a
Universal
LVDT Signal Conditioner
AD698
FEATURES
Single Chip Solution, Contains Internal Oscillator and
Voltage Reference
No Adjustments Required
Interfaces to Half-Bridge, 4-Wire LVDT
DC Output Proportional to Position
20 Hz to 20 kHz Frequency Range
Unipolar or Bipolar Output
Will Also Decode AC Bridge Signals
Outstanding Performance
Linearity: 0.05%
Output Voltage: 611 V
Gain Drift: 20 ppm/8C (typ)
Offset Drift: 5 ppm/8C (typ)
FUNCTIONAL BLOCK DIAGRAM
VOLTAGE
REFERENCE
AMP
OSCILLATOR
AD698
B
A
B
FILTER
AMP
A
PRODUCT DESCRIPTION
PRODUCT HIGHLIGHTS
The AD698 is a complete, monolithic Linear Variable Differential Transformer (LVDT) signal conditioning subsystem. It is
used in conjunction with LVDTs to convert transducer mechanical position to a unipolar or bipolar dc voltage with a high degree of accuracy and repeatability. All circuit functions are
included on the chip. With the addition of a few external passive
components to set frequency and gain, the AD698 converts the
raw LVDT output to a scaled dc signal. The device will operate
with half-bridge LVDTs, LVDTs connected in the series opposed configuration (4-wire), and RVDTs.
1. The AD698 offers a single chip solution to LVDT signal
conditioning problems. All active circuits are on the monolithic chip with only passive components required to complete the conversion from mechanical position to dc voltage.
The AD698 contains a low distortion sine wave oscillator to
drive the LVDT primary. Two synchronous demodulation
channels of the AD698 are used to detect primary and secondary amplitude. The part divides the output of the secondary by
the amplitude of the primary and multiplies by a scale factor.
This eliminates scale factor errors due to drift in the amplitude
of the primary drive, improving temperature performance and
stability.
The AD698 uses a unique ratiometric architecture to eliminate
several of the disadvantages associated with traditional approaches to LVDT interfacing. The benefits of this new circuit are: no adjustments are necessary; temperature stability is
improved; and transducer interchangeability is improved.
The AD698 is available in two performance grades:
Grade
AD698AP
AD698SQ
Temperature Range
–40°C to +85°C
–55°C to +125°C
Package
28-Pin PLCC
24-Pin Cerdip
2. The AD698 can be used with many different types of position sensors. The circuit is optimized for use with any
LVDT, including half-bridge and series opposed, (4 wire)
configurations. The AD698 accommodates a wide range of
input and output voltages and frequencies.
3. The 20 Hz to 20 kHz excitation frequency is determined by a
single external capacitor. The AD698 provides up to 24 volts
rms to differentially drive the LVDT primary, and the
AD698 meets its specifications with input levels as low as
100 millivolts rms.
4. Changes in oscillator amplitude with temperature will not affect overall circuit performance. The AD698 computes the
ratio of the secondary voltage to the primary voltage to determine position and direction. No adjustments are required.
5. Multiple LVDTs can be driven by a single AD698 either in
series or parallel as long as power dissipation limits are not
exceeded. The excitation output is thermally protected.
6. The AD698 may be used as a loop integrator in the design of
simple electromechanical servo loops.
7. The sum of the transducer secondary voltages do not need to
be constant.
REV. B
Information furnished by Analog Devices is believed to be accurate and
reliable. However, no responsibility is assumed by Analog Devices for its
use, nor for any infringements of patents or other rights of third parties
which may result from its use. No license is granted by implication or
otherwise under any patent or patent rights of Analog Devices.
© Analog Devices, Inc., 1995
One Technology Way, P.O. Box 9106, Norwood. MA 02062-9106, U.S.A.
