MAX2043EVKIT ,Evaluation Kit for the MAX2043component suppliers.Component ListDESIGNATION QTY DESCRIPTIONDESIGNATION QTY DESCRIPTIONR1 1 357Ω ± ..
MAX2047ETJ ,High-Gain Vector MultipliersApplicationsCONTROL90°VI2 2 23 GNDAMPLIFIER IPHASESHIFTERVQ13 22 RBIASMAX2045Ordering InformationMA ..
MAX204CPE ,+5V RS-232 Transceivers with 0.1uF External Capacitorsapplications with limited circuit board space.
MAX204CWE ,+5V RS-232 Transceivers with 0.1uF External CapacitorsFeatures
Superior to Bipolar:
. 0.1pF to 10pF External Capacitors
' 120kbits/sec Data Rate
..
MAX204EWE ,+5V RS-232 Transceivers with 0.1uF External CapacitorsELECTRICAL CHARACTERISTICS
(MAX202/204/206/208/211/213VCC = 5V uF10%, MAX200/203/205/207 Vcc = 5 ..
MAX2051ETP+ ,SiGe, High-Linearity, 850MHz to 1550MHz Up/Downconversion Mixer with LO BufferBlock DiagramMicrowave LinksTOP VIEWMilitary Systems+20 19 18 17 16Predistortion ReceiversEP*Privat ..
MAX5115EEP ,Nonvolatile, Quad, 8-Bit DACs with 2-Wire Serial InterfaceFeatures♦ Nonvolatile Registers Initialize DACs to StoredThe MAX5115/MAX5116 quad, 8-bit, digital-t ..
MAX5116EEE ,Nonvolatile, Quad, 8-Bit DACs with 2-Wire Serial InterfaceApplicationsDAC1Digital Gain and Offset AdjustmentsNONVOLATILE/DAC1VOLATILEOUT1SCLProgrammable Atte ..
MAX512 ,Low-Cost, Triple, 8-Bit Voltage-Output DACs with Serial InterfaceFeaturesThe MAX512/MAX513 contain three 8-bit, voltage-output' Operate from a Single +5V (MAX512) o ..
MAX5120BEEE ,+3V/+5V, 12-Bit, Serial Voltage-Output DACs with Internal ReferenceFeaturesThe MAX5120/MAX5121 are low-power, 12-bit, voltage-' Single-Supply Operationoutput digital- ..
MAX5120BEEE+ ,+3V/+5V, 12-Bit, Serial, Voltage-Output DACs with Internal ReferenceFeaturesThe MAX5120/MAX5121 are low-power, 12-bit, voltage-♦ Single-Supply Operationoutput digital- ..
MAX5122AEEE ,+5V/+3V, 12-Bit, Serial, Force/Sense DACs with 10ppm/∑C Internal ReferenceApplicationsPin ConfigurationIndustrial Process ControlAutomatic Test EquipmentTOP VIEWFB 1 16 VDDD ..
MAX2043EVKIT
Evaluation Kit for the MAX2043
General DescriptionThe MAX2043 evaluation kit (EV kit) simplifies the evalu-
ation of the MAX2043 UMTS/WCDMA, DCS, PCS, and
WiMAX base-station up/downconversion mixer. 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.
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 PC board.
FeaturesFully Assembled and Tested50ΩSMA Connectors on Input and Output Ports1700MHz to 3000MHz RF Frequency Range1900MHz to 3000MHz LO Frequency RangeDC to 350MHz IF Frequency Range7.5dB Conversion Loss+31dBm Input IP3 (Downconversion)+23dBm Input 1dB Compression Point7.8dB Noise FigureIntegrated LO BufferIntegrated RF and LO Baluns Low -3dBm to +6dBm LO DriveBuilt-In SPDT LO Switch with 43dB LO1 to LO2
Isolation and 50ns Switching TimeExternal Current-Setting Resistor Provides Option
for Operating Mixer in Reduced-Power/Reduced-
Performance Mode
Evaluates: MAX2043
MAX2043 Evaluation Kit19-0570; Rev 0; 5/06
Component List
Ordering Information
PARTTEMP RANGEIC PACKAGEMAX2043EVKIT-40°C to +85°C36 Thin QFN-EP*
DESIGNATIONQTYDESCRIPTION1
4pF ±0.25pF, 50V C0G ceramic
capacitor (0402)
Murata GRM1555C1H4R0C
C2, C4, C6, C84
22pF ±5%, 50V C0G ceramic
capacitors (0402)
Murata GRM1555C1H220J0Not installed (0603)
C5, C7, C93
0.01µF ±10%, 25V X7R ceramic
capacitors (0402)
Murata GRM155R71E103K
J1–J44
PC board edge-mount SMA RF
connectors (flat-tab launch)
Johnson 142-0741-856
DESIGNATIONQTYDESCRIPTION1357Ω ±1% resistor (0402)147kΩ ±5% resistor (0603)11:1 transformer (50:50)
M/A-COM MABAES0029
TP11
Large test point for 0.062in PC board
(red)
Mouser 151-107-RC or equivalent
TP21
Large test point for 0.062in PC board
(black)
Mouser 151-103-RC or equivalent
TP31
Large test point for 0.062in PC board
(white)
Mouser 151-101-RC or equivalent
*EP = Exposed paddle.
