MAXIM MAX2700ECM

19-1667; Rev 0; 4/00
1.8GHz to 2.5GHz Direct Downconversion
Receivers
♦ Baseband Gain Offset Correction Loop
♦ +2.7V to +3.3V Single-Supply Operation
♦ Small 48-pin TQFP-EP Package
Ordering Information
PART
MAX2700ECM
TEMP. RANGE
-40°C to 85°C
MAX2701ECM
-40°C to 85°C
PIN-PACKAGE
48 TQFP-EP
48 TQFP-EP
Pin Configuration
IIN2+
37
38
39
40
41
42
43
44
45
46
VCC
LO
GND
MIX_I
GND
IIN1+
IIN1DCI1+
DCI1IOUT1
VCC
47
48
TOP VIEW
CEXTCEXT+
1
36
IIN2-
2
35
VCC
3
34
X2_EN
GND
4
33
32
DCI2+
DCI2IOUT2
GND
LNAIN
GND
6
31
RFIN-
30
GND
GAIN_SET
SHDN
8
29
RFIN+
VCC
QOUT2
DCQ2-
MAX2700
MAX2701
7
25
DCQ2+
QIN2-
24
26
12
23
27
11
22
28
21
9
10
20
AGC
VCC
5
GND
LNAOUT
GND
MIX_Q
VCC
QIN1+
QIN1DCQ1+
DCQ1QOUT1
MIXTNK
QIN2+
Digital Microwave Radios
♦ Variable Gain Baseband Amplifiers with >60dB
Control Range
19
Wideband 2.4GHz ISM Radios
♦ 3dB Baseband Channel Bandwidth of At Least
56MHz
18
Two-Way MMDS
♦ Wideband LO Quadrature Generator
17
Wideband Direct-Sequence Spread-Spectrum
Systems
♦ High Linearity Direct I/Q Downconverter
16
Wireless Local Loop
♦ LNA with Selectable Gain and Shutdown Option
15
________________________Applications
♦ Cascaded Performance at 1960 MHz
3.5dB Noise Figure
-7.5dBm Input IP3 at Maximum Gain
14
The two baseband VGAs in each channel provide 80dB
of total maximum gain and greater than 60dB of gain
control. The first AGC amplifier is optimized for low
noise, low power dissipation, and high linearity over the
entire gain range to ensure high gain compression performance. An external lowpass filter between baseband
VGAs provides the required channel selectivity at the
adjacent channel. An integrated gain offset correction
loop circuit provides <0.3dB amplitude mismatch
between the I and Q channels.
The MAX2700/MAX2701 operate from a single +2.7V to
+3.3V power supply, drawing only 165mA of supply
current and 20µA in shutdown mode. Both devices are
available in small 48-pin TQFP packages with exposed
paddle (EP) for optimum high-frequency performance.
♦ Input Frequency Range
1.8GHz to 2.1GHz (MAX2700)
2.1GHz to 2.5GHz (MAX2701)
13
The MAX2700/MAX2701 are highly integrated direct
downconversion (zero-IF) receivers designed for wideband wireless local loop (WLL) systems operating in
the 1.8GHz to 2.5GHz band. The MAX2700/MAX2701s’
zero-IF architecture eliminates the need for IF downconversion stages and the use of an IF SAW filter. This
reduces the overall receiver cost by reducing the component count and required board space.
The MAX2700/MAX2701 have three main blocks: lownoise amplifier (LNA), quadrature downconverter, and
baseband variable gain amplifiers (VGAs). The LNA is
a single-ended amplifier with selectable gain and shutdown options. It provides a high input third-order intercept point (IP3), which reduces cross-modulation and
gain compression due to high-level RF interference.
The quadrature downconverter section consists of two
highly linear double-balanced mixers driven by an
external local oscillator (LO) with a selectable LO doubler. The double-balanced mixers are optimized to provide high input IP3 and minimum added noise. The
mixers’ high input second-order intercept point (IIP2)
helps minimize receiver desensitization due to highlevel AM-modulated interferers.
Features
TQFP-EP
________________________________________________________________ Maxim Integrated Products
1
For free samples and the latest literature, visit www.maxim-ic.com or phone 1-800-998-8800.
For small orders, phone 1-800-835-8769.
MAX2700/MAX2701
General Description
MAX2700/MAX2701
1.8GHz to 2.5GHz Direct Downconversion
Receivers
ABSOLUTE MAXIMUM RATINGS
VCC to GND ..............................................................-0.3V to +6V
RF Signals
PRFIN, PLNAIN, PLO .....................................................+15dBm
Baseband Signals
IIN1+ to IIN1-, IIN2+ to IIN2-,
QIN1+ to QIN1-, QIN2+ to QIN2- ......................................±2V
Input Voltages
AGC, GAIN_SET, SHDN, X2_EN,
CEXT_, RFIN_, LO, LNAIN, IIN_ _,
QIN_ _ , DCI_ _ , DCQ_ _ to GND ..........-0.3V to (VCC + 0.3V)
Input Current
AGC……………………………………………………..±50mA
All Digital Inputs………………………………………..±10mA
Continuous Power Dissipation (TA = +70°C)
48-Pin TQFP-EP (derate 27mW/°C above +70°C) .....2000mW
Operating Temperature Range ...........................-40°C to +85°C
Storage Temperature Range .............................-65°C to +150°C
Junction Temperature ......................................................+150°C
Lead Temperature (soldering, 10s) .................................+300°C
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
DC ELECTRICAL CHARACTERISTICS
(MAX2700/MAX2701 EV kit (Figure 3), VCC = +2.7V to +3.3V, SHDN = GAIN_SET = VCC, X2_EN = GND, VAGC = 1.25V, CEXT+ connected to CEXT-; no RF input signals applied; RFIN, LNAIN, LO inputs are terminated with 50Ω, LNAOUT connected to VCC through a
10nH inductor; MIX_I, MIX_Q, QIN1+, QIN1-, QOUT1, IIN1+, IIN1-, IOUT1, QIN2+, QIN2-, QOUT2, IIN2+, IIN2-, IOUT2 pins are
unconnected; TA = -40°C to +85°C, unless otherwise noted. Typical values are at VCC = +3.0V, TA = +25°C.)
PARAMETERS
CONDITIONS
MIN
TYP
MAX
UNITS
3.3
V
SUPPLY
Supply Voltage
2.7
TA = +25°C
LNA
enabled
MAX2700
165
215
MAX2701
167
220
LNA
disabled
MAX2700
155
200
MAX2701
156
LNA
enabled
MAX2700
230
MAX2701
235
LNA
disabled
MAX2700
210
MAX2701
215
Operating Supply Current
TA = -40°C to +85°C
Shutdown Supply Current
SHDN = GND, VAGC = 0.5V
20
205
100
mA
µA
CONTROL INPUTS/OUTPUTS
Input Logic Voltage High
2
V
Input Logic Voltage Low
Input Bias Current
DC Output Voltage
0.6
SHDN, X2_EN, GAIN_SET
-1
0.5
AGC, +0.5 < VAGC < +2.0V
-22
12
AGC, VAGC = 0.5V, SHDN = GND
-2
2
µA
2
MIX_I, MIX_Q
1.2
IOUT1, QOUT1
1.1
1.25
IOUT2, QOUT2
V
_______________________________________________________________________________________
V
1.8GHz to 2.5GHz Direct Downconversion
Receivers
(MAX2700/MAX2701 EV kit (Figure 3), VCC = +3.0V, TA = +25°C, SHDN = GAIN_SET = VCC, X2_EN = GND, CEXT+ connected to
CEXT-, PLO = -13dBm, FLO = 980MHz (MAX2700) and 1200MHz (MAX2701), PLNAIN = -30dBm, PRFIN = -25dBm, LNAIN and RFIN
(single-ended input to balun) driven from 50Ω source, LNAOUT terminated into load; MIX_I, MIX_Q AC-coupled to 2kΩ load; IIN1+,
QIN1+, IIN2+, QIN2+ driven from 1.1kΩ AC-coupled source; IOUT1, QOUT1 AC-coupled to 2kΩ; IOUT2, QOUT2 AC-coupled to
100Ω; input to VGAs, 20mVp-p at 1MHz tone, set VAGC = 1.25V, unless otherwise noted.)
