AD CN-0268 Resonant approach to designing a band-pass filter for narrow-band, high if, 16-bit, 250 msps receiver front end Datasheet

Circuit Note
CN-0268
Devices Connected/Referenced
Circuits from the Lab™ reference circuits are engineered and
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ADL5565
6 GHz Ultrahigh Dynamic Range Differential
Amplifier
AD9467
16-Bit, 200 MSPS/250 MSPS ADC
Resonant Approach to Designing a Band-Pass Filter for Narrow-Band, High IF, 16-Bit,
250 MSPS Receiver Front End
EVALUATION AND DESIGN SUPPORT
CIRCUIT DESCRIPTION
Design and Integration Files
Schematics, Layout Files, Bill of Materials
The advantages of using a differential amplifier to drive a high
speed ADC include signal gain, isolation, and source impedance
matching to the ADC. The ADL5565 allows pin-strappable gain
adjustments of 6 dB, 12 dB, or 15.5 dB. Alternatively, by applying
two external resistors to the inputs, finer gain steps can be achieved
within the 0 dB to 15.5 dB range. Additionally, the ADL5565
offers high output linearity, low distortion, low noise, and wide
input bandwidth. The 3 dB bandwidth is 6 GHz, and the 0.1 dB
flatness is 1 GHz. The ADL5565 is capable of achieving an
output third-order intercept (OIP3) of greater than 50 dB.
CIRCUIT FUNCTION AND BENEFITS
The circuit shown in Figure 1 is a 16-bit, 250 MSPS, narrow-band,
high IF receiver front end with an optimum interface between
the ADL5565 differential amplifier and the AD9467 ADC.
The AD9467 is a buffered input 16-bit, 200 MSPS or 250 MSPS
ADC with SNR performance of approximately 75.5 dBFS and
SFDR performance between 95 dBFS and 98 dBFS. The ADL5565
differential amplifier is suitable for driving IF sampling ADCs
because of its high input bandwidth, low distortion, and high
output linearity.
This circuit note describes a systematic procedure for designing
the interface circuit and the antialiasing filter that maintains
high performance and ensures minimal signal loss. A resonant
approach is used to design a maximally flat Butterworth fourthorder band-pass filter with a center frequency of 200 MHz.
+3.3V
+3.3V
5.6Ω
0.1µF
VIP2
INPUT
Z = 50Ω
33Ω
15Ω
150nH
AD9467
5Ω
ADL5565
VIN1
33Ω
39nH
VIP1
ZI = 200Ω
0.1µF
1nF
8.2pF
2pF
39nH
150nH
310Ω
530Ω
180nH
+1.8V
3.5pF
16-BIT
250MSPS
ADC
G = 6dB
5Ω
VIN2
5.6Ω
1nF
INTERNAL
INPUT Z
15Ω
FS = 2V p-p DIFF
10560-001
XFMR
1:1 Z
ECT1-1-13M
Figure 1. Resonant Filter Design for Narrow Band High IF Applications Using the ADL5565 Differential Amplifier and the AD9467 ADC
Rev. 0
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©2012 Analog Devices, Inc. All rights reserved.
CN-0268
Circuit Note
Figure 2 shows a single-ended-to-differential approach to driving
the ADL5565 using a balun or transformer. This configuration
may not be a viable or desirable option in certain applications.
The ADL5565 offers flexibility in its driver interface and can be
driven single ended, as shown, or differentially with a differential
mixer, for example. Refer to the ADL5565 data sheet for details
on the different input interfaces.
To achieve the optimal level of performance that the ADL5565
and AD9467 have to offer, it is important to properly follow the
design guidelines as specified on the respective data sheets. Some of
the important design criteria include properly matching the
input and output impedance of the ADL5565 for minimum
signal loss and optimum linearity performance, systematic
design of an antialiasing filter for improved dynamic range, and
source impedance matching to the ADC inputs.
