MAXIM MAX2406EVKIT

MAX2406 Evaluation Kit
____________________Component List
DESIGNATION QTY
♦ +2.7V to +5.5V Single-Supply Operation
♦ 50Ω SMA Inputs and Outputs on RF, IF, and LO
Ports
♦ Allows Testing of Shutdown Mode
♦ Fully Assembled and Tested
DESCRIPTION
C1, C2
2
47pF ceramic capacitors
C3, C7,
C8, C13
4
220pF ceramic capacitors
C4, C5,
C11, C12
4
1000pF ceramic capacitors
C6, C15
2
1pF ceramic capacitors
C9
1
10µF tantalum capacitor
AVX TAJC106K016
C10, C14
2
0.1µF ceramic capacitors
IF, LNAIN, LO,
LNAOUT,
RXMXIN
5
SMA connectors (PC edge mount)
JU1
1
3-pin header
L1, L2,
L6, L7
4
27nH inductors
Coilcraft 1008CS-270XMBC
L3
1
4:1 balun
Toko 617DB-1010 type B4F
L4
0
Not installed
L5
1
4.7nH inductor
Toko LL2012-F4N7S
R1
1
1kΩ resistor
R2, R3
2
0Ω resistors
R4
0
Not installed
U1
1
MAX2406EEP (20 QSOP)
______________Ordering Information
PART
TEMP. RANGE
IC PACKAGE
MAX2406EVKIT
-40°C to +85°C
20 QSOP
_________________________Quick Start
______________Component Suppliers
SUPPLIER
____________________________Features
PHONE/
FAX
INTERNET
The MAX2406 is fully assembled and factory tested.
Follow these instructions for initial evaluation of the
MAX2406.
Test Equipment Required
This section lists the test equipment recommended for
verifying operation of the MAX2406. It is intended as a
guide only; some substitutions may be possible.
• Two RF signal generators capable of delivering at
least 0dBm of output power at frequencies up to
2GHz (HP8648C or equivalent). One generator is
required for the local oscillator (LO) source; the
other is required for the mixer input. Only one generator is required to operate the LNA.
• An RF spectrum analyzer that covers the MAX2406’s
operating frequency range (HP8561E, for example).
• A power supply that can provide up to 100mA at
2.7V to 5.5V.
• An ammeter for measuring the supply current
(optional).
• Several 50Ω SMA cables.
Connections and Setup
Coilcraft
(847) 639-6400/
(847) 639-1469
http://www.coilcraft.com
AVX
(803) 946-0690/
(803) 626-3123
http://www.avxcorp.com
This section provides a step-by-step guide to getting
the EV kit operational and testing both the LNA and the
receive mixer. Do not turn on the DC power or RF
signal generators until all connections have been
made.
________________________________________________________________ Maxim Integrated Products
1
For free samples & the latest literature: http://www.maxim-ic.com, or phone 1-800-998-8800.
For small orders, phone 408-737-7600 ext. 3468.
Evaluates: MAX2406
_______________General Description
The MAX2406 evaluation kit (EV kit) simplifies testing of
the MAX2406. This EV kit allows the evaluation of the
low-noise amplifier (LNA) as well as the receive downconverter mixer.
Evaluates: MAX2406
MAX2406 Evaluation Kit
Low-Noise Amplifier
1) Set the RXEN jumper (JU1) on the EV kit to the
“logic 1” position. This enables the MAX2406.
2) Connect a DC supply set to 3V (through an ammeter, if desired) to the VCC and GND terminals on the
EV kit. Do not turn on the supply.
This section describes the MAX2406 EV kit circuitry.
For more detailed information about the operation of the
device itself, please consult the MAX2406 data sheet.
3) Connect one RF signal generator to the LNAIN SMA
connector. Do not turn on the generator’s output.
Set the generator for an output frequency of 1.9GHz
and a power level of -40dBm.
The LNA circuitry consists of two DC-blocking capacitors:
one at the input (C13) and one at the output (C8). A shunt
capacitor (C15) provides a simple matching network to
improve the input return loss.
4) Connect a spectrum analyzer to the LNAOUT SMA
connector on the EV kit. Set the spectrum analyzer
to a center frequency of 1.9GHz, a total span of
200MHz, and a reference level of 0dBm.
5) Turn on the DC supply; the supply current should
read approximately 20mA (if using an ammeter).
6) Activate the RF generator’s output. A 1.9GHz signal
shown on the spectrum analyzer’s display should
indicate a typical gain of 16dB after accounting for
cable losses.
7) If desired, the shutdown feature can be tested by
moving the RXEN jumper (JU1) into the “logic 0”
position. This disables the part and reduces the
supply current to typically 0.1µA.
