Editing Amplitude modulation

{{short description|Electronic method of transmitting information with a carrier wave}}
{{Use dmy dates|date=October 2018}}

[[File:Amfm3-en-de.gif|thumb|right|250px|An audio signal (top) carried by a [[carrier signal]] using amplitude modulation (middle) and frequency modulation (bottom).|alt=Animation of audio, AM and FM modulated carriers.]]
{{Modulation techniques}}

'''Amplitude modulation''' ('''AM''') is a  [[signal modulation]] technique used in electronic communication, most commonly for transmitting messages with a [[radio wave]]. In amplitude modulation, the instantaneous [[amplitude]] of the wave is varied in proportion to that of the message signal, such as an [[audio signal]].<ref name=S>{{Cite book|page=85|title=Machines and Inventions|first=Robert H.|last=Smith|publisher=Time Life|year=1993|location=Alexandria, VA|isbn=0-8094-9704-2}}</ref> This technique contrasts with [[angle modulation]], in which either the [[frequency]] of the carrier wave is varied, as in [[frequency modulation]],<ref name=S/> or its [[Phase (waves)|phase]], as in [[phase modulation]].

AM was the earliest modulation method used for transmitting audio in radio broadcasting. It was developed during the first quarter of the 20th century beginning with [[Roberto Landell de Moura]] and [[Reginald Fessenden]]'s [[radiotelephone]] experiments in 1900.<ref>{{cite web|url=http://www.aminharadio.com/radio/files/Artigo-Revista-PCP-USA.pdf |archive-url=https://ghostarchive.org/archive/20221009/http://www.aminharadio.com/radio/files/Artigo-Revista-PCP-USA.pdf |archive-date=2022-10-09 |url-status=live|title=Father Landell de Moura : Radio Broadcasting Pioneer : FABIO S. FLOSI : UNICAMP – University of Campinas, State of São Paulo|website=Aminharadio.com|access-date=15 July 2018}}</ref> This original form of AM is sometimes called '''double-sideband amplitude modulation''' ('''DSBAM'''), because the standard method produces sidebands on either side of the carrier frequency. [[Single-sideband modulation]] uses bandpass filters to eliminate one of the sidebands and possibly the carrier signal, which improves the ratio of message power to total transmission [[Power (physics)|power]], reduces power handling requirements of line repeaters, and permits better bandwidth utilization of the transmission medium.

AM remains in use in many forms of communication in addition to [[AM broadcasting]]: [[shortwave radio]], [[amateur radio]], [[two-way radio]]s, [[Airband|VHF aircraft radio]], [[citizens band radio]], and in computer [[modem]]s in the form of [[quadrature amplitude modulation]] (QAM).

== Foundation ==
In [[electronics]] and [[telecommunications]], [[modulation]] is the variation of a property of a [[continuous wave]] [[carrier signal]] according to an information-bearing signal, such as an [[audio signal]] which represents sound, or a [[video signal]] which represents images. In this sense, the carrier wave, which has a much higher frequency than the message signal, ''carries'' the information. At the receiving station, the message signal is extracted from the modulated carrier by [[demodulation]].

In general form, a modulation process of a [[sine wave|sinusoidal carrier wave]] may be described by the following equation:<ref>{{cite book |author=AT&T Bell Laboratories Staff |title=Telecommunication Transmission Engineering |volume=1—''Principles''|edition=2|publisher=AT&T Bell Center for Technical Education|year=1977}}</ref>

:<math>m(t) = A(t) \cdot \cos(\omega t + \phi(t))\,</math>.

''A(t)'' represents the time-varying amplitude of the sinusoidal carrier wave and the cosine-term is the carrier at its [[angular frequency]] <math>\omega</math>, and the instantaneous phase deviation <math>\phi(t)</math>. This description directly provides the two major groups of modulation, amplitude modulation and [[angle modulation]]. In angle modulation, the term ''A''(''t'') is constant and the second term of the equation has a functional relationship to the modulating message signal. Angle modulation provides two methods of modulation, [[frequency modulation]] and [[phase modulation]].

In amplitude modulation, the angle term is held constant and the first term, ''A''(''t''), of the equation has a functional relationship to the modulating message signal.

The modulating message signal may be analog in nature, or it may be a digital signal, in which case the technique is generally called [[amplitude-shift keying]].

