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A Teletype Model 32 used for telex service

Telex is a telecommunication system that allows text-based messages to be sent and received by teleprinter over telephone lines. The term "telex" may refer to the service, the network, the devices, or a message sent using these.[1] Telex emerged in the 1930s and became a major method of sending text messages electronically between businesses in the post–World War II period. Its usage declined as the fax machine grew in popularity in the 1980s.

Technology

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The technology operates on switched station-to-station basis with teleprinter devices at the receiving and sending locations.[2] It operates over the circuits of the public switched telephone network or by private lines. Point-to-point teleprinter systems had been in use long before telex exchanges were built in the 1930s. Teleprinters evolved from telegraph systems, and, like the telegraph, use binary signals, with mark and space logic represented by the presence or absence of a certain level of electric current. This differs from the analog telephone system, which used varying voltage to represent sound. For this reason, telex exchanges were entirely separate from the telephone system, with their own signalling standards, exchanges and system of telex numbers (the counterpart of telephone numbers).

Telex provided the first common medium for international record communications using standard signalling techniques and operating criteria as specified by the International Telecommunication Union. Customers on any telex exchange could deliver messages to any other, around the world. To reduce connecting line usage, telex messages were encoded onto paper tape and then read into the line as quickly as possible. The system normally delivered information at 50 baud or approximately 66 words per minute, encoded using the International Telegraph Alphabet No. 2. In the last days of the traditional telex networks, end-user equipment was often replaced by modems and phone lines, reducing the telex network to what was effectively a directory service running on the telephone network.

Development

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A late-model British Telecom "Puma" telex machine of the 1980s

Telex began in Germany as a research and development program in 1926 that became an operational teleprinter service in 1933. The service, operated by the German Reichspost[3] had a speed of 50 baud, which is approximately 66 words per minute.

Soon after, telex services were developed by other nations. Telex spread within Europe and after 1945 around the world.[4]

By 1978, West Germany, including West Berlin, had 123,298 telex connections. Long before automatic telephony became available, most countries, even in central Africa and Asia, had at least a few high-frequency shortwave telex links. Often, government postal and telegraph services (PTTs) initiated these radio links. The most common radio standard, CCITT R.44 had error-corrected retransmitting time-division multiplexing of radio channels. Most impoverished PTTs operated their telex-on-radio (TOR) channels non-stop, to get the maximum value from them.

The cost of TOR equipment has continued to fall. Although the system initially required specialised equipment, as of 2016 many amateur radio operators operate TOR, also known as radioteletype (RTTY), with special software and inexpensive hardware to connect computer sound cards to short-wave radios.[5]

Modern cablegrams or telegrams actually operate over dedicated telex networks, using TOR whenever required.[citation needed]

Telex served as the forerunner of modern fax, email, and text messaging – both technically and stylistically. Abbreviated English (like "CU L8R" for "see you later") as used in texting originated with telex operators exchanging informal messages in real time[citation needed] – they became the first "texters" long before the introduction of mobile phones[citation needed]. Telex users could send the same message to several places around the world at the same time, like email today, using the Western Union InfoMaster Computer. This involved transmitting the message via paper tape to the InfoMaster Computer (dial code 6111) and specifying the destination addresses for the single text. In this way, a single message could be sent to multiple distant telex and TWX machines as well as delivering the same message to non-telex and non-TWX subscribers via Western Union Mailgram.

Operation and applications

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Telex messages are routed by addressing them to a telex address, e.g., "14910 ERIC S", where 14910 is the subscriber number, ERIC is an abbreviation for the subscriber's name (in this case Telefonaktiebolaget L.M. Ericsson in Sweden) and S is the country code or location code. Solutions also exist for the automatic routing of messages to different telex terminals within a subscriber organization, by using different terminal identities, e.g., "+T148". The country codes (formally, network identification codes) for the first countries to adopt telex are single letters, while other countries have two-letter codes.[6][7] Some specialty services and American cities have three-letter network or location codes (such as MAS for Inmarsat or LSA for Los Angeles), and a few towns have four-letter codes (such as ROVE for Rockville, Maryland).[8]

A major advantage of telex is that the receipt of the message by the recipient could be confirmed with a high degree of certainty by the "answerback", which is a transmission-control enquiry character. At the beginning of the message, the sender would transmit a WRU (Who are you?) code, and the recipient machine would automatically initiate a response which was usually encoded in a rotating drum with pegs, much like a music box. The position of the pegs sent an unambiguous identifying code to the sender, so the sender could verify connection to the correct recipient. The WRU code would also be sent at the end of the message, so a correct response would confirm that the connection had remained unbroken during the message transmission. This gave telex a major advantage over group 2 fax, which had no inherent error-checking capability.

The usual method of operation was that the message would be prepared off-line, using paper tape. All common telex machines incorporated a five-hole paper-tape punch and reader. Once the paper tape had been prepared, the message could be transmitted in minimum time. Telex billing was always by connected duration, so minimizing the connected time saved money. However, it was also possible to connect in "real-time", where the sender and the recipient could both type on the keyboard and these characters would be immediately printed on the distant machine.

