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Tuner (radio)

From Wikipedia, the free encyclopedia
"Tune in" redirects here. For the internet radio service, see TuneIn. For the book by Mark Lewisohn, see The Beatles: All These Years.
This article is about electronics component or device in audio. Not to be confused with electronic tuner.
For other uses, see Tuner.
Marantz 2050L AM/FM stereo tuner (USA; 1978-1980)[1]

In electronics and radio, a tuner is a type of receiver subsystem that receives RF transmissions, such as AM or FM broadcasts, and converts the selected carrier frequency into a form suitable for further processing or output, such as to an amplifier or loudspeaker. A tuner is also a standalone home audio product, component, or device called an AM/FM tuner or a stereo tuner that is part of a hi-fi or stereo system, or a TV tuner for television broadcasts. The verb tuning in radio contexts means adjusting the receiver to detect the desired radio signal carrier frequency that a particular radio station uses. Tuners were a major consumer electronics product in the 20th century but in practice are often integrated into other products in the modern day, such as stereo or AV receivers or portable radios.

Design history and overview

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Fisher 101-R AM/FM tuner, 15 vacuum tubes (USA; 1959)[2]
Inductively coupled crystal radio receiver
Sony DAR-1000ES DSR digital tuner, inside view of circuit board (Japan, 1992-1996)[3]
Yamaha T-420, digital tuning (Japan; 1986)[4]

The purpose of a tuner's design is to reduce noise and have a strong ability to amplify the wanted signal.[5] Tuners may be monophonic or stereophonic, and generally output left and right channels of sound.[6] Tuners generally include a tuning knob or keypad to adjust the frequency, i.e. the intended radio station, measured in megahertz (e.g. 101.1 MHz). Mistuning is the greatest source of distortion in FM reception.[5] Some models realize manual tuning by means of mechanically operated ganged variable capacitors (gangs). Often several sections are provided on a tuning capacitor, to tune several stages of the receiver in tandem, or to allow switching between different frequency bands. A later method used a potentiometer supplying a variable voltage to varactor diodes in the local oscillator and tank circuits of front end tuner, for electronic tuning. Modern radio tuners use a superheterodyne receiver with tuning selected by adjustment of the frequency of a local oscillator. This system shifts the radio frequency of interest to a fixed frequency so that it can be tuned with fixed-frequency band-pass filter. Still later, phase locked loop methods were used, with microprocessor control.[citation needed]

The crystal radio receiver is the simplest kind of radio receiver or tuner, and was the basis for the first commercially successful type of radio product design. Inexpensive and reliable, it was sold in millions of units and became popular in kits used by hobbyists, and was a major factor in the popularity of radio broadcasting around 1920.[7][8] The crystal radio consists of a antenna, a variable inductor and a variable capacitor connected in parallel. This creates a tank circuit which responds to one resonant frequency when combined with a detector, also known as a demodulator (diode D1 in the circuit).[9][8] Stereophonic receivers include a decoder as well.[10]

Vacuum tubes made crystal sets obsolete in the 1920s due to their effective amplification.[11] From the 1920s until the 1960s, most tuners used a vacuum tube-based design. Manufacturing shifted to solid state electronics in the 1960s, but this didn't always result in improved sound quality compared to the older tube tuners.[12][13] The radiogram, which combined a gramophone with a radio, was a predecessor of the hi-fi tuner.[14]

The transistor was invented in 1947 and largely replaced tubes.[15] The MOSFET was used because it is capable of handling larger inputs than bipolar transistors.[10] Starting in the 1960s, Japanese transistor radios, which were cheaper despite their crudeness compared to American designs, began to outcompete the American products in the portable radio market. Eventually, after switching from germanium to silicon transistors, the Japanese consumer electronics companies achieved a dominant market position. Heathkit, an American company which had supplied popular kits for electronic devices since the 1940s, went out of business in 1980. [15][16]

FM broadcasting originated in the United States and was adopted as a worldwide standard.[17] FM broadcasting in stereo in the USA began in 1961 when authorized by the FCC. This led to greater demand for new radio stations and better technology in radios. The growth of hi-fi stereo systems and car radios in turn led to a boost in FM listening. FM surpassed AM radio in 1978.[18] FM also doubled the number of stations, enabling specialized broadcasts for different genres of music. It also required consumers to purchase new equipment. [14] The broadcast audio FM band (88 - 108 MHz in most countries) is around 100 times higher in frequency than the AM band and provides enough space for a bandwidth of 50 kHz. This bandwidth is sufficient to transmit both stereo channels with almost the full hearing range. [citation needed]

The Post–World War II economic expansion in the US led to the growth of hi-fi products, increasingly seen as high tech hardware, with requisite jargon, and separated into premium quality components with high-class aesthetics and marketing.[19] The 1970s and 80s were the peak period for the hi-fi audio market.[12] Demand increased for stereo products which fueled the growth of the industry as Japan caught up with the US.[20] Standalone audio stereo FM tuners are still sought after for audiophile and TV/FM DX applications, especially those produced in the 1970s and early 1980s, when performance and manufacturing standards were higher.[21] The McIntosh MR78 (1972) is known as one of the first FM tuners precise enough to tune into a weaker station broadcast on the same frequency as another stronger signal. [22]

