BB ISO212JP-15

®
ISO212P
FPO
Low Cost, Two-Port Isolated, 1500Vrms
ISOLATION AMPLIFIER
FEATURES
APPLICATIONS
● 12-BIT ACCURACY
● 2.5mA (typ) QUIESCENT CURRENT
● INDUSTRIAL PROCESS CONTROL:
Transducer Channel Isolator for
Thermocouples, RTDs, Pressure
Bridges, Flow Meters
● LOW PROFILE (LESS THAN 0.5" HIGH)
● SMALL FOOTPRINT
● EXTERNAL POWER CAPABILITY
(±8V at 5mA)
● “MASTER/SLAVES” SYNCHRONIZATION
CAPABILITY
● INPUT OFFSET ADJUSTMENT
● 4mA TO 20mA LOOP ISOLATION
● MOTOR AND SCR CONTROL
● GROUND LOOP ELIMINATION
● ANALYTICAL MEASUREMENTS
● POWER PLANT MONITORING
● DATA ACQUISITION/TEST EQUIPMENT
ISOLATION
● LOW POWER (53mW)
● SINGLE 10V TO 15V SUPPLY OPERATION
● MULTIPLEXED SYSTEMS WITH CHANNEL
TO CHANNEL ISOLATION
Isolation Barrier
DESCRIPTION
The ISO212P signal isolation amplifier is a member of
a series of low-cost isolation products from BurrBrown. The low-profile SIL plastic package allows
PCB spacings of 0.5" to be achieved, and the small
footprint results in efficient use of board space.
To provide isolation, the design uses high-efficiency,
miniature toroidal transformers in both the signal and
power paths. An uncommitted input amplifier and an
isolated external bipolar supply ensure the majority of
input interfacing or conditioning needs can be met. The
ISO212P accepts an input voltage range of ±5V for
single 15V supply operation or ±3.0V for single 10V
supply operation.
Offset
Adjust
Offset
Adjust
–I/P
+I/P
fB
+VSS 1 Out
Com 1
–VSS 1 Out
8
7
3
38
1
37
O/P High
O/P Low
4
6
2
DC/DC
Converter
31
32
5
34
35
+VCC
Com 2
Clock Out
Clock In
International Airport Industrial Park • Mailing Address: PO Box 11400, Tucson, AZ 85734 • Street Address: 6730 S. Tucson Blvd., Tucson, AZ 85706 • Tel: (520) 746-1111 • Twx: 910-952-1111
Internet: http://www.burr-brown.com/ • FAXLine: (800) 548-6133 (US/Canada Only) • Cable: BBRCORP • Telex: 066-6491 • FAX: (520) 889-1510 • Immediate Product Info: (800) 548-6132
©
1988 Burr-Brown Corporation
PDS-881G
Printed in U.S.A. December, 1995
SPECIFICATIONS
ELECTRICAL
At TA = +25°C and V CC = +15V, unless otherwise noted.
