History of telecommunication

The history of telecommunication began with the use of smoke signals and drums in Africa, Asia, and the Americas. In the 1790s, the first fixed semaphore systems emerged in Europe. However, it was not until the 1830s that electrical telecommunication systems started to appear. This article details the history of telecommunication and the individuals who helped make telecommunication systems what they are today. The history of telecommunication is an important part of the larger history of communication.

A replica of one of Claude Chappe's semaphore towers (optical telegraph) in Nalbach, Germany

Ancient systems and optical telegraphy

Early telecommunications included smoke signals and drums. Talking drums were used by natives in Africa, and smoke signals in North America and China. Contrary to what one might think, these systems were often used to do more than merely announce the presence of a military camp.[1][2]

In Rabbinical Judaism a signal was given by means of kerchiefs or flags at intervals along the way back to the high priest to indicate the goat "for Azazel" had been pushed from the cliff.

Homing pigeons have occasionally been used throughout history by different cultures. Pigeon post had Persian roots, and was later used by the Romans to aid their military.[3]

Greek hydraulic semaphore systems were used as early as the 4th century BC. The hydraulic semaphores, which worked with water filled vessels and visual signals, functioned as optical telegraphs. However, they could only utilize a very limited range of pre-determined messages, and as with all such optical telegraphs could only be deployed during good visibility conditions.[4]

Code of letters and symbols for Chappe telegraph (Rees's Cyclopaedia)

During the Middle Ages, chains of beacons were commonly used on hilltops as a means of relaying a signal. Beacon chains suffered the drawback that they could only pass a single bit of information, so the meaning of the message such as "the enemy has been sighted" had to be agreed upon in advance. One notable instance of their use was during the Spanish Armada, when a beacon chain relayed a signal from Plymouth to London that signaled the arrival of the Spanish warships.[5]

French engineer Claude Chappe began working on visual telegraphy in 1790, using pairs of "clocks" whose hands pointed at different symbols. These did not prove quite viable at long distances, and Chappe revised his model to use two sets of jointed wooden beams. Operators moved the beams using cranks and wires.[6] He built his first telegraph line between Lille and Paris, followed by a line from Strasbourg to Paris. In 1794, a Swedish engineer, Abraham Edelcrantz built a quite different system from Stockholm to Drottningholm. As opposed to Chappe's system which involved pulleys rotating beams of wood, Edelcrantz's system relied only upon shutters and was therefore faster.[7]

However, semaphore as a communication system suffered from the need for skilled operators and expensive towers often at intervals of only ten to thirty kilometres (six to nineteen miles). As a result, the last commercial line was abandoned in 1880.[8]

Electrical telegraph

Stock telegraph ticker machine by Thomas Edison

Experiments on communication with electricity, initially unsuccessful, started in about 1726. Scientists including Laplace, Ampère, and Gauss were involved.

An early experiment in electrical telegraphy was an 'electrochemical' telegraph created by the German physician, anatomist and inventor Samuel Thomas von Sömmerring in 1809, based on an earlier, less robust design of 1804 by Spanish polymath and scientist Francisco Salva Campillo.[9] Both their designs employed multiple wires (up to 35) in order to visually represent almost all Latin letters and numerals. Thus, messages could be conveyed electrically up to a few kilometers (in von Sömmerring's design), with each of the telegraph receiver's wires immersed in a separate glass tube of acid. An electric current was sequentially applied by the sender through the various wires representing each digit of a message; at the recipient's end the currents electrolysed the acid in the tubes in sequence, releasing streams of hydrogen bubbles next to each associated letter or numeral. The telegraph receiver's operator would visually observe the bubbles and could then record the transmitted message, albeit at a very low baud rate.[9] The principal disadvantage to the system was its prohibitive cost, due to having to manufacture and string-up the multiple wire circuits it employed, as opposed to the single wire (with ground return) used by later telegraphs.

The first working telegraph was built by Francis Ronalds in 1816 and used static electricity.[10]

Charles Wheatstone and William Fothergill Cooke patented a five-needle, six-wire system, which entered commercial use in 1838.[11] It used the deflection of needles to represent messages and started operating over twenty-one kilometres (thirteen miles) of the Great Western Railway on 9 April 1839. Both Wheatstone and Cooke viewed their device as "an improvement to the [existing] electromagnetic telegraph" not as a new device.

On the other side of the Atlantic Ocean, Samuel Morse developed a version of the electrical telegraph which he demonstrated on 2 September 1837. Alfred Vail saw this demonstration and joined Morse to develop the register—a telegraph terminal that integrated a logging device for recording messages to paper tape. This was demonstrated successfully over three miles (five kilometres) on 6 January 1838 and eventually over forty miles (sixty-four kilometres) between Washington, D.C. and Baltimore on 24 May 1844. The patented invention proved lucrative and by 1851 telegraph lines in the United States spanned over 20,000 miles (32,000 kilometres).[12] Morse's most important technical contribution to this telegraph was the simple and highly efficient Morse Code, co-developed with Vail, which was an important advance over Wheatstone's more complicated and expensive system, and required just two wires. The communications efficiency of the Morse Code preceded that of the Huffman code in digital communications by over 100 years, but Morse and Vail developed the code purely empirically, with shorter codes for more frequent letters.

