MAXIM MAX2620

19-1248; Rev 1; 5/98
MAX2620 Evaluation Kit
____________________________Features
♦ Complete, Tunable VCO Test Board with Tank
Circuit
____________________Component List
DESIGNATION QTY
DESCRIPTION
♦ Tuning in 900MHz Frequency Range
♦ Low Phase Noise (-110dBc/Hz typical at 25kHz
offset from carrier)
♦ Operates from Single +2.7V to +5.25V Supply
♦ Two Output Buffers with 50Ω SMA Connectors
♦ Low-Power Shutdown Mode
♦ Test Port for Oscillator Tank Port Characterization
♦ Fully Assembled and Tested
C1, C7–C10,
C12
6
1000pF, 10% ceramic capacitors
C2, C11, C14
0
Not installed
C3
1
2.7pF, 10% ceramic capacitor
C4, C6
2
1pF, 10% ceramic capacitors
C5, C13, C17
3
1.5pF, 10% ceramic capacitors
C15
1
10µF, ±10%, 25V tantalum capacitor
Sprague 293D106X9025D2
D1
1
Varactor diode
Alpha Industries SMV1204-34
JU1, VCC,
GND
3
2-pin headers
L1
1
Ceramic coaxial resonator
Trans-Tech SR8800LPQ1357BY
L4
0
Not installed
L3
1
10nH inductor
Coilcraft 0603HS-10NTJBC
The MAX2620 EV kit is fully assembled and factory tested. Follow the instructions in the Connections and
Setup section.
OUT, OUT,
TEST PORT
3
SMA connectors (edge mount)
__________Test Equipment Required
R1, R3
2
10Ω, 5% resistors
R2
1
1kΩ, 5% resistor
R4
0
Not installed
R5
1
51Ω, 5% resistor
SHDN
1
3-pin header
U1
1
MAX2620EUA
VCONT
1
SMA connector (PC mount)
None
1
Shunt
None
1
MAX2620 circuit board
None
1
MAX2620 data sheet
NOTE: All capacitors and resistors are size 0805 unless otherwise noted.
______________Ordering Information
PART
MAX2620EVKIT
TEMP. RANGE
BOARD TYPE
-40°C to +85°C
Surface Mount
______________Component Suppliers
SUPPLIER
PHONE
FAX
Alpha Industries
(617) 935-5150
(617) 824-4579
Coilcraft
(847) 639-6400
(847) 639-1469
Sprague
(603) 224-1961
(603) 224-1430
Trans-Tech
(301) 695-9400
(301) 695-7065
_________________________Quick Start
•
Power supplies. Low-noise power supplies are recommended for oscillator-noise measurements. This
is especially important for the tuning voltage supplied to the varactor (VCONT). Noise or ripple on
the tuning voltage frequency-modulates the oscillator and causes spectral spreading. Batteries can be
used in place of power supplies, if necessary.
—DC supply capable of supplying +2.7V to +5.25V
at 20mA. Alternatively, use two or three 1.5V AA
batteries.
—DC supply capable of supplying 0V to +3V, continuously variable, for VCONT. Alternatively, use
two or three 1.5V batteries with a resistive voltage divider or potentiometer.
________________________________________________________________ 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: MAX2620
________________General Description
The MAX2620 evaluation kit (EV kit) simplifies evaluation of the MAX2620 integrated oscillator with buffered
outputs. It includes a varactor-based tank circuit that
allows the VCO to tune across an approximately 30MHz
band in the 900MHz frequency range. Outputs utilize
50Ω SMA connectors. The EV kit has a test port that
facilitates complete characterization of the MAX2620
tank port, enabling resonators to be designed for frequency ranges other than that supplied with the EV kit.
Evaluates: MAX2620
MAX2620 Evaluation Kit
•
•
•
•
HP8561E spectrum analyzer, or equivalent highsensitivity spectrum analyzer with approximately
3GHz frequency range. Contact the instrument
manufacturer for information regarding phase-noise
measurement capabilities.
