General Description
The MAX2016 dual logarithmic detector/controller is a
fully integrated system designed for measuring and
comparing power, gain/loss, and voltage standing-wave
ratio (VSWR) of two incoming RF signals. An internal
broadband impedance match on the two differential RF
input ports allows for the simultaneous monitoring of sig-
nals ranging from low frequency to 2.5GHz.
The MAX2016 uses a pair of logarithmic amplifiers to
detect and compare the power levels of two RF input
signals. The device internally subtracts one power level
from the other to provide a DC output voltage that is pro-
portional to the power difference (gain). The MAX2016
can also measure the return loss/VSWR of an RF signal
by monitoring the incident and reflected power levels
associated with any given load. A window detector is
easily implemented by using the on-chip comparators,
OR gate, and 2V reference. This combination of circuitry
provides an automatic indication of when the measured
gain is outside a programmable range. Alarm monitoring
can thus be implemented for detecting high-VSWR
states (such as open or shorted loads).
The MAX2016 operates from a single +2.7V to +5.25V*
power supply and is specified over the extended -40°C
to +85°C temperature range. The MAX2016 is available
in a space-saving, 5mm x 5mm, 28-pin thin QFN.
Applications
Return Loss/VSWR Measurements
Dual-Channel RF Power Measurements
Dual-Channel Precision AGC/RF Power Control
Log Ratio Function for RF Signals
Remote System Monitoring and Diagnostics
Cellular Base Station, Microwave Link, Radar,
and other Military Applications
RF/IF Power Amplifier (PA) Linearization
Features
Complete Gain and VSWR Detector/Controller
Dual-Channel RF Power Detector/Controller
Low-Frequency to 2.5GHz Frequency Range
Exceptional Accuracy Over Temperature
High 80dB Dynamic Range
2.7V to 5.25V Supply Voltage Range*
Internal 2V Reference
Scaling Stable Over Supply and Temperature
Variations
Controller Mode with Error Output
Available in 5mm x 5mm, 28-Pin Thin QFN
Package
*See Power-Supply Connection section.
MAX2016
LF-to-2.5GHz Dual Logarithmic Detector/
Controller for Power, Gain, and VSWR Measurements
________________________________________________________________ Maxim Integrated Products 1
FA1 1
VCC 2
RFINA+ 3
RFINA- 4
GND 5
COUTH 6
CSETH 7
FB121
VCC
20
RFINB+19
RFINB-18
GND17
COUTL16
CSETL15
COR
8
VCC
9
SETD
10
OUTD
11
VCC
12
FV2
13
FV1
14
FA2
28
OUTA
27
SETA
26
REF
25
SETB
24
OUTB
23
FB2
22
MAX2016
THIN QFN
Pin Configuration
Ordering Information
19-3404; Rev 1; 10/06
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.
EVALUATION KIT
AVAILABLE
PART TEMP RANGE PIN-
PACKAGE
PKG
CODE
MAX2016ETI -40°C to +85°C28 Thi n QFN - E P *,
b ul kT2855-3
MAX2016ETI-T -40°C to +85°C28 Thi n QFN - E P *,
T/R T2855-3
MAX2016ETI+D -40°C to +85°C28 Thi n QFN - E P *,
l ead fr ee, b ul kT2855-3
MAX2016ETI+TD -40°C to +85°C28 Thi n QFN - E P *,
l ead fr ee, T/R T2855-3
*EP = Exposed pad.
+Indicates lead-free package.
D= Dry pack.
Typical Application Circuit appears at end of data sheet.
MAX2016
LF-to-2.5GHz Dual Logarithmic Detector/
Controller for Power, Gain, and VSWR Measurements
2 _______________________________________________________________________________________
ABSOLUTE MAXIMUM RATINGS
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.
VCC to GND.........................................................-0.3V to +5.25V
Input Power Differential (RFIN_+, RFIN_-)......................+23dBm
Input Power Single Ended (RFIN_+ or RFIN _-) .............+19dBm
All Other Pins to GND.................................-0.3V to (VCC + 0.3V)
Continuous Power Dissipation (TA= +70°C)
28-Pin, 5mm x 5mm Thin QFN (derate 35.7mW/°C
above +70°C)..................................................................2.8W
Operating Temperature Range ...........................-40°C to +85°C
Junction Temperature......................................................+150°C
Storage Temperature Range .............................-65°C to +150°C
Lead Temperature (soldering, 10s) .................................+300°C
DC ELECTRICAL CHARACTERISTICS
(VCC = +2.7V to +3.6V, R1= R2= R3= 0Ω, TA= -40°C to +85°C, unless otherwise noted. Typical values are at VCC = +3.3V,
CSETL = CSETH = VCC, 50ΩRF system, TA= +25°C, unless otherwise noted.) (Note 1)
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
POWER SUPPLY
