AD AD9516-1

Circuit Note
CN-0243
Devices Connected/Referenced
Circuits from the Lab™ reference circuits are
engineered and tested for quick and easy
system integration to help solve today’s analog,
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ADRF6702
AD9122
AD9516-0/AD9516-1/
AD9516-2/AD9516-3/
AD9516-4
1200 MHz to 2400 MHz Quadrature
Modulator with1550 MHz to 2150 MHz
Fractional-N PLL and Integrated VCO
Dual, 16-Bit, 1230 MSPS, TxDAC®
Clock Generator with Integrated VCO
with Various Frequency Range Options
from 1.45 GHz to 2.95 GHz
High Dynamic Range RF Transmitter Signal Chain Using Single External Frequency
Reference for DAC Sample Clock and IQ Modulator LO Generation
CIRCUIT FUNCTION AND BENEFITS
EVALUATION AND DESIGN SUPPORT
The combination of the ADRF6702 IQ modulator and the
AD9122 16-bit dual 1.2 GSPS TxDAC has the dynamic range
necessary for a modern high level QAM or OFDM based
wireless transmitter as shown in Figure 1. The dynamic range
Circuit Evaluation Boards
CN-0243 Circuit Evaluation Board (EVAL-CN0243-EB1Z)
Design and Integration Files
Schematics, Layout Files, Bill of Materials
EXTERNAL LOOP
FILTER
EXTERNAL LOOP
FILTER
EXTERNAL
FREQUENCY
REFERENCE
INPUT
DUAL MODULUS PLL
WITH ON CHIP VCO
AD9516
OPTIONAL
EXTERNAL
2 × LO (I/O)
ADRF6702
PLL REFERENCE
INPUT
INTERNALLY
GENERATED
2 × LO
PLL CORE (PFD, CHARGE
PUMP, DIVIDER)
PROGRAMMABLE DIVIDER
PROGRAMMABLE DIVIDER
INTERNAL
VCO
AD9122 DAC
SAMPLE CLOCK
÷2
MODULATOR
CORE
RF OUTPUT
INTERNAL LO
SYNTHESIZER/PLL
ADRF6702
AD9122
32-BIT NCO
I CHANNEL PASSIVE INTERFACE FILTER
16-BIT
DATA BUS
(I)
2×/4×/8×
INTERPOLATION
FILTERS
IDAC
16-BIT
DATA BUS
(Q)
2×/4×/8×
INTERPOLATION
FILTERS
QDAC
10165-001
Q CHANNEL PASSIVE INTERFACE FILTER
Figure 1. AD9122, ADRF6702, and AD9516 Used in a High Dynamic Range Transmitter
Rev.0
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CN-0243
Circuit Note
CIRCUIT DESCRIPTION
of this circuit is good enough to enable both ZIF (zero IF/
baseband) and CIF (complex IF up to 200 MHz to 300 MHz).
The AD9122 has the option of up to 8× interpolation, as well as
a 32-bit NCO for very fine IF frequency selectivity.
ADRF6702 IQ Modulator with Internal LO Synthesizer,
Synthesizer IQ Modulator Interface
The ADRF6702 IQ modulator is a unique device in several
respects. In addition to its exceptional dynamic range, it also
includes a fractional-N PLL, which allows programming of
discrete LO frequency steps of less than 25 kHz while at the
same time keeping the overall frequency multiplication small
enough to avoid a large increase in phase noise from the
reference to the synthesizer output.
Overall performance of a transmitter is highly dependent on the
dynamic range of the components directly in the signal chain.
In a mixed-signal transmitter using a DAC and IQ modulator,
the noise floor and distortion characteristics of these
components define the overall dynamic range of the signal
chain. However, the noise floor of the DAC can also be
degraded by sample clock jitter, and the IQ modulator
performance is dependent on the noise and spur characteristics
of its local oscillator (LO). Using high performance components
for sample clock and LO generation is, therefore, key to a high
performance transmitter.
