DOCSLIB.ORG

Microphone (Edited from Wikipedia)

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text

Load more

Microphone (Edited from Wikipedia) SUMMARY A microphone, colloquially nicknamed mic or mike, is a transducer that converts sound into an electrical signal. Microphones are used in many applications such as telephones, hearing aids, public address systems for concert halls and public events, motion picture production, live and recorded audio engineering, sound recording, two-way radios, megaphones, radio and television broadcasting, and in computers for recording voice, speech recognition, VoIP, and for non-acoustic purposes such as ultrasonic sensors or knock sensors. Several different types of microphone are in use, which employ different methods to convert the air pressure variations of a sound wave to an electrical signal. The most common are the dynamic microphone, which uses a coil of wire suspended in a magnetic field; the condenser microphone, which uses the vibrating diaphragm as a capacitor plate, and the piezoelectric microphone, which uses a crystal of piezoelectric material. Microphones typically need to be connected to a preamplifier before the signal can be recorded or reproduced. HISTORY In order to speak to larger groups of people, a need arose to increase the volume of the human voice. The earliest devices used to achieve this were acoustic megaphones. Some of the first examples, from fifth century BC Greece, were theater masks with horn- shaped mouth openings that acoustically amplified the voice of actors in amphitheatres. In 1665, the English physicist Robert Hooke was the first to experiment with a medium other than air with the invention of the "lovers' telephone" made of stretched wire with a cup attached at each end. Charles Wheatstone invented an early modern microphone. He invented the term “microphone,” even though his version doesn’t resemble the modern conception of the microphone today. German inventor Johann Philipp Reis designed an early sound transmitter that used a metallic strip attached to a vibrating membrane that would produce intermittent 1 current. Better results were achieved with the "liquid transmitter" design in Scottish- American Alexander Graham Bell's telephone of 1876 – the diaphragm was attached to a conductive rod in an acid solution. These systems, however, gave a very poor sound quality. The first microphone that enabled proper voice telephony was the (loose-contact) carbon microphone. This was independently developed by David Edward Hughes in England and Emile Berliner and Thomas Edison in the US. Although Edison was awarded the first patent (after a long legal dispute) in mid-1877, Hughes had demonstrated his working device in front of many witnesses some years earlier, and most historians credit him with its invention. The carbon microphone is the direct prototype of today's microphones and was critical in the development of telephony, broadcasting and the recording industries. Thomas Edison refined the carbon microphone into his carbon-button transmitter of 1886. This microphone was employed at the first ever radio broadcast, a performance at the New York Metropolitan Opera House in 1910. In 1916, E.C. Wente of Western Electric developed the next breakthrough with the first condenser microphone. In 1923, the first practical moving coil microphone was built. "The Marconi Skykes" or "magnetophon", developed by Captain H. J. Round, was the standard for BBC studios in London. This was improved in 1930 by Alan Blumlein and Herbert Holman who released the HB1A and was the best standard of the day. Also in 1923, the ribbon microphone was introduced, another electromagnetic type, believed to have been developed by Harry F. Olson, who essentially reverse-engineered a ribbon speaker. Over the years these microphones were developed by several companies, most notably RCA that made large advancements in pattern control, to give the microphone directionality. With television and film technology booming there was demand for high fidelity microphones and greater directionality. Electro-Voice responded with their Academy Award-winning shotgun microphone in 1963. The latest research developments include the use of fibre optics, lasers and interferometers. 2 DYNAMIC MICROPHONES The dynamic microphone (also known as the moving-coil microphone) works via electromagnetic induction. They are robust, relatively inexpensive and resistant to moisture. This, coupled with their potentially high gain before feedback, makes them ideal for on-stage use. Dynamic microphones use the same dynamic principle as in a loudspeaker, only reversed. A small movable induction coil, positioned in the magnetic field of a permanent magnet, is attached to the diaphragm. When sound enters through the windscreen of the microphone, the sound wave moves the diaphragm. When the diaphragm vibrates, the coil moves in the magnetic field, producing a varying current in the coil through electromagnetic induction. A single dynamic membrane does not respond linearly to all audio frequencies. For this reason some microphones utilize multiple membranes for the different parts of the audio spectrum and then combine the resulting signals. Combining the multiple signals correctly is difficult and designs that do this are rare and tend to be expensive. CHARLES WHEATSTONE Charles Wheatstone was born in Barnwood, Gloucester, in England in 1802. His father was a music-seller in the town, who moved to London, four years later, becoming a teacher of the flute. Charles, the second son, went to a village school, near Gloucester, and afterwards to several institutions in London. One of them was in Kennington, and kept by a Mrs. Castlemaine, who was astonished at his rapid progress. From another he ran away, but was captured at Windsor. As a boy he was very shy and sensitive, preferring to retire into an attic, without any other company than his own thoughts. When he was about fourteen years old he was apprenticed to his uncle and namesake, a maker and seller of musical instruments in London; but he showed little taste for handicraft or business, and loved better to study books. His father encouraged him in this, and finally took him out of the uncle's charge. At the age of fifteen, Wheatstone translated French poetry, and wrote two songs, one of which was given to his uncle, who published it without knowing it as his nephew's composition. Some lines of his on the lyre became the motto of an engraving by Bartolozzi. Small for his age, but with a fine brow, and intelligent blue eyes, he often visited an old book-stall in the vicinity of Pall Mall, which was then a dilapidated and unpaved thoroughfare. 3 Most of his pocket-money was spent in purchasing the books which had taken his fancy, whether fairy tales, history, or science. One day, to the surprise of the bookseller, he coveted a volume on the discoveries of Volta in electricity, but not having the price, he saved his pennies and secured the volume. It was written in French, and so he was obliged to save again, until he could buy a dictionary. Then he began to read the volume, and, with the help of his elder brother, William, to repeat the experiments described in it, with a home-made battery, in the scullery behind his father's house. In constructing the battery, the boy philosophers ran short of money to procure the requisite copper-plates. They had only a few copper coins left. A happy thought occurred to Charles, who was the leading spirit in these researches, 'We must use the pennies themselves,' said he, and the battery was soon complete. In September 1821, Wheatstone brought himself into public notice by exhibiting the 'Enchanted Lyre,' or 'Aconcryptophone,' at a music-shop at Pall Mall and in the Adelaide Gallery. It consisted of a mimic lyre hung from the ceiling by a cord, and emitting the strains of several instruments – the piano, harp, and dulcimer. In reality it was a mere sounding box, and the cord was a steel rod that conveyed the vibrations of the music from the several instruments which were played out of sight and ear-shot. At this period Wheatstone made numerous experiments on sound and its transmission. Besides transmitting sounds to a distance, Wheatstone devised a simple instrument for augmenting feeble sounds, to which he gave the name of 'Microphone.' It consisted of two slender rods, which conveyed the mechanical vibrations to both ears, and is quite different from the electrical microphone of Professor Hughes. 4.
Recommended publications
  • Army Radio Communication in the Great War Keith R Thrower, OBE

