AD8318-EVALZ [ADI]
1 MHz to 8 GHz, 70 dB Logarithmic Detector/Controller; 1 MHz至8 GHz的, 70分贝对数检测器/控制器型号: | AD8318-EVALZ |
厂家: | ADI |
描述: | 1 MHz to 8 GHz, 70 dB Logarithmic Detector/Controller |
文件: | 总24页 (文件大小:2007K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
1 MHz to 8 GHz, 70 dB
Logarithmic Detector/Controller
AD8318
FUNCTIONAL BLOCK DIAGRAM
FEATURES
VPSI
ENBL
TADJ
VPSO
Wide bandwidth: 1 MHz to 8 GHz
High accuracy: 1.0 dB over 55 dB range (f < 5.8 GHz)
Stability over temperature: 0.5 dB
Low noise measurement/controller output (VOUT)
Pulse response time: 10 ns/12 ns (fall/rise)
Integrated temperature sensor
TEMP
SENSOR
GAIN
BIAS
TEMP
SLOPE
VSET
I
I
V
V
VOUT
CLPF
DET
DET
DET
DET
Small footprint LFCSP
INHI
Power-down feature: <1.5 mW at 5 V
Single-supply operation: 5 V @ 68 mA
Fabricated using high speed SiGe process
INLO
CMIP
CMOP
Figure 1.
2.4
2.2
2.0
1.8
1.6
1.4
1.2
1.0
0.8
0.6
0.4
0.2
0
6
APPLICATIONS
5
RF transmitter PA setpoint control and level monitoring
RSSI measurement in base stations, WLAN, WiMAX, and
radars
4
3
2
1
0
GENERAL DESCRIPTION
–1
–2
–3
–4
–5
–6
The AD8318 is a demodulating logarithmic amplifier, capable
of accurately converting an RF input signal to a corresponding
decibel-scaled output voltage. It employs the progressive
compression technique over a cascaded amplifier chain, each
stage of which is equipped with a detector cell. The device is
used in measurement or controller mode. The AD8318
maintains accurate log conformance for signals of 1 MHz to
6 GHz and provides useful operation to 8 GHz. The input range
is typically 60 dB (re: 50 Ω) with error less than 1 dB. The
AD8318 has a 10 ns response time that enables RF burst
detection to beyond 45 MHz. The device provides unprece-
dented logarithmic intercept stability vs. ambient temperature
conditions. A 2 mV/°C slope temperature sensor output is also
provided for additional system monitoring. A single supply of
5 V is required. Current consumption is typically 68 mA. Power
consumption decreases to <1.5 mW when the device is disabled.
–65 –60 –55 –50 –45 –40 –35 –30 –25 –20 –15 –10 –5
0
5
10
P
(dBm)
IN
Figure 2. Typical Logarithmic Response and Error vs. Input Amplitude at 5.8 GHz
In this mode, the setpoint control voltage is applied to VSET.
The feedback loop through an RF amplifier is closed via VOUT,
the output of which regulates the amplifier output to a magnitude
corresponding to VSET. The AD8318 provides 0 V to 4.9 V
output capability at the VOUT pin, suitable for controller
applications. As a measurement device, Pin VOUT is externally
connected to VSET to produce an output voltage, VOUT, which
is a decreasing linear-in-dB function of the RF input signal
amplitude.
The AD8318 can be configured to provide a control voltage
to a VGA, such as a power amplifier or a measurement output,
from Pin VOUT. Because the output can be used for controller
applications, wideband noise is minimal.
The logarithmic slope is nominally −25 mV/dB but can be
adjusted by scaling the feedback voltage from VOUT to the
VSET interface. The intercept is 20 dBm (re: 50 Ω, CW input)
using the INHI input. These parameters are very stable against
supply and temperature variations.
The AD8318 is fabricated on a SiGe bipolar IC process and is
available in a 4 mm × 4 mm, 16-lead LFCSP for the operating
temperature range of –40oC to +85oC.
Rev. B
Information furnished by Analog Devices is believed to be accurate and reliable. However, no
responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other
rights of third parties that may result from its use. Specifications subject to change without notice. No
license is granted by implication or otherwise under any patent or patent rights of Analog Devices.
Trademarks and registeredtrademarks arethe property of their respective owners.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781.329.4700
www.analog.com
Fax: 781.461.3113 ©2004-2007 Analog Devices, Inc. All rights reserved.
AD8318
TABLE OF CONTENTS
Features .............................................................................................. 1
Temperature Compensation of Output Voltage..................... 13
Temperature Sensor ................................................................... 14
Measurement Mode ................................................................... 14
Device Calibration and Error Calculation.............................. 15
Applications....................................................................................... 1
General Description......................................................................... 1
Functional Block Diagram .............................................................. 1
Revision History ............................................................................... 2
Specifications..................................................................................... 3
Absolute Maximum Ratings............................................................ 6
ESD Caution.................................................................................. 6
Pin Configuration and Function Descriptions............................. 7
Typical Performance Characteristics ............................................. 8
Theory of Operation ...................................................................... 11
Using the AD8318 .......................................................................... 12
Basic Connections...................................................................... 12
Enable Interface .......................................................................... 12
Input Signal Coupling................................................................ 12
Output Interface ......................................................................... 13
Setpoint Interface ....................................................................... 13
Selecting Calibration Points to Improve Accuracy over a
Reduced Range ........................................................................... 16
Variation in Temperature Drift from Device to Device........ 17
Temperature Drift at Different Temperatures ........................ 17
Setting the Output Slope in Measurement Mode .................. 17
Response Time Capability......................................................... 18
Output Filtering.......................................................................... 18
Controller Mode......................................................................... 19
Characterization Setup and Methods...................................... 21
Evaluation Board ............................................................................ 22
Outline Dimensions....................................................................... 24
Ordering Guide .......................................................................... 24
REVISION HISTORY
Changed General Description Heading to
4/07—Rev. A to Rev. B
Theory of Operation ...................................................................... 11
Changes to Enable Interface Section ........................................... 12
Inserted Figure 24........................................................................... 12
Changes to Input Signal Coupling Section ................................. 12
Changes to Measurement Mode Section..................................... 14
Changes to Figure 36...................................................................... 17
Added Output Filtering Section ................................................... 19
Changes to Controller Mode Section .......................................... 19
Changes to Response Time Capability Section .......................... 18
Changes to Table 6.......................................................................... 22
Changes to Figure 47, Figure 48, and Figure 49......................... 23
Updated Outline Dimensions....................................................... 24
Changes to Ordering Guide.......................................................... 24
Added Figure 2; Renumbered Sequentially .................................. 1
Changes to Table 1............................................................................ 3
Changes to Figure 23...................................................................... 12
Changes to Characterization Setup and Methods Section........ 21
Changes to Figure 48...................................................................... 23
Updated Outline Dimensions....................................................... 24
Changes to Ordering Guide .......................................................... 24
1/06—Rev. 0 to Rev. A
Changed TADJ Resistor to RTADJ Resistor....................Universal
Changes to Applications .................................................................. 1
Changes to Table 1............................................................................ 3
Changes to Figure 5, Figure 6, and Figure 7 Captions................. 8
Changes to Figure 12 Caption......................................................... 9
Changes to Figure 15 Caption......................................................... 9
7/04—Rev. 0: Initial Version
Rev. B | Page 2 of 24
AD8318
SPECIFICATIONS
VPOS = 5 V, CLPF = 220 pF, TA = 25°C, 52.3 Ω termination resistor at INHI, unless otherwise noted.
Table 1.