Another aspect of the ADRF6702 is the divide-by-2 architecture
of the IQ modulator. Traditional IQ modulators accept an LO
input frequency at 1× the desired LO. Internally, a distributed
RC network creates the desired in-phase and quadrature LO
signals from the single LO frequency input. Because this is a
passive RC network, the bandwidth over which quadrature
modulation accuracy is achieved is limited. Also, for good
quadrature accuracy, the external LO should be spectrally pure.
Harmonics on the LO with this traditional IQ modulator
architecture can degrade the overall modulation accuracy. For
this reason, when using a PLL synthesizer to generate an LO
signal for an IQ modulator, a sharp band-pass or low-pass filter
is often required at the IQ modulator LO input.
In addition, generating these signals physically close to the DAC
and modulator on the PCB and using a single external reference
can make the design much simpler. Generating the sample
clock and LO (LO is very often a multi-GHz signal) separately
and at some distance from the DAC and IQ modulator requires
great care in the PCB layout. Subtle layout errors can cause
coupling to and from these critical signals and degrade overall
signal chain performance.
The signal chain performance is also heavily dependent on the
DAC/ IQ modulator interface filter. For optimal performance,
this passive filter should be designed after careful analysis of the
required system specifications.
In the divide-by-2 LO architecture of the ADRF6702, a simple
digital divider is used internally to create nearly perfect
quadrature over a wide band. The PLL synthesizer generates the
2× LO internally, so that it does not have to be distributed
around the PCB, and no filter is required between the
synthesizer and IQ modulator LO because the 2× LO
architecture is only sensitive to the edges of the LO signal, not
the frequency content. For a detailed descripton of the effects of
LO harmonics on a 1× IQ modulator and the design of the LO
filter, see Circuit Note CN-0134.
The ADRF6702 includes an on-board fractional PLL for LO
generation so that a low frequency reference (typically less than
100 MHz) is all that is necessary to synthesize the IQ modulator
LO. Using the PLL in the AD9516 clock generator allows a
single reference to generate both the DAC sample clock and the
PLL reference for the ADRF6702.
The circuit in Figure 1 was built using the AD9516-0, but other
members of the AD9516 family could be used depending on the
desired internal VCO frequency.
Sampled Signal to RF, Overall Spur Floor
A baseband signal goes through a number of steps on the way to
the RF transmit frequency. The signal begins in the discrete
FREQUENCY (x-FDATA)
–4x
–3x
–2x
–1x
–184.32
–122.88
–61.44
DC
1x
2x
3x
4x
DC
61.44
122.88
184.32
245.76
–20dB
–40dB
–60dB
–80dB
–100dB
–245.76
FREQUENCY
Figure 2. DAC Output Spectrum, Solid Blue Line Represents Baseband Signal and Images, Dotted Red Line Represents DAC Sinc Function
Rev. 0 | Page 2 of 8
1065-002
AMPLITUDE (dBFS)
0dB
Circuit Note
CN-0243
FREQUENCY (x-FDATA)
–4x
–3x
–2x
–1x
–184.32
–122.88
–61.44
DC
1x
2x
3x
4x
DC
61.44
122.88
184.32
245.76
–20dB
–40dB
–60dB
–80dB
–100dB
–245.76
FREQUENCY
1065-003
AMPLITUDE (dBFS)
0dB
Figure 3. DAC Output Spectrum Using 4× Interpolation, the Thin Blue Line Represents the DAC Interpolation Transfer Function
(sampled) domain and is synthesized by the DAC into the
analog domain. The results of this step are images and
distortion products generated by the DAC. As shown in Figure 2,
an ideal DAC with no distortion will generate images of a
baseband signal that must be filtered before being modulated.
The use of interpolation filters such as those in the AD9122 can
suppress most of the image energy, but an analog interface filter
between DAC and modulator will still be necessary. There is a
trade-off, however, between the order of the DAC interpolation
and the order of the analog filter. Higher DAC interpolation
rates mean lower required analog filter order and vice versa.
