HD Radio (HDR) is a trademarked term for the in-band on-channel (IBOC) digital radio technology. HD Radio is used by AM and FM radio stations – mostly in the United States, Canada, and Mexico, with a few implementations outside North America. The system transmits additional digital data associated with an existing radio station's standard analog signals, re-broadcasting the same signal in a digital format, with less noise. The digital data may also include up to three additional digital radio signals, which can be used to broadcast other stations within the same frequency allocation.
HD Radio allows for an all-digital mode. Three AM stations use it, one under experimental authorization, the other two under new rules adopted by the FCC in October 2020. All other AM radio and FM radio stations that use HD, simulcast both digital and analog audio on the same frequency (a hybrid digital-analog signal) as well as to add new subchannels and text information. HD Radio broadcasting's content is currently free-to-air, although prospective listeners still must purchase new receivers, in order to hear the digital content of the transmission.
iBiquity developed HD Radio™, and the system was selected by the U.S. Federal Communications Commission (FCC) in 2002 as a digital audio broadcasting method for the United States. It is officially known as NRSC‑5, with the latest version being NRSC‑5‑D.
iBiquity was acquired by DTS in September 2015 bringing the HD Radio™ technology under the same banner as DTS’s eponymous theater surround sound systems. The HD Radio™ technology and trademarks were subsequently acquired by Xperi Holding Corporation in 2016.
HD Radio™ is one of several digital radio standards which are generally incompatible with each other:
- Compatible AM Digital (CAM‑D) for AM stations.
- Digital Audio Broadcasting (DAB), a.k.a. Eureka 147, is the most common standard in Europe.
- Digital Radio Mondiale (DRM‑30 and DRM+ configurations) was intended mostly for shortwave radio.
- FMeXtra was a competing U.S. standard, but has since gone stagnant.[when?]
By May 2018, iBiquity Digital Co. claimed its HD Radio technology was used by more than 3,500 individual services, mostly in the United States. This compares with more than 2,200 services operating with the DAB system.
The bandwidth required for HD FM is increased to 400 kHz, for analog-digital hybrid transmission with extra sidebands. This makes adoption outside the United States problematic: In the United States, the FM channels are spaced 200 kHz apart, as opposed to the spacing elsewhere, which is normally 100 kHz. From long-standing FCC licensing practice, stations assigned to geographicly overlapping or adjacent coverage areas will be assigned frequencies separated by (at least) 400 kHz, in order to provide a further degree of protection against interference between stations on adjacent frequencies, than could be achieved with the 200 kHz spacing alone. Hence the wide 200 kHz U.S. spacing in combination with geographical separation means that the needed 400 kHz spacing already exists; the only impediment is the extent of cross-station interference can be prevented by the digital technology and / or tolerated in practice. The extra space is used for the digital sidebands; outside the U.S., spacing can be 300 kHz, which causes problems with some of the sidebands.
The FCC has not indicated any intent to end analog radio broadcasting as it did with analog television, since it would not result in the recovery of any radio spectrum rights which could be sold. Thus, there is no deadline by which consumers must buy an HD receiver. In addition, there are many more analog AM band and FM band receivers, than there ever were analog televisions that relied on over-the-air signals; many of these are car receivers or radios embedded in other technology that cannot be upgraded (like cell phones or emergency lighting).
Digital information is transmitted using OFDM with an audio compression format called HDC (High-Definition Coding). HDC is a proprietary codec based upon, but incompatible with, the MPEG-4 standard HE-AAC. It uses a modified discrete cosine transform (MDCT) audio data compression algorithm.
HD equipped stations pay a one-time licensing fee for converting their primary audio channel to iBiquity's HD Radio™ technology, and 3% of incremental net revenues for any additional digital subchannels. The cost of converting a radio station can run between $100,000 and $200,000. Receiver manufacturers pay a royalty.
If the primary digital signal (HD‑1) is lost the HD receiver will revert to the analog signal, thereby providing seamless operation between the newer and older transmission methods. The extra HD‑2 and HD‑3 streams do not have an analog simulcast; consequently, their sound will drop-out or "skip" when digital reception degrades (similar to digital television drop-outs). Alternatively the HD signal can revert to a more robust 20 kbit/s stream, although the sound quality is then reduced to conventional AM-level. Datacasting is also possible, with metadata providing song titles or artist information.
iBiquity Digital claims that the system approaches CD quality audio and offers reduction of both interference and static; however, some listeners have complained of increased interference on the analog AM band (see § AM, below).