Receive Downconverter Mixer
1) Remove the RF signal generator and spectrum analyzer from the LNAIN and LNAOUT connections, if
necessary. The DC supply connections needed for
testing the downconverter mixer are the same as in
the LNA section.
2) Connect one RF signal generator (with the output
disabled) to the LO SMA connector. Set the frequency to 1.5GHz and the output power to -10dBm.
This is the LO signal.
3) Connect the other RF signal generator (with the output disabled) to the RXMXIN SMA connector. Set
the frequency to 1.9GHz and the amplitude to
-30dBm.
4) Connect the spectrum analyzer to the IF SMA connector. Set the spectrum analyzer to a 400MHz center frequency, a 200MHz total span, and a 0dBm
reference level.
5) Turn on the LO signal generator and the RF signal
generator.
6) The downconverted output signal at 400MHz is visible on the spectrum analyzer, indicating a mixer
conversion gain of 8.4dB after accounting for cable
and balun losses. The balun loss is typically 1dB at
400MHz.
2
_______________Detailed Description
Low-Noise Amplifier
Local Oscillator
The MAX2406 EV kit’s LO input requires only a DC blocking capacitor (C3). No other circuitry is needed. For more
information on the LO port, including the optional use of a
differential LO source, consult the MAX2406 data sheet.
Mixer Input
The receiver mixer’s input (RXMXIN) requires a simple
matching network. Capacitor C6 and inductor L5 are
used to match the input pin to 50Ω, while C7 provides
DC blocking.
IF Output
The MAX2406 has a differential IF output port (IF and IF)
that can be used either in a differential or single-ended
configuration. The EV kit uses a differential configuration.
The balun (L3) converts the MAX2406’s differential output
signal into a single-ended signal compatible with 50Ω test
equipment. The balun is not required in a typical application. Inductors L1, L2, L6, and L7 provide DC bias and an
impedance-matching network. Please note that the matching network is frequency selective and must be changed
for operation at other IF frequencies. Consult the MAX2406
data sheet for a plot of IF output impedance versus frequency. Capacitors C4 and C5 provide DC blocking. The
balun (L3) provides the differential to single-ended conversion with about 1dB of loss at 400MHz. The IF output signal is then connected to the IF SMA connector. Resistors
R2 and R3 (0Ω) and inductor L4 (not installed) are provided as pads on the EV kit’s PC board layout for experimentation, if desired.
______________________________Layout
A good PC board layout is an essential part of an RF
circuit design. The EV kit’s PC board can serve as a
guide for laying out a board using the MAX2406.
Each VCC node on the PC board has its own decoupling capacitor. This minimizes supply coupling from
one section of the MAX2406 to another. A star topology
for the supply layout, in which each VCC node on the
MAX2406 circuit has a separate connection to a central
VCC node, can further minimize coupling between the
LNA and mixer sections of the MAX2406.
_______________________________________________________________________________________
GND
VCC
LO
SMA
J1
LOGIC 0
RXEN
LOGIC 1
J6
J5
VCC
LNAIN
SMA
JU1
J7
C9
10µF
C14
0.1µF
R1
1kΩ
C13
220pF
RXMXIN
SMA
VCC
C2
47pF
C10
0.1µF
C3
220pF
C1
47pF
C15
1pF
C7
220pF
VCC
VCC
9
8
7
6
5
4
3
2
1
C6
1pF
16
MAX2406
RXMXIN
10
11
12
15
17
18
IF
IF
LNAOUT
GND
GND GND GND GND GND GND
VCC
LO
LO
RXEN
VCC
GND
GND
LNAIN
GND
L5
4.7nH
13
14
19
20
L1
27nH
R4
(OPEN)
L2
27nH
C8
220pF
L6
27nH
VCC
L7
27nH
VCC
C5
1000pF
L3
1
BALUN
WITH
4:1
IMPEDANCE
RATIO
C11
1000pF 4
C12
1000pF
LNAOUT
SMA
C4
1000pF
J4
R2
0Ω
L4
(OPEN)
R3
0Ω
J2
IF
SMA
Evaluates: MAX2406
J3
MAX2406 Evaluation Kit
Figure 1. MAX2406 EV Kit Schematic
_______________________________________________________________________________________
3
Evaluates: MAX2406
MAX2406 Evaluation Kit
1.0"
1.0"
Figure 2. MAX2406 EV Kit Layout—Top Silk Screen and Pad
Placement
1.0"
Figure 3. MAX2406 EV Kit Layout—Component Side
1.0"
Figure 4. MAX2406 EV Kit Layout—Ground Plane (layer 2)
Figure 5. MAX2406 EV Kit Layout—Bottom Side (solder side)
(layer 4)
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.
4 _____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600
© 1997 Maxim Integrated Products
Printed USA
is a registered trademark of Maxim Integrated Products.