PARAMETERS
CONDITIONS
MIN
TYP
MAX
UNITS
LNA STAGE
Operating Frequency Range
(Note 1)
MAX2700
1800
2100
MAX2701
2100
2500
MAX2700,
fLNAIN = 1960MHz
TA = -40°C to 85°C
Power Gain (Note 2)
MAX2701,
fLNAIN = 2400MHz
TA = -40°C to 85°C
Noise Figure
Input Third-Order Intercept
(Note 3)
Reverse Isolation
Isolation
GAIN_SET = VCC
13.5
17.1
-1.9
GAIN_SET = GND
-7.5
13
20
GAIN_SET = GND
-8
2.5
GAIN_SET = VCC
13
16.5
18.5
-1.8
0.5
GAIN_SET = GND
-6
12.5
GAIN_SET = GND
-6.5
2.0
GAIN_SET = GND
15.8
MAX2701,
fLNAIN = 2400MHz
GAIN_SET = VCC
2.3
GAIN_SET = GND
16.7
MAX2700,
fLNAIN = 1960MHz
GAIN_SET = VCC
+2.7
GAIN_SET = GND
+5.1
MAX2701,
fLNAIN = 2400MHz
GAIN_SET = VCC
+3.8
GAIN_SET = GND
+4.3
1800MHz to 2500MHz, GAIN_SET = VCC or GND
28
LNAIN to LO, fLNAIN = 1800MHz to 2500MHz
30
LNAOUT to RFIN, fLNAIN = 1800 MHz to 2500 MHz
44
At LNA output, with external
matching circuit at LNAOUT
dB
1.0
GAIN_SET = VCC
VSWR
2
19
MAX2700,
fLNAIN = 1960MHz
At LNA input, with external
matching circuit at LNAIN
19.5
GAIN_SET = VCC
GAIN_SET = VCC
MHz
MAX2700 GAIN_SET = VCC
1.1
GAIN_SET = GND
1.8
MAX2701 GAIN_SET = VCC
1.3
GAIN_SET = GND
2.1
MAX2700 GAIN_SET = VCC
1.7
GAIN_SET = GND
1.6
MAX2701 GAIN_SET = VCC
1.2
GAIN_SET = GND
1.4
dB
dBm
dB
dB
−
MIXER STAGE (Differential RF input to mixer I/Q outputs with external balun and matching circuit to 50Ω)
Frequency Range
(Notes 1, 2)
Voltage Gain
DSB Noise Figure
MAX2700
1800
2100
MAX2701
2100
2500
MAX2700, fRFIN = 1960 MHz
16
19.3
21.5
MAX2701, fRFIN = 2400 MHz
14.5
18.1
20
MAX2700, fRFIN = 1960MHz
11.0
MAX2701, fRFIN = 2400MHz
12.8
MHz
dB
dB
_______________________________________________________________________________________
3
MAX2700/MAX2701
AC ELECTRICAL CHARACTERISTICS
MAX2700/MAX2701
1.8GHz to 2.5GHz Direct Downconversion
Receivers
AC ELECTRICAL CHARACTERISTICS (continued)
(MAX2700/MAX2701 EV kit (Figure 3), VCC = +3.0V, TA = +25°C, SHDN = GAIN_SET = VCC, X2_EN = GND, CEXT+ connected to
CEXT-, PLO = -13dBm, FLO = 980MHz (MAX2700) and 1200MHz (MAX2701), PLNAIN = -30dBm, PRFIN = -25dBm, LNAIN and RFIN
(single-ended input to balun) driven from 50Ω source, LNAOUT terminated into load; MIX_I, MIX_Q AC-coupled to 2kΩ load; IIN1+,
QIN1+, IIN2+, QIN2+ driven from 1.1kΩ AC-coupled source; IOUT1, QOUT1 AC-coupled to 2kΩ; IOUT2, QOUT2 AC-coupled to
100Ω; input to VGAs, 20mVp-p at 1MHz tone, set VAGC = 1.25V, unless otherwise noted.)
PARAMETERS
Input Third-Order Intercept
(Note 4)
Input Second-Order Intercept
(Note 5)
VSWR
CONDITIONS
MAX2701, f LO = 1200MHz
+6.5
MAX2700
+28.3
MAX2701
+38
With 50Ω external
matching at RFIN+/ RFIN-
Isolation (RFIN to MIX_I/Q)
MAX2701
1.5
MAX2701
1.2
fRFIN = 1800MHz to
2100MHz
35
fRFIN ≤20MHz
28
fRFIN = 2100MHz to
2500MHz
22
fRFIN ≤20MHz
12
38
MAX2701, f RFIN = 2100MHz to 2500MHz
45
Isolation (LO to RFIN)
MAX2701
4
MAX2700
MAX2700, f RFIN = 1800MHz to 2100MHz
MAX2700
Mixer Spurious Suppression
TYP
+6.3
MAX2700
Isolation (RFIN to LO)
MIN
MAX2700, f LO = 980MHz
fLO = 900MHz to
1050MHz, X2_EN = GND
49
fLO = 900MHz to
1050MHz, X2_EN = GND,
isolation at 2 x FLO
43
fLO = 1800MHz to
2100MHz, X2_EN = V CC
33
fLO = 1050MHz to 1250MHz,
X2_EN = GND
60
fLO = 1050MHz to 1250MHz,
X2_EN = GND, isolation at
2 x F LO
44
fLO = 2100MHz to
2500MHz, X2_EN = V CC
70
2 x LO - RF (Note 6)
Baseband Bandwidth
MIX_I/Q
Gain Mismatch
∆GV (I-Q) (between mixer
I and Q channels)
MAX
dBm
dBm
–
dB
dB
dB
60
-1dB bandwidth (Note 2)
37
UNITS
dBc
69
MHz
-3dB bandwidth
170
Baseband frequency =
125kHz
0.1
0.7
Up to -1dB baseband
width (Note 2)
0
0.7
dB
_______________________________________________________________________________________
1.8GHz to 2.5GHz Direct Downconversion
Receivers
(MAX2700/MAX2701 EV kit (Figure 3), VCC = +3.0V, TA = +25°C, SHDN = GAIN_SET = VCC, X2_EN = GND, CEXT+ connected to
CEXT-, PLO = -13dBm, FLO = 980MHz (MAX2700) and 1200MHz (MAX2701), PLNAIN = -30dBm, PRFIN = -25dBm, LNAIN and RFIN
(single-ended input to balun) driven from 50Ω source, LNAOUT terminated into load; MIX_I, MIX_Q AC-coupled to 2kΩ load; IIN1+,
QIN1+, IIN2+, QIN2+ driven from 1.1kΩ AC-coupled source; IOUT1, QOUT1 AC-coupled to 2kΩ; IOUT2, QOUT2 AC-coupled to
100Ω; input to VGAs, 20mVp-p at 1MHz tone, set VAGC = 1.25V, unless otherwise noted.)
PARAMETERS
CONDITIONS
Group Delay
tgd , RFIN to MIX_I/Q, frequency up to
-1dB baseband width
Differential Group Delay
(Note 2)
∆tgd (between mixer I and Q channels)
Output Impedance
Zout , MIX_I, MIX_Q, frequency up to -1dB baseband
width
Mixer Output Level
(Note 2)
MIX_I, MIX_Q, baseband output at -1dB compression
point
MIN
TYP
MAX
1.8
ns
1
1.4
UNITS
ns
1.4
Ω
2.1
Vp-p
LO DOUBLER, LO BUFFER, QUADRATURE GENERATOR
X2_EN = GND
LO Frequency Range
(Notes 1, 2)
LO Input Power (Note 7)
X2_EN = V CC
MAX2700
900
1050
MAX2701
1050
1250
MAX2700
1800
2100
MAX2701
2100
2500
X2_EN = V CC or GND
-16
-13
fLO = 900MHz to
1050MHz, X2_EN = GND
2.0
fLO = 1800MHz to
2100MHz, X2_EN = V CC
1.8
fLO = 1050MHz to
1250MHz, X2_EN = GND
1.7
fLO = 2100MHz to
2500MHz, X2_EN = V CC
2.0
-10
MHz
dBm
MAX2700
LO VSWR
−
MAX2701
∆φ , MIX_I to MIX_Q
Quadrature Error
1.5
4.5
degrees
BASEBAND STAGE 1 (IIN1 TO IOUT1, QIN1 TO QOUT1)
Channel Bandwidth
-1dB bandwidth (Note 2)
14
26
MHz
-3dB bandwidth
56
Input Impedance
IIN1+, IIN1-, QIN1+, QIN1-, single-ended
1.9
kΩ
Input Impedance Mismatch
Between IIN1+ and QIN1+
4
Ω
Voltage Gain (G V)
VAGC = 0.5V
-1.5
2.2
6
VAGC = 2.0V
37
40
42
dB
Voltage Gain Mismatch
Mismatch between IIN1 to IOUT1 and QIN1 to QOUT1,
0.5V < V AGC < 2 V
0.2
dB
VGA1 Gain Slope
Guaranteed Monotonic over 0.5V <V AGC < 2V,
VAGC = 1.25V
34
dB/V
Noise Figure
ZS = 1.1kΩ (Note 8)
Phase Shift (Note 2)
For 10dB of gain (with AGC)
VAGC = 2.0V
7.5
VAGC = 0.5V
34
0.5
dB
0.9
degrees
_______________________________________________________________________________________
5
MAX2700/MAX2701
AC ELECTRICAL CHARACTERISTICS (continued)
MAX2700/MAX2701
1.8GHz to 2.5GHz Direct Downconversion
Receivers
AC ELECTRICAL CHARACTERISTICS (continued)
(MAX2700/MAX2701 EV kit (Figure 3), VCC = +3.0V, TA = +25°C, SHDN = GAIN_SET = VCC, X2_EN = GND, CEXT+ connected to
CEXT-, PLO = -13dBm, FLO = 980MHz (MAX2700) and 1200MHz (MAX2701), PLNAIN = -30dBm, PRFIN = -25dBm, LNAIN and RFIN
(single-ended input to balun) driven from 50Ω source, LNAOUT terminated into load; MIX_I, MIX_Q AC-coupled to 2kΩ load; IIN1+,
QIN1+, IIN2+, QIN2+ driven from 1.1kΩ AC-coupled source; IOUT1, QOUT1 AC-coupled to 2kΩ; IOUT2, QOUT2 AC-coupled to
100Ω; input to VGAs, 20mVp-p at 1MHz tone, set VAGC = 1.25V, unless otherwise noted.)