The submarine cable across the English Channel, wire coated in gutta percha, was laid in 1851.[13] Transatlantic cables installed in 1857 and 1858 only operated for a few days or weeks (carried messages of greeting back and forth between James Buchanan and Queen Victoria) before they failed.[14] The project to lay a replacement line was delayed for five years by the American Civil War. The first successful transatlantic telegraph cable was completed on 27 July 1866, allowing continuous transatlantic telecommunication for the first time.

Telephone

The master telephone patent, 174465, granted to Bell, March 7, 1876

The electric telephone was invented in the 1870s, based on earlier work with harmonic (multi-signal) telegraphs. The first commercial telephone services were set up in 1878 and 1879 on both sides of the Atlantic in the cities of New Haven, Connecticut in the US and London, England in the UK. Alexander Graham Bell held the master patent for the telephone that was needed for such services in both countries.[15] All other patents for electric telephone devices and features flowed from this master patent. Credit for the invention of the electric telephone has been frequently disputed, and new controversies over the issue have arisen from time-to-time. As with other great inventions such as radio, television, the light bulb, and the digital computer, there were several inventors who did pioneering experimental work on voice transmission over a wire, who then improved on each other's ideas. However, the key innovators were Alexander Graham Bell and Gardiner Greene Hubbard, who created the first telephone company, the Bell Telephone Company in the United States, which later evolved into American Telephone & Telegraph (AT&T), at times the world's largest phone company.

Telephone technology grew quickly after the first commercial services emerged, with inter-city lines being built and telephone exchanges in every major city of the United States by the mid-1880s.[16][17][18] The first transcontinental telephone call occurred on January 25, 1915. Despite this, transatlantic voice communication remained impossible for customers until January 7, 1927 when a connection was established using radio.[19] However no cable connection existed until TAT-1 was inaugurated on September 25, 1956 providing 36 telephone circuits.[20]

In 1880, Bell and co-inventor Charles Sumner Tainter conducted the world's first wireless telephone call via modulated lightbeams projected by photophones. The scientific principles of their invention would not be utilized for several decades, when they were first deployed in military and fiber-optic communications.

The first transatlantic telephone cable (which incorporated hundreds of electronic amplifiers) was not operational until 1956, only six years before the first commercial telecommunications satellite, Telstar, was launched into space.[21]

Radio and television

Over several years starting in 1894, the Italian inventor Guglielmo Marconi worked on adapting the newly discovered phenomenon of radio waves to telecommunication, building the first wireless telegraphy system using them.[22] In December 1901, he established wireless communication between St. John's, Newfoundland and Poldhu, Cornwall (England), earning him a Nobel Prize in Physics (which he shared with Karl Braun) in 1909.[23] In 1900, Reginald Fessenden was able to wirelessly transmit a human voice.

Millimetre wave communication was first investigated by Bengali physicist Jagadish Chandra Bose during 18941896, when he reached an extremely high frequency of up to 60 GHz in his experiments.[24] He also introduced the use of semiconductor junctions to detect radio waves,[25] when he patented the radio crystal detector in 1901.[26][27]

In 1924, Japanese engineer Kenjiro Takayanagi began a research program on electronic television. In 1925, he demonstrated a CRT television with thermal electron emission.[28] In 1926, he demonstrated a CRT television with 40-line resolution,[29] the first working example of a fully electronic television receiver.[28] In 1927, he increased the television resolution to 100 lines, which was unrivaled until 1931.[30] In 1928, he was the first to transmit human faces in half-tones on television, influencing the later work of Vladimir K. Zworykin.[31]

On March 25, 1925, Scottish inventor John Logie Baird publicly demonstrated the transmission of moving silhouette pictures at the London department store Selfridge's. Baird's system relied upon the fast-rotating Nipkow disk, and thus it became known as the mechanical television. In October 1925, Baird was successful in obtaining moving pictures with halftone shades, which were by most accounts the first true television pictures.[32] This led to a public demonstration of the improved device on 26 January 1926 again at Selfridges. His invention formed the basis of semi-experimental broadcasts done by the British Broadcasting Corporation beginning September 30, 1929.[33]

For most of the twentieth century televisions used the cathode ray tube (CRT) invented by Karl Braun. Such a television was produced by Philo Farnsworth, who demonstrated crude silhouette images to his family in Idaho on September 7, 1927.[34] Farnsworth's device would compete with the concurrent work of Kalman Tihanyi and Vladimir Zworykin. Though the execution of the device was not yet what everyone hoped it could be, it earned Farnsworth a small production company. In 1934, he gave the first public demonstration of the television at Philadelphia's Franklin Institute and opened his own broadcasting station.[35] Zworykin's camera, based on Tihanyi's Radioskop, which later would be known as the Iconoscope, had the backing of the influential Radio Corporation of America (RCA). In the United States, court action between Farnsworth and RCA would resolve in Farnsworth's favour.[36] John Logie Baird switched from mechanical television and became a pioneer of colour television using cathode-ray tubes.[32]

After mid-century the spread of coaxial cable and microwave radio relay allowed television networks to spread across even large countries.

