ISL5239 Evaluation Board User Guide

Evaluation Board Analog Output
Functions and Characteristics
®
Application Note
July 2002
Introduction
The ISL5239 Evaluation Board includes the circuit provisions
to convert the baseband digital I and Q outputs of the
ISL5239 to differential analog I and Q output signals that are
suitable to drive an analog quadrature modulator (AQM)
circuit for direct up-conversion to RF.
This Application Note describes the performance
characteristics of the DAC and analog output stages of the
Evaluation Board. It also provides information for adjusting
the Evaluation Board for different analog interfacing
requirements, and provides instructions and examples for
changing the analog I and Q low-pass filter bandwidths. The
Application Note includes performance measurements for a
typical application.
The Evaluation Board is shipped with a set of low-pass filters
that have 3 dB bandwidth of approximately 42 MHz. When
corrected with the digital correction filters of the ISL5239, an
ideally flat response of greater than 80 MHz can be
obtained. In some linearization applications, a wider predistortion signal bandwidth may be desired. The Application
Note provides two alternate designs that can be simply
implemented on the Board with component value changes
only. The alternate designs achieve a 3 dB bandwidth of
approximately 53 MHz, thus providing a full 100 MHz of flat
RF passband pre-distortion signal bandwidth.
AN1023
Overview of DAC and Analog Output
Circuits
The analog output circuits feature the Intersil ISL5929 14-bit
Dual-DAC and two fully differential DC-coupled low-pass
filter and buffer amplifier sections for I and Q outputs. The
outputs are suitable for directly driving the inputs of
contemporary analog quadrature modulator RFICs such as
the Sirenza STQ-2016 with performance levels limited only
by the RFIC dynamic range. DC-coupling allows the ISL5239
to digitally control the DC offsets and balance of the
baseband modulator channels to achieve nearly perfect
carrier suppression.
The combination of analog output circuits and digital
processing capabilities of the ISL5239 allow the following
output signal parameters to be adjusted with high precision:
• Output signal level (independently adjustable for I and Q)
• DC-offset (independent for I and Q)
• DC common mode output voltage
• Quadrature phase relationship of I and Q
• Quadrature gain relationship of I and Q
• Quadrature group delay relationship of I and Q
• Full-scale digital saturation output voltage level
• Common I and Q frequency response
• Differential I and Q frequency response
Figure 1 shows a simplified circuit schematic of one analog
I or Q output channel of the Evaluation Board.
ISL5929
Dual-DAC
42 MHz LPF
3-p, 0.1 dB Cheby
Differential
Buffer Amp
750 nH, 5%
0 to 15 mA
(0.35 vdc)
+
499
124
0.1%
0.5 pf
124
0.1%
0 to 15 mA
49.9
165
0.1%
12 pf
2%
+
22 pf
2%
Vcm
(0.35 vdc)
1.7 v p-p
differential
F.S.
AD8138
+
49.9
499
-
-
-
165
0.1%
0.5 pf
562
562
+1.9 vdc
Vcm for
STQ2016
12.3 mA
750 nH, 5%
274
2.67K
0.1 uf
21.5
-4.5dc
FIGURE 1. SIMPLIFIED SCHEMATIC OF ONE ANALOG OUTPUT CHANNEL
1
CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures.
1-888-INTERSIL or 321-724-7143 | Intersil (and design) is a registered trademark of Intersil Americas Inc.
Copyright © Intersil Americas Inc. 2002. All Rights Reserved
CommLink™ is a trademark of Intersil Americas Inc.
Application Note 1023
The DAC sampling rate for the ISL5239 Eval Board is
125 MHz. The 2.67K resistor sets the full scale DAC output
currents to approximately 15 mA.