ADL5565 Output Load Matching
ADL5565 Input Impedance Matching
The ADL5565 linearity performance has been optimized for a
200 Ω output load. This is a common output impedance used
to interface to ADCs and for filter design. With an optimized
output load of 200 Ω, the output IP3 of the ADL5565 at 200 MHz
is 46 dBm.
R3
R1
VIP2
0.1µF
R4
ETC1-1-13
50Ω
VIP1
VOP
ADL5565
In situations where a 200 Ω output load may not fit the application,
tradeoffs can be made between the output load of the ADL5565
and its linearity performance. Figure 3 shows a plot of thirdorder intermodulation (IMD3) vs. frequency for commonly
used output loads.
R5
VIN1
VON
R6
VIN2
10560-002
R2
0.1µF
Figure 2. ADL5565 Input Impedance Match
0
Figure 2 shows the recommended input matching network for
the ADL5565. The input impedance of the ADL5565 is gain
dependent, and the differential input impedance is 200 Ω for 6 dB
gain, 100 Ω for 12 dB gain, and 67 Ω for 15.5 dB gain. To match
the 50 Ω source impedance of the signal generator to the input
impedance of the ADL5565, R1 and R2 must be chosen so that
their sum in parallel with the input impedance of the ADL5565,
ZI, is equal to 50 Ω. To maintain balance in the differential circuit,
R1 must equal R2. The following formula can be used to calculate
the necessary matching resistors.
–20
IMD3 (dBc)
–40
50Ω LOAD
100Ω LOAD
200Ω LOAD
400Ω LOAD
–60
–80
–100
–120
–140
2R1 || Zl = 50 Ω
R1 = R2 =
0
50
100
150
200
250
300
350
400
FREQUENCY (MHz)
25
1 − (50 / Z l )
450
500
10560-003
R1 = R2
Figure 3. ADL5565 IMD3 vs. Frequency for 50 Ω, 100 Ω, 200 Ω, and 400 Ω
Output Loads, 3.3 V Supply, Gain = 6 dB
Table 1 shows the calculated termination resistors and pin
configuration for the different gain settings of the ADL5565.
An alternative configuration to the one shown in Figure 2 is
to replace the 1:1 balun, ETC1-1-13, with an impedance
transformation RF transformer. This can eliminate the need
for R1 and R2. A 1:4 transformer can be used for the 6 dB gain
configuration or a 1:2 transformer for the 12 dB gain configuration.
The advantages of this alternative configuration are lower
component count and minimum signal loss. However, pay
attention to the bandwidth of the transformer. Impedance
transformation transformers have narrower bandwidths and
higher insertion loss as compared to a 1:1 balun.
Table 1. Gain, Input Impedance, and R1, R2, R3, R4, R5, and R6 Values for ADL5565
Gain (dB)
6
12
15.5
ADL5565 Input Impedance, Zl, (Ω)
200
100
67
R1 (Ω)
33
50
Open
Rev. 0 | Page 2 of 6
R2 (Ω)
33
50
Open
R3 (Ω)
Open
0
0
R4 (Ω)
0
Open
0
R5 (Ω)
0
Open
0
R6 (Ω)
Open
0
0
Circuit Note
CN-0268
39nH
When interfacing to the ADC, it is recommended that the real
input impedance be reduced from 530 Ω to a lower value within
the 200 Ω to 400 Ω range. By lowering the input impedance of
the ADC, the kickback due to the sample-and-hold structure
settles out faster, yielding improved linearity performance. The
tradeoff is increased input power because more power is required
to drive the full scale of the ADC. In this circuit example, the
input impedance of the AD9467 was reduced to 200 Ω to match
the output impedance of the ADL5565 and also to balance the
linearity vs. input power of the ADC. The input impedance of
the AD9467 was reduced to 200 Ω by placing a 310 Ω resistor in
parallel with the ADC differential input.
8.2pF
39nH
In the circuit in Figure 1, the ADS program was used to design
a fourth-order maximally flat (Butterworth) low-pass filter.
Figure 4 shows the low-pass filter design with a source and load
impedance of 200 Ω and a 3 dB cutoff frequency of 300 MHz.