As a result of circuit miniaturization, tuners began to be integrated with other products such as amplifiers and preamps, and other digital electronics, and marketed as AV or stereo receivers for home theater or hi-fi systems.[23][24] The Japanese development of silicon transistor technology led to popular radio products in the 1980s such as the boombox and the Sony Walkman.[14] Although integrated hi-fi stereo systems and AV or stereo receivers contain integrated tuners, separate components are sometimes preferred for higher quality.[25][26] Separating amplification also often increases overall performance.[27]

Television

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A TV Tuner plugged into Sega Game Gear
Main article: Television set
See also: Television antenna
See also: TV tuner card

A television tuner or TV tuner, also called a TV receiver, is a component or subsystem that converts analog television or digital television transmissions into audio and video signals which can be further processed to produce sound and a picture.[36][37][38] A TV tuner must filter out unwanted signals and have a high signal-to-noise ratio.[39] Television standards supported by TV tuners include PAL, NTSC, SECAM, ATSC, DVB-C, DVB-T, DVB-T2, ISDB, DTMB, T-DMB, and open cable. VHF/UHF TV tuners are rarely found as a separate component, but are incorporated into television sets. Cable boxes, converter boxes and other set top boxes contain tuners for digital TV services, and send their output via SCART or other connector, or using an RF modulator (typically on channel 36 in Europe and channel 3/4 in North America) to TV receivers that do not natively support the services. They provide outputs via composite, S-video, or component video. Many can be used with video monitors that do not have a TV tuner or direct video input. They are often part of a VCR or digital video recorder (DVR, PVR). Many home computers in the 1970s and 1980s used an RF modulator to connect to a TV set, but today there are USB TV tuner cards and similar devices.[citation needed]

Analog tuners can tune only analog signals. An ATSC tuner is a digital tuner that tunes digital signals only. Some digital tuners provide an analog bypass. An example frequency range is 48.25 MHz - 855.25 MHz (E2-E69), with a tuning frequency step size of 31.25, 50 or 62.5 kHz. Before the use of solid-state frequency synthesizers, covering the broad range of TV signal frequencies with a single tuned circuit and sufficient precision was uneconomic. Television channel frequencies were non-contiguous, with many non-broadcast services interleaved between VHF channels 6 and 7 in North America, for example. Instead, TV tuners of the era incorporated multiple sets of tuned circuits for the main signal path and local oscillator circuit. These "turret" tuners mechanically switched the receiving circuits by rotating a knob to select the desired channel. Channels were presented in fixed sequence, with no means to skip channels unused in a particular area. When UHF TV broadcasting was made available, often two complete separate tuner stages were used, with separate tuning knobs for selection of VHF band and UHF band channels. To allow for a small amount of drift or misalignment of the tuner with the actual transmitted frequency, tuners of that era included a "fine tuning" knob to allow minor adjustment for best reception. The combination of high frequencies, multiple electrical contacts, and frequent changing of channels in the tuner made it a high maintenance part of the television receiver, as relatively small electrical or mechanical problems with the tuner would make the set unusable. [citation needed]

Opened VHF/UHF tuner of a television set. The antenna connector is on the right.

See also

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Wikimedia Commons has media related to Hi-Fi tuners.

