AD AD8318

Circuit Note
CN-0150
Devices Connected/Referenced
Circuits from the Lab™ reference circuits are engineered and
tested for quick and easy system integration to help solve today’s
analog, mixed-signal, and RF design challenges. For more
information and/or support, visit www.analog.com/CN0150.
AD8318
1 MHz to 8 GHz, 70 dB, Logarithmic
Detector/Controller
AD7887
2.7 V to 5.25 V, Micropower, 2-Channel,
125 kSPS, 12-Bit ADC in 8-Lead MSOP
ADR421
Precision, Low Noise, 2.5 V Reference
Software-Calibrated, 1 MHz to 8 GHz, 60 dB RF Power
Measurement System Using a Logarithmic Detector
A simple two-point system calibration is performed in the
digital domain.
EVALUATION AND DESIGN SUPPORT
Circuit Evaluation Boards
CN-0150 Circuit Evaluation Board (EVAL-CN0150A-SDPZ)
System Demonstration Platform (EVAL-SDP-CB1Z)
Design and Integration Files
Schematics, Layout Files, Bill of Materials
The AD8318 maintains accurate log conformance for signals of
1 MHz to 6 GHz and provides useful operation to 8 GHz.
The device provides a typical output voltage temperature
stability of ±0.5 dB.
CIRCUIT FUNCTION AND BENEFITS
This circuit measures RF power at any frequency from
1 MHz to 8 GHz over a range of approximately 60 dB. The
measurement result is provided as a digital code at the output of
a 12-bit ADC with serial interface and integrated reference. The
output of the RF detector has a glueless interface to the ADC and
uses most of the ADC’s input range without further adjustment.
The AD7887 ADC can be configured for either dual or single
channel operation via the on-chip control register. There is a
default single-channel mode that allows the AD7887 to be operated
as a read-only ADC, thereby simplifying the control logic.
Typical data is shown for the two devices operating over a
−40°C to +85°C temperature range.
+5V
VPOS
R4
499Ω
12
11
C5
0.1µF
10
9
10µF
0.1µF
C6
100pF
13 TEMP
PULSED RF
INPUT
C1 1nF
RFIN
R1
52.3Ω
C2 1nF
CMOP 8
14 INHI
15 INLO
16 ENBL
1
SEE
TEXT
VOUT 6
0.1µF
CLPF 5
CMIP CMIP
2
VPSI
VPSI
3
4
AD7887
VOUT
VSET 7
AD8318
SERIAL
INTERFACE
VDD
CMIP CMIP TADJ VPSO
C9
0.1µF
AIN0
SCLK
AIN1/
VREF
DOUT
GND
µC/µP
DIN
CS
C7
100pF
C8
0.1µF
08967-001
VPOS
Figure 1. Software-Calibrated RF Measurement System (Simplified Schematic: All Connections Not Shown)
Rev. C
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CN-0150
Circuit Note
CIRCUIT DESCRIPTION
The RF signal being measured is applied to the AD8318. The
device is configured in its so-called measurement mode, with
the VSET and VOUT pins connected together. In this mode,
the output voltage vs. the input signal level is linear-in-dB
(nominally −24 mV/dB) and has a typical output voltage range
of 0.5 V to 2.1 V.
The AD8318 output is connected directly to the AD7887, 12-bit
ADC. The ADC uses its internal reference and is configured for
a 0 V to 2.5 V input, resulting in an LSB size of 610 μV. With the RF
detector providing a nominal −24 mV/dB, the digital resolution
is 39.3 LSBs/dB. With this much resolution, there is little value
in trying to scale the 0.5 V to 2.1 V signal from the RF detector
to exactly fit the 0 V to 2.5 V range of the ADC.