Parameter
Conditions
Min
Typ
Max
Unit
SIGNAL INPUT INTERFACE
Specified Frequency Range
DC Common-Mode Voltage
MEASUREMENT MODE
INHI (Pin 14) and INLO (Pin 15)
0.001
8
GHz
V
VPOS – 1.8
VOUT (Pin 6) shorted to VSET (Pin 7), sinusoidal
input signal
f = 900 MHz
RTADJ = 500 Ω
Input Impedance
3 dB Dynamic Range
1 dB Dynamic Range
957||0.71
65
57
Ω||pF
dB
dB
TA = 25°C
TA = 25°C
−40°C < TA < +85°C
1 dB error
1 dB error
48
−1
dB
Maximum Input Level
Minimum Input Level
Slope
dBm
dBm
mV/dB
dBm
V
−58
−24.5
22
0.78
1.52
−26
19.5
0.7
−23
24
0.86
1.62
Intercept
Output Voltage—High Power In
Output Voltage—Low Power In
Temperature Sensitivity
PIN = −10 dBm
PIN = −40 dBm
PIN = −10 dBm
25°C ≤ TA ≤85°C
−40°C ≤ TA ≤ +25°C
RTADJ = 500 Ω
1.42
V
0.0011
0.003
dB/°C
dB/°C
f = 1.9 GHz
Input Impedance
3 dB Dynamic Range
1 dB Dynamic Range
523||0.68
65
57
Ω||pF
dB
dB
TA = 25°C
TA = 25°C
−40°C < TA < +85°C
1 dB error
1 dB error
50
−2
dB
Maximum Input Level
Minimum Input Level
Slope
dBm
dBm
mV/dB
dBm
V
−59
−24.4
20.4
0.73
1.35
−27
17
0.63
1.2
−22
24
0.83
1.5
Intercept
Output Voltage—High Power In
Output Voltage—Low Power In
Temperature Sensitivity
PIN = −10 dBm
PIN = −35 dBm
PIN = –10 dBm
25°C ≤ TA ≤ 85°C
−40°C ≤ TA ≤ +5°C
RTADJ = 500 Ω
V
0.0011
0.0072
dB/°C
dB/°C
f = 2.2 GHz
Input Impedance
3 dB Dynamic Range
1 dB Dynamic Range
391||0.66
65
58
Ω||pF
dB
dB
TA = 25°C
TA = 25°C
−40°C < TA < +85°C
1 dB error
1 dB error
50
−2
dB
dBm
dBm
Maximum Input Level
Minimum Input Level
Slope
−60
−24.4
19.6
0.73
1.34
−28
15
0.63
1.2
−21.5 mV/dB
Intercept
25
0.84
1.5
dBm
V
V
Output Voltage—High Power In
Output Voltage—Low Power In
Temperature Sensitivity
PIN = −10 dBm
PIN = −35 dBm
PIN = −10 dBm
25°C ≤ TA ≤ 85°C
−40°C ≤ TA ≤ +25°C
−0.0005
0.0062
dB/°C
dB/°C
Rev. B | Page 3 of 24
AD8318
Parameter
Conditions
Min
Typ
Max
Unit
f = 3.6 GHz
RTADJ = 51 Ω
Input Impedance
3 dB Dynamic Range
1 dB Dynamic Range
119||0.7
70
58
Ω||pF
dB
dB
TA = 25°C
TA = 25°C
−40°C < TA < +85°C
1 dB error
1 dB error
42
−2
–60
−24.3
19.8
0.717
1.46
dB
Maximum Input Level
Minimum Input Level
Slope
dBm
dBm
mV/dB
dBm
V
Intercept
Output Voltage—High Power In
Output Voltage—Low Power In
Temperature Sensitivity
PIN = −10 dBm
PIN = −40 dBm
PIN = −10 dBm
25°C ≤ TA ≤ 85°C
−40°C ≤ TA ≤ +25°C
RTADJ = 1000 Ω
V
0.0022
0.004
dB/°C
dB/°C
f = 5.8 GHz
Input Impedance
3 dB Dynamic Range
1 dB Dynamic Range
33||0.59
70
57
Ω||pF
dB
dB
TA = 25°C
TA = 25°C
−40°C < TA < +85°C
1 dB error
1 dB error
48
−1
dB
Maximum Input Level
Minimum Input Level
Slope
dBm
dBm
mV/dB
dBm
V
−58
−24.3
25
0.86
1.59
Intercept
Output Voltage—High Power In
Output Voltage—Low Power In
Temperature Sensitivity
PIN = −10 dBm
PIN = −40 dBm
PIN = −10 dBm
25°C ≤ TA ≤ 85°C
−40°C ≤ TA ≤ +25°C
RTADJ = 500 Ω
TA = 25°C
V
0.0033
0.0069
dB/°C
dB/°C
f = 8.0 GHz
3 dB Dynamic Range
60
dB
−40°C < TA < +85°C
3 dB error
3 dB error
58
3
dB
Maximum Input Level
Minimum Input Level
Slope
dBm
dBm
mV/dB
dBm
V
−55
−23
37
1.06
1.78
Intercept
Output Voltage—High Power In
Output Voltage—Low Power In
Temperature Sensitivity
PIN = −10 dBm
PIN = −40 dBm
PIN = −10 dBm
V
25°C ≤ TA ≤ 85°C
−40°C ≤ TA ≤ +25°C
0.028
−0.0085
dB/°C
dB/°C
OUTPUT INTERFACE
Voltage Swing
VOUT (Pin 6)
VSET = 0 V; PIN = −10 dBm, no load1
VSET = 2.1 V; PIN = −10 dBm, no load1
VSET = 1.5 V; PIN = −50 dBm
PIN = −10 dBm; from CLPF to VOUT
4.9
25
60
60
45
90
10
12
V
mV
mA
MHz
MHz
nV/√Hz
ns
Output Current Drive
Small Signal Bandwidth
Video Bandwidth (or Envelope Bandwidth)
Output Noise
Fall Time
Rise Time
PIN = 2.2 GHz; −10 dBm, fNOISE = 100 kHz, CLPF = 220 pF
PIN = Off to −10 dBm, 90% to 10%
PIN = −10 dBm to off, 10% to 90%
ns
Rev. B | Page 4 of 24
AD8318
Parameter
Conditions
Min
Typ
Max
Unit
VSET INTERFACE
Nominal Input Range
VSET (Pin 7)
PIN = 0 dBm; measurement mode2
PIN = −65 dBm; measurement mode2
0.5
2.1
V
Logarithmic Scale Factor
Bias Current Source
−0.04
2.5
dB/mV
μA
PIN = −10 dBm; VSET = 2.1 V
TEMP (Pin 13)
TA = 25°C, RLOAD = 10 kΩ
−40°C ≤ TA ≤ +85°C, RLOAD = 10 kΩ
TA = 25°C
TEMPERATURE REFERENCE
Output Voltage
Temperature Slope
0.57
0.6
2
0.63
V
mV/°C
mA
Current Source/Sink
10/0.1
POWER-DOWN INTERFACE
Logic Level to Enable Device
ENBL Current When Enabled
ENBL Current When Disabled
POWER INTERFACE
ENBL (Pin 16)
1.7
<1
15
V
μA
μA
ENBL = 5 V
ENBL = 0 V; sourcing
VPSI (Pin 3 and Pin 4), VPSO (Pin 9)
Supply Voltage
Quiescent Current
vs. Temperature
Supply Current when Disabled
vs. Temperature
4.5
50
5
68
150
260
350
5.5
82
V
ENBL = 5 V
−40°C ≤ TA ≤ +85°C
ENBL = 0 V, total currents for VPSI and VPSO
−40°C ≤ TA ≤ +85°C
mA
μA/°C
μA
μA
1 Controller mode.
2 Gain = 1. For other gains, see the Measurement Mode section.
Rev. B | Page 5 of 24
AD8318
ABSOLUTE MAXIMUM RATINGS
Table 2.
Stresses above those listed under Absolute Maximum Ratings
may cause permanent damage to the device. This is a stress
rating only; functional operation of the device at these or any
other conditions above those indicated in the operational
section of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect
device reliability.
Parameter
Rating
Supply Voltage: Pin VPSO, Pin VPSI
ENBL, VSET Voltage
5.7 V
0 to VPOS
12 dBm
0.73 W
55°C/W
Input Power (Single-Ended, re: 50 Ω)
Internal Power Dissipation
1
θJA
Maximum Junction Temperature
Operating Temperature Range
Storage Temperature Range
Lead Temperature
125°C
−40°C to +85°C
−65°C to +150°C
260°C
ESD CAUTION
1 With package die paddle soldered to thermal pads with vias connecting
to inner and bottom layers.
Rev. B | Page 6 of 24
AD8318
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
12
11
10
9
CMIP CMIP TADJ VPSO
13 TEMP
CMOP
VSET
VOUT
CLPF
8
7
6
5
14 INHI
AD8318
15 INLO
16 ENBL
CMIP CMIP VPSI VPSI
1
2
3
4
Figure 3. Pin Configuration
Table 3. Pin Function Descriptions
Pin No.
Mnemonic Description
1, 2, 11, 12
3, 4
5
6
7
CMIP
VPSI
Device Common (Input System Ground).
Positive Supply Voltage (Input System): 4.5 V to 5.5 V. Voltage on Pin 3, Pin 4, and Pin 9 should be equal.
Loop Filter Capacitor.
Measurement and Controller Output.
Setpoint Input for Controller Mode or Feedback Input for Measurement Mode.
Device Common (Output System Ground).
Positive Supply Voltage (Output System): 4.5 V to 5.5 V. Voltage on Pin 3, Pin 4, and Pin 9 should be equal.
Temperature Compensation Adjustment.
Temperature Sensor Output.
RF Input. Nominal input range: −60 dBm to 0 dBm (re: 50 Ω), ac-coupled.
RF Common for INHI. AC-coupled RF common.
Device Enable. Connect to VPSI for normal operation. Connect pin to ground for disable mode.
Internally Connected to CMIP (Solder to Ground).
CLPF
VOUT
VSET
CMOP
VPSO
TADJ
TEMP
INHI
8
9
10
13
14
15
16
INLO
ENBL
Paddle
Rev. B | Page 7 of 24
AD8318
TYPICAL PERFORMANCE CHARACTERISTICS
VPOS = 5 V; TA = +25°C, −40°C, +85°C; CLPF = 220 pF; RTADJ = 500 ꢀ; unless otherwise noted. Colors: +25°C ꢀ Black; −40°C ꢀ Blue;
+85°C ꢀ Red.