The 200 Ω impedance was chosen because it is the common
source and load impedance of the driver amplifier and ADC.
The first elements are series inductors to ease driver requirements.
In the final optimized circuit of Figure 1, the filter source
impedance is equal to approximately 21.6 Ω; however, 200 Ω was
chosen to design the low-pass portion of the filter because the
overall filter is ultimately a resonant band-pass filter, and it is
more critical that the amplifier and ADC see the correct load and
source impedance for optimized linearity performance. The effect
of doing this is amplitude loss due to the impedance mismatch.
150nH
Figure 4. Low-Pass Filter Design
The low-pass filter design was further tuned by creating resonance
to cause peaking at the band of interest. This resulted in a
narrow-band, band-pass filter at a high IF. Placing an inductor
across the ADC differential inputs nulls the input capacitance of
the ADC and creates peaking. Figure 5 shows the calculation
used to determine the resonant inductor value. In the case of
the 3.5 pF source impedance of the AD9467, a parallel inductor
of 181 nH is necessary to null the capacitive susceptance; leaving
only the high impedance resistive portion of the RC parallel
equivalent. The resonant frequency chosen for the calculation
was 200 MHz.
ZL
ZR
ZC
Figure 5. Resonant Match
1
j ωC
Z L = j ωL
ZC =
Antialiasing Filter Design
An antialising filter ahead of the ADC helps reduce signal
content and noise from unwanted Nyquist zones that would
otherwise alias in band and degrade the dynamic performance.
Antialiasing filters are often designed using LC networks and
must have well defined source and load impedances to achieve
the desired stop-band and pass-band characteristics. The filter
design is accomplished using software available from Nuhertz
Technologies or Agilent Technologies Advanced Design
Systems (ADS), for example.
2pF
10560-005
The AD9467 is an ideal choice for an ADC in this circuit because it
is an IF sampling ADC optimized for high performance over
wide bandwidths and ease of use. The AD9467 has an integrated
buffer that presents a fixed input impedance to the driver amplifier.
This input structure is an advantage over ADCs that use an
unbuffered front end directly coupled to the sampling switches.
Unbuffered ADCs present time varying input sample-and-hold
impedances to the drive amplifier. The addition of the input
buffer eases the drive requirements at the expense of slightly
higher power consumption. The buffered source impedance of
the AD9467 is modeled as a fixed impedance of a 530 Ω resistance
in parallel with a 3.5 pF capacitance.
150nH
10560-004
AD9467 Source Impedance
YC =
1
ZC
YL =
1
ZL
YC + YL = 0
L=
1
ω 2C
Measured Performance
Figure 1 shows the final circuit configuration. The outputs of the
ADL5565 were padded with 5.6 Ω on each output to improve
the stability of the driver amplifier. The recommended series
resistance is generally between a few ohms to several tens of ohms.
A larger resistor value improves on stability; however, the tradeoff is
a power loss because the series resistor forms a voltage divider
with the impedance at the ADC inputs, resulting in signal
attenuation.
Following the series resistors at the output of the ADL5565 are
1 nF dc blocking capacitors. Following that is the antialiasing
filter and then the parallel resistor of 310 Ω to reduce the input
impedance of the ADC. Finally, the 15 Ω resistors in series with
the ADC inputs isolate the internal switching transients from
the filter and the amplifier.
Rev. 0 | Page 3 of 6
CN-0268
Circuit Note
Figure 6 and Figure 7 shows the resulting antialiasing filter
response with a 1 dB bandwidth of 41 MHz and a 3 dB bandwidth
of 89 MHz, centered at an IF of 203 MHz. Figure 8 shows the FFT
spectrum for the final receiver circuit of Figure 1, where the SNR is
72.5 dBFS, and the SFDR performance approaches 90 dBc.
20.000
Using ADS as a simulation tool, the filter components can
be further tuned to shift the resonant peak to the desired IF.
