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Teleprinter

A teleprinter, also known as a teletypewriter or TTY, is an electromechanical that transmits and receives typed messages over communication channels such as dedicated lines, radio links, or cables. These devices operate using a start-stop method with codes, typically at speeds of 60 to 100 , allowing one to handle both sending and receiving without expertise. Invented in the late to automate , teleprinters evolved from early patents like Émile Baudot's 1874 five-bit code system for signals over wires. Key developments accelerated in the early 20th century, with Howard L. Krum's 1910 start-stop synchronization enabling reliable point-to-point transmission, leading to widespread adoption by news agencies like the starting in 1914 for global story distribution. During , portable models such as the Kleinschmidt teleprinter became standard for U.S. Navy communications, achieving speeds up to 100 words per minute over radio. Postwar, teleprinters powered the network launched in 1932, connecting businesses worldwide for direct dialing, and served as early computer input/output terminals in the 1950s and 1960s. Beyond , they facilitated accessibility for deaf individuals via text-based phone relays and influenced modern digital communication protocols. By the 1980s, electronic alternatives largely supplanted them, though their legacy persists in terminal emulators like the TTY interface in Unix systems.

Fundamentals

Definition and Components

A teleprinter, also known as a teletypewriter or TTY, is an electromechanical device resembling a that transmits and receives typed text messages over wire or radio channels by converting keystrokes into electrical signals and vice versa. Unlike manual telegraphs, which require operators to send , teleprinters automate the encoding and decoding of alphanumeric characters for direct printing or transmission. This device evolved from technology by integrating electrical actuation for remote communication. Key components include a keyboard for operator input, typically featuring a typewriter-style arrangement with keys that generate electrical contacts to encode characters. The transmitter section converts these key presses into serial electrical pulses via a contact mechanism, while the receiver interprets incoming signals to actuate the printing. The printing mechanism employs a type basket or similar mechanism, positioned by solenoids—often five for character selection in 5-bit systems—to strike characters onto paper. An electric motor, usually a fractional horsepower synchronous type, drives the mechanical timing and carriage functions, synchronized to line frequency for precise operation. Additional functional parts encompass a paper tape reader and puncher for offline message preparation and playback, allowing tape to store or feed encoded without typing. The signal interface handles electrical connections, such as current loops at 20-60 mA or early serial standards akin to precursors, for linking to communication lines. variations range from compact desktop models to larger console units, often encased in metal for durability and noise containment. Typical specifications feature 5- to 8-bit encoding for character representation, with transmission speeds of 45 to 110 to balance reliability and throughput. Paper handling involves rolls or fanfold sheets up to 8.5 inches wide for standard printing. Power requirements vary by model, supporting variants at 115 V or 230 V, 50-60 Hz, with some adaptable to DC for field use. Visually and ergonomically, teleprinters often use or custom layouts adapted for telegraph codes, with keyboards positioned for touch-typing efficiency. They produce notable operational noise from motor hum and mechanical impacts, necessitating enclosed designs for office environments. Early models weigh 50 to 100 pounds, measuring around 20 by 18 by 16 inches for configurations.

Basic Principles of Operation

A teleprinter operates by converting typed input into electrical signals for transmission and interpreting received signals to produce printed output. In the sending process, pressing a key on the activates mechanical contacts that generate a series of electrical pulses representing the , typically in a start-stop format with a start bit followed by five unit impulses (marking or spacing) for the code elements, and stop bits. These pulses are sent over the communication line via a interface, where a motor in the transmitter synchronizes the signal generation, and at the local or remote printer, the pulses drive a type basket or selector to position the correct before a actuates the ribbon to imprint the on the paper tape or page. The receiving process mirrors this by detecting incoming pulses through a selector mechanism, often comprising polarized electromagnets that respond to the signal polarities to align the printing elements. A continuously running motor, synchronized via the start-stop timing, advances the paper incrementally after each character sequence, ensuring sequential as the or striker mechanism impacts the inked against the paper for each interpreted code. This electromechanical conversion allows reliable character reproduction without manual intervention. Synchronization in teleprinters relies on start-stop , where a start pulse (marking ) initiates the 's timing for the subsequent five code , followed by a stop pulse (spacing ) that allows the to idle until the next start, using rates consistent with the code for consistent pulse duration without a shared clock. Later models using ASCII encoding may incorporate bits for odd or even checks to identify single-bit errors, or simple checksums for verifying in extended operations, though these are not universal in all models. Teleprinters support local operation for standalone printing or remote via leased lines, powered by a 20 mA circuit that maintains over distances up to several kilometers with (typically 24-60 V supply), where the basic diagram involves a power source in series with the transmitter/receiver coils, switching between (current flow) and space (interrupted) states. Safety features include thermal overheat protection in the drive motor to prevent from prolonged use, while maintenance requires periodic lubrication of pivot points, selector cams, and type basket mechanisms with light oil to minimize . Common failure modes, such as stuck solenoids from accumulated dust or dried , can disrupt printing and are addressed through cleaning and re-lubrication during routine servicing.