The AM hybrid mode ("MA1") uses 30 kHz of bandwidth (±15 kHz), and fully overlaps the adjacent channels on both sides of the station's assigned channel. Some nighttime listeners have expressed concern this design harms reception of adjacent channels with one formal complaint filed regarding the matter: WYSL-AM owner Bob Savage against WBZ‑AM in Boston.
Sending digital data through a 30 kHz channel is roughly equivalent to sending data through two 33 kbit/s analog telephone lines, thus limiting the maximum possible throughput. By using spectral band replication the HDC+SBR codec is able to simulate the recreation of sounds up to 15,000 Hz, thus achieving moderate quality on the bandwidth-tight AM band. The HD Radio AM hybrid mode offers two options which can carry approximately 40~60 kbit/s of data, with most AM digital stations defaulting to the more-robust 40 kbit/s mode, which features redundancy (same data is broadcast twice).
The digital radio signal received on a conventional AM receiver tuned to an adjacent channel causes white noise – the sound of a "hiss", or a large waterfall, or a strong, steady wind through a dense forest canopy, or similar.
- In enhanced mode, the primary, secondary and tertiary carriers are transmitted, allowing for a maximum throughput of 40.2 kbit/s while using 20 kHz of bandwidth out to the station's 0.5 mV/m contour. Inside this contour, stereo audio along with graphics (station logo and “artist experience” album artwork) and text information (the station's call sign, title, album, and artist) can be decoded by the receiver.
- Beyond the station's 0.5 mV/m contour, typically only the primary carriers can be received, which restricts the maximum throughput to 20.2 kbit/s while only requiring 10 kHz of bandwidth.
- In core-only mode, the station only transmits the primary carriers.
When the receiver can only decode the primary carriers in either mode, the audio will be mono and only text information can be displayed. The narrower bandwidth needed in either all-digital mode compared to hybrid mode reduces possible interference to and from stations broadcasting on adjacent channels. However, all-digital AM lacks the analog signal for fallback when the signal is too weak for the receiver to decode the primary digital carrier.
Three stations operate as all-digital / digital-only broadcasters:
- WWFD has had special temporary authority from the FCC since July 2018 to broadcast all-digital.
- WMGG (since January 2021) and WFAS (since May 2021) broadcast all-digital under new rules adopted by the FCC on 27 October 2020 that allow any AM station to voluntarily choose to convert to all-digital operation.
WWFD experimented with using a digital subchannel, operating a second channel (HD2) at a low data rate while reducing the data rate of the primary channel (HD1). In October 2020, the FCC concluded from WWFD's experiments:
- "The [experimental] record does not establish that an audio stream on an [AM] HD-2 subchannel is currently technically feasible".
The FM hybrid digital / analog mode offers four options which can carry approximately 100, 112, 125, or 150 kbit/s of data carrying (lossy) compressed digital audio depending upon the station manager's power budget and desired range of signal. HD FM also provides several pure digital modes with up to 300 kbit/s rate, and enabling extra features like surround sound. Like AM, purely-digital FM provides a "fallback" condition where it reverts to a more robust 25 kbit/s signal.
FM stations have the option to subdivide their datastream into sub-channels (e.g., 88.1 HD‑1, HD‑2, HD‑3) of varying audio quality. The multiple services are similar to the digital subchannels found in ATSC-compliant digital television using multiplexed broadcasting. For example, some top 40 stations have added hot AC and classic rock to their digital subchannels, to provide more variety to listeners. Stations may eventually go all-digital, thus allowing as many as three full-power channels and four low-power channels (seven total). Alternatively, they could broadcast one single channel at 300 kbit/s.
