AD ADL5310ACP-REEL7 120 db range (3 na to 3 ma) dual logarithmic converter Datasheet

120 dB Range (3 nA to 3 mA)
Dual Logarithmic Converter
ADL5310
FUNCTIONAL BLOCK DIAGRAM
FEATURES
665kΩ
VREF
OUT1
4.99kΩ
IRF1
SCL1
VBIAS
VNEG
I
TEMPERATURE LOG
COMPENSATION
451Ω
LOG1
14.2kΩ
IPD1
INP1
OUT2
IRF2
80kΩ
REFERENCE
GENERATOR
VOUT2
4.99kΩ
20kΩ
2.5V
COMM
VBIAS
SCL2
BIN2
14.2kΩ
VNEG
PRODUCT DESCRIPTION
The ADL5310 employs an optimized translinear structure that
use the accurate logarithmic relationship between a bipolar
transistor’s base emitter voltage and collector current, with
appropriate scaling by precision currents to compensate for the
inherent temperature dependence. Input and reference current
pins sink current ranging from 3 nA to 3 mA (limited to ±60 dB
between input and reference) into a fixed voltage defined by the
VSUM potential. The VSUM potential is internally set to
500 mV but may be externally grounded for dual-supply operation, and for additional applications requiring voltage inputs.
BIN1
6.69kΩ
APPLICATIONS
The ADL53101 low cost, dual logarithmic amplifier converts
input current over a wide dynamic range to a linear-in-dB
output voltage. It is optimized to determine the optical power
in wide-ranging optical communication system applications,
including control circuitry for lasers, optical switches, attenuators, and amplifiers, as well as system monitoring. The device
is equivalent to a dual AD8305 with enhanced dynamic range
(120 dB). While the ADL5310 contains two independent signal
channels with individually configurable transfer function
constants (slope and intercept), internal bias circuitry is shared
between channels for improved power consumption and
channel matching. Dual converters in a single, compact LFCSP
package yield space-efficient solutions for measuring gain or
attenuation across optical elements. Only a single supply is
required; optional dual-supply operation offers added flexibility.
VOUT1
COMM
0.5V
Gain and absorbance measurements
Multichannel power monitoring
General-purpose baseband log compression
VRDZ
VSUM
I
TEMPERATURE LOG
COMPENSATION
451Ω
LOG2
6.69kΩ
IPD2
INP2
COMM
VSUM
665kΩ
VREF
Figure 1.
The logarithmic slope is set to 10 mV/dB (200 mV/decade)
nominal and can be modified using external resistors and the
independent buffer amplifiers. The logarithmic intercepts for
each channel are defined by the individual reference currents,
which are set to 3 μA nominal for maximum input range by
connecting 665 kΩ resistors between the 2.5 V VREF pins and
the IRF1 and IRF2 inputs. Tying VRDZ to VREF effectively sets
the x-intercept four decades below the reference current—
typically 300 pA for a 3 µA reference.
The use of individually optimized reference currents may
be valuable when using the ADL5310 for gain or absorbance
measurements where each channel input has a different currentrange requirement. The reference current inputs
are also fully functional dynamic inputs, allowing log ratio
operation with the reference input current as the denominator.
The ADL5310 is specified for operation from –40°C to +85°C.
1
US Patents: 4,604,532, 5,519,308. Other patents pending.
Rev. A
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
registered trademarks are the property of their respective owners.
04415-0-001
2 independent channels optimized for photodiode
interfacing
6-decade input dynamic range
Law conformance 0.3 dB from 3 nA to 3 mA
Temperature-stable logarithmic outputs
Nominal slope 10 mV/dB (200 mV/dec), externally scalable
Intercepts may be independently set by external resistors
User-configurable output buffer amplifiers
Single- or dual-supply operation
Space-efficient, 24-lead 4 mm × 4 mm LFCSP
Low power: < 10 mA quiescent current
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
www.analog.com
Tel: 781.329.4700
Fax: 781.326.8703
© 2004 Analog Devices, Inc. All rights reserved.
ADL5310
TABLE OF CONTENTS
Specifications..................................................................................... 3
Applications..................................................................................... 13
Absolute Maximum Ratings............................................................ 4
Calibration................................................................................... 14
Pin Configuration and Function Descriptions............................. 5
Minimizing Crosstalk ................................................................ 14
Typical Performance Characteristics ............................................. 6
Relative and Absolute Power Measurements .......................... 15
General Structure............................................................................ 11
Characterization Methods......................................................... 16
Theory.......................................................................................... 11
Evaluation Board ............................................................................ 17
Managing Intercept and Slope .................................................. 12
Outline Dimensions ....................................................................... 20
Response Time and Noise Considerations.............................. 12
Ordering Guide........................................................................... 20
REVISION HISTORY
9/04—Data Sheet Changed from Rev. 0 to Rev. A
Changes to Ordering Guide .......................................................... 20
11/03—Revision 0: Initial Version
Rev. A | Page 2 of 20
ADL5310
SPECIFICATIONS
VP = 5 V, VN = 0 V, TA = 25°C, RREF = 665 kΩ, and VRDZ connected to VREF, unless otherwise noted.
Table 1.
Parameter
INPUT INTERFACE
Specified Current Range, IPD
Input Current Min/Max Limits
Reference Current, IREF, Range
Summing Node Voltage
Temperature Drift
Input Offset Voltage
Conditions
Pins 1 to 6: INP1 and INP2, IRF1 and IRF2, VSUM
Flows toward INP1 pin or INP2 pin
Flows toward INP1 pin or INP2 pin
Flows toward IRF1 pin or IRF2 pin
Internally preset; user alterable
–40°C < TA < +85°C
VIN − VSUM, VIREF − VSUM
LOGARITHMIC OUTPUTS
Logarithmic Slope
Pin 15 and Pin 16: LOG1 and LOG2
–40°C < TA < +85°C
Logarithmic Intercept1
Law Conformance Error
Wideband Noise2
Small Signal Bandwidth
Maximum Output Voltage
Minimum Output Voltage
Output Resistance
REFERENCE OUTPUT
Voltage wrt Ground
2
Maximum Output Current
Incremental Output Resistance
OUTPUT BUFFERS
Input Offset Voltage
Input Bias Current
Incremental Input Resistance
Incremental Output Resistance
Output High Voltage
Output Low Voltage
Peak Source/Sink Current
Small-Signal Bandwidth
Slew Rate
POWER SUPPLY
Positive Supply Voltage
Quiescent Current
Negative Supply Voltage (Optional)
1
2
–40°C < TA < +85°C
10 nA < IPD < 1 mA
3 nA < IPD < 3 mA
IPD > 3 µA; output referred
IPD = 3 µA
Min
Typ
3n
3n
0.46
0.5
0.030
Limited by VN = 0 V
4.375
Unit
3m
10 m
3m
0.54
A
A
A
V
mV/°C
mV
+20
−20
190
185
165
40
Max
200
300
0.1
0.3
0.5
1.5
1.7
0.10
5
210
215
535
1940
0.4
0.6
5.625
mV/dec
mV/dec
pA
pA
dB
dB
µV/√Hz
MHz
V
V
kΩ
Pin 7 and Pin 24 (internally shorted): VREF
–40°C < TA < +85°C
Sourcing (grounded load)
Load current < 10 mA
Pins 12 to 14 and 17 to 19: OUT2, SCL2, BIN2, BIN1, SCL1,
and OUT1
2.45
2.42
2.5
−20
+20
mV
µA
MΩ
Ω
V
0.4
35
0.5
VP −
0.1
0.10
30
15
15
Load current < 10 mA; gain = 1
RL = 1 kΩ to ground
RL = 1 kΩ to ground
3
−5.5
Other values of logarithmic intercept can be achieved by adjustment of RREF.
