MAXIM MAX3654EVKIT

19-0409; Rev 1; 3/07
MAX3654 Evaluation Kit
The MAX3654 evaluation kit (EV kit) is a factoryassembled printed circuit board (PCB) that provides two
circuit versions—optical input and electrical input.
The optical circuit includes the photodiode bias circuitry,
an op amp for feed-forward AGC operation, and a balun
for single-ended 75Ω output. Through-hole pads are
provided to attach a triplexer analog photodiode. It is
important to select a photodiode with capacitance and
inductance in the anode and cathode connections as
symmetric as possible for optimum linearity.
The electrical circuit is normally configured with a 50Ω
input for use with conventional test and measurement
equipment and a 75Ω output. The 75Ω output can be
connected to 50Ω test and measurement equipment using
a minimum loss pad. If desired, the MAX3654 input can
also provide a 75Ω input by replacing R12 and R13 with
25Ω resistors.
_________________________ Features
♦
Fully Assembled and Tested
♦
Optical and Electrical Inputs
♦
Automatic Gain Control
_______________Ordering Information
PART
TEMP RANGE
MAX3654EVKIT
-40°C to +85°C
IC-PACKAGE
16 QFN
__________________________________________________ Evaluation Component List
DESIGNATION
C1, C2, C4, C5,
C19–C22
C3, C7, C8, C9,
C12, C16, C17,
C23, C24, C27,
C29
C6, C10, C11,
C25, C26
QTY
DESCRIPTION
C13, C14, C28
3
R6, R18
R2
R3, R4, R5,
R16, R17
R1, R21
2
1
1μF 10V, ±10% min ceramic
capacitors
33μF 10V, ±20% min
tantalum capacitors
1.62kΩ ±1% resistors (0402)
10Ω ±1% resistor (0402)
6
100kΩ ±1% resistors (0402)
2
R7, R19
8
0.001μF ±10% ceramic
capacitors (0402)
11
0.1μF ±5% ceramic
capacitors (0603)
DESIGNATION
QTY
DESCRIPTION
J2, J4
2
J3
1
TP1–TP13
JU1–JU3, JU5,
JU6
13
BNC 75Ω, Edge Mount
Trompeter UCBJE20-1
SMA connector, tab contact,
Johnson, 142-0701-851
Test Points
5
2-pin headers, 0.1in centers
L1, L5
2
L2, L6
2
U1, U3
2
MAX3654ETE+
U2, U4
2
MAX4240EUK
1kΩ ±1% resistors (0402)
U5
0
2
2.43kΩ ±1% resistors (0402)
U6
1
R9, R15
2
20kΩ ±1% resistors (0402)
R12, R13
R8, R20
R22
2
2
1
12.1Ω ±1% resistors (0402)
6.04kΩ ±1% resistors (0402)
open (0402)
U7, U8
2
Photodiode not supplied
Balun Pulse Engineering
CX2039
Balun Pulse Engineering
CX2038
5
Bead, Murata
BLM15HD182SN1 (0402)
10μH inductor, TDK
MLF1608E100K (0603)
__________________________________________Maxim Integrated Products
1
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.
Evaluates: MAX3654
________________General Description
Evaluates: MAX3654
MAX3654 Evaluation Kit
_____________Component Suppliers
SUPPLIER
PHONE
WEBSITE
AVX
803-448-9411
www.avxcorp.com
Pulse
Engineering
858-674-8100
www.pulseeng.com
Murata
770-436-1300
www.murata.com
Note: Please indicate that you are using the MAX3654 when
contacting these component suppliers.
________________________Quick Start
Optical Evaluation
1)
Attach triplexer photodiode to IN+ and IN- of the
MAX3654. The cathode normally connects to IN+.
The photodiode case should be grounded to the
most convenient ground via. Make certain that the
anode and cathode leads are symmetric in length
and orientation, lead lengths should normally be
about 5mm.
2)
Set JU2 to R4 to manually adjust the gain with an
input from 0 to 1.4V on TP3.
3)
Leave JU3 open for minimum hysteresis.
4)
Set JU1 to R8 to enable the output signal.
5)
Connect the signal output at J2 to a 75Ω
spectrum-analyser input. A minimum loss pad may
also be used to connect J2 to 50Ω test equipment.
6)
Connect a +5V supply to the VCC terminal, TP1
and ground to the GND terminal, TP2.
7)
Connect the photodiode bias supply to TP13.
Typically use +12V bias supply, or as required by
the photodiode.
Electrical Evaluation
1)
Connect a 50Ω signal source to IN at J3. Set the
input signal level to PIN = -18dBm, so that the
voltage on 50Ω produces the maximum input
level of 1.6mAP-P.
2)
Connect the RF output at J4 to a 75Ω spectrum
analyser input. A minimum loss pad may also be
used to connect J4 to 50Ω test equipment.
3)
Leave JU6 open for minimum hysteresis.
4)
Set JU5 to R20 to enable output.
5)
Connect a +5V supply to the VCC terminal, TP7
and ground to the GND terminal, TP8.
6)
Apply 1.4V to TP12 to set the MAX3654 gain to
minimum, 43.5dBΩ. A voltage from 0.175V to
1.4V at TP12 adjusts the gain from 62dBΩ to
43.5dBΩ
Input and Output Signal Levels
When used in the electrical input configuration shown
in Figure 2, the MAX3654 is intended to operate with
AC input signal current from 175μAP-P to 1.6mAP-P. The
corresponding electrical input is -37dBm (0 < VAGC <
0.175V) to -18dBm (VAGC = 1.4V), on 50Ω. The
MAX3654 EV Kit can also be configured to provide
75Ω input impedance by replacing R12 and R13 with
25Ω resistors.