Semiconductor era

The modern period of telecommunication history from 1950 onwards is referred to as the semiconductor era, due to the wide adoption of semiconductor devices in telecommunication technology. The development of transistor technology and the semiconductor industry enabled significant advances in telecommunication technology, led to the price of telecommunications services declining significantly, and led to a transition away from state-owned narrowband circuit-switched networks to private broadband packet-switched networks. In turn, this led to a significant increase in the total number of telephone subscribers, reaching nearly 1 billion users worldwide by the end of the 20th century.[37]

The development of metal–oxide–semiconductor (MOS) large-scale integration (LSI) technology, information theory and cellular networking led to the development of affordable mobile communications. There was a rapid growth of the telecommunications industry towards the end of the 20th century, primarily due to the introduction of digital signal processing in wireless communications, driven by the development of low-cost, very large-scale integration (VLSI) RF CMOS (radio-frequency complementary MOS) technology.[38]

Transistors

The development of transistor technology has been fundamental to modern electronic telecommunication.[39][40][41] Julius Edgar Lilienfeld proposed the concept of a field-effect transistor in 1926, but it was not possible to actually construct a working device at that time.[42] The first working transistor, a point-contact transistor, was invented by John Bardeen and Walter Houser Brattain while working under William Shockley at Bell Labs in 1947.[40]

The MOSFET (metal-oxide-silicon field-effect transistor), also known as the MOS transistor, was later invented by Mohamed Atalla and Dawon Kahng at Bell Labs in 1959.[43][44][45] It was the first truly compact transistor that could be miniaturised and mass-produced for a wide range of uses.[46] The MOSFET is the building block or "workhorse" of the information revolution and the information age,[47][48][49] and the most widely manufactured device in history.[50][51] MOS technology, including MOS integrated circuits and power MOSFETs, drives the communications infrastructure of modern telecommunication.[52][53][54] According to Edholm's law, the bandwidth of telecommunication networks has been doubling every 18 months.[55] Advances in MOS technology, including MOSFET scaling (increasing transistor counts at an exponential pace, as predicted by Moore's law), has been the most important contributing factor in the rapid rise of bandwidth in telecommunications networks.[56]

By the early 1970s, MOSFETs were used in a wide range of telecommunications equipment, such as crosspoint switches, mail sorter machines, mobile radio, modems, multimeters, multiplexers, push-button signal receivers, teleprinters, display devices such as television receivers, and telephone sets such as payphones and push-button telephones.[57] By the 1990s, CMOS (complementary MOS) VLSI (very large-scale integration) technology was widely used in electronic switching systems for telephone exchanges, private branch exchanges (PBX) and key telephone systems (KTS); digital transmission applications such as digital loop carriers, pair gain multiplexers, telephone loop extenders, integrated services digital network (ISDN) terminals, cordless telephones and cell phones; and applications such as speech recognition equipment, voice data storage, voice mail and digital tapeless answering machines.[58] By the early 21st century, MOSFETs were used in all microprocessors, memory chips, and telecommunication circuits,[59] as well as most essential elements of wireless telecommunications, such as mobile devices, transceivers, base station modules, routers and RF power amplifiers.[60]

Videotelephony

The 1969 AT&T Mod II Picturephone, the result of decades long R&D at a cost of over $500M.

The development of videotelephony involved the historical development of several technologies which enabled the use of live video in addition to voice telecommunications. The concept of videotelephony was first popularized in the late 1870s in both the United States and Europe, although the basic sciences to permit its very earliest trials would take nearly a half century to be discovered. This was first embodied in the device which came to be known as the video telephone, or videophone, and it evolved from intensive research and experimentation in several telecommunication fields, notably electrical telegraphy, telephony, radio, and television.

The development of the crucial video technology first started in the latter half of the 1920s in the United Kingdom and the United States, spurred notably by John Logie Baird and AT&T's Bell Labs. This occurred in part, at least by AT&T, to serve as an adjunct supplementing the use of the telephone. A number of organizations believed that videotelephony would be superior to plain voice communications. However video technology was to be deployed in analog television broadcasting long before it could become practical—or popular—for videophones.

Videotelephony developed in parallel with conventional voice telephone systems from the mid-to-late 20th century. Only in the late 20th century with the advent of powerful video codecs and high-speed broadband did it become a practical technology for regular use. With the rapid improvements and popularity of the Internet, it became widespread through the use of videoconferencing and webcams, which frequently utilize Internet telephony, and in business, where telepresence technology has helped reduce the need to travel.

Practical digital videotelephony was only made possible with advances in video compression, due to the impractically high bandwidth requirements of uncompressed video. To achieve Video Graphics Array (VGA) quality video (480p resolution and 256 colors) with raw uncompressed video, it would require a bandwidth of over 92 Mbps.[61] The most important compression technique that enabled practical digital videotelephony and videoconferencing is the discrete cosine transform (DCT).[61][62] The DCT, a form of lossy compression, was first proposed by Nasir Ahmed in 1972.[63] The DCT algorithm became the basis for the first practical video coding standard that was useful for videoconferencing, H.261, standardised by the ITU-T in 1988.[62]

Satellite

The first U.S. satellite to relay communications was Project SCORE in 1958, which used a tape recorder to store and forward voice messages. It was used to send a Christmas greeting to the world from U.S. President Dwight D. Eisenhower. In 1960 NASA launched an Echo satellite; the 100-foot (30 m) aluminized PET film balloon served as a passive reflector for radio communications. Courier 1B, built by Philco, also launched in 1960, was the world's first active repeater satellite. Satellites these days are used for many applications such as GPS, television, internet and telephone.