References

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  1. ^ "Marantz 2050 AM/FM Stereo Tuner Manual". HiFi Engine. Retrieved 2024-10-02.
  2. ^ "Fisher 101-R AC Operated 15 Tube AM/FM Tuner Manual". HiFi Engine. Retrieved 2024-10-02.
  3. ^ "Sony DAR-1000ES DSR Tuner Manual". HiFi Engine. Retrieved 2024-10-02.
  4. ^ "Yamaha T-420 AM/FM Stereo Tuner Manual". HiFi Engine. Retrieved 2024-10-02.
  5. ^ a b Bali, S. P. (2007). Consumer Electronics. Pearson Education India. ISBN 978-93-325-0073-0.
  6. ^ Bishop, Owen (2007-11-09). Electronics - Circuits and Systems. Routledge. ISBN 978-1-136-07238-3.
  7. ^ Corbin, Alfred (2006). The Third Element: A Brief History of Electronics. AuthorHouse. pp. 44–45. ISBN 1-4208-9084-0.
  8. ^ a b Ben-Menahem, Ari (2009-03-06). Historical Encyclopedia of Natural and Mathematical Sciences. Springer Science & Business Media. p. 5185. ISBN 978-3-540-68831-0.
  9. ^ Tipler, Paul A.; Mosca, Gene (2004). Physics for Scientists and Engineers. Macmillan. p. 955. ISBN 978-0-7167-8339-8.
  10. ^ a b Turner, L. W. (2013-10-22). Electronics Engineer's Reference Book. Butterworth-Heinemann. ISBN 978-1-4831-6127-3.
  11. ^ Basalla, George (1988). The Evolution of Technology. Cambridge University Press. ISBN 978-0-521-29681-6.
  12. ^ a b Schwartz, Gideon (2019-10-30). Hi-Fi: The History of High-End Audio Design. Phaidon Press. ISBN 978-0-7148-7808-9.
  13. ^ Austin, Jim (Jan 30, 2020). "Book Review: Hi-Fi: The History of High-End Audio Design". Stereophile.
  14. ^ a b c Continuum Encyclopedia of Popular Music of the World: Performance and production. Volume II. A&C Black. 2003-01-30. ISBN 978-0-8264-6321-0.
  15. ^ a b Williams, Lyle Russell (2006-09-01). The New Radio Receiver Building Handbook. Lulu.com. ISBN 978-1-84728-526-3.
  16. ^ International Competitiveness in Electronics. Congress of the U.S., Office of Technology Assessment. 1983.
  17. ^ Lax, Stephen (2017-01-02). "Different Standards: Engineers' Expectations and Listener Adoption of Digital and FM Radio Broadcasting". Journal of Radio & Audio Media. 24 (1): 28–44. doi:10.1080/19376529.2017.1297147. ISSN 1937-6529.
  18. ^ Medoff, Norman J.; Kaye, Barbara K. (2016-12-01). Electronic Media: Then, Now, and Later. Taylor & Francis. ISBN 978-1-317-44862-4.
  19. ^ Keightley, Keir (2003-06-01). "Low Television, High Fidelity: Taste and the Gendering of Home Entertainment Technologies". Journal of Broadcasting & Electronic Media. 47 (2): 236–259. doi:10.1207/s15506878jobem4702_5. ISSN 0883-8151.
  20. ^ Nakayama, Wataru (2019-01-15). The Japanese Electronics Industry. CRC Press. ISBN 978-1-351-82986-1.
  21. ^ "Stereo Gear in the 1970's Was it The Audiophile Golden Age?". Audioholics Home Theater, HDTV, Receivers, Speakers, Blu-ray Reviews and News. 8 November 2021. Retrieved 2022-08-15.
  22. ^ "The Consumer Electronics Hall of Fame: McIntosh MR 78 Tuner". IEEE Spectrum. 2019-10-24. Retrieved 2022-08-15.
  23. ^ Watkinson, John (2012-11-12). The Art of Sound Reproduction. Taylor & Francis. ISBN 978-1-136-11853-1.
  24. ^ Miniaturization technologies. DIANE Publishing. ISBN 978-1-4289-2161-0.
  25. ^ Anand, M. L. (2024-10-18). Audio and Video Systems. CRC Press. ISBN 978-1-040-14797-9.
  26. ^ "For Your Receiver? Again?". Popular Science. Bonnier Corporation. April 1983. pp. 28–29.
  27. ^ Lam, John C. M. (2024-01-31). Analog Audio Amplifier Design. CRC Press. ISBN 978-1-000-99896-2.
  28. ^ "Heathkit catalog" (PDF). May 1961.
  29. ^ "Stereomaster 370-B Radio Scott; H.H.; Maynard, Massachusetts, build". Radiomuseum. Retrieved 2024-10-02.
  30. ^ "H.H. Scott Service Bulletin and Schematic for Model 370-B Stereo Multiplex Tuner" (PDF).
  31. ^ "Sherwood S-2100 AM/FM Stereo Tuner Manual". HiFi Engine. Retrieved 2024-10-02.
  32. ^ "Studiomeister RS222 Superelectronic Radio Siemens & Halske". Radiomuseum. Retrieved 2024-10-02.
  33. ^ "Marantz 150 AM/FM Stereo Tuner Manual". HiFi Engine. Retrieved 2024-10-02.
  34. ^ "Luxman T-34 Solid State AM/FM Tuner Manual". HiFi Engine. Retrieved 2024-10-02.
  35. ^ "Onkyo T-4000 Quartz Synthesized AM/FM Stereo Tuner Manual". HiFi Engine. Retrieved 2024-10-02.
  36. ^ Kybett, Harry (1978). Video Tape Recorders. H. W. Sams. ISBN 978-0-672-21521-6.
  37. ^ Goodman, Robert L. (1974). TV Tuner Schematic/servicing Manual. G/L Tab Books. ISBN 978-0-8306-3696-9.
  38. ^ Blumenthal, Howard J.; Goodenough, Oliver R. (2006). This Business of Television. BillBoard Books. ISBN 978-0-8230-7763-2.
  39. ^ Kiver, Milton S.; Kaufman, Milton (1983-07-31). Television Electronics: Theory and Servicing. Springer Netherlands. ISBN 978-0-442-24871-0.
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