MAXIM MAX2701EVKIT

19-1882; Rev 0; 12/00
MAX2700/MAX2701 Evaluation Kits
Features
♦ Easy Evaluation of MAX2700/MAX2701
♦ +2.7V to +3.3V Single-Supply Operation
♦ RF Ports Matched to 1960MHz (MAX2700)
♦ RF Ports Matched to 2400MHz (MAX2701)
♦ SMA Connectors for All RF Signal Ports
♦ BNC Connectors for All Baseband Signal Ports
♦ Low-Power Shutdown Mode
Ordering Information
TEMP.RANGE
IC PACKAGE
MAX2700EVKIT
PART
-40°C to +85°C
48 TQFP-EP
MAX2701EVKIT
-40°C to +85°C
48 TQFP-EP
MAX2700 Component List
DESIGNATION
QTY
C1, C17, C18, C19,
C21, C22, C23,
C30, C31, C32,
C36, C37, C38
13
C2, C10, C11, C25,
C43, C46
6
DESCRIPTION
0.1µF 10% ceramic capacitors
(0603)
Murata GRM39X7R104K016A
68pF 5% ceramic capacitors
(0402)
Murata GRM36COG680J050A
DESIGNATION
QTY
DESCRIPTION
C13, C41, C42,
C47, C48
5
Not installed
C15, C20, C35,
C39
4
0.056µF 10% ceramic
capacitors (0603)
Murata GRM39X7R563K016A
C24, C29
2
0.56µF 10% ceramic capacitors
(0805)
Murata GRM40X7R564K016A
C28
1
Not installed
4
1000pF 10% ceramic
capacitors (0402)
Murata GRM36X7R102K050A
C44
1
C4, C50
2
2.0pF ±0.1pF ceramic
capacitors
Murata GRM36COG020B050A
10µF tantalum capacitor ±10%
16V min
AVX TAJC106K016
C5
1
0Ω resistor (0603)
C49
1
C8, C14, C33
3
100pF 5% ceramic capacitors
(0402)
Murata GRM36COG101J050A
5pF ±0.1pF ceramic capacitor
(0402)
Murata GRM36COG050B050A
R1, R12, R15, R26,
R32, R40, R45
7
0Ω resistors (0805)
R2, R5, R6, R11
4
100Ω ±5% resistors (0402)
R3, R4, R7, R8, R9,
R10
6
0Ω resistors (0402)
R13, R14, R19,
R20, R33, R34,
R38, R39,
8
1kΩ ±5% resistors (0402)
C3, C6, C7, C45
C9, C16, C34
C12, C26, C27,
C40
3
0.01µF 10% ceramic capacitors
(0402)
Murata GRM36X7R103K016A
4
22pF 5% ceramic capacitors
(0402)
Murata GRM36COG220J050A
________________________________________________________________ Maxim Integrated Products
1
For price, delivery, and to place orders, please contact Maxim Distribution at 1-888-629-4642,
or visit Maxim’s website at www.maxim-ic.com.
Evaluate: MAX2700/MAX2701
General Description
The MAX2700/MAX2701 evaluation kits (EV kits) simplify evaluation of the MAX2700/MAX2701 direct downconverter receivers. These kits allow evaluation of the
devices’ low-noise amplifier (LNA), I/Q demodulator,
and variable gain amplifiers (VGAs). Figure 1 shows the
MAX2700/MAX2701 EV kits schematic. The EV kits provide 50Ω SMA connectors for all RF input and output
signals, and BNC connectors for all baseband input
and output signals.
MAX2700/MAX2701 Evaluation Kits
Evaluate: MAX2700/MAX2701
MAX2700 Component List (continued)
DESIGNATION
QTY
L5, L6
2
3.9nH inductors
Toko LL1608-FH3N9J
L7
1
0Ω resistor (0603)
U1
1
MAX2700ECM 48-pin TQFP-EP
NOTE: U1 has an exposed
paddle which needs to be
solder-attached to the circuit
board to ensure proper
functionality of the part.
