AD ADL5373 Correcting imperfections in iq modulators to improve rf signal fidelity Datasheet

AN-1039
APPLICATION NOTE
One Technology Way • P.O. Box 9106 • Norwood, MA 02062-9106, U.S.A. • Tel: 781.329.4700 • Fax: 781.461.3113 • www.analog.com
Correcting Imperfections in IQ Modulators to Improve RF Signal Fidelity
by Eamon Nash
INTRODUCTION
The in-phase and quadrature modulator (IQ modulator) is a
key component in modern wireless transmitters. It provides a
convenient method for modulating data bits or symbols onto
an RF carrier. IQ upconversion has become the architecture
of choice for implementing transmitter signal chains for end
applications such as cellular, WiMAX, and wireless point-topoint. IQ modulators, however, can degrade signal fidelity in
ways that are somewhat unique. These effects can degrade the
quality of the transmitted signal during the modulation process,
resulting in degraded error vector magnitude (EVM) at the
receiver, which in turn degrades bit error rate (BER). Fortunately, algorithms exist that can correct these imperfections.
This application note describes a typical zero-IF or directconversion transmitter and provides a brief introduction to
digital modulation. Other items discussed are: the imperfections introduced by the modulator are examined with
particular focus on the effect of temperature and frequency
changes, in-factory and in-field algorithms that can reduce the
effect of these modulator imperfections is also discussed, and
particular focus is placed on the efficacy of in-factory set-andforget algorithms.
A TYPICAL WIRELESS TRANSMITTER
Figure 1 shows a block diagram of a direct-conversion wireless
transmitter that uses an IQ modulator to modulate a bit stream
onto a carrier. A single bit stream is split into two parallel bit
streams at half the original data rate. To limit the spectral bandwidth of the final carrier, the two bit streams are low-pass filtered
in the digital domain. To do this, the original bit-streams must
be digitally oversampled by the digital signal processor or field
programmable gate array (FPGA). So, instead of two bit streams,
there are now two streams of digital words. The chosen resolution of these words depends upon multiple factors such as the
required signal-to-noise ratio of the link and the chosen modulation scheme (QPSK in this case). Word widths between 12
and 16 bits are commonly chosen.
Q
AD9788
FPGA OR DSP
I
AUX
DAC1
GAIN
DAC 1
1.5
TIME (msec)
2.0
800
600
400
200
–800
1.0
IIOUT3 (mV)
50Ω
0°
2.0
ADL5320
HPA
90°
AUX
DAC2
800
600
400
200
0
–200
–400
–600
1.829
OVERSAMPLE
LOW-PASS
FILTER
LOWPASS
FILTER
100Ω
GAIN
DAC 2
2.329
TIME (msec)
1.5
TIME (msec)
ADL5375
LOWPASS
FILTER
16-BIT
I DAC
800
600
400
200
0
–200
–400
–600
–800
1.329
0
–200
–400
–600
PHASE
ADJUST
DIGITAL
FILTER
PHASE
ADJUST
AD8363
50dB RMS
DETECTOR
16-BIT
Q DAC
50Ω
SPECTRUM
ANALYZER
DIGITAL
DEMOD
AD9230
AD8352
Figure 1. A Zero IF Direct-Conversion Transmitter with Optional Loop-Back Receiver
Rev. 0 | Page 1 of 8
08383-001
–800
1.0
DIGITAL
FILTER
–800
IIOUT3 (mV)
BIT
DE-INTERLEVER
OVERSAMPLE
LOW-PASS
FILTER
800
600
400
200
0
–200
–400
–600
QQOUT1 (mV)
DATAOUT(mV)
IIOUT1 (mV)
100Ω
800
600
400
200
0
–200
–400
–600
–800
AN-1039
Application Note
TABLE OF CONTENTS
Introduction ...................................................................................... 1
Correcting for Quadrature and I/Q Gain Errors ......................6
A Typical Wireless Transmitter ...................................................... 1
Frequency Variations ....................................................................7
Modulator Imperfections ............................................................ 3
Post Calibration Temperature Drift ............................................7
Correcting Modulator Imperfections ........................................ 4
Calibration vs. Time......................................................................7
Factory Calibration ...................................................................... 4
Complex Modulation ....................................................................8
Calibration Procedure.................................................................. 6
Conclusions ....................................................................................8
Rev. 0 | Page 2 of 8
Application Note
AN-1039
After low-pass filtering, the two word streams are applied to a
pair of digital-to-analog converters (DAC). The DAC outputs
drive two low-pass filters whose primary role is to remove
Nyquist images. The outputs of these filters then drive the
baseband inputs of the IQ modulator. The local oscillator (LO)
input of the modulator is driven by a relatively pure CW signal
generated by a phase-locked loop (PLL) such as the ADF4106
from Analog Devices, Inc. Now, take a closer look at the
operation of the IQ modulator.