2.2
2.0
1.8
1.6
1.4
1.2
1.0
0.8
0.6
0.4
0.2
2.0
2.2
2.0
1.8
1.6
1.4
1.2
1.0
0.8
0.6
0.4
0.2
2.0
1.6
1.6
1.2
1.2
0.8
0.8
0.4
0.4
0
0
–0.4
–0.8
–1.2
–1.6
–2.0
–0.4
–0.8
–1.2
–1.6
–2.0
–65
–55
–45
–35
–25
–15
–5
5
15
–65
–55
–45
–35
–25
–15
–5
5
15
P
(dBm)
P
(dBm)
IN
IN
Figure 4. VOUT and Log Conformance vs. Input Amplitude at 900 MHz,
Typical Device
Figure 7. VOUT and Log Conformance vs. Input Amplitude at 3.6 GHz,
Typical Device, RTADJ = 51 Ω
2.2
2.0
1.8
1.6
1.4
1.2
1.0
0.8
0.6
0.4
0.2
2.0
2.2
2.0
1.8
1.6
1.4
1.2
1.0
0.8
0.6
0.4
0.2
2.0
1.6
1.6
1.2
1.2
0.8
0.8
0.4
0.4
0
0
–0.4
–0.8
–1.2
–1.6
–2.0
–0.4
–0.8
–1.2
–1.6
–2.0
–65
–55
–45
–35
–25
–15
–5
5
15
–65
–55
–45
–35
–25
–15
–5
5
15
P
(dBm)
P
(dBm)
IN
IN
Figure 5. VOUT and Log Conformance vs. Input Amplitude at 1.9 GHz,
Typical Device
Figure 8. VOUT and Log Conformance vs. Input Amplitude at 5.8 GHz,
Typical Device, RTADJ = 1000 Ω
2.2
2.0
1.8
1.6
1.4
1.2
1.0
0.8
0.6
0.4
0.2
2.0
2.2
2.0
1.8
1.6
1.4
1.2
1.0
0.8
0.6
0.4
0.2
4.5
1.6
3.6
1.2
2.7
0.8
1.8
0.4
0.9
0
0
–0.4
–0.8
–1.2
–1.6
–2.0
–0.9
–1.8
–2.7
–3.6
–4.5
–65
–55
–45
–35
–25
–15
–5
5
15
–65
–55
–45
–35
–25
–15
–5
5
P
(dBm)
P
(dBm)
IN
IN
Figure 6. VOUT and Log Conformance vs. Input Amplitude at 2.2 GHz,
Typical Device
Figure 9. VOUT and Log Conformance vs. Input Amplitude at 8 GHz,
Typical Device
Rev. B | Page 8 of 24
AD8318
2.0
1.6
2.0
1.6
1.2
1.2
0.8
0.8
0.4
0.4
0
0
–0.4
–0.8
–1.2
–1.6
–2.0
–0.4
–0.8
–1.2
–1.6
–2.0
–65
–55
–45
–35
–25
–15
–5
5
15
–65
–55
–45
–35
–25
–15
–5
5
15
P
(dBm)
P
(dBm)
IN
IN
Figure 10. Distribution of Error over Temperature After Ambient
Normalization vs. Input Amplitude at 900 MHz for at Least 70 Devices
Figure 13. Distribution of Error at Temperature After Ambient
Normalization vs. Input Amplitude at 3.6 GHz for at Least 70 Devices,
R
TADJ = 51 Ω
2.0
1.6
2.0
1.6
1.2
1.2
0.8
0.8
0.4
0.4
0
0
–0.4
–0.8
–1.2
–1.6
–2.0
–0.4
–0.8
–1.2
–1.6
–2.0
–65
–55
–45
–35
–25
–15
–5
5
15
–65
–55
–45
–35
–25
–15
–5
5
15
P
(dBm)
P
(dBm)
IN
IN
Figure 11. Distribution of Error at Temperature After Ambient
Normalization vs. Input Amplitude at 1900 MHz for at Least 70 Devices
Figure 14. Distribution of Error at Temperature After Ambient
Normalization vs. Input Amplitude at 5.8 GHz for at Least 70 Devices,
RTADJ = 1000 Ω
2.0
1.6
4.5
3.6
1.2
2.7
0.8
1.9
0.4
0.9
0
0
–0.4
–0.8
–1.2
–1.6
–2.0
–0.9
–1.8
–2.7
–3.6
–4.5
–65
–55
–45
–35
–25
–15
–5
5
15
–65
–55
–45
–35
–25
–15
–5
5
P
(dBm)
P
(dBm)
IN
IN
Figure 12. Distribution of Error at Temperature After Ambient
Normalization vs. Input Amplitude at 2.2 GHz for at Least 70 Devices
Figure 15. Distribution of Error at Temperature After Ambient
Normalization vs. Input Amplitude at 8 GHz for at Least 70 Devices
Rev. B | Page 9 of 24
AD8318
j1
j2
j0.5
10k
1k
RF OFF
j0.2
0
0.2
8GHz
0.5
1
2
–60dBm
0.1GHz
–40dBm
–20dBm
5.8GHz
0.9GHz
1.9GHz
–j0.2
100
–10dBm
0dBm
1k
3.6GHz
2.2GHz
–j2
–j0.5
10
1
3
10
30
100
300
3k
10k
START FREQUENCY = 0.1GHz
STOP FREQUENCY = 8GHz
–j1
FREQUENCY (kHz)
Figure 19. Noise Spectral Density of Output; CLPF = Open
Figure 16. Input Impedance vs. Frequency; No Termination Resistor on
INHI, ZO = 50 Ω
1k
0.07
0.06
0.05
0.04
DECREASING V
INCREASING V
ENBL
ENBL
100
0.03
0.02
0.01
0
10
1
3
10
30
100
300
1k
3k
10k
1.4
1.5
1.6
1.7
1.8
FREQUENCY (kHz)
V
(V)
ENBL
Figure 17. Supply Current vs. Enable Voltage
Figure 20. Noise Spectral Density of Output Buffer (from CLPF to VOUT);
CLPF = 0.1 μF
2.2
2.0
1.8
1.6
1.4
1.2
1.0
0.8
0.6
0.4
0.2
2.0
1.6
1.2
VOUT
0.8
0.4
200mV/VERTICAL
DIVISION
0
–0.4
–0.8
–1.2
–1.6
–2.0
PULSED RF INPUT 0.1GHz,
–10dBm
GND
–65
–55
–45
–35
–25
–15
–5
5
15
P
(dBm)
IN
20ns PER HORIZONTAL DIVISION
Figure 21. Output Voltage Stability vs. Supply Voltage at 1.9 GHz
When VP Varies by 10%, Multiple Devices
Figure 18. VOUT Pulse Response Time; Pulsed RF Input 0.1 GHz, –10 dBm;
CLPF = Open
Rev. B | Page 10 of 24
AD8318
THEORY OF OPERATION
CMIP, the input system common pin, provides a quality low
The AD8318 is a 9-stage demodulating logarithmic amplifier
that provides RF measurement and power amplifier control
functions. The design of the AD8318 is similar to the AD8313
logarithmic detector/controller. However, the AD8318 input
frequency range extends to 8 GHz with a 60 dB dynamic range.
Other improvements include: reduced intercept variability vs.
temperature, increased dynamic range at higher frequencies,
low noise measurement and controller output (VOUT),
adjustable low-pass corner frequency (CLPF), temperature
sensor output (TEMP), negative transfer function slope for
higher accuracy, and 10 ns response time for RF burst detection
capability. A block diagram is shown in Figure 22.
impedance connection to the printed circuit board (PCB)
ground via four package pins. Ground the package paddle,
which is internally connected to the CMIP pin, to the PCB to
reduce thermal impedance from the die to the PCB.
The logarithmic function is approximated in a piecewise
fashion by nine cascaded gain stages. For a more complete
explanation of the logarithm approximation, refer to the
AD8307 data sheet. The cells have a nominal voltage gain of
8.7 dB each and a 3 dB bandwidth of 10.5 GHz.
Using precision biasing, the gain is stabilized over temperature
and supply variations. Because the cascaded gain stages are
dc-coupled, the overall dc gain is high. An offset compensation
loop is included to correct for offsets within the cascaded cells.
At the output of each of the gain stages, a square-law detector
cell rectifies the signal. The RF signal voltages are converted to a
fluctuating differential current with an average value that
increases with signal level. Along with the nine gain stages and
detector cells, an additional detector is included at the input of
the AD8318, altogether providing a 60 dB dynamic range. After
the detector currents are summed and filtered, the function
VPSI
ENBL
TADJ
VPSO
TEMP
SENSOR
GAIN
BIAS
TEMP
SLOPE
VSET
I
I
V
V
VOUT
CLPF
DET
DET
DET
DET
INHI
INLO
CMIP
CMOP
ID × log10(VIN/VINTERCEPT
)
(1)
Figure 22. Block Diagram
is formed at the summing node,
A fully differential design, using a proprietary high speed SiGe
process, extends high frequency performance. Input INHI
receives the signal with a low frequency impedance of nominally
1200 Ω in parallel with 0.7 pF. The maximum input with 1 dB
log conformance error is typically 0 dBm (re: 50 Ω). The noise
spectral density referred to the input is 1.15 nV/√Hz, which is
equivalent to a voltage of 118 μV rms in a 10.5 GHz bandwidth,
or a noise power of −66 dBm (re: 50 Ω). This noise spectral
density sets the lower limit of the dynamic range. However, the
low end accuracy of the AD8318 is enhanced by specially
shaping the demodulating transfer characteristic to partially
compensate for errors due to internal noise.
where:
ID is the internally set detector current.