Output noise and incremental bandwidth are functions of input current; measured using output buffer connected for GAIN = 1.
Rev. A | Page 3 of 20
V
V
mA
Ω
20
4
Flowing out of Pins 13, 14, 17, and 18
Gain = 1
0.2 V to 4.8 V output swing
Pins 8 and 9: VPOS; Pins 10, 11, and 20: VNEG
(VP – VN ) ≤ 12 V
Input currents < 10 µA
(VP – VN ) ≤ 12 V
2.55
2.58
5
9.5
0
V
mA
MHz
V/µs
12
11.5
V
mA
V
ADL5310
ABSOLUTE MAXIMUM RATINGS
Table 2.
Parameter
Supply Voltage VP − VN
Input Current
Internal Power Dissipation
θJA
Maximum Junction Temperature
Operating Temperature Range
Storage Temperature Range
Lead Temperature Range (Soldering 60 sec)
1
Rating
12 V
20 mA
500 mW
35°C/W1
125°C
–40°C to +85°C
−65°C to +150°C
300°C
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 listed in the operational sections
of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect
device reliability.
With paddle soldered down.
ESD CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily accumulate on
the human body and test equipment and can discharge without detection. Although this product features
proprietary ESD protection circuitry, permanent damage may occur on devices subjected to high energy
electrostatic discharges. Therefore, proper ESD precautions are recommended to avoid performance
degradation or loss of functionality.
Rev. A | Page 4 of 20
ADL5310
VREF
VRDZ
COMM
COMM
VNEG
OUT1
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
24
23
22
21
20
19
18
SCL1
2
17
BIN1
IRF1 3
16
LOG1
VSUM 1
INP1
PIN 1
INDICATOR
ADL5310
DUAL LOG AMP
15
LOG2
INP2 5
TOP VIEW
(Not to Scale)
14
BIN2
13
SCL2
8
9
10
11
12
VPOS
VNEG
VNEG
OUT2
VREF
7
VPOS
VSUM 6
04415-0-002
IRF2 4
Figure 2. 24-Lead LFCSP Pin Configuration
Table 3. Pin Function Descriptions
Pin No.
1, 6
Mnemonic
VSUM
2
INP1
3
4
5
IRF1
IRF2
INP2
7, 24
8, 9
10, 11, 20
VREF
VPOS
VNEG
12
13
14
15
16
17
18
19
21, 22
23
OUT2
SCL2
BIN2
LOG2
LOG1
BIN1
SCL1
OUT1
COMM
VRDZ
Function
Guard Pin. Used to shield the INP1 and INP2 input current lines, and for optional adjustment of the input
summing node potentials. Pin 1 and Pin 6 are internally shorted.
Channel 1 Numerator Input. Accepts (sinks) photodiode current IPD1. Usually connected to photodiode anode
such that photocurrent flows into INP1.
Channel 1 Denominator Input. Accepts (sinks) reference current, IRF1.
Channel 2 Denominator Input. Accepts (sinks) reference current, IRF2.
Channel 2 Numerator Input. Accepts (sinks) photodiode current IPD2. Usually connected to photodiode anode
such that photocurrent flows into INP2.
Reference Output Voltage of 2.5 V. Pin 7 and Pin 24 are internally shorted.
Positive Supply, (VP – VN) ≤ 12 V. Both pins must be connected externally.
Optional Negative Supply, VN. These pins are usually grounded. For more details, see the General Structure and
Applications sections. All VNEG pins must be connected externally.
Buffer Output for Channel 2.
Buffer Amplifier Inverting Input for Channel 2.
Buffer Amplifier Noninverting Input for Channel 2.
Output of the Logarithmic Front End for Channel 2.
Output of the Logarithmic Front End for Channel 1.
Buffer Amplifier Noninverting Input for Channel 1.
Buffer Amplifier Inverting Input for Channel 1.
Buffer Output for Channel 1.
Analog Ground. Pin 21 and Pin 22 are internally shorted.
Intercept Shift Reference Input. The top of a resistive divider network that offsets VLOG to position the
intercept. Normally connected to VREF; may also be connected to ground when bipolar outputs are to be
provided.
Rev. A | Page 5 of 20
ADL5310
TYPICAL PERFORMANCE CHARACTERISTICS
VP = 5 V, VN = 0 V, RREF = 665 kΩ, TA = 25°C, unless otherwise noted.
