QAM Formats:
8-QAM, 16-QAM, 32-QAM, 64-QAM, 128-QAM, 256-QAM
QAM,
quadrature amplitude modulation provides some significant benefits for data
transmission. As 16QAM transitions to 64QAM, 64QAM to 256 QAM and so forth,
higher data rates can be achieved, but at the cost of the noise margin.
Many
data transmission systems migrate between the different orders of QAM, 16QAM,
32QAM, etc., dependent upon the link conditions. If there is a good margin,
higher orders of QAM can be used to gain a faster data rate, but if the link
deteriorates, lower orders are used to preserve the noise margin and ensure
that a low bit error rate is preserved.
As the QAM order increases, so the distance between the
different points on the constellation diagram decreases and there is a higher
possibility of data errors being introduced. To utilise the high order QAM
formats, the link must have a very good Eb/No otherwise data errors will be
present.When the Eb/No deteriorates, then other the power
level must be increased, or the QAM order reduced if the bit error rate is to
be preserved.
Accordingly
there is a balance to be made between the data rate and QAM modulation order,
power and the acceptable bit error rate. Whilst further error correction can be
introduced to mitigate any deterioration in link quality, this will also
decrease the data throughput.
QAM formats and applications
QAM
is in many radio communications and data delivery applications. However some
specific variants of QAM are used in some specific applications and standards.
There
is a balance between data throughput and signal to noise ratio required. As the
order of the QAM signal is increased, i.e. progressing from 16QAM to 64QAM,
etc. the data throughput achievable under ideal conditions increases. However
the downside is that a better signal to noise ratio is required to achieve
this.
For
some systems the order of the modulation format is fixed, but in others where
there is a two way link, it is possible to adapt the order of the modulation to
obtain the best throughput for the given link conditions. The level of error
correction used is also altered. In this way, changing the modulation order,
and the error correction, the data speed can be optimised whilst maintaining
the required error rate.
For domestic broadcast applications for example, 64 QAM and 256 QAM are often
used in digital cable television and cable modem applications. The order of the
QAM modulation has to be set at the transmitter, because the transmission is
only one way, and in addition to this, there are thousands of receivers, making
it impossible to have a dynamically adaptive form of modulation.
In
the UK, 16 QAM and 64 QAM are currently used for digital terrestrial television
using DVB - Digital Video Broadcasting. In the US, 64 QAM and 256 QAM are the
mandated modulation schemes for digital cable as standardised by the SCTE in
the standard ANSI/SCTE 07 2000.
For
the many forms of wireless and cellular technology it is possible to
dynamically alter the order of QAM modulation and error correction according to
the link conditions between the two ends.
As
data rates have risen and the demands on spectrum efficiency have increased, so
too has the complexity of the link adaptation technology. Data channels are
carried on the cellular radio signal to enable fast adaptation of the link to
meet the prevailing link quality and ensure the optimum data throughput,
balancing transmitter power, QAM order, and forward error correction, etc.
Constellation
diagrams for QAM
The
constellation diagrams show the different positions for the states within
different forms of QAM, quadrature amplitude modulation. As the order of the
modulation increases, so does the number of points on the QAM constellation
diagram.
The
diagrams below show constellation diagrams for a variety of formats of
modulation:
16QAM constellation32QAM
constellation64QAM
constellation
It
can be seen from these few QAM constellation diagrams, that as the modulation
order increases, so the distance between the points on the constellation
decreases. Accordingly small amounts of noise can cause greater issues.
As
the level of noise increases due to low signal strengths, so the area covered
by a point on the constellation increases. If it becomes too large, then the
receiver is unable to determine which position on the constellation the
transmitted signal was meant to be, and this results in errors.
It is also found that the higher the order of modulation for the QAM signal,
the greater the amount of amplitude variation is present on the transmitted
signal. For transmitter RF amplifiers for everything from Wi-Fi to cellular and
more, it means that linear amplifiers are required. As linear amplifiers are
less efficient than those that can be run in saturation, it means that techniques
like Doherty amplifiers and envelope tracking may be needed.
Also
as the amplitude variation increases, so the level of efficiency falls. This is
very important for mobile equipment battery efficiency, and base station power
efficiency.
QAM bits
per symbol
The
advantage of using QAM is that it is a higher order form of modulation and as a
result it is able to carry more bits of information per symbol. By selecting a
higher order format of QAM, the data rate of a link can be increased.
The
table below gives a summary of the bit rates of different forms of QAM and PSK.
Bit
mapping for a 16QAM signal
|
QAM FORMATS & BIT RATES
COMPARISON |
||
|
MODULATION |
BITS PER SYMBOL |
SYMBOL RATE |
|
BPSK |
1 |
1 x bit rate |
|
QPSK |
2 |
1/2 bit rate |
|
8PSK |
3 |
1/3 bit rate |
|
16QAM |
4 |
1/4 bit rate |
|
32QAM |
5 |
1/5 bit rate |
|
64QAM |
6 |
1/6 bit rate |
The
power spectrum and bandwidth efficiency of QAM modulation is identical to M-ary
PSK modulation, in other words for the same order phase shift keying, the power
spectrum and bandwidth efficiency levels are exactly the same whether
quadrature amplitude modulation or phase shift keying is used.
QAM noise
margin
While
higher order modulation rates are able to offer much faster data rates and
higher levels of spectral efficiency for the radio communications system, this
comes at a price. The higher order modulation schemes are considerably less
resilient to noise and interference.
As
a result of this, many radio communications systems now use dynamic adaptive
modulation techniques. They sense the channel conditions and adapt the
modulation scheme to obtain the highest data rate for the given conditions. As
signal to noise ratios decrease errors will increase along with re-sends of the
data, thereby slowing throughput. By reverting to a lower order modulation
scheme the link can be made more reliable with fewer data errors and re-sends.
|
QAM FORMATS & NOISE PERFORMANCE |
||
|
MODULATION |
ηB |
EB / NO FOR BER = 1 IN 106 |
|
16QAM |
2 |
10.5 |
|
64QAM |
3 |
18.5 |
|
256QAM |
4 |
24 |
|
1024QAM |
5 |
28 |
Selecting
the right order of QAM modulation for any given situation, and having he
ability to dynamically adapt it can enable the optimum throughput to be
obtained for the link conditions for that moment. Reducing the order of the QAM
modulation enables lower bit error rates to be achieved and this reduces the
amount of error correction required. In this way the throughput can be
maximised for the prevailing link quality.