Balun transformer
Murata LDB15C500A1900
J3, J6, J12, J18
4
SMA PC-mount connectors
Johnson 142-0701-201 or
Digi-Key J500-ND
1
4.7nH inductor
Toko LL1608-FH4N7J
J7–J11, J13–J17
10
BNC connectors
A/D Electronics 580-002-00
6pF ±0.1pF ceramic capacitor
(0402)
Murata GRM36COG060B050A
VCC, GND
2
Test points, Digi-Key 5000K-ND
1
J1, TP1
2
1×2 headers (0.1in centers)
Digi-Key S1012-36-ND
J2, J4, J5
3
1×3 headers (0.1in centers)
Digi-Key S1012-36-ND
J2, J4, J5
3
Shunts, Digi-Key S9000-ND
—
1
MAX2700/2701 evaluation kit
circuit board, rev. E
DESIGNATION
QTY
R16, R22, R30,
R36
4
1.1kΩ ±5% resistors (0402)
R17, R21, R31,
R37
4
3.6kΩ ±5% resistors (0402)
R18, R23, R29,
R35
4
R24, R25, R27,
R28, R41, R42,
R43, R44
8
51Ω ±5% resistors (0402)
T1
1
Z1
Z4
L2
L3
L4
DESCRIPTION
820Ω ±5% resistors (0402)
1
Not installed
1
1.5nH inductor
Toko LL1608-FH1N5S
1
5.6nH inductor
Toko LL1005-FH5N6S
DESCRIPTION
MAX2701 Component List
DESIGNATION
C1, C17, C18,C19,
C21, C22, C23,
C30, C31, C32,
C36, C37, C38
C2, C10, C11, C25,
C43, C46
C3, C6, C7, C45
C4, C50
C5
2
DESIGNATION
QTY
13
0.1µF 10% ceramic capacitors
(0603)
Murata GRM39X7R104K016A
C8, C14, C33
3
100pF 5% ceramic capacitors
(0402)
Murata GRM36COG101J050A
C9, C16, C34
3
6
68pF 5% ceramic capacitors
(0402)
Murata GRM36COG680J050A
0.01µF 10% ceramic capacitors
(0402)
Murata GRM36X7R103K016A
C12, C26, C27,
C40
4
4
1000pF 10% ceramic
capacitors (0402)
Murata GRM36X7R102K050A
22pF 5% ceramic capacitors
(0402)
Murata GRM36COG220J050A
C13
1
2
1.5pF ±0.1pF ceramic
capacitors
Murata GRM36COG1R5B050A
2pF ±0.1pF ceramic capacitor
(0402)
Murata GRM36COG020B050A
C15, C20, C35,
C39
4
1
10pF ±0.1pF ceramic capacitor
(0603)
Murata GRM39COG100B050A
0.056µF 10% ceramic
capacitors (0603)
Murata GRM39X7R563K016A
QTY
DESCRIPTION
DESCRIPTION
_______________________________________________________________________________________
MAX2700/MAX2701 Evaluation Kits
DESIGNATION
QTY
DESCRIPTION
DESIGNATION
QTY
C24, C29
2
0.56µF 10% ceramic capacitors
(0805)
Murata GRM40X7R564K016A
L4
1
5.6nH inductor
Toko LL1005-FH5N6S
L7
1
0Ω resistor (0603)
U1
1
MAX2701ECM 48-pin TQFP-EP
NOTE: U1 has an exposed
paddle which needs to be
solder-attached to the circuit
board to ensure proper
functionality of the part.
J3, J6, J12, J18
4
SMA PC-mount connectors
Johnson 142-0701-201 or
Digi-Key J500-ND
J7–J11,
J13–J17
10
BNC connectors
A/D Electronics 580-002-00
VCC, GND
2
Test points, Digi-Key 5000K-ND
J1, TP1
2
1×2 headers (0.1in centers)
Digi-Key S1012-36-ND
J2, J4, J5
3
1×3 headers (0.1in centers)
Digi-Key S1012-36-ND
J2, J4, J5
3
Shunts, Digi-Key S9000-ND
—
1
MAX2700/MAX2701 evaluation
kit circuit board, rev. E
C28, C41, C42,
C47, C48
5
Not installed
C44
1
10µF tantalum capacitor ±10%
16V min
AVX TAJC106K016
C49
1
3pF ±0.1pF ceramic capacitor
(0402)
Murata GRM36COG030B050A
R1, R12, R15,
R26, R32, R40,
R45
7
0Ω resistors (0805)
R2, R5, R6, R11
4
100Ω ±5% resistors (0402)
R3, R4, R7, R8,
R9, R10
6
0Ω resistors (0402)
R13, R14, R19,
R20, R33, R34,
R38, R39
8
1kΩ 5% resistors (0402)
R16, R22, R30,
R36
4
1.1kΩ ±5% resistors (0402)
R17, R21, R31,
R37
4
3.6kΩ ±5% resistors (0402)
R18, R23, R29,
R35
4
820Ω ±5% resistors (0402)
R24, R25, R27,
R28, R41, R42,
R43, R44
8
51Ω ±5% resistors (0402)
1
Balun transformer
Murata LDB15C500A2400
1
0.5pF ±0.1pF ceramic
capacitor (0603)
Murata GRM39COG0R5B050A
Z4
1
1nH inductor
Toko LL1005-FH1N0S
L2
1
Not installed
L3, L5, L6
3
2.7nH inductors
Toko LL1608-FH2N7S
T1
Z1
DESCRIPTION
Component Suppliers
SUPPLIER
PHONE
FAX
AVX
803-946-0690
803-626-3123
EFJohnson
402-474-4800
402-474-4858
Kamaya
219-489-1533
219-489-2261
Murata
949-852-2001
949-852-2002
Toko
708-297-0070
708-699-1194
Note: Please indicate that you are using the MAX2700 or
MAX2701 when contacting these component suppliers.
