Mobile service In Europe, the Electronic Communications Committee (ECC) of the
European Conference of Postal and Telecommunications Administrations (CEPT) has harmonized part of the L band (1452–1492 MHz), allowing individual countries to adopt this spectrum for terrestrial mobile/fixed communications networks supplemental downlink (MFCN SDL). By means of carrier aggregation, an
LTE-Advanced or UMTS/
HSDPA base station could use this spectrum to provide additional bandwidth for communications from the base station to the mobile device; i.e., in the downlink direction. In the Americas, mobile services are operated between the 1.7 GHz to 2.1 GHz range in the
PCS and
AWS bands.
Satellite navigation The
Global Positioning System carriers are in the L band, centered at 1176.45 MHz (L5), 1227.60 MHz (L2), 1381.05 MHz (L3), and 1575.42 MHz (L1) frequencies. L band waves are used for GPS units because they are able to penetrate clouds, fog, rain, storms, and vegetation. Only dense environments such as heavy forest canopies or concrete buildings can cause GPS units to receive data inaccurately. The
Galileo Navigation System, the
GLONASS System, and the
BeiDou systems use the L band similar to GPS, although the frequency ranges are named differently. Modern receivers, such as those found in
smartphones, are able to take advantage of multiple systems (usually only around the oldest L1 band) at the same time.
Telecommunications use Mobile phones operate at 600–900 and 1700–2100 MHz.
Iridium Communications satellite phones use frequencies between 1616 and 1626.5 MHz to communicate with the satellites. Iridium Communications 2-way messaging service
Snapdragon Satellite would have utilized frequencies in the L Band as well.
Inmarsat and
Ligado Networks (formerly
LightSquared) terminals use frequencies between 1525 and 1646.5 MHz.
Thuraya satellite phones use frequencies between 1525 and 1661 MHz. In January 2025
China Telecom Satellite Application Technology Research Institute, in association with Huawei, and others industry announced the
Tiantong was capable of providing regular
smartphones bidirectional access to satellite communications within their allocated
L-band frequency (as opposed to specific
satellite phones). Starlink has beta-tested a similar direct-to-cell service with T-Mobile since December 2024, operating in the upper L-Band (1900 MHz).
NOAA NOAA cyclically broadcasts weather data from its two geosynchronous satellites on 1694.1 MHz.
Aircraft surveillance The aircraft L-band ranges from 960–1215MHz. Aircraft can use
Automatic dependent surveillance-broadcast (ADS-B) equipment at 1090 MHz to communicate position information to the ground as well as between them for traffic information and avoidance. The 1090 MHz frequency (paired with 1030 MHz) is also used by
Mode S transponders, which ADS-B augments when operated at this frequency. The TCAS system also utilizes the 1030/1090MHz paired frequencies. ADS-B information can also be broadcast on the L band frequency of 978 MHz. DME and TACAN systems are also in this frequency band.
Amateur radio The Radio Regulations of the
International Telecommunication Union allow
amateur radio operations in the frequency range 1,240–1,300 MHz, and
amateur satellite up-links are allowed in the range 1,260–1,270 MHz. This is known as the
23-centimeter band by radio amateurs and as the L-band by
AMSAT.
Digital audio broadcasting In the
United States and
overseas territories, the L band is held by the
military for
telemetry, thereby forcing
digital radio to
in-band on-channel (IBOC) solutions. The standard
Digital Audio Broadcasting (DAB) allowed many broadcasting bands including 1452–1492MHz, but now only uses
Band III.
WorldSpace satellite radio used to broadcast in the 1467–1492 MHz L sub-band.
Digital video broadcasting DVB-H,
DVB-SH, and
DVB-T2 can operate in the L band.
Digital multimedia broadcasting T-DMB can operate in the L band.
Astronomy The band contains the hyperfine transition of neutral hydrogen (the
hydrogen line, 1420 MHz), which is of great astronomical interest as a means of imaging the normally invisible neutral atomic hydrogen in interstellar space. The band also contains
hydroxyl radical transition lines at 1665 and 1667 MHz. Consequently, parts of the L band are protected
radio astronomy allocations worldwide. Specifically, the 1400–1427 MHz and 1660.6–1670.0 MHz regions are protected. == References ==