Figure 3 shows what the DAC output spectrum looks like when
using 4× interpolation, as an example.
A Multitude of Spurious Components at RF
The signal chain can add significant spurious components to the
spectrum, due both to modulation products, distortion
products, and integer multiples of the LO frequency. It we take
into account all of the possibilities for spurious which we have
discussed, the spurious content can consist of
(j × LO_freq) + (k × DAC_sample_rate) +
3.
and load impedances, as well as parasitics in the signal
traces, may add unwanted ripple in the filter pass band.
PCB layout. As shown in Figure 4, the I and Q
baseband inputs on the ADRF6702 IQ modulator are
located on opposite edges of the device. Note the filter
layout area within the dotted circles. To route the DAC
output signals to these pins, the traces must travel up
and then back down to get to the baseband pins on the
ADRF6702. These differential signal traces should be
of equal length, and any changes in direction of the
trace should be done by using 45° bends. If these
recommendations are not implemented, in-band
ripple, phase, or amplitude response may be degraded
in the filter response. Note that with this filter
topology, the capacitors can be used differentially
(across the signal path) or they can be used in a
common-mode connection by placing the filter caps
from the signal path pads to ground pads. There are
conditions (discussed later in this circuit note) where
common-mode capacitors improve performance vs.
differential-mode capacitors.
(l × DAC_NCO_freq) + (m × DAC_input_IF)
Where j, k, l, and m are integers over the range of negative
infinity to positive infinity.
DAC/Modulator Passive Interface Filter
1.
2.
Filter topology, order, and 3 dB cutoff frequency
At dc, the DAC sees a load impedance equal to the
DAC termination resistors (typically a 100 Ω
differential impedance) in parallel with the input
impedance of the IQ modulator. The IQ modulator
impedance is often >1kΩ, so a shunt resistor is often
used across the IQ modulator inputs to create a similar
load impedance to the source. Unequal filter source
Rev. 0 | Page 3 of 8
10165-004
The key to reducing the overall spurious spectrum is the analog
interface filter between the DAC and the IQ modulator. The
design of the interface filter between the DAC and IQ modulator
must take into account multiple aspects of performance:
Figure 4. PCB Layout for Transmitter, DAC/Mod Interface Filter Section
CN-0243
4.
Circuit Note
To achieve optimal performance from the filter, these
traces should be 100 Ω differential, or 50 Ω per line.
Note that with typical FR4 material, a 50 Ω line results
from a T/W ratio of 2:1.
If higher impedance lines are desired it should be
understood that the impedance of the line is a
nonlinear function of T/W (T = board layer thickness,
W = width of trace). A thinner line results in a higher
impedance line. With typical FR4 layer thicknesses, a
100 Ω line can get very thin, often close to minimum
design constraints. One solution to this is to void the
ground layer underneath the trace and put another
ground layer on the third layer of the PCB. This
effectively doubles T and allows for a wider trace.
DAC and Distortion Related Spurious Components
The use of DAC interpolation filters by themselves can reduce
the spurious content at the modulator input and, therefore, the
spurious content at RF. However, there may still be significant
spurious content. Figure 7 shows the RF output spectrum of the
IQ modulator under the following conditions;
FLO = 1940 MHz
DAC input data rate = 300 MSPS
DAC interpolation = 4×
DAC NCO frequency = 150 MHz
DAC input IF frequency = 8 MHz
Note that the strongest spurious component (aside from the
fundamental at 2098 MHz) is the 2× component of the DAC
clock at 2400 MHz. This is likely a result of common and
differential mode components of the DAC output containing
some spectrum from the DAC clock. The common-mode
rejection of the IQ modulator input rejects much of this signal,
but it is still contains significant energy. The next two highest
spurs, at 2062 MHz and at 2242 MHz, also seem to be related to
DAC clock spurs. The spur at 2242 MHz is easily recognized as
2 × (DAC clock – DAC fundamental) = 2400 − 158. The spur at
2062 MHz is not so obvious, but looks like (3 × LO) − (3 × DAC
clock) − 158 = 5820 − 3600 − 158. If the analysis is correct, then
we should be able to see significant spur reduction if we can
suppress the common-mode component of the DAC clock at
the IQ modulator inputs.