_______________________________________________________________________________________
3
Evaluate: MAX2700/MAX2701
MAX2701 Component List (continued)
Evaluate: MAX2700/MAX2701
MAX2700/MAX2701 Evaluation Kits
Table 1. Recommended Test Equipment
3) Set the X2EN jumper on the EV kit to GND (LOW).
This enables the VCO doubler.
EQUIPMENT
DESCRIPTION
RF Signal Generators
(2)
HP 8648C or equivalent, capable
of delivering -50dBm to -10dBm of
output power from 900MHz to
2500MHz
Dual-Channel
Oscilloscope
For viewing the demodulator
outputs
6) Connect port 1 and port 2 of network analyzer to
LNAIN and LNAOUT, respectively.
Power Supply
Capable of providing at least
200mA at +2.7V to +3.3V
Additional Variable
Voltage Source
For external control of VGA
function
7) Turn on the DC supply. The supply current should
read approximately 165mA for MAX2700 (167mA
for MAX2701) if using an ammeter.
Spectrum Analyzer
HP 8561E or equivalent, covering
MAX2700/MAX2701 operating
frequency range
Cables (50Ω)
(2) 50Ω cables with SMA
connectors
Cables with BNC
Connectors
(2) BNC cables to check
baseband signals
Ammeter (optional)
For measuring supply current
Noise Figure Meter
(optional)
HP 8970B or equivalent, for
measuring the noise figure of the
LNA and I/Q demodulator
Network Analyzer
HP 8753D or equivalent, for
measuring return loss and gain
simultaneously
4) Connect a DC supply preset to +3V (through an
ammeter, if desired) to the EV kit’s VCC and GND
terminals. Do not turn on the supply.
5) Perform a full two-port calibration on a network analyzer at a -30dBm power level.
8) The network analyzer display should indicate a typical gain of 16.5dB for MAX2700 at 1960MHz
(15.5dB for MAX2701at 2400Mhz) after accounting
for board losses.
9) The input and output board losses for MAX2700 are
0.25dB and 0.3dB, respectively. The input and output board losses for MAX2701 are 0.3dB and
0.35dB, respectively.
10) Set the GAIN_SET jumper on the EV kit to GND
(LOW). This enables the LNA’s low-gain-mode
operation. Measurements on the network analyzer
should indicate a typical gain of -1.75dB for
MAX2700 (-2.5dB for MAX2701) after accounting
for board losses.
11) Connect the SHDN jumper to GND (LOW) to activate the shutdown mode. The supply current should
drop to less than 100µA.
I/Q Demodulator
Quick Start
1) Turn off the DC supply.
The MAX2700/MAX2701 EV kits are fully assembled
and factory tested. Follow the instructions in the
Connections and Setup section for proper device evaluation.
2) Remove the network analyzer from the LNAIN and
LNAOUT connections. The DC supply connections
needed for testing the downconverter mixer are the
same as in the LNA section.
Connections and Setup
3) Set jumper J2 (X2_EN) to GND (LOW) to enable the
LO doubler circuit.
This section provides a step-by-step guide to setting
up the MAX2700/MAX2701 EV kits and testing all three
major functional blocks: LNA, I/Q demodulator, and
VGAs. Do not turn on the DC power or RF signal
generators until all connections are made.
