A report on Morse code and Electrical telegraph

Chart of the Morse code 26 letters and 10 numerals

Cooke and Wheatstone's five-needle telegraph from 1837

This Morse key was originally used by Gotthard railway, later by a shortwave radio amateur

Hughes telegraph, an early (1855) teleprinter built by Siemens and Halske

Telegraph key and sounder. The signal is "on" when the knob is pressed, and "off" when it is released. Length and timing of the dits and dahs are entirely controlled by the telegraphist.

Morse code receiver, recording on paper tape

Revolving alphanumeric dial created by Francis Ronalds as part of his electric telegraph (1816)

Comparison of historical versions of Morse code with the current standard. Left: Later American Morse code from 1844. Center: The modified and rationalized version used by Friedrich Gerke on German railways. Right: Current ITU standard.

Pavel Schilling, an early pioneer of electrical telegraphy

A U.S. Navy Morse Code training class in 2015. The sailors will use their new skills to collect signals intelligence.

Diagram of alphabet used in a 5-needle Cooke and Wheatstone Telegraph, indicating the letter G

A commercially manufactured iambic paddle used in conjunction with an electronic keyer to generate high-speed Morse code, the timing of which is controlled by the electronic keyer.

A U.S. Navy signalman sends Morse code signals in 2005.

GWR Cooke and Wheatstone double needle telegraph instrument

A magneto-powered Wheatstone A. B. C. telegraph with the horizontal "communicator" dial, the inclined "indicator" dial and crank handle for the magneto that generated the electrical signal.

Professor Morse sending the message – WHAT HATH GOD WROUGHT on 24 May 1844

Foy–Breguet telegraph displaying the letter "Q"

Graphical representation of the dichotomic search table. The graph branches left for each dot and right for each dash until the character representation is exhausted.

Wheatstone automated telegraph network equipment

Scout movement founder Baden-Powell's mnemonic chart from 1918

Phelps' Electro-motor Printing Telegraph from circa 1880, the last and most advanced telegraphy mechanism designed by George May Phelps

Teletype Model 33 ASR (Automatic Send and Receive)

The Eastern Telegraph Company network in 1901

German Lorenz SZ42 teleprinter attachment (left) and Lorenz military teleprinter (right) at The National Museum of Computing on Bletchley Park, England

Morse code is named after Samuel Morse, one of the inventors of the telegraph.

- Morse code

At the sending station, an operator would tap on a switch called a telegraph key, spelling out text messages in Morse code.

- Electrical telegraph

7 related topics with Alpha

Replica of Claude Chappe's optical telegraph on the Litermont near Nalbach, Germany

Telegraphy

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Long-distance transmission of messages where the sender uses symbolic codes, known to the recipient, rather than a physical exchange of an object bearing the message.

Schematic of a Prussian optical telegraph (or semaphore) tower, c. 1835

19th-century demonstration of the semaphore

Cooke and Wheatstone's five-needle, six-wire telegraph (1837)

An early Cooke and Wheatstone double-needle railway telegraph instrument at the National Railway Museum

A block signalling instrument as used in Britain in the 20th century

Australian troops using a Mance mk.V heliograph in the Western Desert in November 1940

US Forest Service lookout using a Colomb shutter type heliograph in 1912 at the end of a telephone line

Creed paper tape reader at The National Museum of Computing

The first message is received by the Submarine Telegraph Company in London from Paris on the Foy–Breguet instrument in 1851. The equipment in the background is a Cooke and Wheatstone set for onward transmission.

Alexander Bain's facsimile machine, 1850

Marconi watching associates raising the kite (a "Levitor" by B.F.S. Baden-Powell ) used to lift the antenna at St. John's, Newfoundland, December 1901

Post Office Engineers inspect the Marconi Company's equipment at Flat Holm, May 1897

ITT Creed Model 23B teleprinter with telex dial-up facility

An illustration declaring that the submarine cable between England and France would bring those countries peace and goodwill

The electric telegraph started to replace the optical telegraph in the mid-19th century.

The Morse system was adopted as the international standard in 1865, using a modified Morse code developed in Germany in 1848.

A US Army Signal Corps radio operator in 1943 in New Guinea transmitting by radiotelegraphy

Wireless telegraphy

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Amateur radio operator transmitting Morse code

Tesla's explanation in the 1919 issue of "Electrical Experimenter" on how he thought his wireless system would work

Thomas Edison's 1891 patent for a ship-to-shore wireless telegraph that used electrostatic induction

Example of transatlantic radiotelegraph message recorded on paper tape at RCA's New York receiving center in 1920. The translation of the Morse code is given below the tape.