When used in the optical input configuration shown in
Figure 2, JU2 may be connected to R3 to configure the
MAX3654 for AGC operation based on the average
optical power level. In this case, the MAX3654
transimpedance is controlled by the average optical
power level, as measured by the voltage across R21.
The values of R1, R21 and R22 shown in Figure 1 will
provide an output level of 15dBmV/ch (+1dB) for
optical input signals ranging from -6dBm to +2dBm,
(OMI = 3.5%, N = 129) using a typical triplexer
photodiode. The total output signal level in this case is
15dBmV/ch + 10 log(129 channels) = 36dBmV, which
is the maximum operating level at which the specified
linearity will be achieved. Operating at higher outputs
may reduce MAX3654 performance.
Operating conditions (OMI, number of channels,
responsivity, etc) change the VAGC setting required for
a given output voltage. EV Kit AGC circuit gain can be
increased by adding a voltage-divider, R22, to the
op amp. To reduce gain the values of R1 and R21
should both be increased. Remember to keep the total
output at 36dBmV or less to maintain the desired
MAX3654 performance.
Photodiode Lead Configuration
Photodiode lead parasitic impedances can significantly
effect performance of the MAX3654. It is especially
important that the anode and cathode connections are
electrically symmetric. Refer to Figure 1 in the
MAX3654 data sheet. Note that the EV Kit layout is
designed to minimize capacitance to ground in the
input signal path.
2 _________________________________________________________________________________________
MAX3654 Evaluation Kit
COMPONENT
NAME
FUNCTION
JU1
MUTE
NA
JU2
VAGC
MUTE. TTL high enables output. Low mutes output.
Gain Control. Set JU2 to R4 for manual gain control. Set JU2
to R3 to allow feedforward AGC operation. The electrical
circuit board is always set for manual gain control.
JU6
JU3
Hysteresis
ELECTRICAL
OPTICAL
JU5
R2
L2
2
C1
0.001μF
R21
1kΩ
L6
10μH
L5
BEAD
TP13
VPD
TP1
VCC
TP5
R4 100kΩ
1μF
R22
Open
VPD
OUT+
MAX3654
IN-
OUT-
U1
EP*
VCC
0.1μF
VCC
5
6
7
8
VCC
12
0.001μF
C4
11
10
VCC
C5
0.001μF
9
EP
J2
U8
CX2038
C9
0.1μF
R9
JU3
20kΩ
HYST
TP3
TP4
R5 100kΩ
JU1
VCC
MUTE
C11
R6
R7
1μF
1.62kΩ
2.43kΩ
TP2
GND
TEST1
GND
IN+
C29
C8
0.1μF
VCC
MAX4240
- U2
C13
33μF
13
VCC
C12
0.1μF
+
VCC
C14
33μF
C6
VCC
JU2
VAGC
C10
1μF
VCC
4
R3
100kΩ
BLM15HD182SN1
TP6
GAIN
3
C2
0.001μF
U5
14
GND
1
15
HYST
R1
1kΩ
16
C7
0.1μF
VCC
TEST2
L1
BEAD
BLM15HD182SN1
MUTE
C3
0.1μF
GND
10μH
10Ω
VAGC
VPD
Hysteresis. Leave open for (minimum) ±0.13dB hysteresis
between gain switch points. Connect 20kΩ to ground for
±0.3dB and short to GND for (maximum) ±0.65dB hysteresis.
R8
6.04kΩ
*EP - Exposed Pad, Solder to GND
Figure 1. MAX3654 Optical EV Kit Schematic
_______________________________________________________
3
Evaluates: MAX3654
_____________________________________Adjustments and Control Descriptions
C19
12Ω
0.001μF
3
4
TP12
GAIN
TP8
TP11
GND
TEST1
GND
TEST2
EP*
5
6
7
8
R16 100kΩ
VCC
C22
0.001μF
9
VCC
EP
J4
U7
CX2038
C24
0.1μF
R15
+
C25
1μF
MAX4240
- U4
VCC
TP7
VCC
0.1μF
10
OUT-
U3
VCC
C17
C27
VCC 0.1μF
MAX3654
IN-
VCC
0.001μF
C21
11
OUT+
IN+
VCC
12
VCC
VCC
2
C23
0.1μF
13
GND
R13
14
HYST
CX2039
0.001μF
15
MUTE
U6
12Ω
16
1
C20
R12
J3
C16
0.1μF
GND
VCC
VAGC
Evaluates: MAX3654
MAX3654 Evaluation Kit
JU6
HYST
TP9
R17 100kΩ
C28
33μF
C26
1μF
TP10
20kΩ
JU5
VCC
R18
MUTE
R19
R20
1.62kΩ
2.43kΩ
6.04kΩ
*EP - Exposed Pad, Solder to GND
Figure 2. MAX3654 Electrical EV Kit Schematic
4 ________________________________________________________________________________________
MAX3654 Evaluation Kit
Evaluates: MAX3654
Figure 3. MAX3654 EV Kit
PC Component Placement Guide—
Component Side
Figure 5. MAX3654 EV Kit
PC Board Layout—Ground
Plane
Figure 4. MAX3654 EV Kit
PC Board Layout—Component Side
Figure 6. MAX3654 EV Kit
PC Board Layout—Power
Plane
Figure 7. MAX3654 EV Kit
PC Board Layout—Solder
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.
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is a registered trademark of Maxim Integrated Products