AD ADL5303ACPZ-R7 160 db range 100 pa to 10 ma low cost logarithmic converter Datasheet

160 dB Range 100 pA to 10 mA
Low Cost Logarithmic Converter
ADL5303
Data Sheet
FEATURES
SIMPLIFIED BLOCK DIAGRAM
APPLICATIONS
VPS2
PWDN
VPS1
10
16
12
ADL5303
PDB
5
2
IPD
3
4
VPDB
BIAS
VREF
~10kΩ
VREF
6
0.5V
VSUM
VLOG
INPT
TEMPERATURE
COMPENSATION
VSUM
8
BFIN
5kΩ
BFNG
15
7
14
11
GND
ACOM
GND
VOUT
9
13
10661-001
Optimized for fiber optic photodiode interfacing
8 full decades of range
Law conformance: 0.1 dB from 1 nA to 1 mA
Single-supply operation: 3.0 V to 5.5 V
Complete and temperature stable
Accurate laser trimmed scaling
Logarithmic slope of 10 mV/dB (at the VLOG pin)
Basic logarithmic intercept at 100 pA
Easy adjustment of slope and intercept
Output bandwidth of 10 MHz, 15 V/μs slew rate
Miniature 16-lead package (LFCSP)
Low power: ~4.5 mA quiescent current (enabled)
Figure 1.
High accuracy optical power measurement
Wide range baseband log compression
Versatile detector for APC loops
GENERAL DESCRIPTION
The ADL5303 is a monolithic logarithmic detector optimized
for the measurement of low frequency signal power in fiber
optic systems and offers a large dynamic range in a versatile and
easily used form. Wide measurement range and accuracy are
achieved using proprietary design and precise laser trimming.
The ADL5303 requires only a single positive supply, VPS, of 5 V.
When using low supply voltages, the log slope can be altered to
fit the available span. Low quiescent current and chip disable
facilitate use in battery-operated applications.
The input current, IPD, flows in the collector of an optimally
scaled NPN transistor, connected in a feedback path around a
low offset JFET amplifier. The current summing input node
operates at a constant voltage, independent of current, with
a default value of 0.5 V; this may be adjusted over a wide range.
An adaptive biasing scheme is provided for reducing photodiode dark current at very low light input levels. The VPDB pin
applies approximately 0.1 V reverse bias across the photodiode
for IPD = 100 pA, rising linearly to 2.0 V of reverse bias at IPD =
10 mA to improve response time at higher power levels. The
Rev. 0
input pin INPT is flanked by the VSUM guard pins that track
the voltage at the summing node. Connecting the exposed pad
of the device to the VSUM pins provides a continuous guard to
minimize leakage into the INPT pin.
The default value of the logarithmic slope at the VLOG output
is set by an internal 5 kΩ resistor. Logarithmic slope can be
lowered with an external shunt resistor or increased using the
buffer and a pair of external feedback resistors. The addition of
a capacitor at the VLOG pin provides a simple low-pass filter.
The intermediate voltage, VLOG, is buffered in an output stage
that can swing to within about 100 mV of ground and the positive supply, VPS, and provides a peak current drive capacity of
±20 mA. An on-board 2 V reference is provided to facilitate
the repositioning of the intercept. The incremental bandwidth
of a translinear logarithmic amplifier inherently diminishes
for small input currents. At IPD =1 nA, the bandwidth of the
ADL5303 is approximately 2 kHz increasing in proportion to
IPD up to a maximum value of 10 MHz.
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ADL5303
Data Sheet
TABLE OF CONTENTS
Features .............................................................................................. 1
Bandwidth and Noise Considerations ..................................... 10
Applications ....................................................................................... 1
Chip Enable ................................................................................. 11
Simplified Block Diagram ............................................................... 1
Using the ADL5303 ........................................................................ 12
General Description ......................................................................... 1
Slope and Intercept Adjustments ............................................. 12
Revision History ............................................................................... 2
Low Supply Slope and Intercept Adjustment ......................... 15
Specifications..................................................................................... 3
Changing the Voltage at the Summing Node ............................ 15
Absolute Maximum Ratings ............................................................ 4
Using the Adaptive Bias ............................................................. 16
ESD Caution .................................................................................. 4
Applications Information .............................................................. 17
Pin Configuration and Function Descriptions ............................. 5
Rescaling ...................................................................................... 17
Typical Performance Characteristics ............................................. 6
Inverting the Slope ..................................................................... 17
Theory of Operation ...................................................................... 10
Evaluation Board ........................................................................ 18
Basic Concepts ............................................................................ 10
Shields and Guards..................................................................... 18
Optical Measurements ............................................................... 10
Outline Dimensions ....................................................................... 21
Decibel Scaling............................................................................ 10
Ordering Guide .......................................................................... 21
REVISION HISTORY
1/13—Revision 0: Initial Version
Rev. 0 | Page 2 of 24
Data Sheet
ADL5303
SPECIFICATIONS
VPS = 5 V, GND, ACOM = 0 V, TA = 25°C, unless otherwise noted.
Table 1.