The LO signal is split into two signals, equal in amplitude but
with a phase difference of exactly 90°. These two quadrature
signals drive the inputs of the two mixers that, for the purposes
of this application note, are viewed as analog multipliers. The
outputs of these two multipliers are added together (in the
Σ block of the IQ modulator) to provide the IQ modulator’s
output.
While it is apparent that the baseband data streams have
been filtered, instead briefly consider them as the original bit
streams. Instead of a stream of 1s and 0s, think of them as two
streams switching between a value of +1 and –1. So, the output
of the I multiplier consists of a vector which is flipping in-phase
between 0° and 180°as the bit stream alternates. Likewise, the
output of the Q multiplier is a vector that flips between +90°
and –90° as the bit stream modulates the original 90° vector.
Thus, if at a particular instant, both the I and Q bit streams are
equal to +1, the result at the output of the IQ modulator is the
sum of the 90° and 0° vectors, that is, a +45° vector. Likewise,
I and Q bit combinations of −1/+1, −1/−1, and +1/−1 produce
vectors (commonly called symbols) all of equal amplitude at
+135°, −135°, and −45°, respectively. If these vectors were
plotted, observe the constellation of the modulated carrier
(see Figure 2A).
(D)
(B)
(E)
(C)
(F)
08383-002
(A)
Figure 2. Error Vector Magnitude Constellations that Result from Various
Modulator Imperfections
MODULATOR IMPERFECTIONS
Contrary to the previous hypothetical situation, in a real IQ
modulator, things do not look so perfect. A series of effects in
the IQ modulator conspire to create QPSK (or QAM) vectors
that are neither equal in amplitude nor separated by exactly 45°.
Consider first what happens if for some reason the gain of the I
path is greater than that of the Q channel; this could be caused
by a DAC gain mismatch, low-pass filter insertion loss, mismatch,
or gain imbalance inside the IQ modulator. Regardless of where
this gain imbalance comes from, its effect is the same. Because
the 0°/180° vectors at the output of the I multiplier are larger
than the +90°/−90° vectors from the Q multiplier, the shape
of the constellation becomes rectangular (see Figure 2B). This
degrades signal integrity at the receiver because the receiver is
expecting a perfectly square constellation. In the QPSK example
shown in Figure 2B, a slight gain imbalance is unlikely to result
in an incorrect bit decision in the receiver unless the received
signal is very small. However, in higher order modulation
schemes such as 16 QAM or 64 QAM (see Figure 2E and
Figure 2F), the increased density of the constellation points
could easily combine with an IQ gain imbalance to produce
an incorrect symbol decision in the receiver.
In most IQ modulators, the 90° phase split of the LO is achieved
using either a polyphase filter or a divide-by-two flip-flop circuit
(which requires an external LO that is twice the desired output
frequency). In either circuit, the 90° phase split or quadrature is
never perfect. For example, if there is a 1° quadrature error, the
shape of the resulting constellation is slightly trapezoidal (see
Figure 2C). Just like IQ gain imbalance, this can result in
incorrect bit decisions in the receiver.