Telstar was the first active, direct relay commercial communications satellite. Belonging to AT&T as part of a multi-national agreement between AT&T, Bell Telephone Laboratories, NASA, the British General Post Office, and the French National PTT (Post Office) to develop satellite communications, it was launched by NASA from Cape Canaveral on July 10, 1962, the first privately sponsored space launch. Relay 1 was launched on December 13, 1962, and became the first satellite to broadcast across the Pacific on November 22, 1963.[64]

The first and historically most important application for communication satellites was in intercontinental long distance telephony. The fixed Public Switched Telephone Network relays telephone calls from land line telephones to an earth station, where they are then transmitted a receiving satellite dish via a geostationary satellite in Earth orbit. Improvements in submarine communications cables, through the use of fiber-optics, caused some decline in the use of satellites for fixed telephony in the late 20th century, but they still exclusively service remote islands such as Ascension Island, Saint Helena, Diego Garcia, and Easter Island, where no submarine cables are in service. There are also some continents and some regions of countries where landline telecommunications are rare to nonexistent, for example Antarctica, plus large regions of Australia, South America, Africa, Northern Canada, China, Russia and Greenland.

After commercial long distance telephone service was established via communication satellites, a host of other commercial telecommunications were also adapted to similar satellites starting in 1979, including mobile satellite phones, satellite radio, satellite television and satellite Internet access. The earliest adaption for most such services occurred in the 1990s as the pricing for commercial satellite transponder channels continued to drop significantly.

Realization and demonstration, on October 29, 2001, of the first digital cinema transmission by satellite in Europe[65][66][67] of a feature film by Bernard Pauchon[68], Alain Lorentz, Raymond Melwig[69] and Philippe Binant.[70]

Computer networks and the Internet

On September 11, 1940, George Stibitz was able to transmit problems using teletype to his Complex Number Calculator in New York City and receive the computed results back at Dartmouth College in New Hampshire.[71] This configuration of a centralized computer or mainframe with remote dumb terminals remained popular throughout the 1950s. However it was not until the 1960s that researchers started to investigate packet switching a technology that would allow chunks of data to be sent to different computers without first passing through a centralized mainframe. A four-node network emerged on December 5, 1969 between the University of California, Los Angeles, the Stanford Research Institute, the University of Utah and the University of California, Santa Barbara. This network would become ARPANET, which by 1981 would consist of 213 nodes.[72] In June 1973, the first non-US node was added to the network belonging to Norway's NORSAR project. This was shortly followed by a node in London.[73]

ARPANET's development centred on the Request for Comment process and on April 7, 1969, RFC 1 was published. This process is important because ARPANET would eventually merge with other networks to form the Internet and many of the protocols the Internet relies upon today were specified through this process. The first Transmission Control Protocol (TCP) specification, RFC 675 (Specification of Internet Transmission Control Program), was written by Vinton Cerf, Yogen Dalal, and Carl Sunshine, and published in December 1974. It coined the term "Internet" as a shorthand for internetworking.[74] In September 1981, RFC 791 introduced the Internet Protocol v4 (IPv4). This established the TCP/IP protocol, which much of the Internet relies upon today. The User Datagram Protocol (UDP), a more relaxed transport protocol that, unlike TCP, did not guarantee the orderly delivery of packets, was submitted on 28 August 1980 as RFC 768. An e-mail protocol, SMTP, was introduced in August 1982 by RFC 821 and http://1.0%5B%5D a protocol that would make the hyperlinked Internet possible was introduced in May 1996 by RFC 1945.

However, not all important developments were made through the Request for Comment process. Two popular link protocols for local area networks (LANs) also appeared in the 1970s. A patent for the Token Ring protocol was filed by Olof Söderblom on October 29, 1974.[75] And a paper on the Ethernet protocol was published by Robert Metcalfe and David Boggs in the July 1976 issue of Communications of the ACM.[76] The Ethernet protocol had been inspired by the ALOHAnet protocol which had been developed by electrical engineering researchers at the University of Hawaii.

Internet access became widespread late in the century, using the old telephone and television networks.

Digital telephone technology

The rapid development and wide adoption of pulse-code modulation (PCM) digital telephony was enabled by metal–oxide–semiconductor (MOS) technology.[77] MOS technology was initially overlooked by Bell because they did not find it practical for analog telephone applications.[78][77] MOS technology eventually became practical for telephone applications with the MOS mixed-signal integrated circuit, which combines analog and digital signal processing on a single chip, developed by former Bell engineer David A. Hodges with Paul R. Gray at UC Berkeley in the early 1970s.[77] In 1974, Hodges and Gray worked with R.E. Suarez to develop MOS switched capacitor (SC) circuit technology, which they used to develop the digital-to-analog converter (DAC) chip, using MOSFETs and MOS capacitors for data conversion. This was followed by the analog-to-digital converter (ADC) chip, developed by Gray and J. McCreary in 1975.[77]