ISO212JP
PARAMETER
CONDITIONS
ISOLATION
Voltage
Rated Continuous
AC, 50Hz
DC
100% Test (AC, 50Hz)
Isolation-Mode
Rejection(1)
AC
DC
Barrier Resistance
Barrier Capacitance
Leakage Current(8)
GAIN
Initial Error
Gain vs Temperature
Nonlinearity(3): KP
JP-15
INPUT OFFSET VOLTAGE
Offset Voltage RTI: KP
JP-15
vs Temperature
vs Power Supply(4)
Adjustment Range
Partial Discharge
1s : <5pC
VISO = Rated
Continuous 60Hz
MIN
TYP
ISO212KP, JP-15
MAX
MIN
TYP
1500
2120
Vrms
VDC
1200
2400
Vrms
115
160
1010
12
1
±1
20
0.04
VO = –5V to +5V
✻(9)
✻
✻
✻
✻
2
1.6
±2
50
0.05
✻
✻
0.015
0.04
±10 ±10/G
±20
30 ±30/G
±1.5
±5
Ripple Voltage(6)
Ouput Compliance
FREQUENCY RESPONSE
Small Signal Bandwidth
Full Signal Bandwidth
ISOLATED POWER OUTPUTS
Voltage Outputs (±VSS 1)(7)
vs Temperature
vs Load
Current Output (7)
(Both Loaded)
(One Loaded)
POWER SUPPLIES
Rated Voltage
Voltage Range(5)
Quiescent Current
TEMPERATURE RANGE
Specification
Operating
No Load
mV
mV
µV/°C
mV/V
mV
✻
✻
nA
nA
V
Ω
✻
kΩ
V
8
0.4
7.5
✻
✻
mVp-p
mVrms
V
1
✻
kHz
200
✻
Hz
±5
I/P = 1Vp-p, –3dB
G=1
I/P = 10Vp-p,
G=1
G = 10 (–3dB)
±7.5 ±7.5/G
±10 ±10/G
✻
3
Out Hi to Out Lo
Min Load = 1MΩ
f = 0 to 100kHz
f = 0 to 5kHz
Out Hi or Out Lo
% FSR(2)
ppm of FSR/°C
%FSR
%FSR
✻
1012
OUTPUT
Output Impedance
Voltage Range
✻
✻
0.025
0.05
✻
✻
50
4
G=1
✻
✻
dB
dB
Ω
pF
µArms
µArms
✻
INPUT CURRENT
Bias
Offset
INPUT
Voltage Range(5)
Resistance
UNITS
750
1060
VISO = 240Vrms, 60Hz
VISO = 240Vrms, 50Hz
VCC = 14V to 16V
MAX
✻
1.8
±7.5
kHz
±8
–8
90
✻
✻
✻
✻
5
8
Rated Performance
15
11.4 to 16
2.5
No Load
0
–25
VDC
mV/°C
mV/mA
✻
✻
mA
mA
✻
✻
V
V
mA
✻
✻
°C
°C
✻
✻
✻
3.5
+70
+85
✻
✻
NOTES: (1) Isolation-mode rejection is the ratio of the change in output voltage to a change in isolation barrier voltage. It is a function of frequency. (2) FSR = Full
Scale Range = 10V. (3) Nonlinearity is the peak deviation of the output voltage from the best-fit straight line. It is expressed as the ratio of deviation to FSR. (4) Power
Supply Rejection is the change in VOS/Supply Change. (5) At VCC = +10.0V, input voltage range = ±3.0V min. (6) Ripple is the residual component of the barrier carrier
frequency generated internally. (7) Derated at VCC < +15V. (8) Tested at 2400Vrms, 50Hz limit 16µA. (9) Asterisk (✻) same as ISO212JP.
®
ISO212P
2
PIN CONFIGURATION
ABSOLUTE MAXIMUM RATINGS
Bottom View
Supply Voltage Without Damage ......................................................... 18V
Continuous Isolation Voltage Across Barrier: JP ......................... 750Vrms
KP, JP-15 ........... 1500Vrms
Storage Temperature Range ............................................ –25°C to 100°C
Lead Temperature (soldering, 10s) ................................................ +300°C
Amplifier Output Short-Circuit Duration ................ Continuous to Common
Output Voltage Hi or Lo to Com 2 .................................................. ±VCC /2
1 +I/P
Com 1 2
3 –I/P
fB 4
5 –VSS 1
+VSS1 6
7 Offset Adjust
Offset Adjust 8
PACKAGE/ORDERING INFORMATION
PRODUCT
ISO212JP
ISO212JP-15
ISO212KP
31 +VCC
TEMPERATURE
RANGE
38-Pin Plastic SIP
38-Pin Plastic SIP
38-Pin Plastic SIP
326
326
326
–25°C to +85°C
–25°C to +85°C
–25°C to +85°C
NOTE: (1) For detailed drawing and dimension table, please see end of data
sheet, or Appendix C of Burr-Brown IC Data Book.