Low-Noise Amplifier
1) Set the SHDN jumper on the EV kit to VCC (HI). This
enables the device to operate in the normal mode.
2) Set the GAIN_SET jumper on the EV kit to VCC (HI).
This enables the LNA to operate in high-gain mode.
4
4) Connect an RF signal generator (with output disabled) to the LO SMA connector. Set the frequency
to 980MHz for MAX2700 (1200MHz for MAX2701)
and the output power to -10dBm. This is the LO signal.
5) Connect another RF signal generator to the RFIN
SMA connector (with output disabled). Set the frequency to 1961MHz for MAX2700 (2401MHz for
MAX2701) and the output power to -25dBm. This is
the RF input signal.
_______________________________________________________________________________________
MAX2700/MAX2701 Evaluation Kits
7) Turn on the DC supply. Enable the LO signal generator and RF input signal generator outputs.
8) Measure the peak-to-peak amplitude of the 1MHz
IF signal on the oscilloscope with a high-impedance
probe (VOUTp-p). Voltage gain can be calculated
by the following formula:
Voltage Gain = 20 log[((V OUTp-p ) / (2
VIN (RMS)]
✕
√2)) /
VIN (RMS) = SQRT(50 ✕ 10-3 ✕ 10Pin(dBm)/10)
Voltage Gain should be nominally 19.3dB for
MAX2700 (18.1dB for MAX2701).
Note: Compensate PIN for input balun loss (1.25dB)
and input board loss (0.3dB) and VOUT p-p for the voltage divider network at the mixer output.
To check the Q-channel performance of the I/Q demodulator, connect the oscilloscope to MIXQ and repeat the
measurements from step 7 of the I/Q Demodulator section.
7) Connect a jumper across J1.
8) Perform a similar measurement between IIN2+
(J14) and IOUT2 (J13); voltage gain should be
30dB nominal between IIN2+ and IOUT2.
Note: Compensate PIN for the input network loss
and VOUTp-p for the voltage divider network at the
amplifier output.
9) The corresponding VGAs in the Q channel
(between QIN1+ and QOUT1 and between QIN2+
and QOUT2) can be tested in the same way.
Checking Noise Figure
Noise-figure measurements are sensitive to board and
lab setup losses and parasitics. There are many techniques and precautions for measuring a low-noise figure. Detailed explanation of these items goes beyond
the scope of this document. For more information on
how to perform this level of noise-figure measurement,
refer to the noise-figure meter operating manual, as
well as to Hewlett Packard application note #57-2,
Noise Figure Measurement Accuracy.
PC Board Layout Considerations
Variable Gain Amplifiers
1) Remove the RF signal generators and oscilloscope
from RFIN, LO, and MIXI connections. The DC supply connections needed for testing the VGAs are
the same as in the LNA section. Turn off the DC
supply while making connections.
The MAX2700/MAX2701 EV kits can serve as board
layout guides. Keep PC board trace lengths as short as
possible to minimize parasitics. Keep decoupling
capacitors close to the device, with a low inductance
via connection to the ground plane.
2) Connect a variable voltage source, preset to
+1.25V, to the VGC input of the EV kit. Do not turn
on the supply.
The MAX2700/MAX2701 EV kits have been optimized
for operation at 1960MHz and 2400MHz, respectively.
The MAX2700/MAX2701 EV kits can be configured to
operate in the 1800MHz to 2100MHz band and the
2100MHz to 2500MHz band, respectively. Use the
device parameters listed in the MAX2700/MAX2701
data sheet to determine the proper input and output
matching components at other frequencies.
3) Connect an RF signal generator to the BNC connector of input IIN1+ (using appropriate connector
adapters). Do not turn on the generator’s output.
Set the generator for a output frequency of 1MHz at a
-40dBm power level.
Modifying the EV Kit
4) Connect the oscilloscope to the IOUT1 (for I channel signal) BNC connector. Set the oscilloscope to
high-impedance-input mode.
5) Turn on the DC supply and the voltage source connected to the VGC input.
6) Measure the peak-to-peak output voltage of the
1MHz signal on the oscilloscope (VOUTp-p), and
compute the voltage gain using the equation in the
I/Q demodulator section. The voltage gain should
be nominally 20dB between IIN1+ (J16) and IOU1
(J15).
_______________________________________________________________________________________
5
Evaluate: MAX2700/MAX2701
6) Connect the oscilloscope to the MIX_I (for I channel
signal) BNC connector. Set the oscilloscope to
high-impedance input mode.