MOS SC circuits led to the development of PCM codec-filter chips in the late 1970s.[77][58] The silicon-gate CMOS (complementary MOS) PCM codec-filter chip, developed by Hodges and W.C. Black in 1980,[77] has since been the industry standard for digital telephony.[77][58] By the 1990s, telecommunication networks such as the public switched telephone network (PSTN) had been largely digitized with very-large-scale integration (VLSI) CMOS PCM codec-filters, widely used in electronic switching systems for telephone exchanges and data transmission applications.[58]

Digital media

Practical digital media distribution and streaming was made possible by advances in data compression, due to the impractically high memory, storage and bandwidth requirements of uncompressed media.[79] The most important compression technique is the discrete cosine transform (DCT),[80] a lossy compression algorithm that was first proposed as an image compression technique by Nasir Ahmed at the University of Texas in 1972.[63] The DCT algorithm was the basis for the first practical video coding format, H.261, in 1988.[81] It was followed by more DCT-based video coding standards, most notably the MPEG video formats from 1991 onwards.[80] The JPEG image format, also based on the DCT algorithm, was introduced in 1992.[82] The development of the modified discrete cosine transform (MDCT) algorithm led to the MP3 audio coding format in 1994,[83] and the Advanced Audio Coding (AAC) format in 1999.[84]

Realization and demonstration, on 29 October 2001, of the first digital cinema transmission by satellite in Europe[85][86][87] of a feature film by Bernard Pauchon,[88] Alain Lorentz, Raymond Melwig[89] and Philippe Binant.[90]

Wireless revolution

The wireless revolution began in the 1990s,[91][92][93] with the advent of digital wireless networks leading to a social revolution, and a paradigm shift from wired to wireless technology,[94] including the proliferation of commercial wireless technologies such as cell phones, mobile telephony, pagers, wireless computer networks,[91] cellular networks, the wireless Internet, and laptop and handheld computers with wireless connections.[95] The wireless revolution has been driven by advances in radio frequency (RF) and microwave engineering,[91] and the transition from analog to digital RF technology.[94][95]

Advances in metal–oxide–semiconductor field-effect transistor (MOSFET, or MOS transistor) technology, the key component of the RF technology that enables digital wireless networks, has been central to this revolution.[94] The invention of the MOSFET by Mohamed Atalla and Dawon Kahng at Bell Labs in 1959 led to the development of power MOSFET technology.[96] Hitachi developed the vertical power MOSFET in 1969,[97] and then the lateral-diffused metal-oxide semiconductor (LDMOS) in 1977.[98] RF CMOS (radio frequency CMOS) integrated circuit technology was later developed by Asad Abidi at UCLA in the late 1980s.[99] By the 1990s, RF CMOS integrated circuits were widely adopted as RF circuits,[99] while discrete MOSFET (power MOSFET and LDMOS) devices were widely adopted as RF power amplifiers, which led to the development and proliferation of digital wireless networks.[94][60] Most of the essential elements of modern wireless networks are built from MOSFETs, including base station modules, routers,[60] telecommunication circuits,[100] and radio transceivers.[99] MOSFET scaling has led to rapidly increasing wireless bandwidth, which has been doubling every 18 months (as noted by Edholm's law).[94]

Timeline

Visual, auditory and ancillary methods (non-electrical)