Telex could also be used as a rudimentary but functional carrier of information from one IT system to another, in effect a primitive forerunner of electronic data interchange. The sending IT system would create an output (e.g., an inventory list) on paper tape using a mutually agreed format. The tape would be sent by telex and collected on a corresponding paper tape by the receiver and this tape could then be read into the receiving IT system.

One use of telex circuits, in use until the widescale adoption of X.400 and Internet email, was to facilitate a message handling system, allowing local email systems to exchange messages with other email and telex systems via a central routing operation, or switch. One of the largest such switches was operated by Royal Dutch Shell as recently as 1994, permitting the exchange of messages between a number of IBM Officevision, Digital Equipment Corporation ALL-IN-1 and Microsoft Mail systems. In addition to permitting email to be sent to telex, formal coding conventions adopted in the composition of telex messages enabled automatic routing of telexes to email recipients.

United States

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Teletypewriter Exchange Service

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The Teletypewriter Exchange Service (TWX) was developed by the American Telephone and Telegraph Company (AT&T) in the United States, commencing service on November 21, 1931.[9]

From 1942 to 1952, AT&T published progress with the system in the trade magazine TWX. It published articles that touched upon many aspects of the technology.

From inception to 1962, access to the service was provided by operator-assisted, manual switching. By 1962, the network had grown to 100 switchboard locations to handle the traffic, causing considerable delay in the speed of connections of up to 212 minutes on average.[9] On August 31, 1962, the service was integrated into the Direct Distance Dialing (DDD) network, which improved connection times to about thirty seconds.[9] For the new dial technology, each station was assigned a ten-digit telephone number from a reserved set of N10 area codes, designated as Service Access Codes (SAC). Area code 510 was assigned for the United States and Area Code 610 in Canada. Sixteen operating centers were established across the United States.

Later in the decade, the United States was subdivided into three service regions. and assigned codes from the remaining set of SACs (710, 810, and 910). SAC 710 covered the Northeast of the United States (New England, New York, New Jersey, Pennsylvania, Maryland, the District of Columbia, Virginia, and West Virginia). 810 was assigned from Michigan southward and east of the Mississippi River to Ohio, Indiana, and Kentucky, and the entire South and 910 served west of the Mississippi to the Southwest and West Coast.[10]

TWX lines were configured with a special Class of Service to prevent interconnections with voice services.

Western Union purchased the TWX system from AT&T in January 1969.[11] The TWX system and the use of the special US area codes continued until 1981, when Western Union completed the conversion to the Western Union Telex II system.

Canada moved its TWX-numbers, as well as Datalink services, to the non-geographic area code 600, effective October 1, 1993, in exchange for returning 610.[12]

The network originally transmitted at a speed of 45.45 baud, or approximately 60 words per minute, using five-bit Baudot code, often referred to as 3-row coding with 32 characters arranged in three key rows of the keyboard.[13][14]

In 1963, AT&T implemented a new coding technology for TWX, called 4-row (64 characters in four key rows) based on the new Teletype Model 33 teleprinter using a 110-baud modem and a subset of the seven-bit ASCII code without lower-case letters.[15] TWX was offered in both 3-row Baudot and 4-row ASCII versions up to the late 1970s.

The modem for the 4-row ASCII service was the Bell 101 dataset, developed by 1958 for military applications. It is the direct ancestor of the Bell 103 modem that launched computer time-sharing. The 101 was revolutionary because it allowed the Bell System to run TWX on its regular voice telephone lines.

The code and speed conversion between 3-row Baudot and 4-row ASCII TWX service was accomplished using a special Bell 10A/B board via a live operator. A TWX customer would place a call to the 10A/B board operator for Baudot–ASCII calls, ASCII–Baudot calls, and also TWX conference calls. The code and speed conversion was facilitated by a special service unit made by Western Electric. Multiple code and speed conversion units were placed at each operator position.

During the conversion to Telex II, the remaining 3-row Baudot customers were converted to the new service during the period 1979 to 1981.

In February 1969, AT&T installed the first electronic switching system (ESS) for TWX service. It was a version of the No. 1ESS switch, arranged for data features (1ESS-AFD) in the Long Lines Department of AT&T. It had a capacity of handling 1,250 4-row teletypewriters.[16] However, due to the purchase of TWX by Western Union, further installations were canceled.

Western Union's Telex II system was re-acquired by AT&T in 1990 in the purchase of the Western Union assets that became AT&T EasyLink Services.[17][18]

Western Union

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In 1958, Western Union started to build a telex network in the United States.[19] This telex network started as a satellite exchange located in New York City and expanded to a nationwide network. Western Union chose Siemens & Halske AG,[20] now Siemens AG, and ITT[21] to supply the exchange equipment, provisioned the exchange trunks via the Western Union national microwave system and leased the exchange to customer site facilities from the local telephone company. Teleprinter equipment was originally provided by Siemens & Halske AG[22] and later by Teletype Corporation.[23] Initial direct international telex service was offered by Western Union, via W.U. International, in the summer of 1960 with limited service to London and Paris.[24] In 1962, the major exchanges were located in New York City (1), Chicago (2), San Francisco (3), Kansas City (4) and Atlanta (5).[25] The telex network expanded by adding the final parent exchange cities of Los Angeles (6), Dallas (7), Philadelphia (8) and Boston (9), starting in 1966.