Com 2 32
Clock Out 34
PACKAGE
PACKAGE
DRAWING
NUMBER(1)
35 Clock In
ELECTROSTATIC
DISCHARGE SENSITIVITY
37 O/P Low
O/P High 38
This integrated circuit can be damaged by ESD. Burr-Brown
recommends that all integrated circuits be handled with
appropriate precautions. Failure to observe proper handling
and installation procedures can cause damage.
ESD damage can range from subtle performance degradation
to complete device failure. Precision integrated circuits may
be more susceptible to damage because very small parametric
changes could cause the device not to meet its published
specifications.
TYPICAL PERFORMANCE CURVES
At TA = +25°C, VS = ±15V, unless otherwise noted.
SINE RESPONSE (f = 200Hz)
VOLTAGE OUT vs SUPPLY VOLTAGE +VCC
7
+5
Output Voltage (V)
Voltage Out (V)
6
5
4
VOUT
+VOUT
Ideal
+VOUT
3
VIN
–VOUT
(Absolute)
2
–VOUT
1
±VOUT
0
5
Ideal
VIN = ±5V, G = 1
VIN
0
17 16 15 14 13 12
11 10
9
8
7
6
5
0
4
5
10
Time (ms)
Supply Voltage VCC (V)
The information provided herein is believed to be reliable; however, BURR-BROWN assumes no responsibility for inaccuracies or omissions. BURR-BROWN assumes
no responsibility for the use of this information, and all use of such information shall be entirely at the user’s own risk. Prices and specifications are subject to change
without notice. No patent rights or licenses to any of the circuits described herein are implied or granted to any third party. BURR-BROWN does not authorize or warrant
any BURR-BROWN product for use in life support devices and/or systems.
®
3
ISO212P
TYPICAL PERFORMANCE CURVES (CONT)
At TA = +25°C and VS = ±15V, unless otherwise noted.
SINE RESPONSE (f = 2kHz)
STEP RESPONSE (f = 200Hz)
+5
Output Voltage (V)
Output Voltage (mV)
+500
0
–500
0
–5
VIN = ±0.5V, G = 1
V IN = ±5V, G = 1
0
500
0
1000
5
10
Time (ms)
Time (µs)
STEP RESPONSE (f = 2kHz)
IMR vs FREQUENCY
85
80
+500
Output Voltage (mV)
75
IMR (dB)
70
0
65
60
55
50
–500
45
V IN = ±0.5V, G = 1
40
0
500
1000
1k
10k
100k
Time (µs)
1M
10M
100M
Frequency (Hz)
GAIN ERROR vs CLOCK-IN RATE
LINEARITY vs CLOCK-IN RATE
100
0
90
–0.5
Gain Error (% FSR)
Linearity Error (m%)
80
70
60
50
40
30
20
–1
–1.5
–2
10
0
–2.5
30
40
50
60
70
80
90
30
100
®
ISO212P
40
50
60
70
Clock-In Rate (kHz)
Clock-In Rate (kHz)
4
80
90
100
inverting configurations, a separate resistor is required.
Neglecting this point may also lead to problems when
powering on the ISO212P.
DISCUSSION
OF SPECIFICATIONS
The ISO212P is intended for applications where isolation
and input signal conditioning are required. Best signal-tonoise performance is obtained when the input amplifier gain
setting is such that VOUT has a full scale range of ±5V. The
bandwidth is typically 1kHz, making the device ideal for use
in conjunction with sensors that monitor slowly varying
processes. To power external functions or networks, 5mA at
±8V typical is available at the isolated port.
USING ±VSS1 TO POWER EXTERNAL CIRCUITRY
The DC/DC converter in the ISO212P runs at a switching
frequency of 25kHz. Internal rectification and filtering is
sufficient for most applications at low frequencies or with no
external networks connected.
The ripple on ±VSS1 will typically be 100mVp-p at 25kHz.