The transfer function of the detector can be approximated by
the equation
Using the two known input power levels, PIN_1 and PIN_2,
and the corresponding observed ADC codes, CODE_1 and
CODE_2, SLOPE_ADC, and INTERCEPT can be calculated
using the following equations:
SLOPE_ADC = (CODE_2 − CODE_1)/(PIN_2 − PIN_1)
INTERCEPT = PIN_2 − (CODE_2/SLOPE_ADC)
Once SLOPE_ADC and INTERCEPT are calculated and stored (in
nonvolatile RAM) during factory calibration, they can be used
to calculate an unknown input power level, PIN, when the
equipment is in operation in the field using the equation
PIN = (CODE_OUT/SLOPE_ADC) + INTERCEPT
Figure 3 through Figure 8 show how the system transfer function
deviates from this straight line equation, particularly at the
endpoints of the transfer function. This deviation is expressed
in dB using the equation
Error (dB) = Measured Input Power − True Input Power =
(CODE_OUT/SLOPE_ADC) + INTERCEPT – PIN_TRUE
VOUT = SLOPE × (PIN − INTERCEPT)
where SLOPE is in mV/dB (−24 mV/dB nominal); INTERCEPT is
the x-axis intercept with a unit of dBm (20 dBm nominal);
and PIN is the input power expressed in dBm. A typical plot
of detector output voltage vs. input power is shown in Figure 2.
1.5
1.5
0.5
1.2
0
–0.5
0.9
0.6
0.3
RANGE OF
CALCULATION
OF SLOPE AND
INTERCEPT
0
–65 –60 –55 –50 –45 –40 –35 –30 –25 –20 –15 –10 –5
PIN (dBm)
–1.0
–1.5
0
5
10 15
INTERCEPT
Figure 2. Typical Output Voltage vs. Input Signal Level for the AD8318
The plots shown in Figure 3 through Figure 8 show the typical
system performance that can be obtained using the AD8318 and
AD7887BR in an RF power measurement system. The graphs
depict the RF input power in dBm vs. the ADC output code and
output error in dB (scaled on the axes on the right side of the
plots). They were generated from data taken with various input
power levels, frequencies, and temperatures and with both internal
and external ADC voltage references. The charts show improved
system performance and lower temperature drift with the use of
a low drift external ADC voltage reference. (See the Common
Variations section for more details about the use of an external
reference.
A complete design support package for this circuit note can be
found at www.analog.com/CN0150-DesignSupport.
At the output of the ADC, the equation can be written as
CODE_OUT = SLOPE_ADC × (PIN − INTERCEPT)
4
4.0k
Because the slope and intercept of the system vary from device
to device, a system level calibration is required. A calibration is
performed by applying two known signal levels close to the
endpoints of the AD8318 linear input range and measuring the
corresponding output codes from the ADC. The calibration
points chosen should be well within the linear operating
range of the device (−10 dBm and −50 dBm in this case).
3.5k
3.0k
CODE_2
ADC CODE
where SLOPE_ADC is in codes/dB and PIN and INTERCEPT
are in dBm. Figure 3 shows a typical detector power sweep in
terms of input power and observed ADC codes.
+25°C CODE
–40°C CODE
+85°C CODE
+25°C ERROR
–40°C ERROR
+85°C ERROR
3
2
2.5k
1
2.0k
0
1.5k
–1
1.0k
–2
0.5k
–3
CODE_1
0
–70
OUTPUT ERROR (dBm)
1.0
–4
–60 –50
–40
–30
–20 –10
0
10
INPUT POWER (dBm)
PIN_2
PIN_1
Figure 3. Input = 900 MHz, ADC Using an Internal 2.5 V Reference
Rev. C | Page 2 of 5
08967-003
1.8
08967-002
VOUT (V)
2.1
2.0
VOUT 25°C
ERROR 25°C
ERROR (dB)
2.4
where:
CODE_OUT is the ADC output code.
SLOPE_ADC is the stored ADC slope in codes/dB.
INTERCEPT is the stored intercept.
PIN_TRUE is the exact (and unknown) input level.
Circuit Note
CN-0150
2
3.0k
2.0k
0
1.5k
–1
1.0k
–2
0.5k
–3
0
–70
–60
–50
–40
–30
–20
–10
0
10
–4
INPUT POWER (dBm)
–1
1.0k
–2
0.5k
–3
–20
–10
0
10
–4
ADC CODE
1.5k
–30
INPUT POWER (dBm)
ADC CODE
3.0k
2
0
1.5k
–1
1.0k
–2
0.5k
–3
–40
–30
–20
–10
0
10
–30
–20
–10
0
10
–4
4
+25°C CODE
–40°C CODE
+85°C CODE
+25°C ERROR
–40°C ERROR
+85°C ERROR
3
2
2.5k
1
2.0k
0
1.5k
–1
1.0k
–2
0.5k
–3
–60
–50
–40
–30
–20
–10
0
10
–4
INPUT POWER (dBm)
The AD7887 is a 2-channel, 12-bit ADC with an SPI interface.