The differential outputs of the DAC current sources drive a
fully-differential symmetrically- terminated 3-pole elliptical
low-pass filter. The filter characteristic is approximated by a
3-pole, 0.1 dB passband ripple Chebychev response with
3 dB corner at 42 MHz and a transmission zero at about
190 MHz.
The filter output is buffered by a fully differential amplifier
(AD8138) to provide a well controlled resistive output source
impedance to the AQM through 50Ω lines. The analog
outputs are intended to connect directly to high-impedance
AQM inputs through short low-capacitance coax lines. This
configuration permits full output swings into the AQM with
minimal high frequency distortion due to the buffer amp
drivers and loading.
A resistor divider bias network is shared between the two
channels in order to set the common mode DC operating
levels of the filters to the middle of the DAC output
compliance range (approximately 0.35 vdc).
A Common Mode Output Voltage potentiometer, R62 on the
Eval Board schematic, is used to set the output DC common
mode voltage of both I and Q channels to a level between
0.0 vdc and 2.5 vdc. The output common mode voltage is set
by the AD8138 based on this adjustable control voltage. For
the Sirenza STQ-2016 AQM, this voltage should be set for
approximately 1.90 vdc.
With the DAC currents set for 15 mA, the full scale output at
the analog I and Q outputs is approximately 1.75 v p-p. This
level can be adjusted up or down by changing the DAC
current setting resistor, R9 on the Eval Board schematic, and
making appropriate adjustments to the filter biasing current
in order to maintain a filter bias voltage that is roughly
centered within the DAC output compliance range.
Analog Filter Characteristics
Version 1: 42 MHz Bandwidth (shipped with Eval
Board)
The baseline analog low-pass filters which come with the
ISL5239 Eval Board have a 3 dB bandwidth of approximately
42 MHz, as shown in the simulated response plots below.
FIGURE 2. RESPONSE PLOTS OF THE 42.0 MHz LOW PASS
FILTER
The filters and buffer amp together provide about 40 dB of
attenuation of the DAC output signal spectrum at the
sampling rate of 125 MHz. A transmission zero occurs at
approximately 180 MHz based on the total equivalent
parallel capacitance seen across the inductors. This zero
has the effect of introducing a slight tilt to the passband
characteristic of the normal Chebychev filter and produces a
typical 3-pole elliptical response. Introduction of this zero
ensures several more dB of attenuation at 125 MHz than
otherwise.
Precision components are used in the critical filter elements
to improve I and Q matching and response consistency.
The filter circuit is based on the standard normalized 3-pole
0.1 dB passband ripple Chebychev filter model, shown
below.
Normalized
0.1 dB Cheby
1.5937
Is
1
1.4328
1.4328
1
FIGURE 3. NORMALIZED 0.1 dB CHEBYCHEV FILTER
2
Application Note 1023
This model is a single-ended symmetrically terminated filter
normalized to an impedance of 1Ω and 3 dB frequency of
1 radian per second. When scaled to 124Ω and a 3 dB
frequency of 42 MHz, the element values become those
shown in the following figure.
Scaled to 124 ohms
and 42 MHz
124
Ctot = 1p
44p
However, since the order of the filter remains 3-pole, the
wider bandwidth filters will provide less attenuation at the
sampling frequency of 125 MHz. The 125 MHz filter
attenuation decreases from approximately 40 dB to 30 dB.
The 53 MHz filter is based on the normalized 3-pole 0.01 dB
passband ripple Chebychev filter model given below.
750 nH
Is
substitutions on the Evaluation Board that will increase the
analog filter bandwidths to approximately 53 MHz.
44p
Normalized
0.01 dB Cheby
124
1.8214
FIGURE 4. FILTER MODEL SCALED TO 124Ω AND 42 MHz
BANDWIDTH
The addition of a parallel capacitance across the inductor
introduces a transmission zero. This capacitance is partly
due to the parasitic capacitance of a practical inductor which
limits its self-resonant frequency. We add a small capacitor
to set the zero frequency at approximately 190 MHz.