Historical Development

Origins and Early Inventions

The development of teleprinter technology emerged from 19th-century efforts to automate telegraphy and produce printed outputs, building on early electrical signaling systems primarily in Europe and the United States. In the United Kingdom, Charles Wheatstone, collaborating with William Fothergill Cooke, advanced needle-based telegraphs in the 1830s, culminating in the 1840 patent for a step-by-step electrical telegraph system, which laid the groundwork for Wheatstone's later 1858 ABC telegraph, an alphabetical instrument that displayed letters on a dial to reduce the need for skilled operators. This device represented an early shift toward more user-friendly reception, though it still required manual interpretation rather than direct printing. A significant breakthrough in producing printed telegraph messages occurred with Royal Earl House's 1846 patent for the magnetic letter-printing telegraph, the first practical system to generate readable text output automatically at the receiving end using synchronized typewheels and piano-like keys for input. House's invention transmitted messages at speeds of about 40 over dedicated lines, but it faced major challenges including precise between sender and receiver to align the printing mechanism, as well as reliance on manual telegraph infrastructure that limited scalability. These early systems operated at low speeds—typically a few dozen —and were prone to errors from line noise or misalignment, highlighting the need for more robust . Further innovations addressed these limitations through and mechanical improvements. In , Émile patented a multiplex telegraph system in 1874 that allowed multiple simultaneous s over a single wire using a five-bit code and distributor mechanism, enabling efficient sharing of lines for telegraphs. Influenced by such advancements, inventor contributed in 1872 with an electric adapted for automatic , featuring a perforator that punched to control relays, laying groundwork for -based . By the and , the transition from manual needle and dial systems to automatic perforated mechanisms accelerated, with Wheatstone's perforator and reader systems enabling pre-prepared messages to be sent without real-time operator intervention, improving reliability over manual lines. These evolutions, driven by , , and inventors, set the foundation for fully automated teleprinters by resolving key synchronization and speed issues inherent in earlier prototypes.

Standardization and Key Milestones

The early 1900s marked significant milestones in teleprinter development, with the Morkrum Company introducing the start-stop synchronization system around 1906, which allowed for asynchronous operation and greater reliability in permutation code telegraph systems by using a brief start signal to initiate each character and a stop signal to reset the receiver. This innovation laid the foundation for commercial viability. In 1919, Edward E. Kleinschmidt's company completed a keyboard-operated typebar teleprinter designed for intercommunication systems, featuring a portable model that improved mobility and usability for field applications. Standardization efforts began with the evolution of Émile Baudot's 1870s 5-unit code, which the CCITT adopted and refined into International Telegraph Alphabet No. 1 (ITA1) in the early for international consistency. By the 1930s, the CCITT further standardized the code as ITA2, incorporating modifications like Donald Murray's shift mechanism for uppercase/lowercase letters, enabling broader adoption in teleprinter networks while maintaining the 5-unit format for compatibility with existing equipment. Speeds progressed from around 40 words per minute (wpm) in early models to 100 wpm in later designs, driven by mechanical refinements and the need for efficient message handling. In the 1960s, the shift to 7-bit (and later 8-bit with parity) codes culminated in the ASCII standard, promoted by Bell Data Services for teleprinter use starting in 1963, which supported 128 characters and facilitated integration with emerging computers. Military applications during and II accelerated improvements in reliability, with teleprinters integrated into systems; for instance, the U.S. Army's adoption of printing telegraphs enhanced tactical signaling despite challenges like line disruptions. During WWII, teleprinters were integrated with attachments and one-time tape systems for secure communications, ensuring high-level confidentiality in Allied operations. Post-war, a commercial boom ensued, with teleprinters becoming standard in business and news services due to proven wartime durability. The global spread of teleprinters was propelled by dedicated networks, including the U.S. Teletypewriter Exchange Service (TWX) launched by in 1932 for direct subscriber connections over telephone lines. In , the world's first public switched teletype network, , began trial operations in 1933 under the Reich mail service, enabling automated and rapid expansion across . By the , these networks peaked with millions of installations worldwide, supporting and diplomacy. Key events included the 1920s development of (FSK) for radio transmission, patented for teleprinter use to reduce errors over channels, and the late onset of transistorization in gear, which began replacing vacuum tubes in teleprinter peripherals for more compact, efficient designs.

