MAXIM MAX2022EVKIT

19-3857; Rev 0; 11/06
MAX2022 Evaluation Kit
The MAX2022 evaluation kit (EV kit) simplifies the evaluation of the MAX2022 direct upconversion (downconversion) quadrature modulator (demodulator) designed for
UMTS/WCDMA, cdma2000 ®, DCS/PCS, and WiMAXSM
base-station applications. It is fully assembled and tested at the factory. Standard 50Ω SMA connectors are
included on the EV kit’s input and output ports to allow
quick and easy evaluation on the test bench using RF
test equipment.
This document provides a list of test equipment required
to evaluate the device, a straight-forward test procedure
to verify functionality, a description of the EV kit circuit,
the circuit schematic, a bill of materials (BOM) for the kit,
and artwork for each layer of the PCB.
Features
♦ Fully Assembled and Tested
♦ 50Ω SMA Connectors on Input and Output Ports
♦ 1500MHz to 2500MHz RF Range
♦ High-Linearity and Low-Noise Performance
♦ Broadband Baseband Input/Output
♦ DC-Coupled Input Provides for Direct DAC/ADC
Interface
Ordering Information
cdma2000 is a registered trademark of Telecommunications
Industry Association.
WiMAX is a service mark of Broadband.com Inc.
PART
TEMP RANGE
IC PACKAGE
MAX2022EVKIT
-40°C to +85°C
36 QFN-EP*
*EP = Exposed paddle.
Component List
DESIGNATION
QTY
6
22pF ±5%, 50V C0G ceramic
capacitors (0402)
Murata GRM1555C1H220J
R5, R6, R9,
R10, R12–R15
0
Not installed
C2, C5, C8,
C11, C12
TP1
1
5
0.1µF ±10%, 16V X7R ceramic
capacitors (0603)
Murata GRM188R71C104K
Large test point for 0.062in PCB
(red)
Mouser 151-107-RC or equivalent
C4
0
Not installed
TP2
1
C9
1
1.2pF ±0.1pF, 50V C0G ceramic
capacitor (0402)
Murata GRM1555C1H1R2B
Large test point for 0.062in PCB
(black)
Mouser 151-103-RC or equivalent
TP3
0
Not installed
J1–J6
6
PCB edge-mount SMA RF
connectors
(flat-tab launch)
Johnson 142-0741-856
1
R1
1
432Ω ±1% resistor (0402)
R2
1
562Ω ±1% resistor (0402)
R3
1
301Ω ±1% resistor (0402)
R4, R7, R8, R11
4
0Ω resistors (0402)
Active-mixer IC (6mm x 6mm, 36-pin
QFN-EP)
Maxim MAX2022ETX+
NOTE: U1 HAS AN EXPOSED
PADDLE CONDUCTOR THAT
REQUIRES IT TO BE SOLDER
ATTACHED TO A GROUNDED PAD
ON THE CIRCUIT BOARD TO
ENSURE A PROPER
ELECTRICAL/THERMAL DESIGN.
DESIGNATION
C1, C3, C6, C7,
C10, C13
QTY
DESCRIPTION
U1
DESCRIPTION
________________________________________________________________ Maxim Integrated Products
For pricing, delivery, and ordering information, please contact Maxim/Dallas Direct! at
1-888-629-4642, or visit Maxim’s website at www.maxim-ic.com.
1
Evaluates: MAX2022
General Description
Evaluates: MAX2022
MAX2022 Evaluation Kit
Component Suppliers
SUPPLIER
Johnson
M/A-Com
Murata
PHONE
WEBSITE
507-833-8822
www.johnsoncomponents.com
1-800-366-2266 www.macom.com
770-436-1300
www.murata.com
Note: Indicate that you are using the MAX2022 when contacting
these component suppliers.
1) Calibrate the power meter. For safety margin, use a
power sensor rated to at least +20dBm, or use
padding to protect the power head as necessary.
2) Connect a 3dB pad to the DUT end of the RF signal
generators’ SMA cable. This padding improves
VSWR and reduces the errors due to mismatch.