The telex numbering plan, usually a six-digit number in the United States, was based on the major exchange where the customer's telex machine terminated.[26] For example, all telex customers that terminated in the New York City exchange were assigned a telex number that started with a first digit "1". Further, all Chicago-based customers had telex numbers that started with a first digit of "2". This numbering plan was maintained by Western Union as the telex exchanges proliferated to smaller cities in the United States. The Western Union Telex network was built on three levels of exchanges.[27] The highest level was made up of the nine exchange cities previously mentioned. Each of these cities had the dual capability of terminating telex customer lines and setting up trunk connections to multiple distant telex exchanges. The second level of exchanges, located in large cities such as Buffalo, Cleveland, Miami, Newark, Pittsburgh and Seattle, were similar to the highest level of exchanges in capability of terminating telex customer lines and setting up trunk connections. However, these second level exchanges had a smaller customer line capacity and only had trunk circuits connected to regional cities. The third level of exchanges, located in small to medium-sized cities, could terminate telex customer lines and had a single trunk group running to its parent exchange.

Loop signaling was offered in two different configurations for Western Union Telex in the United States. The first option, sometimes called local or loop service, provided a 60 milliampere loop circuit from the exchange to the customer teleprinter. The second option, sometimes called long distance or polar was used when a 60 milliampere connection could not be achieved, provided a ground return polar circuit using 35 milliamperes on separate send and receive wires. By the 1970s, under pressure from the Bell operating companies wanting to modernize their cable plant and lower the adjacent circuit noise that these telex circuits sometimes caused, Western Union migrated customers to a third option called F1F2. This F1F2 option replaced the DC voltage of the local and long distance options with Bell 108 modems at the exchange and subscriber ends of the telex circuit. The Bell 108 was operationally compatible with the Bell 103 standard, minus ring detection, as it was designed for use over leased lines.[28]

Western Union offered connections from telex to the AT&T Teletypewriter Exchange (TWX) system in May 1966 via its New York Information Services Computer Center.[29] These connections were limited to those TWX machines that were equipped with automatic answerback capability per CCITT standard.

USA-based telex users could send the same message to several places around the world at the same time, like email today, using the Western Union InfoMaster Computer. This involved transmitting the message via paper tape to the InfoMaster Computer (dial code 6111) and specifying the destination addresses for the single text. In this way, a single message could be sent to multiple distant telex and TWX machines as well as delivering the same message to non-telex and non-TWX subscribers via Western Union Mailgram.

International record carriers

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International record carrier (IRC) was a term created by the Federal Communications Commission in the United States. Bell's original consent agreement limited it to international dial telephony, and the Western Union Telegraph Company had given up its international telegraphic operation in a 1939 bid to monopolize U.S. telegraphy by taking over ITT's postal, telegraph and telephone service (PTT) business. The result was a de-emphasis on telex in the U.S. and the creation of several international telex and telegraphy companies, collectively called IRCs:

  • Western Union Telegraph Company developed a subsidiary named Western Union Cable System. This company was later renamed as Western Union International (WUI) when it was spun off by Western Union as an independent company. WUI was purchased by MCI Communications (MCI) in 1982[30][31] and operated as a subsidiary of MCI International.
  • ITT's "World Communications" division (later known as ITT World Communications) was amalgamated from many smaller companies: Federal Telegraph, All American Cables and Radio, Globe Wireless, and the common carrier division of Mackay Marine. ITT World Communications was purchased by Western Union in 1987.[32]
  • RCA Communications (later known as RCA Global Communications) had specialized in global radiotelegraphic connections. In 1987, it was purchased by MCI International.[33]
  • Before World War I, the Tropical Radiotelegraph Company (later known as Tropical Radio Telecommunications, or TRT) put radio telegraphs on ships for its owner, the United Fruit Company (UFC), to enable them to deliver bananas to the best-paying markets. Communications expanded to UFC's plantations, and were eventually provided to local governments. TRT eventually became the national carrier for many small Central American nations.
  • The French Telegraph Cable Company (later known as FTC Communications, or just FTCC), which was founded in 1871, was owned by French investors and headquartered in the United States; it laid transatlantic cable between the two countries. International telegrams routed via FTCC used routing ID "PQ", the initials of the company's founder, Augustin Pouyer-Quertier (1820–1891).
  • Firestone Rubber developed its own IRC, the United States-Liberia Radio Corporation,[34] which operated shortwave from Akron, Ohio to the rubber plantations in Liberia.[35][36] Services on this circuit were formally discontinued in 1994.[37]

Bell Telex users had to select which IRC to use, and then append the necessary routing digits. The IRCs converted between TWX and Western Union Telegraph Co. standards.

