MAXIM MAX9981_1

19-2691; Rev 0; 12/02
MAX9981 Evaluation Kit
This document provides a list of equipment required to
evaluate the device, a straightforward test procedure to
verify functionality, a description of the EV kit circuit,
the circuit schematic, a bill of materials (BOM) and artwork for each layer of the PC board.
Contact MaximDirect sales at 888-629-4642 to check
on pricing and availability for these kits.
Features
♦
♦
♦
♦
♦
♦
♦
♦
♦
♦
♦
Fully Assembled and Tested
+27.3dBm Input IP3
+13.6dBm Input 1dB Compression Point
825MHz to 915MHz RF Frequency
725MHz to 1085MHz LO Frequency
70MHz to 170MHz IF Frequency
2.1dB Conversion Gain
10.8dB Noise Figure
42dB Channel-to-Channel Isolation
-5dBm to +5dBm LO Drive
Built-In LO Switch with 52dB LO1-to-LO2 Isolation
Ordering Information
Component Suppliers
SUPPLIER
PHONE
WEBSITE
Coilcraft
800-322-2645 www.coilcraft.com
Digi-Key
800-344-4539 www.digikey.com
Johnson
507-833-8822 www.johnsoncomponents.com
Mini-Circuits
718-934-4500 www.minicircuits.com
Murata
770-436-1300 www.murata.com
PART
TEMP RANGE
IC PACKAGE
MAX9981EVKIT
-40°C to +85°C
36 QFN-EP*
(6mm × 6mm)
*EP = Exposed paddle.
Component List
DESIGNATION
QTY
DESCRIPTION
C1, C4
2
33pF ±5%, 50V C0G ceramic
capacitors (0603)
Murata GRM1885C1H330J
C2, C3
2
3.9pF ±0.25pF, 50V C0G ceramic
capacitors (0603)
Murata GRM1885C1H3R9C
C5, C6,
C9, C10
4
100pF ±5%, 50V C0G ceramic
capacitors (0603)
Murata GRM1885C1H101J
C7, C8
2
15pF ±5%, 50V C0G ceramic
capacitors (0603)
Murata GRM1885C1H150J
2
0.033µF ±10%, 25V X7R ceramic
capacitors (0603)
Murata GRM188R71E333K
C11, C12
C13, C16,
C17, C20
4
220pF ±5%, 50V C0G ceramic
capacitors (0603)
Murata GRM1885C1H221J
C14, C15,
C18, C19
4
330pF ±5%, 50V C0G ceramic
capacitors (0603)
Murata GRM1885C1H331J
DESIGNATION
QTY
DESCRIPTION
L1–L4
4
560nH ±5% wire-wound
inductors (1008)
Coilcraft 1008CS-561XJBC
R1, R2
2
267Ω ±1% resistors (0603)
R3–R6
4
137Ω ±1% resistors (0603)
R7
1
47kΩ ±5% resistor (0603)
J1–J6
6
PC board edge-mount SMA RF
connectors (flat tab launch)
Johnson 142-0741-856
T1, T2
1
4:1 transformers (200:50)
Mini-Circuits TC4-1W-7A
TP1
1
Large test point for 0.063in PC board
(red) Mouser 151-107
TP2
1
Large test point for 0.063in PC board
(black) Mouser 151-103
TP3
1
Large test point for 0.063in PC board
(white) Mouser 151-101
U1
1
MAX9981EGX-T*
*The exposed paddle conductor on U1 must be solder
attached to a grounded pad on the circuit to ensure a proper
electrical/thermal design.
________________________________________________________________ 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: MAX9981
General Description
The MAX9981 evaluation kit (EV kit) simplifies the evaluation of the MAX9981 825MHz to 915MHz dual high-linearity active down-converter mixer. It is fully assembled
and tested at the factory. Standard 50Ω SMA connectors are included for the inputs and outputs to allow
quick and easy evaluation on the test bench.
Evaluates: MAX9981
MAX9981 Evaluation Kit
Quick Start
The MAX9981 EV kit is fully assembled and factory tested. Follow the instructions in the Connections and
Setup section for proper device evaluation.
Test Equipment Required
Table 1 lists the equipment required to verify the operation of the MAX9981 EV kit. It is intended as a guide
only, and some substitutions can be made.
Connections and Setup
This section provides a step-by-step guide for testing
the basic functionality of the EV kit. As a general precaution to prevent damaging the outputs by driving
high-VSWR loads, do not turn on DC power or RF
signals until all connections are made.