V
IN is the input signal voltage.
V
INTERCEPT is the intercept voltage (that is, when VIN = VINTERCEPT
,
the output voltage would be 0 V if capable of going to 0 V).
Rev. B | Page 11 of 24
AD8318
USING THE AD8318
BASIC CONNECTIONS
enable interface. The response time of the AD8318 ENBL
interface is shown in Figure 25.
The AD8318 is specified for operation up to 8 GHz. As a result,
low impedance supply pins with adequate isolation between
functions are essential. In the AD8318, VPSI and VPSO, the two
positive supply pins, must be connected to the same positive
potential. The VPSI pin biases the input circuitry, while the
VPSO pin biases the low noise output driver for VOUT.
Separate commons are also included in the device. CMOP is
used as the common for the output drivers. Pin CMIP and
Pin CMOP should be connected to a low impedance ground plane.
VPSI
40kΩ
DISCHARGE
ENBL
2 × V
200Ω
BE
40kΩ
2 × V
BE
ENABLE
CMIP
Figure 24. ENBL Interface
Δ: 2.07V
@: 2.07V
A power supply voltage of between 4.5 V and 5.5 V should be
applied to VPSO and VPSI. In addition, 100 pF and 0.1 μF
power supply decoupling capacitors connect close to each
power supply pin. The two adjacent VPSI pins can share a pair
of decoupling capacitors due to their proximity.
V
S
499Ω
NOTE 1
C5
0.1µF
1
C6
100pF
12
11
10
9
CMIP CMIP TADJ VPSO
T
13 TEMP
CMOP
VSET
VOUT
CLPF
8
7
6
5
EMP
C1
CH1 500mV
M400ns
A
CH1
920mV
1nF
RF
14 INHI
T
425.200ns
INPUT
R1
52.3Ω
C2
1nF
AD8318
15 INLO
16 ENBL
V
Figure 25. ENBL Response Time; VPOS = 5.0 V;
Input AC-Coupling Caps = 18 pF; CLPF = Open
OUT
NOTE 2
CMIP CMIP VPSI VPSI
INPUT SIGNAL COUPLING
V
S
1
2
3
4
The RF input to the AD8318 (INHI) is single ended and must
be ac-coupled. INLO (input common) should be ac-coupled to
ground (see Figure 23). Suggested coupling capacitors are 1 nF
ceramic, 0402-style capacitors for input frequencies of 1 MHz to
8 GHz. The coupling capacitors should be mounted close to the
INHI pin and the INLO pin. These capacitor values can be
increased to lower the input stage high-pass cutoff frequency.
The high-pass corner is set by the input coupling capacitors and
the internal 10 pF capacitor. The dc voltage on INHI and INLO
is approximately one diode voltage drop below the voltage
applied to the VPSI pin.
C7
100pF
C8
0.1µF
V
S
1
SEE TEMPERATURE COMPENSATION SECTION.
SEE RESPONSE TIME SECTION.
2
Figure 23. Basic Connections
The paddle of the AD8318 LFCSP is internally connected to
CMIP. For optimum thermal and electrical performance, solder
the paddle to a low impedance ground plane.
The Smith Chart in Figure 16 shows the AD8318 input
impedance vs. frequency. Table 4 lists the reflection coefficient
and impedance at select frequencies. For Figure 16 and Table 4,
the 52.3 ꢀ input termination resistor is removed. At dc, the
resistance is typically 2 kΩ. At frequencies up to 1 GHz, the
impedance is approximated as 1000 ꢀ||0.7 pF. The RF input
pins are coupled to a network as shown in the simplified
schematic in Figure 26.
ENABLE INTERFACE
To enable the AD8318, the ENBL pin must be pulled high.
Taking ENBL low puts the AD8318 in sleep mode, reducing
current consumption to 260 ꢁA at ambient. The voltage on
ENBL must be greater than 2 VBE (~1.7 V) to enable the device.
When enabled, the ENBL pin draws less than 1 ꢁA. When
ENBL is pulled low, the pin sources 15 ꢁA.
The enable interface has high input impedance. An internal
200 Ω resistor is placed in series with the ENBL input for added
protection. Figure 24 depicts a simplified schematic of the
Rev. B | Page 12 of 24
AD8318
VPSO
CLPF
VPSI
10pF
CURRENT
10pF
10Ω
VOUT
+
0.2V
–
FIRST
GAIN
150Ω
200Ω
20kΩ
INHI
20kΩ
STAGE
2kΩ
A = 8.6dB
CMOP
INLO
Figure 27. Output Interface
gm
STAGE
OFFSET
COMP
SETPOINT INTERFACE
Figure 26. Input Interface
The setpoint interface is shown in Figure 28. The VSET input
drives the high impedance (250 kΩ) input of an internal
operational amplifier. The VSET voltage appears across the
internal 3.13 kΩ resistor to generate ISET. When a portion
of VOUT is applied to VSET, the feedback loop forces
While the input can be reactively matched, this is typically not
necessary. An external 52.3 Ω shunt resistor (connected on the
signal side of the input coupling capacitors, see Figure 23)
combines with the relatively high input impedance to provide
an adequate broadband 50 Ω match.
−ID × log10(VIN/VINTERCEPT) = ISET
(2)
If VSET = VOUT/X, ISET = VOUT/(X × 3.13 kΩ). The result is
Table 4. Input Impedance for Select Frequency
V
OUT = (−ID × 3.13 kꢀ × X) × log10(VIN/VINTERCEPT).
Frequency
(MHz)
100
S11
Impedance Ω
(Series)
927-j491
173-j430
61-j233
28-j117
28-j102
26-j49
I
SET
Real
Imaginary
−0.041
−0.183
−0.350
−0.595
−0.616
−0.601
−0.305
−0.286
−0.062
VSET
+0.918
+0.905
+0.834
+0.605
+0.524
+0.070
−0.369
−0.326
−0.390
450
900
1900
2200
3600
5300
5800
8000
3.13kΩ
CMOP
Figure 28. VSET Interface
20-j16
22-j16
22-j3
The slope is given by −ID × X × 3.13 kΩ = −500 mV × X. For
example, if a resistor divider to ground is used to generate a
V
SET voltage of VOUT/2, X = 2. The slope is set to −1 V/decade or
The coupling time constant, 50 × CC/2, forms a high-pass
corner with a 3 dB attenuation at fHP = 1/(2π × 50 × CC ), where
C1 = C2 = CC. Using the typical value of 1 nF, this high-pass
corner is ~3.2 MHz. In high frequency applications, fHP should
be as large as possible to minimize the coupling of unwanted
low frequency signals. Likewise, in low frequency applications,
a simple RC network forming a low-pass filter should be added,
generally placed at the generator side of the coupling capacitors,
thereby lowering the required capacitance value for a given
high-pass corner frequency.
−50 mV/dB.
TEMPERATURE COMPENSATION OF OUTPUT
VOLTAGE
The AD8318 functionality includes the capability to externally
trim the temperature drift. Attaching a ground-referenced
resistor to the TADJ pin alters an internal current, minimizing
intercept drift vs. temperature. As a result, the RTADJ can be
optimized for operation at different frequencies.
I
COMP
2V
OUTPUT INTERFACE
The logarithmic output interface is shown in Figure 27. The
VOUT pin is driven by a PNP output stage. An internal 10 ꢀ
resistor is placed in series with the emitter follower output and
the VOUT pin. The rise time of the output is limited mainly by
the slew on CLPF. The fall time is an RC limited slew provided
by the load capacitance and the pull-down resistance at VOUT.
There is an internal pull-down resistor of 350 ꢀ. Any resistive
load at VOUT is placed in parallel with the internal pull-down
resistor and provides additional discharge current.
V
INTERNAL
~0.4V
2kΩ
TADJ
Figure 29. TADJ Interface
RTADJ, nominally 499 Ω for optimal temperature compensation
at 2.2 GHz input frequency, is connected between the TADJ pin
and ground (see Figure 23). The value of this resistor partially
determines the magnitude of an analog correction coefficient
that is employed to reduce intercept drift.
Rev. B | Page 13 of 24
AD8318
Table 5 lists recommended resistors for various frequencies.
These resistors provide the best overall temperature drift based
on measurements of a diverse population of devices.
MEASUREMENT MODE
When the VOUT voltage, or a portion of the VOUT voltage, is
fed back to VSET, the device operates in measurement mode.
As shown in Figure 31, the AD8318 has an offset voltage, a
negative slope, and a VOUT measurement intercept greater
than its input signal range.
The relationship between output temperature drift and frequency
is nonlinear and is not easily modeled. Experimentation is
required to choose the correct RTADJ resistor at frequencies
not listed in Table 5.