Tel: 617/329-4700
Fax: 617/326-8703
AD698–SPECIFICATIONS (@ T = +258C, V
A
Parameter
CM
= 0 V, and V+, V– = 615 V dc, unless otherwise noted)
Min
AD698SQ
Typ
Max
Min
AD698AP
Typ
Max
TRANSFER FUNCTION1
VOUT = A × 500 µA × R2
B
OVERALL ERROR TMIN to TMAX
0.4
SIGNAL OUTPUT CHARACTERISTICS
Output Voltage Range
Output Current, TMIN to TMAX
Short Circuit Current
Nonlinearity2 TMIN to TMAX
Gain Error3
Gain Drift
Output Offset
Offset Drift
Excitation Voltage Rejection4
Power Supply Rejection (± 12 V to ± 18 V)
PSRR Gain
PSRR Offset
Common-Mode Rejection (± 3 V)
CMRR Gain
CMRR Offset
Output Ripple5
EXCITATION OUTPUT CHARACTERISTICS (@ 2.5 kHz)
Excitation Voltage Range
Excitation Voltage (Resistors Are 1% Absolute Values)
(R1 = Open)6
(R1 = 12.7 kΩ)
(R1 = 487 Ω)
Excitation Voltage TC7
Output Current
TMIN to TMAX
Short Circuit Current
DC Offset Voltage (Differential, R1 = 12.7 kΩ)
TMIN to TMAX
Frequency
Frequency TC
Total Harmonic Distortion
SIGNAL INPUT CHARACTERISTICS
A/B Ratio Usable Full-Scale Range
Signal Voltage B Channel
Signal Voltage A Channel
Input Impedance
Input Bias Current (BIN, AIN)
Signal Reference Bias Current
Excitation Frequency
POWER SUPPLY REQUIREMENTS
Operating Range
Dual Supply Operation (± 10 V Output)
Single Supply Operation
0 V to +10 V Output
0 V to 10 V Output
Current (No Load at Signal and Excitation Outputs)
TMIN to TMAX
OPERATING TEMPERATURE RANGE
1.65
611
0.4
V
1.65
611
11
20
75
0.1
20
0.02
5
100
11
20
75
0.1
20
0.02
5
100
6500
61.0
6100
61
625
Unit
6500
61.0
6100
61
625
% of FS
V
mA
mA
ppm of FS
% of FS
ppm/°C of FS
% of FS
ppm/°C of FS
ppm/dB
50
15
300
100
50
15
300
100
ppm/V
ppm/V
25
2
4
100
100
25
2
4
100
100
ppm/V
ppm/V
mV rms
2.1
24
2.1
24
V rms
1.2
2.6
14
2.15
4.35
21.2
1.2
2.6
14
2.15
4.35
21.2
V rms
V rms
V rms
ppm/°C
mA rms
mA rms
mA
6100
20 k
mV
Hz
ppm/°C
dB
30
100
50
40
60
30
20
30
6100
20 k
30
20
200
–50
0.1
0.1
0.0
200
–50
0.9
3.5
3.5
200
1
2
0
13
± 13
5
10
20 k
36
17.5
17.5
–2–
0.l
0.1
0.0
0.9
3.5
3.5
200
1
2
0
13
± 13
5
10
20 k
36
17.5
17.5
12
–55
100
50
40
60
15
18
+125
12
–40
V rms
V rms
kΩ
µA
µA
Hz
V
V
15
18
V
V
mA
mA
+85
°C
REV. B
AD698
NOTES
1
A and B represent the Mean Average Deviation (MAD) of the detected sine waves V A and VB. The polarity of VOUT is affected by the sign of the A comparator, i.e.,
multiply VOUT × +1 for ACOMP+ > ACOMP–, and VOUT × –1 for ACOMP– > ACOMP+.
2
Nonlinearity of the AD698 only in units of ppm of full scale. Nonlinearity is defined as the maximum measured deviation of the AD698 output voltage from a
straight line. The straight line is determined by connecting the maximum produced full-scale negative voltage with the maximum produced full-scale positive voltage.
3
See Transfer Function.
4
For example, if the excitation to the primary changes by 1 dB, the gain of the system will change by typically 100 ppm.
5
Output ripple is a function of the AD698 bandwidth determined by C1 and C2. A 1000 pF capacitor should be connected in parallel with R2 to reduce the output
ripple. See Figures 7, 8 and 13.
6
R1 is shown in Figures 7, 8 and 13.
7
Excitation voltage drift is not an important specification because of the ratiometric operation of the AD698.
8
From TMIN to TMAX the overall error due to the AD698 alone is determined by combining gain error, gain drift and offset drift. For example, the typical overall
error for the AD698AP from T MIN to TMAX is calculated as follows: Overall Error = Gain Error at +25°C (± 0.2% Full Scale) + Gain Drift from –40°C to +25°C
(20 ppm/°C × 65°C) + Offset Drift from –40°C to +25°C (5 ppm/°C × 65°C) = ± 0.36% of full scale. Note that 1000 ppm of full scale equals 0.1% of full scale.
Specifications subject to change without notice.
Specifications shown in boldface are tested on all production units at final electrical test. Results from those tested are used to calculate outgoing quality levels.
All min and max specifications are guaranteed, although only those shown in boldface are tested on all production units.
CONNECTION DIAGRAMS
ABSOLUTE MAXIMUM RATINGS
Total Supply Voltage (+VS to –VS) . . . . . . . . . . . . . . . . . 36 V
Storage Temperature Range
P Package . . . . . . . . . . . . . . . . . . . . . . . . . –65°C to +150°C
Q Package . . . . . . . . . . . . . . . . . . . . . . . . –65°C to +150°C
Operating Temperature Range
AD698SQ . . . . . . . . . . . . . . . . . . . . . . . . –55°C to +125°C
AD698AP . . . . . . . . . . . . . . . . . . . . . . . . . –40°C to +85°C
Lead Temperature Range (Soldering 60 sec) . . . . . . . . +300°C
Power Dissipation Derates above +65°C
P Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 mW/°C
Q Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 mW/°C
–VS
+VS
2
1
28 27 26
OFF1
EXC1
3
OFF2
NC
4
LEV1 5
25 NC
LEV2 6
24 SIG REF
FREQ1 7
AD698
FREQ2 8
TOP VIEW
(Not to Scale)
23 SIG OUT
22 FEEDBACK
21 OUT FILT
NC 9
20 AFILT1
BFILT2 11
19 AFILT2
+ACOMP
NC = NO CONNECT
–ACOMP
14 15 16 17 18
+AIN
NC
–BIN
12 13
–AIN
θJA
60°C/W
62°C/W
BFILT1 10
+BIN
THERMAL CHARACTERISTICS
θJC
P Package 30°C/W
Q Package 26°C/W
EXC2
28-Pin PLCC
ORDERING GUIDE
Model
Package Description
Package Option
AD698AP
AD698SQ
28-Pin PLCC
24-Pin Double Cerdip
P-28A
Q-24A
24-Pin Cerdip
–VS 1
24 +VS
EXC1 2
23 OFFSET1
EXC2 3
22 OFFSET2
LEV1 4
21 SIG REF
LEV2 5
20 SIG OUT
AD698
FREQ1 6
TOP VIEW 19 FEEDBACK
FREQ2 7 (Not to Scale) 18 OUT FILT
BFILT1 8
17 AFILT1
BFILT2 9
16 AFILT2
–BIN 10
15 –ACOMP
+BIN 11
14 +ACOMP
–AIN 12
13 +AIN
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 the AD698 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. B
–3–
WARNING!