Technical Operation

Encoding and Transmission Protocols

Teleprinters primarily employed 5-bit code systems to represent characters, enabling transmission of 32 distinct symbols per code word. The original utilized five binary digits to encode basic alphanumeric and punctuation characters, forming the foundation for early telegraphic data representation. Subsequent refinements, such as the Murray code adopted as International Telegraph Alphabet No. 2 (ITA2), introduced shift mechanisms to toggle between letter and figure modes, allowing access to additional symbols like numerals and punctuation without expanding the bit length. For error-prone channels, particularly radio links, (ARQ) protocols extended the 5-bit structure into 7-unit formats, incorporating redundancy for detection and retransmission requests to achieve reliable delivery. Transmission in teleprinters relied on asynchronous start-stop signaling, where each character began with a start bit (mark-to-space transition), followed by five data bits and typically 1.5 to 2 stop bits (space-to-mark) to synchronize the without a shared clock. Signaling occurred via current loops, often at 20 mA or 60 mA, where a closed loop represented the idle state and bit transitions interrupted the current; this contrasted with voltage-based methods like , offering greater compatibility with long-distance lines. Common baud rates ranged from to , with baud corresponding to approximately 60 , baud to around 100 for mechanical models, and baud supporting around 100 for typical 7-bit operation, balancing speed and mechanical reliability. Operational protocols emphasized half-duplex communication, where stations alternated and to avoid , often using basic handshaking signals like end-of-message or ready acknowledgments for coordination. Over radio channels, (FSK) modulated the carrier, typically with an 850 Hz shift around a Hz (e.g., at 2125 Hz and at 1275 Hz), converting into audible tones for robust over-the-air . Early 5-bit codes like Baudot and ITA2 lacked dedicated lowercase letters, restricting alphabets to uppercase and relying on shift functions to access figures, symbols, or alternate characters, which limited expressiveness in mixed-case text. International variants, such as CCITT No. 2 (equivalent to ITA2), adapted the core set for regional needs, substituting certain symbols (e.g., accented characters in versions) while maintaining the 32-code limit and shift protocol. Signal integrity in teleprinter systems benefited from designs, which provided inherent resistance by maintaining consistent current flow despite , unlike voltage signals prone to over distance. Line conditioning, via repeaters or filters, mitigated distortion in leased circuits, ensuring . The baud rate, defined as symbols per second, relates to the by the equation \text{baud rate} = \frac{\text{bit rate}}{\text{bits per symbol}}, where binary signaling (1 bit per symbol) yields equal values; for instance, a 110 baud rate supports 100 words per minute in typical 7-bit asynchronous operation.

Mechanical and Electrical Mechanisms

The printing mechanism in teleprinters relied on a typebar system, where a series of typebars, similar to those in typewriters, were mechanically actuated to strike an inked ribbon against paper wrapped around a platen, imprinting characters. Selection of the appropriate typebar was achieved through a set of five code bars positioned by the selector mechanism in response to incoming electrical signals; notches in these code bars aligned to allow a corresponding pullbar to move freely when the printing bail engaged, throwing the selected typebar toward the platen. The platen, a cylindrical roller, advanced the paper via an escapement mechanism driven by the main shaft rotation, typically one line per character cycle, ensuring sequential printing. Inking was provided by a ribbon, either fabric for repeated use or carbon for single-pass applications, which was advanced by a ratchet wheel engaged by the pullbar bail plunger and oscillated vertically below the printing line to present fresh ribbon sections after each strike. Electrical components translated serial signals into mechanical actions through relays and electromagnets integrated with the mechanical drive. The selector magnets, energized by line signals, controlled the positioning of code bars for character selection, while a clutch mechanism synchronized the main shaft—driven by a 60 Hz synchronous motor—with the signal timing by engaging only during the start impulse of each character code. Relays for decoding handled the five-unit code impulses, with the line relay short-circuiting the circuit during idle states to prevent false actuation, and power supply circuits provided DC for magnet operation from the AC motor source, often incorporating filters to minimize noise. Synchronization was maintained by the clutch disengaging after each character cycle, allowing the motor to idle until the next start signal. Mechanical design evolved from early step-by-step selectors in the 1910s, which used sequential actuations to step through positions like a uniselector, to rotary in that employed a continuously rotating with distributor contacts for faster, more reliable signal distribution and reduced . Weight reduction techniques included lighter alloy frames and simplified linkage systems, minimizing the mass of such as typebar segments and bars to improve speed and without compromising precision. These advancements allowed teleprinters to operate at speeds up to 100 in advanced mechanical models, while maintaining mechanical reliability over long-term use. Basic electrical schematics centered on a interface for transmit and receive, typically operating at 20 mA for later models, where marking (current on) represented one state and spacing (current off) the other, enabling robust over distances up to 2000 feet. Voltage levels varied by system, with neutral loops using 120 VDC supplies, while polar configurations employed bidirectional currents driven by +60 V and -60 V to switch polarities for enhanced immunity in noisy environments. The loop connected the sending and receiving stations in series, with the receiving selector magnet acting as the load. Maintenance of teleprinters involved regular procedures to ensure precise , such as adjusting the code bar notches and pullbar clearances to within 0.005 inches for accurate typebar selection, and calibrating timing to synchronize shaft rotation with signal pulses. Common wear parts included pawls, which controlled paper advance and often fatigued from repeated engagement, requiring replacement to prevent line feed errors, as well as selector armatures and ribbon reverse mechanisms prone to from buildup. Preventive checks encompassed lubricating moving parts with specified oils, inspecting electrical contacts for arcing, and verifying motor clutch engagement to avoid desynchronization.