    Army Radio Communication in the Great War Keith R Thrower, OBE

    Army radio communication in the Great War Keith R Thrower, OBE Introduction Prior to the outbreak of WW1 in August 1914 many of the techniques to be used in later years for radio communications had already been invented, although most were still at an early stage of practical application. Radio transmitters at that time were predominantly using spark discharge from a high voltage induction coil, which created a series of damped oscillations in an associated tuned circuit at the rate of the spark discharge. The transmitted signal was noisy and rich in harmonics and spread widely over the radio spectrum. The ideal transmission was a continuous wave (CW) and there were three methods for producing this: 1. From an HF alternator, the practical design of which was made by the US General Electric engineer Ernst Alexanderson, initially based on a specification by Reginald Fessenden. These alternators were primarily intended for high-power, long-wave transmission and not suitable for use on the battlefield. 2. Arc generator, the practical form of which was invented by Valdemar Poulsen in 1902. Again the transmitters were high power and not suitable for battlefield use. 3. Valve oscillator, which was invented by the German engineer, Alexander Meissner, and patented in April 1913. Several important circuits using valves had been produced by 1914. These include: (a) the heterodyne, an oscillator circuit used to mix with an incoming continuous wave signal and beat it down to an audible note; (b) the detector, to extract the audio signal from the high frequency carrier; (c) the amplifier, both for the incoming high frequency signal and the detected audio or the beat signal from the heterodyne receiver; (d) regenerative feedback from the output of the detector or RF amplifier to its input, which had the effect of sharpening the tuning and increasing the amplification.
  • Electret Microphone Replacement for a Carbon Insert