1.6
2.0
TA = –40°C, 0°C, +25°C, +70°C, +85°C
VIN = 0V
1.4
1.5
ERROR (dB (10mV/dB))
1.0
0.8
0.6
0.4
100n
1µ
10µ
100µ
1m
10m
0
–0.5
0°C
–40°C
–1.0
–2.0
1n
04415-0-003
10n
IINP (A)
1.8
100n
1µ
10µ
100µ
1m
10m
Figure 6. Law Conformance Error vs. IINP for Multiple Temperatures,
Normalized to 25°C
2.0
TA = –40°C, 0°C, +25°C, +70°C, +85°C
VIN = 0V
1.6
10n
IINP (A)
Figure 3. VLOG vs. IINP for Multiple Temperatures
1.5
ERROR (dB (10mV/dB))
1.4
1.2
1.0
0.8
0.6
0.4
1.0
+70°C
+85°C
0.5
+25°C
0
–0.5
–40°C
–1.0
0°C
–1.5
0.2
1n
10n
100n
1µ
10µ
100µ
1m
10m
IREF (A)
–2.0
1n
04415-0-004
0
10n
100n
1µ
10µ
100µ
1m
10m
IREF (A)
Figure 4. VLOG vs. IREF for Multiple Temperatures (IINP = 3 µA)
04415-0-007
VLOG (V)
0.5
–1.5
0
1n
Figure 7. Law Conformance Error vs. IREF for Multiple Temperatures,
Normalized to 25°C (IINP = 3 µA)
1.8
1.0
1.6
0.8
3mA
ERROR (dB (10mV/dB))
300nA
1.2
30nA
3nA
1.0
300µA
0.6
3µA
1.4
0.8
3mA
0.6
300µA
0.4
30µA
0.4
3µA
0.2
0
–0.2
300nA
–0.4
–0.6
30µA
0.2
3nA
–0.8
0
1n
10n
100n
1µ
10µ
100µ
1m
IINP (A)
10m
04415-0-005
VLOG (V)
+85°C
+70°C
+25°C
04415-0-006
0.2
1.0
Figure 5. VLOG vs. IINP for Multiple Values of IREF,
Decade Steps from 3 nA to 3 mA
–1.0
1n
10n
100n
1µ
10µ
100µ
30nA
1m
10m
IINP (A)
Figure 8. Law Conformance Error vs. IINP for Multiple Values of IREF,
Decade Steps from 3 nA to 3 mA
Rev. A | Page 6 of 20
04415-0-008
VLOG (V)
1.2
ADL5310
1.8
1.0
1.6
0.8
1.4
0.6
3nA
30µA
1.2
300µA
1.0
3mA
0.8
3nA
0.6
30nA
300nA
0.4
300nA
0.4
3µA
0.2
3µA
0
3mA
–0.2
3mA
–0.4
300µA
–0.6
3µA
30µA
0.2
–0.8
1n
10n
100n
1µ
10µ
100µ
1m
10m
IREF (A)
–1.0
1n
04415-0-009
0
10n
100n
1µ
10µ
100µ
1m
10m
IREF (A)
Figure 9. VLOG vs. IREF for Multiple Values of IINP,
Decade Steps from 3 nA to 3 mA
04415-0-012
VLOG (V)
ERROR (dB (10mV/dB))
30nA
Figure 12. Law Conformance Error vs. IREF for Multiple Values of IINP,
Decade Steps from 3 nA to 3 mA
1.0
2.0
TA = 25°C
0.8
+5V, 0V
+12V, 0V
+12V, 0V
0.4
ERROR (dB (10mV/dB))
ERROR (dB (10mV/dB))
0.6
1.5
+9V, 0V
0.2
+3V, 0V
0
–0.2
+5V, –5V
+5V, –5V
–0.4
1.0
MEAN + 3σ
0.5
0
–0.5
MEAN – 3σ
–1.0
–0.6
10n
100n
1µ
10µ
100µ
1m
10m
IINP (A)
–2.0
1n
04415-0-010
–1.0
1n
10n
100n
1µ
10µ
100µ
1m
10m
IPD (A)
Figure 10. Law Conformance Error vs. IINP for Various Supply Conditions
04415-0-013
–1.5
–0.8
Figure 13. Law Conformance Error Distribution (3σ to Either Side of Mean)
2.0
4
TA = 0°C, 70°C
TA = –40°C, 85°C
1.5
3
ERROR (dB (10mV/dB))
0.5
0
MEAN ± 3σ AT 0°C
–0.5
–1.0
MEAN – 3σ AT 70°C
1
MEAN + 3σ AT +85°C
0
–1
–2
–1.5
MEAN – 3σ AT –40°C
–3
10n
100n
1µ
10µ
IPD (A)
100µ
1m
10m
–4
1n
04415-0-011
–2.0
1n
2
Figure 11. Law Conformance Error Distribution (3σ to Either Side of Mean)
10n
100n
1µ
10µ
IPD (A)
100µ
1m
10m
04415-0-014
ERROR (dB (10mV/dB))
MEAN + 3σ AT –40°C
MEAN + 3σ AT 70°C
1.0
Figure 14. Law Conformance Error Distribution (3σ to Either Side of Mean)
Rev. A | Page 7 of 20
ADL5310
15
1.6
30nA
10
300nA
1.4
3nA
30µA
0
–5
–10
300µA
–15
–20
–25
–35
300µA TO 3mA
T-RISE < 1µs T-FALL < 1µs
30µA TO 300µA
T-RISE < 1µs T-FALL < 5µs
3µA TO 30µA
T-RISE < 5µs T-FALL < 10µs
300nA TO 3µA
T-RISE < 10µs T-FALL < 40µs
30nA TO 300nA
T-RISE < 30µs T-FALL < 80µs
3nA TO 30nA
1.0
0.8
0.6
3mA
–30
T-RISE < 1µs T-FALL < 1µs
1.2
VOUT (V)
NORMALIZED RESPONSE (dB)
5
0.4
3µA
–40
0.2
1k
10k
100k
1M
10M
100M
FREQUENCY (Hz)
0
04415-0-015
–50
100
0
40
60
80
100
120
140
160
180
200
TIME (µs)
Figure 15. Small Signal AC Response, IINP to VOUT (AV = 1)
(5% Sine Modulation, Decade Steps from 3 nA to 3 mA)
Figure 18. Pulse Response—IINP to VOUT (AV = 1)
in Consecutive 1-Decade Steps
15
1.6
30nA
10
300nA
5
1.4
3mA
0
T-RISE < 80µs T-FALL < 30µs
3nA TO 30nA
T-RISE < 40µs T-FALL < 10µs
30nA TO 300nA
T-RISE < 10µs T-FALL < 5µs
300nA TO 3µA
T-RISE < 1µs T-FALL < 1µs
3µA TO 30µA
T-RISE < 1µs T-FALL < 1µs
30µA TO 300µA
T-RISE < 1µs T-FALL < 1µs
300µA TO 3mA
1.2
–5
300µA
3nA
–10
VOUT (V)
NORMALIZED RESPONSE (dB)
20
04415-0-018
–45
–15
–20
1.0
0.8
3µA
–25
0.6
–30
30µA
0.4
–35
–40
0.2
1k
10k
100k
1M
10M
100M
FREQUENCY (Hz)
0
04415-0-016
–50
100
0
20
40
60
80
100
120
140
160
180
200
TIME (µs)
Figure 16. Small Signal AC Response, IREF to VOUT (AV = 1)
(5% Sine Modulation, Decade Steps from 3 nA to 3 mA)
04415-0-019
–45
Figure 19. Pulse Response—IREF to VOUT (AV = 1)
in Consecutive 1-Decade Steps
100
5.0
3nA
4.0
10
mV rms
3.0
1
300nA
3µA
2.0
0.1
1.0
0.01
100
1k
3mA
30µA
10k
100k
1M
10M
FREQUENCY (Hz)
0
1n
10n
100n
1µ
10µ
100µ
1m
10m
IINP (A)
Figure 20. Total Wideband Noise Voltage at VOUT vs. IINP (AV = 1)
Figure 17. Spot Noise Spectral Density at VOUT vs. Frequency (AV = 1)
for IINP in Decade Steps from 3 nA to 3 mA
Rev. A | Page 8 of 20
04415-0-020
300µA
04415-0-017
µV rms/ Hz
30nA
ADL5310
25
5
20
4
15
3
2
VINPT DRIFT (mV)
MEAN + 3σ