VSR6 = 0Ω2.7 3.3 3.6
Supply Voltage VSR6 = 37.4Ω4.75 5 5.25 V
Total Supply Current ICC 43 55 mA
Measured in each pin 2 and pin 20 16
Measured in pin 9 2
Supply Current
Measured in pin 12 9
mA
INPUT INTERFACE
Input Impedance Differential impedance at RFINA and RFINB 50 Ω
Resistance at SETD 20
Input Resistance R Resistance at SETA and SETB 40 kΩ
DETECTOR OUTPUT
Source Current Measured at OUTA, OUTB, and OUTD 4 mA
Sink Current Measured at OUTA, OUTB, and OUTD 0.45 mA
Minimum Output Voltage Measured at OUTA, OUTB, and OUTD 0.5 V
Maximum Output Voltage Measured at OUTA, OUTB, and OUTD 1.8 V
Difference Output VOUTD PRFINA = PRFINB = -30dBm 1 V
OUTD Accuracy ±12 mV
COMPARATORS
Output High Voltage VOH RLOAD 10kΩVCC -
10mV V
Output Low Voltage VOL RLOAD 10kΩ10 mV
Input Voltage Measured at CSETL and CSETH GND to
VCC V
Input Bias Current CSETL and CSETH 1 nA
REFERENCE
Output Voltage on Pin 25 RLOAD 2kΩ2V
Load Regulation Source 2mA -5 mV
MAX2016
LF-to-2.5GHz Dual Logarithmic Detector/
Controller for Power, Gain, and VSWR Measurements
_______________________________________________________________________________________ 3
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
RF Input Frequency Range fRF AC-coupled input 2.5 GHz
Return Loss S11 0.1GHz to 3GHz 20 dB
Large-Signal Response Time PRFIN = no signal to 0dBm, ±0.5dB settling
accuracy 100 ns
RSSI MODE—0.1GHz
RF Input Power Range (Note 2) -70 to
+10 dBm
±3dB Dynamic Range TA = -20°C to +85°C (Note 3) 80 dB
Range Center -32 dBm
TA = +25°C to +85°C +0.0083
Temperature Sensitivity PRFINA = PRFINB =
-32dBm TA = +25°C to -20°C -0.0083 dB/°C
Slope (Note 4) 19 mV/dB
Typical Slope Variation TA = -20°C to +85°C -4 µV/°C
Intercept (Note 5) -100 dBm
Typical Intercept Variation TA = -20°C to +85°C 0.03 dBm/°C
RSSI MODE—0.9GHz
RF Input Power Range (Note 2) -70 to
+10 dBm
±3dB Dynamic Range TA = -20°C to +85°C (Note 3) 80 dB
Range Center -30 dBm
TA = +25°C to +85°C +0.0083
Temperature Sensitivity PRFINA = PRFINB =
-30dBm TA = +25°C to -20°C -0.0083 dB/°C
Slope (Note 4) 18.1 mV/dB
Typical Slope Variation TA = -20°C to +85°C -4 µV/°C
Intercept (Note 5) -97 dBm
Typical Intercept Variation TA = -20°C to +85°C 0.02 dBm/°C
RSSI MODE—1.9GHz
RF Input Power Range (Note 2) -55 to
+12 dBm
±3dB Dynamic Range TA = -20°C to +85°C (Note 3) 67 dB
Range Center -27 dBm
TA = +25°C to +85°C +0.0125
Temperature Sensitivity PRFINA = PRFINB =
-27dBm TA = +25°C to -20°C -0.0125 dB/°C
Slope (Note 4) 18 mV/dB
Typical Slope Variation TA = -20°C to +85°C -4.8 µV/°C
Intercept (Note 5) -88 dBm
Typical Intercept Variation TA = -20°C to +85°C 0.03 dBm/°C
AC ELECTRICAL CHARACTERISTICS—OUTA AND OUTB
(Typical Application Circuit, VCC = +2.7V to +3.3V, R1= R2= R3= 0Ω, TA= -40°C to +85°C, unless otherwise noted. Typical values
are at VCC = 3.3V, CSETL = CSETH = VCC, TA= +25°C, unless otherwise noted.) (Note 1)
MAX2016
LF-to-2.5GHz Dual Logarithmic Detector/
Controller for Power, Gain, and VSWR Measurements
4 _______________________________________________________________________________________
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
RSSI MODE—2.17GHz
RF Input Power Range (Note 2) -52 to
+12 dBm
±3dB Dynamic Range TA = -20°C to +85°C (Note 3) 64 dB
Range Center -25 dBm
TA = +25°C to +85°C +0.0135
Temperature Sensitivity PRFINA = PRFINB =
-25dBm TA = +25°C to -20°C -0.0135 dB/°C
Slope (Note 4) 17.8 mV/dB
Typical Slope Variation TA = -20°C to +85°C -8 µV/°C
Intercept (Note 5) -81 dBm
Typical Intercept Variation TA = -20°C to +85°C 0.03 dBm/°C
RSSI MODE—2.5GHz
RF Input Power Range (Note 2) -45 to
+7 dBm
±3dB Dynamic Range TA = -20°C to +85°C (Note 3) 52 dB
Range Center -23 dBm
TA = +25°C to +85°C +0.0167
Temperature Sensitivity PRFINA = PRFINB =
-23dBm TA = +25°C to -20°C -0.0167 dB/°C
Slope (Note 4) 17.8 mV/dB
Typical Slope Variation TA = -20°C to +85°C -8 µV/°C
Intercept (Note 5) -80 dBm
Typical Intercept Variation TA = -20°C to +85°C 0.03 dBm/°C
AC ELECTRICAL CHARACTERISTICS—OUTA AND OUTB (continued)
(Typical Application Circuit, VCC = +2.7V to +3.3V, R1= R2= R3= 0Ω, TA= -40°C to +85°C, unless otherwise noted. Typical values
are at VCC = 3.3V, CSETL = CSETH = VCC, TA= +25°C, unless otherwise noted.) (Note 1)
AC ELECTRICAL CHARACTERISTICS—OUTD
(Typical Application Circuit, VCC = +2.7V to +3.3V, R1= R2= R3= 0Ω, TA= -40°C to +85°C, unless otherwise noted. Typical values
are at VCC = 3.3V, CSETL = CSETH = VCC, TA= +25°C, unless otherwise noted.) (Note 1)