    Electret Microphone Replacement for a Carbon Insert

    The VMARS Newsletter Issue 29 Electret microphone replacement for a carbon insert Colin Guy G4DDI When I found that I had a dud carbon insert in an H33F/PT handset, and I couldn’t find another insert that fitted (the original is about 1” diameter) I looked around for an alternative. Trevor Sanderson’s excellent article “The RAF Microphone” (Radio Bygones issue 79/80) makes reference to the use of electret inserts with an IC preamplifier in telephones and aircraft headsets, but the information given was too scant to make construction of one of these possible without reference to the IC data sheet, and the IC’s are expensive and difficult to obtain. I had a GPO type 21A insert, but the innards of this when dismantled were still too large to fit into the available space. The H33 handset is very slim, and also virtually solid, so there is very little room in which to place a preamplifier. A dig around on the internet turned up the following article written by F. Hueber, originally published in Elektor Electronics December 1994, and is published here with permission from Elektor Electronics magazine, December 1994, copyright Segment B.V., Beek (Lb.), The Netherlands, www.segment.nl. The original article included a pcb layout, but I built mine on a strip of veroboard four tracks wide by about 2” (see photo) and mounted it on the back of the ptt switch. The electret insert was acquired from a scrap telephone and all the rest of the components from TV panels. To save space the rectifier and R12 weren’t included, care being taken to ensure that the polarity was correct.
  • The Stage Is Set

    The Stage Is Set

    The Stage Is Set: Developments before 1900 Leading to Practical Wireless Communication Darrel T. Emerson National Radio Astronomy Observatory1, 949 N. Cherry Avenue, Tucson, AZ 85721 In 1909, Guglielmo Marconi and Carl Ferdinand Braun were awarded the Nobel Prize in Physics "in recognition of their contributions to the development of wireless telegraphy." In the Nobel Prize Presentation Speech by the President of the Royal Swedish Academy of Sciences [1], tribute was first paid to the earlier theorists and experimentalists. “It was Faraday with his unique penetrating power of mind, who first suspected a close connection between the phenomena of light and electricity, and it was Maxwell who transformed his bold concepts and thoughts into mathematical language, and finally, it was Hertz who through his classical experiments showed that the new ideas as to the nature of electricity and light had a real basis in fact.” These and many other scientists set the stage for the rapid development of wireless communication starting in the last decade of the 19th century. I. INTRODUCTION A key factor in the development of wireless communication, as opposed to pure research into the science of electromagnetic waves and phenomena, was simply the motivation to make it work. More than anyone else, Marconi was to provide that. However, for the possibility of wireless communication to be treated as a serious possibility in the first place and for it to be able to develop, there had to be an adequate theoretical and technological background. Electromagnetic theory, itself based on earlier experiment and theory, had to be sufficiently developed that 1.
  • Alexander Graham Bell 1847-1922

    Alexander Graham Bell 1847-1922

    NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA BIOGRAPHICAL MEMOIRS VOLUME XXIII FIRST MEMOIR BIOGRAPHICAL MEMOIR OF ALEXANDER GRAHAM BELL 1847-1922 BY HAROLD S. OSBORNE PRESENTED TO THE ACADEMY AT THE ANNUAL MEETING, 1943 It was the intention that this Biographical Memoir would be written jointly by the present author and the late Dr. Bancroft Gherardi. The scope of the memoir and plan of work were laid out in cooperation with him, but Dr. Gherardi's untimely death prevented the proposed collaboration in writing the text. The author expresses his appreciation also of the help of members of the Bell family, particularly Dr. Gilbert Grosvenor, and of Mr. R. T. Barrett and Mr. A. M. Dowling of the American Telephone & Telegraph Company staff. The courtesy of these gentlemen has included, in addition to other help, making available to the author historic documents relating to the life of Alexander Graham Bell in the files of the National Geographic Society and in the Historical Museum of the American Telephone and Telegraph Company. ALEXANDER GRAHAM BELL 1847-1922 BY HAROLD S. OSBORNE Alexander Graham Bell—teacher, scientist, inventor, gentle- man—was one whose life was devoted to the benefit of mankind with unusual success. Known throughout the world as the inventor of the telephone, he made also other inventions and scientific discoveries of first importance, greatly advanced the methods and practices for teaching the deaf and came to be admired and loved throughout the world for his accuracy of thought and expression, his rigid code of honor, punctilious courtesy, and unfailing generosity in helping others.
  • The Electric Telegraph