2.4
2.1
1.8
1.5
1.2
0.9
0.6
0.3
0
2.0
1.5
1.0
0.5
0
V
25°C
OUT
ERROR 25°C
Table 5. Recommended RTADJ Resistors
Frequency
900 MHz
1.9 MHz
2.2 GHz
3.6 GHz
5.8 GHz
8 GHz
Recommended RTADJ
500 Ω
500 Ω
500 Ω
51 Ω
1 kΩ
500 Ω
–0.5
–1.0
–1.5
RANGE OF
CALCULATION
OF SLOPE AND
INTERCEPT
TEMPERATURE SENSOR
The AD8318 internally generates a voltage that is proportional
to absolute-temperature (VPTAT). The VPTAT voltage is multiplied
by a factor of 5, resulting in a 2 mV/°C output at the TEMP pin.
The output voltage at 27°C is typically 600 mV. An emitter
follower drives the TEMP pin, as shown in Figure 30.
–65 –60 –55 –50 –45 –40 –35 –30 –25 –20 –15 –10 –5
0
5
10 15
INTERCEPT
P
(dBm)
IN
Figure 31. Typical Output Voltage vs. Input Signal
The output voltage vs. input signal voltage of the AD8318 is
linear-in-dB over a multidecade range. The equation for this
function is
VPSI
INTERNAL
V
OUT = X × VSLOPE/DEC × log10(VIN/VINTERCEPT
)
(3)
(4)
TEMP
= X × VSLOPE/dB × 20 × log10(VIN/VINTERCEPT
)
4kΩ
where:
1kΩ
X is the feedback factor in VSET = VOUT/X.
V
INTERCEPT is expressed in Vrms
.
CMIP
V
SLOPE/DEC is nominally −500 mV/decade and VSLOPE/dB is
Figure 30. Temp Sensor Interface
nominally −25 mV/dB.
INTERCEPT, expressed in dBV, is the x-axis intercept of the linear-
in-dB transfer function shown in Figure 31.
INTERCEPT is 7 dBV (20 dBm, re: 50 Ω or 2.239 Vrms) for a
The internal pull-down resistance is 5 kꢀ. The temperature
sensor has a slope of 2 mV/°C.
V
V
The temperature sensor output varies with output current due
to increased die temperature. Output loads less than 1 kꢀ draw
enough current from the output stage causing this increase to
occur. An output current of 10 mA results in the voltage on the
temperature sensor to increase by 1.5°C, or ~3 mV.
sinusoidal input signal.
The slope of the transfer function can be increased to
accommodate various converter mV per dB (LSB per dB)
requirements. However, increasing the slope can reduce the
dynamic range. This is due to the limitation of the minimum
and maximum output voltages, determined by the chosen
scaling factor X.
Best precision from the temperature sensor is obtained when
the supply current to AD8318 remains fairly constant, that is,
no heavy load drive.
The minimum value for VOUT is X × VOFFSET. The offset voltage,
VOFFSET, is equal to 0.5 V and is internally added to the detector
output signal.
V
OUT(MIN) = (X × VOFFSET
)
(5)
Rev. B | Page 14 of 24
AD8318
For further information on the intercept variation dependence
upon waveform, refer to the AD8313 and AD8307 data sheets.
The maximum output voltage is 2.1 V × X, and cannot exceed
400 mV below the positive supply.
V
V
OUT(MAX) = (2.1 V × X) when X < (VPOS − 400 mV)/(2.1 V) (6)
DEVICE CALIBRATION AND ERROR CALCULATION
The measured transfer function of the AD8318 at 2.2 GHz is
shown in Figure 32. The figure shows plots of both output
voltage vs. input power and calculated log conformance error
vs. input power.
OUT(MAX) = (VPOS − 400 mV) when X ≥ (VPOS − 400 mV)/ (2.1 V)
(7)
When X = 1, the typical output voltage swing is 0.5 V to 2.1 V.
The output voltage swing is modeled using Equation 5 to
Equation 7 and restricted by Equation 8:
As the input power varies from −65 dBm to 0 dBm, the output
voltage varies from 2 V to about 0.5 V.
V
OUT(MIN) < VOUT < VOUT(MAX)
(8)
V
V
V
+25°C
–40°C
+85°C
OUT
OUT
OUT
When X = 4 and VPOS = 5 V,
(X × VOFFSET) < VOUT < (VPOS − 400 mV)
(4 × 0.5 V) < VOUT < (2.1 V × 4)
2 V < VOUT < 4.6 V
VOUT
= SLOPE × (P – INTERCEPT)
IN
IDEAL
SLOPE = (V
– V
)/(P
– P )
OUT1
INTERCEPT = P
OUT2 IN1
IN2
ERROR +25°C
ERROR –40°C
ERROR +85°C
– (V
/SLOPE)
× VOUT )/SLOPE
IN1
OUT1
ERROR (dB) = (V
OUT
IDEAL
2.2
2.0
1.8
1.6
1.4
1.2
1.0
0.8
0.6
0.4
0.2
2.5
2.0
1.5
1.0
0.5
0
V
OUT2
For X = 4, slope = −100 mV/dB; VOUT can swing 2.6 V, and the
usable dynamic range is reduced to 26 dB from 0 dBm to –26 dBm.
The slope is very stable vs. process and temperature variation.
When base-10 logarithms are used, VSLOPE/DECADE represents the
output voltage per decade of input power. One decade is equal
to 20 dB; VSLOPE/DEC/20 = VSLOPE/dB represents the output voltage
slope in V/dB.
–0.5
–1.0
–1.5
–2.0
V
OUT1
As noted in Equation 3, the VOUT voltage has a negative slope.
This is the correct slope polarity to control the gain of many
power amplifiers and other VGAs in a negative feedback
configuration. Because both the slope and intercept vary
slightly with frequency, refer to Table 1 for application-specific
values for the slope and intercept.
–65 –60 –55
–45 –40 –35 –30 –25 –20 –15
–5
0
5
P
P
IN1
INTERCEPT
IN2
P
(dBm)
IN
Figure 32. Transfer Function at 2.2 GHz
Because the slope and intercept vary from device to device,
board-level calibration is performed to achieve high accuracy.
Although demodulating log amps respond to input signal
voltage, not input signal power, it is customary to discuss the
amplitude of high frequency signals in terms of power. In this
case, the characteristic impedance of the system, Z0, must be
known to convert voltages to corresponding power levels.
Beginning with the definitions of dBm and dBV,
The equation can be rewritten for output voltage, from the
Measurement Mode section, using an intercept expressed
in dBm.
V
OUT = Slope × (PIN – Intercept)
(14)
In general, the calibration is performed by applying two known
signal levels to the AD8318 input and measuring the corre-
sponding output voltages. The calibration points are generally
chosen to be within the linear-in-dB operating range of the
device (see Figure 32). Calculation of the slope and intercept is
done by:
P (dBm) = 10 × log10(Vrms2/(Z0 × 1 mW))
(9)
V (dBV) = 20 × log10(Vrms/1 Vrms
)
(10)
When Equation 9 is expanded
P (dBm) = 20 × log10(Vrms) − 10 × log10(Z0 × 1 mW)
(11)
Slope = (VOUT1 − VOUT2)/(PIN1 − PIN2
Intercept = PIN1 − VOUT1/Slope
)
(15)
(16)
and given Equation 10, Equation 11 can be rewritten as
P (dBm) = V (dBV) − 10 × log10(Z0 × 1 mW)
(12)
Once the slope and intercept are calculated, an equation can be
written to allow calculation of an (unknown) input power based
on the output voltage of the detector.
For example, PINTERCEPT for a sinusoidal input signal, expressed
in terms of dBm (decibels referred to 1 mW), in a 50 ꢀ system is
P
INTERCEPT (dBm) = VINTERCEPT (dBV)
PIN(unknown) = VOUT (measured)/Slope + Intercept
(17)
− 10 × log10(Z0 × 1 mW) =
(13)
7 dBV − 10 × log10(50 × 10−3) = 20 dBm
Rev. B | Page 15 of 24
AD8318
Using the equation for the ideal output voltage (see Equation 13) as
a reference, the log conformance error of the measured data can
be calculated as
Figure 34 shows how calibration points can be adjusted to
increase dynamic range but at the expense of linearity. In this
case, the calibration points for slope and intercept are set at
−4 dBm and −60 dBm. These points are at the end of the linear
range of the device.
Error (dB) = (VOUT(MEASURED) − VOUT(IDEAL))/Slope
(18)
Figure 32 includes a plot of the error at 25°C, the temperature at
which the log amp is calibrated. Note that the error is not zero.
This is because the log amp does not perfectly follow the ideal
Once again, at 25°C, an error of 0 dB is seen at the calibration
points. Note also that the range over which the AD8318
maintains an error of < 1 dB is extended to 60 dB at 25°C and
58 dB over temperature. The disadvantage of this approach is
that linearity suffers, especially at the top end of the input range.
V
OUT vs. PIN equation, even within its operating region. The
error at the calibration points (−12 dBm and −52 dBm, in this
case) is, however, equal to 0 by definition.