Where the digital signal fails, the analog signal is used as a fallback for the main digital channel (normally HD‑1), requiring synchronization of the two. This requires a significant delay being added to the analog service. Current FCC rules require that one channel be a simulcast of the analog signal. In some cases, particularly during tropospheric ducting events, an HD receiver will lock on to the digital sidebands of a distant station, even though there is a much stronger local analog-only station on the same frequency. With no automatic identification of the station on the analog signal, there is no way for the receiver to recognize that there is no correlation between the two.[a] The listener can possibly turn HD reception off (to listen to the local station, or avoid random flipping between the two stations), or listen to the distant stations and try to get a station ID.
Although the signals may be synchronized at the transmitter and reach the receiving equipment simultaneously, what the listener hears through an HD unit and an analog radio played together can be distinctly unsynchronized. This is because all analog receivers process analog signals faster than digital radios can process digital signals. The digital processing of analog signals in an HD Radio also delays them. The resulting unmistakable "reverb" or echo effect from playing digital and analog radios in the same room or house, tuned to the same station, can be annoying. It is more noticeable with simple voice transmission than with complex musical program content.[b]
Stations can transmit HD through their existing antennas using a diplexer, as on AM, or are permitted by the FCC to use a separate antenna at the same general location, or at a site licensed as an analog auxiliary, provided it is within a certain distance and height referenced to the main analog signal. The limitation assures that the two transmissions have nearly the same broadcast range, and that they maintain the proper ratio of signal strength to each other so as not to cause destructive interference at any given location where they may be received.
HD Radio supports a service called “Artist Experience” in which the transmission of album art, logos, and other graphics can be displayed on the receiver. Album art and logos are displayed at the station's discretion, and require extra equipment. An HD Radio manufacturer should pass the iBiquity certification, which includes displaying the artwork properly.
Since 2016, newer HD Radios support Bluetooth and Emergency Alert System (EAS) alerts in which the transmission of traffic, weather alerts, AMBER, and security alerts can be displayed on the radio. As with “Artist Experience”, emergency alerts are displayed at the station's discretion, and requires extra equipment.
Bandwidth and power
FM stereo stations typically require up to 280 kilohertz of spectrum. The bandwidth of an FM carrier is found by doubling the sum of the peak deviation (usually 75 kHz) and the highest baseband modulating frequency (around 60 kHz when RBDS is used). Only 15 kHz of the baseband bandwidth is used by analog monaural audio (baseband), with the remainder used for stereo, RBDS, paging, radio reading service, rental to other customers, or as a transmitter/studio link for in-house telemetry.
In regular hybrid mode a station has ±100 kHz of analog bandwidth and adds an extra ±30 kHz guard band and ±70 kHz for its digital signals, thus taking a full 400 kHz of width. FM stations also have the option to discontinue existing subcarrier services (usually at 92 kHz and 67 kHz) in order to carry extended HD, though such services can be restored through use of the digital subchannels that are then made available. However, this requires the replacement of all related equipment both for the broadcasters and all of the receivers that use the services shifted to HD subchannels.
The ratio of power of the analog signal to the digital signal was initially standardized at 100:1 (−20 dBc), making the digital signal 1% of the analog carrier power. Unlike with subcarriers, where the total baseband modulation is reduced, there is no reduction to the analog carrier power. The National Association of Broadcasters (NAB) requested a 10 dB (10×) increase in the digital signal from the FCC. This equates to an increase to 10% of the analog carrier power, but no decrease in the analog signal. This was shown to reduce analog coverage because of interference, but results in a dramatic improvement in digital coverage. Other levels were also tested, including a 6 dB or fourfold increase to 4% (−14 dBc or 25:1). National Public Radio was opposed to any increase because it is likely to increase interference to their member stations, particularly to their broadcast translators, which are secondary and therefore left unprotected from such interference. Other broadcasters are also opposed (or indifferent), since increasing power would require expensive changes in equipment for many, and the already-expensive system has so far given them no benefit.
There are still some concerns that HD FM will increase interference between different stations, even though HD Radio at the 10% power level fits within the FCC spectral mask. North American FM channels are spaced 200 kHz apart. An HD broadcast station will not generally cause interference to any analog station within its 1 mV/m service contour – the limit above which the FCC protects most stations. However, the IBOC signal resides within the analog signal of the immediately adjacent station(s). With the proposed power increase of 10 dB, the potential exists to cause the degradation of the second-adjacent analog signals within its 1 mV/m contour.
