MAXIM MAX3503EVKIT

19-2504; Rev 0; 7/02
MAX3503/MAX3505 Evaluation Kits
Windows 95/98 is a registered trademark of Microsoft Corp.
Features
♦ Single-Supply Operation
♦ Output Level Range Up to 64dBmV (MAX3505)
♦ Gain Programmable in 0.5dB Steps
♦
♦
♦
♦
Transmit-Disable Mode
Shutdown Mode
Control Software Available for Download
Fully Assembled and Tested Surface-Mount
Board
Ordering Information
PART
TEMP RANGE
IC PACKAGE
MAX3503EVKIT
-40°C to +85°C
20 QFN
MAX3505EVKIT
-40°C to +85°C
20 QFN
Component List
DESIGNATION QTY
DESCRIPTION
DESIGNATION QTY
DESCRIPTION
B1–B5
5
0Ω resistors (0805)
L1
1
0Ω resistor (0805)
C1
1
10µF ±10%, 16V min tantalum capacitor
AVX TAJC106K016
R1
1
49.9Ω_±1% resistor (0402)
R2
1
86.6Ω ±1% resistor (0805)
6
0.1µF ±10% ceramic capacitors (0603)
Murata GRM188R71C104K
R3
1
43.2Ω ±1% resistor (0805)
C6, C7
2
1000pF ±10% ceramic capacitors
(0603)
Murata GRM188R71H102K
R4, R5, R6, R14,
R16, R17, R19,
R25, R26, R27,
R29, R30
12
Open
C8
1
Open
R7–R13, R15,
R20–R24
13
100Ω ±5% resistors (0603)
11
100pF ±10% ceramic capacitors (0603)
Murata GRM1885C1H101K
R18, R28
2
100kΩ ±5% resistors (0603)
1
SMA connector, PC mount
EFJohnson 142-0701-201 or
Digi-Key J500-ND
T1
1
Transformer, 1 to 1
M/A Com ETC1-1T
T2
1
1
DB25 connector, right angle, female
Digi-Key A2102-ND AMP 745783-4
Transformer, 1 to 1
Toko 458PT-1457
U1
1
MAX3503EGP QFN20
MAX3505EGP QFN20
1
SMA connector, edge mount
EFJohnson 142-0701-801 or
Digi-Key J502-ND
Note: Cut center pin to approximately
1/16in length.
U2
1
Octal buffer
Texas Instruments SN74LVTH244ADBR
VCC, GND, TP1,
IN1, IN2
5
Test points
Digi-Key 5000K-ND
None
1
MAX3503/MAX3505 EV kit circuit board,
rev 3
None
1
MAX3503 data sheet
MAX3505 data sheet
None
1
MAX3503/MAX3505 EV kits data sheet
C2–C5, C9, C15
C10–C14,
C16–C21
J1
J2
J3
JU1–JU8
JU1–JU8
8
8
3-pin headers, 0.1in centers
Digi-Key S1012-36-ND
Shunts
Digi-Key S9000-ND
________________________________________________________________ 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
Evaluate: MAX3503/MAX3505
General Description
The MAX3503/MAX3505 evaluation kits (EV kits) simplify
evaluation of the MAX3503 and MAX3505 CATV upstream
amplifiers. The kits include a data interface that can be
programmed through the parallel port of a standard PC.
Software (Windows 95/98® compatible) is available at
www.maxim-ic.com/TechSupport/other.htm to facilitate
this function. This software allows programming of all
available features through a simple user interface.
Access to the device input and output is provided
through 50Ω SMA connectors. The input is terminated
with 50Ω. The output circuit includes a 75Ω to 50Ω
minimum-loss pad for use with 50Ω equipment.
Evaluate: MAX3503/MAX3505
MAX3503/MAX3505 Evaluation Kits
Component Suppliers
PHONE
FAX
AVX
SUPPLIER
843-448-9411
843-448-1943
www.avxcorp.com
WEBSITE
M/A-COM
978-442-5000
978-442-4178
www.macom.com
Murata
814-237-1431
814-238-0490
www.murata.com
Toko
800-745-8656
—
www.tokoam.com
Table 1. Jumper Setting Functions
JUMPER
FUNCTION
SHORT PIN1 to PIN2
SHORT PIN2 to PIN3
JU1
PC port buffer
Disabled
Enabled
JU2
SDA input
PC port control
N/A
JU3
SCLK input
PC port control
N/A
JU4
CS input
PC port control
N/A
JU5
Sets the method of control for TXEN
PC port control
Manual control through JU6
JU6
Sets the manual control state of TXEN
Logic 1 state (VCC)
Logic 0 state (GND)
JU7
Sets the method of control for SHDN
PC port control
Manual control through JU8
JU8
Sets the manual control state of SHDN
Logic 1 state (VCC)
Logic 0 state (GND)
Quick Start
The MAX3503/MAX3505 EV kits are fully assembled
and factory tested. Follow the instructions in the
Connections and Setup section. Note that the output
circuit includes a minimum-loss pad used to bring the
load impedance up to 75Ω. This must be accounted for
in all measurements (see the Output Circuit section).