This procedure is specific to operation with an RF input
frequency range of 825MHz to 915MHz, low-side injected
LO for a 100MHz IF. Choose the test frequency based on
the particular system’s frequency plan, and adjust the
following procedure accordingly. See Figure 1 for the
main mixer test setup diagram.
1) Calibrate the power meter for 870MHz. For safety
margin, use a power sensor rated to at least
+20dBm, or use padding to protect the power head
as necessary.
Table 1. Test Equipment Required
EQUIPMENT
QTY
DESCRIPTION
HP E3631A
1
DC power supply
Fluke 75 series II
1
Digital multimeter (ammeter)
HP/Agilent 8648B
3
RF signal generators
HP 437B
1
RF power meter
HP 8561
1
Spectrum analyzer
HP 8482A
1
High-power sensor (power head)
3dB pad
4
3dB attenuators
50Ω termination
2
50Ω (1W) terminations
8) Connect this 3dB pad to the EV kit’s IFMAIN connector, and connect a cable from the pad to the
spectrum analyzer.
9) Connect a 50Ω terminator to the unused RF input
and IF output.
10) Set the DC supply to +5.0V, and set a current limit to
around 500mA if possible. Disable the output voltage
and connect supply to the EV kit through a low internal resistance ammeter. Enable the supply. Re-adjust
the supply to get +5.0V at the EV kit since there will
be a voltage drop across the ammeter when the
mixer is drawing current.
2) Connect 3dB pads to DUT ends of each of the
three RF signal generators’ SMA cables. This
padding improves VSWR and reduces the errors
due to mismatch.
11) Select LO1 by leaving LOSEL (TP3) unconnected
or connecting it to +5V. If left floating, LOSEL will
be pulled high by an on-board pullup resistor.
3) Use the power meter to set the RF signal generators according to the following:
To test the diversity mixer, disable the LO and RF
sources, turn off the DC supply and repeat steps 3
through 12, replacing RFDIV for RFMAIN and IFDIV for
IFMAIN. Be sure to terminate RFMAIN and IFMAIN with
50Ω terminators. See Figure 2 for diversity mixer test
setup.
• RFMAIN signal source: -5dBm into DUT at
870MHz (approximately -2dBm before the 3dB
pad)
• LO1 signal source: 0dBm into DUT at 770MHz
(approximately +3dBm before the 3dB pad)
• LO2 signal source: 0dBm into DUT at 771MHz
(approximately +3dBm before the 3dB pad)
4) Disable the signal generator outputs.
5) Connect the RF source (with pad) to RFMAIN.
6) Connect the LO1 and LO2 signal sources to the EV
kit LO inputs.
7) Measure loss in the 3dB pad and the cable that is
connected to IFMAIN. Losses are frequency
dependent, so test this at 100MHz (IF frequency).
Use this loss as an offset in all output power/gain
calculations.
2
12) Enable the LO and the RF sources.
Testing the Mixer
Adjust the center and span of the spectrum analyzer to
observe the IF output tone at 100MHz. The level should
be about -5.4dBm (2.6dB conversion gain, 3dB pad
loss). The spectrum analyzer’s absolute magnitude
accuracy is typically no better than ±1dB; therefore,
use the power meter to get an accurate output power
measurement. There will also be a tone at 99MHz which
is due to the LO signal applied to LO2. The amount of
suppression between the 100MHz and 99MHz signals
is the switch isolation.
Connect LOSEL to GND to select LO2. Observe that
the IF output level at 99MHz increases while the
100MHz level decreases.
_______________________________________________________________________________________
MAX9981 Evaluation Kit
The MAX9981 is a highly integrated downconverter. RF
and LO baluns are integrated on-chip, as well as an LO
buffer and a SPDT LO input select switch. The EV kit circuit consists mostly of supply decoupling capacitors and
DC-blocking capacitors, allowing for a simple design-in.
Supply Decoupling Capacitors
Ceramic capacitors C5, C6, C9, and C10 are 100pF
used for high-frequency bypass on the supply. C13
and C17 are 220pF bypass capacitors for IF frequencies. C16 and C20 are used to provide IF ground for
the center tap of T1 and T2. Although called out,
replacing C16 and C20 with a short circuit causes little
to no change in performance.