On 29 January 2010, the U.S. FCC approved a report and order to voluntarily increase the maximum digital effective radiated power (ERP) to 4% of analog ERP (−14 dBc), up from the previous maximum of 1% (−20 dBc). Individual stations may apply for up to 10% (−10 dBc) if they can prove it will not cause harmful interference to any other station. If at least six verified complaints of ongoing RF interference to another station come from locations within the other station's licensed service geographic region, the interfering station will be required to reduce to the next level down of 4%, 2% (−17 dB), or 1%, until the FCC finally determines that the interference has been satisfactorily reduced. The station to which the interference is caused bears the burden of proof and its associated expenses, rather than the station that causes the problem. For grandfathered FM stations, which are allowed to remain over the limit for their broadcast class, these numbers are relative to that lower limit rather than their actual power.
Comparison to other digital radio standards
HD versus DAB
Some countries have implemented Eureka-147 Digital Audio Broadcasting (DAB) or its successor DAB+. DAB broadcasts a single station that is approximately 1.5 megahertz wide (≈1 megabit per second). That station is then subdivided into multiple digital streams of between 9~12 programs. In contrast, HD FM requires 400 kHz bandwidth – compatible with the 200 kHz channel spacing traditionally used in the United States – with capability of 300 kbit/s in digital-only mode.
The first generation DAB uses the MPEG-1 Audio Layer II (MP2) audio codec which has less efficient compression than newer codecs. The typical bitrate for DAB stereo programs is 128 kbit/s or less and as a result most radio stations on DAB have a poorer sound quality than FM does under similar conditions. Many DAB stations also broadcast in mono. In contrast, DAB+ uses the newer AAC+ codec and HD FM uses a codec based upon the MPEG-4 HE-AAC standard.
Before DAB+ was introduced, DAB's inefficient compression led in some cases to "downgrading" stations from stereophonic to monaural, in order to include more channels in the limited 1 Mbit/s bandwidth.
Digital radio, such as DAB, DAB+, and HD FM currently often have smaller coverage of markets as compared to analog FM, radios are more expensive, and reception inside vehicles and buildings may be poor, depending on the frequencies used. HD Radio shares most of these same flaws (see criticisms below). On the other hand, digital radio allows for more stations and less susceptibility for disturbances in the signal. In the United States, however, digital broadcast technologies other than HD Radio™ (such as DAB+) have not been approved for use on either the FM or AM bands.
HD versus DRM
Digital Radio Mondiale (DRM 30) is a system designed primarily for shortwave radio with compatible radios already available for sale. DRM 30 is similar to HD AM, in that each station is broadcast via channels spaced 10 kHz (or 9 kHz in some regions) on frequencies up to 30 MHz. The two standards also share the same basic modulation scheme (COFDM), and HD AM uses a proprietary codec. DRM 30 operates with any of a number of codecs, including AAC, Opus, and HVXC. The receiver synchronization and data coding are quite different between HD AM and DRM 30. As of 2015 there are several radio chipsets available which can decode AM, FM, DAB, DRM 30 and DRM+, and HD AM and HD FM.
- Hybrid mode (digital/analog) - 10 kHz analog plus 5 kHz digital bandwidth allows 5–16 kbit/s data rate;
- 10 kHz digital-only bandwidth confined to ±5 kHz of the channel center allows 12–35 kbit/s;
- 20 kHz digital-only bandwidth using ±10 kHz (including half of the adjacent channels) allows 24–72 kbit/s.
- Shorter broadcast distance in hybrid mode compared to an analog AM signal
- Poor reception inside vehicles and buildings
- Interference with adjacent channels when using the 20 kHz mode though in all-digital mode the signal fits inside the designated channel mask.
Digital Radio Mondiale is an open standards system, albeit one that is subject to patents and licensing. HD Radio™ is based upon the intellectual property of iBiquity Digital Co. / Xperi Holding Co. The United States uses DRM for HF / shortwave broadcasts.
Acceptance and criticism
Awareness and coverage
According to a survey dated 8 August 2007 by Bridge Ratings, when asked the question, "Would you buy an HD Radio in the next two months?" Only 1.0% responded "yes".