For example, in AM radio communication, a continuous wave radio-frequency signal has its amplitude modulated by an audio waveform before transmission. The message signal determines the ''[[Envelope (waves)|envelope]]'' of the transmitted waveform. In the [[frequency domain]], amplitude modulation produces a signal with power concentrated at the [[carrier frequency]] and two adjacent [[sideband]]s. Each sideband is equal in [[bandwidth (signal processing)|bandwidth]] to that of the modulating signal, and is a mirror image of the other. Standard AM is thus sometimes called "double-sideband amplitude modulation" (DSBAM).

A disadvantage of all amplitude modulation techniques, not only standard AM, is that the receiver amplifies and detects [[Noise (radio)|noise]] and [[electromagnetic interference]] in equal proportion to the signal. Increasing the received [[signal-to-noise ratio]], say, by a factor of 10 (a 10 [[decibel]] improvement), thus would require increasing the transmitter power by a factor of 10. This is in contrast to [[frequency modulation]] (FM) and [[digital radio]] where the effect of such noise following demodulation is strongly reduced so long as the received signal is well above the threshold for reception. For this reason AM broadcast is not favored for music and [[high fidelity]] broadcasting, but rather for voice communications and broadcasts (sports, news, [[talk radio]] etc.).

AM is inefficient in power usage, as at least two-thirds of the transmitting power is concentrated in the carrier signal. The carrier signal contains none of the transmitted information (voice, video, data, etc.). However, its presence provides a simple means of demodulation using [[envelope detection]], providing a frequency and phase reference for extracting the message signal from the sidebands. In some modulation systems based on AM, a lower transmitter power is required through partial or total elimination of the carrier component, however receivers for these signals are more complex because they must provide a precise carrier frequency reference signal (usually as shifted to the [[intermediate frequency]]) from a greatly reduced "pilot" carrier (in [[reduced-carrier transmission]] or DSB-RC) to use in the demodulation process. Even with the carrier eliminated in [[double-sideband suppressed-carrier transmission]], carrier regeneration is possible using a [[Costas loop|Costas phase-locked loop]]. This does not work for [[single-sideband suppressed-carrier transmission]] (SSB-SC), leading to the characteristic "Donald Duck" sound from such receivers when slightly detuned. Single-sideband AM is nevertheless used widely in [[amateur radio]] and other voice communications because it has power and bandwidth efficiency (cutting the RF bandwidth in half compared to standard AM). On the other hand, in [[medium wave]] and [[short wave]] broadcasting, standard AM with the full carrier allows for reception using inexpensive receivers. The broadcaster absorbs the extra power cost to greatly increase potential audience.

=== Shift keying ===
A simple form of digital amplitude modulation which can be used for transmitting [[digital data|binary data]] is [[on–off keying]], the simplest form of amplitude-shift keying, in which [[binary numeral system|ones and zeros]] are represented by the presence or absence of a carrier. On–off keying is likewise used by radio amateurs to transmit [[Morse code]] where it is known as continuous wave (CW) operation, even though the transmission is not strictly "continuous". A more complex form of AM, [[quadrature amplitude modulation]] is now more commonly used with digital data, while making more efficient use of the available bandwidth.

=== Analog telephony ===
A simple form of amplitude modulation is the transmission of speech signals from a traditional analog telephone set using a common battery local loop.<ref>{{cite book |author=AT&T Bell Laboratories Staff |editor=R.J. Rey |title=Engineering and Operations in the Bell System|edition=2 |location=Murray Hill, NJ|year=1984|page=211|publisher=AT&T Bell Laboratories|isbn=0-932764-04-5}}</ref> The direct current provided by the central office battery is a carrier with a frequency of 0&nbsp;Hz. It is modulated by a microphone (''transmitter'') in the telephone set according to the acoustic signal from the speaker. The result is a varying amplitude direct current, whose AC-component is the speech signal extracted at the central office for transmission to another subscriber.