ESD SENSITIVE DEVICE
AD698
Typical Characteristics (at +25°C and V = ±15 V unless otherwise noted)
240
120
200
80
160
TYPICAL GAIN DRIFT – ppm/°C
GAIN AND OFFSET PSRR – ppm/V
S
GAIN PSRR 15–18V
120
80
40
GAIN PSRR 12–15V
20
0
OFFSET PSRR 12–15V
40
20
0
–20
–40
–60
OFFSET PSRR 15–18V
–20
–60
–40
–20
0
20
40
60
80
100
120
–80
–60
140
TEMPERATURE – °C
0
20
40
60
80
100
120
140
Figure 3. Typical Gain Drift vs. Temperature
0
20
OFFSET CMRR ± 3V
15
TYPICAL OFFSET DRIFT – ppm/°C
–05
GAIN AND OFFSET CMRR – ppm/V
–20
TEMPERATURE – °C
Figure 1. Gain and Offset PSRR vs. Temperature
–10
–15
–20
–25
–30
GAIN CMRR ± 3V
–35
10
5
0
–5
–10
–15
–40
–45
–60
–40
–40
–20
0
20
40
60
80
TEMPERATURE – °C
100
120
–20
–60
140
–40
–20
0
20
40
60
80
100
120
140
TEMPERATURE – °C
Figure 2. Gain and Offset CMRR vs. Temperature
Figure 4. Typical Offset Drift vs. Temperature
–4–
REV. B
AD698
THEORY OF OPERATION
gain error in the output. The AD698, eliminates these errors by
A block diagram of the AD698 along with an LVDT (linear
variable differential transformer) connected to its input is shown
in Figure 5 below. The LVDT is an electromechanical transducer—its input is the mechanical displacement of a core, and
its output is an ac voltage proportional to core position. Two
popular types of LVDTs are the half-bridge type and the series
opposed or four-wire LVDT. In both types the moveable core
couples flux between the windings. The series-opposed connected LVDT transducer consists of a primary winding energized by an external sine wave reference source and two
secondary windings connected in the series opposed configuration.
calculating the ratio of the LVDT output to its input excitation in
order to cancel out any drift effects. This device differs from the
AD598 LVDT signal conditioner in that it implements a different
circuit transfer function and does not require the sum of the LVDT
secondaries (A + B) to be constant with stroke length.
The AD698 block diagram is shown below. The inputs consist
of two independent synchronous demodulation channels. The B
channel is designed to monitor the drive excitation to the LVDT.
The full wave rectified output is filtered by C2 and sent to the
computational circuit. Channel A is identical except that the
comparator is pinned out separately. Since the A channel may
reach 0 V output at LVDT null, the A channel demodulator is
usually triggered by the primary voltage (B Channel). In addition, a phase compensation network may be required to add a
phase lead or lag to the A Channel to compensate for the LVDT
primary to secondary phase shift. For half-bridge circuits the
phase shift is noncritical, and the A channel voltage is large
enough to trigger the demodulator.
The output voltage across the series secondary increases as the core
is moved from the center. The direction of movement is detected
by measuring the phase of the output. Half-bridge LVDTs have a
single coil with a center tap and work like an autotransformer. The
excitation voltage is applied across the coil; the voltage at the center
tap is proportional to position. The device behaves similarly to a
resistive voltage divider.
C2
VOLTAGE
REFERENCE
AMP
BFILT1
+VS
BFILT2
OSCILLATOR
B
AD698
R2
–BIN
A
B
V/I
FILTER
C5
CHANNEL
B
±1
+BIN
AMP
OUT
FILTER
FILTER
C4
FB
VOUT
A
COMP
DUTY CYCLE
DIVIDER
A/B = 1 = 100%
DUTY
–ACOMP
COMP
Figure 5. Functional Block Diagram
+ACOMP
The AD698 energizes the LVDT coil, senses the LVDT output
voltages and produces a dc output voltage proportional to core
position. The AD698 has a sine wave oscillator and power amplifier to drive the LVDT. Two synchronous demodulation
stages are available for decoding the primary and secondary
voltages. A decoder determines the ratio of the output signal
voltage to the input drive voltage (A/B). A filter stage and output amplifier are used to scale the resulting output.