Component Suppliers
SUPPLIERPHONEWEBSITEJohnson507-833-8822www.johnsoncomponents.com
M/A-Com800-366-2266www.macom.com
Murata770-436-1300www.murata.com
Note:Indicate that you are using the MAX2043 when contact-
ing these component suppliers.
Evaluates: MAX2043
MAX2043 Evaluation Kit
Quick StartThe MAX2043 EV kit is fully assembled and factory test-
ed. Follow the instructions in the Connections and
Setupsection for proper device evaluation.
Test Equipment RequiredThis section lists the recommended test equipment to
verify the operation of the MAX2043. It is intended as a
guide only, and substitutions may be possible:DC supply capable of delivering +5.0V and 175mAThree RF signal generators capable of delivering
10dBm of output power in the 1GHz to 3GHz frequency
range (i.e., HP 8648)RF spectrum analyzer with a minimum 100kHz to
3GHz frequency range (HP 8561E)RF power meter (HP 437B)Power sensor (HP 8482A)
Connections and SetupThis section provides a step-by-step guide to testing
the basic functionality of the EV kit. As a general pre-
caution 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 procedure is specific to operation in the US PCS
band (reverse channel: 1850MHz to 1910MHz), high-
side injected LO for a 200MHz IF. Choose the test fre-
quency based on the particular system’s frequency
plan, and adjust the following procedure accordingly.
See Figure 1 for the mixer test setup diagram:Calibrate the power meter for 2100MHz. For safety
margin, use a power sensor rated to at least
+20dBm, or use padding to protect the power head
as necessary.Connect 3dB pads to DUT ends of each of the two
RF signal generators’ SMA cables. This padding
improves VSWR and reduces the errors due to mis-
match.Use the power meter to set the RF signal generators
according to the following:RF signal source: 0dBm into DUT at 1900MHz
(this will be about +3dBm before the 3dB pad).LO1 signal source: 0dBm into DUT at 2100MHz
(this will be about +3dBm before the 3dB pad).LO2 signal source: 0dBm into DUT at 2101MHz
(this will be about +3dBm before the 3dB pad).Disable the signal generator outputs.Connect the RF source (with pad) to the RF port.Connect the LO1 and LO2 signal sources to the EV
kit’s LO1 and LO2 inputs, respectively.Measure the loss in the 3dB pad and cable that will
be connected to the IF port. Losses are frequency
dependent, so test this at 200MHz (the IF frequency).
Use this loss as an offset in all output power/gain cal-
culations.Connect this 3dB pad to the EV kit’s IF port connec-
tor and connect a cable from the pad to the spec-
trum analyzer.Set the DC supply to +5.0V, and set a current limit
of around 175mA if possible. Disable the output
voltage and connect the supply to the EV kit
(through an ammeter, if desired). Enable the sup-
ply. Readjust the supply to get +5.0V at the EV kit.
There will be a voltage drop across the ammeter
when the mixer is drawing current.
10)Select LO2 by connecting LOSEL (TP3) to GND.
11)Enable the LO and the RF sources.
Testing the MixerAdjust the center and span of the spectrum analyzer to
observe the IF output tone at 201MHz. The level should
be about -10.5dBm (7.5dB conversion loss, 3dB pad
loss). The spectrum analyzer’s absolute magnitude
accuracy is typically no better than ±1dB. Use the power
meter to get an accurate output power measurement.
Disconnect the GND connection to LOSEL. It will be
pulled high by a pullup resistor on the board to select
LO1. Observe that the 200MHz signal increases while
the 201MHz decreases.
Reconfigure the test setup using a combiner or hybrid
to sum the two LO inputs to do a two-tone IP3 measure-
ment if desired. Terminate the unused LO input in 50Ω.
Component List (continued)
DESIGNATIONQTYDESCRIPTION1
Active dual-mixer IC (6mm x 6mm,
36-pin TQFN with exposed paddle)
Maxim MAX2043ETX+
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.+Denotes lead-free package.
Detailed DescriptionThe MAX2043 is a high-linearity up/downconverter inte-
grated with RF and LO baluns, an LO buffer, and an
SPDT LO input select switch. The EV kit circuit uses the
MAX2043 and consists mostly of supply-decoupling
capacitors, DC-blocking capacitors, a current-setting
resistor, and an IF balun. The MAX2043 EV kit circuit
allows for thorough analysis and a simple design-in.
Supply-Decoupling CapacitorsCapacitor C4 is a 22pF supply-decoupling capacitor
used to filter high-frequency noise. Capacitors C5, C7,
and C9 are larger 0.01µF used for filtering lower frequen-
cy noise on the supply.
DC-Blocking CapacitorsThe MAX2043 has internal baluns at the RF and LO
inputs. These inputs have almost 0Ωresistance at DC,
and so DC-blocking capacitors C1, C6, and C8 are
used to prevent any external bias from being shunted
directly to ground.