=== Amplitude reference ===
An additional function provided by the carrier in standard AM, but which is lost in either single or double-sideband suppressed-carrier transmission, is that it provides an amplitude reference. In the receiver, the [[automatic gain control]] (AGC) responds to the carrier so that the reproduced audio level stays in a fixed proportion to the original modulation. On the other hand, with suppressed-carrier transmissions there is ''no'' transmitted power during pauses in the modulation, so the AGC must respond to peaks of the transmitted power during peaks in the modulation. This typically involves a so-called ''fast attack, slow decay'' circuit which holds the AGC level for a second or more following such peaks, in between syllables or short pauses in the program. This is very acceptable for communications radios, where [[Dynamic range compression|compression]] of the audio aids intelligibility. However, it is absolutely undesired for music or normal broadcast programming, where a faithful reproduction of the original program, including its varying modulation levels, is expected.

==ITU type designations==
In 1982, the [[International Telecommunication Union]] (ITU) designated the types of amplitude modulation:
{|class="wikitable"
|-
!Designation!!Description
|-
|A3E||[[double-sideband]] a full-carrier – the basic amplitude modulation scheme
|-
|R3E||[[single-sideband]] [[Reduced-carrier transmission|reduced-carrier]]
|-
|H3E||[[single-sideband]] full-carrier
|-
|J3E||[[Single-sideband suppressed-carrier transmission|single-sideband suppressed-carrier]]
|-
|B8E||[[independent sideband|independent-sideband]] emission
|-
|C3F||[[vestigal sideband|vestigial-sideband]]
|-
|Lincompex||linked [[compander|compressor and expander]] (a submode of any of the above ITU Emission Modes)
|}<!--single mid band linked modulation
[B4E side bander inter linked] [expand carrier] full reduced.aLTIDOE-->

==History==
[[Image:Telefunken arc radiotelephone.jpg|thumb|One of the crude pre-vacuum tube AM transmitters, a Telefunken [[arc converter|arc transmitter]] 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. ]]
[[Image:Meissner radiotelephone transmitter.jpg|thumb|One of the first [[vacuum tube]] AM radio transmitters, built by Meissner in 1913 with an early triode tube by Robert von Lieben. He used it in a historic {{convert|36|km|mi|abbr=on}} 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.<ref name="Bray">{{cite book
 | last = Bray
 | first = John
 | title = Innovation and the Communications Revolution: From the Victorian Pioneers to Broadband Internet
 | publisher = Inst. of Electrical Engineers
 | year = 2002
 | pages = 59, 61–62
 | url = https://books.google.com/books?id=3h7R36Y0yFUC&pg=PA61
 | isbn = 0852962185}}</ref> 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 transmitter]]s, 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 wave]]s, 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]]<ref name="t786">{{cite web | title=Reginald Fessenden (U.S. National Park Service) | website=NPS.gov Homepage (U.S. National Park Service) | date=1932-07-22 | url=https://www.nps.gov/people/reginaldfessenden.htm | access-date=2024-12-16}}</ref> on December 23, 1900<ref name="t779">{{cite web | last=Reel | first=Monte | title=Island Is Birthplace of Broadcast | website=Washington Post | date=2000-12-17 | url=https://www.washingtonpost.com/archive/local/2000/12/17/island-is-birthplace-of-broadcast/61d6fb5e-ecd2-4db4-b9ba-8b89e5c167b0/ | access-date=2024-12-16}}</ref> using a spark gap transmitter with a specially designed high frequency 10&nbsp;kHz [[induction coil|interrupter]],<ref name="AGARD_1992">{{cite report |author=Advisory Group for Research and Development (AGARD) |date=October 2, 1992 |title=ELF/VLF/LF Radio Propagation and Systems Aspects |url=https://apps.dtic.mil/sti/tr/pdf/ADA267991.pdf |publisher=North Atlantic Treaty Organization (NATO) |access-date=2024-12-16}}</ref> over a distance of {{convert|1|mi|km|spell=in}} at Cobb Island, Maryland, US. His first transmitted words were, "Hello. One, two, three, four. Is it snowing where you are, Mr. Thiessen?".<ref name="t779" /> Though his words were "perfectly intelligible", the spark created a loud and unpleasant noise.<ref name="AGARD_1992" />

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 wave]]s'', 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 [[detector (radio)|detector]]s able to [[rectifier|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 [[amplifier|amplification]]. The first practical continuous wave AM [[transmitter]]s 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 wave]]s 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 Corporation|AT&T]] were developing the other large application for AM: sending multiple telephone calls through a single wire by modulating them on separate [[carrier signal|carrier]] frequencies, called ''[[frequency division multiplexing]]''.<ref name="Bray" />

===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.<ref name="Bray" /> 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.<ref name="Bray" /> 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==
[[File:Illustration of Amplitude Modulation.png|thumb|391x391px|Illustration of amplitude modulation]]
The carrier wave ([[sine wave]]) of frequency ''f<sub>c</sub>'' and amplitude ''A'' is expressed by

:<math>c(t) = A \sin(2 \pi f_c t)\,</math>.