OFF 2
FILTER
–AIN
V/I
+AIN
±1
DEMODULATOR
OFF 1
IREF
500µA
V
AD698
A
CHANNEL
AFILT1
AFILT2
–VS
C3
Figure 6. AD698 Block Diagram
The oscillator comprises a multivibrator that produces a triwave
output. The triwave drives a sine shaper that produces a low distortion sine wave. Frequency and amplitude are determined by a
single resistor and capacitor. Output frequency can range from
20 Hz to 20 kHz and amplitude from 2 V to 24 V rms. Total harmonic distortion is typically –50 dB.
Once both channels are demodulated and filtered a division circuit, implemented with a duty cycle multiplier, is used to calculate the ratio A/B. The output of the divider is a duty cycle.
When A/B is equal to 1, the duty cycle will be equal to 100%.
(This signal can be used as is if a pulse width modulated output
is required.) The duty cycle drives a circuit that modulates and
filters a reference current proportional to the duty cycle. The
output amplifier scales the 500 µA reference current converting
it to a voltage. The output transfer function is thus:
The AD698 decodes LVDTs by synchronously demodulating
the amplitude modulated input (secondaries), A, and a fixed input reference (primary or sum of secondaries or fixed input), B.
A common problem with earlier solutions was that any drift in
the amplitude of the drive oscillator corresponded directly to a
REV. B
A
B
VOUT = IREF × A/B × R2, where IREF = 500 µA
–5–
AD698
CONNECTING THE AD698
3. Select a suitable LVDT that will operate with an excitation
frequency of 2.5 kHz. The Schaevitz E100, for instance, will
operate over a range of 50 Hz to 10 kHz and is an eligible
candidate for this example.
The AD698 can easily be connected for dual or single supply
operation as shown in Figures 7, 8 and 13. The following general design procedures demonstrate how external component
values are selected and can be used for any LVDT that meets
AD698 input/output criteria. The connections for the A and B
channels and the A channel comparators will depend on which
transducer is used. In general follow the guidelines below.
4. Select excitation frequency determining component C1.
C1 = 35 µF Hz/f EXCITATION
Parameters set with external passive components include: excitation frequency and amplitude, AD698 input signal frequency,
and the scale factor (V/inch). Additionally, there are optional
features; offset null adjustment, filtering, and signal integration,
which can be implemented by adding external components.
+15V
6.8µF
–15V
100nF
100nF
6.8µF
1 –VS
AD698
+VS 24
R4
2 EXC1
OFFSET1 23
3 EXC2
OFFSET2 22
R3
+15V
6.8µF
100nF
4 LEV1
SIG REF 21
5 LEV2
SIG OUT 20
SIGNAL
REFERENCE
RL
R1
–15V
6.8µF
100nF
1 –VS
AD698
2 EXC1
+VS 24
6 FREQ1 FEEDBACK 19
R4
C4 1000pF
C1
OFFSET1 23
7 FREQ2
R3
3 EXC2
OFFSET2 22
4 LEV1
SIG REF 21
SIGNAL
REFERENCE
SIG OUT 20
6 FREQ1 FEEDBACK 19
C1
15nF
C4
7 FREQ2
OUT FILT 18
8 BFILT1
AFILT1 17
8 BFILT1
AFILT1 17
9 BFILT2
AFILT2 16
C3
VOUT
R2
33kΩ
OUT FILT 18
C2
RL
R1
5 LEV2
1000pF
10 –BIN
–ACOMP 15
11 +BIN
+ACOMP 14
12 –AIN
+AIN 13
A
9 BFILT2
AFILT2 16
10 –BIN
–ACOMP 15
11 +BIN
+ACOMP 14
12 –AIN
+AIN 13
1M
C
PHASE LAG
A
B
RT
Figure 7. Interconnection Diagram for Half-Bridge LVDT
and Dual Supply Operation
C
RS
D
D
PHASE LEAD
A
B
C
RS
B
PHASE
LAG/LEAD
NETWORK
C3
C2
VOUT
R2
C
RT
RS
C
C
PHASE LAG = Arc Tan (Hz RC);
PHASE LEAD = Arc Tan 1/(Hz RC)
WHERE R = RS// (RS + RT)
D
Figure 8. AD698 Interconnection Diagram for Series
Opposed LVDT and Dual Supply Operation
DESIGN PROCEDURE
DUAL SUPPLY OPERATION
Figure 7 shows the connection method for half-bridge LVDTs.
Figure 8 demonstrates the connections for 3- and 4-wire
LVDTs connected in the series opposed configuration. Both examples use dual ± 15 volt power supplies.
B. Determine the Oscillator Amplitude
Amplitude is set such that the primary signal is in the 1.0 V to
3.5 V rms range and the secondary signal is in the 0.25 V to
3.5 V rms range when the LVDT is at its mechanical full-scale
position. This optimizes linearity and minimizes noise susceptibility. Since the part is ratiometric, the exact value of the excitation is relatively unimportant.
