What is DRM - Digital Radio Mondiale
- overview, introduction or tutorial about the basics of what is Digital
Radio Mondiale DRM, the new standard to replace AM broadcasting.
Digital Radio Mondiale (DRM) is set to revolutionise
broadcasting on the long, medium and short wave bands. Since the very earliest
days of broadcasting these wavebands have been filled with signals that are
amplitude modulated. These transmissions are of low audio quality and
particularly in recent years there has been a move away from these bands to find
higher quality transmissions. Broadcasts in the VHF FM band have received far
more listeners with the result that audience figures are dropping for AM
broadcasting. Now DAB Digital Radio is available in many countries and this has
set new standards in broadcasting. The next stage is to improve the
transmissions on the long medium and short wave bands. As the requirements are
very different to those experienced on the higher frequencies the DAB standard
is not applicable and as a result a totally new system has been developed. Known
as DRM it provides many of the improvements that are badly needed along with the
flexibility to allow for future developments.
What is DRM?
DRM itself is a consortium of broadcasters, network
operators, equipment manufacturers, broadcasting unions, regulatory bodies and
other organisations representing 29 countries. It was founded in Guangzhou,
China in 1998 and now has its headquarters in Geneva. Now with 82 members, the
wide base of its membership has been part of the reason for its success. It has
been able to draw on the experience of the membership to ensure that the
resulting standard met the requirements, and it has also drawn on the experience
gained by the Eureka project that was set up to develop DAB Digital Radio. As a
result the new system has come to fruition remarkably swiftly. A preliminary
system was designed and tested within a laboratory and this was later extended
to include field trials on air to ensure that the new system would successfully
meet all the requirements.
The DRM system
When the specification for DRM, Digital Radio Mondiale was
being drawn up there were a number of key requirements that needed to meet. The
main thrust of the development was to ensure that far greater audio quality
could be achieved, but this needed to be achieved whilst keeping the
transmissions in a form where they could operate alongside the existing AM
transmissions. This meant having the ability for the transmissions to occupy a
variety of different bandwidths dependent up the location and frequencies in
use. In the Americas a 10 kHz channel spacing is used on the medium wave band
whilst in Europe there is a 9 kHz spacing. On the short wave bands a 5 KHz
channel spacing has been adopted. It is necessary for the new standard to be
able to be compatible with these whilst offering the possibility of other
bandwidth options for the future.
Data can also transmitted. Not only does this supply
information required for decoding the signal but it also allows data to be
transmitted in support of the programme. One particularly useful feature for the
short wave bands is that a list of alternative frequencies is transmitted so
that listeners can be transferred to better channels very easily as conditions
change.
Another advantage of the new system is that it can support
what is termed a single frequency network (SFN). This allows a single frequency
to be re-used even within the coverage area of the first transmitter without
mutual interference. Currently frequencies can only be re-used used outside the
coverage area of the first transmitter to avoid interference problems. By using
an SFN, far more efficient use can be made of the available channels. With
spectrum bandwidth always in short supply, this is another important feature.
DRM transmissions
There are two main elements to the new transmission system.
These are the audio coding and the RF modulation used.
The main audio encoding system employs two main techniques.
The first is called Advanced Audio Coding (AAC). It is found that the ear does
not perceive all the sounds that are heard. A strong sound on one frequency will
mask out others close in frequency that may be weaker. AAC, therefore, analyses
each section of the spectrum and only encodes those sounds that will be
perceived.
However AAC on its own does not provide sufficient
compression of the data to enable the transmissions to be contained within the
narrow transmission bandwidths required. To provide the additional data
compression required a scheme known as Spectral Band Replication (SBR) is
employed. This analyses the sounds in the highest octave which are normally from
sounds such as percussion instruments of those that are harmonically related to
other sounds lower in frequency. It analyses them and sends data to the receiver
that will enable them to be reconstituted later.
Data channels
Data to provide the different functions on the transmission
is organised into a number of channels that are then applied to the overall
modulating signal. The main payload for the signal is known as the Main Service
Channel (MSC) and this includes the audio signal data. Two subsidiary channels
are also available. These are known as the Fast Access Channel (FAC) that
provides the essential data required to fully decode the signal and the Service
Description Channel (SDC).
RF Signal
The transmitted signal uses a form of modulation known as
Coded Orthogonal Frequency Division Multiplex (COFDM). This form of modulation
based around OFDM but with additional coding, and it is very resilient to many
common forms of interference and fading. Its main drawback has been that it
requires a significant level of signal processing to extract the data from the
carriers and reassemble it in the correct fashion. However signal processing ICs
are now sufficiently powerful and at a reasonable cost to make the use of this
form of modulation viable. Interestingly COFDM is also used by DAB Digital
Radio.
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Note on OFDM:
Orthogonal Frequency Division Multiplex (OFDM) is a
form of transmission that uses a large number of close spaced carriers
that are modulated with low rate data. Normally these signals would be
expected to interfere with each other, but by making the signals
orthogonal to each another there is no mutual interference. This is
achieved by having the carrier spacing equal to the reciprocal of the
symbol period. This means that when the signals are demodulated they
will have a whole number of cycles in the symbol period and their
contribution will sum to zero - in other words there is no interference
contribution. The data to be transmitted is split across all the
carriers and this means that by using error correction techniques, if
some of the carriers are lost due to multi-path effects, then the data
can be reconstructed. Additionally having data carried at a low rate
across all the carriers means that the effects of reflections and
inter-symbol interference can be overcome. It also means that single
frequency networks, where all transmitters can transmit on the same
channel can be implemented. |
Summary
DRM, Digital Radio Mondiale has been trialled for some time
with experimental transmissions from broadcasters including the BBC. Now
scheduled transmissions are taking place from a number of broadcasters, with
more commencing their transmissions all the time.
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