Control Features and Error Handling

Teleprinters incorporated a range of control characters to facilitate precise formatting and operational coordination during transmission and reception. The character repositioned the printing to the left margin, essential for aligning text at the start of each line, while the line feed (LF) advanced the vertically by one line increment. In the 5-unit prevalent in early models, the FIGS shift code transitioned the set to numerals and symbols, and the LETRS shift code reverted to alphabetic , enabling efficient use of limited code space for mixed content. The activated an audible alarm on the receiving unit to signal , such as message completion or alerts. Additionally, the WRU () initiated an inquiry for by triggering the integrated response system. The answer-back mechanism provided an automated response to the WRU signal, transmitting a predefined 2- to 4-character code that uniquely identified the receiving station, thereby verifying connectivity in point-to-point or setups. This feature was configured via mechanical elements such as code blades inserted into the stunt box, rotating drums, or plugboard interconnections, allowing customization for specific installations like or commercial . Security implications arose from the potential for or spoofing of the ID code, which could enable unauthorized access or message rerouting in shared circuits. Error handling mechanisms ensured transmission reliability despite noise or distortion in telegraph lines. In 5-unit Baudot systems, dedicated error-detection schemes analyzed code patterns for anomalies, often employing redundancy to flag invalid sequences and initiate repeat requests from the receiver back to the sender. Later 7- and 8-unit models, such as those using ASCII, incorporated bits—typically even —appended to characters to detect single-bit errors in or signals, with the receiving circuitry verifying the bit count before actuation. Tape punch verification in automatic send-receive (ASR) units involved or electrical checks during to confirm hole placement against the intended , reducing preparation errors for offline queuing. Overprint avoidance was addressed through interlock circuits that halted until prior operations cleared, preventing overlapping characters from inertia. Formatting controls optimized output presentation and transmission efficiency. Page eject was simulated by issuing multiple consecutive LF characters to advance the paper fully, clearing the platen for a new sheet in continuous-form setups. Space suppression eliminated transmission of codes in sequences, compressing messages by substituting them with a single control to skip multiple positions without . In 7-bit implementations, upper- and lower-case handling utilized distinct assignments rather than shifts, allowing direct of alphabetic variants without changes, which enhanced compatibility with computing interfaces. These functions were implemented using dedicated electromagnetic within the teleprinter's selector and circuits, isolating signals from paths to ensure responsive operation. For instance, separate relay banks handled and LF sequencing, with relays energizing carriage motors and LF relays engaging paper-feed clutches. Timing delays, typically around 100 following a , were enforced by capacitor-resistor networks or mechanical dashpots in the relay timing circuits, synchronizing actions to accommodate the slower carriage movement relative to vertical feed and avoiding collisions or incomplete returns.