5
0
–5
MEAN – 3σ
–10
–1
MEAN – 3σ
–2
–4
–20
–5
20
30
40
50
60
70
80
90
–6
–40 –30 –20 –10
0
10
20
30
40
50
60
70
80
90
TEMPERATURE (°C)
Figure 24. VINPT Drift vs. Temperature (3σ to Either Side of Mean)
Normalized to 25°C
6
7
5
6
4
5
3
4
2
∆VY DRIFT (mV/dec)
Figure 21. VREF Drift vs. Temperature (3σ to Either Side of Mean)
Normalized to 25°C
MEAN + 3σ
1
0
–1
–2
MEAN – 3σ
3
2
0
–1
–2
–3
–3
–4
–4
–5
–5
0
10
20
30
40
50
60
70
80
90
TEMPERATURE (°C)
MEAN – 3σ
–6
–40 –30 –20 –10
04415-0-022
–6
–40 –30 –20 –10
MEAN + 3σ
1
0
10
20
30
40
50
60
70
80
90
TEMPERATURE (°C)
Figure 22. Slope Drift vs. Temperature (3σ to Either Side of Mean)
Normalized to 25°C
04415-0-025
10
04415-0-021
0
04415-0-024
–3
TEMPERATURE (°C)
Figure 25. Slope Mismatch Drift vs. Temperature
(VY1 – VY2, 3σ to Either Side of Mean) Normalized to 25°C
200
200
150
150
100
100
∆IZ DRIFT (pA)
MEAN + 3σ
50
0
MEAN – 3σ
–50
MEAN + 3σ
50
0
–50
MEAN – 3σ
–100
–100
–150
–150
–40 –30 –20 –10
0
10
20
30
40
50
60
70
80
TEMPERATURE (°C)
90
04415-0-023
IZ DRIFT (pA)
MEAN + 3σ
0
–15
–25
–40 –30 –20 –10
VY DRIFT (mV/dec)
1
Figure 23. Intercept Drift vs. Temperature
(3σ to Either Side of Mean) Normalized to 25°C
–200
–40 –30 –20 –10
0
10
20
30
40
50
60
70
80
TEMPERATURE (°C)
Figure 26. Intercept Mismatch Drift vs. Temperature
(IZ1 – IZ2, 3σ to Either Side of Mean) Normalized to 25°C
Rev. A | Page 9 of 20
90
04415-0-026
VREF DRIFT (mV)
10
ADL5310
450
700
400
600
350
500
400
COUNT
COUNT
300
300
250
200
150
200
100
100
200
205
210
SLOPE (mV/dec)
0
–9
–6
–3
0
3
6
9
SLOPE MISMATCH (mV/dec)
04415-0-030
195
04415-0-027
0
190
50
Figure 30. Distribution of Channel-to-Channel Slope Mismatch (VY1 – VY2)
Figure 27. Distribution of Logarithmic Slope
500
600
500
400
COUNT
COUNT
400
300
300
200
200
100
200
300
400
500
INTERCEPT (pA)
0
–300
04415-0-028
0
100
–200
–100
0
100
200
300
INTERCEPT MISMATCH (pA)
04415-0-031
100
Figure 31. Distribution of Channel-to-Channel Intercept Mismatch (IZ1 – IZ2)
Figure 28. Distribution of Logarithmic Intercept
500
700
600
400
COUNT
400
300
300
200
200
100
0
2.46
2.48
2.50
2.52
VREF VOLTAGE (V)
2.54
Figure 29. Distribution of VREF (RL = 100 kΩ)
0
–9
–6
–3
0
3
6
VINPT – VSUM VOLTAGE (mV)
Figure 32. Distribution of Offset Voltage (VINPT – VSUM)
Rev. A | Page 10 of 20
9
04415-0-032
100
04415-0-029
COUNT
500
ADL5310
GENERAL STRUCTURE
The ADL5310 addresses a wide variety of interfacing conditions
to meet the needs of fiber optic supervisory systems and is
useful in many nonoptical applications. These notes explain the
structure of this unique style of translinear log amp. Figure 33
shows the key elements of one of the two identical on-board
log amps.
BIAS
GENERATOR
PHOTODIODE
2.5V
INPUT
CURRENT
80kΩ
IPD
0.5V
IREF
IREF
VBE2
20kΩ
COMM
VSUM
INP1
(INP2)
VBE1
VREF
TEMPERATURE
COMPENSATION
(SUBTRACT AND
DIVIDE BY T°K)
44µA/dec
0.5V
14.2kΩ
451Ω
VRDZ
VLOG
0.5V
VBE1
Q2
VNEG (NORMALLY GROUNDED)
VBE2
6.69kΩ
COMM
04415-0-033
Q1
THEORY
The base-emitter voltage of a bipolar junction transistor (BJT)
can be expressed by Equation 1, which immediately shows its
basic logarithmic nature:
VBE = kT/q ln(IC/IS)
where:
IC is the collector current.
IS is a scaling current, typically only 10–17 A.
kT/q is the thermal voltage, proportional to absolute
temperature (PTAT), and is 25.85 mV at 300 K.
IS is never precisely defined and exhibits an even stronger temperature dependence, varying by a factor of roughly a billion
between −35°C and +85°C. Thus, to make use of the BJT as an
accurate logarithmic element, both of these temperature
dependencies must be eliminated.
The difference between the base-emitter voltages of a matched
pair of BJTs, one operating at the photodiode current IPD and the
other operating at a reference current IREF, can be written as
VBE1 – VBE2 = kT/q ln(IPD/IS) – kT/q ln(IREF/IS)
= ln(10) kT/q log10(IPD/IREF)
= 59.5 mV log10(IPD/IREF) (T = 300 K)
Figure 33. Simplified Schematic of Single Log Amp
The photodiode current IPD is received at either Pin INP1 or
Pin INP2. The voltages at these nodes are approximately equal
to the voltage on the adjacent guard pins, VSUM, as well as
reference inputs IRF1 and IRF2, due to the low offset voltage
of the JFET operational amplifiers. Transistor Q1 converts IPD
to a corresponding logarithmic voltage, as shown in Equation 1.
A finite positive value of VSUM is needed to bias the collector of
Q1 for the usual case of a single-supply voltage. This is internally set to 0.5 V, one-fifth of the 2.5 V reference voltage that
appears on Pin VREF. Both VREF pins are internally shorted,
as are both VSUM pins. The resistance at the VSUM pin is
nominally 16 kΩ; this voltage is not intended as a general bias
source.