For example, by changing the parallel 8.2 pF capacitor of the
antialiasing filter to 10 pF shifts the resonance peak lower to
180 MHz. Figure 9 through Figure 11 show the filter profile
and single-tone FFT performance for this condition.
20.000
14.286
14.286
8.571
AMPLITUDE (dB)
AMPLITUDE (dB)
8.571
2.857
–2.857
–8.571
2.857
–2.857
–8.571
–14.286
100
200
FREQUENCY (MHz)
300
400
–20.000
0
100
200
FREQUENCY (MHz)
Figure 6. Antialiasing Filter Response, fC = 203 MHz
300
400
Figure 9. Antialiasing Filter Response, fC = 183 MHz
0
0
–0.5
–0.5
1dB BW = 41MHz
–1.0
AMPLITUDE (dB)
AMPLITUDE (dB)
–1.0
–1.5
–2.0
–2.5
1dB BW = 40MHz
–1.5
–2.0
–2.5
–3.0
3dB BW = 89MHz
160
180
–3.0
200
220
240
FREQUENCY (MHz)
3dB BW = 75MHz
–3.5
100
120
Figure 7. Antialiasing Filter Response, fC = 203 MHz, 1 dB and 3 dB Bandwidth
220
240
fIN = 183MHz
fS = 245.76MHz
–10
–20
–50
–30
–60
–40
AMPLITUDE (dBFS)
–40
–70
–80
–90
–100
–110
SNR = 73dB
SFDR = –91dBc
H2/H3 = –94dBc/–91dBc
–50
–60
–70
–80
–90
–100
–120
0
20
40
60
80
100
FREQUENCY (MHz)
120
–110
–120
–130
Figure 8. Single Tone FFT Plot, Input = 203 MHz,
Sampling Rate = 245.76 MSPS
0
20
40
60
80
100
FREQUENCY (MHz)
Figure 11. Single Tone FFT Plot, Input = 183 MHz,
Sampling Rate = 245.76 MSPS
Rev. 0 | Page 4 of 6
120
10560-011
–130
10560-008
AMPLITUDE (dBFS)
200
0
SNR = 72.5dB
SFDR = –88.9dBc
H2/H3 = –89.1dBc/–88.9dBc
–30
180
Figure 10. Antialiasing Filter Response, fC = 183 MHz,
1 dB and 3 dB Bandwidth
fIN = 203MHz
fS = 245.76MHz
–20
160
FREQUENCY (MHz)
0
–10
140
10560-010
140
10560-007
–3.5
120
10560-009
0
10560-006
–14.286
–20.000
Circuit Note
CN-0268
COMMON VARIATIONS
CIRCUIT EVALUATION AND TEST
Quite a few combinations of drivers and high speed ADCs are
available; however, for optimum performance, it is important to
pay attention to the input and output impedance of the ADC
driver and the input reactance of the ADC. Each device has its
own unique impedance characteristic. A common variation to
the Figure 1 circuit is the ADL5562 (3.3 GHz bandwidth) driving
the AD9467 with a low-pass, antialiasing filter design for wideband
receiver applications, as described in Circuit Note CN-0227.
The circuit shown in Figure 1 is implemented using the AD9467
evaluation board (AD9467-250EBZ). The bottom side of the
AD9467 evaluation board includes the ADL5562 and a prototype
area for a fourth-order filter. The ADL5562 was replaced with
the ADL5565 because both ADC drivers are pin compatible.
See User Guide UG-200 for the complete schematics, BOM,
and layout for the AD9467-250EBZ board. Table 2 shows the
modifications to the AD9467 evaluation board required to
duplicate the circuit shown in Figure 1. Complete documentation
for this circuit note can be found in the CN-0268 Design
Support package located at: http://www.analog.com/CN0268DesignSupport.
Similarly, Circuit Note CN-0110 describes using the ADL5562
differential driver amplifier to drive wide bandwidth ADCs,
such as the AD9445, for high IF ac-coupled applications. Another
alternative where variable gain is desired, the ADL5565 can be
replaced with the AD8375 variable gain amplifier. The AD8375
is a digitally controlled, variable gain, wide bandwidth amplifier
that provides precise gain control across a broad 24 dB gain range
with 1 dB resolution. The AD8376 is a dual version of the AD8375.