Parameter
INPUT INTERFACE
Specified Current Range
Input Node Voltage
Temperature Drift
Input Guard Offset Voltage
PHOTODIODE BIAS 2
Minimum Value
Transresistance
LOGARITHMIC OUTPUT
Slope
Intercept
Law Conformance Error
Maximum Output Voltage
Minimum Output Voltage
Output Resistance
REFERENCE OUTPUT
Voltage WRT Ground
Output Resistance
OUTPUT BUFFER
Input Offset Voltage
Input Bias Current
Incremental Input Resistance
Output Range
Output Resistance
Wideband Noise 3
Small Signal Bandwidth3
Slew Rate
POWER-DOWN INPUT
Logic Level, High State
Logic Level, Low State
POWER SUPPLY
Supply Voltage
Quiescent Current
In Disabled State
Test Conditions/Comments
Pin 3, INPT; Pin 2 and Pin 4, VSUM
Flows toward Pin 3
Internally preset; may be altered
−40°C < TA < +85°C
VOFS = VIN – VSUM
Established between VPDB and INPT
IPD = 100 pA
Pin 8, VLOG
Laser trimmed at 25°C
0°C < TA < 70°C
Laser trimmed at 25°C
0°C < TA < 70°C
10 nA < IPD < 1 mA, peak error
1 nA < IPD < 1 mA, peak error
Laser trimmed at 25°C
Pin 6, VREF
Laser trimmed at 25°C
−40°C < TA < +85°C
Min 1
Typ
Max1
100
0.46
0.5
0.04
−20
+20
70
100
200
195
193
60
35
200
4.95
1.98
1.92
10
0.54
100
0.05
0.1
1.6
0.1
5
2
Unit
pA
mA
V
mV/°C
mV
mV
mV/mA
205
207
140
175
0.25
0.7
5.05
mV/dec
mV/dec
pA
pA
dB
dB
V
V
kΩ
2.02
2.08
V
V
Ω
+20
mV
μA
MΩ
V
Ω
μV/√Hz
MHz
V/μs
2
Pin 9, BFIN; Pin 13, BFNG; Pin 11, VOUT
−20
Flowing out of Pin 9 or Pin 13
0.4
35
VPS − 0.1
0.5
1
10
15
RL = 1 kΩ to ground
IPD > 1 μA (see the Typical Performance Characteristics section)
IPD > 1 μA (see the Typical Performance Characteristics section)
0.2 V to 4.8 V output swing
Pin 16, PWDN
−40°C < TA < +85°C, 2.7 V < VPS < 5.5 V
−40°C < TA < +85°C, 2.7 V < VPS < 5.5 V
Pin 10 and Pin 12, VPS2 and VPS1; Pin 14 and 15, GND
2
1
3.0
Minimum and maximum specified limits on parameters are guaranteed but not tested and are six sigma values.
This bias is internally arranged to track the input voltage at INPT; it is not specified relative to ground.
3
Output noise and incremental bandwidth are functions of input current; see the Typical Performance Characteristics section.
1
2
Rev. 0 | Page 3 of 24
5
4.5
60
5.5
5.6
V
V
V
mA
μA
ADL5303
Data Sheet
ABSOLUTE MAXIMUM RATINGS
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.
Table 2.
Parameter
VPS
Input Current to INPT
Thermal Data, 2-Layer JEDEC Board, No Air
Flow (Exposed Pad Soldered to PCB)
θJA
θJC
Maximum Power Dissipation (Exposed
Pad Soldered to PCB)
Maximum Junction Temperature
Operating Temperature Range
Storage Temperature Range
Lead Temperature (Soldering 60 sec)
Rating
6V
20 mA
61.6°C/W
1.2°C/W
0.6 W
ESD CAUTION
125°C
−40°C to +85°C
−65°C to +150°C
300°C
Rev. 0 | Page 4 of 24
Data Sheet
ADL5303
VLOG 8
9 BFIN
NOTES
1. PINS LABELED NC CAN BE ALLOWED TO FLOAT, BUT
IT IS BETTER TO CONNECT THESE PINS TO GROUND.
AVOID ROUTING HIGH SPEED SIGNALS THROUGH
THESE PINS BECAUSE NOISE COUPLING MAY RESULT.
2. EXPOSED PAD. CONNECT THE EXPOSED PAD TO THE
VSUM PINS TO PROVIDE LOW LEAKAGE GUARD.
10661-002
14 GND
10 VPS2
ACOM 7
11 VOUT
TOP VIEW
(Not to Scale)
VPDB 5
VSUM 4
12 VPS1
ADL5303
VREF 6
INPT 3
13 BFNG
16 PWDN
PIN 1
INDICATOR
NC 1
VSUM 2
15 GND
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
Figure 2. Pin Configuration
Table 3. Pin Function Descriptions
Pin No.
1
Mnemonic
NC
2, 4
3
5
VSUM
INPT
VPDB
6
7
8
9
10
11
12
13
14, 15
16
17
VREF
ACOM
VLOG
BFIN
VPS2
VOUT
VPS1
BFNG
GND
PWDN
EPAD
Description
Pins labeled NC can be allowed to float, but it is better to connect these pins to ground. Avoid routing high
speed signals through these pins because noise coupling may result.
Guard Pins. VSUM is used to shield the INPT current line.
Photodiode Current Input. Connect this pin to the photodiode anode (the photo current flows toward INPT).
Photodiode Biaser Output. Connect this pin to the photodiode cathode when using adaptive bias control;
otherwise, leave this pin floating.
Voltage Reference Output of 2 V.
Analog Reference Ground.
Output of the Logarithmic Front-End Processor. ROUT = 5 kΩ to ground.
Buffer Amplifier Noninverting Input (High Impedance).
Positive Supply, VPS (3.0 V to 5.5 V).
Buffer Output; Low Impedance.
Positive Supply, VPS (3.0 V to 5.5 V).
Buffer Amplifier Inverting Input.
Power Supply Ground Connection.
Power-Down Control Input. Device is active when PWDN is taken low.
Exposed Pad. Connect the exposed pad to the VSUM pins to provide low leakage guard.