Basic electrical signals

Advanced electrical and electronic signals

See also

References

  1. Native American Smoke Signals, William Tomkins, 2005.
  2. Talking Drums Archived 2006-09-10 at the Wayback Machine, Instrument Encyclopedia, Cultural Heritage for Community Outreach, 1996.
  3. Levi, Wendell (1977). The Pigeon. Sumter, S.C.: Levi Publishing Co, Inc. ISBN 0853900132.
  4. Lahanas, Michael, Ancient Greek Communication Methods Archived 2014-11-02 at the Wayback Machine, Mlahanas.de website. Retrieved 14 July 2009.
  5. David Ross, The Spanish Armada, Britain Express, October 2008.
  6. Wenzlhuemer, Connecting the Nineteenth-Century World (2013), pp. 63–64.
  7. Les Télégraphes Chappe Archived 2011-03-17 at the Wayback Machine, Cédrick Chatenet, l'Ecole Centrale de Lyon, 2003.
  8. CCIT/ITU-T 50 Years of Excellence, International Telecommunication Union, 2006.
  9. Jones, R. Victor Samuel Thomas von Sömmerring's "Space Multiplexed" Electrochemical Telegraph (1808-10), Harvard University website. Attributed to "Semaphore to Satellite" , International Telecommunication Union, Geneva 1965. Retrieved 2009-05-01
  10. Ronalds, B.F. (2016). Sir Francis Ronalds: Father of the Electric Telegraph. London: Imperial College Press. ISBN 978-1-78326-917-4.
  11. The hindot Electromagnetic Telegraph Archived 2007-08-04 at the Wayback Machine, J. B. Calvert, 19 May 2004.
  12. The Electromagnetic Telegraph Archived 2007-08-04 at the Wayback Machine, J. B. Calvert, April 2000.
  13. Wenzlhuemer, Connecting the Nineteenth-Century World (2013), pp. 74.
  14. The Atlantic Cable, Bern Dibner, Burndy Library Inc., 1959
  15. Brown, Travis (1994). Historical first patents: the first United States patent for many everyday things (illustrated ed.). University of Michigan: Scarecrow Press. pp. 179. ISBN 978-0-8108-2898-8.
  16. Connected Earth: The telephone, BT, 2006.
  17. History of AT&T, AT&T, 2006.
  18. Page, Arthur W. (January 1906). "Communication By Wire And 'Wireless': The Wonders of Telegraph and Telephone". The World's Work: A History of Our Time. XIII: 8408–8422. Retrieved 2009-07-10.
  19. Editors, History com, First Transatlantic Telephone Call, retrieved 2019-03-22CS1 maint: extra text: authors list (link)
  20. History of the Atlantic Cable & Submarine Telegraphy, Bill Glover, 2006.
  21. Arthur C. Clarke. Voice Across the Sea, Harper & Brothers, New York City, 1958.
  22. Icons of invention: the makers of the modern world from Gutenberg to Gates. ABC-CLIO. 2009. ISBN 9780313347436. Retrieved August 11, 2011.
  23. Tesla Biography, Ljubo Vujovic, Tesla Memorial Society of New York, 1998.
  24. "Milestones: First Millimeter-wave Communication Experiments by J.C. Bose, 1894-96". List of IEEE milestones. Institute of Electrical and Electronics Engineers. Retrieved 1 October 2019.
  25. Emerson, D. T. (1997). "The work of Jagadis Chandra Bose: 100 years of MM-wave research". IEEE Transactions on Microwave Theory and Research. 45 (12): 2267–2273. Bibcode:1997imsd.conf..553E. doi:10.1109/MWSYM.1997.602853. ISBN 9780986488511. reprinted in Igor Grigorov, Ed., Antentop, Vol. 2, No.3, pp. 87–96.
  26. "Timeline". The Silicon Engine. Computer History Museum. Retrieved 22 August 2019.
  27. "1901: Semiconductor Rectifiers Patented as "Cat's Whisker" Detectors". The Silicon Engine. Computer History Museum. Retrieved 23 August 2019.
  28. "Milestones:Development of Electronic Television, 1924-1941". Retrieved December 11, 2015.
  29. Kenjiro Takayanagi: The Father of Japanese Television, NHK (Japan Broadcasting Corporation), 2002, retrieved 2009-05-23.
  30. High Above: The untold story of Astra, Europe's leading satellite company, page 220, Springer Science+Business Media
  31. Albert Abramson, Zworykin, Pioneer of Television, University of Illinois Press, 1995, p. 231. ISBN 0-252-02104-5.
  32. The Baird Television Website
  33. The Pioneers Archived 2013-05-14 at the Wayback Machine, MZTV Museum of Television, 2006.
  34. Philo Farnsworth, Neil Postman, TIME Magazine, 29 March 1999.
  35. Karwatka, D. (1996). Philo Farnsworth--television pioneer. Tech Directions, 56(4), 7.
  36. Philo Farnsworth, Neil Postman, TIME Magazine, 29 March 1999
  37. Huurdeman, Anton A. (2003). The Worldwide History of Telecommunications. John Wiley & Sons. pp. 363–8. ISBN 9780471205050.
  38. Srivastava, Viranjay M.; Singh, Ghanshyam (2013). MOSFET Technologies for Double-Pole Four-Throw Radio-Frequency Switch. Springer Science & Business Media. p. 1. ISBN 9783319011653.
  39. Jakubowski, A.; Łukasiak, L. (2010). "History of Semiconductors". Journal of Telecommunications and Information Technology. nr 1: 3–9.
  40. Lambert, Laura; Poole, Hilary W.; Woodford, Chris; Moschovitis, Christos J. P. (2005). The Internet: A Historical Encyclopedia. ABC-CLIO. p. 16. ISBN 9781851096596.
  41. Gaudin, Sharon (12 December 2007). "The transistor: The most important invention of the 20th century?". Computerworld. Retrieved 10 August 2019.
  42. "1926 – Field Effect Semiconductor Device Concepts Patented". Computer History Museum. Archived from the original on March 22, 2016. Retrieved March 25, 2016.