Loading the supplies will increase the ripple unless extra
filtering is added externally; a capacitor of 1µF is normally
sufficient for most applications, although in some cases
10µF may be required. Noise introduced onto ±VSS1 should
be decoupled to prevent degraded performance.
LINEARITY PERFORMANCE
The ISO212P offers linearity performance compatible with
12-bit resolution systems (0.025%). Note that the specification is based on a best-fit straight line.
THEORY OF OPERATION
OPTIONAL OFFSET VOLTAGE ADJUSTMENT
In many applications, the untrimmed input offset voltage
will be adequate. For situations where it is necessary to trim
the offset, a potentiometer can be used. See Figure 1 for
details. It is important to keep the traces to the offset adjust
pins as short as practical, because noise can be injected into
the input op amp via this route.
The ISO212P has no galvanic connection between the input
and output. The analog input signal referenced to the input
common (Com 1) is multiplied by the gain of the input
amplifier and accurately reproduced at the output. The
output section uses a differential design so either the HI or
LO pin may be referenced to the output common (Com 2).
This allows simple input signal inversion while maintaining
the high impedance input configuration. A simplified diagram of the ISO212P is shown in Figure 2. The design
consists of a DC/DC converter, an uncommitted input operational amplifier, a modulator circuit and a demodulator
circuit. Magnetic isolation is provided by separate transformers in the power and signal paths.
INPUT PROTECTION
If the ISO212P is used in systems where a transducer or
sensor does not derive its power from the isolated power
available from the device, then some input protection must
be present to prevent damage to the input op amp when the
ISO212P is not powered. A resistor of 5kΩ should be
included to limit the output impedance of the signal source.
Where the op amp is configured for an inverting gain, then
RIN of the gain setting network can be used. For non-
The DC/DC converter provides power and synchronization
signals across the isolation barrier to operate the operational
amplifier and modulator circuitry. It also has sufficient
capacity to power external input signal conditioning net-
Isolation
Barrier
3
–I/P
5kΩ
1
+I/P
2
Com 1
4
35
fB
34
Clock Clock
In
Out
O/P High 38
VIN
O/P Low 37
VOUT
Com 2 32
+V SS 1 –V SS 1 Offset
Out
Adjust
Out
+V
CC
6
(2)
10µF
+
0.1µF
(1)
(2)
+
31
5 7 100kΩ 8
10µF Tantalum
+
10µF
100µH
Input Ground Plane
Output Ground Plane
NOTES: (1) Optional voltage offset adjust components. (2) 10µF decoupling to be used with external
loads connected.
FIGURE 1. Power Supply and Signal Connections Shown for Non-Inverting, Unity Gain Configuration.
®
5
ISO212P
works. The uncommitted operational amplifier may be configured for signal buffering or amplification, depending on
the application.
Recent improvements in high voltage stress testing have
produced a more meaningful test for determining maximum
permissible voltage ratings, and Burr-Brown has chosen to
apply this new technology in the manufacture and testing of
the ISO212P.
The modulator converts the input signal to an amplitudemodulated AC signal that is magnetically coupled to the
demodulator by a miniature transformer providing the signal-path isolation. The demodulator recovers the input signal from the modulated signal using a synchronous technique to minimize noise and interference.
PARTIAL DISCHARGE
When an insulation defect such as a void occurs within an
insulation system, the defect will display localized corona or
ionization during exposure to high voltage stress. This ionization requires a higher applied voltage to start the discharge
and a lower voltage to extinguish it once started. The higher
start voltage is known as the inception voltage and the lower
voltage is called the extinction voltage. Just as the total
insulation system has an inception voltage, so do the individual voids. A voltage will build up across a void until its
inception voltage is reached. At this point, the void will
ionize, effectively shorting itself out. This action redistributes electrical charge within the dielectric and is known as
partial discharge. If the applied voltage gradient across the
device continues to rise, another partial discharge cycle
begins. The importance of this phenomenon is that if the
discharge does not occur, the insulation system retains its
integrity. If the discharge begins and is allowed to continue,
the action of the ions and electrons within the defect will
eventually degrade any organic insulation system in which
they occur. The measurement of partial discharge is both
useful in rating the devices and in providing quality control
of the manufacturing process. The inception voltage of these
voids tends to be constant, so that the measurement of total
charge being re-distributed within the dielectric is a very
good indicator of the size of the voids and their likelihood of
becoming an incipient failure.