3) Use the power meter to set the RF signal generators
according to the following:
•
Quick Start
The MAX2022 EV kit is fully assembled and factory tested. Follow the instructions in the Connections and
Setup section for proper device evaluation as an
upconverter.
Test Equipment Required
This section lists the recommended test equipment to
verify the operation of the MAX2022 as an upconverter.
It is intended as a guide only, and substitutions may be
possible.
•
One DC supply capable of delivering +5.0V and
350mA
•
One low-noise RF signal generator capable of delivering 10dBm of output power in the 1GHz to 3GHz
frequency range (i.e., HP 8648)
•
One I/Q generator capable of producing two differential 1MHz sine waves, 90° out-of-phase with each
other, with a 200mVP-P differential amplitude
•
One quad-channel oscilloscope with a 100MHz
minimum bandwidth
•
Low-capacitance oscilloscope probes
•
One RF spectrum analyzer with a 100kHz to 3GHz
frequency range (HP 8561E)
•
One RF power meter (HP 437B)
•
One power sensor (HP 8482A)
Connections and Setup
This section provides a step-by-step guide to testing
the basic functionality of the EV kit as an upconverter.
As a general precaution to prevent damaging the outputs by driving high VSWR loads, do not turn on DC
power or RF signal generators until all connections are
made.
This upconverter procedure is general to operation with
an I/Q baseband input signal at 1MHz. Choose the test
frequency based on the particular system’s frequency
plan and adjust the following procedure accordingly.
See Figure 2 for the test setup diagram.
2
LO signal source: 0dBm into DUT at 2140MHz
(this will be approximately 3dBm before the
3dB pad).
Use an oscilloscope to set the baseband I/Q differential inputs to the following:
•
I/Q signal source: 109mVP-P differential into I+/Iand Q+/Q- input ports at 1MHz. Note that the
differential I+/I- and Q+/Q- source impedance
needs to be 50Ω.
4) Disable the signal generator outputs.
5) Connect the I/Q source to the differential I/Q ports.
6) Connect the LO source to the EV kit LO input.
7) Measure the loss in the 3dB pad and cable that will
be connected to the RF port. Losses are frequency
dependent, so test this at 2140MHz (the RF frequency). Use this loss as an offset in all output
power/gain calculations.
8) Connect this 3dB pad to the EV kit’s RF port connector and connect a cable from the pad to the
spectrum analyzer.
9) Set the DC supply to +5.0V, and set a current limit
around 350mA, if possible. Disable the output voltage and connect the supply to the EV kit (through
an ammeter, if desired). Enable the supply.
Readjust the supply to get +5.0V at the EV kit. A
voltage drop occurs across the ammeter when the
device is drawing current.
10) Enable the LO and the I/Q sources.
Testing the Direct Upconverter
Adjust the center and span of the spectrum analyzer to
2140MHz and 5MHz, respectively. The LO leakage
appears at 2140MHz and there are two sidebands at
2139MHz and 2141MHz (LSB and USB). One of the
sidebands is the selected RF signal, while the second
is the image. Depending on whether the Q channel is
90 degrees advanced or 90 degrees delayed from the
I channel determines which sideband is selected and
which is rejected. Note that the sideband suppression
is about 45dB typical down from the desired sideband.
_______________________________________________________________________________________
MAX2022 Evaluation Kit
Detailed Description
The MAX2022 is designed for upconverting (downconverting) to (from) a 1500MHz to 2500MHz RF from (to)
baseband. Applications include single- and multicarrier
1800MHz to 2200MHz UMTS/WCDMA, cdma2000,
DCS/PCS, and WiMAX base stations. Direct upconversion (downconversion) architectures are advantageous
since they significantly reduce transmitter (receiver)
cost, part count, and power consumption compared to
traditional heterodyne conversion systems.
The MAX2022 integrates internal baluns, an LO buffer,
a phase splitter, two LO driver amplifiers, two matched
double-balanced passive mixers, and a wideband
quadrature combiner. Precision matching between the
in-phase and quadrature channels, and highly linear
mixers achieve excellent dynamic range, ACLR, 1dB
compression point, along with LO and sideband suppression, making it ideal for 4-carrier W-CDMA/UMTS
operation.