DAC_MOD Interface Filter Topology
Figure 5 shows a typical topology which gives a 5th order
maximally flat Butterworth response for a differential input and
output impedance of 100 Ω.. The actual response is given in
Figure 6. This filter uses 4.6 pF capacitors at the source and load.
This magnitude of capacitor value (<20 pF) is typical of filters
with high cutoff frequencies. Parasitics may have a significant
effect on response when using these small capacitor values.
L
L1
L = 58.5nH
R = 1pΩ
C
C1
C = 4.46893pF
PORT
IN_BB
NUM = 3
L
L3
L = 58.5nH
R = 1pΩ
L
L2
L = 58.5nH
R = 1pΩ
PORT
IP_MOD
NUM = 2
C
C2
C = 14.461762pF
C
C3
C = 4.46893pF
L
L4
L = 58.51nH
R = 1pΩ
PORT
IN_MOD
NUM = 4
1065-005
PORT
IP_BB
NUM = 1
2098MHz
Figure 5. DAC/Mod Interface Filter Topology, 5th Order Butterworth,
3 dB BW = 220 MHz, 100 Ω Differential Input and Output Impedance
0
2400MHz
–10
2242MHz
2062MHz
–30
10165-007
–40
–50
–60
Figure 7. IQ Modulator RF Output with DAC/IQ Mod Filter Absent,
LO = 1940 MHz, DAC Input IF = 8 MHz, DAC NCO = 150 MHz, RF = 2098 MHz
S1
SPC
–70
0
0.2
0.4
0.6
0.8
1.0
FREQUENCY (GHz)
10165-006
S21 (dB)
–20
Figure 6. Frequency Response of Filter Topology Given in Figure 5
Rev. 0 | Page 4 of 8
Circuit Note
CN-0243
Applying the differential Butterworth filter gives significant
spur level reduction, as shown in Figure 8. The strongest spurs
are still at 2062 MHz, 2242 MHz, and the 2× DAC clock spur at
2400 MHz. All three spurious components have been reduced
significantly.
2098MHz
2242MHz
As shown in Figure 1, this circuit uses a single external
reference to generate the AD9122 DAC sample clock and the
reference clock for the PLL in the ADRF6702. The AD9516 is
fundamental in providing the flexibility to do this. The AD9516
contains a PLL and integrated VCO. It also contains a number
of outputs that can be programmed for differential LVPECL,
LVDS, or single-ended CMOS, with independent divider
settings for each output path. In this circuit, one of these output
paths is used for the DAC clock and another output is used for
the reference input of the fractional-N PLL in the ADRF6702.
2400MHz
Figure 8. RF Spectrum Using 5th Order Butterworth Filter, Differential
Capacitors
The common-mode rejection of the DAC/IQ modulator
interface can often be improved by changing the topology of the
interface filter. In Figure 9, the input and output 4.7 pF caps are
replaced by common-mode capacitors (9.0 pF) from both sides
of the filter input and both sides of the filter output to ground.
This does not change the overall differential filter mode
response but does have an effect on this board on the overall
spurious content at RF. The harmonics mentioned earlier at
2098MHz
2242MHz
2400MHz
The advantage of using a fractional PLL in the ADRF6702 is
twofold. First, the fractional PLL allows very fine tuning of the
output LO. As an example, with an input frequency of 38.4 MHz
and a programmed MOD value in the ADRF6702 of 1536, the
LO can be programmed in increments of 25 kHz. The second
advantage is that the reference frequency does not have to be
equal to LO freq/divider ratio, but can be much higher, leading
to a lower divider ratio. Because the output phase noise is a
function of the reference phase noise multiplied by the divider
ratio, this means inherently lower phase noise at RF.