Rev. 0 | Page 5 of 24
ADL5303
Data Sheet
TYPICAL PERFORMANCE CHARACTERISTICS
0.510
1.6
–40°C
+25°C
+85°C
1.4
TA = –40°C, +25°C, +85°C
0.508
1.2
VSUM (V)
VLOG (V)
1.0
0.8
0.6
0.506
0.504
–40°C
+25°C
0.4
+85°C
0.502
1n
10n
100n
1µ
10µ
100µ
1m
10m
IPD (A)
0.500
100p
10661-003
0
100p
1n
10n
1µ
10µ
1m
100µ
10m
IPD (A)
Figure 3. VLOG vs. IPD
Figure 6. VSUM vs. IPD
2.0
2.8
+85°C
+25°C
–40°C
2.6
1.5
2.4
1.0
2.2
2.0
0.5
+25°C
VPDB (V)
ERROR (dB) 10mV/dB SCALE
100n
10661-006
0.2
0
–0.5
1.8
1.6
1.4
+85°C
1.2
–1.0 –40°C
1.0
–1.5
1µ
10µ
100µ
1m
10m
IPD (A)
0.6
0
1
2
5
6
7
8
10
9
Figure 7. VPDB vs. IPD
2.4
4.5V
5.0V
5.5V
2.2
1.25
TA = –40°C, +25°C, +85°C
VP = 3.0V
1.00
0.75
2.0
0.5
VOUT (V)
1.8
0
–40°C
0.50
0.25
1.6
1.4
+25°C
0
+85°C
–0.5
–1.0
100p
1n
10n
100n
1µ
IPD (A)
10µ
100µ
1m
10m
Figure 5. Absolute Deviation from Nominal Specified Value of VLOG for Several
Supply Voltages @ 25°C
1.2
–0.25
1.0
–0.50
0.8
–0.75
0.6
100p
10661-005
ERROR(dB) 10mV/dB SCALE
4
IPD (mA)
Figure 4. Logarithmic Conformance (Linearity) for VLOG
1.0
3
1n
10n
100n
1µ
10µ
100µ
1m
ERROR ((dB) (10mV/dB))
100n
–1.00
10m
IPD (A)
Figure 8. Logarithmic Conformance (Linearity) for a 3 V Single Supply
Rev. 0 | Page 6 of 24
10661-008
10n
10661-004
1n
10661-007
0.8
–2.0
100p
Data Sheet
ADL5303
10
10nA 100nA
10
1µA
10µA
10mA
1nA
A
–10
WIDEBAND NOISE (mV rms)
1mA
–20
–30
–40
–50
8
7
6
5
4
3
2
–60
1
1k
10k
100k
1M
10M
100M
FREQUENCY (Hz)
0
1n
10661-009
–70
100
10n
100n
1µ
10µ
100µ
1m
10m
INPUT CURRENT (A)
10661-012
NORMALIZED RESPONSE (dB)
9
100µA
0
Figure 12. Total Wideband Noise Voltage at VLOG vs. IPD
Figure 9. Small Signal AC Response, IPD to VLOG (5% Sine Modulation of IPD at
Frequency)
3
100
GAIN = 1×, 2×, 2.5×, 5×
100kHz
1
100Hz
1kHz
1MHz
0.1
0.01
1n
10n
100n
1µ
10µ
100µ
1m
10m
IPD (A)
0
AV = 5
AV = 2.5
–6
AV = 2
–9
10k
100k
1M
10M
100M
Figure 13. Small Signal Response of Buffer
10
100
fC =1kHz
1nA
NORMALIZED RESPONSE (dB)
–10
10
10nA
1µA
100nA
10µA
>100µA
0.1
0
–20
–30
–40
–50
0.01
100
1k
10k
100k
1M
10M
FREQUENCY (Hz)
Figure 11. Spot Noise Spectral Density at VLOG vs. Frequency
–70
10
100
1k
FREQUENCY (Hz)
10k
100k
10661-014
–60
10661-011
(µV rms/√Hz)
1k
FREQUENCY (Hz)
Figure 10. Spot Noise Spectral Density at VLOG vs. IPD
1
AV = 1
–3
–12
100
10661-010
(µV rms/√Hz)
10
10661-013
NORMALIZED RESPONSE (dB)
10kHz
Figure 14. Small Signal Response of Buffer Operating as Two-Pole Filter
Rev. 0 | Page 7 of 24
ADL5303
Data Sheet
20
2.0
TA = 25°C
15
1.5
MEAN + 3σ
10
ERROR (dB) ((10mV/dB))
1.0
VREF DRIFT (mV)
5
MEAN + 3σ
0.5
0
MEAN – 3σ
–0.5
0
–5
–10
–15
–1.0
MEAN – 3σ
–20
–1.5
10n
100n
1µ
10µ
1m
100µ
–30
–40 –30 –20 –10
10661-015
1n
10m
INPUT (A)
0
10
20
30
40
50
60
70
80
90
TEMPERATURE (°C)
Figure 15. Logarithmic Conformance Error Distribution (3 σ to Either
Side of Mean)
10661-018
–25
–2.0
100p
Figure 18. VREF Drift vs. Temperature (3 σ to Either Side of Mean)
5
3
TA = 0°C, 70°C
ERROR ((dB) (10mV/dB))
3
2
MEAN + 3σ @ 70°C
1
MEAN ± 3σ @ 0°C
0
–1
MEAN – 3σ @ 70°C
–2
–3
–4
1n
10n
100n
1µ
10µ
100µ
1m
10m
INPUT (A)
MEAN + 3σ
1
0
–1
–2
–3
MEAN – 3σ
–4
–5
–40 –30 –20 –10
10661-016
–5
100p
2
0
10
20
30
40
50
60
70
80
90
TEMPERATURE (°C)
Figure 16. Logarithmic Conformance Error Distribution (3 σ to Either
Side of Mean)
10661-019
SLOPE CHANGE FROM 25°C (mV/dec)
4
Figure 19. Slope Drift vs. Temperature (3 σ to Either Side of Mean)
40
5
TA = –40°C, +85°C
INTERCEPT CHANGE FROM 25°C (pA)
MEAN + 3σ @ –40°C
ERROR ((dB) (10mV/dB))
3
2
1
MEAN ± 3σ @ +85°C
0
–1
–2
–3
MEAN – 3σ @ –40°C
–4
1n
10n
100n
1µ
INPUT (A)
10µ
100µ
1m
10m
MEAN + 3σ
20
10
0
–10
–20
–30
MEAN – 3σ
–40
–50
–40 –30 –20 –10
10661-017
–5
100p
30
0
10
20
30
40
TEMPERATURE (°C)
50
60
70
80
90
10661-020
4
Figure 20. Intercept Drift vs. Temperature (3 σ to Either Side of Mean)
Figure 17. Logarithmic Conformance Error Distribution (3 σ to Either
Side of Mean)
Rev. 0 | Page 8 of 24
Data Sheet
ADL5303
8
160
140
6
120
MEAN + 3σ
100
2
HITS
80
0
60
–2
–6
–40 –30 –20 –10
0
10
20
30
40
50
60
70
80
90
TEMPERATURE (°C)
0
60
180
160
160
140
140
120
120
100
100
HITS
180
80
80
60
60
40
40
20
20
0
196
198
200
202
LOGARITHMIC SLOPE (mV/dec)
Figure 22. Distribution of Logarithmic Slope
204
140
Figure 23. Distribution of Logarithmic Intercept
0
–20
10661-022
HITS
Figure 21. Output Buffer Offset vs. Temperature (3 σ to Either Side of Mean)
80
100
120
LOGARITHMIC INTERCEPT (pA)
10661-023
20
10661-021
–4
40
MEAN – 3σ
–10
0
10
INPUT GUARD OFFSET (mV)
20
10661-024
Vos DRIFT (mV)
4
Figure 24. Distribution of Input Guard Offset Voltage VOFS (VINPT – VSUM)
Rev. 0 | Page 9 of 24
ADL5303
Data Sheet
THEORY OF OPERATION
Therefore, Equation 1 can be written as
BASIC CONCEPTS
VLOG = VY log10(POPT/PZ)
The ADL5303 uses an advanced circuit implementation that
exploits the logarithmic relationship between the base-toemitter voltage, VBE, and collector current, IC, in a bipolar
transistor.