Now consider what happens if either the I or Q paths have
unwanted dc offset errors. This results in the +1/−1 multiplication being skewed. For example, an offset that is equal to 1%
of the baseband signal amplitude causes the +1/−1 multipliers
to be modified to +1.01/−0.99. This has the effect of shifting
the center of the constellation off the origin, on either the I or
Q axis, most likely in both (see Figure 2D). In the frequency
domain, this manifests itself as a small portion of the unmodulated carrier appearing at the output of the modulator. In the
frequency domain, this LO leakage (also referred to as LO
feedthrough) appears at the center of the modulated spectrum.
Because of parasitic capacitances within the silicon die and
bond-wire to bond-wire coupling, the signal that is applied
to the LO port of the IQ modulator may also couple directly
to the RF output. This leakage is independent of the offset
multiplication effect that was described previously. However,
its manifestation, that is, the presence of the unmodulated
carrier in the output spectrum, is exactly the same. Thus, the
net LO leakage seen at the output of the IQ modulator is the
vector sum of these two components. Fortunately, as discussed
in the Correcting Modulator Imperfections section, the composite LO leakage at the output can be mitigated by a single
compensation technique.
Rev. 0 | Page 3 of 8
AN-1039
Application Note
Table 1. IQ Modulator Selection Table Showing Uncompensated Gain and Phase Imbalance
FREQUENCY
(MHz)
IQ 3dB
BANDWIDTH
(MHz)
CARRIER
SUPPRESS
(dBm)
SIDEBAND
SUPPRESSION
(dBc)
GAIN
IMBALANCE
(dB)
PHASE
IMBALANCE
(°)
NOISE
FLOOR
(dBm/Hz)
AD8345
140 TO 1000
80
–42
–42
0.200
0.50
AD8346
800 TO 2500
70
–42
–36
0.200
1.00
AD8349
700 TO 2700
160
–45
–35
0.100
1.90
ADL5370
300 TO 1000
500
–50
–41
0.030
0.76
ADL5371
500 TO 1500
500
–50
–55
0.100
ADL5372
1500 TO 2500
500
–45
–45
ADL5373
2300 TO 3000
500
–32
ADL5374
3000 TO 4000
500
–33
ADL5375
400 TO 6000
750
ADL5385
50 TO 2200
ADL5386
P1dB
(dBm)
OUTPUT
IP3 (dBm)
SUPPLY
VOLTAGE
(V)
SUPPLY
CURRENT
(mA)
–155.0
2.5
N/A
2.70 TO 5.50
65
800
–147.0
–3.0
N/A
2.70 TO 5.50
45
1900
–155.0
7.6
21.0
4.75 TO 5.50
135
900
–160.0
11.0
24.0
4.75 TO 5.25
205
450
–0.03
–158.6
14.4
27.0
4.75 TO 5.25
175
900
0.090
0.21
–158.0
14.2
27.0
4.75 TO 5.25
165
1900
–57
0.010
0.10
–157.0
13.8
26.0
4.75 TO 5.25
174
2500
–50
0.015
0.25
–160.0
12.0
22.8
4.75 TO 5.25
173
3500
–46
–52
–0.050
–0.29
–160.0
9.4
27.0
4.75 TO 5.25
200
900
700
–46
–50
–0.030
–0.39
–159.0
11.0
26.0
4.75 TO 5.50
215
350
50 TO 2200
700
–38
–46
0.050
–0.50
–160.0
11.1
25.0
4.75 TO 5.50
230
350
ADL5590
869 TO 960
250
–44
–50
0.050
0.20
–157.0
16.0
29.0
4.75 TO 5.50
170
940
ADL5591
1805 TO 1990
250
–39
–48
0.050
0.30
–157.0
16.0
30.0
4.75 TO 5.50
170
1960
SPECS @
(MHz)
CORRECTING MODULATOR IMPERFECTIONS
FACTORY CALIBRATION
Note that in Figure 1, in addition to the direct conversion signal
chain, an optional loop-back or transmit observation receiver
has also been incorporated into the radio. The primary function
of this receiver is to analyze the adjacent channel power ratio
(ACPR) of the transmitter that is primarily caused by distortion
in the high power amplifier (HPA). By continually observing
the ACPR of the transmitter, digital predistortion of the
baseband signal can be employed to partially correct HPA
nonlinearities while allowing the HPA to operate closer to its
compression point.