ABOUT THE BARRIER
For any isolation product, barrier integrity is of paramount
importance in achieving high reliability. The ISO212P uses
miniature toroidal transformers designed to give maximum
isolation performance when encapsulated with a high-dielectric-strength material. The internal component layout is
designed so that circuitry associated with each side of the
barrier is positioned at opposite ends of the package. Areas
where high electric fields can exist are positioned in the
center of the package. The result is that the dielectric
strength of the barrier typically exceeds 3kVrms.
ISOLATION VOLTAGE RATINGS
Because a long term test is impractical in a manufacturing
situation, the generally accepted practice is to perform a
production test at a high voltage for some shorter time. The
relationship between actual test voltage and the continuous
derated maximum specification is an important one. Historically, Burr-Brown has chosen a deliberately conservative
one: VTEST = (2 x ACrms continuous rating) + 1000V for ten
seconds, followed by a test at rated ACrms voltage for one
minute. This choice was appropriate for conditions where
system transients were not well defined.
fB
4
Off Adjust
7
–I/P
3
Signal
–
38
Modulator
+I/P
Off Adjust
1
+
37
8
31
+8V
+VSS 1 O/P
–VSS 1 O/P
6
Oscillator
–8V
25kHz
Rectifier
2
FIGURE 2. Simplified Diagram of Isolation Amplifier.
®
ISO212P
35
32
5
0.47µF
Com 1
50kHz
Power
34
0.47µF
O/P High
Demodulator
6
O/P Low
+VCC
Clock Out
Clock In
Com 2
The bulk inception voltage, on the other hand, varies with
the insulation system and the number of ionization defects.
This directly establishes the absolute maximum voltage
(transient) that can be applied across the test device before
destructive partial discharge can begin.
the barrier will increase AC leakage and, in conjunction with
ground line resistance, may degrade high frequency IMR.
VOLTAGE GAIN MODIFICATIONS
The uncommitted operational amplifier at the input can be
used to provide gain, signal inversion, active filtering or
current to voltage conversion. The standard design approach
for any op-amp stage can be used, provided that the full scale
voltage appearing on fB does not exceed ±5V.
Measuring the bulk extinction voltage provides a lower,
more conservative, voltage from which to derive a safe
continuous rating. In production, it’s acceptable to measure
at a level somewhat below the expected inception voltage
and then de-rate by a factor related to expectations about the
system transients. The isolation amplifier has been extensively evaluated under a combination of high temperatures
and high voltage to confirm its performance in this respect.
The ISO212P is free of partial discharges at rated voltages.
If the input op-amp is overdriven, ripple at the output will
result. To prevent this, the feedback resistor should have a
minimum value of 10kΩ.
Also, it should be noted that the current required to drive the
equivalent impedance of the feedback network is supplied
by the internal DC/DC converter and must be taken into
account when calculating the loading added to ±VSS1.
PARTIAL DISCHARGE TESTING IN PRODUCTION
Not only does this test method provide far more qualitative
information about stress withstand levels than did previous
stress tests, but it also provides quantitative measurements
from which quality assurance and control measures can be
based. Tests similar to this test have been used by some
manufacturers such as those of high voltage power distribution equipment for some time, but they employed a simple
measurement of RF noise to detect ionization. This method
was not quantitative with regard to energy of the discharge
and was not sensitive enough for small components such as
isolation amplifiers. Now, however, manufacturers of HV
test equipment have developed means to measure partial
discharge, and VDE, the German standards group, has adopted
use of this method for the testing of opto-couplers. To
accommodate poorly defined transients, the part under test is
exposed to a voltage that is 1.6 times the continuous rated
voltage and must display < 5pC partial discharge level in a
100% production test.