The MAX2022 EV kit circuit allows for thorough analysis
and a simple design-in.
Supply-Decoupling Capacitors
The MAX2022 has several RF processing stages that
use the various V CC pins. While they have on-chip
decoupling, off-chip interaction between them may
degrade gain, linearity, carrier suppression, and output
power. Proper voltage-supply bypassing is essential for
high-frequency circuit stability.
C1, C6, C7, C10, and C13 are 22pF supply-decoupling
capacitors used to filter high-frequency noise. C2, C5,
C8, C11, and C12 are larger 0.1µF capacitors used for
filtering lower-frequency noise on the supply.
DC-Blocking Capacitors
The MAX2022 has internal baluns at the RF output and
LO input. These inputs have almost 0Ω resistance at
DC, and so DC-blocking capacitors C3 and C9 are
used to prevent any external bias from being shunted
directly to ground.
LO Bias
The bias current for the integrated LO buffer is set with
resistor R1 (432Ω ±1%). Resistors R2 (562Ω ±1%) and
R3 (301Ω ±1%) set the bias currents for the LO driver
amplifiers. Increasing the value of R1, R2, and R3
reduces the current, but the device will operate at
reduced performance levels. Doubling the values of R1,
R2, and R3 reduces the total current to approximately
166mA, but the OIP3 degrades by approximately 4.5dB.
IF Bias
When desired, a common-mode voltage can be injected onto the BB input lines through TP3 on the EV kit. To
enable this feature, the proper value of resistors R5, R6,
R9, R10, and R12–R15 need to be installed. Resistors
R15/R14 and R13/R12 form voltage-dividers, while R5,
R6, R9, and R10 are large-value bias injection resistors.
See Figure 3 for EV kit schematic details.
External Diplexer
LO leakage at the RF port can be nulled to a level less
than -80dBm by introducing DC offsets at the I and Q
ports. However, this null at the RF port can be compromised by an improperly terminated I/Q IF interface.
Care must be taken to match the I/Q ports to the driving
DAC circuitry. Without matching, the LO’s second-order
(2fLO) term may leak back into the modulator’s I/Q input
port where it can mix with the internal LO signal to produce additional LO leakage at the RF output. This leakage effectively counteracts against the LO nulling. In
addition, the LO signal reflected at the I/Q IF port produces a residual DC term that can disturb the nulling
condition.
As shown in Figure 1, providing an RC termination on
each of the I+, I-, Q+, Q- ports reduces the amount of
LO leakage present at the RF port under varying temperature, LO frequency, and baseband drive conditions.
Note that the resistor value is chosen to be 100Ω with a
corner frequency 1 / (2πRC) selected to adequately filter
the fLO and 2fLO leakage, yet not affecting the flatness
of the baseband response at the highest baseband
frequency. The common-mode fLO and 2fLO signals at
I+/I- and Q+/Q- effectively see the RC networks and
thus become terminated in 50Ω (R/2). The RC network
provides a path for absorbing the 2fLO and fLO leakage,
while the inductor provides high impedance at fLO and
2fLO to help the diplexing process.
_______________________________________________________________________________________
3
Evaluates: MAX2022
The desired sideband power level should be approximately -23.5dBm (-20.5dBm output power including
3dB pad loss). Phase and amplitude differences at the
I and Q inputs result in degradation of the sideband
suppression. Note that the spectrum analyzer’s uncalibrated absolute magnitude accuracy is typically no
better than ±1dB.
Evaluates: MAX2022
MAX2022 Evaluation Kit
C = 15pF
C = 10pF
100Ω
MAX2022
RF MODULATOR
L = 15nH
I
C = 15pF
C = 10pF
100Ω
C = 15pF
C = 10pF
LO
0°
90°
∑
100Ω
L = 15nH
Q
C = 15pF
C = 10pF
100Ω
Figure 1. Diplexer Network
Layout Considerations
The MAX2022 evaluation board can be a guide for your
board layout. Pay close attention to thermal design and
close placement of components to the IC. The
MAX2022’s package exposed paddle (EP) conducts
heat from the device and provides a low-impedance
electrical connection to the ground plane. The EP must
be attached to the PCB ground plane with a low thermal and electrical impedance contact. Ideally, this is
achieved by soldering the backside of the package
4
directly to a top metal ground plane on the PCB.