If a wireless transmitter does not use digital predistortion, it
would be difficult to justify the cost of a loop-back receiver
purely for the sake of the IQ modulator. In such situations,
the two options that remain are:
The presence of a loop-back receiver can be opportunistically
used to also correct for modulator imperfections.
A detailed discussion of the IQ modulator correction techniques used when a loop-back receiver is present is beyond the
scope of this application note. However, the general procedure
involves using the loop-back receiver to demodulate the I and
Q bit streams. The demodulated constellation is then examined
for evidence of IQ gain imbalance, imperfect quadrature, and/
or LO leakage. Once these imperfections have been identified,
the I and Q data streams can be preprocessed so that the IQ
modulator imperfections cancel out. For example, if the
demodulated constellation from the loop-back receiver shows
a rectangular constellation with the width of I being larger than
the height of Q (see Figure 2B), gain adjust registers in the DAC
can be used to either decrease the size of the I data stream or
increase the size of the Q data stream. Likewise, the phase
adjustment registers of the DAC can be used to slightly skew
the I and Q channels so that the imperfect quadrature of the
IQ modulator’s phase splitter is compensated.
•
•
08383-009
PART
NUMBER
Do not perform any correction of the IQ modulator’s
imperfections.
Complete a one-time factory calibration and store the
correction coefficients in nonvolatile memory.
In recent years, the performance of IQ modulators has
improved to such a degree that it is now feasible (depending
on the modulation scheme) to design a transmitter without any
need to provide correction for imperfections. For example, the
ADL5375 from Analog Devices has gain and quadrature imbalances of 0.05 dB and 0.29°, respectively, at 900 MHz, with little
or no degradation over temperature. As a result, in many applications, it may be adequate to dispense with any correction
algorithms. Table 1 shows the performance of this and other
members of the Analog Devices IQ modulator family.
Rev. 0 | Page 4 of 8
Application Note
AN-1039
SIDEBAND SUPPRESSION (dBc)
•
–10
2.5dB
–20 1.25dB
–30 0.5dB
0.25dB
–40 0.125dB
–50 0.05dB
0.025dB
–60 0.0125dB
–70
0dB
–80
–90
0.01
0
0.1
1
PHASE ERROR (Degrees)
–10
10
100
Figure 4. Plot Showing the Relationship Between Modulator Errors and
Sideband Suppression
–20
–30
By using a directional coupler and a power splitter (as shown
in Figure 1), it is quite simple to add an auxiliary output to
the transmitter that can be used during factory calibration. A
spectrum analyzer is connected to this port. Another alternative
would be to connect the spectrum analyzer at the antenna
connector (after the signal has been adequately attenuated).
–40
–50
–60
–70
–80
–90
CENTER 899.9334MHz
333kHz/
SPAN 3.33MHz
08383-003
•
0
Lower sideband: If the IQ modulator has no imperfections,
this is the only spectral component observed, the result of
multiplication and summing of the baseband sine and
cosine signals with the two in-quadrature LO signals.
Undesired upper sideband: This undesired component
results from gain and phase imbalances between the I and
Q signal paths along with LO quadrature imbalance.
Undesired LO leakage: As discussed earlier, the LO leakage
results from I and Q offsets and/or parasitic leakage of the
LO directly to the IQ modulator’s output.
POWER (dBm)
•
Figure 4 shows a plot that can be used to relate sideband
suppression to I/Q gain mismatch and quadrature mismatch.