In realizing the final circuit element values, several other
factors need to be included. In the differential form of this
filter, the shunt capacitor values are scaled by 1/2 since
capacitors are effectively in series. In addition, the output
capacitance of the DAC and the parasitic pad and trace
capacitances at the DAC output need to be included in the
total capacitance seen at the input nodes of the filter. The
assumptions used in the Evaluation Board design are as
follows:
• DAC output capacitance:
1
Is
1.181
The frequency (bandwidth) of an R-L-C filter of this type can
be scaled by scaling any two or more of the Rs, Ls, or Cs
element values. With the goal of using standard available
inductor values, we provide two alternative filter versions,
each with 3 dB bandwidth of approximately 53 MHz.
Version 2 analog filter keeps the filter impedance at 124Ω,
and uses a standard 680 nH inductor value. This single
ended model is shown below. The alternative Version 3
analog filter uses a standard 750 nH inductor value and
scales the filter impedance to 137Ω.
Scaled to 124 ohms
and 53 M Hz
680 nH
6pf
These filter model assumptions then produce the final circuit
component values shown in the simplified Evaluation Board
schematic given above.
Note that the effective differential voltage gain from the DAC
output to the final buffered output is approximately one for
frequencies within the passband of the filter. The balanced
differential nature of the filter facilitates excellent rejection of
clock and digital switching noise from the Eval Board digital
circuits.
Version 2
53 MHz BW (Suggested Modification)
For full bandwidth baseband pre-distortion linearization
applications or digital IF upconversion applications, a wider
analog filter bandwidth is recommended. This section
explains simple design modifications and component value
3
1
FIGURE 5. NORMALIZED 0.01 dB CHEBYSHEV FILTER
11pf
• Pad and trace capacitances:
1.181
124
28.6
Ctot = 1p
28.6p
124
FIGURE 6. FILTER MODEL SCALED TO 124Ω AND 53.0 MHz
BANDWIDTH
The simulated characteristics of the 53 MHz bandwidth filter
designs are shown in the plots below. Again, the
transmission zero introduces a slight tilt in the normally flat
0.01 dB Chebychev passband, but adds several more dB
attenuation at 125 MHz than otherwise. The non-flatness is
of little consequence and can be easily removed by using the
ISL5239 digital correction filters.
Application Note 1023
The final filter element value changes for filter Version 2 are shown in the modified simplified schematic below.
FIGURE 7. RESPONSE PLOTS OF 53.0 MHz LOW PASS FILTER
ISL5929
Dual-DAC
53 MHz LPF
3-p, 0.01 dB Cheby
Differential
Buffer Amp
680 nH, 5%
0 to 15 mA
+
(0.35 vdc)
499
124
0.1%
0.5 pf
9.1pf
2%
124
0.1%
0 to 15 mA
49.9
165
0.1%
+
15 pf
2%
0.5 pf
562
Vcm
(0.35 vdc)
-
165
0.1%
49.9
12.3 mA
680 nH, 5%
274
0.1 uf
2.67K
21.5
-4.5dc
FIGURE 8. SIMPLIFIED SCHEMATIC WITH VERSION 2 FILTER
4
1.7 v p-p
differential
F.S.
AD8138
+
499
-
-
562
+1.9 vdc
Vcm for
STQ2016
Application Note 1023
To implement the version-2 53MHz bandwidth filters on the
ISL5239 Evaluation Board, the following L and C component
substitutions should be made:
53 MHz BW (Alternative Modification)
The alternative filter is based on scaling R's and A’s only.
The scaled model is as follows:
TABLE 1. L AND C COMPONENT SUBSTITUTIONS
WAS
Version 3
Scaled to 137 ohms
and 53 MHz
IS
L1, L2, L3, L4
750 nH, 5%
680 nH, 5%
C95, C105
12.0 pf, 2%
9.1 pf, 5%
C96, C106
22 pf, 2%
15 pf, 2%
750 nH
137
Is
Ctot = 1p
26p
26p
137
The substitute inductors should be of the same characteristic
family as specified in the original ISL5239 Evaluation Board
BOM.
FIGURE 9. FILTER MODEL SCALED TO 53.0 MHz AND 137Ω
The final filter element value changes for filter version 2 are shown in the modified simplified schematic below.
