin, the island of Capri, Nice, and at about this age while on a trip to Germany, in the middle of the war, his father took his son to meet Kaiser Wilhelm II.

At 9 years of age the prince already owned simple instruments for demonstration of electricity, and the most expensive of professionally made telescopes available at the time. He also owned a collection of cowboy paraphernalia that included a Yellowboy lever action rifle that he fired at the palace gun range located in the back of the palace (now one of private gardens enclosed deep within the modern Royal Palace complex) while wearing ear muffs designed especially for him.

At about this age he grew fascinated with electricity, as a result of reading the accounts of Benjamin Franklin’s experiments with lightning. The prince soon showed interest in storing or reproducing the electricity for use in electrical motors. At about 10 years of age he displayed many talents for mathematics and physics, and started to build his own models of electrical motors, and combinations of flash bulbs, capacitors and other electrical components. He also started to experiment on interactions of electricity with heat, fire, magnets and gases.

The prince quickly aced the standard high school curriculum at the Miklasgard College Junior School, and excelled on his graduation equivalency exams, receiving the only low grade of B in Greek Drama, below his A average of the rest of the courses. At this time he entertained his family by decorating his room with his home-made (what may have been the first) fluorescent and neon lights; and during family picnics by cooking hot dogs and skewered meat with electric current.

At Copenhagen 1921-1924 he researched deuterium and discovered heavy water together with Harold Urey (who was credited with the 1933 discovery)

…has worked for the RAND Corporation And afterwards at Sperry Rand producing the company's first digital computer, SPEEDAC, in 1953.

He went on the safari with E. Hemingway in the fall of 1933 to Mombasa, Nairobi, and Machakos in Kenya, moving on to Tanzania, where he hunted in the Serengeti, around Lake Manyara and west and southeast of the present-day Tarangire National Park.

List of inventions:

(1) Latticed Polymer Crystals, Optically-Active Crystals, Crystal Photonic Logic and spinoffs:

• Computing Devices,
• networks,
• UCICS,
• integrated displays and devices,

(2) Electron-Ion Cascade Charge Energy

• Supercharged ion discharged Explosives
• Matter Synthesis Particle Accelerator and Storage Devices

(3) Integral Core Nuclear Reactor

(4) Differential Spectrum Surface and Material Scanning

(5) Deep-Water Oil Drilling and Production Systems

(6) Radio-ionized plasma

• plasma reactor
• aerospace propulsion engine

(7) Composite Metals and thermodynamic diffusion alloys:

• Electric conductors and solid state microelectronics
• Combustion, molecular synthesis and waste recycling catalysts
• Bimetallic coins

(8) Turbomolecular filtering

(9) Variable Mirror Optics

(10) Ocean Bottom Methane Clathrate Extraction

(11) Special electrical motors

(12) Bionic reciprocal motor

(13) developed wolrd’s first digital and opt electronic computers,

(14) formulated the idea of Internet

(15) various aircraft engines based on combinations of turborpop, turbojet and other technologies

Accomplishments:

1. Instrumental in obtaining help from Admiral Canaris to grant safe passage for Rabbi Schneerson in 1940, and other Jews out of Nazi-occupied areas.

2. Succeeded in photographing conditions in Nazi industrial facilities and concentration camps:

Vaihingen an der Enz (officially named Wiesengrund) concentration camp, near the city of Vaihingen an der Enz in the Neckar region

Dora V-2 missile factory

Mauthausen camp associated facilities:
Flugmotorenwerke Ostmark aircraft engine manufacturing plant
Heinkel and Messerschmitt (aircraft factories, also a V-2 rocket fuselage factory)
Österreichische Sauerwerks arms producer
Rax-Werke machinery and V-2 rockets production site

3. Founding the Koborg College (later the King Yarl Research School)

3a. Established courses unique for his time: NGO, globalization, studies in peace doctrine, studies in socialism, and computational logic.

4. 1920-1930 developed voltage-multiplier charge collider and cascade device.

5. producing the company's first digital computer, SPEEDAC, in 1953.

6. Organized the unique Maarheinigt (Regular Ranks) armed forces.

7. Invented and planned the manufacture of a plasma-powered fighter jet plane.

8. Ended the period of chaos and destructive political situation leading to the beginning of an open conflict between constitutionalists, republicans, anarchists, socialists, and communists and conservatives, monarchists, nationalists, populists, and established a stable compromise government.