From the plot, it can be noted that a quadrature phase error of
1°, coupled with an I/Q gain mismatch of 0.5 dB, results in
−30 dB of sideband suppression. It is notable in this example
that improving the quadrature phase mismatch has no effect
on the sideband suppression unless the gain mismatch is also
improved.
08383-004
The second alternative presented previously is to perform
factory calibration. To do this, the popular single sideband
spectrum can be used as a simple but valuable diagnosis
tool during factory calibration. To create a single sideband
spectrum, the I and Q inputs are driven by low frequency
(typically 1 MHz) sine and cosine signals, that is, the baseband signals are in quadrature. Figure 3 shows the spectrum
that results when these baseband signals are mixed with the LO.
The primary components of the single sideband spectrum are:
Figure 3. Single Sideband Spectrum
Rev. 0 | Page 5 of 8
AN-1039
Application Note
Correcting all of the modulator’s imperfections is a multistep
process. Start by looking at the procedure for LO leakage correction which results in a constellation that is offset from the
origin. A single sideband spectrum is applied to the transmitter
and is monitored on the spectrum analyzer. Next, small differential offset voltages are applied to the I and Q inputs. Applying
differential offset voltages to the I and Q inputs should not be
confused with changing the dc bias levels (also referred to as the
common-mode level) on these pins, which has no effect. This is
done as an I offset sweep followed by a Q offset sweep (or vice
versa). Returning briefly to Figure 1, note that the AD9788 (a
16-bit, 800 MSPS dual DAC) conveniently includes two auxiliary DACs that can be used to couple differential dc offset
voltages on I and Q lines. This coupling is performed externally
using resistor dividers.
Figure 5 shows how sweeping the I and Q offset voltages alters
the LO leakage. Start by sweeping the I offset voltage around 0 V
while holding the Q offset voltage at 0 V. With modern IQ
modulators exhibiting unadjusted LO leakage in the −40 dBm
range and having voltage gains in the −5 dB to +5 dB range, an
offset voltage sweep range of ±5 mV is more than adequate to
identify the location of the null (in this example, ±2 mV is
adequate to identify a nulling voltage somewhere between
100 μV and 200 μV). Note, however, that the first pass (black
trace) only manages to reduce the LO leakage to just under
−40 dBm. This clearly indicates that the Q offset needs
correction. The second pass (blue trace) involves sweeping
the Q offset around 0 V with the I offset held at the value that
yielded the first I null. Note that a Q offset of 400 μV reduces
the LO leakage a further 10 dB to around −50 dBm. However,
a third pass is required. The trough from the first pass is quite
shallow because the Q channel had not yet been adjusted. This
makes it difficult to identify the ideal I nulling voltage. A third
pass (red trace) that involves again sweeping the I offset while
holding the Q offset at 400 μV, identifies the optimum I nulling
voltage to be 150 μV.
CORRECTING FOR QUADRATURE AND I/Q GAIN
ERRORS
A similar procedure can be used to correct quadrature and I/Q
gain mismatch. IQ modulator family data sheets typically specify
the quadrature phase mismatch and I/Q gain imbalance in
degrees and decibels, respectively, along with the sideband
suppression (also in decibels). Using this information, it is
advisable to perform the first optimization pass on the weaker
of the two specifications, that is, the specification which most
contributes to the sideband suppression. For example, assume
that the device data sheet specifies a sideband suppression of
−40 dBc, comprising of 1 degree of phase imbalance and 0.1 dB
of gain imbalance amplitude. In this case, it is advisable to first
try to adjust phase because making a gain adjustment has
almost no effect as long as the 1 degree of phase error is present
(see Figure 4).
Figure 6 shows the results of a gain sweep followed by a
phase sweep. In the first pass, the gain delta between I and Q
is adjusted over a range of approximately ±2 dB. The TxDAC®
in Figure 1 facilitates this adjustment by providing internal
gain adjust auxiliary DACs. The sweep yields a null of around
−57 dBc for a gain difference of approximately −0.1 dB (gain is
scaled on the top axis). Next, adjust the skew between I and Q.