The second input channel of this device can be connected to the
AD8318 TEMP pin. This provides a convenient measure of the
ambient temperature around the AD8318. Like the AD8318
power measurement output, the TEMP voltage output should
also be calibrated.
2.0k
–50
–40
COMMON VARIATIONS
1
–60
–50
3
2.5k
0
–70
–60
4
–4
INPUT POWER (dBm)
Figure 6. Input = 1.9 GHz, ADC Using an External 2.5 V Reference
OUTPUT ERROR (dBm)
3.5k
–3
Figure 8. Input = 2.2 GHz, ADC Using an External 2.5 V Reference
08967-006
+25°C CODE
–40°C CODE
+85°C CODE
+25°C ERROR
–40°C ERROR
+85°C ERROR
0.5k
0
–70
Figure 5. Input = 1.9 GHz, ADC Using an Internal 2.5 V Reference
4.0k
–2
3.0k
0
–40
1.0k
2
2.0k
–50
–1
3.5k
1
–60
1.5k
3
2.5k
0
–70
0
Figure 7. Input = 2.2 GHz, ADC Using an Internal 2.5 V Reference
OUTPUT ERROR (dBm)
ADC CODE
3.0k
2.0k
4.0k
08967-005
3.5k
1
INPUT POWER (dBm)
4
+25°C CODE
–40°C CODE
+85°C CODE
+25°C ERROR
–40°C ERROR
+85°C ERROR
2.5k
0
–70
Figure 4. Input = 900 MHz, ADC Using an External 2.5 V Reference
4.0k
2
OUTPUT ERROR (dBm)
1
3
08967-008
2.5k
+25°C CODE
–40°C CODE
+85°C CODE
+25°C ERROR
–40°C ERROR
+85°C ERROR
OUTPUT ERROR (dBm)
3.5k
ADC CODE
ADC CODE
3.0k
3
OUTPUT ERROR (dBm)
3.5k
4
4.0k
08967-004
+25°C CODE
–40°C CODE
+85°C CODE
+25°C ERROR
–40°C ERROR
+85°C ERROR
08967-007
4
4.0k
If the end application requires only a single channel, the 12-bit
AD7495 can be used. In multichannel applications that require
multiple ADCs and DAC channels, the AD7294 can be used.
In addition to providing four 12-bit DAC outputs, this subsystem
chip includes four uncommitted ADC channels, two high-side
current sense inputs, and three temperature sensors. Current
and temperature measurements are digitally converted and
available to read over the I2C-compatible interface.
The temperature stability of the circuit can be improved using an
external ADC reference. The AD7887 internal 2.5 V reference has
a 50 ppm/°C drift, which is approximately 15 mV over a 125°C
range. Because the detector has a slope of −24 mV/dB, the ADC
reference drift contributes approximately ±0.3 dB to the temperature
drift error budget. The AD8318 temperature drift is approximately
±0.5 dB over a similar temperature range. (This varies with
frequency. See the AD8318 data sheet for more details.)
Rev. C | Page 3 of 5
CN-0150
Circuit Note
If an external voltage reference is to be used, the ADR421 2.5 V
reference is recommended. Its 1 ppm/°C temperature drift results
in a reference voltage variation of only 312 μV from −40°C to
+85°C. This has a negligible effect on the overall temperature
stability of the system.
6 V wall wart can be connected to the barrel connector on the
board and used in place of the 6 V power supply. Connect the USB
cable supplied with the SDP board to the USB port on the PC.
Note: Do not connect the USB cable to the mini USB connector
on the SDP board at this time.
If a less dynamic range is required, the AD8317 (55 dB) or AD8319
(45 dB) log detector can be used. If a true rms responding power
measurement is required, the AD8363 (50 dB) or ADL5902
(65 dB) can be used.
Test
CIRCUIT EVALUATION AND TEST
Apply power to the 6 V supply (or wall wart) connected to
EVAL-CN0150A-SDPZ circuit board. Launch the evaluation
software and connect the USB cable from the PC to the USB
mini connector on the SDP board.