PARAMETERS
CONDITIONS
MIN
TYP
MAX
UNITS
IIN1+ to IOUT1, up to -1dB frequency
1.6
1.6
Group Delay Mismatch (Note 2)
QIN1+ to QOUT1, up to -1dB frequency
Between I and Q channel from 100kHz up to -1dB
Output Impedance
IOUT1, QOUT1, up to -1dB bandwidth
7
Ω
Output Impedance Mismatch
Between IOUT1 and QOUT1, up to -1dB bandwidth
1
Ω
Output Voltage (Note 2)
At -1dB compression point, IOUT1, QOUT1
0.7
1.1
Vp-p
19
34
Group Delay
0.3
ns
1.3
ns
BASEBAND STAGE 2 (IIN2+ TO IOUT2, QIN2+ TO QOUT2)
Channel Bandwidth
-3dB bandwidth
63
Input Impedance
IIN2+, IIN2-, QIN2+, QIN2-, single-ended
Input Impedance Mismatch
Between IIN2+ and QIN2+
2.1
1.5
Voltage Gain (G V)
6
-1dB bandwidth (Note 2)
MHz
KΩ
Ω
VAGC = 0.5V
-0.6
4.4
9.5
VAGC = 2.0V
37
39
42
0.9
Gain Correction Disabled
Voltage Gain Mismatch
(Note 2)
Mismatch between IIN2 to
IOUT2 and QIN2 to
QOUT2, 0.5V < VAGC < 2V
VGA2 Gain Slope
Guaranteed monotonic over 0.5V < V AGC <2V,
VAGC =1.25V
Noise Figure
ZS = 1.1kΩ
dB
dB
Gain Correction Enabled
(2dB initial mismatch)
0.3
30
VAGC = 2.0V
14
VAGC = 0.5V
47
Phase shift (Note 2)
For 10dB of gain
0.2
Group Delay
IIN2+ to IOUT2, QIN2+ to QOUT2, up to -1dB Frequency
1.7
Group Delay Mismatch
(Note 2)
Between I and Q channel from 100kHz up to -1dB
frequency
0.2
Output Impedance
IOUT2 , QOUT2, up to -1dB bandwidth
4.0
Output Impedance Mismatch
Between IOUT2 and QOUT2, up to -1 dB bandwidth
Output Voltage (Note 2)
At -1dB compression point, IOUT2 , QOUT2
1.2
dB/V
dB
1.4
degrees
ns
2.0
ns
Ω
4.0
Ω
1.9
Vp-p
_______________________________________________________________________________________
1.8GHz to 2.5GHz Direct Downconversion
Receivers
(MAX2700/MAX2701 EV kit (Figure 3), VCC = +3.0V, TA = +25°C, SHDN = GAIN_SET = VCC, X2_EN = GND, CEXT+ connected to
CEXT-, PLO = -13dBm, FLO = 980MHz (MAX2700) and 1200MHz (MAX2701), PLNAIN = -30dBm, PRFIN = -25dBm, LNAIN and RFIN
(single-ended input to balun) driven from 50Ω source, LNAOUT terminated into load; MIX_I, MIX_Q AC-coupled to 2kΩ load; IIN1+,
QIN1+, IIN2+, QIN2+ driven from 1.1kΩ AC-coupled source; IOUT1, QOUT1 AC-coupled to 2kΩ; IOUT2, QOUT2 AC-coupled to
100Ω; input to VGAs, 20mVp-p at 1MHz tone, set VAGC = 1.25V, unless otherwise noted.)
PARAMETERS
CONDITIONS
MIN
TYP
MAX
UNITS
POWER SUPPLY
Power-Supply Ripple Rejection
VCC = 3.0V + 100mVPP
frequency = 100 to 300kHz,
VOUT = 0.3Vp-p, (Note 9)
Mixer
57
VGA1
35
VGA2
28
dBc
Note 1: This is the recommended operating frequency range. The parts have been characterized over the specified frequency
range. Operation outside this range is possible but not guaranteed.
Note 2: Guaranteed by design and characterization.
Note 3: LNA is matched at input and output to 50Ω; f1 = 1960MHz, f2 = 1965MHz for MAX2700; f1 = 2400MHz, f2 = 2405MHz for
MAX2701; PIN = -30dBm per tone.
Note 4: Mixer IIP3 test. For MAX2700, RFIN is matched to 50Ω at 1960MHz. At RFIN, apply f1 = 1964.2MHz, f2 = 1968.2MHz, PIN =
-25dBm per tone, and measure IM3 product power level at 200kHz. For MAX2701, RFIN is matched to 50Ω at 2400MHz. At
RFIN, apply f1 = 2404.2MHz, f2 = 2408.2MHz, PIN = -25dBm per tone, and measure IM3 product power level at 200kHz.
Note 5: Mixer IIP2 test. For MAX2700, RFIN is matched to 50Ω at 1960MHz. At RFIN, apply f1 = 1964.2MHz, f2 = 1968.2MHz, PIN =
-25dBm per tone, and measure IM2 product power level at 4MHz. For MAX2701, RFIN is matched to 50Ω at 2400MHz. At
RFIN, apply f1 = 2404.2MHz, f2 = 2408.2MHz, PIN = -25dBm per tone, and measure IM2 product power level at 4MHz.
Note 6: Mixer spurious attenuation response. Mixer is matched to 50Ω at 1800MHz and FLO = 900MHz (LO doubler enabled).
FRFIN = 1801MHz, PRFIN = -85dBm, FSPUR = 3601.5MHz, PSPUR = -60dBm. Measure IF at 1MHz and spurious at 1.5MHz at
the output. For better than 38dBc spurious attenuation response, output spurious level should be at least 10dB lower than
the IF signal level. In the (2 x LO) - (1 x RF) spurious product notation, LO denotes the frequency of the final LO driving the
I/Q mixers inputs.
Note 7: Mixer gain specifications are production tested over LO power range.
Note 8: A filter output impedance of 1.1kΩ can directly drive the VGA inputs since there is minimal mismatch loss between source and
VGA input impedance.
Note 9: Electrolytic bypass cap to VCC not connected.
_______________________________________________________________________________________
7
MAX2700/MAX2701
AC ELECTRICAL CHARACTERISTICS (continued)
Typical Operating Characteristics
(MAX2700/MAX2701 EV kit (Figure 3), VCC = +3.0V, TA = +25°C, SHDN = GAIN_SET = VCC, X2_EN = GND, CEXT+ connected to
CEXT-, PLO = -13dBm, FLO = 980MHz (MAX2700) and 1200MHz (MAX2701), PLNAIN = -30dBm, PRFIN = -25dBm, LNAIN and RFIN
(single-ended input to balun) driven from 50Ω source, LNAOUT terminated into load; MIX_I, MIX_Q AC-coupled to 2kΩ load; IIN1+,
QIN1+, IIN2+, QIN2+ driven from 1.1kΩ AC-coupled source; IOUT1, QOUT1 AC-coupled to 2kΩ; IOUT2, QOUT2 AC-coupled to
100Ω; input to VGAs, 20mVp-p at 1MHz tone, set VAGC = 1.25V, unless otherwise noted.)
MAX2700
TA = -45°C
18
TA = +25°C
4
TA = -45°C
2
TA = +25°C
TA = +25°C
TA = +85°C
160
TA = -45°C
GAIN (dB)
0
GAIN (dB)
170
MAX2700-03
MAX2700-02
20
MAX2700-01
180
LNA GAIN vs. FREQUENCY
vs. TEMPERATURE
LNA GAIN vs. FREQUENCY
vs. TEMPERATURE
ICC vs. VCC vs. TEMPERATURE
ICC (mA)
16
TA = +85°C
14
-2
TA = +85°C
-4
-6
150
12
-8
140
10
2.7
2.9
3.1
3.3
3.5
HIGH-GAIN MODE
1700
1800
VCC (V)
-10
1900
2000
1900
LNA NOISE FIGURE vs. FREQUENCY
vs. TEMPERATURE
MAX2700-04
-25
1800
2.6
2.4
NF (dB)
HIGH-GAIN MODE
TA = +85°C
2.2
2.0
TA = +25°C
LOW-GAIN MODE
1.8
-35
1.6
1700
1800
1900
FREQUENCY (MHz)
8
TA = -45°C
HIGH-GAIN MODE
1.4
-40
2000
2100
2000
FREQUENCY (MHz)
FREQUENCY (MHz)
LNA REVERSE ISOLATION
vs. FREQUENCY vs. GAIN MODE
-30
LOW-GAIN MODE
1700
2100
MAX2700-05
2.5
S12 (dB)
MAX2700/MAX2701
1.8GHz to 2.5GHz Direct Downconversion
Receivers
1700 1750
1800 1850 1900
1950 2000
FREQUENCY (MHz)
_______________________________________________________________________________________
2100
1.8GHz to 2.5GHz Direct Downconversion
Receivers
(MAX2700/MAX2701 EV kit (Figure 3), VCC = +3.0V, TA = +25°C, SHDN = GAIN_SET = VCC, X2_EN = GND, CEXT+ connected to
CEXT-, PLO = -13dBm, FLO = 980MHz (MAX2700) and 1200MHz (MAX2701), PLNAIN = -30dBm, PRFIN = -25dBm, LNAIN and RFIN
(single-ended input to balun) driven from 50Ω source, LNAOUT terminated into load; MIX_I, MIX_Q AC-coupled to 2kΩ load; IIN1+,
QIN1+, IIN2+, QIN2+ driven from 1.1kΩ AC-coupled source; IOUT1, QOUT1 AC-coupled to 2kΩ; IOUT2, QOUT2 AC-coupled to
100Ω; input to VGAs, 20mVp-p at 1MHz tone, set VAGC = 1.25V, unless otherwise noted.)
MAX2700
4.5
MAX2700-07
6
MAX2700-06
17
LNA IIP3 vs. VCC
LNA IIP3 vs. TEMPERATURE
18
5
3.5
TA = +85°C
3.0
TA = +25°C
15
IIP3 (dBm)
IIP3 (dBm)
NF (dB)
4
16
LOW-GAIN MODE
4.0
LOW-GAIN MODE
HIGH-GAIN MODE
3
MAX2700-08
LNA NOISE FIGURE vs. FREQUENCY
vs. TEMPERATURE
HIGH-GAIN MODE
2.5
2.0
1.5
2
TA = -45°C
1.0
14
1
0.5
1800
1900
-45
2000
-25
-5
MAX2700-09
TA = +25°C
24
20
18
TA = +85°C
16
TA = +25°C
TA = -45°C
20
TA = +85°C
16
DOUBLER ENABLED
1.7
1.8
10
1.9
FREQUENCY (GHz)
2.0
2.1
3.50
LO = -16dBm TO -10dBm
20
18
16
14
12
12
3.25
24
22
18
3.00
MIXER VOLTAGE GAIN vs. FREQUENCY
vs. LO POWER
14
14
2.75
VCC (V)
VOLTAGE GAIN (dB)
VOLTAGE GAIN (dB)
VOLTAGE GAIN (dB)
2.50
75
22
22
10
55
MIXER VOLTAGE GAIN vs. FREQUENCY
vs. TEMPERATURE
MIXER VOLTAGE GAIN vs. FREQUENCY
vs. TEMPERATURE
TA = -45°C
35
TEMPERATURE (°C)
FREQUENCY (MHz)
24
15
MAX2700-11
1700
0
0
MAX2700-10
13
LOW-GAIN MODE
12
DOUBLER DISABLED
1.7
1.8
10
1.9
FREQUENCY (GHz)
2.0
2.1
DOUBLER DISABLED
1.7
1.8
1.9
2.0
2.1
FREQUENCY (GHz)
_______________________________________________________________________________________
9
MAX2700/MAX2701
Typical Operating Characteristics (continued)
Typical Operating Characteristics (continued)
(MAX2700/MAX2701 EV kit (Figure 3), VCC = +3.0V, TA = +25°C, SHDN = GAIN_SET = VCC, X2_EN = GND, CEXT+ connected to
CEXT-, PLO = -13dBm, FLO = 980MHz (MAX2700) and 1200MHz (MAX2701), PLNAIN = -30dBm, PRFIN = -25dBm, LNAIN and RFIN
(single-ended input to balun) driven from 50Ω source, LNAOUT terminated into load; MIX_I, MIX_Q AC-coupled to 2kΩ load; IIN1+,
QIN1+, IIN2+, QIN2+ driven from 1.1kΩ AC-coupled source; IOUT1, QOUT1 AC-coupled to 2kΩ; IOUT2, QOUT2 AC-coupled to
100Ω; input to VGAs, 20mVp-p at 1MHz tone, set VAGC = 1.25V, unless otherwise noted.)