Using these principles, the relationship between the input current,
IPD, applied to the INPT pin, and the voltage appearing at the
intermediate output VLOG pin is:
VLOG = VY log10(IPD/IZ)
(1)
where:
VY is the voltage slope (in the case of base-10 logarithms, it is
also referred to as volts per decade).
IZ is the fixed current in the logarithmic equation called the
intercept.
In the following example, the scaling is chosen so that VY is
trimmed to 200 mV/decade (10 mV/dB). The intercept is
positioned at 100 pA; the output voltage, VLOG, crosses zero
when IPD is of this value. However, the actual VLOG must always
be slightly above ground. Using Equation 2, calculate the output
for any value of IPD. Thus, for an input current of 25 nA,
VLOG = 0.2 V log10(25 nA/100 pA) = 0.4796 V
(2)
In practice, both the slope and intercept can be altered, to
either higher or lower values, without any significant loss of
calibration accuracy, by using one or two external resistors,
often in conjunction with the trimmed 2 V voltage reference
at the VREF pin.
(5)
For the ADL5303 operating in its default configuration, an IZ
of 100 pA corresponds to a PZ of 110 pW, for a diode having
a responsivity of 0.9 A/W. Thus, an optical power of 3 mW
generates
VLOG = 0.2 V log10(3 mW/110 pW) = 1487 V
(6)
Note that when using the ADL5303 in optical applications the
VLOG output is referred to in terms of the equivalent optical
power, the logarithmic slope remains 10 mV/dB at this output.
This can be confusing because a decibel change on the optical
side has a different meaning than on the electrical side. In either
case, the logarithmic slope can always be expressed in units of
millivolts per decade to help eliminate confusion.
DECIBEL SCALING
When power levels are expressed as decibels above a reference
level (in dBm, for a reference of 1 mW), the logarithmic conversion has already been performed, and the log ratio in the previous
expressions becomes a simple difference. Be careful in assigning
variable names here, because P is often used to denote actual
power as well as this same power expressed in decibels; however, these are numerically different quantities.
BANDWIDTH AND NOISE CONSIDERATIONS
OPTICAL MEASUREMENTS
Response time and wideband noise of translinear log amps
are a function of the signal current, IPD. Bandwidth becomes
progressively lower as IPD is reduced, largely due to the effects
of junction capacitances in the translinear device.
When interpreting the IPD current in terms of optical power
incident on a photodetector, it is necessary to be clear about
the conversion (optical power to current) properties of a reverse
biased photodiode. The units of this conversion are expressed
in amps per watt and referred to as photodiode responsivity, ρ.
For the typical InGaAs PIN photodiode, the responsivity is
approximately 0.9 A/W.
Figure 9 shows ac response curves for the ADL5303 at eight
representative currents of 1 nA to 10 mA, using R1 = 750 Ω
and C1 = 1000 pF. The values for R1 and C1 ensure stability
over the full 160 dB dynamic range. More optimal values may
be used for smaller subranges. A certain amount of experimental trial and error may be necessary to select the optimum
input network component values for a given application.
It is important to note that in purely electrical circuits, current
and power are not related in this proportional manner. A
current applied to a resistive load results in a power proportional to the square of the current, P = I2R. The difference in
scaling for a photodiode is because IPD flow in a reverse-biased
diode is largely dependent on the fixed built-in voltage of the
PN junction and is relatively insensitive to the external bias
voltage. In the detector diode, power dissipated is proportional
to the IPD current and the relationship of IPD to the optical
power, POPT, is preserved.
The relationship between IPD and the voltage noise spectral
density, SNSD, associated with the VBE of Q1, calculates to the
following:
IPD = ρPOPT
SNSD =
where:
SNSD is nV/Hz.
IPD is expressed in microamps.
TA = 25°C.
(3)
The same relationship exists between the intercept current, IZ,
and an equivalent intercept power, PZ, thus,
IPZ = ρPZ
14.7
I PD
(4)
Rev. 0 | Page 10 of 24
(7)
Data Sheet
ADL5303
For an input of 1 nA, SNSD evaluates to almost 0.5 μV/√Hz;
assuming a 20 kHz bandwidth at this current, the integrated
noise voltage is 70 μV rms. However, this calculation is not
complete. The basic scaling of the VBE is approximately
3 mV/dB; translated to 10 mV/dB, the noise predicted by
Equation 7 must be multiplied by approximately 3.33. The
additive noise effects associated with the reference transistor,
Q2, and the temperature compensation circuitry must also be
included. The final voltage noise spectral density presented at
the VLOG pin varies inversely with IPD, but is not a simple
square root relationship. Figure 10 shows the measured noise
spectral density vs. frequency at the VLOG output, for the same
nine-decade spaced values of IPD.
CHIP ENABLE
Power down the ADL5303 by taking the PWDN pin to a high
logic level. The residual supply current in the disabled mode is
typically 60 μA.
Rev. 0 | Page 11 of 24
ADL5303
Data Sheet
USING THE ADL5303
The slope can be lowered without limit by the addition of a
shunt resistor, RS, from VLOG to ground. Because the resistance
at this pin is trimmed to 5 kΩ, the accuracy of the modified
slope depends on the external resistor. It is calculated by,
The default configuration (see Figure 25) includes a 2.5:1 attenuator in the feedback path around the buffer. This increases the
slope of 10 mV/dB at the VLOG pin to 25 mV/dB at VOUT.