Applications

Communication Networks

The telex system represented a pioneering for text-based messaging using , originating in in as a for distributing messages before expanding into a commercial service. By the late 1970s, the network had grown to over 1 million subscribers worldwide, reaching a peak of approximately 3 million machines in the 1980s as businesses adopted it for reliable international communication. The system operated at a standard speed of 50 baud using the International Telegraph Alphabet No. 2 (ITA2) 5-bit code, enabling asynchronous serial transmission over dedicated lines. Telex networks featured automatic exchanges that routed messages point-to-point, similar to telephone switching, with international connectivity facilitated by major carriers such as International Telephone and Telegraph (ITT) and RCA Communications Inc. (RCI). These exchanges handled subscriber dialing via numeric addresses, supporting seamless global interconnectivity across over 200 countries. Integration with existing telegraph systems occurred through direct wire links and multiplexers, allowing multiple teleprinter channels to share a single circuit for efficient bandwidth use. Adaptations for radio transmission, known as radio teletype (RTTY), employed frequency-shift keying (FSK) modulation at 45.45 baud, enabling wireless extensions in remote or mobile scenarios. Network operations relied on centralized switching centers that managed call setup, message routing, and disconnection, with billing typically calculated on a per-word basis to reflect transmission length and distance. Security was enhanced through leased lines for sensitive traffic, preventing interception on routes, while standards like CCITT Recommendation F.1 governed operational provisions for telegram and services, ensuring . Usage spanned messaging for contracts and orders, distribution via wires like those of the (AP) and (UPI), and non-secure for routine reporting. In military contexts, teleprinters facilitated unencrypted tactical updates over teletype networks. Despite its reliability, the system faced limitations inherent to its design, including fixed transmission speeds that restricted throughput to about 60 , the absence of graphical or capabilities, and susceptibility to errors from line noise or interference, often requiring manual retransmission. Answer-back controls allowed brief verification of connection status during queries.

Printing and Publishing Systems

The Teletypesetter (TTS), developed in the mid-1920s through collaboration between the and the Mergenthaler Linotype Company, enabled automated control of hot-metal machines via perforated paper tape, revolutionizing high-volume text preparation for . This system used a specialized perforator in newsrooms to punch tape with encoded instructions, which could then be transmitted remotely over telegraph lines to printing facilities equipped with Linotype machines. Operating at speeds of 60 to 90 , the TTS significantly accelerated the process compared to manual , allowing newspapers to handle wire service copy efficiently. In operation, the TTS employed a six-unit perforated tape code, an extension of standard five-unit teletype codes, to represent lowercase letters, uppercase shifts, and specialized functions tailored to Linotype requirements. Justification was achieved through embedded counting codes and pointers that calculated spaceband expansions for even line lengths, with the perforator's counting scale displaying left and right justification pointers to guide operators in maintaining consistent widths across different typefaces. Font selection signals were incorporated via changeable counting magazines—sets of blades calibrated to specific typeface widths—ensuring accurate slug casting without manual intervention. To minimize errors in high-stakes publishing, workflows often involved punching dual verification tapes alongside the primary one, allowing cross-checks before transmission to the receiver's operating unit, which read the tape to actuate the Linotype's matrix assembly and casting mechanisms. By the 1960s, TTS technology integrated with emerging phototypesetters, where perforated tapes drove or film-based composition systems, bridging hot-metal and digital eras before gradually supplanted paper. Mergenthaler produced several TTS variants, including the Model 20 page printer adapted from Teletype designs and high-speed perforators for Linomatic units, optimizing for diverse layouts. International adaptations appeared in , where some systems shifted to seven-unit codes to accommodate accented characters and multilingual needs while retaining core TTS logic for compatibility with local linecasting machines. The TTS profoundly impacted publishing by streamlining newsroom-to-press workflows, enabling remote copy transmission from wire services like the and reducing typesetting time from hours to minutes per page. This efficiency fostered greater uniformity in content and design across distant facilities, boosting daily production volumes during the mid-20th century. Widespread adoption persisted into the 1980s, particularly for small to mid-sized papers, until software and direct digital interfaces rendered tape-based systems obsolete.