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
OUTD Center Point PRFINA = PRFINB 1V
Small-Signal Envelope Bandwidth No external capacitor on pins FV1 and FV2 22 MHz
Small-Signal Settling Time
Any 8dB change on the inputs,
no external capacitor on FV1 and FV2,
settling accuracy is ±0.5dB
150 ns
Large-Signal Settling Time
Any 30dB change on the inputs, no external
capacitor on pins FV1 and FV2, settling
accuracy is ±0.5dB
300 ns
Small-Signal Rise and Fall Time Any 8dB step, no external capacitor on pins
FV1 and FV2 15 ns
MAX2016
LF-to-2.5GHz Dual Logarithmic Detector/
Controller for Power, Gain, and VSWR Measurements
_______________________________________________________________________________________ 5
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
Large-Signal Rise and Fall Time Any 30dB step, no external capacitor on
pins FV1 and FV2 35 ns
0.1GHz PRFINB = -32dBm 80
0.9GHz PRFINB = -30dBm 75
1.9GHz PRFINB = -27dBm 60
2.17GHz PRFINB = -25dBm 55
±1dB Dynamic Range
2.5GHz PRFINB = -23dBm 50
dB
Slope fRF = 0.1GHz to 2.5GHz (A-B) -25 mV/dB
OUTD Voltage Deviation PRFINA = PRFINB = -30dBm, TA =
-20°C to +85°C ±0.25 dB
0.1GHz, PRFINB =
-32dBm 80
0.9GHz, PRFINB =
-30dBm 70
1.9GHz, PRFINB =
-27dBm 55
2.17GHz, PRFINB =
-25dBm 50
±1dB Dynamic Range over
Temperature Relative to Best-Fit
Curve at +25°C
PRFINA is swept ;
TA = -20°C to
+85°C
2.5GHz, PRFINB =
-23dBm 45
dB
Gain Measurement Balance PRFINB = PRFINB = -50dBm to -5dBm, fRF =
1.9GHz 0.2 dB
0.9GHz 90
1.9GHz 65
Channel Isolation
2.5GHz 55
dB
AC ELECTRICAL CHARACTERISTICS—OUTD (continued)
(Typical Application Circuit, VCC = +2.7V to +3.3V, R1= R2= R3= 0Ω, TA= -40°C to +85°C, unless otherwise noted. Typical values
are at VCC = 3.3V, CSETL = CSETH = VCC, TA= +25°C, unless otherwise noted.) (Note 1)
Note 1: The MAX2016 is tested at TA= +25°C and is guaranteed by design for TA= -40°C to +85°C.
Note 2: Typical minimum and maximum range of the detector at the stated frequency.
Note 3: Dynamic range refers to the range over which the error remains within the ±3dB range.
Note 4: The slope is the variation of the output voltage per change in input power. It is calculated by fitting a root-mean-square
straight line to the data indicated by the RF input power range.
Note 5: The intercept is an extrapolated value that corresponds to the output power for which the output voltage is zero. It is calcu-
lated by fitting a root-mean-square straight line to the data.
MAX2016
LF-to-2.5GHz Dual Logarithmic Detector/
Controller for Power, Gain, and VSWR Measurements
6 _______________________________________________________________________________________
Typical Operating Characteristics
(MAX2016 EV kit, VCC = 3.3V, R1= R2= R3= 0Ω, CSETL = CSETH = VCC, TA= +25°C, unless otherwise noted.)
DIFFERENTIAL OUTPUT VOLTAGE
vs. A/B DIFFERENCE
MAX2016 toc01
MAGNITUDE RATIO (dB)
VOUTD (V)
3010-10-30
0.5
1.0
1.5
2.0
2.5
0
-50 50
fIN = 100MHz
PRFINB = -32dBm PRFINA IS SWEPT
TA = -20°C,
+25°C, +85°C
DIFFERENTIAL OUTPUT-VOLTAGE ERROR
vs. A/B DIFFERENCE
MAX2016 toc02
MAGNITUDE RATIO (dB)
ERROR (dB)
3010-10-30
-2
-1
0
1
2
3
-3
-50 50
fIN = 100MHz
PRFINB = -32dBm
NORMALIZED TO DATA
AT +25°C
TA = -20°C
TA = +85°C
DIFFERENTIAL OUTPUT VOLTAGE
vs. A/B DIFFERENCE
MAX2016 toc03
MAGNITUDE RATIO (dB)
VOUTD (V)
3010-10-30
0.5
1.0
1.5
2.0
2.5
0
-50 50
fIN = 900MHz
PRFINB = -30dBm PRFINA IS SWEPT
TA = -20°C,
+25°C, +85°C
DIFFERENTIAL OUTPUT-VOLTAGE ERROR
vs. A/B DIFFERENCE
MAX2016 toc04
MAGNITUDE RATIO (dB)
ERROR (dB)
3010-10-30
-2
-1
0
1
2
3
-3
-50 50
fIN = 900MHz
PRFINB = -30dBm
NORMALIZED TO DATA
AT +25°C
TA = -20°C
TA = +85°C
DIFFERENTIAL OUTPUT VOLTAGE
vs. A/B DIFFERENCE
MAX2016 toc05
MAGNITUDE RATIO (dB)
VOUTD (V)
200-20
0.5
1.0
1.5
2.0
2.5
0
-40 40
fIN = 1900MHz
PRFINB = -27dBm
PRFINA IS SWEPT
TA = -20°C
TA = +25°C
TA = +85°C
DIFFERENTIAL OUTPUT-VOLTAGE ERROR
vs. A/B DIFFERENCE
MAX2016 toc06
MAGNITUDE RATIO (dB)
ERROR (dB)
200-20
-2
-1
0
1
2
3
-3
-40 40
fIN = 1900MHz
PRFINB = -27dBm
NORMALIZED TO DATA
AT +25°C
TA = -20°C
TA = +85°C
MAX2016
LF-to-2.5GHz Dual Logarithmic Detector/
Controller for Power, Gain, and VSWR Measurements
_______________________________________________________________________________________ 7
Typical Operating Characteristics (continued)
(MAX2016 EV kit, VCC = 3.3V, R1= R2= R3= 0Ω, CSETL = CSETH = VCC, TA= +25°C, unless otherwise noted.)