2.2
2.0
1.8
1.6
1.4
1.2
1.0
0.8
0.6
0.4
0.2
2.5
V
V
V
+25°C
–40°C
+85°C
ERROR +25°C
ERROR –40°C
ERROR +85°C
OUT
OUT
OUT
Figure 32 includes error plots for the output voltage at −40°C
and +85°C. These error plots are calculated using the slope
and intercept at 25°C. This method is consistent with a mass-
production environment where calibration at temperature is
not practical.
2.0
1.5
1.0
0.5
0
SELECTING CALIBRATION POINTS TO IMPROVE
ACCURACY OVER A REDUCED RANGE
–0.5
–1.0
–1.5
–2.0
–2.5
In some applications, very high accuracy is required at just one
power level or over a reduced input range. For example, in a
wireless transmitter, the accuracy of the high power amplifier
(HPA) is most critical at, or close to, full power.
58dB DYNAMIC RANGE (±1dB ERROR)
–65 –60 –55 –50 –45 –40 –35 –30 –25 –20 –15 –10 –5
0
5
P
(dBm)
IN
Figure 33 shows the same measured data as Figure 32. Note
that accuracy is very high from −10 dBm to −30 dBm. Below
−30 dBm, the error increases to about −1 dB. This is because
the calibration points have changed to −14 dBm and −26 dBm.
Figure 34. Dynamic Range Extension by Choosing Calibration Points
Close to the End of the Linear Range
Another way of presenting the error function of a log amp
detector is shown in Figure 35. In this case, the dB error at hot
and cold temperatures is calculated with respect to the output
voltage at ambient. This is a key difference in comparison to the
plots in Figure 33 and Figure 34. Previously, all errors were
calculated with respect to the ideal transfer function at ambient.
V
V
V
+25°C
–40°C
+85°C
ERROR +25°C
ERROR –40°C
ERROR +85°C
OUT
OUT
OUT
2.2
2.0
1.8
1.6
1.4
1.2
1.0
2.5
2.0
1.5
1.0
When this alternative technique is used, the error at ambient
becomes, by definition, equal to 0 (see Figure 35). This is valid
if the device transfer function perfectly follows the ideal
0.5
0
V
V
OUT2
–0.5
–1.0
–1.5
–2.0
–2.5
V
OUT = Slope × (PIN − Intercept) equation. However, because a
OUT1
log amp in practice never perfectly follows this equation
(especially outside of its linear operating range), this plot tends
to artificially improve linearity and extend the dynamic range.
This plot is a useful tool for estimating temperature drift at a
particular power level with respect to the (nonideal) output
voltage at ambient. However, to achieve this level of accuracy in
an end application requires calibration at multiple points in the
operating range of the device.
0.6
0.4
0.2
–65 –60 –55 –50 –45 –40 –35 –30
(dBm)
–20
–10 –5
0
5
P
IN
P
P
IN1
IN2
Figure 33. Output Voltage and Error vs. PIN with 2-Point Calibration at
−10 dBm and −30 dBm
Calibration points are chosen to suit the application at hand. In
general, the calibration points are never chosen in the nonlinear
portion of the transfer function of the log amp (above −5 dBm
or below −60 dBm, in this case).
Rev. B | Page 16 of 24
AD8318
2.2
2.0
1.8
1.6
1.4
1.2
1.0
0.8
0.6
0.4
0.2
2.5
V
V
V
+25°C
–40°C
+85°C
ERROR +25°C wrt V
ERROR –40°C wrt V
ERROR +85°C wrt V
TEMPERATURE DRIFT AT DIFFERENT
TEMPERATURES
OUT
OUT
OUT
OUT
OUT
OUT
2.0
1.5
Figure 37 shows the log slope and error over temperature for
a 5.8 GHz input signal. Error due to drift over temperature
consistently remains within 0.5 dB, and only begins to exceed
this limit when the ambient temperature drops below −20°C.
When using a reduced temperature range, higher measurement
accuracy is achievable for all frequencies.
1.0
0.5
0
–0.5
–1.0
–1.5
–2.0
–2.5
V
V
+25°C
0°C
V
V
–40°C
+70°C
V
+85°C
OUT
OUT
OUT
OUT
OUT
ERROR +25°C
ERROR 0°C
ERROR –10°C
ERROR +70°C
ERROR –20°C
–10°C
V
V
–20°C
OUT
ERROR –40°C
OUT
ERROR +85°C
2.2
2.0
1.8
1.6
1.4
1.2
1.0
0.8
0.6
0.4
0.2
2.5
–65 –60 –55 –50 –45 –40 –35 –30 –25 –20 –15 –10 –5
0
5
2.0
P
(dBm)
IN
1.5
Figure 35. Error vs. Temperature with Respect to Output Voltage at 25°C
(Does Not Take Transfer Function Nonlinearities at 25°C into Account)
1.0
0.5
VARIATION IN TEMPERATURE DRIFT FROM
DEVICE TO DEVICE
0
–0.5
–1.0
–1.5
–2.0
–2.5
Figure 36 shows a plot of output voltage and error for multiple
AD8318 devices measured at 5.8 GHz. The concentration of
black error plots represents the performance of the population
at 25°C (slope and intercept are calculated for each device).
The red and blue curves indicate the measured behavior of a
population of devices over temperature. This suggests a range
on the drift (from device to device) of 1.2 dB.
–65 –60 –55 –50 –45 –40 –35 –30 –25 –20 –15 –10 –5
0
5
P
(dBm)
IN
Figure 37. Typical Drift at 5.8 GHz for Various Temperatures
2.2
2.0
1.8
1.6
1.4
1.2
1.0
0.8
0.6
0.4
0.2
2.0
1.6
SETTING THE OUTPUT SLOPE IN MEASUREMENT
MODE
1.2
0.8
To operate in measurement mode, VOUT is connected to VSET.
This yields the typical logarithmic slope of −25 mV/dB. The
output swing corresponding to the specified input range is then
approximately 0.5 V to 2.1 V. The slope and output swing can be
increased by placing a resistor divider between VOUT and
VSET (that is, one resistor from VOUT to VSET and one
resistor from VSET to common).
0.4
0
–0.4
–0.8
–1.2
–1.6
–2.0
As an example, if two equal resistors, such as 10 kꢀ/10 kꢀ, are
used, the slope doubles to approximately −50 mV/dB. The input
impedance of VSET is approximately 500 kꢀ. Slope setting
resistors should be kept below ~50 kꢀ to prevent this input
impedance from affecting the resulting slope. When increasing
the slope, the new output voltage range cannot exceed the
output voltage swing capability of the output stage. Refer to the
Measurement Mode section for further details.
–65
–55
–45
–35
–25
–15
–5
5
15
P
(dBm)
IN
Figure 36. Output Voltage and Error vs. Temperature (+25°C, −40°C, and
+85°C) of a Population of Devices Measured at 5.8 GHz
AD8318
VOUT
–50mV/dB
10kΩ
10kΩ
VSET
Figure 38. Increasing the Slope
Rev. B | Page 17 of 24
AD8318
AD8318
OUTPUT
+5V
PULSED RF
INPUT
+5V
1nF
1nF
VPOS
40Ω
50Ω
50Ω
INHI
VOUT
52.3Ω
AD8318
INLO
ADCMP563
VSET
GND
100Ω
100Ω
50Ω 50Ω
COMPARATOR
OUTPUT
–5.2V
V
= 1.8V–1.2V
REF
–5.2V
Figure 39. AD8318 Operating with the High Speed ADCMP563 Comparator
Figure 40 shows the response of the AD8318 and the comparator
RESPONSE TIME CAPABILITY
for a 500 MHz pulsed sine wave of varying amplitudes. The
output level of the AD8318 is the signal strength of the input
signal. For applications where these RF bursts are very small,
the output level does not change by a large amount. Using a
comparator is beneficial in this case because it turns the output
of the log amp into a limiter-like signal. While this configuration
does result in the loss of received signal power level, it does
allow for presence-only detection of low power RF bursts.
The AD8318 has a 10 ns rise/fall time capability (10% to 90%)
for input power switching between the noise floor and 0 dBm.
This capability enables RF burst measurements at repetition
rates beyond 45 MHz. In most measurement applications, the
AD8318 has an external capacitor connected to CLPF to
provide additional filtering for VOUT. However, using the
CLPF capacitor slows the response time as does stray capacitance
on VOUT. For an application requiring maximum RF burst
detection capability, the CLPF pin is left unconnected. In this
case, the integration function is provided by the 1.5 pF on-chip
capacitor.
OUTPUT FILTERING
For applications in which maximum video bandwidth and,
consequently, fast rise time are desired, it is essential that the
CLPF pin be left unconnected and free of any stray capacitance.
There is a 10 ꢀ internal resistor in series with the output driver.
Because of this resistor, it is necessary to add an external 40 ꢀ
back-terminating resistor in series with the output when driving
a 50 ꢀ load. Place the back-terminating resistor close to the
VOUT pin. The AD8318 has the drive capability to drive a 50 ꢀ
load at the end of a coaxial cable or transmission line when back
terminated (see Figure 39).
To reduce the nominal output video bandwidth of 45 MHz,
connect a ground-referenced capacitor (CFLT) to the CLPF pin,
as shown in Figure 41. Generally, this is done to reduce output
ripple (at twice the input frequency for a symmetric input
waveform, such as sinusoidal signals).