Since gain inversion can be incorporated in either the input
or output stage of the ISO212P, it is possible to use the input
amplifier in a non-inverting configuration and preserve the
high impedance this configuration offers. Signal inversion at
the output is easily accomplished by connecting O/P High to
Com 2 instead of O/P Low.
ISOLATED POWER OUTPUT DRIVE CAPABILITY
On the input side of the ISO212P, there are two power
supplies capable of delivering 5mA at ±8V to power external circuitry. When using these supplies with external loads,
it is recommended that additional decoupling in the form of
10µF tantalum bead capacitors be added to improve the
voltage regulation. Loss of linearity will result if additional
filtering is not used with an output load. Again, power
dissipated in the feedback loop around the input op amp
must be subtracted from the available power output at ±VSS1.
If the ISO212P is to be used in multiple applications, care
should be taken in the design of the power distribution
INSTALLATION AND
OPERATING INSTRUCTIONS
POWER SUPPLY AND SIGNAL CONNECTIONS
As with any mixed analog and digital signal component,
correct decoupling and signal routing precautions must be
used to optimize performance. Figure 1 shows the proper
power supply and signal connections. VCC should be bypassed to Com 2 with a 0.1µF ceramic capacitor as close to
the device as possible. Short leads will minimize lead
inductance. A ground plane will also reduce noise problems.
If a low impedance ground plane is not used, signal common
lines, and either O/P High or O/P Low pin should be tied
directly to the ground at the supply and Com 2 returned via
a separate trace to the supply ground.
CEXT 1 has minimal effect on total IMR.
fB
CEXT 2 and R have a direct effect.
–
O/P High
CINT
R
Load
Circuit
+
O/P Low
CEXT 2
Com 2
–VCC
+VCC
CEXT 1
To avoid gain and isolation mode (IMR) errors introduced
by the external circuit, connect grounds as indicated in
Figure 3. Layout practices associated with isolation amplifiers are very important. In particular, the capacitance associated with the barrier, and series resistance in the signal and
reference leads, must be minimized. Any capacitance across
Power
Supply
Com 1
Input
Common
VISO
FIGURE 3. Technique for Connecting Com 1 and Com 2.
®
7
ISO212P
external driver connected to Clk In. See Figure 5. The driver
may be an external component with Series 4000 CMOS
characteristics, or one of the ISO212Ps in the system can be
used as the master clock for the system. See Figure 6 and 7
for connections in multiple ISO212P installations.
network, especially when all ISO212Ps are synchronized. It
is best to use a well decoupled distribution point and to take
power to individual ISO212Ps from this point in a star
arrangement as shown in Figure 4.
NOISE
Output noise is generated by residual components of the
25kHz carrier that have not been removed from the signal.
This noise may be reduced by adding an output low pass
filter (see Figure 8). The filter time constants should be set
below the carrier frequency. The output from the ISO212P
is a switched capacitor and requires a high impedance load
to prevent degradation of linearity. Loads of less than 1MΩ
will cause an increase in noise at the carrier frequency and
will appear as ripple in the output waveform. Since the
output signal power is generated from the input side of the
barrier, decoupling of the ±VSS 1 outputs will improve the
signal to noise ratio.
CHARGE ISOLATION
When more than one ISO212P is used in synchronous mode,
the charge which is returned from the timing capacitor
(220pF in Figure 5) on each transition of the clock becomes
significant. Figure 7 illustrates a method of isolating the
“Clk Out” clamp diodes (Figure 5) from this charge.