In World War I balloons were used as a quick way to raise wire antennas for military field radiotelegraph stations. Balloons at Tempelhofer Field, Germany, 1908.

Guglielmo Marconi, the father of radio-based wireless telegraphy, in 1901, with one of his first wireless transmitters (right) and receivers (left)

German troops erecting a wireless field telegraph station during World War I

German officers and troops manning a wireless field telegraph station during World War I

Mobile radio station in German South West Africa, using a hydrogen balloon to lift the antenna

Wireless telegraphy or radiotelegraphy is transmission of telegraph signals by radio waves.

In radiotelegraphy, information is transmitted by pulses of radio waves of two different lengths called "dots" and "dashes", which spell out text messages, usually in Morse code.

Samuel Morse

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American inventor and painter.

Birthplace of Morse, Charlestown, Massachusetts, c. 1898 photo

Daguerreotype of Samuel Morse Professor of Art while at NYU in 1839. One of the earliest existing American photographs by Dr John William Draper

Self-portrait of Morse in 1812 (National Portrait Gallery)

Dying Hercules, Morse's early masterpiece

Jonas Platt, New York politician, by Morse. Oil on canvas, 1828, Brooklyn Museum.

The House of Representatives. Oil on canvass, 1822, National Gallery of Art.

Morse maintained a studio at 94 Tradd St., Charleston, South Carolina, for a short period.

Leonard Gale, who helped Morse achieve the technological breakthrough of getting the telegraphic signal to travel long distances over wire

Cover of Foreign Conspiracy Against the Liberties of the United States by Samuel F.B. Morse, 1835 edition

Morse's "repeater" circuit for telegraphy was the basis for the Supreme Court's holding some claims of Morse's patent valid.

Portrait of Samuel F. B. Morse taken by Mathew Brady, in 1866. Medals worn (from wearer's right to left, top row): Nichan Iftikhar (Ottoman); Order of the Tower and Sword (Portugal); Order of the Dannebrog (Denmark); cross of the Order of Isabella the Catholic (Spain); Legion of Honour (France); Order of Saints Maurice and Lazarus (Italy). Bottom row: Grand cross of the Order of Isabella the Catholic (Spain)

Statue of Samuel F. B. Morse by Byron M. Picket, New York's Central Park, dedicated 1871

Morse was honored on the US Famous Americans Series postal issue of 1940.

Captain Demaresque of Gloucester, Massachusetts, Princeton University Art Museum

Portrait of James Monroe, 5th President of the United States (c. 1819)

Eli Whitney, inventor, 1822. Yale University Art Gallery

Chart of Colors, drawn to illustrate his palette of colors

After having established his reputation as a portrait painter, in his middle age Morse contributed to the invention of a single-wire telegraph system based on European telegraphs.

He was a co-developer of Morse code and helped to develop the commercial use of telegraphy.

Telegraph key

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a Wright Brothers telegraph key (missing its knob)

Early "bug" telegraph key invented in 1913 by Weston Hadden

Electronic dual paddle keyer (homemade in 1972)

A telegraph key is a specialized electrical switch used by a trained operator to transmit text messages in Morse code in a telegraphy system.

Keys are used in all forms of electrical telegraph systems, including landline (also called wire) telegraphy and "wireless" and radio (also called wireless) telegraphy.

Earth station at the satellite communication facility in Raisting, Bavaria, Germany

Telecommunications

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Transmission of information by various types of technologies over wire, radio, optical, or other electromagnetic systems.

Visualization from the Opte Project of the various routes through a portion of the Internet

A replica of one of Chappe's semaphore towers

Optical fiber provides cheaper bandwidth for long-distance communication.

Digital television standards and their adoption worldwide

20th- and 21st-century technologies for long-distance communication usually involve electrical and electromagnetic technologies, such as telegraph, telephone, television and teleprinter, networks, radio, microwave transmission, optical fiber, and communications satellites.

His code was an important advance over Wheatstone's signaling method.

Telegraph sounder

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A telegraph sounder is an antique electromechanical device used as a receiver on electrical telegraph lines during the 19th century.

When a telegraph message comes in it produces an audible "clicking" sound representing the short and long keypresses – "dots" and "dashes" – which are used to represent text characters in Morse code.

1911 Chart of the Standard American Morse Characters

American Morse code

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The first public telegram in America, "What hath God wrought" sent by Samuel Morse in 1844.

American Morse Code — also known as Railroad Morse—is the latter-day name for the original version of the Morse Code developed in the mid-1840s, by Samuel Morse and Alfred Vail for their electric telegraph.