  43. "1960 - Metal Oxide Semiconductor (MOS) Transistor Demonstrated". The Silicon Engine. Computer History Museum.
  44. Lojek, Bo (2007). History of Semiconductor Engineering. Springer Science & Business Media. pp. 321–3. ISBN 9783540342588.
  45. "Who Invented the Transistor?". Computer History Museum. 4 December 2013. Retrieved 20 July 2019.
  46. Moskowitz, Sanford L. (2016). Advanced Materials Innovation: Managing Global Technology in the 21st century. John Wiley & Sons. pp. 165–167. ISBN 9780470508923.
  47. "Triumph of the MOS Transistor". YouTube. Computer History Museum. 6 August 2010. Retrieved 21 July 2019.
  48. Raymer, Michael G. (2009). The Silicon Web: Physics for the Internet Age. CRC Press. p. 365. ISBN 9781439803127.
  49. "Transistors - an overview". ScienceDirect. Retrieved 8 August 2019.
  50. "13 Sextillion & Counting: The Long & Winding Road to the Most Frequently Manufactured Human Artifact in History". Computer History Museum. April 2, 2018. Retrieved 28 July 2019.
  51. Baker, R. Jacob (2011). CMOS: Circuit Design, Layout, and Simulation. John Wiley & Sons. p. 7. ISBN 978-1118038239.
  52. Fossum, Jerry G.; Trivedi, Vishal P. (2013). Fundamentals of Ultra-Thin-Body MOSFETs and FinFETs. Cambridge University Press. p. vii. ISBN 9781107434493.
  53. Omura, Yasuhisa; Mallik, Abhijit; Matsuo, Naoto (2017). MOS Devices for Low-Voltage and Low-Energy Applications. John Wiley & Sons. p. 53. ISBN 9781119107354.
  54. Whiteley, Carol; McLaughlin, John Robert (2002). Technology, Entrepreneurs, and Silicon Valley. Institute for the History of Technology. ISBN 9780964921719. These active electronic components, or power semiconductor products, from Siliconix are used to switch and convert power in a wide range of systems, from portable information appliances to the communications infrastructure that enable the Internet. The company's power MOSFETs — tiny solid-state switches, or metal oxide semiconductor field-effect transistors — and power integrated circuits are widely used in cell phones and notebook computers to manage battery power efficiently
  55. Cherry, Steven (2004). "Edholm's law of bandwidth". IEEE Spectrum. 41 (7): 58–60. doi:10.1109/MSPEC.2004.1309810.
  56. Jindal, R. P. (2009). "From millibits to terabits per second and beyond - Over 60 years of innovation". 2009 2nd International Workshop on Electron Devices and Semiconductor Technology: 1–6. doi:10.1109/EDST.2009.5166093. ISBN 978-1-4244-3831-0.
  57. Zeidler, G.; Becker, D. (1974). "MOS LSI Custom Circuits Offer New Prospects for Communications Equipment Design". Electrical Communication. Western Electric Company. 49-50: 88–92. In many fields of communications equipment design, MOS LSI custom built circuits provide the only practical and economic solution. Important examples include the coin telephone NT 2000, the QUICKSTEP* push button set, and a push button signal receiver. (...) A complete list of all applications is beyond the scope of this paper since new MOS developments are constantly being initiated in the various technical areas. Typical examples of completed and present MOS developments are:
    — crosspoints
    — multiplexers
    — modems
    — mobile radios
    — push button signal receivers
    — mail sorting machines
    — multimeters
    — telephone sets
    — coin telephones
    — teleprinters
    — screen displays
    — television receivers.
  58. Floyd, Michael D.; Hillman, Garth D. (8 October 2018) [1st pub. 2000]. "Pulse-Code Modulation Codec-Filters". The Communications Handbook (2nd ed.). CRC Press. pp. 26–1, 26–2, 26–3. ISBN 9781420041163.
  59. Colinge, Jean-Pierre; Greer, James C. (2016). Nanowire Transistors: Physics of Devices and Materials in One Dimension. Cambridge University Press. p. 2. ISBN 9781107052406.
  60. Asif, Saad (2018). 5G Mobile Communications: Concepts and Technologies. CRC Press. pp. 128–134. ISBN 9780429881343.
  61. Belmudez, Benjamin (2014). Audiovisual Quality Assessment and Prediction for Videotelephony. Springer. pp. 11–13. ISBN 9783319141664.
  62. Huang, Hsiang-Cheh; Fang, Wai-Chi (2007). Intelligent Multimedia Data Hiding: New Directions. Springer. p. 41. ISBN 9783540711698.
  63. Ahmed, Nasir (January 1991). "How I Came Up With the Discrete Cosine Transform". Digital Signal Processing. 1 (1): 4–5. doi:10.1016/1051-2004(91)90086-Z.
  64. "Significant Achievements in Space Communications and Navigation, 1958-1964" (PDF). NASA-SP-93. NASA. 1966. pp. 30–32. Retrieved 2009-10-31.
  65. France Télécom, Commission Supérieure Technique de l'Image et du Son, Communiqué de presse, Paris, October 29th, 2001.
  66. «Numérique : le cinéma en mutation», Projections, 13, CNC, Paris, September 2004, p. 7.
  67. Olivier Bomsel, Gilles Le Blanc, Dernier tango argentique. Le cinéma face à la numérisation, Ecole des Mines de Paris, 2002, p. 12.
  68. Bernard Pauchon, France Telecom and digital cinema, ShowEast, 2001, p. 10.
  69. Alexandru Georgescu (et al.), Critical Space Infrastructures. Risk, Resilience and Complexity, Springer, 2019, p. 48.