DIFFERENTIAL OUTPUT-VOLTAGE BALANCE
MAX2016 toc11
PRFINA (dBm)
VOUTD (V)
-15-30-45
0.90
0.95
1.00
1.05
1.10
1.15
0.85
-60 0
fIN = 1900MHz
PRFINA = PRFINB + 5dB
PRFINA = PRFINB - 5dB
PRFINA = PRFINB
TA = -20°C
TA = +25°C
TA = +85°C
TA = -20°C
TA = +25°CTA = +85°C
TA = -20°C
TA = +25°C
TA = +85°C
S11 MAGNITUDE
MAX2016 toc12
FREQUENCY (GHz)
MAGNITUDE (dB)
2.52.01.51.00.5
-55
-50
-45
-40
-35
-30
-25
-20
-15
-10
-60
03.0
TA = -20°C
TA = +25°C
TA = +85°C
200-20-40 40
MAX2016 toc09
DIFFERENTIAL OUTPUT VOLTAGE
vs. A/B DIFFERENCE
MAGNITUDE RATIO (dB)
VOUTD (V)
0.5
1.0
1.5
2.0
2.5
0
fIN = 2500MHz
PRFINB = -23dBm PRFINA IS SWEPT
TA = -20°C
TA = +25°C
TA = +85°C
DIFFERENTIAL OUTPUT-VOLTAGE ERROR
vs. A/B DIFFERENCE
MAX2016 toc10
MAGNITUDE RATIO (dB)
ERROR (dB)
200-20
-2
-1
0
1
2
3
-3
-40 40
fIN = 2500MHz
PRFINB = -23dBm
NORMALIZED TO DATA
AT +25°C
TA = -20°C
TA = +85°C
15-5-25-45 35
MAX2016 toc07
DIFFERENTIAL OUTPUT VOLTAGE
vs. A/B DIFFERENCE
MAGNITUDE RATIO (dB)
VOUTD (V)
0.5
1.0
1.5
2.0
2.5
0
fIN = 2170MHz
PRFINB = -25dBm PRFINA IS SWEPT
TA = -20°C
TA = +25°C
TA = +85°C
DIFFERENTIAL OUTPUT-VOLTAGE ERROR
vs. A/B DIFFERENCE
MAX2016 toc08
MAGNITUDE RATIO (dB)
ERROR (dB)
200-20
-2
-1
0
1
2
3
-3
-40 40
fIN = 2170MHz
PRFINB = -25dBm
NORMALIZED TO DATA
AT +25°C
TA = -20°C
TA = +85°C
MAX2016
LF-to-2.5GHz Dual Logarithmic Detector/
Controller for Power, Gain, and VSWR Measurements
8 _______________________________________________________________________________________
Typical Operating Characteristics (continued)
(MAX2016 EV kit, VCC = 3.3V, R1= R2= R3= 0Ω, CSETL = CSETH = VCC, TA= +25°C, unless otherwise noted.)
VOUTA vs. PRFINA
MAX2016 toc17
PRFINA (dBm)
VOUTA (V)
-5-25-45
0.5
1.0
1.5
2.0
2.5
0
-65 15
fIN = 1900MHz TA = -20°C
TA = +25°C
TA = +85°C
VOUTA ERROR vs. PRFINA
MAX2016 toc18
PRFINA (dBm)
ERROR (dB)
-5-25-45
-2
-1
0
1
2
3
-3
-65 15
fIN = 1900MHz
NORMALIZED TO DATA
AT +25°C
TA = -20°C
TA = +85°C
VOUTA vs. PRFINA
MAX2016 toc13
PRFINA (dBm)
VOUTA (V)
0-20-40-60
0.5
1.0
1.5
2.0
2.5
0
-80 20
fIN = 100MHz TA = -20°C
TA = +25°C
TA = +85°C
VOUTA ERROR vs. PRFINA
MAX2016 toc14
PRFINA (dBm)
ERROR (dB)
0-20-40-60
-2
-1
0
1
2
3
-3
-80 20
fIN = 100MHz
NORMALIZED TO DATA
AT +25°C
TA = -20°C
TA = +85°C
VOUTA vs. PRFINA
MAX2016 toc15
PRFINA (dBm)
VOUTA (V)
0-20-40-60
0.5
1.0
1.5
2.0
2.5
0
-80 20
fIN = 900MHz
TA = -20°C
TA = +25°C
TA = +85°C
VOUTA ERROR vs. PRFINA
MAX2016 toc16
PRFINA (dBm)
ERROR (dB)
0-15-30-45-60
-2
-1
0
1
2
3
-3
-75 15
fIN = 900MHz
NORMALIZED TO DATA
AT +25°C
TA = -20°C
TA = +85°C
MAX2016
LF-to-2.5GHz Dual Logarithmic Detector/
Controller for Power, Gain, and VSWR Measurements
_______________________________________________________________________________________ 9
Typical Operating Characteristics (continued)
(MAX2016 EV kit, VCC = 3.3V, R1= R2= R3= 0Ω, CSETL = CSETH = VCC, TA= +25°C, unless otherwise noted.)