AD8318
The circuit diagram in Figure 39 shows the AD8318 used with a
high speed comparator circuit. The 40 ꢀ series resistor at the
output of the AD8318 combines with an internal 10 ꢀ to
properly match to the 50 ꢀ input of the comparator.
I
LOG
VOUT
+4
3.13kΩ
CLPF
1.5pF
PULSED RF
INPUT
–50dB
–30dB
–20dB
–10dB
C
FLT
Figure 41. Lowering the Postdemodulation Bandwidth
CFLT is selected by
CFLT
AD8318
OUTPUT
1
=
− 1.5 pF
(19)
COMPARATOR
OUTPUT
(
π × 3.13 kΩ ×VideoBandwidth
)
Set the video bandwidth to a frequency equal to about one-
tenth the minimum input frequency. This ensures that the
output ripple of the demodulated log output, which is at twice
the input frequency, is well filtered.
0
100
200
300
400
500
600
700
800
TIME (ns)
Figure 40. Pulse Response of AD8318 and Comparator for RF Pulses
of Varying Amplitudes
Rev. B | Page 18 of 24
AD8318
In many log amp applications, it may be necessary to lower the
corner frequency of the postdemodulation filtering to achieve
low output ripple while maintaining a rapid response time to
changes in signal level. For an example of a 4-pole active filter,
see the AD8307 data sheet.
The basic connections for operating the AD8318 as an analog
controller with the AD8367 are shown in Figure 43. The
AD8367 is a low frequency to 500 MHz VGA with 45 dB of
dynamic range. This configuration is very similar to the one
shown in Figure 42. For applications working at high input
frequencies, such as cellular bands or WLAN, or those
requiring large gain control ranges, the AD8318 can control
the 10 MHz to 3 GHz ADL5330 RF VGA. For further details
and an application schematic, refer to the ADL5330 data sheet.
CONTROLLER MODE
The AD8318 provides a controller mode feature at the VOUT
pin. Using VSET for the setpoint voltage, it is possible for the
AD8318 to control subsystems, such as power amplifiers (PAs),
variable gain amplifiers (VGAs), or variable voltage attenuators
(VVAs) that have output power that increases monotonically
with respect to their gain control signal.
The voltage applied to the GAIN pin controls the gain of the
AD8367. This voltage, VGAIN, is scaled linear-in-dB with a slope
of 20 mV/dB and runs from 50 mV at −2.5 dB of gain up to
1.0 V at +42.5 dB.
To operate in controller mode, the link between VSET and
VOUT is broken. A setpoint voltage is applied to the VSET
input; VOUT is connected to the gain control terminal of the
VGA, and the detector RF input is connected to the output of
the VGA (usually using a directional coupler and some
additional attenuation). Based on the defined relationship
between VOUT and the RF input signal when the device is in
measurement mode, the AD8318 adjusts the voltage on VOUT
(VOUT is now an error amplifier output) until the level at the
The incoming RF signal to the AD8367 has a varying amplitude
level. Receiving and demodulating it with the lowest possible
error requires that the signal levels be optimized for the highest
signal-to-noise ratio (SNR) feeding into the analog-to-digital
converters (ADC). This is done by using an automatic gain
control (AGC) loop. In Figure 43, the voltage output of the
AD8318 modifies the gain of the AD8367 until the incoming
RF signal produces an output voltage that is equal to the
setpoint voltage VSET
.
RF input corresponds to the applied VSET
.
+3V
When the AD8318 operates in controller mode, there is no
defined relationship between VSET and VOUT voltage; VOUT settles
to a value that results in the correct input signal level appearing
at INHI/INLO.
RF INPUT SIGNAL
RF OUTPUT SIGNAL
VPOS GND
0.1µF
174Ω
AD8367
VGA
INPT
GAIN
VOUT
HPFL
57.6Ω
C
HP
100pF
In order for this output power control loop to be stable, a
ground-referenced capacitor is connected to the CLPF pin.
This capacitor, CFLT, integrates the error signal (in the form of a
current) to set the loop bandwidth and ensure loop stability. For
further details on control loop dynamics, refer to the AD8315
data sheet.
R2
R
100Ω
HP
100MHz
BANDPASS
FILTER
261Ω
R1
1kΩ
+5V
VOUT
VPOS
INHI
1nF
1nF
+V
SET
DAC
VSET
SETPOINT
VOLTAGE
AD8318
INLO
CLPF
GND
C
FLT
100pF
Figure 43. AD8318 Operating in Controller Mode to Provide Automatic Gain
Control Functionality in Combination with the AD8367
VGA/VVA
GAIN
RFIN
The AGC loop is capable of controlling signals over ~45 dB
dynamic range. The output of the AD8367 is designed to drive
loads ≥ 200 ꢀ. As a result, it is not necessary to use the 53.6 ꢀ
resistor at the input of the AD8318; the nominal input imped-
ance of 2 kꢀ is sufficient.
DIRECTIONAL
COUPLER
CONTROL
VOLTAGE
ATTENUATOR
1nF
1nF
VOUT
INHI
AD8318
52.3Ω
DAC
If the AD8367 output drives a 50 ꢀ load, such as an oscilloscope
or spectrum analyzer, use a simple resistive divider network.
The divider used in Figure 43 has an insertion loss of 11.5 dB.
Figure 44 shows the transfer function of output power vs. VSET
voltage for a 100 MHz sine wave at −40 dBm into the AD8367.
VSET
INLO
CLPF
C
FLT
Figure 42. AD8318 Controller Mode
Decreasing VSET, which corresponds to demanding a higher
signal from the VGA, tends to increase VOUT. The gain control
voltage of the VGA must have a positive sense. A positive
control voltage to the VGA increases the gain of the device.
Rev. B | Page 19 of 24
AD8318
0
1.2
10
0
–5
1.0
MAXIMUM INPUT LEVEL
–10
–15
–20
–25
–30
–35
–40
–45
–50
–55
0.8
–10
–20
–30
–40
–50
–60
–70
–80
0.6
0.4
0.2
0
–0.2
–0.4
–0.6
–0.8
–1.0
–1.2
MINIMUM INPUT LEVEL
–60
0.6
0.8
1.0
1.2
1.4
(V)
1.6
1.8
2.0
0.5
0.6
0.7
0.8
0.9
1.0
V (V)
SET
1.1
1.2
1.3
1.4
1.5
V
SET
Figure 44. AD8367 Output Power vs. AD8318 Setpoint Voltage
Figure 46. Setpoint Voltage vs. Input Power. Optimal
signal levels must be used to achieve the full 45 dB
dynamic range capabilities of the AD8367.
For the AGC loop to remain locked, the AD8318 must track the
envelope of the VGA output signal and provide the necessary
voltage levels to the AD8367 gain control input. Figure 45
shows an oscilloscope screen image of the AGC loop depicted
in Figure 43. A 50 MHz sine wave with 50% AM modulation is
applied to the AD8367. The output signal from the VGA is a
constant envelope sine wave with an amplitude corresponding
to a setpoint voltage at the AD8318 of 1.0 V.
In some cases, if VGAIN is >1.0 V it can take an unusually long
time for the AGC loop to recover; that is, the output of the
AD8318 remains at an abnormally high value and the gain is set
to its maximum level. A voltage divider is placed between the
output of the AD8318 and the AD8367 GAIN pin to ensure that
V
GAIN does not exceed 1.0 V.
In Figure 43, CHP and RHP are configured to reduce oscillation
and distortion due to harmonics at higher gain settings. Some
additional filtering is recommended between the output of the
AD8367 and the input of the AD8318. This helps to decrease
the output noise of the AD8367, which can reduce the dynamic
range of the loop at higher gain settings (smaller VSET).
AM MODULATED INPUT
1
AD8318 V
OUT
2
3
Response time and the amount of signal integration are controlled
by CFLT. This functionality is analogous to the feedback capacitor
around an integrating amplifier. Though it is possible to use
large capacitors for CFLT, in most applications, values under 1 nF
provide sufficient filtering.
AD8367 OUTPUT
CH1 50.0mV
CH3 20.0mV
CH2 200mV
M4.00ms
A
CH2
64.0mV
Calibration in controller mode is similar to the method used in
measurement mode. Do a simple 2-point calibration by applying
two known VSET voltages or DAC codes and measuring the
output power from the VGA. Slope and intercept are calculated
using Equation 20 to Equation 22:
Figure 45. Oscilloscope Screen Image Showing an AM Modulated
Input Signal to the AD8367. The AD8318 tracks the envelope
of this input signal and applies the appropriate voltage to ensure
a constant output from the AD8367.
Slope = (VSET1 − VSET2)/(POUT1 − POUT2
Intercept = POUT1 − VSET1/Slope
)
(20)
(21)
(22)
The 45 dB control range is constant for the range of VSET
voltages. The input power levels to the AD8367 must be optimized
to achieve this range. In Figure 46, the minimum and maximum
input power levels are shown vs. setpoint voltage.