A. Determine the Oscillator Frequency
Frequency is often determined by the required BW of the system. However, in some systems the frequency is set to match
the LVDT zero phase frequency as recommended by the
manufacturer; in this case skip to Step 4.
5. Determine optimum LVDT excitation voltage, VEXC. For a
4-wire LVDT determine the voltage transformation ratio,
VTR, of the LVDT at its mechanical full scale. VTR =
LVDT sensitivity × Maximum Stroke Length from null.
1. Determine the mechanical bandwidth required for LVDT
position measurement subsystem, fSUBSYSTEM. For this example, assume fSUBSYSTEM = 250 Hz.
LVDT sensitivity is listed in the LVDT manufacturer’s catalog and has units of volts output per volts input per inch displacement. The E100 has a sensitivity of 2.4 mV/V/mil. In
the event that LVDT sensitivity is not given by the manufacturer, it can be computed. See section on determining LVDT
sensitivity.
2. Select minimum LVDT excitation frequency approximately
10 × fSUBSYSTEM. Therefore, let excitation frequency = 2.5 kHz.
–6–
REV. B
AD698
Multiply the primary excitation voltage by the VTR to get
the expected secondary voltage at mechanical full scale. For
example, for an LVDT with a sensitivity of 2.4 mV/V/mil and
a full scale of ± 0.1 inch, the VTR = 0.0024 V/V/Mil × 100
mil = 0.24. Assuming the maximum excitation of 3.5 V rms,
the maximum secondary voltage will be 3.5 V rms × 0.24 =
0.84 V rms, which is in the acceptable range.
b. Full-scale core displacement from null, d
Conversely the VTR may be measured explicitly. With the
LVDT energized at its typical drive level VPRI, as indicated
by the manufacturer, set the core displacement to its mechanical full-scale position and measure the output VSEC of
the secondary. Compute the LVDT voltage transformation
ratio, VTR. VTR = VSEC//VPRI. For the E100, VSEC = 0.72 V
for VPRI = 3 V. VTR = 0.24.
VOUT is measured with respect to the signal reference,
Pin 21, shown in Figure 7.
S × d = VTR and also equals the ratio A/B at mechanical full
scale. The VTR should be converted to units of V/V.
For a full-scale displacement of d inches, voltage out of the
AD698 is computed as
VOUT = S × d × 500 µA × R2
Solving for R2,
R2 =
VOUT
S × d × 500 µA
(1)
For VOUT = ± 10 V full-scale range (20 V span) and d = ± 0.1
inch full-scale displacement (0.2 inch span)
For situations where LVDT sensitivity is low, or the mechanical FS is a small fraction of the total stroke length, an
input excitation of more than 3.5 V rms may be needed. In
this case a voltage divider network may be placed across the
LVDT primary to provide smaller voltage for the +BIN and
–BIN input. If, for example, a network was added to divide
the B Channel input by 1/2, then the VTR should also be reduced by 1/2 for the purpose of component selection.
R2 =
20V
= 83. 3 kΩ
2.4 × 0.2 × 500 µA
VOUT as a function of displacement for the above example is
shown in Figure 10.
VOUT (VOLTS)
Check the power supply voltages by verifying that the peak
values of VA and VB are at least 2.5 volts less than the voltages at +VS and –VS.
+10
+0.1d (INCHES)
–0.1
6. Referring to Figure 9, for VS = ± 15 V, select the value of the
amplitude determining component R1 as shown by the curve
in Figure 9.
–10
Figure 10. VOUT (± 10 V Full Scale) vs. Core Displacement (± 0.1 Inch)
30
E. Optional Offset of Output Voltage Swing
9. Selections of R3 and R4 permit a positive or negative output
voltage offset adjustment.
VEXC – V rms
25
20
1
1
VOS = 1.2 V × R2 ×
–
R3 + 2 kΩ R 4 + 2 kΩ
15
V rms
(2)
For no offset adjustment R3 and R4 should be open circuit.
To design a circuit producing a 0 V to +10 V output for a
displacement of +0.1 inch, set VOUT to +10 V, d = 0.2 inch
and solve Equation (1) for R2.
10
5
VOUT (VOLTS)
0
0.01
0.1
1
10
100
+5
1k
R1 – kΩ
+0.1d (INCHES)
–0.1
Figure 9. Excitation Voltage VEXC vs. R1
7. C2, C3 and C4 are a function of the desired bandwidth of
the AD698 position measurement subsystem. They should
be nominally equal values.
–5
Figure 11. VOUT (± 5 V Full Scale) vs. Core Displacement
(± 0.1 Inch)
–4
C2 = C3 = C4 = 10 Farad Hz/f5UBSYSTEM (Hz)
This will produce a response shown in Figure 11.
If the desired system bandwidth is 250 Hz, then
In Equation (2) set VOS = 5 V and solve for R3 and R4. Since a
positive offset is desired, let R4 be open circuit. Rearranging
Equation (2) and solving for R3
C2 = C3 = C4 = 10-4 Farad Hz/250 Hz = 0.4 µF
See Figures 14, 15 and 16 for more information about
AD698 bandwidth and phase characterization.