LO BiasBias current for the integrated LO buffer is set with
resistor R1 (357Ω±1%). The DC current of the device
can be reduced by increasing the value of R1 but the
device would operate at reduced performance levels
(see the Modifying the EV Kitsection).
Tap NetworkCapacitor C3 helps to terminate the second-order inter-
modulation products.
IF±The MAX2043 mixer has an IF frequency range of DC
to 350MHz. Note that these differential ports are ideal
for providing enhanced IIP2 performance. Single-
ended IF applications require a 1:1 balun to transform
the 50Ωdifferential output impedance to a 50Ωsingle-
ended output. After the balun, the IF return loss is bet-
ter than 15dB. The differential IF is used as an input
port for upconverter operation. The user can use a dif-
ferential IF amplifier following the mixer, but a DC block
is required on both IF pins. In this configuration, the IF+
and IF- pins need to be returned to ground through a
high resistance (about 1kΩ). This ground return can
also be accomplished by grounding the RF tap (pin 8)
and AC-coupling the IF+ and IF- ports (pins 13 and 14).
LOSELThe EV kit includes a 47kΩpullup resistor (R2) for easy
selection of the LO port. Providing a ground at TP3
selects LO2, and leaving TP3 open selects LO1. To
drive TP3 from an external source, follow the limits
called out in the MAX2043 device data sheet. Logic
voltages should not be applied to LOSEL without the
+5V supply voltage. Doing so can cause the on-chip
ESD diodes to conduct and could damage the device.
Layout ConsiderationsThe MAX2043 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
MAX2043 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 PC board ground plane with a low
thermal and electrical impedance contact. Ideally, this
is achieved by soldering the backside of the package
directly to a top metal ground plane on the PC board.
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 MAX2043 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 sur-
face-mount pads in the IF path may need to have the
ground plane relieved under them to reduce parasitic
shunt capacitance.
Modifying the EV KitThe RF, LO, and IF ports are broadband matched, so
there is no need to modify the circuit for use anywhere
in the 1700MHz to 3000MHz RF range, 1900MHz to
3000MHz LO range, and 50MHz to 350MHz IF range.
The DC current of the device can be reduced if reduced
performance is acceptable. Reducing the current is
accomplished by increasing the value of R1. Doubling
the value of R1 reduces the DC current approximately
in half. Approximately 10% of the overall IC current is
used for basic operation of the device (R1 set at 357Ω)
and cannot be reduced.
Evaluates: MAX2043
MAX2043 Evaluation Kit
Evaluates: MAX2043
MAX2043 Evaluation Kit+-+
POWER SUPPLY
3-OUT, HPIB
(AG E3631A)
RF SIGNAL GENERATOR
(HP 8648B)
RF POWER METER
(GIGA 80701A,
HP 437B)
RF HIGH-
POWER SENSOR
(AMMETER)3dB
3dB
3dB
3dBLO2
LO1
+5V
GND
MAX2043EVKIT
RF SIGNAL GENERATOR
(HP 8648B)
RF SIGNAL GENERATOR
(HP 8648B)1900.000MHz
2100.000MHz
2101.000MHz
5.0V, 175mA (MAX)
RF SPECTRUM ANALYZER
(HP 8561x)
BENCH
MULTIMETER HPIB
(HP 34401A)108mA
GND
OPENLOSEL
Figure 1. Test Setup Diagram
Evaluates: MAX2043
MAX2043 Evaluation Kit35343331302928
GND
GND
VCC
MAX20431112131415161718
4pF
22pF
47kΩ
22pF
OPEN
GNDGNDGNDGNDGNDGNDV
0.01μF
GNDGND
GND
GND
GND
VCC
GND
RFTAP
VCC
0.01μF
NOTE: PINS 1–5, 7, 10, 11, 12, 15, 18, 20, 22, 24, 25, 26, 28, 29, 31–36 OF U1 HAVE NO INTERNAL CONNECTIONS. THESE PINS CAN BE CONNECTED BACK TO THE GROUNDED EXPOSED PADDLE WHERE POSSIBLE TO IMPROVE
PIN-TO-PIN ISOLATION.
VCC
357Ω
0.01μF
VCC
VCC
VCC
GND
GND
LO2
GND
GND
GND
LOSEL
22pF
SMA
SMA
LO2
TP3
LOSEL
22pF
EXPOSED
PADDLE
LO1J3
SMA
LO1
SMA
GNDGNDGNDGND
LO_ADJ
IF+
IF-
GND
TP2
GND
VCC
TP1
+5V
Figure2. MAX2043 EV Kit Schematic
Evaluates: MAX2043
MAX2043 Evaluation KitFigure 3. MAX2043 EV Kit PC Board Layout—Top SilkscreenFigure 4. MAX2043 EV Kit PC Board Layout—Top Soldermask
Figure 5. MAX2043 EV Kit PC Board Layout—Top Layer MetalFigure 6. MAX2043 EV Kit PC Board Layout—Inner Layer 2
(GND)