Alternatively, the EP can be connected to an internal or
bottom-side ground plane using an array of plated vias
directly below the EP. The MAX2022 EV kit uses nine
evenly spaced 0.016in-diameter, plated through holes
to connect the EP to the lower ground planes.
Depending on the ground plane spacing, large surface-mount pads in the IF path may need to have the
ground plane relieved under them to reduce parasitic
shunt capacitance.
_______________________________________________________________________________________
MAX2022 Evaluation Kit
Evaluates: MAX2022
BENCH MULTIMETER HPIB
(HP 34401A)
DIFFERENTIAL I/Q GENERATOR
POWER SUPPLY 3-OUT, HPIB
(AG E3631A)
5.0V, 350mA (max)
292mA
+
(AMMETER)
-
+
-
+ 5V
Q+
GND
Q-
MAX2022EVKIT
LO
3dB
2140.000MHz
I+
I-
RF SIGNAL GENERATOR
(HP 8648B)
3dB
RF
RF SPECTRUM ANALYZER
(HP 8561x)
QUAD-CHANNEL OSCILLOSCOPE
RF POWER METER
(GIGA 80701A, HP 437B)
RF HIGHPOWER SENSOR
Figure 2. Test Setup Diagram
_______________________________________________________________________________________
5
VCC
C2
0.1µF
C1
22pF
R1
432Ω
LO
GND
VCC
C3
22pF
TP2
GND
+5V
TP1
R2
562Ω
C5
0.1µF
VCC
COMP
RBIASLO2
GND
VCCLOA
LO
GND
RBIASLO1
9
8
7
6
5
4
3
2
C10
22pF
BIAS
LO2
BIAS
LO1
BIAS
LO3
0°
90°
U1
∑
EP
MAX2022
10 11 12 13 14 15 16 17 18
C6
22pF
GND
1
GND
GND
RBIASLO3
GND
36 35 34 33 32 31 30 29 28
GND
GND
VCCLOQ1
GND
GND
VCCLOI1
R3
301Ω
GND
C13
22pF
VCCLOQ2
GND
VCCLOI2
GND
C12
0.1µF
GND
VCC
GND
GND
6
C7
22pF
GND
19
20
21
22
23
24
25
26
27
C8
0.1µF
VCC
GND
GND
BBIN
BBIP
GND
RFOUT
BBQP
BBQN
GND
C11
0.1µF
VCC
R4
0Ω
R7
0Ω
R11
0Ω
R8
0Ω
C9
1.2pF
RF
R5
R6
R10
R9
I+
I-
Q-
Q+
R12
R14
R13
TP3
R15 IBIAS
Evaluates: MAX2022
MAX2022 Evaluation Kit
Figure 3. MAX2022 EV Kit Schematic
_______________________________________________________________________________________
MAX2022 Evaluation Kit
Figure 5. MAX2022 EV Kit PCB Layout—Top Soldermask
Figure 6. MAX2022 EV Kit PCB Layout—Top Layer Metal
Figure 7. MAX2022 EV Kit PCB Layout—Inner Layer 2 (GND)
_______________________________________________________________________________________
Evaluates: MAX2022
Figure 4. MAX2022 EV Kit PCB Layout—Top Silkscreen
7
Evaluates: MAX2022
MAX2022 Evaluation Kit
Figure 8. MAX2022 EV Kit PCB Layout—Inner Layer 3 (Routes)
Figure 9. MAX2022 EV Kit PCB Layout—Bottom Layer (Metal)
Figure 10. MAX2022 EV Kit PCB Layout—Bottom Soldermask
Figure 11. MAX2022 EV Kit PCB Layout—Bottom Silkscreen
Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are
implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.
8 _____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600
© 2006 Maxim Integrated Products
Springer
is a registered trademark of Maxim Integrated Products, Inc.