Also note that an input transformer is supplied to allow
differential input drive from a single-ended source. This
transformer is not required in the application.
Test Equipment Required
• DC supply capable of delivering 5.25V and 400mA
of continuous current
• HP 8648 (or equivalent) signal source capable of
generating 40dBmV up to 200MHz
• HP 8561E (or equivalent) spectrum analyzer with a
minimum 200MHz frequency range
• Two digital multimeters (DMMs) to monitor VCC and
ICC, if desired
• Lowpass filters to attenuate harmonic output of signal
sources, if harmonic measurements are desired
• IBM PC or compatible with Windows 95/98 installed
• Male-to-male 25-pin parallel cable, wired straight
through
• Low-noise amplifier with 40dB gain from 5MHz to
100MHz for noise measurement
• Oscilloscope with 200MHz bandwidth
• Network analyzer, such as the HP 8753D, which can
be used to measure gain vs. frequency.
Connections and Setup
1) Connect the power supply (preset to 3.3V for
MAX3503 and 5V for MAX3505) to the pins labeled
VCC and GND on the circuit board. Connect the
50Ω signal source to INPUT (preset the signal
source for -13dBm (34dBmV across a 50Ω load)),
and terminate OUTPUT with a spectrum analyzer
50Ω input impedance. If using a signal source with
a source impedance other than 50Ω, or if a different
input impedance is required, replace resistor (R1)
with a resistor of the appropriate value.
2) Connect the 25-pin male-to-male cable between the
parallel port of the PC and the 25-pin female connector on the EV kit board.
3) See Table 1 for board jumper settings. Set all
jumpers to enable PC port control, unless otherwise
stated.
4) Turn on the power supply. Turn on the PC and the
test equipment.
5) Run the software program.
• 0V to 3.3V pulse generator for transient measurement
2
_______________________________________________________________________________________
MAX3503/MAX3505 Evaluation Kits
Using the Software
The MAX3503/MAX3505 use a serial data interface (SDI)
to set gain. Some method of communicating with the SDI
is required to use the MAX3503/MAX3505 EV kits. A
microprocessor, pattern generator, or PC can be used.
Software and supporting documentation for programming the part through the parallel port of a PC is available at www.maxim-ic.com/TechSupport/other.htm.
Gain Adjustment
The valid gain codes are 0 to 127 (decimal). The nominal change in gain is 0.5dB per gain code. Gain codes
are set exclusively by programming the SDI. Highpower (HP) mode and low-noise (LN) mode can be
controlled only through the PC interface. Refer to the
MAX3503 or MAX3505 data sheet for details.
Shutdown and Transmit Enable
Jumpers JU5 through JU8 determine how shutdown
and transmit-enable features are controlled. Pin 2 of
JU5 and JU7 are connected directly to the device. If an
external source, such as a modulator chip or microprocessor, is used to control these features, make the
connection to pin 2 of JU5 and JU7. If manual control
of shutdown and transmit enable is desired, shunt pins
2 and 3 of jumper JU5 and pins 2 and 3 of jumper JU7.
This allows TXEN and SHDN to be controlled by JU6
and JU8, respectively. JU6 and JU8 are used to place
either VCC or ground at SHDN or TXEN. Pin 3 of JU6
and JU8 is ground, and pin 1 is VCC. To control the
TXEN and SHDN features using the software, shunt pin
1 and pin 2 of JU5 and JU7.
Manual Control of Serial Data Interface
If using a source other than a PC to control the serial
data interface (SDI) of the MAX3503/MAX3505 EV kits,
such as a digital pattern generator or microprocessor,
remove the shunts on jumpers JU2, JU3, and JU4.
Access to the SDI is available through these jumpers.
Termination pads are provided (R4, R5, R6). Solder an
appropriate resistor to these pads, if desired. Refer to
the MAX3503 or MAX3505 data sheet for a description
of the SDI. To control the SDI using the software, shunt
pin 1 and pin 2 of JU2, JU3, and JU4.
Input Circuit
input resistor. This allows the input to be driven with
single-ended 50Ω test equipment. The balun generates
a differential signal, because rated performance is
specified with a differential input drive, typically from a
differential lowpass filter. If the MAX3503 or MAX3505
is to be driven single ended, the input balun must be
removed and the undriven input connected to ground
through a 0.1µF blocking capacitor.
Output Circuit
The MAX3503 and MAX3505 have differential outputs.