ISL5929
Dual-DAC
53 MHz LPF
3-p, 0.01 dB Cheby
Differential
Buffer Amp
750 nH, 5%
0 to 15 mA
+
(0.40 vdc)
499
137
0.1%
0.5 pf
8.2 pf
2%
0 to 15 mA
49.9
187
0.1%
+
13 pf
2%
0.5 pf
137
0.1%
562
Vcm
(0.40 vdc)
1.9 v p-p
differential
F.S.
-
187
0.1%
49.9
499
-
-
AD8138
+
+1.9 vdc
Vcm for
STQ2016
562
12.4 mA
750 nH, 5%
243
0.1 uf
2.67K
21.5
-4.5dc
FIGURE 10. SIMPLIFIED SCHEMATIC WITH VERSION 3 FILTER
TABLE 2. L AND C COMPONENT SUBSTITUTIONS
WAS
IS
R50, R54, R69, R73
124Ωs, 0.1%
137Ω, 0.1%
R51, R55, R70, R74
165Ω, 0.1%
187Ω, 0.1%
C95, C105
12.0 pf, 2%
8.2 pf, 5%
C96, C106
22 pf, 2%
13 pf, 2%
R61, R65
274Ω, 1%
243Ω, 1%
5
Application Note 1023
To implement the version-3 53MHz bandwidth filters on the
ISL5239 Evaluation Board, the following R and C component
substitutions should be made:
Thus, for best distortion performance, it is recommended
that the load impedance be divided down so as to remain
greater than about 200Ω.
Versions 2 and 3 of the filter should result in nearly the same
frequency response characteristic as shown above.
Version 3 has slightly larger output level due to the
increased filter impedance.
When driving an AQM device such as the Sirenza
STQ-2016, the common mode DC output level should be set
as recommended by the AQM vendor. This voltage will effect
the distortion performance of the AQM and may need to be
tuned to a level that minimizes operating distortion. For the
STQ-2016, the optimum common mode levels are
approximately 1.90 vdc to 1.95 vdc.
Output Adjustment and Loading
Considerations
The analog output path design allows flexibility for setting the
common mode DC output level and the peak differential
analog output levels that correspond to full scale signals
from the DACs. To obtain full performance, care must be
exercised in the impedance loading at the outputs.
The circuits are designed to drive a relatively high
impedance load over short, matched 50Ω lines between the
Evaluation Board and an analog AQM circuit. The outputs
may also be loaded with 50Ω, but with reduced distortion
performance and a 6 dB decrease in output level. The
differential outputs may be loaded unsymmetrically without
unbalancing the filter impedances.
Please become familiar with the following recommendations:
Common Mode DC Output Voltages
Before operating the ISL5239 Evaluation Board, the
Common Mode DC output voltages of the I and Q output
pairs should be set appropriately for the application.
Since the DC output characteristics are directly controlled by
the ISL5239 IC, it is recommended that the ISL5239 be
initialized to have zero digital DC offset and zero digital DC
output level on both I and Q channels before making set-up
adjustments. When initialized, the differential DC levels of both
the I and Q outputs should typically be less than 3 mV.
Potentiometer R62 should be adjusted to set the common
mode DC levels of the I and Q outputs to a desired voltage
between 0.0 vdc and 2.5 vdc.
The I and Q outputs will normally not be sourcing significant
DC current when driving high resistance loads such as the
inputs of an AQM device.
However, when any of the outputs is terminated in a lower
impedance load such as 50Ω, then the common mode DC
voltage may cause significant DC current to be sourced to the
load. This will reduce the distortion performance of the
AD8138 differential driver. Therefore, when observing the I or
Q output signals with a 50Ω instrument, it is recommended
that the common mode DC output voltage be set to zero.
The differential output drivers can support an unbalanced
load (e.g. 50Ω load on one side only) without a significant
change in performance characteristics. The distortion
contribution of the differential output buffer amp will increase
slightly at higher frequencies when loaded with 50Ω loads.