VOUTA vs. PRFINA
MAX2016 toc19
PRFINA (dBm)
VOUTA (V)
0-15-30-45
0.5
1.0
1.5
2.0
2.5
0
-60 15
fIN = 2170MHz
TA = -20°C
TA = +25°C
TA = +85°C
VOUTA ERROR vs. PRFINA
MAX2016 toc20
PRFINA (dBm)
ERROR (dB)
0-15-30-45
-2
-1
0
1
2
3
-3
-60 15
fIN = 2170MHz
NORMALIZED TO DATA
AT +25°C
TA = -20°C
TA = +85°C
MAX2016 toc21
0-15-30-45
0.5
1.0
1.5
2.0
2.5
0
-60 15
VOUTA vs. PRFINA
PRFINA (dBm)
VOUTA (V)
fIN = 2500MHz
TA = -20°C
TA = +25°C
TA = +85°C
-2
-1
0
1
2
3
-3
MAX2016 toc22
0-15-30-45-60 15
VOUTA ERROR vs. PRFINA
PRFINA (dBm)
ERROR (dB)
fIN = 2500MHz
NORMALIZED TO DATA
AT +25°C
TA = -20°C
TA = +85°C
MAX2016
LF-to-2.5GHz Dual Logarithmic Detector/
Controller for Power, Gain, and VSWR Measurements
10 ______________________________________________________________________________________
Detailed Description
The MAX2016 dual logarithmic amplifier is designed for
a multitude of applications including dual-channel RF
power measurements, AGC control, gain/loss detection,
and VSWR monitoring. This device measures RF signals
ranging from low frequency to 2.5GHz, and operates
from a single 2.7V to 5.25V (using series resistor, R6)
power supply. As with its single-channel counterpart
(MAX2015), the MAX2016 provides unparalleled perfor-
mance with a high 80dB dynamic range at 100MHz and
exceptional accuracy over the extended temperature
and supply voltage ranges.
The MAX2016 uses a pair of logarithmic amplifiers to
detect and compare the power levels of two RF input
signals. The device subtracts one power level from the
other to provide a DC output voltage that is proportional
to the power difference (gain). The MAX2016 can also
measure the return loss/VSWR of an RF signal by moni-
toring the incident and reflected power levels associat-
ed with any given load.
A window detector is easily implemented by using the
on-chip comparators, OR gate, and 2V reference. This
combination of circuitry provides an automatic indica-
tion of when the measured gain is outside a program-
mable range. Alarm monitoring can thus be imple-
mented for detecting high-VSWR states (such as open
or shorted loads).
RF Inputs (RFINA and RFINB)
The MAX2016 has two differential RF inputs. The input
to detector A (RFINA) uses the two input ports RFINA+
and RFINA-, and the input to detector B (RFINB) uses
the two input ports RFINB+ and RFINB-.
Pin Description
PIN NAME FUNCTION
1, 28 FA1, FA2 External Capacitor Input. Connecting a capacitor between FA1 and FA2 sets the highpass cutoff
frequency corner for detector A (see the Input Highpass Filter section).
2, 9, 12, 20 VCC Supply Voltage. Bypass with capacitors as specified in the Typical Application Circuit. Place
capacitors as close to each VCC as possible (see the Power-Supply Connections section).
3, 4 RFINA+, RFINA- Differential RF Inputs for Detector A. Requires external DC-blocking capacitors.
5, 17 GND Ground. Connect to the PCB ground plane.
6 COUTH High-Comparator Output
7 CSETH Threshold Input on High Comparator
8 COR Comparator OR Logic Output. Output of COUTH ORed with COUTL.
10 SETD Set-Point Input for Gain Detector
11 OUTD DC Output Voltage Representing PRFINA - PRFINB. This output provides a DC voltage
proportional to the difference of the input RF powers on RFINA and RFINB.
13, 14 FV2, FV1 Video-Filter Capacitor Inputs for OUTD
15 CSETL Threshold Set Input on Low Comparator
16 COUTL Low-Comparator Output
18, 19 RFINB-, RFINB+ Differential RF Inputs for Detector B. Requires external DC-blocking capacitors.
21, 22 FB1, FB2 External Capacitor Input. Connecting a capacitor between FB1 and FB2 sets the highpass cutoff
frequency corner for detector B (see the Input Highpass Filter section).
23 OUTB Detector B Output. This output provides a voltage proportional to the log of the input power on
differential inputs RFINB+ and RFINB- (RFINB).
24 SETB Set-Point Input for Detector B
25 REF 2V Reference Output
26 SETA Set-Point Input for Detector A
27 OUTA Detector A Output. This output provides a voltage proportional to the log of the input power on
differential inputs RFINA+ and RFINA- (RFINA).
EP GND Exposed Paddle. EP must connect to the PCB ground plane.
MAX2016
LF-to-2.5GHz Dual Logarithmic Detector/
Controller for Power, Gain, and VSWR Measurements
______________________________________________________________________________________ 11
The differential RF inputs allow for the measurement of
broadband signals ranging from low frequency to
2.5GHz. For single-ended signals, RFINA- and RFINB-
are AC-coupled to ground. The RF inputs are internally
biased and need to be AC-coupled. Using 680pF
capacitors, as shown in the Typical Application Circuit,
results in a 10MHz highpass corner frequency. An
internal 50Ωresistor between RFINA+ and RFINA- (as
well as RFINB+ and RFINB-) produces a good low-fre-
quency to 3.0GHz match.
SETA, SETB, and SETD Inputs
The SET_ inputs are used for loop control when the
device is in controller mode. Likewise, these same
SET_ inputs are used to set the slope of the output sig-
nal (mV/dB) when the MAX2016 is in detector mode.
The center node of the internal resistor-divider is fed to
the negative input of the power detector’s internal out-
put op amp.
Reference
The MAX2016 has an on-chip 2V voltage reference.
The internal reference output is connected to REF. The
output can be used as a reference voltage source for
the comparators or other components and can source
up to 2mA.
OUTA and OUTB
Each OUT_ is a DC voltage proportional to the RF input
power level. The change of OUT_ with respect to the
power input is approximately 18mV/dB (R1= R2= 0Ω).
The input power level can be determined by the following
equation:
where PINT is the extrapolated intercept point of where
the output voltage intersects the horizontal axis.
OUTD
OUTD is a DC voltage proportional to the difference of
the input RF power levels. The change of the OUTD
with respect to the power difference is -25mV/dB (R3 =
0Ω). The difference of the input power levels (gain) can
be determined by the following equation:
where VCENTER is the output voltage, typically 1V, when
PRFINA = PRFINB.