United Kingdom

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Telex began in the UK as an evolution from the 1930s Telex Printergram service, appearing in 1932 on a limited basis. This used the telephone network in conjunction with a Teleprinter 7B and signalling equipment to send a message to another subscriber with a teleprinter, or to the Central Telegraph Office.

In 1945, as the traffic increased, it was decided to have a separate network for telex traffic, and the first manual exchange opened in London. By 1954, the public inland telex service opened via manually switched exchanges. A number of subscribers were served via automatic sub-centres which used relays and Type 2 uniselectors, acting as concentrators for a manual exchange.

In the late 1950s, the decision was made to convert to automatic switching and this was completed by 1961; there were 21 exchanges spread across the country, with one international exchange in London. The equipment used the Strowger system for switching, as was the case for the telephone network. Conversion to Stored Programme Control (SPC) began in 1984 using exchanges made by Canadian Marconi, with the last Strowger exchange closing in 1992. User numbers increased over the ensuing years into the 1990s.

The dominant supplier of the telex machines was Creed & Company, a division of the ITT Corporation.

A separate service Secure Stream 300 (previously Circuit Switched Data Network) was a variant of telex running at 300 baud, used for telemetry and monitoring purposes by utility companies and banks, among others. This was a high-security virtual private wire system with a high degree of resilience through diversely routed dual-path network configurations.

After privatization of the telecommunications network under Margaret Thatcher's government at the start of the 1980s, Mercury Communications[38] also provided a telex network, based on T200-series switching equipment[39] supplied by the Swiss company Hasler in 1986 (after 1987 a member of the Ascom company). In 1996 Mercury was incorporated into Cable & Wireless Communications, which continued telex operation until 2006 when the remaining telex subscribers were transferred to Swiss Telex, which operated a multinational telex network until 2020 (also with T200 equipment).

British Telecom stopped offering the telex service to new customers in 2004 and discontinued the service in 2008, allowing users to transfer to Swiss Telex if they wished to continue to use telex.[40]

Canada

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Canada-wide automatic teleprinter exchange service was introduced by the CPR Telegraph Company and CN Telegraph in July 1957 (the two companies, operated by rivals Canadian National Railway and Canadian Pacific Railway, would join to form CNCP Telecommunications in 1967). This service supplemented the existing international telex service that was put in place in November 1956. Canadian telex customers could connect with nineteen European countries in addition to eighteen Latin American, African, and trans-Pacific countries.[41] The major exchanges were located in Montreal (01), Toronto (02), and Winnipeg (03).[42]

New Zealand

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In 1960, telex was introduced in New Zealand for businesses to communicate with the northern hemisphere, specially with the United Kingdom. In 1966 there were over 400 subscribers, and by 1981 the number had jumped to 3,600.[43]

In 1960, the New Zealand Post Office released GENTEX, a telex system cheaper than the ones available at a time.[43]

Kenya

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Telex was introduced in Kenya by the British Empire during the Kenya Colony period. International telex and telephone lines were installed on Kenya's major urban centers, such as Nairobi and Mombasa, to connect British administrators and merchants with their counterparts in England.[44] After the independence of Kenya in 1963, the telex system was expandaded to the rural areas. In 1977 there were 920 lines on Kenya, raised to 2,800 in 1988.[44]

Decline

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Telex is still in operation but not in the sense described in the CCITT Blue Book documentation. Telex has been mostly superseded by fax, email, and SWIFT, although radiotelex (telex via HF radio) is still used in the maritime industry and is a required element of the Global Maritime Distress and Safety System.

See also

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References

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Further reading

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Revisions and contributorsEdit on WikipediaRead on Wikipedia

Telex

View on Grokipedia
from Grokipedia
Telex is an international telecommunications service consisting of a network of teleprinters connected by switched exchanges, enabling subscribers to exchange typed text messages directly and automatically over dedicated lines. Originating in during the early , Telex evolved from earlier telegraph technologies, such as Émile Baudot's 5-unit code invented in 1874 and Donald Murray's typewriter-based system developed in 1901, to provide a standardized method for written business communications. The first wide-coverage Telex network was implemented in in the 1930s, with the launching its dedicated automatic switched network for teleprinters in 1958. In the United States, introduced Telex in 1962 as a competitor to AT&T's TWX service, marking its expansion into . Technically, Telex operated using asynchronous with the 5-bit International Telegraph Alphabet No. 2 (ITA2) code, transmitted at a standard speed of 50 over voice-frequency telegraph channels, allowing messages to be typed on a keyboard and printed at the receiving end without intervention. Each subscriber had a unique numeric address and an answerback code for verification, facilitating direct dialing similar to telephones but for text. The system supported both national and international traffic, with approximately 30% of messages crossing borders, and was particularly valued for its permanent written record and reliability in sectors like banking and maritime operations. Telex experienced rapid growth from the through the , surpassing telephone expansion in many countries between 1965 and 1980, and reaching its peak around 1987 with millions of subscribers worldwide. It served as a for global business and official communications, including secure fund transfers in banking starting in 1966, until its decline in the late 1980s and 1990s due to the rise of machines, which offered higher speeds and , and later electronic mail over the . By the early 2000s, Telex networks had largely been dismantled in developed countries, though remnants persisted in some developing regions and specialized applications.