9. Expanded the family’s traditional banking business, Koborg Bank, into industrial and insurance, forming the Koborg Corporation.

10. Studied and discovered unusual rocks unique to Attland, naming them and researching their geochemistry, further discovering important metal ores.

11. One of the original authors (together with Claude Elwood Shannon (April 30, 1916 – February 24, 2001), an American electronic engineer and mathematician) of Information Theory

In Germany:

Wilhelm II 27 January 1859 – 4 June 1941

Vladimir Nabokov 22 April 1899, Saint Petersburg – 2 July 1977

Met Rabbi Menachem Mendel Schneerson and Rabbi Joseph B. Soloveitchik while they both studied in Berlin

Konrad Adenauer 5 January 1876 – 19 April 1967

Erwin Rudolf Josef Alexander Schroedinger 12 August 1887 – 4 January 1961
Berlin

Bohr 1885-1962 - Copenhagen from 1921
Max Plank 1858-1947 Kiel, Berlin, Goettinggen, Kaiser-Wilhelm Inistute,

George Gamow (March 4, 1904 – August 19, 1968)On graduation, he worked on quantum theory in Göttingen, where his research into the atomic nucleus provided the basis for his doctorate. He then worked at the Theoretical Physics Institute of the University of Copenhagen, from 1928 to 1931.

Werner Heisenberg 5 December 1901 - 1 February 1976

Albert Speer March 19, 1905 – September 1, 1981

Otto Hahn 1879-1968 Hahn and nine German physicists (including Max von Laue, Werner Heisenberg and Carl Friedrich von Weizsacker) were interned at Farm Hall, Godmanchester, near Cambridge, England.

Wilhelm Franz Canaris (January 1, 1887 – April 9, 1945)

Erich Johann Albert Raeder 24 April 1876–6 November 1960

Bernhard Rogge admiral November 4, 1899 – June 29, 1982

Baldur Benedikt von Schirach May 9, 1907 – August 8, 1974

Eugen Saenger September 22, 1905 - February 10, 1964

Eduard Schulte, German industrialist ( 4 January 1891 in Düsseldorf – 6 January 1966 in Zürich) was a prominent German industrialist was one of the first to warn the Allies and tell the world of the Holocaust

Gerhart Moritz Riegner, office manager of the WJC in Geneva, (September 12, 1911 in Berlin–December 3, 2001) in Geneva, Through British and American diplomatic channels Riegner sent the following message to London and Washington

Wernher von Braun March 23, 1912 – June 16, 1977

Hans-Ulrich Rudel 2 July 1916 – 18 December 1982

General Walter Bedell "Beetle" Smith October 5, 1895 – August 9, 1961

Internationally:

Ernest Hemingway (July 21, 1899 — July 2, 1961)

Antoine de Saint Exupéry (June 29, 1900—July 31, 1944)

Maxim Gorky (March 28, 1868 – June 18, 1936) from 1921 to 1929 he lived abroad, mostly in Capri, Italy;

James Joyce (2 February 1882 – 13 January 1941)

Gertrude Stein (February 3, 1874 – July 27, 1946)

Virginia Hall April 6, 1906 - July 14, 1982

Thomas Stearns Eliot, (September 26, 1888 – January 4, 1965)

Hannes Olof Gösta Alfvén (May 30, 1908, Sweden – April 2, 1995, a Swedish plasma physicist and Nobel laureate for his work on the theory of magnetohydrodynamics. He was originally trained as an electrical power engineer and later moved to research and teaching in the fields of plasma physics.

Subrahmanyan Chandrasekhar, October 19, 1910 – August 21, 1995 In Copenhagen

Lionel Walter Rothschild, 2nd Baron Rothschild (February 8, 1868 – August 27, 1937)

Nathaniel Victor Rothschild, 3rd Baron Rothschild, GBE, GM, FRS (October 31, 1910 – March 20, 1990)

Francisco Franco December 4, 1892 in Ferrol, died November 20, 1975

Alfredo Stroessner November 3, 1912 August 16, 2006

Anastasio Somoza Debayle December 5, 1925 – September 17, 1980

In US:

Ezra Pound October 30, 1885 – Venice, Italy, November 1, 1972

Nikola Tesla (10 July 1856 – 7 January 1943)