Some broadcast engineers have expressed concern over the new HD system. A survey conducted in September 2008 saw a small percentage of participants that confused HD Radio with satellite radio.
Many first-generation HD Radios had insensitive receivers, which caused issues with sound quality. The HD Radio digital signal is 10–20 dB below the analog signal in the station's transmission. In addition, commentors have noted that the analog section of some receivers were inferior compared to older, analog-only models.
However, since 2012 HD capable receiver adoption has significantly increased in most newer cars, and several aftermarket radio systems both for vehicles and home use contain HD Radio receivers and special features such as Full Artist Experience. iBiquity reports that 78% of all radio listening is done on stations that broadcast in HD. There are an increasing number of stations switching to HD or adding subchannels compatible with digital radio, such as St. Cloud, Minnesota where many local radio outlets find a growing number of listeners tuning in to their HD signals, which in turn has benefited sales.
Different format and compatibility standards
Even though DAB and DRM standards are open-standards and pre-date HD Radio™, HD receivers cannot be used to receive these stations when sold or moved overseas (with certain exceptions; there are HD stations in Sri Lanka, Thailand, Taiwan, Japan, Romania, and a few other countries).
DAB and DRM receivers cannot receive HD signals in the US. The HD system, which enables AM and FM stations to upgrade to digital without changing frequencies, is a different digital broadcasting standard. The lack of a common standard means that HD receivers cannot receive DAB or DRM broadcasts from other countries, and vice versa, and that manufacturers must develop separate products for different countries, which typically are not dual-format.
HD Radio does not use ATSC, the standard for digital television in the United States, and so fails to recover the former TV and FM radio compatibility enjoyed by TV channel 6 broadcasters. In the days of analog television, the lowest sliver of the FM broadcast band (87.7–87.9 MHz) overlapped with the audio subcarrier of U.S. analog television's channel 6; [d] because the NTSC analog television standard used conventional analog FM to modulate the audio subcarrier, the audio of television stations that broadcast on channel 6 could be heard on most FM receivers. In earlier days of television and radio, several television stations exploited this overlap and operated as radio stations (a process that still continues with some low-powered stations, which are still allowed to broadcast in analog, for the time being). Full-powered television stations were forced to cease their analog broadcast in June 2009, with low-powered stations scheduled to cease analog broadcast by September 2015. Because the digital television and all digital radio standards are incompatible, HD receivers are not able to receive digital TV signals on the 87.75 MHz frequency, eliminating the former dual-medium compatibility of channel 6 television stations.
Promotion for HD Radio often fails to make clear that some of its features are mutually incompatible with other features. For example, the FM system has been described as "CD quality"; however, the FM system also allows multiplexing the data stream between two or more separate programs. A program utilizing one half or less of the data stream does not attain the higher audio quality of a single program allowed the full data stream. The FCC has declared
- "one free over-the-air digital stream [must be] of equal or greater quality than the station’s existing analog signal".[e]
The broadcasting industry is seeking FCC approval on future HD receiver models, for conditional access; that is, enabling the extra subchannels to be available only by paid subscription. NDS[f] has made a deal with iBiquity to provide HD Radio with an encrypted content-delivery system called “RadioGuard”. NDS claims that RadioGuard will "provide additional revenue-generating possibilities".
A few existing FM receivers tuned to a channel broadcasting a HD signal are prone to increased noise on the analog signal, called "HD Radio self-noise", due to analog demodulation of the digital signal(s). In some high fidelity FM receivers in quality playback systems, this noise can be audible and irritating. A few existing FM receivers might require major internal modifications to the internal filters or the addition of a post-detection filter may be required to prevent degradation of the analog signal quality on stations broadcasting HD Radio™.
Reduced analog signal
Radio stations are licensed in the United States to broadcast at a specific effective radiated power level. NPR Labs recently did a study of predicted HD Radio operation if power levels were increased to 10% of maximum power as is now allowed by the FCC under certain circumstances, and found the digital signal would increase RF interference on FM. However the boosted digital HD signal coverage would then exceed analog coverage, with 17% more population covered in vehicles but 17% less indoors.