MAX2700
7
6
12
5
11
10
TA = +25°C
25
TA = -45°C
TA = +85°C
4
3
TA = +25°C
10
DOUBLER ENABLED
0
1850
1900
1950
2000
2050
2100
2.60
2.85
3.10
LO-RFIN ISOLATION vs. LO FREQUENCY
(INCLUDING BALUN)
DOUBLER DISABLED
1.25
-45
-50
DOUBLER ENABLED
-55
-60
1.00
1.7
1.8
1.9
FREQUENCY (GHz)
2.0
2.1
3.35
LO-LNAIN ISOLATION vs. LO FREQUENCY
DOUBLER DISABLED
LO-LNAIN ISOLATION (dB)
LO-RFIN ISOLATION (dB)
DOUBLER ENABLED
3.10
-40
MAX2700-16
-40
DOUBLER DISABLED
1.50
2.85
VCC (V)
φ ERROR vs. LO FREQUENCY
1.75
DOUBLER ENABLED
2.60
VCC (V)
MAX2700-15
5
3.35
FREQUENCY (MHz)
2.00
TA = -45°C
15
1
7
1800
TA = +25°C
TA = +85°C
2
TA = -45°C
8
20
MAX2700-17
9
10
30
IIP2 (dBm)
13
35
MAX2700-13
TA = +85°C
IIP3 (dBm)
NF (dB)
14
MIXER IIP2 vs. VCC vs. TEMPERATURE
MIXER IIP3 vs. VCC vs. TEMPERATURE
8
MAX2700-12
15
MAX2700-14
DSB MIXER NOISE FIGURE vs. FREQUENCY
vs. TEMPERATURE
φ ERROR (DEGREES)
MAX2700/MAX2701
1.8GHz to 2.5GHz Direct Downconversion
Receivers
-50
-60
DOUBLER ENABLED
-70
-80
0.85
0.90
0.95
FREQUENCY (GHz)
1.00
1.05
0.85
0.90
0.95
FREQUENCY (GHz)
______________________________________________________________________________________
1.00
1.05
1.8GHz to 2.5GHz Direct Downconversion
Receivers
(MAX2700/MAX2701 EV kit (Figure 3), VCC = +3.0V, TA = +25°C, SHDN = GAIN_SET = VCC, X2_EN = GND, CEXT+ connected to
CEXT-, PLO = -13dBm, FLO = 980MHz (MAX2700) and 1200MHz (MAX2701), PLNAIN = -30dBm, PRFIN = -25dBm, LNAIN and RFIN
(single-ended input to balun) driven from 50Ω source, LNAOUT terminated into load; MIX_I, MIX_Q AC-coupled to 2kΩ load; IIN1+,
QIN1+, IIN2+, QIN2+ driven from 1.1kΩ AC-coupled source; IOUT1, QOUT1 AC-coupled to 2kΩ; IOUT2, QOUT2 AC-coupled to
100Ω; input to VGAs, 20mVp-p at 1MHz tone, set VAGC = 1.25V, unless otherwise noted.)
MAX2700
MIXER'S OUTPUT 1dB COMPRESSION
POINT vs. VCC vs. RL
MIXER BASEBAND BANDWIDTH vs. RL
3dB BANDWIDTH
2.4
MIXER OUTPUT (Vp-p)
BANDWIDTH (MHz)
120
100
80
1dB BANDWIDTH
60
RL = 1.05kΩ, 2.00kΩ
2.2
2.0
RL = 0.56kΩ
1.8
1.6
40
1.4
20
1.2
0
MAX2700-19
140
2.6
MAX2700-18
160
1.0
0.50
0.75
1.00
1.25
1.50
1.75
2.00
2.5
2.7
2.9
RL (kΩ)
3.1
3.3
3.5
VCC (V)
MAX2701
TA = -45°C
18
170
TA = +25°C
160
TA = -45°C
2
16
1
15
2.7
2.9
VCC (V)
3.1
3.3
TA = +25°C
14
TA = +85°C
3.5
TA = +85°C
0
TA = +25°C
TA = -45°C
-1
13
-2
12
-3
10
2.5
3
17
-4
11
150
4
GAIN (dB)
TA = +85°C
GAIN (dB)
ICC (mA)
180
MAX2701-22
19
5
MAX2701-21
20
MAX2701-20
190
LNA GAIN vs. FREQUENCY
vs. TEMPERATURE
LNA GAIN vs. FREQUENCY
vs. TEMPERATURE
ICC vs. VCC vs. TEMPERATURE
HIGH-GAIN MODE
2100
2200
-5
2300
FREQUENCY (MHz)
2400
2500
LOW-GAIN MODE
2100
2200
2300
2400
2500
FREQUENCY (MHz)
______________________________________________________________________________________
11
MAX2700/MAX2701
Typical Operating Characteristics (continued)
Typical Operating Characteristics (continued)
(MAX2700/MAX2701 EV kit (Figure 3), VCC = +3.0V, TA = +25°C, SHDN = GAIN_SET = VCC, X2_EN = GND, CEXT+ connected to
CEXT-, PLO = -13dBm, FLO = 980MHz (MAX2700) and 1200MHz (MAX2701), PLNAIN = -30dBm, PRFIN = -25dBm, LNAIN and RFIN
(single-ended input to balun) driven from 50Ω source, LNAOUT terminated into load; MIX_I, MIX_Q AC-coupled to 2kΩ load; IIN1+,
QIN1+, IIN2+, QIN2+ driven from 1.1kΩ AC-coupled source; IOUT1, QOUT1 AC-coupled to 2kΩ; IOUT2, QOUT2 AC-coupled to
100Ω; input to VGAs, 20mVp-p at 1MHz tone, set VAGC = 1.25V, unless otherwise noted.)
MAX2701
LNA REVERSE ISOLATION
vs. FREQUENCY
LNA NOISE FIGURE vs. FREQUENCY
vs. TEMPERATURE
LNA NOISE FIGURE vs. FREQUENCY
vs. TEMPERATURE
TA = +85°C
-26
TA = +25°C
MAX2701-25
HIGH-GAIN MODE
20
MAX2701-24
3.5
MAX2701-23
-24
18
NF (dB)
TA = -45°C
LOW-GAIN MODE
-28
NF (dB)
2.5
-30
14
2.0
-32
-34
2200
2300
2400
2500
TA = +85°C
TA = -45°C
TA = +25°C
12
HIGH-GAIN MODE
1.5
2100
2100
2200
10
2300
2400
LOW-GAIN MODE
2100
2500
2200
2300
2400
2500
FREQUENCY (MHz)
FREQUENCY (MHz)
FREQUENCY (MHz)
LNA IIP3 vs. TEMPERATURE
LNA IIP3 vs. VCC
MIXER VOLTAGE GAIN vs. FREQUENCY
vs. TEMPERATURE
LOW-GAIN MODE
5
22
MAX2701-27
LOW-GAIN MODE
5
6
MAX2701-26
6
21
TA = -45°C
IIP3 (dBm)
3
HIGH-GAIN MODE
2
VOLTAGE GAIN (dB)
4
4
HIGH-GAIN MODE
3
2
20
19
18
1
17
1
0
16
0
-1
15
-45
-25
-5
15
35
TEMPERATURE (°C)
12
16
MAX2701-28
S12 (dB)
3.0
IIP3 (dBm)
MAX2700/MAX2701
1.8GHz to 2.5GHz Direct Downconversion
Receivers
55
75
2.50
2.75
3.00
VCC (V)
3.25
3.50
TA = +25°C
DOUBLER ENABLED
2.1
2.2
TA = +85°C
2.3
2.4
FREQUENCY (GHz)
______________________________________________________________________________________
2.5
1.8GHz to 2.5GHz Direct Downconversion
Receivers
MAX2701
21
24
19
18
17
TA = +25°C
2.2
16
10
14
9
10
2.3
2.4
FREQUENCY (GHz)
11
2.5
TA = +25°C
TA = -45°C
8
DOUBLER ENABLED
2.1
7
2.2
2.3
2.4
2100
2.5
2200
60
MAX2701-32
9
2400
2500
φ ERROR vs. LO FREQUENCY
MIXER IIP2 vs. VCC vs. TEMPERATURE
MIXER IIP3 vs. VCC vs. TEMPERATURE
11
2300
FREQUENCY (MHz)
FREQUENCY (GHz)
2.0
TA = +25°C
50
MAX2701-34
2.1
12
18
12
TA = +85°C
TA = +85°C
13
20
MAX2701-33
15
DOUBLER DISABLED
14
NF (dB)
20
16
PLO = -16dBm TO -10dBm
22
VOLTAGE GAIN (dB)
VOLTAGE GAIN (dB)
TA = -45°C
15
MAX2701-30
MAX2701-29
22
DSB MIXER NOISE FIGURE
vs. FREQUENCY vs. TEMPERATURE
MIXER VOLTAGE GAIN vs. FREQUENCY
vs. LO POWER
MAX2701-31
MIXER VOLTAGE GAIN vs. FREQUENCY
vs. TEMPERATURE
TA = +85°C
TA = -45°C
TA = +25°C
IIP2 (dBm)
IIP3 (dBm)
5
30
3
20
1
10
TA = -45°C
TA = +85°C
φ ERROR (DEGREES)
1.5
40
7
DOUBLER ENABLED
1.0
DOUBLER DISABLED
0.5
DOUBLER ENABLED
-1
2.60
2.85
3.10
VCC (V)
3.35
0
DOUBLER ENABLED
2.60
2.85
0
3.10
VCC (V)
3.35
2.1
2.2
2.3
2.4
2.5
FREQUENCY (GHz)
______________________________________________________________________________________
13
MAX2700/MAX2701
Typical Operating Characteristics (continued)
(MAX2700/MAX2701 EV kit (Figure 3), VCC = +3.0V, TA = +25°C, SHDN = GAIN_SET = VCC, X2_EN = GND, CEXT+ connected to
CEXT-, PLO = -13dBm, FLO = 980MHz (MAX2700) and 1200MHz (MAX2701), PLNAIN = -30dBm, PRFIN = -25dBm, LNAIN and RFIN
(single-ended input to balun) driven from 50Ω source, LNAOUT terminated into load; MIX_I, MIX_Q AC-coupled to 2kΩ load; IIN1+,
QIN1+, IIN2+, QIN2+ driven from 1.1kΩ AC-coupled source; IOUT1, QOUT1 AC-coupled to 2kΩ; IOUT2, QOUT2 AC-coupled to
100Ω; input to VGAs, 20mVp-p at 1MHz tone, set VAGC = 1.25V, unless otherwise noted.)