This drives the null down further to −60 dBc for a phase adjust
of −0.05°.
–2
–10
SIDEBAND SUPPRESSION (dBc)
CALIBRATION PROCEDURE
–1
–20
1
2
FIRST PASS (GAIN ADJUST)
–30
–40
–50
–60
–10
–70
–0.4
FIRST PASS – I OFFSET ADJUST
SECOND PASS – Q OFFSET ADJUST
–20
THIRD PASS – I OFFSET ADJUST
–0.3
–0.2
–0.1
0
0.1
0.2
PHASE ADJUST (Degrees)
0.3
0.4
08383-006
SECOND PASS (PHASE ADJUST)
0
Figure 6. Multipass Sideband Suppression Compensation Sweeps
–30
In this case, a third pass is not necessary and does not yield
further improvement. This stems from the fact that the
unadjusted phase error is very close to the optimized value
(~0.05°). Thus, the first-pass gain adjust yields a deep trough
that is only slightly improved during the phase sweep. This
contrasts to the LO leakage nulling where a third pass yielded
further improvement.
–40
–50
–60
–70
–80
–2
–1
0
1
I AND Q DIFFERENTIAL OFFSET VOLTAGES (mV)
2
08383-005
LO LEAKAGE (dBm)
GAIN ADJUST (dB)
0
Figure 5. Multipass LO Leakage Compensation Sweeps
Rev. 0 | Page 6 of 8
Application Note
AN-1039
Once the LO leakage and quadrature error have been calibrated,
all that remains is for the calibration coefficients to be stored in
nonvolatile RAM so that they are available when the equipment
is turned on in the field. To recap, the four calibration
coefficients are
I channel offset voltage
Q channel offset voltage
I channel vs. Q channel gain imbalance
Quadrature phase imbalance
FREQUENCY VARIATIONS
Calibrating at multiple frequencies within a band adds time to
the factory calibration, requires more nonvolatile memory for
the larger look up table, and is more cumbersome during field
operation as calibration coefficients have to be swapped out as
the frequency changes.
Now, consider what happens to the quality of calibration as the
frequency changes. In Figure 7, sideband suppression and LO
leakage have been nulled to −60 dBc and −74 dBm, respectively,
at 1900 MHz. Figure 7 also shows how the uncompensated
sideband suppression and LO leakage vary with frequency (the
flatter green and red traces a the top of the plot). Next, adjust
the frequency over a range of ±30 MHz (the typical width of a
cellular telephony band) without recalibration. The LO leakage
quickly loses its null and at some frequencies is only around
8 dB better than the uncompensated value. In the case of the
sideband suppression, the difference between the compensated
and uncompensated values becomes as low as around 1 dB.
Figure 7 suggests that factory calibration be performed at
multiple frequencies within a band to maintain nulled
performance across the band.
–30
In Figure 8, the LO leakage and sideband suppression have
again been nulled midband. After nulling, the device is cycled
over temperature. This again has the effect of moving sideband
suppression and LO leakage off their nulled levels. However,
notice that the performance at temperature is quite flat across
frequency and it is no longer clear at which frequency the
nulling was performed. The net improvement over temperature
is approximately 15 dB compared to the unadjusted LO leakage.
CALIBRATION VS. TIME
In the set-and-forget factory calibration scheme that has just
been described, the question of long-term drift arises because
the equipment may never be recalibrated in the field. Experiments have shown that it is very difficult, if not impossible, to
measure the degradation of nulled sideband suppression and
LO leakage over time. Very mild changes in environmental
conditions tend to quickly move the device off its null. This
makes it impossible to determine whether the environment and
the test equipment are altering the experiment or if genuine
device drift over time is taking place.