The costs of installing the system, including fees, vary from station to station, according to the station's size and existing infrastructure. Typical costs are at least several tens of thousands of dollars at the outset[g] plus per-channel annual fees (3% of the station's annual revenue) to be paid to Xperi for HD‑2 and HD‑3 (HD‑1 has no royalty charge). Large companies in larger media markets – such as iHeartRadio or Cumulus Broadcasting – can afford to implement the technology for their stations. However, community radio stations, both commercial and noncommercial, in many cases cannot afford the US$1,000 yearly Xperi fee assessed to LPFM stations. During mid-2010 a new generation of HD Radio broadcasting equipment was introduced, greatly lowering the startup costs[g] of implementing the system.
Current HD Radio receivers cost anywhere from around US$50 to several hundred dollars, compared to regular FM radios which can sometimes even be found at dollar stores. Although costs have historically been higher for HD hardware, as adoption has increased, prices have lowererd, and receivers containing HD Radio are becoming more commonplace – especially as more stations broadcast in HD format.
Conventional analog-only FM transmitters normally operate with “class C” amplifiers, which are efficient, but not linear; HD Radio requires a different amplifier class. A class C amplifier can operate with overall transmitter efficiency higher than 70%.[h] Digital transmitters need to operate in one of the other amplifier classes – one that is close to linear, and linearity costs efficiency. A modern hybrid HD FM transmitter typically achieves 50~60% efficiency, whereas an HD digital-only FM transmitter should manage just 40~45%. The reduced efficiency causes significantly increased costs for electricity and for cooling.
Until 2013, the HD Digital Radio Alliance,[i] acted as a liaison for stations to choose unduplicated formats for the extra channels (HD‑2, HD‑3, etc.). Now, iBiquity works with the major owners of the stations to provide various additional choices for listeners, instead of having several stations independently deciding to create the same format. HD‑1 stations broadcast the same format as the regular FM (and some AM) stations, and many of these stations offer one, two, or even three subchannels (designated HD‑2, HD‑3, HD‑4) to complement their main programming.
iHeartRadio is selling programming of several different music genres to other competing stations, in addition to airing them on its own stations. Some stations are simulcasting their local AM or lower-power FM broadcasts on sister stations' HD‑2 or HD‑3 channels, such as KMBZ-FM in Kansas City simulcasting 610 AM KCSP���AM's programming on 96.5 FM‑HD2. It is common practice to broadcast an older, discontinued format on HD‑2 channels; for example, with the recent disappearance of the smooth jazz format from the analog radio dial in many markets, stations such as WDZH‑FM in Detroit, Michigan (formerly WVMV), WFAN-FM in New York City, and WNWV-FM in Cleveland, Ohio program smooth jazz on their HD‑2 or HD‑3 bands. Some HD‑2 or HD‑3 stations are even simulcasting sister AM stations. In St. Louis, for example, clear-channel KMOX‑AM (1120 kHz analog and HD) is simulcast on KEZK-FM 102.5 FM‑HD3. KBCO‑FM in Boulder, Colorado uses its HD‑2 channel to broadcast exclusive live recordings from their private recording studio. CBS Radio is implementing plans to introduce its more popular superstations into distant markets (KROQ-FM into New York City, WFAN‑AM into Florida, and KFRG-FM and KSCF‑FM into Los Angeles) via HD‑2 and HD‑3 channels.
On 8 March 2009, CBS Radio inaugurated the first station with an HD4 subchannel, WJFK-FM in Washington, D.C., a sports radio station which also carries sister sports operations WJZ-FM from Baltimore; Philadelphia's WTEL‑AM and WIP-FM; and WFAN‑AM from New York.[j] Since then numerous other channels have implemented HD‑4 subchannels as well, although with nearly 100% talk-based formats, because of the reduced audio quality. For example, KKLQ‑FM in Los Angeles operates an HD‑4 signal and aired The Mormon Channel which was 99% talk.
Public broadcasters are also embracing HD Radio. Minnesota Public Radio offers a few services: KNOW-FM, the MPR News station in the Twin Cities, offers music service Radio Heartland on 91.1 FM‑HD2 and additional news programming called ���BBC News and More” on 91.1 FM‑HD3; KSJN-FM, the classical MPR station in the Twin Cities, provides “Classical 24” service on 99.5 FM‑HD2; and KCMP-FM, on 89.3 FM in the Twin Cities, offers “Wonderground Radio”, music for kids and their parents, on 89.3 FM‑HD2.