William Faulkner (September 25, 1897–July 6, 1962)

Francis Scott Key Fitzgerald (September 24, 1896 – December 21, 1940)

Dale Carnegie November 24, 1888 – November 1, 1955

Jean Paul Getty December 15, 1892 – June 6, 1976

Dorothy Parker (August 22, 1893–June 7, 1967)

John Davison Rockefeller July 8, 1839 – May 23, 1937

John Davison Rockefeller, Jr. (January 29, 1874 – May 11, 1960

David Rockefeller Sr. June 12, 1915

Robert Lee Frost (March 26, 1874 – January 29, 1963)

Theodore Roosevelt October 27, 1858 – January 6, 1919

Julia Child (born Julia Carolyn McWilliams August 15, 1912 – August 13, 2004

Ayn Rand February 2, 1905 – March 6, 1982

Morris "Moe" Berg March 2, 1902 – May 29, 1972

Marlene Dietrich December 27 1901–May 6 1992

Howard Hughes, Jr. December 24, 1905 – April 5, 1976
Hughes was living in the Intercontinental Hotel near Lake Managua in Nicaragua, seeking privacy and security,[33] when a magnitude 6.5 earthquake damaged Managua in December 1972. As a precaution, Hughes moved to the Nicaraguan National Palace and stayed there as a guest of Anastasio Somoza Debayle before leaving for Florida on a private jet the following day.[34] He subsequently moved into the Penthouse at the Xanadu Princess Resort on Grand Bahama Island, which he had purchased recently. He lived almost exclusively in the penthouse of the Xanadu Resort and marina for the last four years of his life.

Dwight David Eisenhower October 14, 1890 – March 28, 1969

Joseph Patrick "Joe" Kennedy, Sr. September 6, 1888 – November 18, 1969

John Fitzgerald Kennedy May 29, 1917 – November 22, 1963

Raoul Wallenberg August 4, 1912 – July 17, 1947

Charles Augustus Lindbergh, February 4, 1902 – August 28, 1974

Joseph Patrick Kennedy, Jr. July 25, 1915 – August 12, 1944, entered Harvard University in 1934 and graduated in 1938

Lieutenant General Leslie Richard Groves 1896 – July 13, 1970), VP of Sperry Rand 1946-1961

Clarence Leonard Johnson February 27, 1910 – December 21, 1990, leader of the Lockheed Skunk Works,

Linus Carl Pauling (February 28, 1901 – August 19, 1994

Colonel Arthur D. "Bull" Simons June 28, 1918 - May 21, 1979

Thomas Kennerly Wolfe, Jr. (born March 2, 1931

Samuel T. Cohen (born 1921) RAND Corp., 1950,

Hyman Rickover, January 27, 1900 – July 8, 1986

Philip Hauge Abelson (April 27, 1913 – August 1, 2004) was an American physicist, editor of scientific literature, and science writer. The Liquid Thermal Diffusion isotope separation technique that he invented was used in the S-50 plant in Oak Ridge, Tennessee, and proved a critical step in creating sufficient fuel for the weapon.

James Edwin Webb (October 7, 1906 – March 27, 1992) was the second administrator of NASA, serving from February 14, 1961 to October 7, 1968.

James Jesus Angleton December 9, 1917 – May 12, 1987 gemologist and orchid-breeder

Richard McGarrah Helms March 30, 1913 – October 22, 2002 met King Yarl at Berlin Olympics; after becoming the Director of CIA was instrumental in helping the king to train and execute the invasion.

Jesse Alexander Helms, Jr. October 18, 1921 – July 4, 2008

James Strom Thurmond (December 5, 1902 – June 26, 2003)

Jerry Lamon Falwell, Sr. (August 11, 1933 – May 15, 2007

George Corley Wallace Jr. (August 25, 1919 – September 13, 1998

Robert Carlyle Byrd (born November 20, 1917

Zbigniew Kazimierz Brzezinski (born March 28, 1928) His father was Tadeusz Brzeziński, a Polish diplomat who was posted to Germany from 1931 to 1935; Zbigniew Brzezinski thus spent some of his earliest years witnessing the rise of the Nazis.

Awarded the titile of von Koborg (Coburg), by virtue of his ancestors having won the battle over the Saxe-Coburg and Gotha (Carolingen and Thyringen) in 1132.