Computing and Data Interfaces

Teleprinters played a pivotal role as early computer peripherals, particularly in the 1960s, when models like the ASR-33 from were widely adopted as input and output terminals for minicomputers such as the PDP-8. Introduced in , the ASR-33 provided affordable keyboard entry and printed output at a cost of approximately $700, making it a standard choice for data interaction in resource-constrained environments. Its integrated paper reader and punch enabled offline program preparation and loading, where punched tapes stored or instructions that could be fed directly into the computer via bootstrap routines entered through front-panel switches. This method facilitated efficient program transport and in early systems lacking . Teleprinters also enabled accessibility in telecommunications for deaf and hard-of-hearing individuals through the development of the (TDD) or text telephone (TTY) in 1964. Invented by deaf engineers Robert Weitbrecht, , and , these devices modified surplus teleprinters with acoustic couplers to transmit typed messages over standard lines, allowing text-based conversations between users with compatible equipment. This innovation, which used Baudot or later ASCII codes at speeds around 45 baud, laid the groundwork for relay services and significantly expanded communication options for the deaf community before the rise of and . Key interfaces bridged teleprinters to digital systems, with the serial standard—established in 1960 by the Electronic Industries Association—serving as the foundational protocol for asynchronous data exchange between terminals and computers. Originally designed to link electromechanical teletypewriters to , RS-232 supported reliable point-to-point transmission at low speeds, typically using voltage levels for over short distances. For compatibility between legacy Baudot-coded teleprinters and ASCII-based computers, converters like the Frederick Electronics Model 703 translated 5-level start-stop Baudot input to 8-level ASCII output, operating across baud rates from 37.5 to 2400 and interfacing via RS-232 or dry contacts. connections, often through acoustic couplers, extended this setup for remote access, allowing teleprinters to dial into systems over public telephone networks for interactive computing sessions. In computing applications, teleprinters functioned primarily as console devices for operations, where users entered commands via the and received system responses or program listings as printed lines, effectively serving as early line printers. The TTY (teletypewriter) abstraction in operating systems like UNIX managed this interaction, providing line discipline for buffering and echoing input while supporting through direct access for tracing execution or error logs. Specific implementations included UNIX terminals operating in cbreak mode for immediate character return without echoing—useful for password entry—or raw mode for unprocessed byte streams, adapting teleprinter hardware to software demands without canonical line editing. In networks like , teleprinter terminals connected nodes at 110 baud, a common rate matching the ASR-33's mechanical limits and early acoustic modems, enabling packet-switched remote logins despite the era's constraints. Despite their versatility, teleprinters had notable limitations in computing contexts, including slow operational speeds of around 10-50 characters per second—far below the batch throughput of punch card systems, which handled denser 80-column records more efficiently for large-scale data entry. Mechanical clacking from print hammers and tape punches generated significant noise, often disrupting shared computing facilities and necessitating sound-dampening enclosures. These factors, combined with error-prone tape handling in dusty environments, gradually relegated teleprinters to niche roles as faster peripherals emerged.

Manufacturers

North American Companies

The , established in 1928 as a subsidiary of the , became the preeminent North American manufacturer of teleprinters, building on earlier innovations in printing telegraphy. acquired the Morkrum-Kleinschmidt Company that year and reorganized it under the Teletype name, focusing on reliable, high-volume production of electromechanical devices for telecommunications and data transmission. Key early models included the Model 15, introduced in the 1930s and widely adopted for during as the standard U.S. Army page printer, capable of operating at speeds up to 60 words per minute using . By the 1960s, Teletype advanced to the Model 28 series, launched in 1951, and the Model 33, introduced in 1963, which offered variants such as ASR (Automatic Send and Receive) for tape punching and reading, and RO (Receive Only) for printing incoming messages; these models supported ASCII encoding and became staples in interfaces and like TWX (Teletypewriter Exchange Service), where Teletype supplied the core hardware for 's nationwide system starting in 1932. Production peaked in the 1970s, with the Model 33 remaining a dominant terminal until the late decade, enabling widespread adoption in business and government sectors. The roots of Teletype trace back to the Morkrum Company, founded in 1906 by inventor Charles L. Krum and the Morton family in , which pioneered early page-printing telegraphs. Morkrum's 1908 , a five-unit tested on the , marked the first practical commercial teleprinter, emphasizing page printing over tape for direct readability. The company merged with rival Kleinschmidt efforts in 1924 to form Morkrum-Kleinschmidt, enhancing designs with combined mechanical and electrical features before the 1928 acquisition; Morkrum's innovations directly influenced Teletype's TWX hardware, which facilitated automated message exchange over telegraph lines. Kleinschmidt Laboratories, founded in 1931 by inventor Edward E. Kleinschmidt in , emerged as a significant competitor, specializing in compact, rugged teleprinters for applications. Building on Kleinschmidt's earlier patents from the and his work with Morkrum, the company developed portable models during , including a 100-words-per-minute unit demonstrated to the U.S. Navy in the early 1940s, which became a standard for shipboard communications due to its lightweight design and reliability in harsh environments. Postwar, Kleinschmidt secured major contracts, such as the 1949 U.S. order for the TT-4 teleprinter (also known in variants as the Labs K series), replacing Teletype models in some roles and establishing the firm as a key supplier through the . Texas Instruments entered the teleprinter market in the early 1970s with the Silent 700 series, adapting thermal printing technology for portable data terminals that bridged telegraphy and early computing. Introduced in 1971, models like the 743 and 745 featured dot-matrix thermal printers on heat-sensitive paper, operating at up to 30 characters per second, with built-in modems for 300-baud connections; these "silent" devices minimized noise compared to mechanical teleprinters and found use in field reporting and remote access. North American teleprinter production was dominated by Teletype, which held a commanding position in the U.S. market by the through extensive government contracts, including supply for signaling and the TWX , while competitors like Kleinschmidt captured specialized niches. This concentration supported national infrastructure, with Teletype fulfilling orders for thousands of units annually for federal agencies and utilities.