Fundamentals

Definition and Purpose

Telex is a telecommunication system consisting of a network of teleprinters that enables the transmission of text-based messages over dedicated lines or networks, functioning as a switched service from the 1930s until its widespread decline in the 1980s due to the rise of and technologies. It represented an evolution from earlier telegraph systems, providing automated, direct station-to-station communication without the need for manual operators. The primary purposes of Telex included facilitating communications, such as rapid exchanges between offices, and serving as a medium for international telegrams and urgent dispatches. In industries like , it supported secure data exchange, including encrypted instructions for funds transfers between banks, while in shipping, it enabled real-time coordination of and . Overall, Telex acted as a precursor to modern digital messaging systems by establishing global, text-oriented networks for professional and commercial use. Key characteristics of Telex encompass point-to-point switched connections that allow direct linking of subscriber terminals, the assignment of unique dedicated telex numbers for identification and , and the employment of error-resistant binary signaling via 5-bit codes to ensure reliable transmission over potentially noisy lines. Emerging during the , it upgraded manual by automating exchanges and integrating hardware for typed input and output, thereby enhancing efficiency in global text communication.

Technical Principles

Telex systems center on s as the essential hardware for user interaction, typically featuring integrated keyboards for message composition, electromechanical printers for output display, and paper tape readers or punches to facilitate automated input, storage, and batch transmission of data. Prominent models include the Creed 7B, a 50-baud page-printing introduced in the 1930s, and the T-1000, an electronic desktop unit developed in the 1970s that supported full-page printing and tape handling for efficient operation. At the core of Telex signaling is binary on-off keying, where electrical pulses represent mark (on) and space (off) states to transmit data using the 5-bit International Telegraph Alphabet No. 2 (ITA2), which encodes uppercase letters, numbers, and select symbols through shift mechanisms between figures and letters modes. This occurs at a standard modulation rate of 50 baud—corresponding to roughly 66 words per minute—in a 7-unit asynchronous start-stop format comprising a start pulse, five data bits, and 1.5 stop pulses per character to synchronize receiving devices without a shared clock. Transmission over the medium employs (FSK) to modulate the binary signals into audio tones suitable for voice-grade lines or dedicated leased cables, with a typical frequency shift of 60 Hz in narrowband configurations per CCITT standards, and separate send/receive channels enabling simultaneous bidirectional communication in full-duplex mode where supported. Error detection relies on and mandatory answerback codes—variable-length sequences, typically 8-16 characters, automatically transmitted upon connection, such as "VULCAN WPB" identifying a specific subscriber—for verifying terminal identity during handshakes. across global networks is governed by CCITT (now ) recommendations, notably F.59, which define the 7-unit start-stop transmission parameters, signal levels, and impedance standards to ensure seamless connection between diverse models and national systems.

Historical Development

Origins and Invention

The origins of the Telex network lie in , where a program for an automatic switched system was initiated in 1926 by the German Reichspost, building on earlier telegraph technologies such as the using asynchronous transmission. This effort addressed the limitations of manual telegraph switching by aiming for automated routing of text messages via teleprinters, marking a significant advance in infrastructure. Key contributions came from German engineering firms, including , which proposed the concept for a public network. The development culminated in 1933 with the world's first operational public switched teletype network, trialed by the as a means to distribute and commercial messages at speeds around 66 . Initial rollout was limited, starting with just 21 subscribers connected via dedicated lines in major cities like . By 1939, the network had expanded to approximately 1,500 subscribers, primarily serving businesses and government offices within . Early exchanges required manual intervention for complex routing, restricting efficiency and scalability. The system remained largely confined to domestic use, with only limited international links to neighboring European countries, hindering broader adoption before . These pre-war constraints, including reliance on the ITA2 alphabet for , underscored the nascent stage of the .

Global Expansion and Standardization

Following , telex networks experienced a significant revival in , building on pre-war foundations to support economic reconstruction and international trade. In , the service was restarted and expanded rapidly, reflecting the country's industrial recovery, with the network reaching substantial scale by the late 1970s. Adoption across was facilitated through the International Telecommunication Union's (ITU) Consultative Committee for International Telegraph and Telephone (CCIT, predecessor to CCITT), which helped coordinate telegraph and telex operations in the period. International efforts intensified in the under ITU auspices, establishing agreements for global of telex systems. These included the development of telex destination codes (TDCs) and country prefixes to enable seamless routing across national networks. By the mid-, these standards allowed telex exchanges to interconnect reliably, fostering a unified global service. The marked initial growth phases in and , where telex adoption surged among businesses for reliable , driven by post-war industrialization and the need for direct . Expansion accelerated in the and into , , and , as developing regions integrated telex into their telecommunication infrastructures to facilitate trade and administration; global subscribers approached 1 million by 1978, reaching a peak of over 2 million around 1987. A pivotal event was the 1960 introduction of automatic international gateways, exemplified by Western Union's launch of direct telex service to via W.U. International, enabling subscriber dialing without manual intervention and expanding access to key hubs like and . In the , telex began bridging to emerging networks through ITU standards, such as Recommendation S.15 (, revised in subsequent years), which permitted transmission over telex lines under controlled conditions to enhance compatibility with early computer-based systems.