Figure 1a. MAX2700 EV Kit Schematic
_______________________________________________________________________________________
VCC
X2ENB
VCC
R8
0Ω
R7
0Ω
R10
0Ω
R9
0Ω
J4
VCC
J5
R4
0Ω
R3
0Ω
J2
VCC
TP1
J3
J1
VCC
R12
0Ω
R11
100Ω
R6
100Ω
R5
100Ω
Z1
4.7nH
C5
0
J20
VCC
R2
100Ω
R1
0Ω
C44
10µF
R45
0Ω
C11
68pF
C10
68pF
6
C8
100pF
12
11
10
9
8
GND 7
C7
1000pF
C6
1000pF
C9
0.01µF
Z4
5pF
4
3
2
1
C3
1000pF
GND 5
C2
68pF
C1
0.1µF
C43
68pF
48
47
14
GND
J6
C13
OPEN
L3
1.5nH
13
VCCLNA
AGC
SHDNB
GAINSET
GND
GNDRF
LNAIN
GNDRF
X2ENB
VCCRF
CEXT
L7
0
C41
OPEN
C48
OPEN
CEXTB
R40
0Ω
15
GND
R39
1kΩ
45
16
J7
R13
1kΩ
C15
0.056µF
C12
22pF
L2
OPEN
46
C40
22pF
C42
OPEN
GNDLO
GNDRF
C47
OPEN
44
C39
0.056µF
R38
1kΩ
R14
1kΩ
VCC
18
C17
0.1µF
R15
0Ω
U1
C38
0.1µF
42
R37
3.6kΩ
R36
1.1kΩ
R44
51Ω
J8
R16
1.1kΩ
19
C18
0.1µF
MAX2700
43
C14 C16
100pF 0.01µF
17
MIXI
MIXQ
VCC
GNDLO
VCC1
J16
41
C37
0.1µF
40
C36
0.1µF
R35
820Ω
C35
0.056µF
R33
1kΩ
39
J15
R32
0Ω
C49
5pF
38
21
R41
51Ω
R17
3.6kΩ
C19
0.1µF
R18
820Ω
20
J9
C20
0.056µF
22
R20
1kΩ
R19
1kΩ
23
J14
37
C33 C34
100pF 0.01µF
VCC
R34
1kΩ
IIN1B
QIN1B
J17
DCI1
DCQ1
J18
DCI1B
DCQ1B
C46
68pF
IOUT1
DCQ2B
C45
1000pF
IND-0402
IIN1
QIN1
QIN2B
DCQ2
DCQ2B
QOUT2
VCCMIX
RFINB
J10
L4
5.6nH
24
C29
0.56µF
R22
1.1kΩ
R42
51Ω
R21
3.6kΩ
R26
0Ω
L5
3.9nH
L6
3.9nH
R23
820Ω
VCC
R28
51Ω
R27
51Ω
R29
820Ω
C24
0.56µF
C25
68pF
C23
0.1µF
C22
0.1µF
C21
0.1µF
25
26
27
28
29
C26
22pF
32
GNDMIX
30
33
IOUT2
C30
0.1µF
31
34
DC12B
RFIN
35
DC12
C31
0.1µF
R43
51Ω
C27
22pF
36
C32
0.1µF
R31
3.6kΩ
R30
1.1kΩ
IIN2B
IIN2
VCC
VCCLO
GNDRF
LO
LNAOUT
2
1
VCC2
GNDMIX
2
1
QIN2
J19
R24
51Ω
4
C4
2.0pF
C28
OPEN
R25
51Ω
5
C50
2.0pF
3
2
J11
1
X9
LOGO
X8
MTHOLE4
1
X7
MTHOLE4
1
X6
MTHOLE4
1
X5
MTHOLE4
1
J12
T1
BALUN/MUR/LDB
J13
1
6
GND
Evaluate: MAX2700/MAX2701
MAX2700/MAX2701 Evaluation Kits
_______________________________________________________________________________________
VCC
X2ENB
VCC
R8
0Ω
R7
0Ω
R10
0Ω
R9
0Ω
J4
VCC
J5
R4
0Ω
R3
0Ω
J2
VCC
TP1
J3
J1
VCC
R12
0Ω
R11
100Ω
R6
100Ω
R5
100Ω
Z1
0.5pF
C5
10pF
J20
VCC
R2
100Ω
R1
0Ω
R45
0Ω
4
C11
68pF
C10
68pF
11
C8
100pF
12
C7
1000pF
10
9
8
GND 7
6
C3
1000pF
GND 5
C2
68pF
3
48
47
14
GND
J6
C13
2pF
L3
2.7nH
13
VCCLNA
AGC
SHDNB