VSET = Slope × (Px − Intercept)
For more information on AGC applications, refer to the
AD8367 data sheet or ADL5330 data sheet.
Rev. B | Page 20 of 24
AD8318
To measure noise spectral density, the 0 ꢀ resistor in series with
the VOUT pin is replaced with a 1 ꢁF dc blocking capacitor.
The capacitor is used because the Rohde & Schwarz FSEA
spectrum analyzer cannot handle dc voltages at its RF input.
The CLPF pin is left open for data collected for Figure 19. For
Figure 20, a 1 ꢁF capacitor is placed between CLPF and ground.
The large capacitor filters the noise from the detector stages
of the log amp. Noise spectral density measurements are taken
using the FSEA spectrum analyzer and the SMT06 signal
generator. The signal generator frequency is set to 2.2 GHz.
The spectrum analyzer has a span of 10 Hz, resolution
CHARACTERIZATION SETUP AND METHODS
The general hardware configuration used for the AD8318
characterization is shown in Figure 47. The primary setup used
for characterization is measurement mode. The characterization
board is similar to the customer evaluation board with the
exception that the RF input has a Rosenberger SMA connector
and R10 has changed to a 1 kꢀ resistor to remove cable
capacitance from the bench characterization setup. Slope and
intercept are calculated in this data sheet and in the production
environment using linear regression from −50 dBm to −10 dBm.
The slope and intercept generate an ideal line. Log conformance
error is the difference from the ideal line and the measured
output voltage for a given temperature in dB. For additional
information on the error calculation, refer to the Device
Calibration and Error Calculation section.
bandwidth of 50 Hz, video bandwidth of 50 Hz, and averages
the signal 100×. Data is adjusted to account for the dc blocking
capacitor impedance on the output at lower frequencies.
The hardware configuration for pulse response measurement
replaces the 0 ꢀ series resistor at the VOUT pin with a 40 ꢀ
resistor; the CLPF pin remains open. Pulse response time is
measured using a Tektronix TDS5104 digital phosphor
oscilloscope. Both channels on the scope are configured for
50 ꢀ termination. The 10 ꢀ internal series resistance at VOUT,
combined with the 40 ꢀ resistor, attenuates the output voltage
level by two. RF input frequency is set to 100 MHz with
−10 dBm at the input of the device. The RF burst is generated
using a Rohde & Schwarz SMT06 with the pulse option with a
period of 1.5 μs, a width of 0.1 ꢁs, and a pulse delay of 0.04 ꢁs.
The output response is triggered using the video output from
the SMT06. Refer to Figure 47 for an overview of the test setup.
ROHDE & SCHWARZ
SMT06
TEKTRONIX
TDS5104
VIDEO RF OUT
OUT
–7dBm
5V
CH1* CH3* TRIGGER
3dB
SPLITTER
*50Ω
TERMINATION
VPOS
1nF
52.3Ω
1nF
40Ω
INHI
VOUT
AD8318
INLO
VSET
GND
Figure 47. Pulse Response Measurement Test Setup
Rev. B | Page 21 of 24
AD8318
EVALUATION BOARD
Table 6. Evaluation Board (Rev. A) Bill of Materials
Component
Function
Default Conditions
Not Applicable
SW1 = A
VP, GND
Supply and Ground Connections
SW1, R3
Device Enable. When in Position A, the ENBL pin is connected to VP and the
AD8318 is in operating mode. In Position B, the ENBL pin is grounded through
R3, putting the device in power-down mode. The ENBL pin may be exercised
by a pulse generator connected to ENBL SMA and SW1 in Position B.
R3 = 10 kΩ (Size 0603)
R1, C1, C2
Input Interface. The 52.3 Ω resistor (R1) combines with the AD8318 internal
input impedance to give a broadband input impedance of 50 Ω. C1 and C2 are
dc-blocking capacitors. A reactive impedance match can be implemented by
replacing R1 with an inductor and C1 and C2 with appropriately valued
capacitors.
R1 = 52.3 Ω (Size 0402)
C1 = 1 nF (Size 0402)
C2 = 1 nF (Size 0402)
R2
R4
Temperature Sensor Interface. The temperature sensor output voltage is
available at the SMA labeled TEMP via the current limiting resistor, R2.
R2 = 1 kΩ (Size 0402)
Temperature Compensation Interface. The internal temperature compensation R4 = 499 Ω (Size 0603)
resistor is optimized for an input signal of 2.2 GHz when R4 is 500 Ω. This circuit
can be adjusted to optimize performance for other input frequencies by
changing the value of Resistor R4. See the Temperature Compensation of
Output Voltage section.
R7, R8, R9, R10
R7, R8, R9, R10
Output Interface—Measurement Mode. In measurement mode, a portion of
the output voltage is fed back to the VSET pin via R7. The magnitude of the
slope at VOUT can be increased by reducing the portion of VOUT that is fed back
to VSET. R10 can be used as a back-terminating resistor or as part of a single-
pole, low-pass filter.
R7 = 0 Ω = (Size 0402)
R8 = open (Size 0402)
R9 = open (Size 0402
R10 = 0 Ω (Size 0402)
Output Interface—Controller Mode. In this mode, R7 must be open. In
controller mode, the AD8318 can control the gain of an external component. A
setpoint voltage is applied to the VSET pin, the value of which corresponds to
the desired RF input signal level applied to the AD8318 RF input. The
magnitude of the control voltage is optionally attenuated via the voltage
divider comprised of R8 and R9, or a capacitor can be installed in R8 to form a
low-pass filter along with R9. See the Controller Mode section for more details.
R7 = open (Size 0402)
R8 = open (Size 0402)
R9 = 0 Ω (Size 0402)
R10 = 0 Ω (Size 0402)
C5, C6, C7, C8, R5, R6
Power Supply Decoupling. The nominal supply decoupling consists of a 100 pF C5 = 0.1 ꢀF (Size 0603)
filter capacitor placed physically close to the AD8318, a 0 Ω series resistor, and
a 0.1 ꢀF capacitor placed closer to the power supply input pin.
C6 = 100 pF (Size 0402)
C7 = 100 pF (Size 0402)
C8 = 0.1 ꢀF (Size 0603)
R5 = 0 Ω (Size 0603)
R6 = 0 Ω (Size 0603)
C9 = open (Size 0603)
C9
Loop Filter Capacitor. The low-pass corner frequency of the circuit that drives
the VOUT pin can be lowered by placing a capacitor between CLPF and
ground. Increasing this capacitor increases the overall rise/fall time of the
AD8318 for pulsed input signals. See the Output Filtering section for more details.
Rev. B | Page 22 of 24
AD8318
V
POS
R4
499Ω
C5
0.1µF
R5
0Ω
C6
100pF
12
11
10
9
CMIP CMIP TADJ VPSO
R2
1kΩ
13 TEMP
CMOP
VSET
VOUT
CLPF
8
7
6
5
R8
T
EMP
OPEN
C1 1nF
C2 1nF
14 INHI
V
V
SET
R1
52.3Ω
R7
0Ω
R9
AD8318
R
FIN
OPEN
15 INLO
16 ENBL
OUT
R10
0Ω
CMIP CMIP VPSI VPSI
A
B
V
C9
OPEN
1
2
3
4
E
POS
NBL
R3
10kΩ
SW1
C7
100pF
R6
0Ω
GND
VP
C8
0.1µF
V
POS
Figure 48. Evaluation Board Schematic
Figure 50. Component Side Silkscreen
Figure 49. Component Side Layout
Rev. B | Page 23 of 24
AD8318
OUTLINE DIMENSIONS
4.00
0.60 MAX
(BOTTOM VIEW)
BSC SQ
0.60 MAX
0.65 BSC
PIN 1
INDICATOR
13
16
1
12
PIN 1
INDICATOR
2.25
2.10 SQ
1.95
TOP
VIEW
3.75
BSC SQ
EXPOSED
PAD
0.75
0.60
0.50
9
4
8
5
0.25 MIN
1.95 BSC
0.80 MAX
0.65 TYP
12° MAX
0.05 MAX
0.02 NOM
1.00
0.85
0.80
0.35
0.30
0.25
0.20 REF
COPLANARITY
0.08
SEATING
PLANE
COMPLIANT TO JEDEC STANDARDS MO-220-VGGC
Figure 51. 16-Lead Lead Frame Chip Scale Package [LFCSP_VQ]
4 mm × 4 mm Body, Very Thin Quad
(CP-16-4)
Dimensions shown in millimeters
ORDERING GUIDE
Ordering
Quantity
Model
Temperature Range
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
Package Description
Package Option
CP-16-4
CP-16-4
AD8318ACPZ-REEL71
AD8318ACPZ-R21
AD8318ACPZ-WP1, 2
AD8318-EVALZ1
16-Lead Lead Frame Chip Scale Package [LFCSP_VQ]
16-Lead Lead Frame Chip Scale Package [LFCSP_VQ]
16-Lead Lead Frame Chip Scale Package [LFCSP_VQ]
Evaluation Board
1,500
250
64
CP-16-4
1 Z = RoHS compliant part.
2 WP = waffle pack.
©2004-2007 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D04853-0-4/07(B)
Rev. B | Page 24 of 24
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