Digital multimeter (DMM) to monitor DC supply and
VCONT, if desired
Male SMA 50Ω terminator
Network analyzer such as HP8753D (required only
if additional device characterization for oscillator
tank design at other frequencies is desired)
____________Connections and Setup
1) Verify that the shunt on jumper SHDN is installed
between pins 1 and 2 (SHDN = V CC ). Placing
the shunt between pins 2 and 3 (SHDN = GND)
puts the MAX2620 into low-current shutdown mode.
2) Connect the spectrum analyzer to either OUT or
OUT. Connect a 50Ω terminator to the output (OUT
or OUT) not connected to the spectrum analyzer.
3) Connect a +2.7V to +5.25V supply across VCC to
GND. VCC should be the most positive terminal.
4) Connect the tuning voltage supply to either VCONT
or JU1. This supply should be positive when referenced to ground.
____________________________Analysis
1) Using the spectrum analyzer, observe the voltagecontrolled oscillator’s output. With 1.5V applied to
VCONT, the fundamental output frequency will be
near 900MHz. The output power level will be
approximately -2dBm at OUT, or -12.5dBm at OUT.
Varying the voltage applied to VCONT between 0V
and VCC changes the fundamental oscillation frequency. (Increasing the voltage applied to VCONT
increases the frequency, and vice versa.) The typical tuning range is a 30MHz band centered near
900MHz with VCONT between 0.5V and 3V. To
avoid damaging the varactor, do not apply voltages
greater than 15V to VCONT. (The varactor on the
EV kit board has a 15V breakdown specification.)
2) Allow the oscillator to operate for about 5 minutes
to thermally stabilize the frequency. Since the frequency is not phase-locked to a reference, this
minimizes frequency drift and measurement error.
3) Center the fundamental on the spectrum analyzer
and set the frequency span to 100kHz.
4) Set the spectrum analyzer for single sweep. This
minimizes errors due to oscillator frequency drift.
5) Set the marker on the waveform’s peak.
2
6) Set another marker to measure the difference
between this peak and the signal level at 25kHz offset from the peak. (Phase noise can be observed at
frequencies other than 25kHz offset.)
7) Under the Marker function, select marker noise and
turn it on. This automatically scales the spectrum
analyzer’s output to take into account the resolution
BW filter’s non-ideal characteristics. If your spectrum
analyzer does not offer this feature, contact the manufacturer for proper scaling for noise measurements.
8) Verify that the resolution bandwidth is 1kHz.
9) Verify that the video bandwidth is 1kHz.
10) Read the measurement directly from the screen.
Phase noise will be about -110dBc/Hz. In some environments that have ambient pulse noise, this measurement may be difficult to achieve without additional shielding or the use of a shielded enclosure.
_____________________________Outputs
The MAX2620 EV kit is assembled with OUT matched
to 50Ω (at approximately 900MHz) using L3 and C13.
OUT is resistively pulled up to the supply with a 51Ω
resistor, R5. R5 provides a simple broadband 50Ω output match but offers less output power than OUT. The
EV kit provides additional component pads at R4, C14,
L4, and C11 to accommodate any output match configuration for OUT and OUT. Refer to the Output Matching
Configuration section in the MAX2620 data sheet for
more information.
___________Resonator and Varactor
The resonator tank circuit is critical in determining VCO
performance. It typically contains a varactor (voltagevariable capacitance) for voltage-tuning the center frequency. For best performance, use high-Q components
and choose values carefully.
The external resonant circuit on the MAX2620 EV kit
has been designed to operate near 900MHz. To synthesize the component values for other frequency
ranges, use the following procedure.
On the EV kit, C3 and C4 are feedback capacitors that
set the oscillator’s negative resistance and impedance.
Their values have been chosen to provide adequate
performance over a 650MHz to 1050MHz frequency
range. To optimize the values of these components for
a specific application, refer to the Feedback Capacitors
section in the MAX2620 data sheet.