  70. Première numérique pour le cinéma français, 01net, 2002.
  71. George Stibitz, Kerry Redshaw, 1996.
  72. Hafner, Katie (1998). Where Wizards Stay Up Late: The Origins Of The Internet. Simon & Schuster. ISBN 0-684-83267-4.
  73. NORSAR and the Internet: Together since 1973 Archived 2005-09-10 at the Wayback Machine, NORSAR, 2006.
  74. Cerf, Vinton; Dalal, Yogen; Sunshine, Carl (December 1974), RFC 675, Specification of Internet Transmission Control Protocol
  75. Data transmission system, Olof Soderblom, PN 4,293,948, October 1974.
  76. Ethernet: Distributed Packet Switching for Local Computer Networks Archived 2007-08-07 at the Wayback Machine, Robert M. Metcalfe and David R. Boggs, Communications of the ACM (pp. 395-404, Vol. 19, No. 5), July 1976.
  77. Allstot, David J. (2016). "Switched Capacitor Filters" (PDF). In Maloberti, Franco; Davies, Anthony C. (eds.). A Short History of Circuits and Systems: From Green, Mobile, Pervasive Networking to Big Data Computing. IEEE Circuits and Systems Society. pp. 105–110. ISBN 9788793609860.
  78. Maloberti, Franco; Davies, Anthony C. (2016). "History of Electronic Devices" (PDF). A Short History of Circuits and Systems: From Green, Mobile, Pervasive Networking to Big Data Computing. IEEE Circuits and Systems Society. pp. 59-70 (65-7). ISBN 9788793609860.
  79. Lee, Jack (2005). Scalable Continuous Media Streaming Systems: Architecture, Design, Analysis and Implementation. John Wiley & Sons. p. 25. ISBN 9780470857649.
  80. Ce, Zhu (2010). Streaming Media Architectures, Techniques, and Applications: Recent Advances: Recent Advances. IGI Global. p. 26. ISBN 9781616928339.
  81. Ghanbari, Mohammed (2003). Standard Codecs: Image Compression to Advanced Video Coding. Institution of Engineering and Technology. pp. 1–2. ISBN 9780852967102.
  82. "T.81 – DIGITAL COMPRESSION AND CODING OF CONTINUOUS-TONE STILL IMAGES – REQUIREMENTS AND GUIDELINES" (PDF). CCITT. September 1992. Retrieved 12 July 2019.
  83. Guckert, John (Spring 2012). "The Use of FFT and MDCT in MP3 Audio Compression" (PDF). University of Utah. Retrieved 14 July 2019.
  84. Brandenburg, Karlheinz (1999). "MP3 and AAC Explained" (PDF). Archived (PDF) from the original on 2017-02-13. Retrieved 2019-10-17.
  85. France Télécom, Commission Supérieure Technique de l'Image et du Son, Communiqué de presse, Paris, 29 October 2001.
  86. «Numérique : le cinéma en mutation», Projections, 13, CNC, Paris, September 2004, p. 7.
  87. Olivier Bomsel, Gilles Le Blanc, Dernier tango argentique. Le cinéma face à la numérisation, Ecole des Mines de Paris, 2002, p. 12.
  88. Bernard Pauchon, France Telecom and digital cinema, ShowEast, 2001, p. 10.
  89. Alexandru Georgescu (et al.), Critical Space Infrastructures. Risk, Resilience and Complexity, Springer, 2019, p. 48.
  90. Première numérique pour le cinéma français, 01net, 2002.
  91. Golio, Mike; Golio, Janet (2018). RF and Microwave Passive and Active Technologies. CRC Press. pp. ix, I–1. ISBN 9781420006728.
  92. Rappaport, T. S. (November 1991). "The wireless revolution". IEEE Communications Magazine. 29 (11): 52–71. doi:10.1109/35.109666.
  93. "The wireless revolution". The Economist. January 21, 1999. Retrieved 12 September 2019.
  94. Baliga, B. Jayant (2005). Silicon RF Power MOSFETS. World Scientific. ISBN 9789812561213.
  95. Harvey, Fiona (May 8, 2003). "The Wireless Revolution". Encyclopedia Britannica. Retrieved 12 September 2019.
  96. "Rethink Power Density with GaN". Electronic Design. 21 April 2017. Retrieved 23 July 2019.
  97. Oxner, E. S. (1988). Fet Technology and Application. CRC Press. p. 18. ISBN 9780824780500.
  98. Duncan, Ben (1996). High Performance Audio Power Amplifiers. Elsevier. pp. 177–8, 406. ISBN 9780080508047.
  99. O'Neill, A. (2008). "Asad Abidi Recognized for Work in RF-CMOS". IEEE Solid-State Circuits Society Newsletter. 13 (1): 57–58. doi:10.1109/N-SSC.2008.4785694. ISSN 1098-4232.
  100. Colinge, Jean-Pierre; Greer, James C. (2016). Nanowire Transistors: Physics of Devices and Materials in One Dimension. Cambridge University Press. p. 2. ISBN 9781107052406.

Sources

  • Wenzlhuemer, Roland. Connecting the Nineteenth-Century World: The Telegraph and Globalization. Cambridge University Press, 2013. ISBN 9781107025288

Further reading

  • Hilmes, Michele. Network Nations: A Transnational History of American and British Broadcasting (2011)
  • John, Richard. Network Nation: Inventing American Telecommunications (Harvard U.P. 2010), emphasis on telephone
  • Noll, Michael. The Evolution of Media, 2007, Rowman & Littlefield
  • Poe, Marshall T. A History of Communications: Media and Society From the Evolution of Speech to the Internet (Cambridge University Press; 2011) 352 pages; Documents how successive forms of communication are embraced and, in turn, foment change in social institutions.
  • Wheen, Andrew. DOT-DASH TO DOT.COM: How Modern Telecommunications Evolved from the Telegraph to the Internet (Springer, 2011)
  • Wu, Tim. The Master Switch: The Rise and Fall of Information Empires (2010)
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.