Applications Information
Monitoring VSWR and Return Loss
The MAX2016 can be used to measure the VSWR of an
RF signal, which is useful for detecting the presence or
absence of a properly loaded termination, such as an
antenna (see Figure 1). The transmitted wave from the
power amplifier is coupled to RFINA and to the anten-
na. The reflected wave from the antenna is connected
to RFINB through a circulator. When the antenna is
missing or damaged, a mismatch in the nominal load
PP VV
SLOPE
RFINA RFINB OUTD CENTER
=()
PV
SLOPE P
RFIN OUT INT__
=+
MAX2016
CSETL
COUTL
VREF
LOGARITHMIC
DETECTOR
LOGARITHMIC
DETECTOR
COUTL
OUTD
SETD
20kΩ
RFINB
RFINA
OUTD
TRANSMITTER
COUPLER
CIRCULATOR
ATTENUATOR
GND
Figure 1. VSWR Monitoring Configuation
MAX2016
LF-to-2.5GHz Dual Logarithmic Detector/
Controller for Power, Gain, and VSWR Measurements
12 ______________________________________________________________________________________
impedance results, leading to an increase in reflected
power and subsequent change in the transmission
line’s VSWR. This increase in reflected power is mani-
fested by an increase in the voltage at OUTD. An alarm
condition can be set by using the low comparator out-
put (COUTL) as shown in Figure 1. The comparator
automatically senses the change in VSWR, yielding a
logic 0 as it compares OUTD to a low DC voltage at
CSETL. CSETL, in turn, is set by using the internal refer-
ence voltage and an external resistor-divider network.
For accurate measurement of signals carrying signifi-
cant amplitude modulation, limit the bandwidth of the
difference amplifier to be less than the lowest modula-
tion frequency. This will minimize the ripple in the
OUTD waveform. This is particularly appropriate if the
system-level time delay between the two sense points
is significant with respect to the period of modulation.
Figure 1 illustrates a simple level detector. For window-
detector implementation, see the Comparator/Window
Detector section.
Measuring VSWR and Return Loss
In Figure 2, the two logarithmic amplifiers measure the
incident and the reflected power levels to produce two
proportional output voltages at OUTA and OUTB. Since
OUTD is a DC voltage proportional to the difference of
OUTA and OUTB, return loss (RL) and VSWR can be
easily calculated within a microprocessor using the
following relationships:
where return loss (RL) is expressed in decibels,
VCENTER is the output voltage (typically 1V) when
PRFINA = PRFINB, and SLOPE is typically equal to
-25mV/dB (for R3 = 0Ω).
VSWR can similarly be calculated through the following
relationship:
VSWR
RL
RL
=+
110
110
20
20
RL P P VV
SLOPE
RFINA RFINB OUTD CENTER
=− =
()
MAX2016
RFINA
RFINB
GND
ADC μP
IN LOAD
4-PORT DIRECTIONAL
COUPLER
LOGARITHMIC
DETECTOR
LOGARITHMIC
DETECTOR
OUTD
SETD
20kΩ
Figure 2. Measuring Return Loss and VSWR of a Given Load
MAX2016
LF-to-2.5GHz Dual Logarithmic Detector/
Controller for Power, Gain, and VSWR Measurements
______________________________________________________________________________________ 13
Measuring Gain
The MAX2016 can be used to measure the gain of an
RF block (or combination of blocks) through the imple-
mentation outlined in Figure 3. As shown, a coupled
signal from the input of the block is fed into RFINA,
while the coupled output is connected to RFINB. The
DC output voltage at OUTD is proportional to the power
difference (i.e., gain).
The gain of a complete receiver or transmitter lineup
can likewise be measured since the MAX2016 accepts
RF signals that range from low frequency to 2.5GHz;
see Figure 4. The MAX2016 accurately measures the
gain, regardless of the different frequencies present
within superheterodyne architectures.
For accurate measurement of signals carrying signifi-
cant amplitude modulation, limit the bandwidth of the
difference amplifier to be less than the lowest modula-
tion frequency. This will minimize the ripple in the
OUTD waveform. This is particularly appropriate if the
system-level time delay between the two sense points
is significant with respect to the period of modulation.
MAX2016
RFINA
RFINB
IN
LOGARITHMIC
DETECTOR
LOGARITHMIC
DETECTOR
GND
OUTD
SETD
20kΩ
COUPLER COUPLER
RF BLOCK
OUT
OUTD
Figure 3. Gain Measurement Configuration
MAX2016
LNA
fRF fIF
RFINA RFINB
LOGARITHMIC
DETECTOR
LOGARITHMIC
DETECTOR
COUPLER
LO
MIXER
COUPLER
OUTD
SETD
20kΩ
OUT
Figure 4. Conversion Gain Measurement Configuration
MAX2016
LF-to-2.5GHz Dual Logarithmic Detector/
Controller for Power, Gain, and VSWR Measurements
14 ______________________________________________________________________________________
Measuring Power (RSSI Detector Mode)
In detector mode, the MAX2016 acts like a receive-sig-
nal-strength indicator (RSSI), which provides an output
voltage proportional to the input power. This is accom-
plished by providing a feedback path from OUTA
(OUTB) to SETA (SETB) (R1/R2 = 0Ω; see Figure 5).
By connecting SET_ directly to OUT_, the op-amp gain
is set to 2V/V due to two internal 20kΩfeedback resis-
tors. This provides a detector slope of approximately
18mV/dB with a 0.5V to 1.8V output range.
Gain-Controller Mode
The MAX2016 can be used as a gain controller within
an automatic gain-control (AGC) loop. As shown in
Figure 6, RFINA and RFINB monitor the VGA’s input
and output power levels, respectively. The MAX2016
produces a DC voltage at OUTD that is proportional to
the difference in these two RF input power levels. An
internal op amp compares the DC voltage with a refer-
ence voltage at SETD. The op amp increases or
decreases the voltage at OUTD until OUTD equals
SETD. Thus, the MAX2016 adjusts the gain of the VGA
to a level determined by the voltage applied to SETD.