Measure the MAX2620 TANK pin’s input impedance
with feedback capacitors C3 and C4 but without the
resonant circuit. This measurement takes into account
parasitic circuit elements that are specific to board lay-
_______________________________________________________________________________________
MAX2620 Evaluation Kit
The MAX2620 EV kit uses a low-voltage varactor. With
the coupling capacitor C17 kept small, the oscillator circuit is less affected by losses in the varactor. However,
keeping C17 small also reduces overall tuning range.
L1 on the MAX2620 is a ceramic coaxial resonator,
which provides the best phase-noise performance. For
cost-sensitive applications, the layout for L1 on the
MAX2620 EV kit is a dual pad that accepts either a
spring coil or a ceramic coaxial resonator. When properly specified, coaxial resonators provide tight tolerance inductance at very high Q for best circuit performance. Spring coils, such as Coilcraft mini-spring coils,
provide a good cost/performance compromise for costsensitive applications.
A useful technique is to configure the vector network analyzer to display 1/S11 for this measurement. The vector
network analyzer displays the information inside the unit
circle of the Smith chart. Most modern vector network
analyzers perform this conversion. Input-impedance data
presented in this format (1/S11) is the complement of the
input impedance, which is the impedance desired to provide the MAX2620 with feedback to oscillate at a particular frequency. The Typical Operating Characteristics section of the MAX2620 data sheet contains a plot of 1/S11
for specific values of C3 and C4 provided in the
MAX2620 EV kit. Also refer to the Tank Circuit Design
section in the MAX2620 data sheet.
_____________Layout Considerations
The MAX2620 EV kit can serve as a guide for your
board layout. To minimize the effects of parasitic elements, which may alter circuit performance, remove the
ground plane around and under the components that
make up the resonant circuit (C3–C6, C17, D1, and L1).
Keep PC board trace lengths as short as possible to
minimize parasitic inductance. Also keep decoupling
capacitors C1, C7, and C9 as close to the MAX2620 as
possible, with direct connection to the ground plane.
VCC
VCC
C8
1000pF
R1
10Ω
L3
10nH
R4
OPEN C13
1.5pF
1
J1
C2
50Ω OPEN
TEST SMA
PORT
2
C5
1.5pF
C3
2.7pF
3
C4
1pF
4
SMA
VCONT
JU1
R2
1k
D1
C17
1.5pF
L1
C6
1pF
VCC1
TANK
U1
MAX2620
OUT
C14
OPEN
8
OUT
7
VCC
VCC2
FDBK
GND
SHDN
OUT
C7
1000pF
R3
10Ω
6
C9
1000pF
L4
OPEN
R5
51Ω
C12
1000pF
50Ω
5
SMA
C10
1000pF
C11
OPEN
OUT
VCC
VCC
GND
50Ω
SMA
C1
1000pF
C15
10µF
25V
VCC
SHDN
1
2
3
Figure 1. MAX2620 EV Kit Schematic
_______________________________________________________________________________________
3
Evaluates: MAX2620
out. Use the test port provided on the MAX2620 EV kit
to facilitate measurement by installing a 1000pF capacitor at C2 and removing C5. (Remove C2 and install C5
to use the MAX2620 as an oscillator.) When using the
test port, subtract an approximately 586ps electrical
delay from the S11 measurement (this delay can be
compensated for on most modern vector network analyzers) to account for the delay of the transmission line
from the test port to the MAX2620 TANK pin. The test
port should provide a negative input resistance and
thus return gain when S11 is measured on a vector network analyzer. This return gain provides measurement
data that is outside the unit circle of the Smith chart.
Evaluates: MAX2620
MAX2620 Evaluation Kit
1.0"
1.0"
Figure 2. MAX2620 EV Kit Component
Placement Guide—
Top Silk Screen
1.0"
Figure 3. MAX2620 EV Kit PC Board
Layout—Component Side
1.0"
Figure 4. MAX2620 EV Kit PC Board
Layout—Solder Side
1.0"
Figure 5. MAX2620 EV Kit PC Board
Layout—Ground Plane
Figure 6. MAX2620 EV Kit PC Board
Layout—Power Plane
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
© 1998 Maxim Integrated Products
Printed USA
is a registered trademark of Maxim Integrated Products.