Operational Mechanics

Network Architecture and Switching

The Telex network employed a hierarchical comprising , regional, and international exchanges to enable reliable point-to-point connections worldwide. exchanges served individual subscribers within a geographic area, aggregating from telex terminals connected via dedicated lines. Regional exchanges interconnected multiple facilities to route domestic efficiently, while international exchanges managed cross-border connections, often interfacing with global gateways. This structure, utilizing electromechanical switches, ensured scalable connectivity for text-based messaging over dedicated circuits. Switching in Telex systems relied on electromechanical technologies, including step-by-step and crossbar mechanisms, for automatic routing of connections. Step-by-step switches, akin to early Strowger systems, sequentially selected paths based on dialed digits, providing direct control for call establishment. Crossbar switches, introduced later, used a grid of electromechanical crosspoints for faster, more reliable switching with reduced wear on components. Early international links frequently required manual operator intervention to complete routing across borders, bridging automated domestic networks. Telex addressing consisted of 5- to 8-digit national numbers prefixed by international country codes, such as 31 for the , to uniquely identify terminals globally. These codes, standardized by the (ITU), facilitated automatic dialing and routing. Directory assistance for locating numbers was handled by operators at exchanges, who maintained subscriber directories. Exchanges typically supported capacities of 1,000 to 10,000 lines, allowing networks to scale with demand through modular expansions. For instance, some installations handled up to 1,500 lines, while larger systems reached 20,000. International trunks connected exchanges via high-capacity links, including submarine cables deployed from the onward, which carried multiplexed Telex signals alongside other telegraph traffic. Security in the Telex network was inherently basic, with rarely implemented due to the era's technological limitations. However, the point-to-point dedicated lines established during active connections minimized risks by avoiding shared media, though signals remained vulnerable to physical on trunks.

Message Transmission and Applications

In Telex networks, the transmission process began with the sender dialing the recipient's unique telex number via the teleprinter's integrated dial or keyboard, similar to placing a , which routed the connection through switched exchanges. Once established, the sender initiated confirmation by pressing the "Who are you?" (WRU) key, which transmits the figures shift followed by a specific control (10110) in ITA2, prompting the receiving machine to automatically transmit its pre-programmed answerback —a short alphanumeric identifier unique to the terminal, such as a combination of name, location, and number—for verification of the correct recipient. This answerback ensured secure and accurate delivery, as the code was compared against known details before proceeding. The message itself was then sent either by direct typing on the keyboard for short, real-time exchanges or, more commonly for longer or pre-composed content, by feeding perforated paper tape into an automatic transmitter; the tape, punched with holes encoding characters in the International Telegraph Alphabet No. 2 (ITA2), allowed transmission at speeds up to 66 words per minute without interruption from the sender. Upon receipt, the message printed simultaneously on the destination teleprinter's paper roll and could be reperforated onto tape for archiving or retransmission, enabling storage for delayed delivery if the recipient was unavailable. Telex messages followed a free-form text format limited to uppercase alphanumeric characters and basic punctuation in ITA2, with practical line lengths of about 69 characters to fit teleprinter mechanisms, though no hard global limit existed—typical messages ranged up to 1,000 characters to minimize costs. Optional headers at the start could denote priority (e.g., urgent via "WRU" sequences) or billing details, while the body conveyed without or formatting, emphasizing brevity through abbreviations common in international . For delayed or stored delivery, networks supported queuing at exchanges, where messages on perforated tape were held and automatically dispatched upon reconnection, bridging gaps in 24/7 availability. Telex found primary applications in commercial telegrams for urgent , dispatches by press agencies collecting and distributing reports globally, and financial transactions such as quotes, confirmations, and early interbank data exchanges before the advent of dedicated systems like in the 1970s. It served as a reliable medium for time-sensitive data interchange in sectors like shipping bookings and trade confirmations, with gateways emerging in the to convert Telex messages into formats for integration with nascent digital networks. Billing for Telex usage was predominantly time-based, charged per minute of connection duration to cover switched line occupancy, with international rates escalating based on distance— for instance, transatlantic calls in the mid-20th century could exceed $1 per minute, prompting concise messaging to reduce expenses. Some domestic services incorporated per-word elements for telegram-style routing, but the core model emphasized efficient, metered online time over volume. Users experienced a robust, always-on system supporting direct peer-to-peer alphanumeric exchanges worldwide, though limitations to text-only content and mechanical speeds (around 50 baud) constrained it to essential, non-visual communications.