However, Figure 8 shows that the question of drift over time
is less important. This is because the effect of temperature drift
is much more significant. Thus, in a system that experiences
reasonable temperature fluctuations, whatever drift over time
takes place is completely masked by the temperature drift.
UNADJUSTED SIDEBAND SUPPRESSION (dBc)
–30
UNADJUSTED LO LEAKAGE (dBm)
–35
–40
CARRIER FEEDTHROUGH (dBm)
CARRIER FEEDTHROUGH (dBm)
SIDEBAND SUPPRESSION (dBc)
–35
Factory calibration at multiple temperatures is even more
difficult and expensive than calibration at multiple frequencies.
As a result, it is generally only practical to perform factory
adjustment of LO leakage and sideband suppression at an
ambient temperature. Thus, what happens to post-calibration
performance as temperature varies?
–45
–50
–55
–60
–65
–70
–75
POST (MIDBAND)
NULLING SIDEBAND
SUPPRESSION (dBc)
POST (MIDBAND) NULLING LO LEAKAGE (dBm)
1880
1890
1900
1910
OUTPUT FREQUENCY (MHz)
1920
1930
Figure 7. Variation of LO Leakage and Sideband Suppression vs. Frequency
after Nulling Midband
–45
–50
–55
–60
–65
–70
–75
08383-007
–80
1870
–40
–80
1802
+25°C UNADJUSTED
+25°C NULLED
+85°C UNADJUSTED
+85°C NULLED
–40°C UNADJUSTED
–40°C NULLED
1812
1822
1842
1862
1832
1852
LO FREQUENCY (MHz)
1872
1882
08383-008
•
•
•
•
POST CALIBRATION TEMPERATURE DRIFT
Figure 8. Variation of LO Leakage vs. Frequency and Temperature After
Nulling Midband
Rev. 0 | Page 7 of 8
AN-1039
Application Note
COMPLEX MODULATION
CONCLUSIONS
While a detailed discussion is beyond the scope of this article,
it is worth mentioning that all of the issues associated with
modulator imperfections can be avoided with a slightly different transmit architecture. Many modern DACs incorporate
complex modulators, that is, digital engines that convert
baseband I and Q data up to a low intermediate frequency (IF).
These signals, which are still in Cartesian I and Q format, drive
the IQ modulator. Because modern IQ modulators, such as
the ADL5375, have baseband input bandwidths of as high as
750 MHz, low IFs in the 100 MHz to 250 MHz range can be
easily accommodated. When an IQ modulator is driven by
such a signal, the output spectrum is essentially a single
sideband spectrum similar to what is shown in Figure 3.
While modern IQ modulators offer excellent out-of-the-box
quadrature accuracy, IQ gain imbalance, and LO leakage, their
performance can be improved further using calibration. If the
transmitter incorporates a loop-back receiver as part of a digital
predistortion scheme, the receiver can also be used to continuously monitor and correct the imperfections of the IQ
modulator. The post-calibration performance is only limited
by the available compensation step sizes and the ability of the
receiver to precisely measure the constellation degradation.
The lower sideband becomes the modulated carrier and is
displaced from the LO by a frequency offset equal to the
intermediate frequency. The imperfections of the IQ modulator
now manifest themselves as out-of-band effects, which can be
filtered away, resulting in in-band EVM, which is not affected
by the IQ modulator’s imperfections.
In transmitters that do not contain a loop-back receiver, factory
calibration is a reasonable alternative. A single calibration in the
middle of a operating band most likely causes degradation at
the band edges. As a result, calibration at multiple frequencies
within a band is more effective. When temperature drift is
factored in, factory calibration at the ambient temperature
typically improves LO leakage and sideband suppression by
around 10 dB to 15 dB.
However, this approach comes at some cost. Care must be taken
to filter out the LO leakage along with the undesired upper
sideband. In contrast, a Nyquist filtered zero IF spectrum is
completely free of spurious components apart from harmonics
of the LO. In addition, as the frequency of the low IF increases,
the distortion of the DAC and IQ modulator increases slightly.
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