Typical Operating Characteristics (continued)
(MAX2700/MAX2701 EV kit (Figure 3), VCC = +3.0V, TA = +25°C, SHDN = GAIN_SET = VCC, X2_EN = GND, CEXT+ connected to
CEXT-, PLO = -13dBm, FLO = 980MHz (MAX2700) and 1200MHz (MAX2701), PLNAIN = -30dBm, PRFIN = -25dBm, LNAIN and RFIN
(single-ended input to balun) driven from 50Ω source, LNAOUT terminated into load; MIX_I, MIX_Q AC-coupled to 2kΩ load; IIN1+,
QIN1+, IIN2+, QIN2+ driven from 1.1kΩ AC-coupled source; IOUT1, QOUT1 AC-coupled to 2kΩ; IOUT2, QOUT2 AC-coupled to
100Ω; input to VGAs, 20mVp-p at 1MHz tone, set VAGC = 1.25V, unless otherwise noted.)
MAX2701
LO-RF ISOLATION vs. LO FREQUENCY
(INCLUDING BALUN)
LO-LNAIN ISOLATION (dB)
-50
-60
-70
MAX2701-36
DOUBLER DISABLED
LO-RFIN ISOLATION (dB)
LO-LNAIN ISOLATION vs. LO FREQUENCY
-40
MAX2701-35
-40
DOUBLER DISABLED
-50
-60
-70
DOUBLER ENABLED
DOUBLER ENABLED
-80
1.05
1.10
1.15
1.20
1.175
1.200
1.225
FREQUENCY (GHz)
MIXER BASEBAND BANDWIDTH vs. RL
MIXER OUTPUT 1dB COMPRESSION
POINT vs. VCC vs. RL
2.8
2.6
3dB BANDWIDTH
MIXER OUTPUT (Vp-p)
140
120
100
80
60
1dB BANDWIDTH
40
1.250
MAX2701-38
3.0
MAX2701-37
160
RL = 2.00kΩ
2.4
2.2
RL = 0.56kΩ
2.0
1.8
RL = 1.05kΩ
1.6
1.4
20
1.2
1.0
0
0.50
0.75
1.00
1.25
RL (kΩ)
14
-80
1.150
1.25
FREQUENCY (GHz)
180
BANDWIDTH (MHz)
MAX2700/MAX2701
1.8GHz to 2.5GHz Direct Downconversion
Receivers
1.50
1.75
2.00
2.5
2.7
2.9
3.1
3.3
VCC (V)
______________________________________________________________________________________
3.5
1.8GHz to 2.5GHz Direct Downconversion
Receivers
(MAX2700/MAX2701 EV kit (Figure 3), VCC = +3.0V, TA = +25°C, SHDN = GAIN_SET = VCC, X2_EN = GND, CEXT+ connected to
CEXT-, PLO = -13dBm, FLO = 980MHz (MAX2700) and 1200MHz (MAX2701), PLNAIN = -30dBm, PRFIN = -25dBm, LNAIN and RFIN
(single-ended input to balun) driven from 50Ω source, LNAOUT terminated into load; MIX_I, MIX_Q AC-coupled to 2kΩ load; IIN1+,
QIN1+, IIN2+, QIN2+ driven from 1.1kΩ AC-coupled source; IOUT1, QOUT1 AC-coupled to 2kΩ; IOUT2, QOUT2 AC-coupled to
100Ω; input to VGAs, 20mVp-p at 1MHz tone, set VAGC = 1.25V, unless otherwise noted.)
MAX2700/MAX2701
TA = +25°C
0
-0.5
TA = -45°C
1.00
1.25
1.50
1.75
0.75
1.00
1.25
1.50
1.75
0.50
2.00
0.75
1.00
1.25
1.50
1.75
AGC (V)
AGC (V)
AGC (V)
VGA1
VGA OUTPUT 1dB COMPRESSION
POINT vs. AGC VOLTAGE vs. RL
VGA1
BANDWIDTH vs. RL
VGA2
VOLTAGE GAIN vs. AGC VOLTAGE
vs. TEMPERATURE
RL = 2.0kΩ
1.50
RL = 0.6kΩ
RL = 1.1kΩ
1.25
3dB BANDWIDTH
50
40
30
40
2.00
MAX2700/1-44
60
VOLTAGE GAIN (dB)
VGA1 BANDWIDTH (MHz)
1.75
50
MAX2700/1-43
70
MAX2700/1-42
2.00
V01 (PEAK TO PEAK)
5
0.50
2.00
TA = +25°C
10
-2.0
0.75
20
15
TA = +85°C
-1.5
0.50
TA = -45°C
25
0.5
-1.0
0
TA = +85°C
30
TA = +25°C
1.0
MAX2700/1-41
MAX2700/1-40
35
NF (dB)
TA = +85°C
20
10
1.5
I/Q VOLTAGE GAIN (dB)
VOLTAGE GAIN (dB)
30
2.0
MAX2700/1-39
TA = -45°C
40
VGA1
NOISE FIGURE vs. AGC VOLTAGE
vs. TEMPERATURE
I/Q VOLTAGE GAIN MISMATCH
vs. TEMPERATURE
AGC VOLTAGE GAIN vs. AGC VOLTAGE
vs. TEMPERATURE
TA = -45°C
30
TA = +85°C
20
TA = +25°C
10
1dB BANDWIDTH
RL = 1.6kΩ
20
1.00
0.50
0.75
1.00
1.25
AGC (V)
1.50
1.75
2.00
0
0.6
0.8
1.0
1.2
1.4
RL (kΩ)
1.6
1.8
2.0
0.50
0.75
1.00
1.25
1.50
1.75
2.00
AGC (V)
______________________________________________________________________________________
15
MAX2700/MAX2701
Typical Operating Characteristics (continued)
Typical Operating Characteristics (continued)
(MAX2700/MAX2701 EV kit (Figure 3), VCC = +3.0V, TA = +25°C, SHDN = GAIN_SET = VCC, X2_EN = GND, CEXT+ connected to
CEXT-, PLO = -13dBm, FLO = 980MHz (MAX2700) and 1200MHz (MAX2701), PLNAIN = -30dBm, PRFIN = -25dBm, LNAIN and RFIN
(single-ended input to balun) driven from 50Ω source, LNAOUT terminated into load; MIX_I, MIX_Q AC-coupled to 2kΩ load; IIN1+,
QIN1+, IIN2+, QIN2+ driven from 1.1kΩ AC-coupled source; IOUT1, QOUT1 AC-coupled to 2kΩ; IOUT2, QOUT2 AC-coupled to
100Ω; input to VGAs, 20mVp-p at 1MHz tone, set VAGC = 1.25V, unless otherwise noted.)
MAX2700/MAX2701
VGA2
I/Q VOLTAGE GAIN MISMATCH WITH
GAIN CORRECTION
I/Q MISMATCH (dB)
1
TA = +85°C
0
2.3
1.2
0.8
RL = 1.025kΩ
2.2
0.4
0dB INPUT MISMATCH
GAIN CORRECTION DISABLED
1.00
1.25
1.50
1.75
2.00
RL = 0.1kΩ
0.75
1.00
1.25
1.50
1.75
2.00
0.75
1.00
1.25
1.50
1.75
2.00
AGC (V)
AGC (V)
VGA2
BANDWIDTH vs. RS
VGA2
Q TO I CROSSTALK vs. RL
COMBINED VGA1 AND VGA2 TURN-ON TIME
vs. DC OFFSET CAPACITANCE*
-35
Q TO I CROSSTALK (dB)
3dB BANDWIDTH
60
-40
-45
-50
40
1dB BANDWIDTH
1.2
1.4
RS (kΩ)
1.6
1.8
2.0
300
200
0
-60
1.0
400
100
-55
20
500
MAX2700/1-50
-30
MAX2700/1-48
80
0.8
2.0
AGC (V)
100
0.6
RL = 0.56kΩ
RL = 0.25kΩ
1.8
0.50
TURN-ON TIME (µs)
0.75
MAX2700/1-49
0.50
2.1
1.9
0
-1
MAX2700/1-47
1.6
TA = +25°C
2
2dB INPUT MISMATCH
GAIN CORRECTION ENABLED
V01 (PEAK-TO-PEAK V)
TA = -45°C
I/Q VOLTAGE GAIN (dB)
2.0
MAX2700/1-45
3
VGA2
VGA OUTPUT 1dB COMPRESSION
POINT vs. AGC VOLTAGE vs. RL
MAX2700/1-46
VGA2
I/Q VOLTAGE GAIN MISMATCH
vs. TEMPERATURE
VGA2 BANDWIDTH (MHz)
MAX2700/MAX2701
1.8GHz to 2.5GHz Direct Downconversion
Receivers
100
300
500
700
RL (Ω)
900
1100
0
25
50
75
100
DC OFFSET CAPACITANCE (nF)
*C19, C23, C30, C36 in the
EV kit schematic in Figure 3
represent DC offset capacitors.