Regional Implementations

North America

In the United States, the Teletypewriter Exchange Service (TWX) was launched by in 1931 as a switched network for teleprinter-based , initially operating at a speed of 45.45 using five-bit . The service began as a manual system but transitioned to automated switching by 1962, enabling direct-dial connections and expanding its reach for business communications. In January 1969, acquired TWX from , integrating it into its broader telegraph operations to compete in the growing data transmission market. By 1981, had upgraded the network to Telex II, which operated at 110 with ASCII encoding to support faster and more compatible international messaging. International connectivity in the US was bolstered by carriers such as ITT World Communications and RCA Global Communications, which provided overseas Telex links alongside , facilitating global business and diplomatic exchanges from the onward. These operators handled record communications like Telex as part of their international telegraph services, often integrating with undersea cables and radio links. In Canada, Telex was introduced in 1956 by the Canadian National Telegraph (CN Telegraph) and Telegraphs, leveraging existing telegraph infrastructure for switched . The network expanded rapidly with major exchanges established in key cities, including in 1957, in 1958, and in 1960, forming the backbone of a national system that connected businesses across the country. By the , the service had grown significantly, with thousands of subscribers relying on it for reliable, real-time document transmission amid rising commercial demand. North American Telex systems shared adaptations like initial slower rates—such as the 45.45 standard in the —and close integration with networks for and signaling, allowing seamless hybrid use in telecom operations. Cross-border interconnections emerged in the early , with Canadian Telex linking to the TWX network by through bilateral agreements, enabling efficient messaging between the two countries. The decline accelerated in the late due to and alternatives, culminating in Western Union's discontinuation of Telex and related messaging services in 2006.

Europe

Telex adoption in Europe was characterized by state-controlled networks managed by national postal administrations, which facilitated early automation and dense international connectivity, distinguishing it from more commercial models elsewhere. served as a pioneering hub, with the operational Telex service launched in 1933 by the following experimental development from 1926; the first public connection linked and , initially serving 21 subscribers that grew to 1,500 by 1939. After , the assumed management of the network, overseeing its expansion amid post-war reconstruction; by 1975, subscriber lines exceeded 90,000, positioning as a key international gateway for Telex traffic due to its advanced switching infrastructure. In the United Kingdom, Telex evolved from the General Post Office's (GPO) 1932 Printergram service, an early teleprinter system that laid the groundwork for automated messaging. Full automation was realized by 1961, when manual operations at central offices like London's Central Telegraph Office were phased out in favor of subscriber-dialed exchanges, such as the one at Fleet Building that absorbed London-area users by late 1960. The network peaked at around 66,000 subscribers in 1977, supporting robust business and international communications until its decline; British Telecom, successor to the GPO, discontinued the service in March 2008, marking the end of public Telex operations in the UK. Across , Telex networks exhibited variations but achieved uniformity through CCITT standards, including the 50-baud transmission rate defined in Recommendation S.1 for reliable operation at approximately 66 words per minute. established its Telex service in the early under the Poste, Télégraphes et Téléphones (PTT), with automated exchanges proliferating from the onward to support press and commercial use. Sweden's network, managed by the state-owned Televerket, began operations in 1953, integrating into its broader telecommunications framework for efficient domestic and Nordic connectivity. In the , European Telex systems interfaced with initiatives like Euronet, a precursor to digital information networks that linked libraries and services across member states, enhancing cross-border and file exchange via integrated communication modes including telex. World War II inflicted severe damage on European telecommunications infrastructure, including Telex lines and exchanges, which postponed full-scale deployment in many countries until the late 1940s. Recovery accelerated in the 1950s through investments by state teleposts, enabling rapid rebuilding and automation that boosted Telex to a vital tool for economic revival and international trade.

Other Regions

In , Telex was introduced in in 1960 by the New Zealand Post Office to facilitate communications with the northern hemisphere, particularly the , using the GENTEX system as defined by ITU standard F.20 for telegram transmission over Telex networks. This marked an early adoption in the region, building on existing telegraph infrastructure to support international messaging. In , Telex networks originated from colonial-era telecommunications setups influenced by British and Dutch administrations, with systems in place before independence in many countries. In , for example, Telex was operational prior to and expanded post-independence to include rural areas, reflecting efforts to modernize inherited colonial for broader access. Similar developments occurred in and , where British and Dutch colonial legacies shaped the integration of Telex into national networks, often prioritizing urban and administrative centers initially. Adoption in and occurred later, amid post-war reconstruction and economic growth, but faced significant hurdles from limited and reliance on imported equipment. In , Telex service commenced in the mid-20th century as part of broader expansion, aligning with the country's rapid industrialization. In , the national Telex service was established in the under public-sector monopoly structures, yet growth was slowed by deficient lines, high costs for imported teleprinters, and uneven switchboard coverage, resulting in slower penetration compared to more developed regions. Globally, Telex served as a vital tool in developing regions for coordinating international and trade, enabling direct text-based exchanges between businesses and organizations where voice was unreliable. The (ITU) supported this connectivity by assigning unique Telex destination codes (TDCs) and network identification codes (TNICs) to countries and geographical areas, fostering a worldwide network that integrated over a hundred nations by the late .