The ADL5310 also supports the use of an optional negative
supply voltage, VN, at Pin VNEG. When VN is 0.5 V or more
negative, VSUM may be connected to ground; thus, INP1, INP2,
IRF1, and IRF2 assume this potential. This allows operation as a
voltage-input logarithmic converter by the inclusion of a series
resistor at either or both inputs. Note that the resistor setting IREF
for each channel needs to be adjusted to maintain the intercept
value. Also note that the collector-emitter voltages of Q1 and Q2
are the full VN and effects due to self-heating cause errors at
large input currents.
The input-dependent VBE1 of Q1 is compared with the reference
VBE2 of a second transistor, Q2, operating at IREF. IREF is generated externally to a recommended value of 3 µA. However, other
values over a several-decade range can be used with a slight
degradation in law conformance.
(1)
(2)
The uncertain, temperature-dependent saturation current, IS,
that appears in Equation 1 has therefore been eliminated. To
eliminate the temperature variation of kT/q, this difference
voltage is processed by what is essentially an analog divider.
Effectively, it puts a variable under Equation 2. The output of
this process, which also involves a conversion from voltage
mode to current mode, is an intermediate, temperaturecorrected current:
ILOG = IY log10(IPD/IREF)
(3)
where IY is an accurate, temperature-stable scaling current that
determines the slope of the function (change in current per
decade). For the ADL5310, IY is 44 µA, resulting in a
temperature-independent slope of 44 µA/decade for all values
of IPD and IREF. This current is subsequently converted back to a
voltage-mode output, VLOG, scaled 200 mV/decade.
It is apparent that this output should be 0 for IPD = IREF and
would need to swing negative for smaller values of input
current. To avoid this, IREF would need to be as small as the
smallest value of IPD. Accordingly, an offset voltage is added to
VLOG to shift it upward by 0.8 V when VRDZ is directly
connected to VREF. This moves the intercept to the left by four
decades (at 200 mV/decade), from 3 μA to 300 pA:
ILOG = IY log10(IPD/IINTC)
(4)
where IINTC is the operational value of the intercept current.
Because values of IPD < IINTC result in a negative VLOG, a negative
supply of sufficient value is required to accommodate this
situation.
Rev. A | Page 11 of 20
ADL5310
The voltage VLOG is generated by applying ILOG to an internal
resistance of 4.55 kΩ, formed by the parallel combination of a
6.69 kΩ resistor to ground and a 14.2 kΩ resistor to Pin VRDZ
(typically tied to the 2.5 V reference, VREF). At the LOG1
(LOG2) pin, the output current ILOG generates a voltage of
VLOG = ILOG × 4.55 kΩ
= 44 µA × 4.55 kΩ × log10(IPD/IINTC)
= VY log10(IPD/IINTC)
(5)
where VY = 200 mV/decade or 10 mV/dB. Note that any resistive loading on LOG1 (LOG2) lowers this slope and results in
an overall scaling uncertainty. This is due to the variability of
the on-chip resistors compared to the off-chip load. As a consequence, this practice is not recommended.
Thus, the effective intercept current IINTC is only one tenthousandth of IREF, corresponding to 300 pA when using the
recommended value of IREF = 3 µA.
The slope can be reduced by attaching a resistor between the log
amp output pin, LOG1 or LOG2, and ground. This is strongly
discouraged given that the on-chip resistors do not ratio
correctly to the added resistance. Also, it is rare that one would
wish to lower the basic slope of 10 mV/dB; if this is needed, it
should be effected at the low impedance output of the buffer
amps, which are provided to avoid such miscalibration and to
allow higher slopes to be used.
VLOG may also swing below ground when dual supplies (VP and
VN) are used. When VN = −0.5 V or larger, the input Pins INP1
(INP2) and IRF1 (INP2) may be positioned at ground level
simply by grounding VSUM. Care must be taken to limit the
power consumed by the input BJT devices when using a larger
negative supply, because self-heating degrades the accuracy at
higher currents.
Each of the ADL5310’s buffers is essentially an uncommitted
operational amplifier with rail-to-rail output swing, good loaddriving capabilities, and a typical unity-gain bandwidth of
15 MHz. In addition to allowing the introduction of gain, using
standard feedback networks and thereby increasing the slope
voltage VY, the buffer can be used to implement multipole, lowpass filters, threshold detectors, and a variety of other functions.
Further details on these applications can be found in the
AD8304 data sheet.
MANAGING INTERCEPT AND SLOPE
RESPONSE TIME AND NOISE CONSIDERATIONS
When using a single supply, VRDZ should be directly connected
to VREF to allow operation over the entire 6-decade input
current range. As noted in the Theory section, this introduces
an accurate offset voltage of 0.8 V at the LOG1 and LOG2 pins,
equivalent to four decades, resulting in a logarithmic transfer
function that can be written as
The response time and output noise of the ADL5310 are fundamentally a function of the signal current, IPD. For small currents,
the bandwidth is proportional to IPD, as shown in Figure 15. The
output low frequency voltage-noise spectral-density is a
function of IPD (see Figure 17) and also increases for small
values of IREF. Details of the noise and bandwidth performance
of translinear log amps can be found in the AD8304 data sheet.
VLOG = VY log10(104 × IPD/IREF)
= VY log10(IPD/IINTC)
(6)
where IINTC = IREF/104.
Rev. A | Page 12 of 20
ADL5310
APPLICATIONS
5V
665kΩ
VREF
VSUM
VRDZ
VPOS
OUT1
IPD1
0.5log10 1nA
(
)
VOUT1
COMM
IRF1
12kΩ
IRF1
SCL1
2kΩ
6.69kΩ
4.7nF
VBIAS
VNEG
I
TEMPERATURE LOG
COMPENSATION
8kΩ
BIN1
LOG1
451Ω
CFLT1
10 nF
14.2kΩ
IPD1
INP1
1kΩ
OUT2
1nF
0.5V
20kΩ
REFERENCE
GENERATOR
2.5V
80kΩ
(
)
VOUT2
12kΩ
COMM
IRF2
SCL2
2kΩ
14.2kΩ
4.7nF
VBIAS
IPD2
0.5log10 1nA
VNEG
I
TEMPERATURE LOG
COMPENSATION
IRF2
8kΩ
BIN2
LOG2
451Ω
CFLT2
10 nF
6.69kΩ
IPD2
INP2
VSUM
1nF
VREF
VNEG
COMM
1nF
665kΩ
04415-0-034
1kΩ
COMM
Figure 34. Basic Connections for Fixed Intercept Use
The ADL5310 is easy to use in optical supervisory systems
and in similar situations where a wide-ranging current is to
be converted to its logarithmic equivalent—that is, represented
in decibel terms. Basic connections for measuring a single
current at each input are shown in Figure 34, which also
includes various nonessential components, as explained next.
The 2 V difference in voltage between the VREF and Input Pins
INP1 and INP2, in conjunction with the external 665 kΩ resistors RRF1 and RRF2, provides 3 µA reference currents IRF1 and IRF2
into Pins IRF1 and IRF2. Connecting VRDZ to VREF raises the
voltage at LOG1 and LOG2 by 0.8 V, effectively lowering each
intercept current IINTC by a factor of 104 to position it at 300 pA.