The message signal, such as an audio signal that is used for modulating the carrier, is ''m''(''t''), and has a frequency ''f<sub>m</sub>'', much lower than ''f<sub>c</sub>'':

:<math>m(t) = M \cos\left(2\pi f_m t + \phi\right)= Am \cos\left(2\pi f_m t + \phi\right)\,</math>,

where ''m'' is the amplitude sensitivity, ''M'' is the amplitude of modulation. If ''m'' < 1, ''(1 + m(t)/A)'' is always positive for undermodulation. If ''m'' > 1 then overmodulation occurs and reconstruction of message signal from the transmitted signal would lead in loss of original signal. Amplitude modulation results when the carrier ''c(t)'' is multiplied by the positive quantity  ''(1 + m(t)/A)'':

:<math>\begin{align}
  y(t) &= \left[1 + \frac{m(t)}{A}\right] c(t) \\
       &= \left[1 + m \cos\left(2\pi f_m t + \phi\right)\right] A \sin\left(2\pi f_c t\right)
\end{align}</math>

In this simple case ''m'' is identical to the [[#Modulation index|modulation index]], discussed below. With ''m'' = 0.5 the amplitude modulated signal ''y''(''t'') thus corresponds to the top graph (labelled "50% Modulation") in figure 4.

Using [[prosthaphaeresis#The identities|prosthaphaeresis identities]], ''y''(''t'') can be shown to be the sum of three sine waves:

:<math>y(t) = A \sin(2\pi f_c t) + \frac{1}{2}Am\left[\sin\left(2\pi \left[f_c + f_m\right] t + \phi\right) +  \sin\left(2\pi \left[f_c - f_m\right] t - \phi\right)\right].\,</math>

Therefore, the modulated signal has three components: the carrier wave ''c(t)'' which is unchanged in frequency, and two [[sideband]]s with frequencies slightly above and below the carrier frequency ''f<sub>c</sub>''.

==Spectrum==
[[File:AM spectrum.svg|thumb|400px|Figure 2: Double-sided spectra of baseband and AM signals.|alt=Diagrams of an AM signal, with formulas]]
A useful modulation signal ''m(t)'' is usually more complex than a single sine wave, as treated above. However, by the principle of [[Fourier decomposition]], ''m(t)'' can be expressed as the sum of a set of sine waves of various frequencies, amplitudes, and phases. Carrying out the multiplication of  ''1 + m(t)'' with ''c(t)'' as above, the result consists of a sum of sine waves. Again, the carrier ''c(t)'' is present unchanged, but each frequency component of ''m'' at ''f<sub>i</sub>'' has two sidebands at frequencies ''f<sub>c</sub> + f<sub>i</sub>'' and  ''f<sub>c</sub> – f<sub>i</sub>''. The collection of the former frequencies above the carrier frequency is known as the upper sideband, and those below constitute the lower sideband. The modulation ''m(t)'' may be considered to consist of an equal mix of positive and negative frequency components, as shown in the top of figure 2. One can view the sidebands as that modulation ''m(t)'' having simply been shifted in frequency by ''f<sub>c</sub>'' as depicted at the bottom right of figure 2.

[[File:AM signal.jpg|thumb|200px|right|Figure 3: The [[spectrogram]] of an AM voice broadcast shows the two sidebands (green) on either side of the carrier (red) with time proceeding in the vertical direction.|alt=Sonogram of an AM signal, showing the carrier and both sidebands vertically]]
The short-term spectrum of modulation, changing as it would for a human voice for instance, the frequency content (horizontal axis) may be plotted as a function of time (vertical axis), as in figure 3. It can again be seen that as the modulation frequency content varies, an upper sideband is generated according to those frequencies shifted ''above'' the carrier frequency, and the same content mirror-imaged in the lower sideband below the carrier frequency. At all times, the carrier itself remains constant, and of greater power than the total sideband power.