KPCC‑FM (Southern California Public Radio), heard on 89.3 FM in Los Angeles, offers a digital simulcast of its analog channel on 89.3 FM‑HD1 and MPR's music service KCMP-FM on 89.3 FM‑HD2 in Los Angeles.
New York Public Radio in New York City, WNYC-AM and WNYC-FM, (d.b.a. WNYC) re-broadcasts a locally programmed, all-classical service from WQXR-FM called “Q2”, on 93.9 FM‑HD2. The service launched in March 2006. On 8 October 2009, the format was moved to WQXR‑HD2 (WXNY-FM) on 105.9 FM when WQXR-FM was acquired by New York Public Radio as part of a frequency swap with Univision Radio for their former frequency. The programming on the WNYC-FM‑HD2 channel now is a rebroadcast of WQXR-FM, in order to give full coverage of WQXR-FM programming in some form, as the 105.9 FM signal is weaker, and does not cover the whole area.
WMIL-FM in Milwaukee has offered an audio simulcast of Fox affiliate WITI‑TV on their HD‑3 subchannel since August 2009 as part of a news and weather content agreement between iHeartRadio and WITI‑TV. This restored WITI‑TV's audio to the Milwaukee radio dial after a two-month break, following the digital transition; as a channel 6 analog television station WITI‑TV exploited the 87.7 FM audio quirk as an advantage, in order to allow viewers to hear the station's newscasts and Fox programming on their car radios.
KYXY‑FM, operated by CBS in San Diego on 96.5 FM and offers their HD‑2 channel as one of the few “subchannel only” independent Christian music based formats on HD Radio. Branded as “The Crossing”, it is operated by Azusa Pacific University.
College radio has also been impacted by HD Radio, stations such as WBJB-FM which is a public station on a college campus offer a student run station as one of the multicast channels. WKNC-FM in Raleigh, NC, runs college radio programming on HD‑1 and HD‑2, and electronic dance music on WolfBytes Radio on WKNC-FM‑HD3 .
Some commercial broadcasters also use their HD‑2 channels to broadcast the programming of noncommercial broadcasters. Bonneville International uses its HD‑2 and HD‑3 channels to broadcast Mormon Channel which is entirely noncommercial and operates solely as a public service from Bonneville's owner, The Church of Jesus Christ of Latter-day Saints. That network of eight HD‑2 and HD‑3 stations was launched on 18 May 2009 and was fully functional within two weeks. Also, in Detroit, WMXD-FM, an urban adult contemporary station, airs the contemporary Christian K-Love format on its HD‑2 band (the HD‑2 also feeds several analog translators around the metropolitan area – see below), due to an agreement between iHeartMedia and K-Love owner Educational Media Foundation (EMF), allowing EMF to program WMXD-FM's HD‑2 channel. On a similar note, Los Angeles' KRRL 92.3 FM‑HD3 signal rebroadcasts EMF's Air1, and in Santa Barbara KLSB 97.5 FM airs K-Love on its primary frequency, and rebroadcasts Air1 on HD‑2 (though neither supports “Artist Experience”).
Although broadcast translators are prohibited from originating their own programming, the FCC has controversially allowed translator stations to rebroadcast in standard analog FM the audio of an HD Radio channel of the primary station the translator is assigned to. This also allows station owners, who already usually own multiple stations locally and nationally, to avoid the rulemaking process of changing the table of allotments as would be needed to get a new separately-licensed station, and to avoid exceeding controlling-interest caps intended to prevent the excessive concentration of media ownership. Such new translator stations can block new LPFM stations from going on the air in the same footprint. Translator stations are allowed greater broadcast range (via less restrictive height and power limitations) than locally originated LPFM stations, so they may occupy a footprint in which several LPFMs might have been licensed otherwise.
In addition to the controversial practice of converting the HD-only secondary radio channels of a primary station into analog FM in areas where the primary station's signal can already readily be received, translators can also be used in a more traditional manner to extend the range of the full content of the primary station, including the unmodified main signal and any HD Radio sub-channels, in areas where the station has poor coverage or reception, as is done via the remote transmitter K202BD in Manti, Utah, which rebroadcasts both the analog and digital signals of KUER-FM from Salt Lake City.