Time from SHDN = GND to
SHDN = VCC, until DC quiescent
point settles within 10% of static
DC quiescent point.
16
______________________________________________________________________________________
1.8GHz to 2.5GHz Direct Downconversion
Receivers
PIN
NAME
FUNCTION
1
CEXT-
Inverting Input Port of VGA2 I/Q Gain Imbalance Correction Circuitry. Connect an
external capacitor between CEXT- and CEXT+ to activate the circuit. Short CEXT- to
CEXT+ to disable.
2
CEXT+
Noninverting Input Port of VGA2 I/Q Gain Imbalance Correction Circuitry. Connect an
external capacitor between CEXT+ and CEXT- to activate the circuit. Short CEXT- to
CEXT+ to disable.
3, 12, 17, 29, 38,
48
VCC
4
X2_EN
5, 7, 8, 13, 15,
32, 44, 46
GND
6
LNAIN
9
GAIN_SET
10
SHDN
11
AGC
Automatic Gain-Control Input for AGC. Bypass this pin with a 1000pF capacitor to
GND to minimize coupling.
14
LNAOUT
LNA Output. This pin requires an external pullup inductor and off-chip 50Ω match.
16
MIX_Q
Mixer Q-Channel Baseband Output. Connect external series capacitor to AC-couple
the output to the load.
18
QIN1+
Noninverting VGA1, Q-Channel Baseband Input
19
QIN1-
Inverting VGA1, Q-Channel Baseband Input
20
DCQ1+
Noninverting Offset Correction Input for Q-Channel VGA1 Amplifier
21
DCQ1-
Inverting Offset Correction Input for Q-Channel VGA1 Amplifier
22
QOUT1
Q-Channel VGA1 Amplifier Baseband Output
23
MIXTNK
Inductive Common-Mode Degeneration Pin for Mixer Stages
24
QIN2+
Noninverting VGA2, Q-Channel Baseband Input
25
QIN2-
Inverting VGA2, Q-Channel Baseband Input
26
DCQ2+
Noninverting Offset Correction Input for Q-Channel VGA2 Amplifier
27
DCQ2-
Inverting Offset Correction Input for Q-Channel VGA2 Amplifier
28
QOUT2
Q-Channel VGA2 Amplifier Baseband Output
30
RFIN+
I/Q Mixers Inverting Input. For narrow frequency bands between 1.8GHz and 2.5GHz,
port must be matched using external matching components.
Supply Voltage. Bypass VCC to GND with capacitors as close to pin as possible.
Logic-Level Enable for Doubler Circuitry. Drive logic low to turn on the doubler
(fLO = fRFIN/2). Drive logic high to bypass the doubler (fLO = fRFIN).
Ground. Connect to ground plane with minimal inductance.
LNA Input. Connect to GND to turn the LNA off. Off-chip 50Ω match required.
LNA Gain Select Input. Drive logic high to select the high-gain mode. Drive logic low to
select low-gain mode.
Shutdown Control Input. Drive logic low to enable shutdown mode.
______________________________________________________________________________________
17
MAX2700/MAX2701
Pin Description
1.8GHz to 2.5GHz Direct Downconversion
Receivers
MAX2700/MAX2701
Pin Description (continued)
PIN
NAME
FUNCTION
31
RFIN-
I/Q Mixers Noninverting Input. For narrow frequency bands between 1.8GHz and
2.5GHz, port must be matched using external matching components.
33
IOUT2
I-Channel VGA2 Baseband Output
34
DCI2-
Inverting Offset Correction Input for I-Channel VGA2 Amplifier
35
DCI2+
Noninverting Offset Correction Input for I-Channel VGA2 Amplifier
36
IIN2-
Inverting VGA2, I-Channel Baseband Input
37
IIN2+
Noninverting VGA2, I-Channel Baseband Input
39
IOUT1
I-Channel VGA1 Amplifier Baseband Output
40
DCI1-
Inverting Offset Correction Input for I-Channel VGA1 Amplifier
41
DCI1+
Noninverting Offset Correction Input for I-Channel VGA1 Amplifier
42
IIN1-
Inverting VGA1, I-Channel Baseband Input
43
IIN1+
Noninverting VGA1, I-Channel Baseband Input
45
MIX_I
Mixer I-Channel Baseband Output. Connect external series capacitor to AC-couple the
output to the load.
47
LO
LO Input. Internally matched to 50Ω.
Detailed Description
The MAX2700/MAX2701 consist of five major blocks:
LNA, I/Q direct demodulator, VGAs, gain correction,
and bias circuits.
Low-Noise Amplifier
The LNA is a two-gain-level amplifier with low noise figure and high IIP3. Connect GAIN_SET to GND to switch
the amplifier to a low-gain mode that provides an accurate gain step. High IIP3 minimizes the cross-modulation between TX power leakage and close-in interferers
at the RX input. The LNA can be turned off independent
of the other functional blocks by connecting LNAIN to
GND. External matching is required to match the input
and output to 50Ω. The LNA in Figures 1 and 2 is
matched to 1960MHz and 2400MHz over a narrow
bandwidth.
I/Q Demodulator
The direct I/Q demodulator downconverts the RF signal
directly to baseband I and Q signals. This architecture’s main advantage is that the received signal is
amplified and filtered at baseband rather than at some
high intermediate frequency. This eliminates the need
for an expensive IF SAW filter and the IF oscillator.
18
Furthermore, the direct conversion scheme eliminates
the need for image rejection, thereby relaxing the
bandpass filter selectivity requirements following the
LNA. The direct downconverter consists of highly linear
double-balanced I/Q mixers, an LO frequency doubler
option, an LO quadrature generator, and baseband I/Q
buffer amplifiers driven by the mixers’ outputs.
In a direct downconversion receiver, I/Q mixers have
more stringent requirements on mixer output linearity
since they need to handle large voltage swings at
baseband due to close-in interferers. The RF signal is
applied to the differential input (RFIN+, RFIN-) of the
direct downconversion receiver through an off-chip
balun. The differential input structure results in a higher
common-mode rejection for second-order nonlinearity
generated in the receiver’s front end. The differential
input requires matching to appropriate impedance of
the balun. Some applications may require a bandpass
filter between the LNA and the mixer, as shown in
Figures 1 and 2, to attenuate the residual transmit
power leakage and out-of-band spurious signals.
The mixer baseband buffers amplify the mixer I and Q
differential outputs and convert them to single-ended
outputs (MIX_I, MIX_Q). These buffer amplifiers have
______________________________________________________________________________________
1.8GHz to 2.5GHz Direct Downconversion
Receivers
IOUT2
QOUT2
AGC2 I_CHANNEL
AGC2 Q_CHANNEL
IIN2IIN2+
VGA CONTROL
QIN2QIN2+
OFFSET CORRECTION
LOOP
IOUT1
AGC1 I_CHANNEL
OFFSET CORRECTION
LOOP
QOUT1
AGC1 Q_CHANNEL
IIN1IIN1+
QIN1QIN1+
OFFSET CORRECTION
LOOP
MIX_I
OFFSET CORRECTION
LOOP
AMP
I_CHANNEL
DOUBLE BALANCED
MIXER
RFINRFIN+
Q_CHANNEL
Q_CHANNEL
I_CHANNEL
MIX_Q
AMP
X2_EN
MULTIPLEXER
X2
POLYPHASE RC
QUADRATURE
GENERATOR
BIAS
BLOCK
DOUBLER
LO
LD GENERATOR
BIAS
BIAS
HIGH-GAIN AMP
LNA BLOCK
MST
SHDN
LNAOUT
LOW-GAIN AMP
SHDN
very low output impedance (<2Ω). The smallest load
that should be used is 600Ω. At the output of the I/Q
mixers’ buffers, baseband lowpass filters should be
used to provide adjacent and alternate channel selectivity. This reduces the level of adjacent channel and
close-in interferers to the input of the following baseband amplifier.
The LO signal is applied externally to the LO input port.