Circuit Note CN-0002 describes how to use the AD8376 VGA to
drive wide bandwidth ADCs for high IF, ac-coupled applications.
This circuit uses the modified AD9467-250EBZ circuit board
and the HSC-ADC-EVALCZ FPGA-based data capture board to
run the tests. The two boards have mating high speed connectors,
allowing for the quick setup and evaluation of the circuit’s
performance. The modified AD9467-250EBZ board contains
the circuit evaluated as described in this note, and the HSCADC-EVALCZ data capture board is used in conjunction with
VisualAnalog evaluation software, as well as the SPI controller
software to properly control the ADC and capture the data.
Application Note AN-835 contains complete details on how to
set up the hardware and software to run the tests described in this
circuit note.
Table 2. AD9467 Evaluation Board Modification for the ADL5565 Driver Option
Reference Designator
R121, R122, C109, C110, C117, R103, C116, R130, C118
R125, R110, R107, R113, R114, R119, R120
T103
R105, R106
C101, C105, C106, C107
U100
R117, R118
C113, C114
L101, L102
C119
L103, L104
C120
L100
R111, R112
R127, R128
Description
DNI
0Ω
Balun, 1:1 impedance ratio
33 Ω
0.1 µF
ADL5565
5.6 Ω
1 nF
39 nH
8.2 pF
150 nH
2 pF
180 nH
155 Ω
15 Ω
Rev. 0 | Page 5 of 6
Manufacturer
Part Number
M/A-Com
MABA-007159-000000
Analog Devices
Coilcraft
Murata
Coilcraft
Murata
Coilcraft
0805CS
GRM15
0805CS
GRM15
0805CS
CN-0268
Circuit Note
LEARN MORE
CN-0268 Design Support Package: http://www.analog.com/CN0268-DesignSupport
UG-200 User Guide: Evaluating the AD9467 16-Bit, 200
MSPS/250 MSPS ADC, Analog Devices.
CN-0002 Circuit Note, Using the AD8376 VGA to Drive Wide
Bandwidth ADCs for High IF AC-Coupled Applications.
Analog Devices
CN-0110 Circuit Note, Using the ADL5562 Differential
Amplifier to Drive Wide Bandwidth ADCs for High IF ACCoupled Applications, Analog Devices
Newman, Eric and Rob Reeder. AN-827 Application Note, A
Resonant Approach to Interfacing Amplifiers to SwitchedCapacitor ADCs. Analog Devices.
Reeder, Rob. AN-742 Application Note, Frequency Domain
Response of Switched Capacitor ADCs. Analog Devices.
MT-031 Tutorial, Grounding Data Converters and Solving the
Mystery of "AGND" and "DGND." Analog Devices.
MT-073 Tutorial, High Speed Variable Gain Amplifiers (VGAs).
Analog Devices.
MT-075 Tutorial, Differential Drivers for High Speed ADCs
Overview. Analog Devices.
CN-0227 Circuit Note, High Performance, 16-Bit, 250 MSPS
Wideband Receiver with Antialiasing Fitler, Analog Devices.
Arrants, Alex, Brad Brannon and Rob Reeder, AN-835
Application Note, Understanding High Speed ADC Testing
and Evaluation, Analog Devices.
MT-101 Tutorial, Decoupling Techniques, Analog Devices.
Data Sheets and Evaluation Boards
AD9467 Data Sheet
ADL5565 Data Sheet
Ardizzoni, John. A Practical Guide to High-Speed PrintedCircuit-Board Layout, Analog Dialogue 39-09, September 2005.
Circuit Evaluation Board (AD9467-250EBZ)
Standard Data Capture Platform (HSC-ADC-EVALCZ)
REVISION HISTORY
4/10—Rev. 0: Initial Version
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CN10560-0-4/12(0)
Rev. 0 | Page 6 of 6
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