    The Electric Telegraph

    To Mark, Karen and Paul CONTENTS page ORIGINS AND DEVELOPMENTS TO 1837 13 Early experiments—Francis Ronalds—Cooke and Wheatstone—successful experiment on the London & Birmingham Railway 2 `THE CORDS THAT HUNG TAWELL' 29 Use on the Great Western and Blackwall railways—the Tawell murder—incorporation of the Electric Tele- graph Company—end of the pioneering stage 3 DEVELOPMENT UNDER THE COMPANIES 46 Early difficulties—rivalry between the Electric and the Magnetic—the telegraph in London—the overhouse system—private telegraphs and the press 4 AN ANALYSIS OF THE TELEGRAPH INDUSTRY TO 1868 73 The inland network—sources of capital—the railway interest—analysis of shareholdings—instruments- working expenses—employment of women—risks of submarine telegraphy—investment rating 5 ACHIEVEMENT IN SUBMARINE TELEGRAPHY I o The first cross-Channel links—the Atlantic cable— links with India—submarine cable maintenance com- panies 6 THE CASE FOR PUBLIC ENTERPRISE 119 Background to the nationalisation debate—public attitudes—the Edinburgh Chamber of Commerce— Frank Ives. Scudamore reports—comparison with continental telegraph systems 7 NATIONALISATION 1868 138 Background to the Telegraph Bill 1868—tactics of the 7 8 CONTENTS Page companies—attitudes of the press—the political situa- tion—the Select Committee of 1868—agreement with the companies 8 THE TELEGRAPH ACTS 154 Terms granted to the telegraph and railway companies under the 1868 Act—implications of the 1869 telegraph monopoly 9 THE POST OFFICE TELEGRAPH 176 The period 87o-1914—reorganisation of the
  • The Otranto-Valona Cable and the Origins of Submarine Telegraphy in Italy

    The Otranto-Valona Cable and the Origins of Submarine Telegraphy in Italy

    Advances in Historical Studies, 2017, 6, 18-39 http://www.scirp.org/journal/ahs ISSN Online: 2327-0446 ISSN Print: 2327-0438 The Otranto-Valona Cable and the Origins of Submarine Telegraphy in Italy Roberto Mantovani Department of Pure and Applied Sciences (DiSPeA), Physics Laboratory: Urbino Museum of Science and Technology, University of Urbino Carlo Bo, Urbino, Italy How to cite this paper: Mantovani, R. Abstract (2017). The Otranto-Valona Cable and the Origins of Submarine Telegraphy in Italy. This work is born out of the accidental finding, in a repository of the ancient Advances in Historical Studies, 6, 18-39. “Oliveriana Library” in the city of Pesaro (Italy), of a small mahogany box https://doi.org/10.4236/ahs.2017.61002 containing three specimens of a submarine telegraph cable built for the Italian Received: December 22, 2016 government by the Henley Company of London. This cable was used to con- Accepted: March 18, 2017 nect, by means of the telegraph, in 1864, the Ports of Otranto and Avlona (to- Published: March 21, 2017 day Valona, Albania). As a scientific relic, the Oliveriana memento perfectly fits in the scene of that rich chapter of the history of long distance electrical Copyright © 2017 by author and Scientific Research Publishing Inc. communications known as submarine telegraphy. It is known that, thanks to This work is licensed under the Creative the English, the issue of submarine electric communication had an impressive Commons Attribution International development in Europe from the second half of the nineteenth century on. License (CC BY 4.0). Less known is the fact that, in this emerging technology field, Italy before uni- http://creativecommons.org/licenses/by/4.0/ fication was able to carve out a non-negligible role for itself, although primar- Open Access ily political.
  • The Early Years of the Telephone