DC-Blocking Capacitors
The MAX9981 has internal baluns on the RFMAIN,
RFDIV, LO1, and LO2 inputs. These inputs have almost
0Ω resistance at DC. C1 and C4 are 33pF DC-blocking
capacitors on the RF ports and C7 and C8 are 15pF DC
blocks for the LO ports. C14, C15, C18, and C19 are
used to block DC current from flowing into the transformers along with providing flexibility for matching.
RFBIAS
Bias current for the mixer is set with resistors R1 and
R2 (267Ω ±1%). This value was carefully chosen for
best linearity and lowest supply current through testing
at the factory. Changing this value, or using lower tolerance resistors degrades performance.
IF±
The MAX9981 employs a differential IF output to offer
increased IP2 system performance. The IF outputs look
like an open collector with 1.8pF of differential capacitance. Inductors L1–L4 are used to resonate out the onchip and evaluation board capacitance at the IF
frequency of interest along with providing a low-resistance path for biasing of the IF amplifier. R3–R6 provide a real impedance used to establish the 200Ω
differential impedance. C14, C15, C18, and C19 provide DC blocking along with adding in the flexibility for
tuning. The 4:1 baluns (T1 and T2) transform the 200Ω
differential impedance to 50Ω single ended for ease of
measurement. The EV kit IF is matched for operation
over the 70MHz to 100MHz frequency range.
Resistors R3–R6 affect the gain of the mixer. For a typical 2.0dB gain, 137Ω resistors are used for R3–R6.
Higher mixer gain can be realized by increasing R3–R6
and retuning L1–L4, C14, C15, C18, and C19 for IF
impedance matching. For example, R3 through R6 =
250Ω, L1 through L4 = 330nH, C14 = C15 = C18 = C19
= 56pF yields a mixer gain of 4.6dB at 70MHz IF with
an IF return loss of 12dB.
As the differential IF outputs are relatively high impedance (200Ω), they are more susceptible to component
parasitics. It is often good practice to relieve the
ground plane directly underneath large components to
reduce associated shunt-C parasitics.
LOSEL
The EV kit includes a 47kΩ pullup resistor to allow for
easy selection of the LO port. Providing a ground at
TP3 selects LO2, while leaving TP3 open selects LO1.
To drive TP3 from an external source, follow the limits
called out in the MAX9981 data sheet. Logic voltages
should not be applied to TP3 without the +5V applied.
Doing so can cause the on-chip ESD diodes to conduct
and could damage the part.
Modifying the EV Kit
The RF and LO inputs are broadband matched, so
there is no need to modify the circuit for use anywhere
in the 825MHz to 915MHz RF range (725MHz to
1085MHz LO range).
Retuning for a different IF is as simple as scaling the
values of the IF pullup inductors up or down with frequency. The IF outputs look like an open collector with
3.6pF to ground (1.8pF differential) from the chip. This
capacitance, along with approximately 5.6pF from the
evaluation board, can be resonated out at the frequency of interest by proper selection of the bias inductor
(L1–L4). To determine the inductor value use the following equation:
fIF =
1
2π L x C
The IF output network is tuned for operation at approximately 70MHz, so a 560nH inductor is used. For lower
IF frequencies (i.e., larger component values), maintain
the component’s Q value at the cost of a larger case
size unless it is unavoidable.
_______________________________________________________________________________________
3
Evaluates: MAX9981
Detailed Description
Evaluates: MAX9981
MAX9981 Evaluation Kit
POWER SUPPLY
(AG E3631A)
BENCH MULTIMETER
(HP 34401A)
5.0V 500mA (MAX)
291mA
(AMMETER)
OPEN = LO1
GND = LO2
RF SIGNAL GENERATOR
(HP 8648B)
870.000MHz
+5V
GND
RF SPECTRUM ANALYZER
(HP 8561x)
LOSEL
3dB
3dB
IFMAIN
RFMAIN
U1
MAX9981
IFDIV
RFDIV
50Ω
50Ω
LO1
LO2
3dB
3dB
RF SIGNAL GENERATOR
(HP 8648B)
RF SIGNAL GENERATOR
(HP 8648B)
770.000MHz
771.000MHz
RF POWER METER
(GIGA 80701A, HP 437B)
RF HIGHPOWER SENSOR
Figure 1. MAX9981 EV Kit Main Mixer Test Setup Diagram
Layout Considerations
The MAX9981 evaluation board can be a guide for your
board layout. Pay close attention to thermal design and
close placement of parts to the IC. The MAX9981 package exposed paddle (EP), conducts heat from the part
and provides a low-impedance electrical connection.