Decline and Legacy

Factors of Decline

The decline of the Telex network in the late was driven primarily by technological limitations that rendered it obsolete in the face of faster, more versatile alternatives. Operating at a standard speed of 50 baud, Telex was constrained to text-only transmissions, lacking the capacity for , images, or content. This became a critical drawback as (fax) technology proliferated in the , with the Group 3 standard enabling near-real-time transmission of documents over standard phone lines at speeds up to 9,600 baud, combining the immediacy of voice calls with the permanence of written records. By the , further accelerated the shift, offering seamless digital integration, lower latency, and compatibility with emerging computer networks, which allowed for attachments and broader without dedicated hardware. Economic pressures compounded these technological shortcomings, as maintaining Telex proved increasingly costly compared to rivals. The dedicated of switches and teleprinters required substantial in aging electromechanical systems, while message rates rose steadily—for instance, , the average cost per Telex message increased from $5.34 in to $9.01 in , even as usage plummeted. in the , particularly in the U.S. following the Modified Final Judgment breakup of in 1982, exposed Telex operators to heightened competition, leading to consolidations and exits; , a major provider, faced severe financial strain from declining Telex revenues, which fell from $415 million in 1985 to just $10 million by 2001, prompting it to refocus on other services. Meanwhile, machines became affordable—dropping to around $200 by 1995—and required minimal , eroding Telex's economic viability. Competitive pressures from specialized systems further marginalized Telex, especially in key sectors. In financial messaging, the Society for Worldwide Interbank Financial Telecommunication (SWIFT), established in , replaced Telex by providing a secure, standardized protocol for international bank transfers, addressing Telex's vulnerabilities like low speed, inconsistent formatting, and security risks. The broader rise of the in the 1990s offered general-purpose messaging at negligible marginal cost, while incomplete digital transitions in some developing regions prolonged but did not halt the overall contraction. These factors culminated in key events marking Telex's widespread obsolescence. Globally, Telex subscriptions peaked at approximately 1.6 million in 1987 before declining sharply, reaching about 1.2 million by 1992 due to the fax boom. In the United States, discontinued its telegram and commercial messaging services on January 27, 2006, citing irrelevance amid dominance. , which had acquired 's Telex operations in , discontinued Telex services in 2008. The followed suit, with BT terminating its Telex service in March 2008 after ceasing new subscriptions in 2004, transferring remaining users to international providers.

Enduring Influence and Modern Uses

Telex's store-and-forward messaging principles, which allowed messages to be held and routed asynchronously across networks, served as a foundational concept for later digital communication systems, including and short message service (). Early email implementations, such as those on in the 1970s, built upon telex-like text-based transmission over switched networks, evolving the idea of reliable, asynchronous delivery without requiring simultaneous sender-receiver availability. Similarly, telex's automated text dispatch influenced store messaging in mobile networks, where brief alphanumeric messages are queued and forwarded, as seen in the precursors to modern SMS protocols. Telex networks also contributed to the development of packet-switched data protocols like X.25, with adaptations enabling telex signals to be encapsulated into X.25 packets for integration with public data networks. In contemporary applications, radiotelex remains a vital component of maritime communication under the International Maritime Organization's (IMO) Global Maritime Distress and Safety System (GMDSS), particularly for narrow-band direct-printing (NBDP) on HF frequencies in remote ocean areas. This IMO-compliant technology allows ships to transmit text messages to coast stations and connect to the international telex network, ensuring safety and operational coordination where satellite or VHF coverage is limited. Legacy telex systems persist in select remote regions of and , supporting basic text communication in areas with underdeveloped infrastructure, though their use has sharply declined. Email-to-telex gateways, which facilitated bidirectional messaging between email and telex networks, operated into the , bridging digital and analog systems for businesses reliant on legacy equipment. Telex holds significant cultural and archival value, particularly in and , where preserved telex transcripts provide primary sources for historical analysis of communications and international negotiations. As an evolution from the telegraph—offering faster, automated printing without —telex enabled real-time textual exchanges that outpaced manual , while later represented a visual advancement by transmitting images alongside text. Today, active telex networks are minimal as of the early 2020s, sustained primarily for niche maritime and archival purposes; the (ITU) continues to maintain telex destination codes (TDCs) and network identification codes (TNICs) to support any residual interoperability. As of , national Telex networks have been retired in most countries, including the U.S. (AT&T, 2008) and U.K. (BT, 2008), with usage limited to radiotelex in maritime applications and hobbyist emulations. Hobbyist communities have revived interest through emulators and networks like i-Telex, which connect vintage teleprinters to the via USB or interfaces, preserving the technology for educational and recreational use.

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