A wide range of other values for IREF, from 3 nA to 3 mA, may be
used. The effect of such changes is shown in Figure 5 and
Figure 8.
Any temperature variation in RRF1 (RRF2) must be taken into
account when estimating the stability of the intercept. Also, the
overall noise increases when using very low values of IRF1 (IRF2).
In fixed-intercept applications there is little benefit in using a
large reference current, because doing so only compresses the
low-current-end of the dynamic range when operated from a
single supply. The capacitor between VSUM and ground is
strongly recommended to minimize the noise on this node, to
reduce channel-to-channel crosstalk, and to help provide clean
reference currents.
In addition, each input and reference pin (INP1, INP2, IRF1,
and IRF2) has a compensation network made up of a series
resistor and capacitor. The junction capacitance of the photodiode along with the network capacitance of the board artwork
around the input system creates a pole that varies widely with
input current. The RC network stabilizes the system by simultaneously reducing this pole frequency and inserting a zero to
compensate an additional pole inherent in the input system. In
general, the 1 nF, 1 kΩ network handles almost any photodiode
interface. In situations where larger active area photodiodes are
used, or when long input traces are used, the capacitor value
may need to be increased to ensure stability. Although the signal
and reference input systems are similar, additional care is
required to ensure stable operation of the reference inputs at
temperature extremes across the full current range of IRF1 (IRF2).
It is recommended that filter components of 4.7 nF and 2 kΩ
should be used from Pin IRF1 (IRF2) to ground. Temperaturestable components should always be used in critical locations
such as the compensation networks; Y5V-type chip capacitors
are to be avoided due to their poor temperature stability.
Rev. A | Page 13 of 20
ADL5310
The optional capacitor from LOG1 (LOG2) to ground forms a
single-pole, low-pass filter in combination with the 5 kΩ resistance at this pin. For example, when using a CFLT of 10 nF, the
3 dB corner frequency is 3.2 kHz. Such filtering is useful in
minimizing the output noise, particularly when IPD is small.
Multipole filters are more effective in reducing the total noise;
examples are provided in the AD8304 data sheet.
Because the basic scaling at LOG1 (LOG2) is 0.2 V/decade,
and thus a 4 V swing at the buffer output would correspond to
20 decades, it is often useful to raise the slope to make better use
of the rail-to-rail voltage range. For illustrative purposes, both
channels in Figure 34 provide a 0.5 V/decade overall slope
(25 mV/dB). Thus, using IREF = 3 μA, VLOG runs from 0.2 V at
IPD = 3 nA to 1.4 V at IPD = 3 mA; the buffer output runs from
0.5 V to 3.5 V, corresponding to a dynamic range of 120 dB
(electrical, that is, 60 dB optical power).
Further information on adjusting the slope and intercept, using
a negative supply, and additional operations can be found in the
AD8305 data sheet.
CALIBRATION
Each channel of the ADL5310 has a nominal slope and intercept
at LOG1 (LOG2) of 200 mV/decade and 300 pA, respectively,
when configured as shown in Figure 34. These values are
untrimmed and the slope alone may vary by as much as 7.5%
over temperature. For this reason, it is recommended that a
simple calibration be done to achieve increased accuracy. While
the ADL5310 offers improved slope and intercept matching
compared to a randomly selected pair of AD8305 log amps, the
specified accuracy can only be achieved by calibrating each
channel individually.
4
1.4
UNCALIBRATED ERROR
2
VLOG (V)
1.0
0.8
1
MEASURED OUTPUT
0
0.6
CALIBRATED ERROR
0.4
0.2
0
1n
–2
IDEAL OUTPUT
10n
100n
1µ
10µ
IPD (A)
–1
ERROR (dB (10mV/dB))
3
100µ
1m
–3
10m
04415-0-035
1.2
Figure 35. Using 2-Point Calibration to Increase Measurement Accuracy
Figure 35 shows the improvement in accuracy when using a 2point calibration method. To perform this calibration,
apply two known currents, I1 and I2, in the linear operating
range between 10 nA and 1 mA. Measure the resulting output,
V1 and V2, respectively, and calculate the slope m and the
intercept b:
m = (V1 – V2)/[log10(I1) – log10(I2)]
(7)
b = V1 – m × log10(I1)
(8)
The same calibration could be performed with two known
optical powers, P1 and P2. This allows for calibration of the
entire measurement system while providing a simplified
relationship between the incident optical power and VLOG
voltage:
m = (V1 – V2)/(P1 – P2)
b = V1 – m × P1
(9)
(10)
The uncalibrated error line in Figure 35 was generated assuming that the slope of the measured output was 200 mV/decade
when in fact it was actually 194 mV/decade. Correcting for this
discrepancy decreased measurement error up to 3 dB.
MINIMIZING CROSSTALK
Combining two high-dynamic-range logarithmic converters in
one IC carries potential pitfalls concerning channel-to-channel
isolation. Special care must be taken in several areas to ensure
acceptable crosstalk performance, particularly when one or both
channels may operate at very low input currents. Fastidious supply bypassing—also necessary for overall stability—and careful
board layout are important first steps for minimizing crosstalk.
While the shared bias circuitry improves channel-to-channel
matching and reduces power consumption, it is also a source of
crosstalk that must be mitigated. The VSUM pins, which are
internally shorted, should be bypassed with at least 1 nF to
ground, and 20 nF is recommended for operation at the lowest
currents (<30 nA). VSUM is of particular importance because it
acts as a reference voltage input for each input system, but
without the bandwidth limitation at low currents that the
primary inputs incur. Disturbances at the VSUM pin that are
well within the bandwidth of the input are tracked by the loop
and do not generate disturbances at the output (aside from the
generally minor perturbation in reference currents caused by
voltage variations at IRF1 and IRF2).
For this reason, the pole frequency at VSUM, which has a 16 kΩ
typical source resistance, should be set below the minimum
input system bandwidth for the lowest input current to be
encountered. Because the low frequency noise at VSUM is also
tracked by the loop within its available bandwidth, this is also a
criterion for reducing the noise contribution at the output from
the thermal noise of the 16 kΩ source resistance at VSUM.
Rev. A | Page 14 of 20
ADL5310
A 10 nF capacitor on each VSUM pin (20 nF parallel equivalent)
combined with the 16 kΩ source resistance yields a 500 Hz pole,
which is sufficiently below the bandwidth for the minimum
input current of 3 nA.
Residual crosstalk disturbance is particularly problematic at the
lowest currents for two reasons. First, the loop is unable to reject
summing node disturbances beyond the limited bandwidth.