GAINSET
GND
GNDRF
LNAIN
GNDRF
X2ENB
VCCRF
CEXT
L7
0
C41
OPEN
C48
OPEN
15
C12
22pF
L2
OPEN
46
C40
22pF
C42
OPEN
45
16
J7
R13
1kΩ
C15
0.056µF
GND
R39
1kΩ
44
R14
1kΩ
VCC
R15
0Ω
C14 C16
100pF 0.01µF
17
U1
C38
0.1µF
42
R37
3.6kΩ
R36
1.1kΩ
R44
51Ω
J8
19
C18
0.1µF
MAX2701
43
18
C17
0.1µF
C39
0.056µF
R38
1kΩ
MIXI
MIXQ
C47
OPEN
CEXTB
R40
0Ω
1
VCC
C1
0.1µF
2
C43
68pF
C6
1000pF
C9
0.01µF
Z4
1nH
C44
10µF
GNDLO
VCC1
41
C37
0.1µF
40
C36
0.1µF
R35
820Ω
C35
0.056µF
39
R33
1kΩ
J15
R32
0Ω
C49
3pF
38
21
R41
51Ω
R16
1.1kΩ
R17
3.6kΩ
C19
0.1µF
R18
820Ω
20
J9
C20
0.056µF
22
R20
1kΩ
R19
1kΩ
23
J14
37
C33 C34
100pF 0.01µF
VCC
R34
1kΩ
IIN1B
QIN1B
J16
DCI1
DCQ1
J17
DCI1B
DCQ1B
J18
IOUT1
QOUT
C46
68pF
IND-0402
IIN1
QIN1
QIN2B
DCQ2
DCQ2B
QOUT2
VCCMIX
RFINB
J10
L4
5.6nH
24
C29
0.56µF
R22
1.1kΩ
R42
51Ω
R21
3.6kΩ
R26
0Ω
L5
2.7nH
L6
2.7nH
R23
820Ω
VCC
R28
51Ω
R27
51Ω
R29
820Ω
C24
0.56µF
C25
68pF
C23
0.1µF
C22
0.1µF
C21
0.1µF
25
26
27
28
29
C26
22pF
32
GNDMIX
30
33
IOUT2
C30
0.1µF
31
34
DC12B
RFIN
35
DC12
C31
0.1µF
R43
51Ω
C27
22pF
36
C32
0.1µF
R31
3.6kΩ
R30
1.1kΩ
IIN2B
IIN2
C45
1000pF
VCCLO
GNDRF
LO
LNAOUT
2
1
GNDLO
GNDRF
GND
VCC2
GNDMIX
2
1
QIN2
VCC
R24
51Ω
4
C4
1.5pF
C28
OPEN
R25
51Ω
5
C50
1.5pF
3
2
J11
1
X9
LOGO
X8
MTHOLE4
1
X7
MTHOLE4
1
X6
MTHOLE4
1
X5
MTHOLE4
1
J12
T1 MURATA LDB15C500A2400
J13
1
Evaluate: MAX2700/MAX2701
J19
MAX2700/MAX2701 Evaluation Kits
Figure 1b. MAX2701 EV Kit Schematic
7
Evaluate: MAX2700/MAX2701
MAX2700/MAX2701 Evaluation Kits
1.0"
1.0"
Figure 2. MAX2700/MAX2701 EV Kits PC Board Layout—
Component Side
Figure 3. MAX2700/MAX2701 EV Kits PC Board Layout—
Ground Plane
1.0"
8
Figure 4. MAX2700/MAX2701 EV Kits PC Board Layout—
Power Plane
_______________________________________________________________________________________
MAX2700/MAX2701 Evaluation Kits
1.0"
Figure 5. MAX2700/MAX2701 EV Kits Component Placement
Guide—Top Silkscreen
Figure 6. MAX2700/MAX2701 EV Kits 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.
Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 _____________________9
© 2001 Maxim Integrated Products
Printed USA
is a registered trademark of Maxim Integrated Products.
Evaluate: MAX2700/MAX2701
1.0"