Place the nominal signal levels of RFINA and RFINB
near the middle of their respective dynamic ranges to
accommodate the largest range of gain compensation.
This is nominally -25dBm to -30dBm. If so selected, the
nominal voltage applied to SETD will be approximately
1.0V. Operate the SETD voltage within the range of
0.5V to 1.5V for the greatest accuracy of gain control.
MAX2016
RFIN+A
RFIN-A
OUTA
IN_
GND
R1/R2
20kΩ
20kΩ
DETECTORS
SETA
OUTA
RFIN+B
RFIN-B
OUTB
IN_
R1/R2
20kΩ
20kΩ
DETECTORS
SETB
OUTB
Figure 5. In Detector Mode (RSSI), OUTA/OUTB is a DC
Voltage Proportional to the Input Power
MAX2016
LOGARITHMIC
DETECTOR
LOGARITHMIC
DETECTOR
20kΩ
VGA
GAIN CONTROL INPUT
RFINA RFINB
OUTDSETD
VGA INPUT VGA OUTPUT
SET-POINT
DAC
COUPLER COUPLER
Figure 6. In Gain-Controller Mode, the OUTD Maintains the
Gain of the VGA
MAX2016
LF-to-2.5GHz Dual Logarithmic Detector/
Controller for Power, Gain, and VSWR Measurements
______________________________________________________________________________________ 15
Power-Controller Mode
The MAX2016 can also be used as a power detector/
controller within an AGC loop. Figure 7 depicts a sce-
nario where the MAX2016 is employed as the AGC cir-
cuit. As shown in the figure, the MAX2016 monitors the
output of the PA through a directional coupler. An inter-
nal differencing amplifier (Figure 5) compares the
detected signal with a reference voltage determined by
VSET_. The differencing amplifier increases or decreas-
es the voltage at OUT_, according to how closely the
detected signal level matches the VSET_ reference. The
MAX2016 maintains the power of the PA to a level
determined by the voltage applied to SET_.
Since the logarithmic detector responds to any ampli-
tude modulation being carried by the carrier signal, it
may be necessary to insert an external lowpass filter
between the differencing amplifier output
(OUTA/OUTB) and the gain-control element to remove
this modulation signal.
OUTA and OUTB Slope Adjustment
The transfer slope function of OUTA and OUTB can be
increased from its nominal value by varying resistors
R1 and R2 (see the Typical Application Circuit). The
equation controlling the slope is:
OUTD Slope Adjustment
The transfer slope function of OUTD can be increased
from its nominal value by varying resistor R3 (see the
Typical Application Circuit). The equation controlling
the slope is:
Input Highpass Filters
The MAX2016 integrates a programmable highpass fil-
ter on each RF input. The lower cutoff frequency of the
MAX2016 can be decreased by increasing the external
capacitor value between FA1 and FA2 or FB1 and FB2.
By default, with no capacitor connecting FA1 and FA2
or FB1 and FB2, the lower cutoff frequency is 20MHz.
Using the following equation determines the lowest
operating frequency:
where R = 2Ω.
Differential Output Video Filter
The bandwidth and response time difference of the out-
put amplifier can be controlled with the external capaci-
tor, C15, connected between FV1 and FV2. With no
external capacitor, the bandwidth is greater than 20MHz.
The following equation determines the bandwidth of the
amplifier difference:
where R = 1.8kΩ.
Use a video bandwidth lower than the anticipated low-
est amplitude-modulation frequency range to yield the
greatest accuracy in tracking the average carrier
power for high peak-to-average ratio waveforms.
frequency RC
=1
2π
frequency RC
=1
2π
SLOPE OUTD mV
dB
Rk
k
=−
+
25 320
20
SLOPE OUTA OR OUTB mV
dB
RorR k
k
=
()
+
91240
20
MAX2016
LOGARITHMIC
DETECTOR
TRANSMITTER
SET-POINT
DAC
OUTA/
OUTB
SETA/
SETB
COUPLER
RFINA/
RFINB
POWER AMPLIFIER
GAIN-CONTROL INPUT
LOWPASS
FILTER
20kΩ
20kΩ
Figure 7. In Power-Controller Mode, the DC Voltage at OUTA or
OUTB Controls the Gain of the PA, Leading to a Constant
Output Power Level (Note: Only one controller channel is
shown within the figure. Since the MAX2016 is a dual con-
troller/detector, the second channel can be easily implemented
by using the adjacent set of input and output connections.)
MAX2016
LF-to-2.5GHz Dual Logarithmic Detector/
Controller for Power, Gain, and VSWR Measurements
16 ______________________________________________________________________________________
Comparators/Window Detectors
The MAX2016 integrates two comparators for use in
monitoring the difference in power levels (gain) of
RFINA and RFINB. The thresholds of the two compara-
tors are set to the voltage applied to the CSETL and
CSETH pins. The output of each comparator can be
monitored independently or from the COR output that
ORs the outputs of the individual comparators. This can
be used for a window-detector function.
These comparators can be used to trigger hardware
interrupts, allowing rapid detection of over-range condi-
tions. These comparators are high-speed devices.
Connect high-value bypass capacitors (0.1µF) between
each comparator threshold input (CSETL and CSETH)
to ground to provide a solid threshold voltage at high
switching speeds.
Some applications may benefit from the use of hystere-
sis in the comparator response. This can be useful for
prevention of false triggering in the presence of small
noise perturbations in the signal levels, or with signals
with large amplitude modulation. To introduce hysteresis
into the comparator output, connect a feedback resistor
from COUTL to CSTEL. Select the value of this resistor,
in combination with the resistive-divider values used to
set threshold-level CSETL, to set the amount of hystere-
sis. Set the parallel combination of resistors connected
to CSETL to be less than 10kΩfor best performance.
