FMeXtra is a deprecated in-band on-channel digital radio broadcasting technology created by Digital Radio Express. It was intended to allow a second all-digital signal to be simulcast with an existing analog FM radio station, offering a less noisy signal that would be particularly useful in urban environments where multipath distortion can seriously degrade analog FM transmissions. It can also support a second all-digital channel at the same frequency, allowing two channels to be broadcast by a single FM station.
FMeXtra was one of two competing systems considered by the FCC for standardization in the U.S., and by extension, Canada and Mexico. The other system, HD Radio, could carry up to four signals in a single channel and offer higher quality audio. FMeXtra's appeal was that it could be implemented at relatively low cost, requiring only a single rack mount case added to a radio station's existing equipment and transmitter plant. It required no license, unlike HD Radio which allows one free channel but requires 3% annual royalties for additional channels.
After extensive consultation, the FCC chose HD Radio over FMeXtra. FMeXtra continued for a time before rebranding itself VuCast as a datacasting play, but that saw little adoption and Digital Radio Express eventually went out of business. References to the system generally end around 2013.
The system is run from a single rack unit box called the X1 Encoder, which is actually based upon a personal computer server and digital audio hardware from Lynx Studio Technologies (LST). Control is entirely via software, via gigabit Ethernet, USB, serial port, and SVGA video monitor. All processing is handled internally by a Pentium 4 running Windows XP.
FMeXtra is fully compatible with HD Radio, which uses additional radio spectrum beyond the ±100 kHz signal. It is not compatible with all existing subcarriers. Thus, a radio station might have to remove its radio reading service for the blind, and replace it (and its dependent listeners' receivers) with a digital one. This would take up much less bandwidth, particularly since voice can be highly compressed. The signal is partitioned so that RBDS, stereo, or other existing subcarriers can be protected, at the expense of bandwidth. If used only for monophonic transmissions, no RDS protection exists for stations in Europe.
The codecs used are AAC and aacPlus v1 and v2 and sample rates of 8 kHz (telephone quality) to 96 kHz (surround sound quality). The other codecs used are AMR-WB+ that can create more multiple audio programs as well as limited multimedia can also be broadcast, as with HD Radio and DAB. The available broadcasting bandwidth for digital audio varies from 40 kbit/s while sharing the space with existing analog signals, or 156 kbit/s if all analog signals (except the base monophonic signal) are dropped. (For comparison, iBiquity's Hybrid Digital/analog system offers 100-150 kbit/s in shared mode, and 300 kbit/s in pure digital mode.)
The coverage is similar to FM Stereo, and therefore high ERP is required in larger urban areas, as with normal FM transmissions.
Digital Radio Express has since gone out of business, after a brief stretch where it rebranded itself as VuCast in an effort to emphasize the technology's datacasting capabilities.
North American FM bands are separated by 200 kHz while only using about 50 kHz for a high-quality stereo broadcast. This leaves significant amounts of unused spectrum between the channels. This unused spectrum led the FCC to strongly favor some sort of in-band standard for the digital transition. This is in contrast to European systems which use a similar amount of bandwidth for FM signals but typically separate the channels only 100 kHz. European stations favored moving to entirely new channels for digital broadcasts to avoid interfering with their existing FM signals. [1]
Two systems were evaluated during the late 1990s, FMeXtra and HD Radio. From a purely technical perspective, HD Radio was more advanced than FMeXtra, using newer compression and encoding to allow the signals to be flexibly allocated into the existing channels. FMeXtra normally added a single 48 kbps digital channel carried in the 62.5-98.5 kHz area of the channel (just above the audio signal). HD Radio offered several different modes that used up more of the empty spectrum, providing 96 to 120 kbps. FMeXtra allowed one stream of "good" quality, two medium, or four mono low-quality signals suitable for talk radio. HD Radio offered one high-fidelity signal, better than FM, or several mixtures of medium quality. [1]
Although HD Radio had superior technical capabilities (largely by using more bandwidth), FMeXtra was dramatically easier to implement. In the most common use-case, the existing FM signal would be fed into an FMeXtra encoder and then sent directly to the existing transmitter systems. The company did not charge any licensing, the only cost was the encoder box itself, around $10,000 when introduced. In contrast, HD Radio required a much more expensive encoder, about $50,000, generally required changes to the transmitter, and charged licensing fees on any additional channels. [1]
As the standardization effort continued, broadcasters clearly favored HD Radio. This was not due to any technical issues specifically, but due to the way radio channels are monetized. Each channel runs advertising that pays for the system, so adding more signals to an existing radio system has significant financial benefits. With FMeXtra, the system normally broadcasts only the existing channel, which would result in no additional revenue. HD Radio would add additional channels, thus generating additional income. [1]
In particular, HD Radio's ability to send one full-fidelity signal along with two or more signals of much higher quality than AM radio offered a significant practical benefit; those companies broadcasting on both FM and AM could move their AM stations to subchannels in their FM channels and turn off their AM transmitters. The combination of more channels and higher quality overwhelmed any financial benefit to FMeXtra's lower installation costs, and it was "left in the dust." [1]
This section needs to be updated.(September 2013) |
and others
Minnesota Reading Services for the Blind has 25 FMeXtra encoders and 7,500 special FMeXtra receivers without a visual display.
FMeXtra is not in use anymore in the BeNeLux. Short test where running on the following stations: [3] [4]
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Radio broadcasting is the broadcasting of audio (sound), sometimes with related metadata, by radio waves to radio receivers belonging to a public audience. In terrestrial radio broadcasting the radio waves are broadcast by a land-based radio station, while in satellite radio the radio waves are broadcast by a satellite in Earth orbit. To receive the content the listener must have a broadcast radio receiver (radio). Stations are often affiliated with a radio network that provides content in a common radio format, either in broadcast syndication or simulcast, or both. Radio stations broadcast with several different types of modulation: AM radio stations transmit in AM, FM radio stations transmit in FM, which are older analog audio standards, while newer digital radio stations transmit in several digital audio standards: DAB, HD radio, DRM.
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Digital Radio Mondiale is a set of digital audio broadcasting technologies designed to work over the bands currently used for analogue radio broadcasting including AM broadcasting—particularly shortwave—and FM broadcasting. DRM is more spectrally efficient than AM and FM, allowing more stations, at higher quality, into a given amount of bandwidth, using xHE-AAC audio coding format. Various other MPEG-4 codecs and Opus are also compatible, but the standard now specifies xHE-AAC.
Digital radio is the use of digital technology to transmit or receive across the radio spectrum. Digital transmission by radio waves includes digital broadcasting, and especially digital audio radio services.
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Broadcasttelevision systems are the encoding or formatting systems for the transmission and reception of terrestrial television signals.
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FM broadcasting is a method of radio broadcasting that uses frequency modulation (FM) of the radio broadcast carrier wave. Invented in 1933 by American engineer Edwin Armstrong, wide-band FM is used worldwide to transmit high-fidelity sound over broadcast radio. FM broadcasting offers higher fidelity—more accurate reproduction of the original program sound—than other broadcasting techniques, such as AM broadcasting. It is also less susceptible to common forms of interference, having less static and popping sounds than are often heard on AM. Therefore, FM is used for most broadcasts of music and general audio. FM radio stations use the very high frequency range of radio frequencies.
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