European Companies

Creed & Company, founded in 1912 by Canadian inventor Frederick George Creed and Danish engineer Harald Bille in , , emerged as a key British pioneer in teleprinter technology, initially focusing on perforated tape systems for automated transmission before shifting to page-printing models. The company's Model 7, introduced in the early as a page-printing teleprinter operating at 50 baud (approximately 66 words per minute), became a cornerstone for the UK's inland service managed by the General (GPO), enabling efficient telegram transmission across domestic networks. During , the Model 7B variant saw extensive deployment by the Royal Air Force (RAF) for secure communications, including at codebreaking sites like , where it facilitated rapid message relay in military operations. In , , established in the mid-19th century but active in advancements, developed early teletypewriters in the , with significant production ramping up in to support national communication infrastructure. The company introduced its first commercial teletype model around 1930, contributing to the buildup of networks that integrated teleprinters into business and governmental systems across . Post-World War II, Siemens launched the T100 series in 1958, a compact teleprinter compliant with start-stop signaling standards, which became widely used in rebuilt European infrastructures for its reliability in point-to-point messaging at speeds up to 50 baud. Italian firm , renowned for office machinery since the early , expanded into teleprinters during and , producing electric models that integrated seamlessly with typing and accounting systems tailored for commercial environments. These devices, such as early electric teleprinters, emphasized ergonomic keyboards and adaptations for Romance accents, enhancing in Mediterranean markets and supporting office workflows in banking and administration. Olivetti's contributions focused on modular designs that combined printing with , influencing post-war European business communications. In , Gretag AG, founded by Edgar Gretener, specialized in precision teleprinter systems post-World War II, with the ETK-47 model developed in 1947 marking a breakthrough in lightweight, segmented construction for high-reliability transmission. This 14-bit teleprinter, operating via single-tone signaling, was particularly valued for military applications, pairing with devices like the TC-53 for secure field communications in the Swiss and exported variants. Gretag's high-speed iterations in the emphasized durability and low noise, aiding neutral Switzerland's role in international telecom standards. European teleprinter manufacturing underwent significant post-war recovery, driven by reconstruction efforts and adherence to CCITT (International Telegraph and Telephone Consultative Committee) protocols, which standardized 5- and 6-unit codes for across borders. Companies like collaborated on CCITT-compliant designs, such as enhanced rates and error detection, facilitating exports to former colonies in and as advanced telecom independence. This regional focus on customization—incorporating multilingual keyboards and robust mechanics—distinguished European firms from mass-produced American models, bolstering adoption in diverse imperial and emerging networks until the 1960s.