Second, the settling response at the lowest currents to any
residual disturbance is significantly slower than that for input
currents even one or two decades higher (see Figure 18).
relative gain or absorbance measurement. A more straightforward analog implementation includes the use of a current
mirror, as shown in Figure 37. The current mirror is used to
feed an opposite polarity replica of the cathode photocurrent of
PD2 into Channel 2 of the ADL5310. This allows one channel to
be used as an absolute power meter for the optical signal
incident on PD2, while the opposite channel is used to directly
compute the log ratio of the two input signals.
5V
5V
0.1µF
VSUM
1.2
IIN2
*Φ2(V) ≅ 0.2log10 100pA
(
ACTIVE CHANNEL OUTPUT PULSE, 1-DECADE STEP
3µA TO 30µA
1.0
6
0.8
IINP – 3nA
3
IINP – 100nA
IINP – 10nA
0
0.6
0.4
IINP – 30nA
–3
0.5
1.0
1.5
2.0
TIME (ms)
IRF2
2MΩ
Figure 36. Crosstalk Pulse Response for Various Input Current Values
α21**
OUT1
BIAS
GENERATOR
VREF
IIN1
**α21(V) ≅ 0.2log10 I
PD2
(
IPD2
PD2
InGaAs PIN
IRF1
)
SCL1
log
BIN1
1kΩ
4.7nF
Figure 36 shows the measured response of an inactive channel
(dc input) to a 1-decade current step on the input of the active
channel for several inactive channel dc current values. Additional system considerations may be necessary to ensure
adequate settling time following a known transient when one or
both channels are operating at very low input currents.
LOG2
log
VRDZ
1kΩ
4.7nF
04415-0-036
0
BIN2
I
TEMPERATURE LOG2
COMPENSATION
1nF
0.2
0
2.5
SCL2
log
4.7nF
INACTIVE CHANNEL RESPONSE
–6
INP2
1kΩ
)
I
TEMPERATURE LOG1
COMPENSATION
1nF
5V
PD1
InGaAs PIN IIN1
1kΩ
0.1µF
LOG1
log
INP1
4.7nF VSUM
COMM
VNEG
COMM
1nF
04415-0-037
9
IIN2=IPD2
ACTIVE CHANNEL OUTPUT (V)
INACTIVE CHANNEL OUTPUT (mV)
COMM
ADL5310
1nF
12
Φ2*
OUT2
VPOS
Figure 37. Absolute and Relative Power Measurement Application
Using Modified Wilson Current Mirror
RELATIVE AND ABSOLUTE POWER
MEASUREMENTS
When properly calibrated, the ADL5310 provides two independent channels capable of accurate absolute optical power
measurements. Often, it is desirable to measure the relative
gain or absorbance across an optical network element, such as
an optical amplifier or variable attenuator. If each channel has
identical logarithmic slopes and intercepts, this can easily be
done by differencing the output signals of each channel. In
reality, channel mismatch can result in significant errors over a
wide range of input levels if left uncompensated. Postprocessing
of the signal can be used to account for individual channel
characteristics. This requires a simple calculation of the
expected input level for a measured log voltage, followed by
differencing of the two signal levels in the digital domain for a
The presented current mirror is a modified Wilson mirror.
Other current mirror implementations would also work, though
the modified Wilson mirror provides fairly constant performance over temperature. It is essential to use matched pair
transistors when designing the current mirror to minimize the
effects of temperature gradients and beta mismatch.
Rev. A | Page 15 of 20
ADL5310
The solution in Figure 37 is no longer subject to potential
channel mismatch issues. Individual channel slope and intercept
characteristics can be calibrated independently. The accuracy
was verified using a pair of calibrated current sources. The
performance of the circuit depicted in Figure 37 is shown in
Figure 38 and Figure 39. Multiple transfer functions and error
plots are provided for various power levels. The accuracy is
better than 0.1 dB over a 5-decade range. The dynamic range is
slightly reduced for strong IIN input currents. This is due to the
limited available swing of the VLOG pin and can be recovered
through careful selection of input and output optical tap
coupling ratios.
1.8
1.6
1.4
OUTPUT VOLTAGE (V)
During the characterization of the ADL5310, the device was
treated as a precision current-input logarithmic converter,
because it is impractical to generate accurate photocurrents by
illuminating a photodiode. The test currents were generated by
using either a well-calibrated current source, such as the
Keithley 236, or a high value resistor from a voltage source to
the input pin. Great care is needed when using very small input
currents. For example, the triax output connection from the
current generator was used with the guard tied to VSUM. The
input trace on the PC board was guarded by connecting
adjacent traces to VSUM.
These measures are needed to minimize the risk of leakage
current paths. With 0.5 V as the nominal bias on the INP1
(INP2) pin, a leakage-path resistance of 1 GΩ to ground would
subtract 0.5 nA from the input, which amounts to a −1.6 dB
error for a 3 nA source current. Additionally, the very high
sensitivity at the input pins and the long cables commonly
needed during characterization allow 60 Hz and RF emissions
to introduce substantial measurement errors. Careful guarding
techniques are essential to reducing the pickup of these spurious
signals.
φ2 WHEN IPD1 = 100µA
1.2
α21 FOR MULTIPLE VALUES OF IPD1
1.0
CHARACTERIZATION METHODS
0.8
0.6
0.4
0
–20
–10
0
10
20
30
40
50
60
LOG10 [IPD1/IPD2] (dB)
04415-0-038
0.2
Additional information, including test setups, can be found in
the AD8305 and ADL5306 data sheets.
Figure 38. Absorbance and Absolute Power Transfer Functions for
Wilson Mirror ADL5310 Combination
0.5
0.4
0.3
IPD1 = 1µA
ERROR (dB)
0.2
0.1
0
–0.1 IPD1 = 10µA
–0.2
–0.3
–0.5
–40
–30
–20
–10
0
10
20
LOG10 [IPD1/IPD2] (dB)
30
40
50
60
04415-0-039
IPD1 = 100µA
–0.4
Figure 39. Log Conformance for Wilson Mirror ADL5310 Combination,
Normalized to 10 mA Channel 1 Input Current, IIN1
Rev. A | Page 16 of 20
ADL5310
EVALUATION BOARD
An evaluation board is available for the ADL5310 (Figure 40 shows the schematic). It can be configured for a wide variety of experiments.
The gain of each buffer amp is factory-set to unity, providing a slope of 200 mV/dec, and the intercept is set to 300 pA. Table 4 describes
the various configuration options.
Table 4. Evaluation Board Configuration Options
Component
P1
P2, R1, R3, R8, R9,
R17, R22, R25, R30
R5, R6, R7, R16,
R18, R19, R20,
R21, R31, R32, C4,
C14, C15, C16,
C19, C20
R2, R28, R29
R4, R10, R11, C2,
C3, C5, C6, C8, C9
Function
Supply Interface. Provides access to the Supply Pins VNEG, COMM, and
VPOS.