An LO doubler circuit doubles the LO signal frequency
LNAIN
GAIN_SET
before it is applied to the mixer LO port. Connect
X2_EN to ground to enable the LO doubler circuit. With
this circuit enabled, the required LO frequency is half
that of the RF carrier frequency. Connect X2_EN to VCC
to disable the frequency doubler circuit and the LO frequency is the same as the RF carrier frequency. The
half LO frequency scheme results in the use of lower
frequency and lower cost VCOs. It also reduces the LO
leakage to the receiver’s input. The mixer is guaranteed
______________________________________________________________________________________
19
MAX2700/MAX2701
Functional Diagram
FROM
TRANSMITTER
DUPLEXER
100pF
1000pF
RX ENABLE
LNA GAIN
SELECT
4.7nH
BPF
AGC
0.01µF
DOUBLER
ENABLE/DISABLE
GND
GND
LNAIN
GND
X2_EN
VCC
CEXT+
CEXT-
68pF
VCC
VCC
22pF
100pF
AGC
SHDN
GAIN_SET
68pF
6pF
68pF
CEXT
0.1µF
12
11
10
9
8
7
6
5
4
3
2
1
21
20
19
18
17
16
15
14
13
1
100pF
1.5nH
LPF_Q1
1k
0.056µF
X2
O
O/I
40
41
48
42
47
VCC
Figure 1. MAX2700 Typical Operating Circuit (1960MHz)
______________________________________________________________________________________
0.01µF
2.2k
680Ω
0.1µF 0.1µF
CTRL 1
MAX2700
43
44
45
46
LO
0.1µF
GND
GND
68pF
680Ω
1k
0.056µF
39
IOUT1
22
38
24
1k
680Ω
0.56µF
22pF
22pF
0.1µF
2.2k
0.1µF
QIN2680Ω
TO ALL
VCC PINS
VCC
68pF
I-CHANNEL
LOAD
Q-CHANNEL
LOAD
Q2
1pF
4.7nH
4.7nH
50Ω
50Ω
0.1µF
0.1µF
DCQ2- 0.56µF
0.1µF
DCQ2+
QOUT2
VCC
RFIN+
RFIN-
GND
IOUT2
DCI2-
DCI2+
IIN2-
LPF_Q2
25
26
27
28
29
30
31
32
33
34
35
36
0.1µF
2.2k
LPF_2
37
0.056µF
23
CTRL 2
I/Q
DETECT
0.1µF 0.1µF
MIX_I
MIX_Q
0.056µF
GND
1k
VCC
LO
INPUT
QIN1+
GND
IIN1+
2.2k
DCI1+
IIN1-
LPF_1
DCI1-
QIN1-
LNAOUT
VCC
DCQ1QOUT1
5pF MIXTNK
IIN2+
5.6nH QIN2+
20
DCQ1+
68pF
1000pF
10µF
T-LINE
BALUN
RF
INPUT
MAX2700/MAX2701
1.8GHz to 2.5GHz Direct Downconversion
Receivers
FROM
TRANSMITTER
DUPLEXER
RX ENABLE
LNA GAIN
SELECT
10pF
BPF
1000pF
AGC
0.01µF
1000pF
0.5pF
DOUBLER
ENABLE/DISABLE
GND
GND
LNAIN
GND
X2_EN
VCC
CEXT+
CEXT-
VCC
2pF
68pF
22pF
100pF
AGC
SHDN
GAIN_SET
68pF
1nH
68pF
CEXT
0.1µF
100pF
2.7nH
LPF_Q1
1k
0.056µF
21
20
19
18
17
16
14
IIN1-
0.01µF
2.2k
VCC
680Ω
1k
0.056µF
37
22
24
23
CTRL 2
1k
680Ω
22pF
22pF
0.56µF
50Ω
50Ω
0.1µF
0.1µF
0.1µF
2.2k
0.1µF
QIN2680Ω
DCQ2- 0.56µF
0.1µF
DCQ2+
QOUT2
VCC
RFIN+
RFIN-
GND
IOUT2
DCI2-
DCI2+
IIN2-
LPF_Q2
25
26
27
28
29
30
31
32
33
34
35
36
0.1µF
2.2k
LPF_2
38
I/Q
DETECT
39
0.056µF
0.1µF 0.1µF
CTRL1
MAX2701
41
15
13
I/O
X2
O 1
40
DCI1+
42
48
43
44
45
46
47
VCC
VCC
12
11
10
9
8
7
6
5
4
3
2
1
LO
0.1µF
GND
GND
68pF
MIX _I
MIX_Q
680Ω
0.1µF 0.1µF
VCC
0.056µF
GND
1k
QIN1+
DCI1-
LO
INPUT
QIN1-
GND
IOUT1
DCQ1QOUT1
IIN1+
2.2k
3pF
DCQ1+
LNAOUT
VCC
MIXTNK
IIN2+
QIN2+
5.6nH
TO ALL
VCC PINS
Q-CHANNEL
LOAD
Q2
0.5pF
2.7nH
2.7nH
I2
VCC
68pF
I-CHANNEL
LOAD
68pF
1000pF
10µF
T-LINE
BALUN
RF
INPUT
MAX2700/MAX2701
LPF_1
1.8GHz to 2.5GHz Direct Downconversion
Receivers
Figure 2. MAX2701 Typical Operating Circuit (2400MHz)
______________________________________________________________________________________
21
VCC
VCC
Figure 3. MAX2700/MAX2701 EV kit Schematic
______________________________________________________________________________________
J4
VCC
R4 J2
0Ω
R3
0Ω
() ARE FOR MAX2701EV KIT ONLY.
R10 J5
0Ω
R9
0Ω
R8 J4
0Ω
R7
0Ω
VCC
X2EN
Z1
4.7nH
(0.5pF)
R12
0Ω
R11
100Ω
R6
100Ω
R5
100Ω
C45
1000pF
R45
0Ω
C9
0.01µF
Z4
6pF
(1nH)
R2
100Ω
R1
0Ω
VCC
C4
10µF
VCC
J1
+
C5
0Ω
(10pF)
J20
J19
1 CEXT-
8
7
6
5
4
3
GND
GND
LNAIN
GND
X2_EN
VCC
C11
68pF
9
GAIN_SET
C6
1000pF
10
SHDN
C7
1000pF
11 AGC
C8
100pF
12
VCC
C10
68pF
C3
1000pF
C2
68pF
C41
OPEN
L7
0Ω
C42
OPEN
C48
OPEN
C1
0.01µF
2 CEXT+
C43
68pF
R40
0Ω
VCC
C46
68pF
C47
OPEN
VCC 48
GND
C13
(2pF)
OPEN
L3
13
LO 47
14 LNAOUT
C40
22pF
J6
C12
22pF
R13
1k
C15
0.56µF
GND
R38
1k
R39
1k
46
GND
GND
15
45
C39
0.56µF
R36
1.1k
C14 C16
100pF 0.1µF
C17
0.1µF
J7
R14
1k
VCC R15
0Ω
MIX_I
16 MIX_Q
44
GND
17 V
CC
J16
43
U1
C38
0.1µF
R37
3.6k
R44
51Ω
R16
1.1k
C36
C37
0.1µF 0.1µF
R35
820Ω
C18
0.1µF
C19
0.1µF
R41
51Ω
R18
820Ω
R17
3.6k
J8
MAX2700
MAX2701
IIN1+
18 QIN1+
J17
C35
0.56µF
R33
1.1k
J15
R19
1k
C20
0.56µF
R30
1.1k
C33 C34
100pF 0.1µF
R32
0Ω
VCC
R34
1k
J9
R20
1k
C49
5pF
(3pF)
IIN119 QIN1-
J18
20 DCQ1+
VCC
DCI1+
42
DCI121 DCQ1-
41
22 QOUT1
40
IOUT1
38
VCC
23 MIXTNK
2
1
C32
0.1µF
R31
3.6k
R43
51Ω
R22
1.1k
L4
5.6nH
C31
0.1µF
25
26
27
28
J10
R42
51Ω
R21
3.6k
C22
0.1µF
R28
51Ω
R23
820Ω
C23
0.1µF
C24
0.56µF
R26
0Ω
L6
4.7nH
(2.7nH)
L5
4.7nH
(2.7nH)
R27
51Ω
C30
0.1µF
R29
820Ω
C25
68pF
C27
22pF
C26
29 22pF
30
31
C29
32 0.56µF
33
34
35
36
C21
0.1µF
QIN2-
DCQ2+
DCQ2-
QOUT2
VCC
RFIN+
RFIN-
GND
IOUT2
DCI2-
DCI2+
IIN2-
J14
37
IIN2+
24 QIN2+
22
39
R24
51Ω
VCC
R25
51Ω
4
3
1
C28
1pF
2
(5pF)
BALUN/TOKO/B4F
5
J13
J11
J12
MAX2700/MAX2701
1.8GHz to 2.5GHz Direct Downconversion
Receivers
1.8GHz to 2.5GHz Direct Downconversion
Receivers
Variable Gain Amplifier (VGA)
The AGC in each baseband channel I/Q is implemented by two variable gain amplifiers with equal gains.
Each amplifier provides about 40dB voltage gain at the
maximum setting and 30dB of gain control. The first
baseband VGA (VGA1) is a cascaded wideband amplifier with differential input and single-ended output. It is
optimized for low noise in the high-gain state and has
low-power dissipation and sufficient linearity in all gain
settings to ensure desired compression performance.
The second baseband VGA (VGA2) is a multistage
wideband amplifier with differential inputs and a singleended output. In each channel, connect a baseband
lowpass filter between VGA1 and VGA2 to provide
additional channel selectivity at the adjacent channel. If
the VGA amplifiers are driven single ended, the complementary input of VGA should be AC-coupled to
ground through a matched source impedance.
VGA Offset Correction
An internal offset correction feedback amplifier associated with each VGA removes the DC offsets present in
the VGAs. Offset correction preserves maximum output
compression performance during maximum gain conditions. Each offset correction loop effectively AC-couples the associated VGA signal path. Each VGA1
network yields a highpass corner frequency according
to the following:
f-3dB (Hz) = 5300 / CDC (nF) (VAGC = 2.0V)
f-3dB (Hz) = 700 / CDC (nF) (VAGC = 0.5V)
where C DC is the value of the capacitors, in nanofarads, across DCI1+, DCI1- and DCQ1+, DCQ1-. Note
that the corner frequency is a function of the gain setting, increasing with increasing gain. Each VGA2 network provides a highpass corner frequency predicted
by the following:
f-3dB (Hz) = 145 / CDC (µF)
where CDC is the value of the capacitors, in microfarads, across DCI2+, DCI2- and DCQ2+, DCQ2-.
The time constants associated with the offset correction
networks limit turn-on time. For applications where the
turn-on time is critical, the offset correction networks
can be disabled by shorting the corresponding pins
together (DCI1+ to DCI1-, DCQ1+ to DCQ1-, DCI2+ to
DCI2-, and DCQ2+ to DCQ2-).
VGA2 I/Q Gain Mismatch Correction
The signal amplitudes at the outputs of the I- and Qchannel VGA2 amplifiers are compared, and any difference is corrected by a differential feedback network
associated with the gain control circuitry. Differential
amplitude information is extracted by use of a single
external capacitor across pins 1 and 2 (CEXT- and
CEXT+). The residual difference signal is amplified and
fed back to the gain control network, increasing the
gain of the channel with the smaller signal while
decreasing the gain of the larger signal’s channel. This
network will correct amplitude mismatches generated
by gain mismatches in the previous stages of the
receiver (the mixer and VGA1), as well as insertion-loss
mismatch. The correction network is capable of
decreasing up to 2dB of amplitude mismatch at the
inputs of the I/Q VGA2 amplifiers to <0.5dB amplitude
mismatch. The gain correction network can be disabled
by shorting CEXT- to CEXT+.