In order to do this, HD Radio may be passed along from the main station via a "bent pipe" setup, where the translator simply makes a frequency shift of the entire channel, often by simple heterodyning. This may require an increase in bandwidth in both the amplifier and radio antenna if either is too narrowband to pass the wider signal, meaning one or both would have to be replaced. Baseband translators which use a separate receiver and transmitter require an HD Radio transmitter, just as does the main station. Translators are not required to pass through HD Radio, and the vast majority of existing translators which repeat FM stations running hybrid HD signals do not repeat the HD part of the radio broadcast, due to technical limitations in equipment designed before the advent of HD Radio™ technology.
Automotive and home/professional
By 2012, there were several HD receivers available on the market. A basic model costs around US$50.
The list of automotive HD receiver manufacturers includes:
Most car manufacturers offer HD receivers as audio packages in new cars, including:
Home and office listening equipment is currently[when?] available from roughly a dozen companies, in both component receiver and tabletop models, including:
Initially, portable HD receivers were not available due to the early chipsets either being too large for a small enclosure and / or needing too much power to be practical for a battery-operated device. However, in January 2008 at the Consumer Electronics Show (CES) in Las Vegas, iBiquity unveiled a prototype of a new portable receiver, roughly the size of a cigarette pack. Two companies are currently making low-power chipsets for HD receivers:
At least four companies presently make portable HD receivers:
- Coby Electronics Corporation produced the first HD portable – the Coby HDR‑700 portable HD receiver for both AM and FM.
- Griffin Technology produced an HD receiver designed to plug into the dock connector of an Apple iPod, or iPhone, with tuning functionality provided via software through the device's multi-touch display. This product is now discontinued.
- Best Buy started selling the Insignia NS‑HD01, a house brand portable unit on 12 July 2009. It was the second portable HD receiver to come to the general market and features FM‑only playback and a non-removable rechargeable battery which charges via mini USB. The Insignia unit sold in 2009 for around US$50 – the least expensive receiver available. Best Buy discontinued the NS‑HD01 model by September 2019, but it continued to be sold.[when?]
- Microsoft released the Zune HD on 15 September 2009. It includes an HD receiver embedded in the media device. The Zune HD is now discontinued.[when?]
Open Source Software-Defined Receiver (SDR)
- Station identification is sent by voice, or as RBDS data, but not all stations transmit RBDS.
- Note that the "reverb" effect is limited to analog vs. digital receivers, or in rare cases, digital receivers with remarkably different circuitry. Multiple receivers that are all HD (of the same make and model, at least), or multiple receivers that are all analog, in the same room or house, will not produce a noticeable echo.
Holm (2007) The sound quality in DAB digital radio, SUMMARY (in English):
This analysis of the audio quality of DAB has been made independently of the broadcasting companies and aims at balancing their information. Through measurement of the audio signal and through informal listening, we have found that DAB suffers from several problems:
- The stereo image is smeared due to heavy use of joint stereo coding. Often the stereo image lacks focus and gives incorrect localization of instruments, in certain cases there is also incorrect balance between a vocalist and the background music.
- The treble cut-off frequency is usually as low as 14 kHz and the result is a lack of brightness and a veiled sound stage. In particular young people will notice this degradation.
- Three stations use 160 kbps with an audio quality similar to FM: P2, Alltid Klassisk1 and P4
- Twelve stations use 128 kbps with lower quality than FM, incl. P1 and P3.
- Two stations transmit in mono at rates of 80 and 96 kbps (Radio 2 Digital Moox and NRK Barn2)
The broadcast companies want us to make a choice between FM, with the best audio quality in stationary receivers, and DAB which is best in a car. Today this is an unnecessary choice as there are no technological problems in making a digital radio which is better than FM on all accounts:
- Reception without garbling in cars
- Capacity for all the stations one wants
- Audio with near-CD quality
- — Steve Holm (2007)
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Software defined radio news and projects; also featuring Airspy, HackRF, FCD, SDRplay, and more.
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