Governmental Regulations
The new U.S. regulations are based on the Wassenaar Arrangement Revision of 1998, where exports without license of 56 bit  DES and similar products are allowed after a technical review, just like encryption commodities and software with key lengths of 64-bits or less which meet the mass market requirements.
For more information see:
 http://www.wassenaar.org/
Seven states stay excluded from the new freedom. These are states like Libya, Iraq, Iran, North Korea and Cuba, altogether states seen as terrorist supporting. No encryption tools may be exported into those countries.
This is, what happened in the USA, whereas in Germany the issue of a cryptography-law is still on the agenda. Until now, in Germany, everyone can decide by her-/himself, whether she/he wants to encrypt electronic messages or not. Some organizations fear that this could get changed soon. Therefore an urgent action was organized in February 2000 to demonstrate the government that people want the freedom to decide on their own. One governmental argument is that only very few people actually use cryptography. Therefore the urgent action is organized as a campaign for using it more frequently.
For more information on this see:
http://www.heise.de/ct/97/04/032/
http://www.fitug.de/ulf/krypto/verbot.html#welt
Other European countries have more liberate laws on cryptography, like France. Austria doesn't have any restrictions at all, probably because of a governmental lack of interest more than accepting freedom.
The (former) restrictions in the bigger countries influenced and hindered developments for safer key-systems, e.g. the key-length was held down extraordinarily.
"Due to the suspicious nature of crypto users I have a feeling DES will be with us forever, we will just keep adding keys and cycles (...). There is a parallel between designing electronic commerce infrastructure today that uses weak cryptography (i.e. 40 or 56 bit keys) and, say, designing air traffic control systems in the '60s using two digit year fields. (...) Just because you can retire before it all blows up doesn't make it any less irresponsible."
(Arnold G. Reinhold)
The Chinese State Encryption Management Commission (SEMC) announced in March 2000 that only strong encryption tools will have to be registered in the future. Which sounds so nice on first sight, does not mean a lot in reality: any kind of useful encryption technique, like the PGP, stay under governmental control.
The restrictions and prohibitions for cryptography are part of the states' wish to acquire more control - in the name of the battle against criminality, probably?
Due to the emerging organized criminality the governments want to obtain more freedom of control over citizens. Organizations like the NSA appear as the leaders of such demands.
What about civil rights or Human Rights?
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 TEXTBLOCK 1/5 // URL: http://world-information.org/wio/infostructure/100437611776/100438659135
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ECHELON Main Stations
Location
| Country
| Target/Task
| Relations
| MORWENSTOW
| UK
| INTELSAT, Atlantic, Europe, Indian Ocean
| NSA, GCHQ
| SUGAR GROVE
| USA
| INTELSAT, Atlantic, North and South America
| NSA
| YAKIMA FIRING CENTER
| USA
| INTELSAT, Pacific
| NSA
| WAIHOPAI
| NEW ZEALAND
| INTELSAT, Pacific
| NSA, GCSB
| GERALDTON
| AUSTRALIA
| INTELSAT, Pacific
| NSA, DSD
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| MENWITH HILL
| UK
| Sat, Groundstation, Microwave(land based)
| NSA, GCHQ
| SHOAL BAY
| AUSTRALIA
| Indonesian Sat
| NSA, DSD
| LEITRIM
| CANADA
| Latin American Sat
| NSA, CSE
| BAD AIBLING
| GERMANY
| Sat, Groundstation
| NSA
| MISAWA
| JAPAN
| Sat
| NSA
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| PINE GAP
| AUSTRALIA
| Groundstation
| CIA
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| FORT MEADE
| USA
| Dictionary Processing
| NSA Headquarters
| WASHINGTON
| USA
| Dictionary Processing
| NSA
| OTTAWA
| CANADA
| Dictionary Processing
| CSE
| CHELTENHAM
| UK
| Dictionary Processing
| GCHQ
| CANBERRA
| AUSTRALIA
| Dictionary Processing
| DSD
| WELLINGTON
| NEW ZEALAND
| Dictionary Processing
| GCSB Headquarters
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TEXTBLOCK 2/5 // URL: http://world-information.org/wio/infostructure/100437611746/100438659207
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Problems of Copyright Management and Control Technologies
Profiling and Data Mining
At their most basic copyright management and control technologies might simply be used to provide pricing information, negotiate the purchase transaction, and release a copy of a work for downloading to the customer's computer. Still, from a technological point of view, such systems also have the capacity to be employed for digital monitoring. Copyright owners could for example use the transaction records generated by their copyright management systems to learn more about their customers. Profiles, in their crudest form consisting of basic demographic information, about the purchasers of copyrighted material might be created. Moreover copyright owners could use search agents or complex data mining techniques to gather more information about their customers that could either be used to market other works or being sold to third parties.
Fair Use
Through the widespread use of copyright management and control systems the balance of control could excessively be shifted in favor of the owners of intellectual property. The currently by copyright law supported practice of fair use might potentially be restricted or even eliminated. While information in analogue form can easily be reproduced, the protection of digital works through copyright management systems might complicate or make impossible the copying of material for purposes, which are explicitly exempt under the doctrine of fair use.