Monitor Interface. By adding 0 Ω resistors to R1, R3, R8, R9, R17, R22, and
R25, the VRDZ, VREF, VSUM, BIN1, BIN2, OUT1, and OUT2 pin voltages
can be monitored using a high impedance probe. VBIAS allows for the
external bias voltages to be applied to J1 and J2. If R30 = 0 Ω,
VBIAS = VREF.
Buffer Amplifier/Output Interface. The logarithmic slopes of the ADL5310
can be altered using each buffer’s gain-setting resistors, R5 and R6, and
R18 and R19. R7, R16, R31, R32, C19, and C20 allow for variation in the
buffer loading. R20, R21, C4, C14, C15, and C16 are provided for a variety
of filtering applications.
Intercept Adjustment. The voltage dropped across Resistors R28 and R29
determines the intercept reference current for each log amp, nominally
set to 3 µA using a 665 kΩ 1% resistor. R2 can be used to adjust the
output offset voltage at the LOG1 and LOG2 outputs.
Supply Decoupling.
C1, C7
R12, R13, R14,
R15, C10, C11,
C12, C13
Filtering VSUM.
Input Compensation. Provides essential HF compensation at the Input
Pins INP1, INP2, IRF1, and IRF2.
IREF, INPT
Input Interface. The test board is configured to accept current through the
SMA connectors labeled INP1 and INP2. Through-holes are provided to
connect photodiodes in place of the INP1 and INP2 SMAs for optical
interfacing. By removing R28 (R29 for INP2), a second current can be
applied to the IRF1 (IRF2 for INP2) input (also SMA) for evaluating the
ADL5310 in log ratio applications.
SC-Style Photodiode. Provides for the direct mounting of SC-style
photodiodes.
J1, J2
Rev. A | Page 17 of 20
Default Condition
P1 = installed
P2 = not installed
R1 = R3 = R8 = open (size 0402)
R9 = R17 = open (size 0402)
R22 = R25 = R30 = open (size 0402)
R5 = R19 = 0 Ω (size 0402)
R7 = R16 = 0 Ω (size 0402)
R20 = R21 = 0 Ω (size 0402)
R6 = R18 = open (size 0402)
R31 = R32 = open (size 0402)
C4 = C14 = open (size 0402)
C19 = C20 = open (size 0402)
C15 = C16 = open (size 0402)
LOG1 = OUT1 = installed
LOG2 = OUT2 = installed
R28 = R29 = 665 kΩ (size 0402)
R2 = 0 Ω (size 0402)
C2 = C5 = C9 = 100 pF (size 0402)
C3 = C6 = C8 = 0.01 µF (size 0402)
R4 = R10 = R11 = 0 Ω (size 0402)
C1 = C7 = 0.01 µF (size 0402)
R12 = R15 = 1 kΩ (size 0402)
R13 = R14 = 2 kΩ (size 0402)
C10 = C13 = 1 nF (size 0402)
C11 = C12 = 4.7 nF (size 0402)
IREF = INPT = installed
J1 = J2 = open
ADL5310
VRDZ
R3
OPEN
3
2
1
J2
PHOTODIODE
VNEG
R4
0Ω
C2
R2
0Ω
VBIAS
R7 0Ω
OUT1
C20
OPEN
R32
OPEN
C3 0.01µF
R8 OPEN
OUT1
C4 OPEN
100pF
R5 0Ω
IRF1
21
20
19
COMM
VNEG
OUT1
C16
OPEN
1
VSUM
SCL1 18
2
INP1
BIN1 17
OPEN
INP1
22
IRF1
4
IRF2
LOG2 15
5
INP2
BIN2 14
ADL5310
IRF2
VSUM
C13
C12
C11
C10
1nF 4.7nF 4.7nF
1nF
OUT2
R9
VNEG
R12
1kΩ
VNEG
R13
2kΩ
VPOS
R14
2kΩ
VPOS
R15
1kΩ
SCL2
VREF
INP2
7
8
9
10
11
12
13
C5 100pF
C9 100pF
R10
0Ω
C6 0.01µF
R11
0Ω
C8 0.01µF
2
1
LOG1
R25
R27 0Ω
OPEN
R18
C14
OPEN OPEN
LOG2
C15
OPEN
R17
OPEN
VBIAS
OUT2
2
3
R21
R22
0Ω
OPEN
R23
BIN2
LOG2
R16 0Ω
VNEG
C7 0.01µF
OUT1
1
BIN1
2
LOG1
3
LOG2
4
BIN2
5
OUT2
6
OUT2
C19
OPEN
AGND
1
BIN1
0Ω
R31
OPEN
VPOS
LOG1
R19
0Ω
3
J1
PHOTODIODE
0Ω
R26 0Ω
VREF
OPEN
R24
0Ω
OPEN
LOG1 16
3
6
R6
R20
7
VREF
R30 OPEN
P1
VBIAS
8
P2
Figure 40. Evaluation Board Schematic
Rev. A | Page 18 of 20
04415-0-040
VSUM
23
COMM
R1
24
VREF
R28
R29
665kΩ 665kΩ
VRDZ
C1 0.01µF
04415-0-042
04415-0-041
ADL5310
Figure 41. Component-Side Layout
Figure 42. Component-Side Silkscreen
Rev. A | Page 19 of 20
ADL5310
OUTLINE DIMENSIONS
0.60 MAX
4.00
BSC SQ
PIN 1
INDICATOR
0.60 MAX
0.50
BSC
3.75
BSC SQ
TOP
VIEW
0.50
0.40
0.30
1.00
0.85
0.80
12° MAX
0.80 MAX
0.65 TYP
0.30
0.23
0.18
SEATING
PLANE
PIN 1
INDICATOR
24 1
19
18
2.25
2.10 SQ
1.95
EXPOSED
PAD
(BOTTOM VIEW)
13
12
7
6
0.25 MIN
2.50 REF
0.05 MAX
0.02 NOM
0.20 REF
COPLANARITY
0.08
COMPLIANT TO JEDEC STANDARDS MO-220-VGGD-2
Figure 43. 24-Lead Lead Frame Chip Scale Package [LFCSP]
4 mm × 4 mm Body
(CP-24-1)
Dimensions shown in millimeters
ORDERING GUIDE
Model
ADL5310ACP-R2
ADL5310ACP-REEL7
ADL5310-EVAL
1
Temperature Range
–40°C to +85°C
–40°C to +85°C
Package Description
24-Lead LFCSP
24-Lead LFCSP
Evaluation Board
Branding is as follows:
Line 1 — JQA
Line 2 — Lot Code
Line 3 — (Date Code) Date Code is in YYWW format
© 2004 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
C04415–0–9/04(A)
Rev. A | Page 20 of 20
Package Outline
CP-24-1
CP-24-1
Branding1
JQA
JQA
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