==Power and spectrum efficiency==
The RF bandwidth of an AM transmission (refer to figure 2, but only considering positive frequencies) is twice the bandwidth of the modulating (or "[[baseband]]") signal, since the upper and lower sidebands around the carrier frequency each have a bandwidth as wide as the highest modulating frequency. Although the bandwidth of an AM signal is narrower than one using [[frequency modulation]] (FM), it is twice as wide as [[single-sideband]] techniques; it thus may be viewed as spectrally inefficient. Within a frequency band, only half as many transmissions (or "channels") can thus be accommodated. For this reason analog television employs a variant of single-sideband (known as [[vestigial sideband]], somewhat of a compromise in terms of bandwidth) in order to reduce the required channel spacing.

Another improvement over standard AM is obtained through reduction or suppression of the carrier component of the modulated spectrum. In figure 2 this is the spike in between the sidebands; even with full (100%) sine wave modulation, the power in the carrier component is twice that in the sidebands, yet it carries no unique information. Thus there is a great advantage in efficiency in reducing or totally suppressing the carrier, either in conjunction with elimination of one sideband ([[single-sideband suppressed-carrier transmission]]) or with both sidebands remaining ([[double sideband suppressed carrier]]). While these suppressed carrier transmissions are efficient in terms of transmitter power, they require more sophisticated receivers employing [[Product detector|synchronous detection]] and regeneration of the carrier frequency. For that reason, standard AM continues to be widely used, especially in broadcast transmission, to allow for the use of inexpensive receivers using [[envelope detection]]. Even (analog) television, with a (largely) suppressed lower sideband, includes sufficient carrier power for use of envelope detection. But for communications systems where both transmitters and receivers can be optimized, suppression of both one sideband and the carrier represent a net advantage and are frequently employed.

A technique used widely in broadcast AM transmitters is an application of the Hapburg carrier, first proposed in the 1930s but impractical with the technology then available. During periods of low modulation the carrier power would be [[Dynamic carrier control|reduced]] and would return to full power during periods of high modulation levels. This has the effect of reducing the overall power demand of the transmitter and is most effective on speech type programmes. Various trade names are used for its implementation by the transmitter manufacturers from the late 80's onwards.

==Modulation index==
The AM modulation index is a measure based on the ratio of the modulation excursions of the RF signal to the level of the unmodulated carrier. It is thus defined as:
:<math>m = \frac{\mathrm{peak\ value\ of\ } m(t)}{A} = \frac{M}{A}  </math>

where <math>M\,</math> and <math>A\,</math> are the modulation amplitude and carrier amplitude, respectively; the modulation amplitude is the peak (positive or negative) change in the RF amplitude from its unmodulated value. Modulation index is normally expressed as a percentage, and may be displayed on a meter connected to an AM transmitter.

So if <math>m=0.5</math>, carrier amplitude varies by 50% above (and below) its unmodulated level, as is shown in the first waveform, below. For <math>m=1.0</math>, it varies by 100% as shown in the illustration below it. With 100% modulation the wave amplitude sometimes reaches zero, and this represents full modulation using standard AM and is often a target (in order to obtain the highest possible [[signal-to-noise ratio]]) but mustn't be exceeded. Increasing the modulating signal beyond that point, known as [[overmodulation]], causes a standard AM modulator (see below) to fail, as the negative excursions of the wave envelope cannot become less than zero, resulting in [[distortion]] ("clipping") of the received modulation. Transmitters typically incorporate a [[limiter]] circuit to avoid overmodulation, and/or a [[Dynamic range compression|compressor]] circuit (especially for voice communications) in order to still approach 100% modulation for maximum intelligibility above the noise. Such circuits are sometimes referred to as a [[vogad]].

However it is possible to talk about a modulation index exceeding 100%, without introducing distortion, in the case of [[double-sideband reduced-carrier transmission]]. In that case, negative excursions beyond zero entail a reversal of the carrier phase, as shown in the third waveform below. This cannot be produced using the efficient high-level (output stage) modulation techniques (see below) which are widely used especially in high power [[broadcast]] transmitters. Rather, a special modulator produces such a waveform at a low level followed by a [[linear amplifier]]. What's more, a standard AM receiver using an [[envelope detector]] is incapable of properly demodulating such a signal. Rather, synchronous detection is required. Thus double-sideband transmission is generally ''not'' referred to as "AM" even though it generates an identical RF waveform as standard AM as long as the modulation index is below 100%. Such systems more often attempt a radical reduction of the carrier level compared to the sidebands (where the useful information is present) to the point of [[double-sideband suppressed-carrier transmission]] where the carrier is (ideally) reduced to zero. In all such cases the term "modulation index" loses its value as it refers to the ratio of the modulation amplitude to a rather small (or zero) remaining carrier amplitude.