6
Full-Scale Output Signal Voltage
As shown in the schematic of Figure 2-1, the ISL5929 DAC
output currents are set for approximately 15 mA. The analog
output path thus provides a full scale peak-to-peak
differential AC output voltage of approximately 1.75v p-p
when the outputs are terminated with high impedance.
While this level is sufficient to drive most AQM devices
beyond their linear operating region, it may be desirable in
some applications to increase or decrease the full-scale
output levels in order to maximize dynamic range of the path.
The full-scale output level can be modified by changing the
DAC current setting resistor, R9, to raise or lower the fullscale DAC current. The maximum DAC current is 20 mA,
which would result in a maximum possible full scale output
voltage of approximately 2.25 v p-p.
Lower output levels can be achieved also by attenuating the
digital signal in the ISL5239 ahead of the DAC. But if full
dynamic range is desired at full-scale levels substantially
below 1.75 v p-p, then we advise reducing the full-scale DAC
current range by changing R9.
Changing the DAC current scale will also effect the DC bias
voltage at the DAC outputs and may require also changing
the common mode biasing resistor so as to restore a midpoint bias voltage near the 0.35 vdc level. These types of
changes, if needed, should be performed by an experienced
analog circuit designer.
The full-scale output signal voltages can be adjusted over a
reasonably wide range without significant loss of dynamic
range by using only the digital level scaling capabilities of the
ISL5239.
Output Loading
In typical applications, the analog I and Q outputs will be
connected to relatively high impedance loads (e.g. AQM
inputs) through short low-capacitance coax cables, preferably
less than 6 inches. In this configuration, the coax lines are
singly terminated with source series terminations of 50Ω.
A short length will ensure that the pole frequency of the 50Ω
output impedance of the drivers, when combined with
loading capacitance, will have a corner frequency beyond
200 to 300 MHz.
Application Note 1023
Longer coax connections can be used if the outputs are
either doubly terminated or divided through a higher value
resistor into a 50Ω terminated line.
The high frequency distortion performance of the AD8138
buffer amplifier depends on the output loading. For best
performance the total loading, including 50Ω series
termination resistor should be greater than 300Ω.
Since output loads will likely be coupled at DC, the common
mode DC output bias voltage may result in DC current
sourced to the load. The combination of low output load
resistance and high common mode voltage will shift the
output bias of the AD8138, causing some degradation in
distortion performance. Thus, we recommend keeping the
load resistances high (greater than a few hundred ohms)
when using significant amounts of common mode DC bias.
Optimum loading conditions are easily satisfied when the
ISL5239 Evaluation Board is driving an AQM RFIC device
over short coax cables.
The +ve and -ve analog outputs may be loaded differently
without effecting the balanced differential characteristics of
the low pass filters.
Typical Performance
In this section, we show examples of typical measured
performance of the ISL5239 Evaluation Board analog output
signals, when driving the Sirenza STQ-2016 RF quadrature
upconverter Eval Board. The Sirenza Eval Board has been
modified to place 20Ω series resistors in the differential input
paths in place of capacitors to enable DC-coupled drive.
Short equal length 50Ω coax cables were used to interface
the ISL5239 Eval Board to the Sirenza Eval Board. The DC
common mode output voltage was adjusted to 1.90 vdc. The
Sirenza Eval Board is set-up to perform direct upconversion
to a carrier center of 2.14 GHz.
Upconverted Signal Spectrum
The spectrum analyzer plot below shows the resulting RF
output with a properly adjusted output. The path is
comprised with a cascade of 4 - ISL5217 Digital Upconverter
Eval Boards driving the ISL5239 Eval Board, in turn driving
the Sirenza STQ-2016 Analog Quadrature Upconverter Eval
Board.
Each ISL5217 Board is producing one of the four wideband
CDMA carriers shown in the spectrum. The total occupied
bandwidth of the signals is 20 MHz.
FIGURE 11. MEASURED OUTPUT OF THE EVAL BOARD AND UPCONVERTER
7
Application Note 1023
Resolution and video bandwidths are 3kHz and 1 kHz
respectively.
The small of residual distortion indicated in this
measurement is due to roughly equal distortion contributions
of the STQ-2016 upconverter and the spectrum analyzer.
