from 1906. The carrier wave is generated by 6 electric arcs in the vertical tubes, connected to a
tuned circuit. Modulation is done by the large carbon microphone
(cone shape) in the antenna lead. AM radio transmitters, built by Meissner in 1913 with an early triode tube by Robert von Lieben. He used it in a historic voice transmission from Berlin to Nauen, Germany. Compare its small size with the arc transmitter above. Amplitude modulation was used in experiments of multiplex telegraph and telephone transmission in the late 1800s. However, the practical development of this technology is identified with the period between 1900 and 1920 of
radiotelephone transmission, that is, the effort to send audio signals by radio waves. The first radio transmitters, called
spark gap transmitters, transmitted information by
wireless telegraphy, using pulses of the carrier wave to spell out text messages in
Morse code. They could not transmit audio because the carrier consisted of strings of
damped waves, pulses of radio waves that declined to zero, and sounded like a buzz in receivers. In effect they were already amplitude modulated.
Continuous waves The first AM transmission was made by Canadian-born American researcher
Reginald Fessenden on 23 December 1900 using a spark gap transmitter with a specially designed high frequency 10 kHz
interrupter, over a distance of at Cobb Island, Maryland, US. His first transmitted words were, "Hello. One, two, three, four. Is it snowing where you are, Mr. Thiessen?". Though his words were "perfectly intelligible", the spark created a loud and unpleasant noise. Fessenden was a significant figure in the development of AM radio. He was one of the first researchers to realize, from experiments like the above, that the existing technology for producing radio waves, the spark transmitter, was not usable for amplitude modulation, and that a new kind of transmitter, one that produced
sinusoidal continuous waves, was needed. This was a radical idea at the time, because experts believed the impulsive spark was necessary to produce radio frequency waves, and Fessenden was ridiculed. He invented and helped develop one of the first continuous wave transmitters – the
Alexanderson alternator, with which he made what is considered the first AM public entertainment broadcast on Christmas Eve, 1906. He also discovered the principle on which AM is based,
heterodyning, and invented one of the first
detectors able to
rectify and receive AM, the
electrolytic detector or "liquid baretter", in 1902. Other radio detectors invented for wireless telegraphy, such as the
Fleming valve (1904) and the
crystal detector (1906) also proved able to rectify AM signals, so the technological hurdle was generating AM waves; receiving them was not a problem.
Early technologies Early experiments in AM radio transmission, conducted by Fessenden,
Valdemar Poulsen,
Ernst Ruhmer,
Quirino Majorana,
Charles Herrold, and
Lee de Forest, were hampered by the lack of a technology for
amplification. The first practical continuous wave AM
transmitters were based on either the huge, expensive
Alexanderson alternator, developed 1906–1910, or versions of the
Poulsen arc transmitter (arc converter), invented in 1903. The modifications necessary to transmit AM were clumsy and resulted in very low quality audio. Modulation was usually accomplished by a
carbon microphone inserted directly in the antenna or ground wire; its varying resistance varied the current to the antenna. The limited power handling ability of the microphone severely limited the power of the first radiotelephones; many of the microphones were water-cooled.
Vacuum tubes The 1912 discovery of the amplifying ability of the
Audion tube, invented in 1906 by
Lee de Forest, solved these problems. The vacuum tube
feedback oscillator, invented in 1912 by
Edwin Armstrong and
Alexander Meissner, was a cheap source of
continuous waves and could be easily
modulated to make an AM transmitter. Modulation did not have to be done at the output but could be applied to the signal before the final amplifier tube, so the microphone or other audio source didn't have to modulate a high-power radio signal. Wartime research greatly advanced the art of AM modulation, and after the war the availability of cheap tubes sparked a great increase in the number of radio stations experimenting with AM transmission of news or music. The vacuum tube was responsible for the rise of
AM broadcasting around 1920, the first electronic
mass communication medium. Amplitude modulation was virtually the only type used for
radio broadcasting until
FM broadcasting began after World War II. At the same time as AM radio began,
telephone companies such as
AT&T were developing the other large application for AM: sending multiple telephone calls through a single wire by modulating them on separate
carrier frequencies, called
frequency division multiplexing.
Single-sideband In 1915,
John Renshaw Carson formulated the first mathematical description of amplitude modulation, showing that a signal and carrier frequency combined in a nonlinear device creates a sideband on both sides of the carrier frequency. Passing the modulated signal through another nonlinear device can extract the original baseband signal. His analysis also showed that only one sideband was necessary to transmit the audio signal, and Carson patented
single-sideband modulation (SSB) on 1 December 1915. This advanced variant of amplitude modulation was adopted by AT&T for
longwave transatlantic telephone service beginning 7 January 1927. After WW-II, it was developed for military aircraft communication. ==Analysis==