For the full dynamic range of 160 dB (80 dB optical), the output
swing is 4.0 V, which can be accommodated by the rail-to-rail
output stage when using the recommended 5 V supply.
VY =
The capacitor from VLOG to ground forms an optional
single-pole low-pass filter. Because the resistance at this pin
is trimmed to 5 kΩ, an accurate time constant can be realized.
For example, with CFLT = 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 even more
effective in reducing noise. A capacitor between VSUM and
ground is essential for minimizing the noise on this node.
When the bias voltage at either VPDB or VREF is not needed,
these pins should be left unconnected.
VY RS
RS + 5 kΩ
(8)
For example, using RS = 3 kΩ, the slope is lowered to 75 mV per
decade or 3.75 mV/dB. Table 4 provides a selection of suitable
values for RS and the resulting slopes.
Table 4. Examples of Lowering the Slope
RS (kΩ)
3
5
15
VY (mV/decade)
75
100
150
In addition to uses in filter and comparator functions, the
buffer amplifier provides the means to adjust both the slope
and intercept, which require a minimal number of external
components. The high input impedance at BFIN, low input
offset voltage, large output swing, and wide bandwidth of this
amplifier permit numerous transformations of the basic VLOG
signal, using standard op amp circuit practices. For example, it
has been noted that to raise the gain of the buffer, and therefore
the slope, a feedback attenuator, RA and RB in Figure 25, should
be inserted between VLOG and the inverting input BFNG pin.
SLOPE AND INTERCEPT ADJUSTMENTS
The choice of slope and intercept depends on the application.
The versatility of the ADL5303 permits optimal choices to
be made in two common situations. First, it allows an input
current range of less than the full 160 dB to use the available
voltage span at the output. Second, it allows this output voltage
range to be optimally positioned to fit the input capacity of a
subsequent ADC. In special applications, very high slopes, such
as 1 V/decade, allow small subranges of IPD to be covered at high
sensitivity.
VP
PWDN
VPS2
VPS1
10
16
12
PDB
BIAS
VREF
ADL5303
IPD
2
3
C1
1nF
4
6
NC
~10kΩ
0.5V
200mV/DEC
VSUM
C7 (CFILT)
VLOG
INPT
8
TEMPERATURE
COMPENSATION
BFIN
9
5kΩ
VSUM
BFNG
13
R18 (RB)
10kΩ
C3
100nF
R1
750
15
GND
7
ACOM
14
GND
11
R15 (RA)
15kΩ
VOUT
VOUT
500mV/DEC
NC = NO CONNECT
Figure 25. Basic Connections (R15, R18, C7 are Optional; R1 and C1 are the Default Values)
Rev. 0 | Page 12 of 24
10661-025
NC 5
VREF
VPDB
Data Sheet
ADL5303
buffer. Table 5 lists some examples of lowering the intercept
combined with several slope variations.
A wide range of gains may be used and the resistor magnitudes
are not critical; their parallel sum should be about equal to
the net source resistance at the noninverting input. When
high gains are used, the output dynamic range is reduced; for
a maximum swing of 4.8 V, it amounts to 4.8 V/VY decades.
Thus, using a ratio of 3×, to set up a slope 30 mV/dB (600 mV/
decade), eight decades can be handled, whereas with a ratio
of 5×, which sets up a slope of 50 mV/dB (1 V/decade), the
dynamic range is 4.8 decades, or 96 dB. When using a lower
supply voltage, the calculation proceeds in the same way,
remembering to first subtract 0.2 V to allow for 0.1 V upper
and lower headroom in the output swing.
Table 5. Examples of Lowering the Intercept
VY (mV/decade)
200
200
200
300
300
300
400
400
400
500
500
500
Alteration of the logarithmic intercept is only slightly more
tricky. First, note that it is rarely necessary to lower the intercept
below a value of 100 pA, because this merely raises all output
voltages further above ground. However, where this is required,
the first step is to raise the voltage, VLOG, by connecting a
resistor, RZ, from VLOG to VREF (2 V) as shown in Figure 26.
IZ (pA)
1
10
50
1
10
50
1
10
50
1
10
50
RA (kΩ)
20.0
10.0
3.01
10.0
8.06
6.65
11.5
9.76
8.66
16.5
14.3
13.0

I 
RLOG 
RZ
× log10  PD  + VREF ×
VOUT = G VY ×
 (9)
RLOG + RZ 
RZ + RLOG
 IZ 

where G = 1 + RA/RB and RLOG = 5 kΩ.
VP
PWDN
VPS1
16
10
12
ADL5303
PDB
IPD
NC 5
2
3
C1
1nF
4
BIAS
VREF
VREF
6
VPDB
~10kΩ
R14 (RZ)
0.5V
VSUM
VLOG
INPT
8
TEMPERATURE
COMPENSATION
BFIN
5kΩ
VSUM
9
BFNG
13
R18 (RB)
C3
100nF
R1
750Ω
7
ACOM
14
GND
11
R15 (RA)
VOUT
VOUT
500mV/DEC
NC = NO CONNECT
Figure 26. Method for Lowering the Intercept
Rev. 0 | Page 13 of 24
10661-026
15
GND
RZ (kΩ)
25
50
165
25
50
165
25
50
165
25
50
165
Use the following equation with Table 5:
This has the effect of elevating, VLOG, for small inputs while
lowering the slope to some extent because of the shunt effect
of RZ on the 5 kΩ output resistance. If necessary, the slope may
be increased as before, using a feedback attenuator around the
VPS2
RB (kΩ)
100
100
100
12.4
12.4
12.4
8.2
8.2
8.2
8.2
8.2
8.2
ADL5303
Data Sheet
Table 6. Examples of Raising the Intercept
Generally, it is useful to raise the intercept. Keep in mind that
this moves the VLOG line in Figure 26 to the right, lowering all
output values. Figure 27 shows how raising the intercept is
achieved. The feedback resistors, RA and RB, around the buffer
are now augmented with a third resistor, RZ, placed between the
BFNG and VREF pins. Adding a third resistor raises the zerosignal voltage on BFNG, which has the effect of pushing VOUT
lower. Note that the addition of the RZ resistor also alters the
feedback ratio. However, this change in feedback ratio is readily
compensated in the design of the network. Table 6 lists the
resistor values for representative intercepts.