Bias Circuit
Operate the MAX2700/MAX2701 in shutdown mode by
connecting SHDN to GND, reducing current consumption to 20µA. In shutdown mode, bias current to all the
blocks is turned off through a master shutdown circuit.
In applications where the LNA is not used, turn off the
LNA by connecting the LNAIN to ground.
Applications Information
LNA Matching
The MAX2700/MAX2701 are designed to operate from
1.8GHz to 2.1GHz and 2.1GHz to 2.5GHz, respectively.
The LNAs in Figures 1 and 2 are optimized for noise
figure and gain centered around 1960MHz and
2400MHz, respectively. Operation at other frequencies
in the band requires reoptimization of the input and output matching circuits. The noise figure is sensitive to
input matching and losses in the input traces. LNA
input matching should be optimized for desired noise
figure, gain, and VSWR performance. High Q matching
elements should be used at the LNA input. Proper
board layout is essential to increase the isolation
between LO and the LNA input. This minimizes LO
leakage and thus DC offset.
I/Q Demodulator Input Matching
The RF input match of the I/Q demodulator in Figure 1
and 2 are optimized for 1960MHz and 2400MHz operation, respectively. For operation at a different frequency,
the matching circuit should be reoptimized. Singleended operation at the demodulator is achieved through
the use of an off-chip balun transformer. In Figure 1, the
balun, inductors, and capacitors constitute the matching
circuit of the differential I/Q demodulator input.
______________________________________________________________________________________
23
MAX2700/MAX2701
to operate without degrading its performance over the
LO power range of -10dBm to -16dBm. The quadrature
generator consists of a wideband polyphase network.
Each output of the polyphase filter is buffered, amplified, and then fed to the mixer’s differential LO port.
MAX2700/MAX2701
1.8GHz to 2.5GHz Direct Downconversion
Receivers
I/Q Mixer and VGA1
Output Load Requirements
To retain acceptable linearity performance, the mixer
and VGA1 output loads should be >600Ω.
Layout Issues
A properly designed PC board is an essential part of
any RF/microwave circuit. Use controlled impedance
lines on all frequency inputs and outputs. Use lowinductance connections to ground on all ground pins
and wherever the components are connected to
ground. Place decoupling capacitors close to all VCC
connections. For proper chip operation, the metal paddle at the back of the chips must be grounded through
via holes in the board.
Table 1. MAX2700 LNA S-Parameters High-Gain Mode (VCC = 3.0V)
FREQUENCY (GHz)
|S11|
∠S11
|S21|
∠S21
|S12|
∠S12
|S22|
1.70
0.542
-84.1
7.09
53.97
0.023
65.36
0.367
∠S22
37.3
1.75
0.485
-82.9
7.412
41.4
0.025
46.6
0.286
11.4
1.80
0.471
-80.1
7.268
29.5
0.024
34.3
0.216
-23.1
1.85
0.466
-78.8
7.07
19.9
0.0243
29.6
0.185
-68.4
1.90
0.443
-79.2
6.977
10.1
0.025
22.5
0.217
-99.5
1.95
0.441
-79.3
6.635
0.2
0.025
13.8
0.306
-127
2.00
0.436
-84.8
6.115
-7.96
0.024
16.4
0.387
-152.8
2.05
0.324
-88.3
6.119
-13.47
0.0338
15.23
0.408
-165
2.10
0.288
-74.9
5.947
-22.7
0.0383
-4.813
0.476
-176.7
2.15
0.300
-66.7
5.687
-31.1
0.0387
-20.7
0.529
172
2.20
0.320
-63.1
5.31
-40.5
0.0384
-32.8
0.587
162.4
Table 2. MAX2700 LNA S-Parameters Low-Gain Mode (VCC = 3.0V)
FREQUENCY (GHz)
1.70
|S11|
0.637
∠S11
-65.6
|S21|
0.731
∠S21
52.5
|S12|
0.018
∠S12
77
|S22|
0.398
∠S22
41.5
1.75
0.625
-66.3
0.763
42.9
0.018
52
0.328
21.8
1.80
0.622
-67.1
0.772
31.3
0.016
40
0.258
-7
1.85
0.618
-67.3
0.76
21.2
0.014
39
0.191
-45
1.90
0.617
-67
0.758
10.3
0.014
38
0.203
-79
1.95
0.617
-69.2
0.717
-1.1
0.015
34
0.238
-114
2.00
0.616
-70.1
0.678
-10.7
0.014
24
0.332
-141
2.05
0.611
-71.8
0.603
-13
0.022
37.6
0.323
-105
2.10
0.611
-74.5
0.634
-19.5
0.028
13.4
0.36
-170
2.15
0.61
-76.8
0.634
0.27
0.03
-5
0.402
-178
2.20
0.6
-80
0.621
-37
0.033
-14
0.484
174
24
______________________________________________________________________________________
1.8GHz to 2.5GHz Direct Downconversion
Receivers
MAX2700/MAX2701
Table 3. MAX2701 LNA S-Parameters High-Gain Mode (VCC = 3.0V)
FREQUENCY (GHz)
|S11|
∠S11
|S21|
∠S21
|S12|
∠S12
|S22|
∠S22
2.10
0.303
-110
6.71
-32.9
0.036
-28.1
0.563
-162.5
2.15
0.283
-108
6.35
-42.7
0.04
-42.6
0.61
-178
2.20
0.269
-108
5.98
-49.8
0.042
-55
0.63
168.4
2.25
0.260
-109
5.7
-56.6
0.042
-67.4
0.64
155.4
2.30
0.254
-111
5.37
-63.4
0.043
-80
0.64
144
2.35
0.250
-114.6
5.08
-69.7
0.043
-92
0.632
134.4
2.40
0.241
-120
4.82
-75.7
0.04
-104
0.626
127
2.45
0.230
-129
4.55
-81.5
0.037
-114
0.625
121
2.50
0.218
-139
4.37
-87
0.035
-122
0.635
116
|S22|
Table 4. MAX2701 LNA S-Parameters Low-Gain Mode (VCC = 3.0V)
0.589
∠S11
-102.2
0.684
∠S21
-36.2
0.025
∠S12
-10.36
0.46
∠S22
-157
0.59
-106.12
0.662
-45.2
0.029
-21.6
0.49
-172
2.20
0.591
-111.15
0.644
-52.8
0.032
-35.3
0.51
176.7
2.25
0.596
-117.3
0.63
-60.4
0.033
-50.4
0.54
165
2.30
0.594
-125.2
0.621
-69
0.036
-62.2
0.56
154.5
2.35
0.58
-134
0.608
-77.8
0.037
-76.5
0.58
145.2
2.40
0.548
-144
0.589
-87.8
0.038
-96
0.6
136.5
2.45
0.506
-154.4
0.556
-98
0.035
-109
0.62
129
2.50
0.469
-164
0.519
-107
0.029
-120
0.63
122
FREQUENCY (GHz)
|S11|
2.10
2.15
|S21|
Table 5. MAX2700 Mixer RFIN+ Input
S-Parameters (VCC = 3.0V)
|S12|
Table 6. MAX2701 Mixer RFIN+ Input
S-Parameters (VCC = 3.0V)
FREQUENCY (GHz)
|S11|
∠S11
FREQUENCY (GHz)
|S11|
∠S11
1.70
0.612
-101.2
2.10
0.590
-152
1.75
0.637
-105
2.15
0.600
-161
1.80
0.624
-111.5
2.20
0.604
-171
1.85
0.615
-116
2.25
0.619
180
1.90
0.607
-121
2.30
0.634
171
1.95
0.603
-128
2.35
0.651
162.7
2.00
0.598
-135
2.40
0.663
154
2.45
0.675
147
2.50
0.690
142
______________________________________________________________________________________
25
MAX2700/MAX2701
1.8GHz to 2.5GHz Direct Downconversion
Receivers
Table 7. MAX2700 LO Input S-Parameters
(X2_EN = 1, X2_EN = 0)
DOUBLER DISABLED
X2_EN = VCC
FREQUENCY
(GHz)
|S11|
DOUBLER ENABLED
X2_EN = 0
∠S11 FREQUENCY
(GHz)
|S11| ∠S11
Table 8. MAX2701 LO Input S-Parameters
(X2_EN = 1, X2_EN = 0)
DOUBLER DISABLED
X2_EN = VCC
FREQUENCY
(GHz)
|S11|
DOUBLER ENABLED
X2_EN = 0
∠S11 FREQUENCY
(GHz)
1.70
0.03
92
850
0.479
-50.6
2.10
0.257
160
1.05
0.358
-53.4
1.75
0.053
116
875
0.474
-50.1
2.15
0.279
164
1.10
0.341
-53
1.80
0.086
123
900
0.466
-51.6
2.20
0.299
167
1.15
0.32
-52
1.85
0.108
127
925
0.456
-52
2.25
0.314
171
1.20
0.299
-52
1.90
0.135
128
950
0.442
-52
2.30
0.33
174
1.25
0.268
-51
1.95
0.161
132
975
0.424
-53
2.35
0.347
178
—
—
—
2.00
0.186
136
1000
0.403
-53.6
2.40
0.357
-179
—
—
—
—
—
—
1025
0.384
-54
2.45
0.366
-175
—
—
—
-54
2.50
0.373
-171
—
—
—
—
—
—
1050
0.365
Chip Information
TRANSISTOR COUNT: 3307
26
|S11| ∠S11
______________________________________________________________________________________
1.8GHz to 2.5GHz Direct Downconversion
Receivers
48L,TQFP.EPS
______________________________________________________________________________________
27
MAX2700/MAX2701
Package Information
MAX2700/MAX2701
1.8GHz to 2.5GHz Direct Downconversion
Receivers
Package Information (continued)
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.
28 ____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600
© 2000 Maxim Integrated Products
Printed USA
is a registered trademark of Maxim Integrated Products.