    The Early Years of the Telephone

    ©2012 JSR The early years of the telephone The early years of the telephone John S. Reid Before Bell Ask who invented the telephone and most people who have an answer will reply Alexander Graham Bell, and probably clock it up as yet another invention by a Scotsman that was commercialised beyond our borders. Like many one line summaries, this is partly true but it credits to one person much more than he really deserves. Bell didn’t invent the word, he didn’t invent the concept, what ever the patent courts decreed, and actually didn’t invent most of the technology needed to turn the telephone into a business or household reality. He did, though, submit a crucial patent at just the right time in 1876, find backers to develop his concept, promoted his invention vigorously and pursued others through the courts to establish close to a monopoly business that made him and a good many others very well off. So, what is the fuller story of the early years of the telephone? In the 1820s, Charles Wheatstone who would later make a big name for himself as an inventor of telegraphy equipment invented a device he called a ‘telephone’ for transmitting music from one room to the next. It was not electrical but relied on conducting sound through a rod. In the same decade he also invented a device he called a ‘microphone’, for listening to faint sounds, but again it was not electrical. In succeeding decades quite a number of different devices by various inventors were given the name ‘telephone’.
  • Morse Code (Edited from Wikipedia)

    Morse Code (Edited from Wikipedia)

    Morse Code (Edited from Wikipedia) SUMMARY Morse code is a method of transmitting text information as a series of on-off tones, lights, or clicks that can be directly understood by a skilled listener or observer without special equipment. It is named for Samuel F. B. Morse, an inventor of the telegraph. The International Morse Code encodes the ISO basic Latin alphabet, some extra Latin letters, the Arabic numerals and a small set of punctuation and procedural signals (prosigns) as standardized sequences of short and long signals called "dots" and "dashes", or "dits" and "dahs", as in amateur radio practice. Because many non-English natural languages use more than the 26 Roman letters, extensions to the Morse alphabet exist for those languages. Each Morse code symbol represents either a text character (letter or numeral) or a prosign and is represented by a unique sequence of dots and dashes. The duration of a dash is three times the duration of a dot. Each dot or dash is followed by a short silence, equal to the dot duration. The letters of a word are separated by a space equal to three dots (one dash), and the words are separated by a space equal to seven dots. The dot duration is the basic unit of time measurement in code transmission. To increase the speed of the communication, the code was designed so that the length of each character in Morse is shorter the more frequently it is used in the language. Thus the most common letter in English, the letter "E", has the shortest code, a single dot.
  • Method of Accommodating for Carbon/Electret Telephone Set Variability in Automatic Speaker Verification

    Method of Accommodating for Carbon/Electret Telephone Set Variability in Automatic Speaker Verification

    Europaisches Patentamt 19 European Patent Office Office europeen des brevets © Publication number: 0 654 781 A2 12 EUROPEAN PATENT APPLICATION @ Application number: 94308231.3 @ Int. CI.6: G10L 5/06 (22) Date of filing : 09.11.94 (So) Priority: 19.11.93 US 155973 @ Inventor: Sachs, Richard M. 64 Sunset Place @ Date of publication of application : Middletown, New Jersey 07748 (US) 24.05.95 Bulletin 95/21 Inventor : Schoeffler, Max S. 17 Kenwood Lane @ Designated Contracting States : Matawan, New Jersey 07747 (US) DE ES FR GB IT (74) Representative : Watts, Christopher Malcolm @ Applicant : AT & T Corp. Kelway, Dr. et al 32 Avenue of the Americas AT&T (UK) Ltd. New York, NY 10013-2412 (US) 5, Mornington Road Woodford Green Essex, IG8 0TU (GB) (S) Method of accommodating for carbon/electret telephone set variability in automatic speaker verification. In verification method of (57) a speaker system, a FIG. 6 compensating for differences in speech sam- ples obtained during registration and those obtained during verification due to the use of VERIFICATION (4-WAY) different types of microphones is provided by ,601 at least of the such that filtering one samples PROMPT the similarities of the two samples are in- creased. The filtered sample is used within the ,604 speaker verification matching process. A two- RECEIVE VERIFICATION way comparison is disclosed in which both a SPEECH SAMPLE verification speech sample and a reference sample are filtered with nonlinear microphone r609 ,606 characteristics such as carbon microphone PRODUCE CARBON characteristics. A is also VERIFICATION FILTER four-way comparison PATTERN SAMPLE disclosed in which patterns produced from un- filtered verification and reference samples and 611 from the filtered verification PRODUCE CARBON patterns produced FILTERED and reference samples are compared to identify VERIFICATION a match.
  • The History of the Telephone

