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 who include HD Radio pay a royalty, which is the main reason it failed to be fully-adopted as a standard feature. If the HD receiver loses the primary digital signal (HD‑1), it reverts 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, the data rates in HD Radio are substantially lower than from a CD, and the digital signals sometimes interfere with adjacent analog
AM band stations. (see §
AM, below).
AM The AM hybrid mode ("MA1") uses 30
kHz of bandwidth (±15
kHz), and overlaps
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 owner Bob Savage against
WBZ in Boston. The capacity of a 30
kHz channel on the AM band is limited. 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 sounds like
white noise – the sound of a , or a large waterfall, or a strong, steady wind through a dense
forest canopy, or similar.
All-digital AM All-digital AM ("MA3") allows for two modes: "Enhanced" and "core-only". • 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. Five AM stations have operated as all-digital / digital-only broadcasters, either on an experimental basis or 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 (WSHE since June 2024) was granted
special temporary authority from the
FCC in July 2018 to broadcast all-digital. It continues broadcast in digital-only mode under regular authorization. •
WMGG broadcast in all-digital mode from January 2021 until a new owner returned it to analog-only mode following a station sale in November 2021. •
WFAS broadcast in digital-only mode from May 2021 until its license was deleted in October 2024. •
WSRO broadcast in digital only-mode from December 2021 until the station went silent in March 2023. After a brief return to the air in 2024, its license was cancelled in March 2025. •
WYDE broadcast in all-digital mode from September 2023 until June 2025 when it returned to broadcasting in hybrid mode. The FCC requires stations that wish to multiplex their digital AM signals to request and receive permission to do so. 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". In early 2020 the FCC rejected a multiplex request from
WTLC.
FM opening test using
KDKA-FM HD‑1 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 can divide 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. FCC rules require that one channel be a simulcast of the analog signal so that when the primary digital stream cannot be decoded, a receiver can fall back to the analog signal. This requires
synchronization of the two, with a significant delay added to the analog service. In some cases, particularly during
tropospheric ducting events, an HD receiver will lock on to the digital stream 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. 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. 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.
Artist Experience 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.
EAS alerts 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 require extra equipment.
Bandwidth and power FM stereo stations typically require up to 280 kilohertz of
spectrum. The bandwidth of an FM signal 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 ±130
kHz of analog bandwidth. The primary main digital sidebands extend ±70
kHz on either side of the analog signal, thus taking a full 400
kHz of spectrum. In extended hybrid mode, the analog signal is restricted to ±100
kHz. Extended primary sidebands are added to the main primary sidebands using the extra ±30
kHz of spectrum created by restricting the analog signal. Extended hybrid provides up to approximately 50 kbit/s additional capacity. Any existing
subcarrier services (usually at 92
kHz and 67
kHz) that must be shut down to use extended hybrid can be restored through use of
digital subchannels. 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), i.e., the digital signal power is 1% of the analog carrier power. This low power, plus the uniform, noise-like nature of the digital modulation, is what reduces its potential for co-channel interference with distant analog stations. 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 dB
c), 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.
Asymmetric sidebands In May 2025, the FCC confirmed it would permit asymmetric sideband levels to be used. The total power in the asymmetric side bands must not exceed that which would be permitted when the sidebands are symmetrical. The use of asymmetrical sidebands can reduce interference to an adjacent FM channel. ==Comparison to other digital radio standards==