R3 = 1.2 × R2 – 2 kΩ = 7.02 kΩ
VOS
D. Set the Full-Scale Output Voltage
8. To compute R2, which sets the AD698 gain or full-scale
output range, several pieces of information are needed:
a. LVDT sensitivity, S
REV. B
–7–
AD698
11. The voltage drop across R5 must be greater than
Note that VOS should be chosen so that R3 cannot have negative
value .
1.2V
V
2 + 10 kΩ
+ 250 µA + OUT Volts
R4 + 2 kΩ
4 × R2
Figure 12 shows the desired response.
VOUT (VOLTS)
Therefore
+10
+5
–0.1
1.2V
V
+ 250 µA + OUT
2 + 10 kΩ
R4 + 2 kΩ
4
× R2 Ohms
R5 ≥
100 µA
+0.1d (INCHES)
Based upon the constraints of R5 + R6 (Step 10) and R5 (Step
11), select an interim value of R6.
Figure 12. VOUT (0 V–10 V Full Scale) vs. Displacement
(± 0.1 Inch)
12. Load current through RL returns to the junction of R5 and
R6, and flows back to VPS. Under maximum load conditions, make sure the voltage drop across R5 is met as defined in Step 11.
DESIGN PROCEDURE
SINGLE SUPPLY OPERATION
Figure 13 shows the single supply connection method.
As a final check on the power supply voltages, verify that
the peak values of VA and VB are at least 2.5 volts less than
the voltage between +VS and –VS.
+30V
Vps
0.1µF
6.8µF
R5
13. C5 is a bypass capacitor in the range of 0.1 µF to 1 µF.
C5
Gain Phase Characteristics
R6
1 –VS
AD698
To use an LVDT in a closed-loop mechanical servo application,
it is necessary to know the dynamic characteristics of the transducer and interface elements. The transducer itself is very quick
to respond once the core is moved. The dynamics arise primarily from the interface electronics. Figures 14, 15 and 16 show
the frequency response of the AD698 LVDT Signal Conditioner.
Note that Figures 15 and 16 are basically the same; the difference is frequency range covered. Figure 15 shows a wider range
of mechanical input frequencies at the expense of accuracy.
+VS 24
R4
2 EXC1
OFFSET1 23
3 EXC2
OFFSET2 22
4 LEV1
SIG REF 21
5 LEV2
SIG OUT 20
R3
SIGNAL
REFERENCE
RL
R1
VOUT
R2
6 FREQ1 FEEDBACK 19
C4 1000pF
C1
7 FREQ2
OUT FILT 18
8 BFILT1
AFILT1 17
9 BFILT2
AFILT2 16
10
C3
C2
0
10 –BIN
–ACOMP 15
11 +BIN
+ACOMP 14
–10
A
12 –AIN
–20
+AIN 13
C
GAIN – dB
PHASE
LAG/LEAD
NETWORK
1M
0.1µF
2.0µF
B
–30
0.33µF
–40
D
–50
PHASE LAG
A
B
RS
D
C
RT
RS
PHASE LAG = Arc Tan (Hz RC);
C
C
PHASE LEAD = Arc Tan 1/(Hz RC)
WHERE R = RS// (RS + RT)
0
D
0.1µF
–60
PHASE SHIFT – Degrees
RT
C
R2 = 81kΩ
fEXC = 2.5kHz
–70
C
RS
–60
PHASE LEAD
A
B
Figure 13. Interconnection Diagram for Single Supply
Operation
For single supply operation, repeat Steps 1 through 10 of the
design procedure for dual supply operation. R5, R6 and C5 are
additional component values to be determined. VOUT is measured with respect to SIGNAL REFERENCE.
–120
2.0µF
0.33µF
–180
–240
R2 = 81kΩ
fEXC = 2.5kHz
–300
–360
10. Compute a maximum value of R5 and R6 based upon the
relationship
–420
0
100
1k
FREQUENCY – Hz
10k
R5 + R6 ≤ VPS/100 µA
Figure 14. Gain and Phase Characteristics vs. Frequency
(0 kHz–10 kHz)
–8–
REV. B
AD698
10
Figure 16 shows a more limited frequency range with enhanced
accuracy. The figures are transfer functions with the input to be
considered as a sinusoidally varying mechanical position and the
output as the voltage from the AD698; the units of the transfer
function are volts per inch. The value of C2, C3, and C4, from
Figure 7, are all equal and designated as a parameter in the figures. The response is approximately that of two real poles.
However, there is appreciable excess phase at higher frequencies. An additional pole of filtering can be introduced with a
shunt capacitor across R2, Figure 7; this will also increase phase
lag.
0.033µF
0
–10
0.1µF
GAIN – dB
–20
0.01µF
–30
–40
–50
R2 = 81kΩ
fEXC = 10kHz
–60
When selecting values of C2, C3 and C4 to set the bandwidth of
the system, a trade-off is involved. There is ripple on the “dc”
position output voltage, and the magnitude is determined by the
filter capacitors. Generally, smaller capacitors will give higher
system bandwidth and larger ripple. Figures 17 and 18 show the
magnitude of ripple as a function of C2, C3 and C4, again all
equal in value. Note also a shunt capacitor across R2, Figure 7,
is shown as a parameter. The value of R2 used was 81 kΩ with a
Schaevitz E100 LVDT.