This circuit uses the EVAL-CN0150A-SDPZ circuit board and
the EVAL-SDP-CB1Z System Demonstration Platform (SDP)
evaluation board. The two boards have 120-pin mating connectors,
allowing for the quick setup and evaluation of the circuit’s
performance. The EVAL-CN0150A-SDPZ board contains the
circuit to be evaluated, as described in this note, and the SDP
evaluation board is used with the CN0150A evaluation software to
capture the data from the EVAL-CN0150A-SDPZ circuit board.
Once USB communications are established, the SDP board can
now be used to send, receive, and capture serial data from the
EVAL-CN0150A-SDPZ board.
Equipment Needed
Temperature testing was performed using a Test Equity Model 107
environmental chamber. The EVAL-CN0150A-SDPZ evaluation
board was placed in the chamber via a slot in the test chamber
door, with the SDP evaluation board extending outside.
• PC with a USB port and Windows® XP or Windows Vista®
(32-bit), or Windows 7 (32-bit)
• EVAL-CN0150A-SDPZ Circuit Evaluation Board
The data in this circuit note were generated using a Rohde &
Schwarz SMT-03 RF signal source and an Agilent E3631A power
supply. The signal source was set to the frequencies indicated in
the graphs, and the input power was stepped and data recorded
in 1 dB increments.
Information and details regarding how to use the evaluation
software for data capture can be found in the CN0150A
evaluation software readme file.
• EVAL-SDP-CB1Z SDP Evaluation Board
• CN0150A Evaluation Software
• Power supply: 6 V or 6 V wall wart
Information regarding the SDP board can be found in the SDP
User Guide.
• Environmental chamber
• RF signal source
LEARN MORE
• Coaxial RF cable with SMA connectors
CN0150 Design Support Package:
http://www.analog.com/CN0150-DesignSupport
Getting Started
SDP User Guide
Load the evaluation software by placing the CN0150A evaluation
software CD in the CD drive of the PC. Using My Computer,
locate the drive that contains the evaluation software CD and
open the readme file. Follow the instructions contained in the
readme file for installing and using the evaluation software.
MT-031 Tutorial, Grounding Data Converters and Solving the
Mystery of “AGND” and “DGND,” Analog Devices.
MT-077 Tutorial, Log Amp Basics, Analog Devices.
MT-078 Tutorial, High Speed Log Amps, Analog Devices.
Functional Block Diagram
MT-101 Tutorial, Decoupling Techniques, Analog Devices.
See Figure 1 of this circuit note for the circuit block diagram
and the EVAL-CN150A-SDPZ-SCH-Rev0.pdf file for the
circuit schematics. This file is contained in the CN0150
Design Support Package.
Whitlow, Dana. Design and Operation of Automatic Gain
Control Loops for Receivers in Modern Communications
Systems. Chapter 8. Analog Devices Wireless Seminar. 2006.
Setup
Connect the 120-pin connector on the EVAL-CN0150A-SDPZ
circuit board to the CON A connector on the EVAL-SDP-CB1Z
evaluation (SDP) board. Use nylon hardware to firmly secure
the two boards, using the holes provided at the ends of the 120-pin
connectors. Using an appropriate RF cable, connect the RF signal
source to the EVAL-CN0150A-SDPZ board via the SMA RF
input connector. With power to the supply off, connect a 6 V power
supply to the +6V and GND pins on the board. If available, a
Data Sheets and Evaluation Boards
CN-0150 Circuit Evaluation Board (EVAL-CN0150A-SDPZ)
System Demonstration Platform (EVAL-SDP-CB1Z)
AD7887 Data Sheet
AD7887 Evaluation Board
AD8318 Data Sheet
AD8318 Evaluation Board
ADR421 Data Sheet
Rev. C | Page 4 of 5
Circuit Note
CN-0150
REVISION HISTORY
2/12—Rev. B to Rev. C
Changed 70 dB to 60 dB in Circuit Note Title ..............................1
3/11—Rev. A to Rev. B
Added Evaluation and Design Support Section............................1
Added Circuit Evaluation and Test Section...................................4
8/10— Rev. 0 to Rev. A
Changes to the Circuit Function and Benefits Section ................1
Changes to the Circuit Description Section ..................................2
Changes to the Common Variations Section ................................4
4/10—Revision 0: Initial Version
I2C refers to a communications protocol originally developed by Philips Semiconductors (now NXP Semiconductors).
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CN08967-0-2/12(C)
Rev. C | Page 5 of 5