Figure 8 illustrates the use of these comparators in a
gain-monitoring application. The low comparator has its
threshold (CSETL) set at a low-gain trip point. If the
gain drops below this trip point, the COUTL output
goes from a logic 0 to a logic 1. The high comparator
has its threshold (CSETH) set at a high trip point. If the
gain exceeds this trip point, the COUTH output goes
from logic 0 to logic 1. The window comparator output
(COR) rests a logic 0 if the gain is in the acceptable
range, between CSETL and CSETH. It goes to a logic 1
if the gain is either above or below these limits.
Power-Supply Connection
The MAX2016 is designed to operate from a single
+2.7V to +3.6V supply. To operate under a higher sup-
ply voltage range, a resistor must be connected in series
with the power supply and VCC to reduce the voltage
delivered to the chip. For a +4.75V to +5.25V supply,
use a 37.4Ω(±1%) resistor in series with the supply.
Layout Considerations
A properly designed PCB is an essential part of any
RF/microwave circuit. Keep RF signal lines as short as
possible to reduce losses, radiation, and inductance.
For the best performance, route the ground pin traces
directly to the exposed pad under the package. The
PCB exposed pad MUST be connected to the ground
plane of the PCB. It is suggested that multiple vias be
used to connect this pad to the lower level ground
MAX2016
RFINA
RFINB
IN
LOGARITHMIC
DETECTOR
LOGARITHMIC
DETECTOR OUTD
SETD
COUPLER COUPLER
RF BLOCK
OUT
CSETL
COR
CSETH
20kΩ
Figure 8. Window Comparators Monitoring Mode. COR goes high if OUTD drops below CSETL or rises above CSETH.
MAX2016
LF-to-2.5GHz Dual Logarithmic Detector/
Controller for Power, Gain, and VSWR Measurements
______________________________________________________________________________________ 17
MAX2016
REFSETA OUTA OUTB SETB
2.0V
REF
LOG
AMPLIFIERS
LOG
AMPLIFIERS
VCC
RFINB+
RFINB-
FB1
FB2
FV1
FV2
SETDOUTDCSETH COUTH COUTL CSETL
COR
FA2
FA1
RFINA-
RFINA+
GND
EXPOSED
PAD
20kΩ
50Ω50Ω
20kΩ20kΩ20kΩ
2, 9, 12, 20
5, 17
3
4
1
28
8
16 15 11 10
13
14
22
21
18
19
2423252726
67
20kΩ
Functional Diagram
planes. This method provides a good RF/thermal con-
duction path for the device. Solder the exposed pad on
the bottom of the device package to the PCB. The
MAX2016 Evaluation Kit can be used as a reference for
board layout. Gerber files are available upon request at
www.maxim-ic.com.
Power-Supply Bypassing
Proper voltage-supply bypassing is essential for high-
frequency circuit stability. Bypass each VCC pin with a
capacitor as close to the pin as possible (Typical
Application Circuit).
Exposed Pad RF/Thermal Considerations
The exposed paddle (EP) of the MAX2016’s 28-pin thin
QFN-EP package provides two functions. One is a low
thermal-resistance path to the die; the second is a low-
RF impedance ground connection. The EP MUST be
soldered to a ground plane on the PCB, either directly
or through an array of plated via holes (minimum of four
holes to provide ground integrity).
MAX2016
LF-to-2.5GHz Dual Logarithmic Detector/
Controller for Power, Gain, and VSWR Measurements
18 ______________________________________________________________________________________
FA1
1
VCC
2
RFINA+
3
RFINA-
4
GND
5
COUTH
6
CSETH
7
FB1 21
VCC
20
RFINB+ 19
RFINB- 18
GND 17
COUTL 16
CSETL 15
COR
8
VCC
9
SETD
10
OUTD
11
VCC
12
FV2
13
FV1
14
FA2
28
OUTA
27
SETA
26
REF
25
SETB
24
OUTB
23
FB2
22
MAX2016
VREF
R1
VOUTA
R2
VOUTB
C12C5
C4
C1
C2
C11
C8
C9
C16 C17
COMPARATORB
C15
A + B
R3
C7 C14
VOUTD
VCC
VCC
VCC VCC
VCC
VCC
VCC
VS
C18
COMPARATORA
RFINA RFINB
C10
C13
C6
C3
R6
EXPOSED
PADDLE
NOTE: COMPARATORS ARE DISABLED
BY CONNECTING CSETL AND CSETH TO VCC.
Typical Application Circuit
Chip Information
PROCESS: BiCMOS
DESIGNATION VALUE DESCRIPTION
C1, C2, C8, C9 680pF Microwave capacitors (0402)
C3, C6, C10, C13 33pF Microwave capacitors (0402)
C4, C7, C11, C14 0.1µF Microwave capacitors (0603)
C5, C12, C15, C16, C17 Not used Capacitors are optional for frequency compensation, bypass
C18 10µF Tantalum capacitor (C case)
R1, R2, R3 0ΩResistors (0402)
0ΩResistor (1206) for VS = 2.7V to 3.6V
R6 37.4Ω±1% resistor (1206) for VS = 4.75V to 5.25V
Table 1. Component Values Used in the Typical Application Circuit
MAX2016
LF-to-2.5GHz Dual Logarithmic Detector/
Controller for Power, Gain, and VSWR Measurements
______________________________________________________________________________________ 19
Package Information
(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,
go to www.maxim-ic.com/packages.)
QFN THIN.EPS
MAX2016
LF-to-2.5GHz Dual Logarithmic Detector/
Controller for Power, Gain, and VSWR Measurements
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.
20 ____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600
© 2006 Maxim Integrated Products is a registered trademark of Maxim Integrated Products, Inc.
MAX2016MAX2016
Package Information (continued)
(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,
go to www.maxim-ic.com/packages.)
Revision History
Pages changed at Rev 1: 1, 5, 10–20