The EP must be attached to the PC board ground plane
with a low thermal and electrical impedance contact.
4
Ideally, this can be achieved by soldering the backside
package contact directly to a top metal ground plane on
the PC board. Alternatively, the EP can be connected to
a ground plane using an array of plated vias directly
below the EP.
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 shunt
capacitance.
_______________________________________________________________________________________
MAX9981 Evaluation Kit
Evaluates: MAX9981
POWER SUPPLY
(AG E3631A)
BENCH MULTIMETER
(HP 34401A)
5.0V 500mA (MAX)
291mA
(AMMETER)
OPEN = LO1
GND = LO2
RF SIGNAL GENERATOR
(HP 8648B)
+5V
GND
IFMAIN
RFMAIN
870.000MHz
RF SPECTRUM ANALYZER
(HP 8561x)
LOSEL
50Ω
50Ω
U1
MAX9981
3dB
3dB
IFDIV
RFDIV
LO1
LO2
3dB
3dB
RF SIGNAL GENERATOR
(HP 8648B)
RF SIGNAL GENERATOR
(HP 8648B)
770.000MHz
771.000MHz
RF POWER METER
(GIGA 80701A, HP 437B)
RF HIGHPOWER SENSOR
Figure 2. MAX9981 EV Kit Diversity Mixer Test Setup Diagram
_______________________________________________________________________________________
5
Evaluates: MAX9981
MAX9981 Evaluation Kit
C14
330pF
4:1 (200:50)
TRANSFORMER
5.0V
TP1
+5V
L1
560nH
5.0V
R3
137Ω
3
T1
6
J2
SMA
IFMAIN
2
TP2
GND
C13
220pF
L2
560nH
R4
137Ω
C16
220pF
4
1
5.0V
5.0V
GND
28
GND
29
30
VCC
GND
31
IFMAIN32
IFMAIN+
33
9
19
J3
SMA
LO2
LO2
GND
GND
GND
LOSEL
TP3
LOSEL
R7
5.0V
47kΩ
GND
VCC
GND
J4
SMA
LO1
LO1
18
C7
15pF
GND
17
20
GND
5.0V
GND
8
16
C4
33pF
21
VCC
RFDIV
7
15
TAPDIV
22
GND
DIVBIAS
6
14
J6
SMA
RFDIV
C3
3.9pF
23
10
C12
0.033µF
GND
5
IFDIV-
R2
267Ω
24
13
GND
25
4
IFDIV+
GND
12
R1
267Ω
26
MAX9981
3
GND
MAINBIAS
U1
2
VCC
C2
3.9pF
C8
15pF
27
11
TAPMAIN
C11
0.033µF
C10
100pF
1
GND
RFMAIN
34
C1
33pF
J1
SMA
RFMAIN
35
36
VCC
C5
100pF
GND
C15
330pF
5.0V
C6
100pF
C9
100pF
5.0V
C19
330pF
L4
560nH
R6
137Ω
L3
560nH
C20
R5 220pF
137Ω
4:1 (200:50)
TRANSFORMER
T2
3
6
2
C17
220pF
1
4
C18
330pF
Figure 3. MAX9981 EV Kit Schematic
6
_______________________________________________________________________________________
J5
SMA
IFDIV
MAX9981 Evaluation Kit
Evaluates: MAX9981
1.0"
Figure 4. MAX9981 EV Kit PC Board Layout—Top Silkscreen
1.0"
Figure 6. MAX9981 EV Kit PC Board Layout—Top Layer Metal
1.0"
Figure 5. MAX9981 EV Kit PC Board Layout—Top Soldermask
1.0"
Figure 7. MAX9981 EV Kit PC Board Layout—Inner Layer 2
(GND)
_______________________________________________________________________________________
7
Evaluates: MAX9981
MAX9981 Evaluation Kit
1.0"
1.0"
Figure 8. MAX9981 EV Kit PC Board Layout—Inner Layer 3
(Routes)
1.0"
Figure 9. MAX9981 EV Kit PC Board Layout—Bottom Layer
Metal
1.0"
Figure 10. MAX9981 EV Kit PC Board Layout—Bottom
Soldermask
Figure 11. MAX9981 EV Kit PC Board 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
© 2002 Maxim Integrated Products
Printed USA
is a registered trademark of Maxim Integrated Products.