VY (mV/decade)
300
300
400
400
400
500
500
500
IZ (nA)
10
100
10
100
500
10
100
500
RA (kΩ)
7.5
8.25
10
9.76
9.76
12.4
12.4
11.5
R A RB 

 = VREF ×


R A RB + RC 

RA
R × RB
and R A RB = A
.
RB RC
RA × RB
where G = 1 +
VP
PWDN
VPS1
10
16
12
PDB
BIAS
VREF
ADL5303
IPD
2
3
C1
1nF
4
VREF
6
VPDB
~10kΩ
0.5V
VSUM
VLOG
INPT
8
TEMPERATURE
COMPENSATION
BFIN
5kΩ
VSUM
R13
(RC)
9
BFNG
13
C3
100nF
R18
(RB)
R1
750
15
GND
7
ACOM
14
GND
11
R15
(RA)
VOUT
VOUT
500mV/DEC
NC = NO CONNECT
Figure 27. Method for Raising the Intercept
Rev. 0 | Page 14 of 24
10661-027
NC 5
RC (kΩ)
24.9
18.2
25.5
16.2
13.3
24.9
16.5
12.4
Use the following equation with Table 6:

I
VOUT = G VY × log 10  PD
 IZ

VPS2
RB (kΩ)
37.4
130
16.5
25.5
36.5
12.4
16.5
20.0
(10)
Data Sheet
ADL5303
CHANGING THE VOLTAGE AT THE SUMMING NODE
LOW SUPPLY SLOPE AND INTERCEPT
ADJUSTMENT
The default value of VSUM is determined by using a quarter
of VREF (2 V). This can be altered by applying an independent
voltage source to VSUM, or by adding an external resistive
divider from VREF to VSUM. This network operates in parallel
with the internal divider (40 kΩ and 13.3 kΩ), and the choice
of external resistors should take this into account. In practice,
the total resistance of the added string may be as low as 10 kΩ
(consuming 400 μA from VREF). Low values of VSUM and
thus VCE are not advised when large values of IPD are expected.
When using the device with a supply of less than 4 V, it is
necessary to reduce the slope and intercept at the VLOG pin
to preserve good log conformance over the entire 160 dB operating range. The voltage at the VLOG pin is generated by an
internal current source with an output current of 40 μA/decade
feeding the internal laser trimmed output resistance of 5 kΩ.
When the voltage at the VLOG pin exceeds VP − 2.3 V, the
current source ceases to respond linearly to logarithmic
increases in current. Avoid headroom issues by reducing
the logarithmic slope and intercept at the VLOG pin and by
connecting an external resistor, RS, from the VLOG pin to
ground in combination with an intercept lowering resistor, RZ.
The values shown in Figure 28 illustrate a good solution for a
3.0 V positive supply. The resulting logarithmic slope measured
at VLOG is 62.5 mV/decade with a new intercept of 57 fA. The
original logarithmic slope of 200 mV/decade can be recovered
using voltage gain on the internal buffer amplifier.
VP
PWDN
VPS2
VPS1
16
10
12
ADL5303
PDB
IPD
2
3
C1
1nF
4
VREF
VREF
~10kΩ
6
R14 (RZ)
15.4kΩ
0.5V
VSUM
VLOG
INPT
TEMPERATURE
COMPENSATION
VSUM
8
BFIN
5kΩ
BFNG
C7 (RS)
2.67kΩ
9
13
R18 (RB)
2.26kΩ
C3
100nF
R1
750Ω
15
GND
7
ACOM
14
GND
11
R15 (RA)
4.98kΩ
VOUT
VOUT
500mV/DEC
NC = NO CONNECT
Figure 28. Recommended Low Supply Application Circuit
Rev. 0 | Page 15 of 24
10661-028
NC 5
BIAS
VPDB
ADL5303
Data Sheet
USING THE ADAPTIVE BIAS
range, the adaptive biasing function is valuable in minimizing
dark current while preventing the loss of photodiode bias at
high currents. Use of the adaptive bias feature is shown in
Figure 29.
For most photodiode applications, the placement of the anode
somewhat above ground is acceptable, as long as the positive
bias on the cathode is adequate to support the peak current for
a particular diode, limited mainly by its series resistance. To
address this matter, the ADL5303 provides for a diode bias that
increases linearly with the current. This bias voltage appears at
the VPDB pin, and varies from 0.6 V (reverse-biasing the diode
by 0.1 V) for IPD = 100 pA and rises to 2.6 V (for a diode bias of
2 V) at IPD = 10 mA. This results in a constant internal junction
bias of 0.1 V when the series resistance of the photodiode is
200 Ω. For optical power measurements over a wide dynamic
Capacitor CPB, between the photodiode cathode at the VPDB
pin and ground, is included to lower the impedance at this node
and thereby improve the high frequency accuracy at current
levels where the ADL5303 bandwidth is high. CPB also ensures
a high frequency path for any high frequency modulation on
the optical signal, which might not otherwise be accurately
averaged. CPB is not necessary in all cases, and experimentation
may be required to find an optimum value.
VP
PWDN
VPS2
10
VPS1
16
12
ADL5303
CPB
R25
PDB
5
IPD
2
3
C1
1nF
4
BIAS
VREF
VREF
6
NC
VPDB
~10kΩ
0.5V
VSUM
C7 (CFILT)
VLOG
INPT
8
TEMPERATURE
COMPENSATION
BFIN
5kΩ
VSUM
9
BFNG
13
R18 (RB)
10kΩ
C3
100nF
R1
750
15
GND
7
ACOM
14
GND
11
R15 (RA)
15kΩ
VOUT
VOUT
500mV/DEC
NC = NO CONNECT
Figure 29. Using the Adaptive Biasing
Rev. 0 | Page 16 of 24
10661-029
LOCATION
Data Sheet
ADL5303
APPLICATIONS INFORMATION
when not needed. Figure 30 shows its use as an inverting amplifier; this changes the polarity of the slope. The output can be
repositioned to a positive value by applying a fraction of VREF
to the BFIN pin. The full design for a practical application is
left undefined in this brief illustration, but a few cases are
discussed, as follows.