This architecture helps suppress second-order distortion (harmonics). To convert to a single-ended output, a
1:1 transformer (T2) is used. Because most test equipment is supplied with a 50Ω input impedance, a minimum-loss pad is provided on the output of the
transformer to increase the load impedance to a nominal 75Ω. This places the proper load on the device but
reduces the measured output voltage level by 7.5dB.
Note: When making measurements with the EV kits,
add 7.5dB to all measurements of voltage gain and output voltage level, including noise, to arrive at the correct value for a 75Ω system.
For use with 75Ω test equipment:
1) Remove the 50Ω output SMA connector and replace
it with a 75Ω connector.
2) Remove R3 and replace it with a 0Ω resistor or lowinductance short.
3) Remove R2.
4) Use a 75Ω cable.
Analysis
Harmonic Distortion
A filter is needed to reject the harmonics generated by
the signal source. For this example, a lowpass filter with
an approximate 25MHz to 35MHz cutoff frequency is
required. This filter must reject at least 20dB of signal at
40MHz.
1) Set the 50Ω signal source for 20MHz and -13dBm.
2) Adjust the amplitude to account for the insertion
loss in the filter.
3) With a spectrum analyzer, verify that the second
and third harmonics generated by the source are
suppressed by at least 70dBc.
The input circuits of the MAX3503/MAX3505 EV kits are
configured with a 1:1 balun, terminated with a 49.9Ω
_______________________________________________________________________________________
3
Evaluate: MAX3503/MAX3505
Detailed Description
Evaluate: MAX3503/MAX3505
MAX3503/MAX3505 Evaluation Kits
4) Connect the filter between INPUT of the EV kit and
the output of the signal source, ensuring that the
proper terminations are being used for this filter.
5) Connect a spectrum analyzer to OUTPUT.
6) Set the center frequency for 40MHz and the span
for 50MHz or greater.
7) Adjust the reference level so that the fundamental
(20MHz tone) is within 10dB to 20dB of the reference level. If the fundamental is less than 10dB
below the reference level, the harmonic distortion of
the spectrum analyzer might prevent accurate measurement of the distortion.
8) Set the gain to 27dB. (Refer to the MAX3503 or
MAX3505 data sheet for details.)
9) Measure the level of the fundamental, second, and
third harmonics on the spectrum analyzer. These
readings are measured in dBm. To convert from
dBm to dBmV in a 50Ω system, use the following
equation:
X(dBmV) = Y(dBm) + 47dB (50Ω system)
5) Using a convenient method, trigger the oscilloscope from the pulse generator
6) A rising- and falling-edge transient should appear
on the scope’s CRT. Multiply the value of the measured transient by 2.37 to account for the presence
of the minimum-loss pad. The gain can now be
changed to show the output transient’s dependence on gain.
Output Noise
Use a spectrum analyzer to measure output noise. A
postamplifier with less than 10dB noise figure and
greater than 40dB gain within the band of interest is
needed.
1) Turn on the power supply.
2) Terminate the input with 50Ω.
3) Using the software, set the device to transmit mode
with approximately 27dB of gain.
4) Connect the output of the postamplifier to the spectrum analyzer and the input to OUTPUT on the EV
kits. Set the spectrum analyzer as follows:
• Center frequency: 35MHz
• Span: 60MHz
10) Add 7.5dB to this value to account for the attenuation
of the minimum-loss pad, in dBmV, for a 75Ω load.
The gain now can be calculated in dB, and the harmonic distortion can be calculated in dBc.
Switching Transients
To measure the transmit-enable and transmit-disable
transients, the TXEN pin is driven from an external
source. No input signal is applied, and the output is
viewed on an oscilloscope.
1) Connect OUTPUT to the oscilloscope’s 50Ω input.
Set the scope’s time base to 5µs/div and the vertical scale to 5mV/div.
2) Set the pulse generator as follows:
• Amplitude: 3.3V
• Duty cycle: 50%
• Rise/fall time: 100ns
• Reference: -50dBm
• Scale: 10dB/div
• IF bandwidth: 1kHz
5) Power up the postamplifier. If the spectrum analyzer
being used has a noise-marker function, enable it.
Otherwise, subtract 10log (RBW) from the measured power. Move this marker to 42MHz. Read the
value of the noise density from the spectrum analyzer. This noise value is a combination of the output noise of the MAX3503 or MAX3505, the gain of
the postamplifier, and the noise figure of the postamplifier. With the specified noise figure of 10dB,
the noise contribution of the postamplifier can be
ignored. The minimum-loss pad reduces the actual
measured value by 7.5dB. Use the following equation to arrive at the output noise in a 160kHz
bandwidth:
• Pulse width: 25µs
• Offset: 1.65V
Do not drive the TXEN pin below 0V or above 3.6V.
VNOISE = PNOISE + 47dB + 7.5dB
+ 10 ✕ log (160,000) - GAMP
3) Turn on the power supply.