Provisions concerning technological protection measures and fair use are stated in the DMCA, which provides that "Since copying of a work may be a fair use under appropriate circumstances, section 1201 does not prohibit the act of circumventing a technological measure that prevents copying. By contrast, since the fair use doctrine is not a defense e to the act of gaining unauthorized access to a work, the act of circumventing a technological measure in order to gain access is prohibited." Also the proposed EU Directive on copyright and related rights in the information society contains similar clauses. It distinguishes between the circumvention of technical protection systems for lawful purposes (fair use) and the circumvention to infringe copyright. Yet besides a still existing lack of legal clarity also very practical problems arise. Even if the circumvention of technological protection measures under fair use is allowed, how will an average user without specialized technological know-how be able to gain access or make a copy of a work? Will the producers of copyright management and control systems provide fair use versions that permit the reproduction of copyrighted material? Or will users only be able to access and copy works if they hold a digital "fair use license" ("fair use licenses" have been proposed by Mark Stefik, whereby holders of such licenses could exercise some limited "permissions" to use a digital work without a fee)?
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TEXTBLOCK 3/5 // URL: http://world-information.org/wio/infostructure/100437611725/100438659629
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Timeline of Communication Systems: Introduction
The timeline of communication systems presents a chronological overview of the most important events in the history of communication systems from the 4th millennium B.C. to the present.
It shows that from the very beginning - the first Sumerian pictographs on clay tablets to today's state-of-the-art technologies - broadband communication via fiber-optic cables and satellites - the amount of information collected, processed and stored, the capabilities to do so, as well as the capable speed of information transmission exponentially accelerate.
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TEXTBLOCK 4/5 // URL: http://world-information.org/wio/infostructure/100437611796/100438659793
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The 19th Century: First Programmable Computing Devices
Until the 19th century "early computers", probably better described as calculating machines, were basically mechanical devices and operated by hand. Early calculators like the abacus worked with a system of sliding beads arranged on a rack and the centerpiece of Leibniz's multiplier was a stepped-drum gear design.
Therefore Charles Babbage's proposal of the Difference Engine (1822), which would have (it was never completed) a stored program and should perform calculations and print the results automatically, was a major breakthrough, as it for the first time suggested the automation of computers. The construction of the Difference Engine, which should perform differential equations, was inspired by Babbage's idea to apply the ability of machines to the needs of mathematics. Machines, he noted, were best at performing tasks repeatedly without mistakes, while mathematics often required the simple repetition of steps.
After working on the Difference Engine for ten years Babbage was inspired to build another machine, which he called Analytical Engine. Its invention was a major step towards the design of modern computers, as it was conceived the first general-purpose computer. Instrumental to the machine's design was his assistant, Augusta Ada King, Countess of Lovelace, the first female computer programmer.
The second major breakthrough in the design of computing machines in the 19th century may be attributed to the American inventor Herman Hollerith. He was concerned with finding a faster way to compute the U.S. census, which in 1880 had taken nearly seven years. Therefore Hollerith invented a method, which used cards to store data information which he fed into a machine that compiled the results automatically. The punch cards not only served as a storage method and helped reduce computational errors, but furthermore significantly increased speed.
Of extraordinary importance for the evolution of digital computers and artificial intelligence have furthermore been the contributions of the English mathematician and logician George Boole. In his postulates concerning the Laws of Thought (1854) he started to theorize about the true/false nature of binary numbers. His principles make up what today is known as Boolean algebra, the collection of logic concerning AND, OR, NOT operands, on which computer switching theory and procedures are grounded. Boole also assumed that the human mind works according to these laws, it performs logical operations that could be reasoned. Ninety years later Boole's principles were applied to circuits, the blueprint for electronic computers, by Claude Shannon.
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TEXTBLOCK 5/5 // URL: http://world-information.org/wio/infostructure/100437611663/100438659426
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cryptology
also called "the study of code". It includes both, cryptography and cryptoanalysis
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 INDEXCARD, 1/4
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INTELSAT
INTELSAT is in business since 1964 and owns and operates a global communications satellite system of 17 geostationary satellites providing capacity for voice, video, corporate/private networks and Internet in more than 200 countries and territories.
http://www.intelsat.int/index.htm
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INDEXCARD, 2/4
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Invention
According to the WIPO an invention is a "... novel idea which permits in practice the solution of a specific problem in the field of technology." Concerning its protection by law the idea "... must be new in the sense that is has not already been published or publicly used; it must be non-obvious in the sense that it would not have occurred to any specialist in the particular industrial field, had such a specialist been asked to find a solution to the particular problem; and it must be capable of industrial application in the sense that it can be industrially manufactured or used." Protection can be obtained through a patent (granted by a government office) and typically is limited to 20 years.
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INDEXCARD, 3/4
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Punch card, 1801
Invented by Joseph Marie Jacquard, an engineer and architect in Lyon, France, the punch cards laid the ground for automatic information processing. For the first time information was stored in binary format on perforated cardboard cards. In 1890 Hermann Hollerith used Joseph-Marie Jacquard's punch card technology for processing statistical data retrieved from the US census in 1890, thus speeding up data analysis from eight to three years. His application of Jacquard's invention was also used for programming computers and data processing until electronic data processing was introduced in the 1960's. - As with writing and calculating, administrative purposes account for the beginning of modern automatic data processing.
Paper tapes are a medium similar to Jacquard's punch cards. In 1857 Sir Charles Wheatstone applied them as a medium for the preparation, storage, and transmission of data for the first time. By their means, telegraph messages could be prepared off-line, sent ten times quicker (up to 400 words per minute), and stored. Later similar paper tapes were used for programming computers.
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INDEXCARD, 4/4
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