[[File:Amplitude Modulated Wave-hm-64.svg|thumb|400px|center|Figure 4: Modulation depth. In the diagram, the unmodulated carrier has an amplitude of 1.|alt=Graphs illustrating how signal intelligibility increases with modulation index, but only up to 100% using standard AM.]]

=={{anchor|AM modulation methods}}Modulation methods==
[[File:ammodstage.png|300px|right|thumb|Anode (plate) modulation. A tetrode's plate and screen grid voltage is modulated via an audio transformer. The resistor R1 sets the grid bias; both the input and output are tuned circuits with inductive coupling.]]

Modulation circuit designs may be classified as low- or high-level (depending on whether they modulate in a low-power domain—followed by amplification for transmission—or in the high-power domain of the transmitted signal).<ref>
{{cite book
 | title = Communication Engineering
 | author1= Atul P. Godse |author2=U. A. Bakshi
 | publisher = Technical Publications
 | year = 2009
 | isbn = 978-81-8431-089-4
 | page = 36
 | url = https://books.google.com/books?id=coQ6ac-fh6QC&pg=PA36
 }}</ref>

===Low-level generation===
In modern radio systems, modulated signals are generated via [[digital signal processing]] (DSP). With DSP many types of AM are possible with software control (including DSB with carrier, SSB suppressed-carrier and independent sideband, or ISB). Calculated digital samples are converted to voltages with a [[digital-to-analog converter]], typically at a frequency less than the desired RF-output frequency. The analog signal must then be shifted in frequency and [[linear amplifier|linearly amplified]] to the desired frequency and power level (linear amplification must be used to prevent modulation distortion).<ref>
{{cite book
|publisher= American Radio Relay League
|title= The ARRL Handbook for Radio Communications
|editor1-last= Silver |editor1-first= Ward
|edition= Eighty-eighth
|year= 2011
|chapter= Ch. 15 DSP and Software Radio Design
|isbn= 978-0-87259-096-0}}</ref>
This low-level method for AM is used in many Amateur Radio transceivers.<ref>{{cite book
|publisher= American Radio Relay League
|title= The ARRL Handbook for Radio Communications
|editor1-last= Silver |editor1-first= Ward
|edition= Eighty-eighth
|year= 2011
|chapter= Ch. 14 Transceivers
|isbn= 978-0-87259-096-0}}</ref>

AM may also be generated at a low level, using analog methods described in the next section.

===High-level generation===
High-power AM [[transmitter]]s (such as those used for [[AM broadcasting]]) are based on high-efficiency [[Class-D amplifier|class-D]] and class-E [[Electronic amplifier|power amplifier]] stages, modulated by varying the supply voltage.<ref>{{cite journal
|author= Frederick H. Raab
|title= RF and Microwave Power Amplifier and Transmitter Technologies – Part 2
|journal= High Frequency Design
|date= May 2003
|pages= 22ff
|url= https://www.scribd.com/doc/8616046/RF-Power-Amplifier-and-Transmitter-Technologies-Part2
|display-authors= etal
|access-date= 8 September 2017
|archive-date= 6 March 2016
|archive-url= https://web.archive.org/web/20160306164053/https://www.scribd.com/doc/8616046/RF-Power-Amplifier-and-Transmitter-Technologies-Part2
|url-status= live
}}</ref>

Older designs (for broadcast and amateur radio) also generate AM by controlling the gain of the transmitter's final amplifier (generally class-C, for efficiency). The following types are for vacuum tube transmitters (but similar options are available with transistors):<ref>
{{cite book
|author= Laurence Gray and Richard Graham
|title= Radio Transmitters
|publisher= McGraw-Hill
|year= 1961
|pages=141ff
}}</ref><ref>
{{cite book
|author=Cavell, Garrison C. Ed.
|title= National Association of Broadcasters Engineering Handbook, 11th Ed.
|publisher= Routledge
|year= 2018
|pages=1099ff
}}</ref>