–70
0
0.033µF
PHASE SHIFT – Degrees
–60
–120
0.01µF
–180
0.1µF
–240
1k
R2 = 81kΩ
fEXC = 10kHz
–300
–360
100
0
100
1k
FREQUENCY – Hz
10k
100k
RIPPLE – mV rms
–420
Figure 15. Gain and Phase Characteristics vs. Frequency
(0 kHz–50 kHz)
10
1
10
2.5kHz, C SHUNT 1nF
0.01µF
0
2.5kHz, C SHUNT 10nF
–10
0.1
0.01
0.033µF
GAIN – dB
–20
0.1µF
–40
1k
R2 = 81kΩ
fEXC = 10kHz
–60
100
RIPPLE – mV rms
–70
0.01µF
0
PHASE SHIFT – Degrees
10
Figure 17. Output Voltage Ripple vs. Filter Capacitance
–30
–50
10
1
–60
10kHz, CSHUNT 1nF
0.1µF
–120
10kHz, CSHUNT 10nF
0.033µF
–180
0.1
0.001
R2 = 81kΩ
fEXC = 10kHz
–240
–300
–360
0.01
0.1
1
C2, C3, C4; C2 = C3 = C4 – µF
10
Figure 18. Output Voltage Ripple vs. Filter Capacitance
0
100
1k
FREQUENCY – Hz
10k
Figure 16. Gain and Phase Characteristics vs. Frequency
(0 kHz–10 kHz)
REV. B
0.1
1
C2, C3, C4; C2 = C3 = C4 – µF
–9–
AD698
– Low Cost Setpoint Controller
– Mechanical Follower Servo Loop
– Differential Gaging and Precision Differential Gaging
Determining LVDT Sensitivity
LVDT sensitivity can be determined by measuring the LVDT
secondary voltages as a function of primary drive and core position, and performing a simple computation.
AC BRIDGE SIGNAL CONDITIONER
Energize the LVDT at its recommended primary drive level,
VPRI (3 V rms for the E100). Set the core displacement to its
mechanical full-scale position and measure secondary voltages
VA and VB.
Sensitivity =
Bridge circuits which use dc excitation are often plagued by errors caused by thermocouple effects, 1/f noise, dc drifts in the
electronics, and line noise pickup. One way to get around these
problems is to excite the bridge with an ac waveform, amplify
the bridge output with an ac amplifier, and synchronously demodulate the resulting signal. The ac phase and amplitude information from the bridge is recovered as a dc signal at the
output of the synchronous demodulator. The low frequency
system noise, dc drifts, and demodulator noise all get mixed to
the carrier frequency and can be removed by means of a lowpass filter.
VSECONDARY
V PRI × d
From Figure 19,
Sensitivity =
0.72
3 V × 100 mils
= 2.4 mV /V mil
The AD698 with the addition of a simple ac gain stage can be
used to implement an ac bridge. Figure 20 shows the connections for such a system. The AD698 oscillator provides ac
excitation for the bridge. The low level bridge signal is amplified
by the gain stage created by A1, A2 to provide a differential input to the A Channel of the AD698. The signal is then synchronously detected by A Channel. The B Channel is used to detect
the level of the bridge excitation. The ratio of A/B is then calculated and converted to an output voltage by R2. An optional
phase lag/lead network can be added in front of the A comparator to adjust for phase delays through the bridge and the amplifier, or if the phase delay is small, it can be ignored or compensated
for by a gain adjustment.
VSEC WHEN VPRI 3V rms
VA
1.71V rms
0.99V rms
VB
d = –100 mils
d=0
d = +100 mils
Figure 19. LVDT Secondary Voltage vs. Core
Displacement
Thermal Shutdown and Loading Considerations
The AD698 is protected by a thermal overload circuit. If the die
temperature reaches 165°C, the sine wave excitation amplitude
gradually reduces, thereby lowering the internal power dissipation and temperature.
Due to the ratiometric operation of the decoder circuit, only
small errors result from the reduction of the excitation amplitude. Under these conditions the signal-processing section of
the AD698 continues to meet its output specifications.
The thermal load depends upon the voltage and current delivered to the load as well as the power supply potentials. An
LVDT Primary will present an inductive load to the sine wave
excitation. The phase angle between the excitation voltage and
current must also be considered, further complicating thermal
calculations.
APPLICATIONS
Most of the applications for the AD598 can also be implemented with the AD698. Please refer to the applications written
for the AD598 for a detailed explanation.
See AD598 data sheet for:
– Proving Ring-Weigh Scale
– Synchronous Operation of Multiple LVDTs
– High Resolution Position-to-Frequency Circuit
This circuit can be used for resistive bridges such as strain
gages, or for inductive or capacitive bridges that are commonly
used for pressure or flow sensors. The low level signal outputs of
these sensors are susceptible to noise and interference and are
good candidates for ac signal processing techniques.
