70-centimeter band

The 70-centimeter amateur radio band is the 420 to 450 MHz portion of the UHF radio spectrum. This band is used by amateurs engaged in emergency communications where portable and mobile radios are frequently used. Many such radios have dual-band capabilities, operating on both the 70-centimeter and 2-meter bands. Some activity within the radio-controlled (RC) aircraft and other types of RC hobby miniature pastimes in Germany on the 70 centimeter band are also possible and permitted for German "amateurfunk" ham radio licensees,[1] and for which a few similar 70-cm band frequencies are also available for Switzerland-licensed amateur radio licenseholders to participate in RC hobby activities as well.[2]

Band allocation

The band's allocation varies regionally. In the United States,[3] Australia and Trinidad and Tobago[4] the band ranges from 420 to 450 MHz with some geographical limitations; in Canada, the band is only 430450 MHz; in the UK, amateurs are allocated 430440 MHz. By international treaty between the US and Canada, operation in the portion of the band from 420 to 430 MHz is prohibited north of Line A,[5] which runs just south of the Canadian border from Washington state to Maine, and east of Line C, which runs from northeast to southeast Alaska.

Propagation characteristics

70-centimeter propagation characteristics lie midway between 2-meter and 33-centimeter (~900 MHz) bands. Above 200 MHz, as frequency increases, building penetration is reduced.[6] However, smaller obstacles may also block or reflect the signal. Higher frequencies also present a lower noise floor, making it easier to overcome both natural and artificial interference, especially prevalent in urban environments.

Atmospheric thermal ducting is often more intense at UHF, because shorter wavelengths have much greater refraction angles than longer ones. However, a much stronger thermal inversion is often required than is needed for ducting in the 2-meter band.

Comparison of the 2-meter and 70-centimeter bands

Propagation considerations often take a back seat to channel availability or economic concerns in system planning. One practical concern when comparing the 70-centimeter band to the 2-meter band is that a quarter-wavelength antenna is much less unwieldy at 70 centimeters than it is at 2 meters. Portable antennas for 2 meters are generally continuously loaded coil spring or "rubber duck" types, while on 70 centimeters they can be a full quarter wavelength. The difference can be as much as 8 dB. The primary advantage of 70 centimeters is that base station antennas of very significant gain (up to 11 dB or so) are practical while 6 dB is about the practical limit on 2m. The extra 5 dB of receive and transmit gain are often critical for long-range communication, particularly for high-power repeaters which can then concentrate all of their power and receive sensitivity at the horizon.

The 70-centimeter amateur band also provides a wider spectrum than the 2-meter band (in the U.S., this is 30 MHz of spectrum, compared to only 4 MHz on the 2-meter band). This allows for many more channels, accommodating fast scan television, wideband digital modes, and point-to-point linking, which may not be permitted on 2-meter and lower frequencies, depending on local regulations.

A problem found with all UHF and higher frequencies is the prevalence of multipath signals. The reflective properties of the 70-centimeter band allow signals to be reflected by dense and solid material such as cement or rock. This creates a slight time delay between the primary and reflected signals, causing cancellations as direct and reflected signals are combined in the receiving antenna. This can cause receiving stations to experience rapid fluctuations in signal strength, or "picket fencing", when they are in motion. The problem is much less severe with modern FM systems because the receiver's limiter circuitry compensates for variations in received signal strength over a very wide amplitude range. In properly engineered systems, multipath can also be reduced by assuring that the transmitter uses only the minimum necessary power, allowing the reflected signals to be lower than the receiver's detection threshold.

70 centimeters is very close to the third harmonic of 2 meters, which allows sufficiently broadband 2 meter antennas to be used for 70 centimeters. Antennas specifically designed to work on both bands are common. Also, 2 meters is far enough away from 70 centimeters to make diplexers small and simple, making it easy to cross-band repeat signals between the two bands with a single dual-band radio.

Use for the radio control hobbies

Germany—with 33 frequencies,[7] having a 50 kHz bandwidth spacing between adjacent channels—and Switzerland with ten[8]—have specifically set aside bandwidth for radio control hobbyists holding amateur radio licenses to operate any form of model craft on the 70 cm band. These frequencies now fall in the LPD433 band mandated for use by short range devices by the European Commission.

Similar (but unofficial) bandwidth provisions as with the six meter VHF band, as secondary users, exist within the amateur radio regulations and permitted frequency allocations for North America with the regulations for American and Canadian amateur radio licensees—American amateur radio licensees can use a maximum of one watt of radiated RF power per the FCC's Part 97.215 rules for RC model operations, on any Ham-band authorized frequency that their license grade allows.

See also

References

  1. "United Kingdom Radio Control Council: International Frequencies - Germany". UKRCC. UKRCC. Retrieved 13 July 2013.
  2. "United Kingdom Radio Control Council: International Frequencies - Switzerland". UKRCC. UKRCC. Retrieved 13 July 2013.
  3. "§ 97.301 Authorized frequency bands" (PDF). The Federal Communications Commission. 1 October 2008. p. 2. Retrieved 15 November 2009.
  4. "Trinidad and Tobago Frequency Allocation Table (9 kHz to 1000 GHz)" (PDF). The Telecommunications Authority of Trinidad and Tobago. 16 October 2009. p. 154. Retrieved 15 November 2009.. See Footnote TT34.
  5. http://www.fcc.gov/oet/info/maps/canline/canline.html
  6. Taylor, Clayborne D.; et al. "13 - Measurement of RF Propagation into Concrete Structures over the Frequency Range 100 MHz to 3 GHz". Wireless Personal Communications : Advances in Coverage and Capacity (PDF). p. 13-14. ISBN 978-1-4613-7861-7. Archived from the original (PDF) on December 27, 2014. measured attenuation above 200 MHz appears to increase with an increase in frequency
  7. "United Kingdom Radio Control Council: International Frequencies - Germany". UKRCC. UKRCC. Retrieved 13 July 2013.
  8. "United Kingdom Radio Control Council: International Frequencies - Switzerland". UKRCC. UKRCC. Retrieved 13 July 2013.

External links

This article is issued from Wikipedia - version of the Saturday, February 06, 2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.