The baseband signal (not shown) exhibits only analyzer
distortion and has a signal-to-noise ratio of about 70 dB. The
dynamic range limitation of approximately 65 dB shown here
at RF is due to the upconverter RFIC and analyzer noise
floor limits.
In achieving full dynamic range performance, it is important
that the combined digital output signal levels be adjusted
through the signal path in order to utilize nearly the full
dynamic range of the DAC outputs and analog outputs. If the
signal level is lowered, the analog noise floor of the
upconverter will remain at the same level, reducing the RF
output signal-to-noise ratio.
The sampling image spectrum at 125 MHz offset is limited
by a combination of DAC sinc rolloff and analog low pass
filter characteristics.
FIGURE 12. MEASURED OUTPUT AT 125 MHz OFFSET (SAMPLING IMAGE)
The spectrum analyzer plot below shows the measured
spectrum corresponding to the above signal, centered at
125 MHz offset, or equivalently 2.265 GHz.
Other than the clock feedthrough component, the spectrum
is void of any significant spurs when detected in a 3 kHz
resolution bandwidth scan.
This spectrum, shown with vertical scale of 2 dB per division,
shows the relative levels of the clock feedthrough signal at
2.265 GHz and the filtered image spectrum due to DAC
sampling.
Passband Frequency Response
The 125MHz clock feedthrough is shown at -79.5 dBm. Total
signal power is approximately +4.5 dBm, equating to a clock
feedthrough power level of -84 dBc.
The plot shows that the DAC sampling spectral image is
approximately -50 dBc at the lower corner of the spectrum,
corresponding to 115 MHz offset at baseband.
8
The frequency response characteristics of the cascade
ISL5239 Evaluation Board/Sirenza
STQ-2016 AQM Eval Board were measured by outputting a
digitally generated wideband pulse signal with ideally flat
spectrum over 100 MHz bandwidth.
Application Note 1023
The resulting spectral output is shown below.
FIGURE 13. MEASURED SPECTRAL RESPONSE OF THE EVAL BOARD AND UPCONVERTER
The vertical scale is again 2 dB per division. The plot shows
approximately 4.0 dB rolloff at frequencies of +/-42 MHz from
center. Taking into account the sinc(x) response rolloff of the
DAC, the rolloff contribution due to the analog output path
filters is approximately 2.4 dB.
The measurement shows that the 3 dB corner frequency
response of the analog path is slightly above 42 MHz, as
expected.
Response Equalization Using ISL5239
Correction Filters
Measured data presented above was obtained with the
digital correction filters of the ISL5239 disabled.
With the version-1 low-pass filters that are shipped with the
ISL5239 Evaluation Board, the correction filters will equalize
the passband response over 80 MHz to 85 MHz bandwidth
to well within 0.1 dB flatness.
To obtain an equivalent flat response over 100 MHz of
bandwidth, version-2 or version-3 low-pass filter
modifications should be used, as described in this App Note.
The digital correction filters can also be used to equalize
magnitude and delay differences between the I and Q
channels in order to obtain nearly ideal image response over
these bandwidths. This topic is covered in other Application
Notes for the ISL5239.
In pre-distortion applications, the correction filters should be
employed to equalize the response of the baseband analog
channel.
All Intersil U.S. products are manufactured, assembled and tested utilizing ISO9000 quality systems.
Intersil Corporation’s quality certifications can be viewed at www.intersil.com/design/quality
Intersil products are sold by description only. Intersil Corporation reserves the right to make changes in circuit design, software and/or specifications at any time without
notice. Accordingly, the reader is cautioned to verify that data sheets are current before placing orders. Information furnished by Intersil is believed to be accurate and
reliable. However, no responsibility is assumed by Intersil or its subsidiaries for its use; nor for any infringements of patents or other rights of third parties which may result
from its use. No license is granted by implication or otherwise under any patent or patent rights of Intersil or its subsidiaries.
For information regarding Intersil Corporation and its products, see www.intersil.com
9