4) Remove the shunt from jumper JU5 (TXEN), and
connect the output of the pulse generator to pin 2 of
this jumper.
4
_______________________________________________________________________________________
MAX3503/MAX3505 Evaluation Kits
Layout Considerations
The MAX3503/MAX3505 EV kits’ PC board can be a
guide for board layout. Pay close attention to thermal
design and to the output network. The MAX3503/
MAX3505 package exposed paddle (EP) conducts
heat out of 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. Ideally, this is provided 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.
The output circuit that connects OUT+ and OUT- (pins
14 and 12) to the output transformer (T2) should be as
symmetrical as possible to reduce second-order distortion. In addition, keep the capacitance of this path low
to minimize gain rolloff at high frequencies.
Functional Diagram
TXEN
SHDN
VCC
BIAS
CONTROL
MAX3503
MAX3505
HIGH
POWER
OUTCEXT
IN+
OUT+
INLOW
NOISE
D/A CONVERTER
SERIAL DATA INTERFACE
CS SDA SCLK
GND
_______________________________________________________________________________________
5
Evaluate: MAX3503/MAX3505
where:
VNOISE = MAX3503/MAX3505 output noise in dBmV
measured in a 160kHz bandwidth
PNOISE = Noise density in dBm/Hz read from the spectrum analyzer
GAMP = Gain of the postamplifier in dB
6
C21
100pF
C20
100pF
C19
100pF
C18
100pF
C17
100pF
IN2
IN1
J2-6
J2-4
J2-3
J2-2
C1
10µF
R25
OPEN
R24
100Ω
R23
100Ω
R22
100Ω
R21
100Ω
R20
100Ω
10
9
8
7
6
5
4
3
2
1
GND
2Y1
1A4
2Y2
1A3
2Y3
1A2
2Y4
1A1
1OE
C2
0.1µF
U2
SN74LVT244A
SMA
INPUT
J1
2A1
1Y4
2A2
1Y3
2A3
1Y2
2A4
1Y1
2OE
VCC
R1
49.9Ω
B2
0Ω
B4
0Ω
B3
0Ω
B1
0Ω
11
12
13
14
15
16
17
18
19
20
TP1
R15
100Ω
R13
100Ω
R12
100Ω
R11
100Ω
R10
100Ω
R9
100Ω
R8
100Ω
R7
100Ω
4
VCC4
C14
100pF
J2-5
J2-8
C15
0.1µF
3
2
T1
M/A-COM ETC1-1T
1
5
VCC4
VCC3
VCC2
VCC1
VCC
J2-15
J2-10
J2-7
C13
100pF
C12
100pF
C11
100pF
C10
100pF
C16
100pF
R14
OPEN
VCC4
C7
1000pF
C6
1000pF
SCLK
SDA
Figure 1. MAX3503/MAX3505 EV Kits Schematic
_______________________________________________________________________________________
VCC4
JU7
VCC4
JU5
JU3
JU2
JU4
CS
JU8
JU6
SHDN
OUT-
N.C.
OUT+
VCC
16
CEXT
R5
OPEN
R6
OPEN
SHDN
10
TXEN
9
17
N.C.
SDA
6
CS
8
MAX3503
MAX3505
U1
18
N.C.
N.C.
SCLK
7
19
N.C.
GND
IN-
GND
IN+
VCC
20
N.C.
VCC
R4
OPEN
5
4
3
2
1
TXEN
J2-13
VCC1
VCC
C3
0.1µF
JU1
R28
100kΩ
R18
100kΩ
11
12
13
14
15
C5
0.1µF
J2-17
J2-16
J2-14
J2-12
J2-11
J2-9
J2-1
C4
0.1µF VCC2
VCC3
C9
0.1µF
1
R26
OPEN
R27
OPEN
R29
OPEN
R16
OPEN
R17
OPEN
R19
OPEN
R30
OPEN
B5
0Ω
2
3
2
1
J2-25
J2-24
J2-23
J2-22
J2-21
J2-20
J2-19
J2-18
T2
458PT-1457
4
5
C8
OPEN
L1
IND0805
OΩ
R2
86.6Ω
R3
43.2Ω
SMA
OUTPUT
J3
Evaluate: MAX3503/MAX3505
MAX3503/MAX3505 Evaluation Kits
MAX3503/MAX3505 Evaluation Kits
Evaluate: MAX3503/MAX3505
1.0"
Figure 2. MAX3503/MAX3505 EV Kits Component Placement Guide—Component Side
_______________________________________________________________________________________
7
Evaluate: MAX3503/MAX3505
MAX3503/MAX3505 Evaluation Kits
1.0"
1.0"
Figure 3. MAX3503/MAX3505 EV Kits PC Board Layout—
Solder Side
Figure 4. MAX3503/MAX3505 EV Kits PC Board Layout—
Component Side
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.