Smaller input voltages can be measured accurately when
aided by a small offset nulling voltage applied to VSUM.
The minimum voltage that can be accurately measured is
limited only by the drift in the input offset of the ADL5303.
The specifications show the maximum spread over the full
temperature and supply range. Over a limited temperature
range and with a regulated supply, the offset drift is lower;
in this situation, processing of inputs down to 5 mV is
practicable.
For example, if slope of −30 mV/dB is needed; a gain of 3 is
required. Because VLOG exhibits a source resistance of 5 kΩ,
RA must be 15 kΩ. A positive offset, VOS, is applied to the BFIN
pin, as indicated in Figure 30. The resulting output voltage can
be expressed as
RESCALING
The use of a much larger value for the intercept may be useful
in certain situations. In this example, it has been moved up four
decades, from the default value of 100 pA to the center of the
full eight-decade range at 1 mA. Using a voltage input as previously described, this corresponds to an altered voltage mode
intercept, VZ, which is 1 V for RIN = 1 MΩ. To take full advantage
of the larger output swing, the gain of the buffer has been
increased to 4.53, resulting in a scaling of 900 mV/decade
zand a full-scale output of ±3.6 V.
 R 
I
VOUT = − A  VY × log10  PD
 5 kΩ 
 IZ


The buffer is essentially an uncommitted op amp that can be
used to support the operation of the ADL5303 in a variety of
ways. It can be completely disconnected from the signal chain
VP
PWDN
VPS1
10
16
12
PDB
BIAS
VREF
ADL5303
IPD
NC
5
2
3
C1
1nF
4
VREF
6
NC
VPDB
~10kΩ
0.5V
VSUM
VLOG
INPT
8
TEMPERATURE
COMPENSATION
BFIN
5kΩ
VSUM
VOS
9
BFNG
13
C3
100nF
R1
750Ω
GND
7
ACOM
14
GND
11
R15 (RA)
VOUT
VOUT
NC = NO CONNECT
Figure 30. Using the Buffer to Invert the Polarity of the Slope
Rev. 0 | Page 17 of 24
10661-030
15
(11)
When the gain is set to 13 (RA = 5 kΩ), the 2 V VREF can be tied
directly to BFIN, in which case the starting point for the output
response is at 4 V. However, because the slope in this case is
only −0.2 V/decade, the full current range takes the output
down by only 1.6 V. Clearly, a higher slope (or gain) is desirable;
in which case, set VOS to a smaller voltage to avoid railing the
output at low currents. If VOS = 1.2 V and G = 33, VOUT now
starts at 4.8 V and falls through this same voltage toward ground
with a slope of −0.6 V per decade, spanning the full range of IPD.
INVERTING THE SLOPE
VPS2


 + VOS

ADL5303
Data Sheet
EVALUATION BOARD
An evaluation board is available for the ADL5303, the schematic for which is shown in Figure 31, and the board layout
is shown in Figure 32 and Figure 33. It can be configured for
a wide variety of experiments. The board is factory set for
photoconductive mode with a buffer gain of unity, providing a
slope of 10 mV/dB and an intercept of 100 pA. By substituting
resistor and capacitor values, all of the application circuits
presented in this data sheet can be evaluated.
The system is completed by the final buffer amplifier, which is
an uncommitted op amp with a rail-to-rail output capability,
a 10 MHz bandwidth, and good load driving capabilities. The
buffer can be used to implement multipole low-pass filters for
noise reduction. The buffer also facilitates modification of the
output scaling and the intercept point using simple resistor
divider networks and the 2 V output provided by the VREF pin.
SHIELDS AND GUARDS
Reducing errors from external sources in a current sensing
circuit requires a different approach then the voltage sensing
input of the typical high impedance op-amp circuit. Leakage
can be a significant source of error for highly sensitive log amps,
especially at the low end of their range. For example, a 1 GΩ
leakage path to ground from the INPT input with a VSUM set
to the default 0.5 V generates a 0.5 nA offset. The ADL5303
evaluation board makes extensive use of guards to reduce the
effects of leakage at low input levels. It is important to carefully
handle and clean the ADL5303 evaluation board to prevent
contaminants from handling or improper washing of the
PCB causing leakage currents. Circuit board designs for
the ADL5303 must connect the EPAD to the VSUM pins
to provide a continuous guard around the sensitive INPT
pin to reduce the influence of surface contaminants.
A common mistake for those unfamiliar with low level current
sensing is to attach a high impedance scope probe or meter to
measure the input for debug. This can cause significant error,
as the typical 1M ~ 100 MΩ impedance of these probes sources/
sinks current from the input, depending on their bias.
In instrumentation applications where measurements <1 nA are
required, the use of triaxial cables and connectors is common to
reduce leakage through the insulating dielectric by carrying a
continuous guard from current source to sensing circuit on the
intermediate conductor. This type of guarding circuit is different from a conventional electrostatic shield used in voltage
sensing applications. An electrostatic shield relies on low
impedance and the ability to flow current freely to minimize
voltage induced on the shield that can capacitively couple into
a high impedance input. A guard is actively driven to the same
voltage as the current carrying center conductor eliminating
leakage through the dielectric between the center conductor
and the guard. The guard does not flow current other than the
leakage from the guard to the outer shield. The guard is usually
connected to a single end of the cable only because any significant current flow through the guard can couple inductively
to the center conductor. Using the ADL5303 evaluation board,
the guard can be driven either from the guard of an external
current source or from the internal VSUM bias of the ADL5303.
The ADL5303 evaluation board can bias the shield of a coaxial
cable connected to the INPT input to the nominal VSUM voltage
with Switch S1 but this requires careful consideration of the
environment on the other side of the cable. For example if
the ADL5303 evaluation board is configured for VSUM = 0.5 V
connecting the other end of the INPT coaxial cable to an
instrument with a ground referenced shield pulls VSUM to
ground and collapses the input stage of the ADL5303. Floating
the current source end of the shield provides a low leakage
guard but a separate return path for the signal current must
then be provided. If cable dielectric leakage is not a concern,
the INPT can be connected directly to a coaxial cable with
the shield providing a signal ground.