One of the key metrics in a synthesizer system is the amount of
phase noise added by the individual PLL and dividers. Figure 10
shows the noise floor of the spectrum analyzer doing the
measurement (green trace), the phase noise of the reference
generator (red), and the phase noise of an output tone at an RF
frequency of 1961 MHz with an LO of 1940 MHz (yellow). The
combination of the PLL in the AD9516 and the ADRF6702 does
generate noticeably high close-in phase noise (less than 500 kHz
offset from carrier) but does not contribute significant
wideband noise to the system. The loop filters for the VCOs in
both the AD9516 and ADRF6702 are set to bandwidths of
~100 kHz in the measurement circuit. Close-in phase noise may
be reduced by lowering the bandwidth of these loop filters.
System specifications should be reviewed to determine how
much close-in phase noise can be tolerated for a given system.
10165-009
2062MHz
The topology and results shown here may vary from layout to
layout, so it is always to the advantage of the designer to
experiment with the layout of the filter, specifically which mix
of differential and common-mode capacitors results in the
lowest overall spur floor.
Synthesizer Path and PLL Phase Noise
10165-008
2062MHz
2062 MHz and 2242 MHz are down a few dB more, and there
has been about a 15 dB reduction in the 2× DAC clock
component, nearly to the noise floor.
Figure 9. RF Spectrum Using 5th Order Butterworth Filter, Combination of
Differential and Common- Mode Capacitors Used in the DAC_Mod Filter
Rev. 0 | Page 5 of 8
CN-0243
Circuit Note
1961MHz RF OUTPUT (LO = 1940MHz)
REFERENCE GENERATOR
10165-011
SPECTRUM ANALYZER
10165-010
Figure 11. EVAL-CN0243-EB1Z Evaluation Board
Figure 10. Spectrum Analyzer Noise Floor, Reference Phase Noise, and RF
Output Phase Noise
COMMON VARIATIONS
10165-012
As described in the last section, PLL performance can be
adjusted by varying the bandwidth of the loop filters. There is a
trade-off between loop filter bandwidth and frequency settling
time that must be taken into account. If a DAC such as the
AD9122 is used, the DAC NCO can also be used for fine
frequency hopping, although there is a limit to the hopping
speed since the NCO requires programming via an SPI port.
Newer clock synthesis and distribution devices such as the
AD9520 and AD9523 may provide improvements in phase
noise.
CIRCUIT EVALUATION AND TEST
Figure 12. Bench Test Setup
The EVAL-CN0243-EB1Z evaluation board requires the
following equipment and software for signal generation and
basic measurement:
Setup and Test
The following steps are required to properly run the
EVAL-CN0243-EB1Z evaluation board:
Equipment Needed
1. Before powering up, connect all instruments, USB
adapters, and cables, as shown in Figure 13.
• 5 V power supply
• Low phase noise reference source (10 MHz to 200 MHz
range @ +3 dBm), Rohde & Schwarz SMA100, low noise
option, or equivalent
• DPG2 Digital Pattern Generator from Analog Devices
• High dynamic range spectrum analyzer, Agilent E4440A or
equivalent
• Analog Devices EVAL-ADF4XXXZ USB Adapter
Software
• DPG2 Software (included with DPG)
• ADRF6702 software available at www.analog.com/ADRF6702
Rev. 0 | Page 6 of 8
2. There is only a single 5 V power supply required. This
should be connected to the female banana plugs on the
EVAL-CN0243-EB1Z board. Make sure this supply is
connected, then turn on the +5 V supply. The total
current at this point should be 850 mA to 900 mA.
3. The DPG2 software contains a GUI to program the
AD9122. Program the AD9122 for the correct
interpolations rate and NCO (if desired).