    The History of the Telephone

    THE HISTORY OF THE TELEPHONE BY HERBERT N. CASSON First edition A. C. McClurg & Co. Chicago Published: 1910 PREFACE Thirty-five short years, and presto! the newborn art of telephony is fullgrown. Three million telephones are now scattered abroad in foreign countries, and seven millions are massed here, in the land of its birth. So entirely has the telephone outgrown the ridicule with which, as many people can well remember, it was first received, that it is now in most places taken for granted, as though it were a part of the natural phenomena of this planet. It has so marvelously extended the facilities of conversation--that "art in which a man has all mankind for competitors"--that it is now an indispensable help to whoever would live the convenient life. The disadvantage of being deaf and dumb to all absent persons, which was universal in pre-telephonic days, has now happily been overcome; and I hope that this story of how and by whom it was done will be a welcome addition to American libraries. It is such a story as the telephone itself might tell, if it could speak with a voice of its own. It is not technical. It is not statistical. It is not exhaustive. It is so brief, in fact, that a second volume could readily be made by describing the careers of telephone leaders whose names I find have been omitted unintentionally from this book--such indispensable men, for instance, as William R. Driver, who has signed more telephone cheques and larger ones than any other man; Geo.
  • Microwave Engineering and Systems Applications

    Microwave Engineering and Systems Applications

    Microwave Engineering and Systems Applications Edward A. Wolff Roger Kaul WILEY A WILEY-INTERSCIENCE PUBLICATION JOHN WILEY & SONS New York • Chichester • Brisbane • Toronto • Singapore Contributors J. Douglas Adam (Chapter 10, co-author), Westinghouse Research Labo­ ratories, Pittsburgh, Pennsylvania David Blough (Chapter 22, co-author), Westinghouse Electric Co., Balti­ more, Maryland Michael C. Driver (Chapter 16), Westinghouse Research Laboratories, Pittsburgh, Pennsylvania Albert W. Friend (Chapter 5), Space and Naval Warfare Systems Com­ mand, Washington, D.C. Robert V. Garver (Chapters 6, 9, and 12; Chapter 10, co-author), Harry Diamond Laboratories, Adelphi, Maryland William E. Hosey (Chapter 17; Chapter 22, co-author), Westinghouse Elec­ tric Co., Baltimore, Maryland Roger Kaul (Chapters 2, 3, 4, 8, 11, 13, 14, 18, 19, 20, 21; Chapters 7, 15 co-author), Litton Amecom, College Park, Maryland (Presently at Harry Diamond Laboratories) David A. Leiss (Chapters 7 and 15, co-author), EEsof Inc., Manassas, Virginia Preface This book had its beginnings when Richard A. Wainwright, Cir-Q-Tel Pres­ ident, asked Washington area microwave engineers to create a course to interest students in microwave engineering and prepare them for positions industry was unable to fill. Five of these microwave engineers, H. Warren Cooper, Albert W. Friend, Robert V. Garver, Roger Kaul, and Edward A. Wolff, responded to the request. These engineers formed the Washington Microwave Education Committee, which designed and developed the mi­ crowave course. Financial support to defray course expenses was provided by Bruno Weinschel, President of Weinschel Engineering. The course was given for several years to seniors at the Capitol Institute of Technology in Laurel, Maryland.
  • The Morse Code Fact Sheet

    The Morse Code Fact Sheet

    THE MORSE CODE In England in 1837, the physicist Charles Wheatstone took out a patent for a telegraph system where a message could be sent down wires to a distant point using the movement of compass needles to spell out the words. In America in the same year, Samuel Morse produced an experimental telegraph system where an automatic printer recorded the incoming messages on a roll of paper, the “Morse inker”. To enable this to have a practical use he invented a code that used dots and dashes, sending the words using a “Morse key”. The inker was soon replaced by a sounder, a bell or buzzer, at the receiving end of the line. In 1843 the American government advanced money for the setting up of a telegraph service between Baltimore and Washington using Morse code. Back in England Wheatstone’s needle system was used extensively along railway lines to send messages between stations. Simultaneously several rival companies set up telegraph links and soon most towns and villages were wired up, the telegraph poles carrying dozens of wires became a familiar site down the side of the roads. In 1870 the post office took over the whole network and the Morse code tapped out by the Morse key and later high speed automatic machines and tele printers became the universal language of telegraphic communication. By the end of the 19th century, the telephone had been invented, people could speak to each other through the wires, and telephony was replacing telegraphy. Morse code, however, was still used in World War One and beyond for radio communication, you can see the Morse key on the trench transmitter in the bottom of the cabinet at the end of the room.