; Plate modulation: In plate modulation, the plate voltage of the RF amplifier is modulated with the audio signal. The audio power requirement is 50 percent of the RF-carrier power.
; Heising (constant-current) modulation: RF amplifier plate voltage is fed through a [[choke (electronics)|choke]] (high-value inductor). The AM modulation tube plate is fed through the same inductor, so the modulator tube diverts current from the RF amplifier. The choke acts as a constant current source in the audio range. This system has a low power efficiency.
; Control grid modulation: The operating bias and gain of the final RF amplifier can be controlled by varying the voltage of the control grid. This method requires little audio power, but care must be taken to reduce distortion.
; Clamp tube (screen grid) modulation: The screen-grid bias may be controlled through a ''clamp tube'', which reduces voltage according to the modulation signal. It is difficult to approach 100-percent modulation while maintaining low distortion with this system.
; [[Doherty amplifier|Doherty modulation]]: One tube provides the power under carrier conditions and another operates only for positive modulation peaks. Overall efficiency is good, and distortion is low.
; [[Ampliphase|Outphasing modulation]]: Two tubes are operated in parallel, but partially out of phase with each other. As they are differentially phase modulated their combined amplitude is greater or smaller. Efficiency is good and distortion low when properly adjusted.
; [[Pulse-width modulation|Pulse-width modulation (PWM) or pulse-duration modulation (PDM)]]: A highly efficient high voltage power supply is applied to the tube plate. The output voltage of this supply is varied at an audio rate to follow the program. This system was pioneered by [[Hilmer Swanson]] and has a number of variations, all of which achieve high efficiency and sound quality.
; Digital methods: The [[Harris Corporation]] obtained a patent for synthesizing a modulated high-power carrier wave from a set of digitally selected low-power amplifiers, running in phase at the same carrier frequency.<ref>{{Cite patent|title=Amplitude modulation using digitally selected carrier amplifiers|fdate=1981-12-24|country=US|number=4580111|inventor1-first=Hilmer|inventor1-last=Swanson|inventor1-link=Hilmer_Swanson|assign=[[Harris Corp]]|pubdate=1986-04-01}}</ref>{{citation needed|date=May 2021}} The input signal is sampled by a conventional audio analog-to-digital converter (ADC), and fed to a digital exciter, which modulates overall transmitter output power by switching a series of low-power solid-state RF amplifiers on and off. The combined output drives the antenna system.

=={{anchor|AM demodulation methods}}Demodulation methods==
The simplest form of AM demodulator consists of a [[diode]] which is configured to act as [[envelope detector]]. Another type of demodulator, the [[product detector]], can provide better-quality demodulation with additional circuit complexity.

==See also==
* [[Airband]]
* [[AM stereo]]
* [[Amplitude modulation signalling system]] (AMSS)
* [[Double-sideband suppressed-carrier transmission]] (DSB-SC)
* [[Modulation sphere]]
* [[Shortwave radio]]
* [[Types of radio emissions]]

==References==
{{Reflist}}

==Bibliography==
* Newkirk, David and Karlquist, Rick (2004). Mixers, modulators and demodulators. In D. G. Reed (ed.), ''The ARRL Handbook for Radio Communications'' (81st ed.), pp.&nbsp;15.1–15.36. Newington: ARRL.  {{ISBN|0-87259-196-4}}.

==External links==
* ''[https://web.archive.org/web/20090728105917/http://demonstrations.wolfram.com/AmplitudeModulation/ Amplitude Modulation]'' by Jakub Serych, [[Wolfram Demonstrations Project]].
* [http://robotics.eecs.berkeley.edu/~sastry/ee20/modulation/node3.html Amplitude Modulation], by S Sastry.
* [https://fas.org/man/dod-101/navy/docs/es310/AM.htm Amplitude Modulation], an introduction by [[Federation of American Scientists]].
* [https://www.electronics-notes.com/articles/radio/modulation/amplitude-modulation-am.php Amplitude Modulation tutorial] including related topics of modulators, demodulators, etc...
* [https://colab.research.google.com/drive/14Ws9gX1hPzBkE7P1sBepVuoz-uo2f-Be?usp=sharing Analog Modulation online interactive demonstration] using Python in [https://colab.research.google.com Google Colab Platform], by C Foh.

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{{Audio broadcasting}}

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[[Category:Radio modulation modes]]