4. Turn on the DPG2 software itself. If all cables and
software are working correctly, the software should
recognize the DAC input data rate and display it in the
lower right hand corner of the DPG GUI. Note that this
Circuit Note
CN-0243
USB
DPG2
DIGITAL PATTERN
GENERATOR
PC
IQ DATA
I
USB
Q
PLL REFERENCE
INPUT
USB ADAPTER
BOARD
REFERENCE
FREQUENCY
GENERATOR
10MHz – 200MHz +3dBm
EVAL-CN0243-EB1Z
EVALUATION BOARD
DIGITAL
INTERFACE
+5V
GND
RF OUTPUT
POWER
SUPPLY
1065-013
SPECTRUM
ANALYZER
Figure 13. Test Setup Functional Block Diagram
to 25 MHz with 1 MHz spacing) @ −8 dB back-off, and
the LO of the ADRF6702 is programmed to 1940 MHz,
the spectrum should look very similar to that shown in
Figure 14.
data rate should be equal to the DAC sample rate
(614.4 MSPS) in Figure 13 divided by the programmed
interpolation rate of the AD9122.
5. Note that as the various devices are activated and
programmed, the current will increase. At the end of this
exercise, the current should be between 1.4 A and 1.5 A,
depending on DAC sample rate.
7. Start the ADRF6702 GUI. To begin with, the only options
in the ADRF6702 GUI which need to be selected are the
input reference frequency and LO output frequency. To
program these values, click the reference input frequency
or the LO output values in the top center of the
ADRF6702 GUI. Another window will appear which will
allow you to enter these values. Important: After entering
these values, the user must finish with a carriage return to
make sure that the values are entered into the GUI.
RBW 10kHz
VBW 30kHz
ATT 10dBm SWT 15ms
MARKER 1 [T1]
–104.90dB
1.89005GHz
–20
–30
–40
–50
–60
–70
–80
–90
–100
–110
–120
CENTER 1.94GHz
10MHz/DIV
SPAN 100MHz
Figure 14. Spectrum of Complex Multitone Signal at LO Frequency of
1940 MHz at ADRF6702 RF Output, Desired Sideband Offset: +20 MHz,
Undesired Sideband Offset: −20 MHz
8. Programming the ADRF6702 is the last step in setting up
the EVAL-CN0243-EB1Z evaluation board. As an
example, if the DPG2 generates a series of tones (20 MHz
Rev. 0 | Page 7 of 8
10165-014
6. Use the DPG2 software to create a waveform (single,
multi tone, or comms standard signals are available).
A digital back-off of −8 dB should be used initially to
optimize linearity of the DAC/ADRF6702 combination.
Complex signal generation should also be selected in the
DPG2 GUI. When the waveform is created, use the "load"
and "play" buttons in the GUI to load the digital pattern
into the DPG memory itself.
REF –20dBm
CN-0243
Circuit Note
LEARN MORE
Data Sheets and Evaluation Boards
CN-0243 Design Support Package:
www.analog.com/CN0243-DesignSupport
ADRF6702 Data Sheet
DPG2 Digital Pattern Generator:
www.analog.com/DPG_DAC_Eval_Platfform
AD9122 Data Sheet
ADIsimPLL Design Tool
ADIsimRF Design Tool
ADRF6702 Evaluation Board
AD9122 Evaluation Board
AD9516-0 Data Sheet
AD9516-0 Evaluation Board
AD9516-1 Data Sheet
AD9516-1 Evaluation Board
AD9516-2 Data Sheet
AD9516-2 Evaluation Board
AD9516-3 Data Sheet
AD9516-3 Evaluation Board
AD9516-4 Data Sheet
AD9516-4 Evaluation Board
REVISION HISTORY
10/11—Revision 0: Initial Version
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CN10165-0-10/11(0)
Rev. 0 | Page 8 of 8