Rev. 0 | Page 18 of 24
Figure 31. Schematic
Rev. 0 | Page 19 of 24
0Ω
R4
AGND
R6
DNI
R25 OR (CPB)
DNI
0Ω
0Ω
AGND
R24
AGND
R2
0Ω
0Ω
R3
1
S2
R5
DNI
GND2
R23
C1
1000pF
R1
750Ω
2
3
DNI = NOT INSTALLED IN DEFAULT CONFIGURATION
AGND
VPDB
INPT
1
S1
AGND
2
AGND
AGND
C3
0.1µF
R7
DNI
VPOS
AGND
R9
DNI
R8
DNI
4
3
2
1
ACOM
VREF
7
6
16 15 14 13
5
VSUM
INPT
VSUM
NC
PAD
R12
0Ω
PWDN
VPDB
3
GND
VREF
R10
10kΩ
GND
ACOM
1000PF
8
9
10
11
12
0Ω
R26
DNI
R14 (RZ)
DNI
R13 (RC)
BFIN
VPS2
VOUT
U1
AGND
GND1
VPS1
BFNG
VLOG
VPOS
AGND
GND2
R11
DNI
0Ω
R16
R15 (RA)
15kΩ
0Ω
R17
VPOS
C5
0.1µF
10kΩ
R18 (RB)
0.1µF
C6
0Ω
R22
0Ω
C7 (CFILT OR RS)
0.1µF
R20
0Ω
R19
DNI
R21
AGND
AGND
AGND
AGND
C8
0.1µF
VLOG_OUT
BUFFER_OUT
AGND
AGND
10661-031
C2
Data Sheet
ADL5303
Data Sheet
10661-033
10661-032
ADL5303
Figure 33. Component Side Silkscreen
Figure 32. Component Side Layout
Table 7. Evaluation Board Configuration Options
Component
VPOS, AGND
S1
S2
R13 (RC), R14 (RZ)
R5, R6, R7, R8, R9
R15 (RA), R18 (RB)
Function
Positive supply and ground pins.
Device enable. When S1 is in the 0 position, the PWDN pin is connected to
ground and the ADL5303 is in its normal operating mode.
Guard/shield options. The shells of the SMA connectors used for the input and
the photodiode bias can be set to the voltage on the VSUM pin or connected
to ground. When S2 is in the 0 position, the SMA shell is connected to VSUM.
Intercept adjustment. A dc offset can be applied to the input terminals of the
buffer amplifier to adjust the effective logarithmic intercept.
Bias adjustment. The voltage on the VSUM and INPT pins can be altered using
appropriate resistor values.
Slope adjustment.
C3
C6
R25 (CPB )
C5, C7 (CFILT or RS), C8,
R11, R16, R17, R19,
R20
R1, C1
VSUM decoupling capacitor.
Supply decoupling capacitor.
Photodiode biaser decoupling. Provides high frequency decoupling.
Output filtering. Allows implementation of a variety of filter configurations,
from simple RC low-pass filters to three-pole Sallen and Key filters.
R2, R3, R4, R23, R24,
R21, R22, R12, R26
Isolation jumpers.
Input filtering. Provides essential HF compensation at the input pin, INPT.
Rev. 0 | Page 20 of 24
Default Condition
S1 = installed
S2 = installed
R13 = open (Size 0603)
R14 = open (Size 0603)
R5, R6, R7 = open (Size 0603)
R8, R9 = open (Size 0603)
R15 = 15 kΩ (Size 0603)
R18 = 10 kΩ (Size 0603)
C3 = 0.1 μF (Size 0603)
C6 = 0.1 μF (Size 0603)
R25 = open (Size 0603)
R11, R19, C5 = Open (Size 0603)
R16, R17, R20 = 0 Ω (Size 0603)
C7, C8 = 0.1 μF (Size 0603)
R1 = 750 Ω (Size 0402)
C1 = 1 nF (Size 0603)
All = 0 Ω (Size 0603)
Data Sheet
ADL5303
OUTLINE DIMENSIONS
PIN 1
INDICATOR
3.10
3.00 SQ
2.90
0.30
0.25
0.20
0.50
BSC
PIN 1
INDICATOR
16
13
1
12
EXPOSED
PAD
1.65
1.50 SQ
1.45
9
0.80
0.75
0.70
SEATING
PLANE
4
8
5
0.20 MIN
BOTTOM VIEW
0.05 MAX
0.02 NOM
COPLANARITY
0.08
0.20 REF
FOR PROPER CONNECTION OF
THE EXPOSED PAD, REFER TO
THE PIN CONFIGURATION AND
FUNCTION DESCRIPTIONS
SECTION OF THIS DATA SHEET.
01-26-2012-A
TOP VIEW
0.50
0.40
0.30
COMPLIANT TO JEDEC STANDARDS MO-220-WEED-6.
Figure 34. 16-Lead Lead Frame Chip Scale Package [LFCSP_WQ]
3 mm × 3 mm Body, Very Very Thin Quad
(CP-16-27)
Dimensions shown in millimeters
ORDERING GUIDE
Model1
ADL5303ACPZ-R2
ADL5303ACPZ-R7
ADL5303ACPZ-RL
ADL5303-EVALZ
1
Temperature
Range
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
Package Description
16-Lead LFCSP_WQ
16-Lead LFCSP_WQ, 7” Tape and Reel
16-Lead LFCSP_WQ, 13” Tape and Reel
Evaluation Board
Z = RoHS Compliant Part.
Rev. 0 | Page 21 of 24
Package
Option
CP-16-27
CP-16-27
CP-16-27
Branding
H38
H38
H38
Ordering
Quantity
250
1500
5000
ADL5303
Data Sheet
NOTES
Rev. 0 | Page 22 of 24
Data Sheet
ADL5303
NOTES
Rev. 0 | Page 23 of 24
ADL5303
Data Sheet
NOTES
©2013 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D10661-0-1/13(0)
Rev. 0 | Page 24 of 24