Component Selection
Amplifiers A1, A2 will be chosen depending on the type of
bridge that is conditioned. Capacitive bridges should use an
amplifier with low bias current; a large bleeder resistor will be
required from the amplifier inputs to ground to provide a path
for the dc bias current. Resistive and inductive bridges can use a
more general purpose amplifier. The dc performance of A1, A2
are not as important as their ac performance. DC errors such as
voltage offset will be chopped out by the AD698 since they are
not synchronous to the carrier frequency.
The oscillator amplitude and span resistor for the AD698 may
be chosen by first computing the transfer function or sensitivity
of the bridge and the ac amplifier. This ratio will correspond to
the A/B term in the AD698 transfer function. For example, suppose that a resistive strain gage with a sensitivity, S, of 2 mV/V
at full scale is used. Select an arbitrary target value for A/B that
is close to its maximum value such as A/B = 0.8. Then choose a
gain for the ac amplifier so that the strain gage transfer function
from excitation to output also equals 0.8. Thus the required amplifier gain will be [A/B]/ S; or 0.8/ 0.002 V/V = 400. Then
select values for RS and RG. For the gain stage:
–10–
REV. B
AD698
Since A/B is known, the value of R2, the output FS resistor may
be chosen by the formula:
2 × RS
VOUT =
× V IN
RG + 1
VOUT = A/B × 500 µA × R2
Solving for VOUT/VIN = 400 and setting RG = 100 Ω then:
For a 10 V output at FS, with an A/B of 0.8; solve for R2.
RS = [400 – 1] × RG/2 = 19.95 kΩ
R2 = 10 V [0.8 × 500 µA] = 25.0 kΩ
Choose an oscillator amplitude that is in the range of 1 V to
3.5 V rms. For an input excitation level of 3 V rms, the output
signal from the amplifier gain stage will be 3.5 V rms × 0.8 V or
2.4 V rms, which is in the acceptable range.
This will result in a VOUT of 10 V for a full-scale signal from the
bridge. The other components, C1, C2, C3, C4 may be selected
by following the guidelines on general device operation mentioned earlier.
If a gain trim is required, then a trim resistor can be used to adjust either R2 or RG. Bridge offsets should be adjusted by a trim
network on the OFFSET 1 and OFFSET 2 pins of the AD698.
+15V
6.8µF
–15V
6.8µF
100nF
100nF
1 –VS
AD698
+VS 24
R4
2 EXC1
OFFSET1 23
3 EXC2
OFFSET2 22
4 LEV1
SIG REF 21
5 LEV2
SIG OUT 20
R3
SIGNAL
REFERENCE
RL
R1
VOUT
R2
6 FREQ1 FEEDBACK 19
RESISTORS,
INDUCTORS
OR CAPACITORS
C4 1000pF
C1
7 FREQ2
OUT FILT 18
8 BFILT1
AFILT1 17
9 BFILT2
AFILT2 16
C3
C2
A1
10 –BIN
–ACOMP 15
11 +BIN
+ACOMP 14
12 –AIN
+AIN 13
RS
RG
A
B
PHASE LAG
A
B
C
PHASE
LAG/LEAD
NETWORK
RS
RT
RS
C
A2
DUAL
OP AMP
D
PHASE LEAD
A
B
C
RS
D
C
RT
RS
C
C
D
PHASE LAG = Arc Tan (Hz RC);
PHASE LEAD = Arc Tan 1/(Hz RC)
WHERE R = RS// (RS + RT)
Figure 20. AD698 Interconnection Diagram for AC Bridge Applications
REV. B
–11–
AD698
OUTLINE DIMENSIONS
Dimensions shown in inches and (mm).
24-Pin Cerdip (Wide)
0.005 (0.13) MIN
C1827a–5–7/95
0.098 (2.49) MAX
13
24
0.610 (15.5)
0.520 (13.2)
PIN 1
1
12
1.280 (32.51) MAX
0.200
(5.08)
MAX
0.150
(3.81)
MIN
0.200 (5.08)
0.125 (3.18)
0.023 (0.58)
0.014 (0.36)
0.100
(2.54)
BSC
0.620 (15.75)
0.590 (15.00)
0.060 (1.52)
0.015 (0.38)
0.070 (1.78)
0.030 (0.76)
SEATING
PLANE
0.015 (0.38)
0.008 (0.20)
15 °
0°
28-Pin PLCC
0.048 (1.21)
0.042 (1.07)
0.048 (1.21)
0.042 (1.07)
4
0.056 (1.42)
0.042 (1.07)
0.050
(1.27)
BSC
0.025 (0.63)
0.015 (0.38)
26
PIN 1
IDENTIFIER
5
0.180 (4.57)
0.165 (4.19)
25
0.021 (0.53)
0.013 (0.33)
0.430 (10.92)
0.390 (9.91)
TOP VIEW
0.032 (0.81)
0.026 (0.66)
19
11
12
18
0.040 (1.01)
0.025 (0.64)
0.456 (11.58)
SQ
0.450 (11.43)
0.110 (2.79)
0.085 (2.16)
0.495 (12.57)
SQ
0.485 (12.32)
PRINTED IN U.S.A.
0.020
(0.50)
R
–12–
REV. B