Decline and Legacy

Factors of Obsolescence

The decline of teleprinters began in the as technological advancements introduced superior alternatives that addressed their mechanical limitations, such as slow printing speeds and paper dependency. (CRT) terminals emerged as a primary replacement, offering faster display rates—up to 240 characters per second compared to teleprinters' typical 10 characters per second—and greater reliability without mechanical wear. These "glass teletypes" enabled real-time interaction and editing, capturing a lucrative market segment previously dominated by teleprinters, with independent manufacturers aggressively targeting Teletype Corporation's customer base. Simultaneously, the development of from 1969 and the invention of network email in 1971 facilitated paperless, asynchronous messaging over distributed networks, gradually supplanting teleprinter-based systems for data exchange in research and military applications. By the late , facsimile technology, which supported graphical transmission at higher speeds, began eroding teleprinter use in business communications, as machines became more affordable and versatile for document sharing. Economic pressures further accelerated , stemming from teleprinters' inherent design flaws in an era of advancing . Operating at standard speeds of 110 , teleprinters lagged behind early modems achieving 300 or more, resulting in inefficient data transfer for growing computational needs. High maintenance costs arose from their electromechanical components, including frequent repairs for typebars, motors, and paper mechanisms, which contrasted sharply with the lower upkeep of solid-state CRTs and modems. through integrated circuits and electronic components enabled compact, desk-friendly devices that reduced space requirements and operational expenses, making bulky teleprinters—often weighing over 100 pounds—impractical for modern offices. Key events in the marked the tipping point for teleprinter networks. systems, a major teleprinter application, reached peak domestic usage around 1986 before plummeting due to adoption and economic downturns like the early- oil industry collapse, which curtailed international messaging volumes. The divestiture on January 1, 1984, dismantled the monopoly, ending subsidized support for legacy services like the Teletypewriter Exchange (TWX)—sold to in 1969 but reliant on infrastructure—and accelerating the shift to competitive alternatives. In publishing, the 1985 release of Aldus PageMaker software ushered in , devastating teletypesetter (TTS) systems used for news wire composition by enabling direct layout on personal computers, which bypassed mechanical tape and hot-metal . Environmental concerns also contributed to teleprinters' disfavor, as their operation generated substantial paper waste from continuous rolls, exacerbating and burdens in an era of rising ecological awareness. Each teleprinter session consumed yards of paper, often discarded after single use, while the devices' mechanical clatter—reaching levels disruptive to office environments—added to , prompting preferences for silent electronic displays. By the , teleprinters had become rare in business settings, confined to niche legacy operations as manufacturers like ceased production in 1990 amid plummeting demand. Into the 2000s, surviving units were primarily artifacts or hobbyist restorations, symbolizing an era overtaken by communication.

Modern Relevance and Preservation

Teleprinters maintain niche applications in contemporary settings, particularly within amateur radio communities where radioteletype (RTTY) digital modes enable text-based communication over shortwave frequencies. Enthusiasts participate in events like the ARRL RTTY Roundup, which continues annually as of 2025, allowing operators to exchange messages using software-defined radios interfaced with computer-based teleprinter emulations or restored hardware. In accessibility technology, variants of teleprinters persist as telecommunications devices for the deaf (TDD) or teletypewriters (TTY), facilitating text-based telephone communication for individuals with hearing or speech impairments. These ASCII-based systems, originally derived from teleprinters, connect via acoustic couplers or modern adapters to standard phone lines, with services bridging calls between TTY users and voice callers; usage remains supported by federal mandates as of 2025, including a November 2025 FCC proposal to modernize services (TRS). Teleprinters also feature prominently in museum exhibits, such as the Computer History Museum's of a Dartmouth time-sharing system teleprinter, which illustrates early interactive computing from the 1960s and underscores the device's role in transitioning from to user interfaces. Adaptations for retro computing have extended teleprinter longevity through modern interfaces, including USB adapters that allow mechanical units like the Model 19 or ASR-33 to function as peripherals for personal computers. For instance, microcontroller-based solutions using Teensy boards or convert the teleprinter's current-loop signals to USB serial, enabling operation with contemporary operating systems for tasks like printing outputs. Software emulators further support preservation by simulating teleprinter behavior on systems; the ttyemu project replicates the ASR-33's operation, including handling and mechanical sound effects via or frontends, allowing users to experience historical terminals without physical hardware. Teleprinters hold cultural significance in media and education, appearing in films like (2014), where they represent wartime code-breaking communications at , highlighting the device's role in relaying decrypted and Lorenz messages. In educational contexts, teleprinters exemplify the origins of digital text transmission, featured in curricula on computing history to demonstrate precursors to modern networking and ASCII standards. The collector market sustains interest, with vintage units such as Model 15 or 33 teleprinters selling on platforms like for $100 to $500 depending on condition and completeness, while rarer models like the Model 26 can fetch up to $2,000 among enthusiasts restoring them for display or functional use. Preservation efforts are driven by dedicated hobbyists and institutions, with online communities sharing restoration guides for models, including disassembly and lubrication techniques to revive mechanical printers from the mid-20th century. Notable projects include ongoing work on WWII-era Lorenz SZ-40 teleprinters, with museums acquiring parts as recently as 2016 to reconstruct functional examples for exhibits on ; by 2025, these align with renewed interest in Colossus-era technology. Archival patents, such as those filed by in for printing mechanisms, are digitized and accessible through repositories like the USPTO, aiding authentic restorations. Looking ahead, teleprinters influence niche text-display devices in low-bandwidth environments, but no mainstream revival is anticipated due to superior digital alternatives like and .

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