A 22kΩ resistor (recommended maximum to use) together
with the 39kΩ internal oscillator timing resistor (Figure 5)
forms a potential divider. The ratio of these resistors should
be greater than 0.6 which ensures that the input voltage
triggers the inverter connected to “Clk In”. If using a single
resistor, then account must be taken of the paralleled timing
resistors. This means that the 22kΩ resistor must be halved
to drive two ISO212Ps, or divided by 8 if driving 8 ISO212Ps
to insure that the ratio of greater than 0.6 is maintained. The
series resistors shown in Figure 7 reduce the high frequency
content of the power supply current.
SYNCHRONIZATION
OF THE INTERNAL OSCILLATOR
The ISO212P has an internal oscillator and associated timing components, which can be synchronized, incorporated
into the design. This alleviates the requirement for an external high-power clock driver. The typical frequency of oscillation is 50kHz. The internal clock will start when power is
applied to the ISO212P and Clk In is not connected.
APPLICATIONS
The ISO212P isolation amplifier, together with a few low
cost components, can isolate and accurately convert a 4-to20mA input to a ±10V output with no external adjustment.
Its low height (0.43" (11mm) ) and small footprint (2.5" x
0.33" (57mm x 8mm) ) make it the solution of choice in 0.5"
board spacing systems and in all applications where board
area savings are critical.
Because the frequencies of several ISO212Ps can be marginally different, “beat” frequencies ranging from a few Hz to
a few kHz can exist in multiple amplifier applications. The
design of the ISO212P accommodates “internal synchronous” noise, but a synchronous beat frequency noise will not
be strongly attenuated, especially at very low frequencies if
it is introduced via the power, signal, or potential grounding
paths. To overcome this problem in systems where several
ISO212Ps are used, the design allows synchronization of
each oscillator in a system to one frequency. Do this by
forcing the timing node on the internal oscillator with an
Power In
The ISO212P operates from a single +15V supply and offers
low power consumption and 12-bit accuracy. On the input
side, two isolated power supplies capable of supplying 5mA
at ±8V are available to power external circuitry.
+VCC
Track Resistance/Inductance
100µF
10µF
0.1µF
0.1µF
10µF
0.1µF
39kΩ
ISO212P
ISO212P
ISO212P
Clock
In
10µF
Clock
Out
0.1µF
220pF
Clamp
Diodes
Ground Plane
Com 2
FIGURE 4. Recommended Decoupling and Power Distribution.
FIGURE 5. Equivalent Circuit, Clock Input/Output. Inverters are CMOS.
®
ISO212P
8
APPLICATIONS FLEXIBILITY
In Figure 8, the ISO212P’s +Vss 1 isolated supply powers a
REF200 to provide an accurate 100µA current source. This
current is opposed by an equal but opposite current through
the 75kΩ feedback resistor to establish an offset of –7.5V at
Iin = 0mA. With Iin = 4-to-20mA, the output is –5 to +5V.
The ratio of the 75kΩ and 3.12kΩ resistors assures the
correct gain.
ISO212P/Master
+V CC
Clk Out
Clk In
Com 2
ISO212P/Slave
+V CC
Clk Out
Clk In
Com 2
The polarity of the output can be reversed by simply reversing the O/P HI and O/P LO pins. This could be used in the
Figure 8 circuit to change the –5V to +5V output to a +5V
to –5V output range.
ISO212P/Slave
+V CC
Clk Out
Clk In
Com 2
The primary function of the output circuitry is to add gain to
produce a ±10V output and to reduce output impedance. The
addition of a few resistors and capacitors provides a low pass
filter with a cut-off frequency equal to the full signal
bandwidth of the ISO212P, typically 200Hz. The filter
response is flat to 1dB and rolls off from cut off at –12dB per
octave.
0V +15V Sync
FIGURE 6. Oscillator Connections for Synchronous Operation in Multiple ISO212P Installations.
Clk In
Clk In
Clk In
The accuracy of the REF200 and external resistors eliminates the need for expensive trim pots and adjustments. The
errors introduced by the external circuitry only add about
10% of the ISO212P’s specified gain and offset voltage
error.
22k Ω
Slave
Clk In
Slave
22k Ω
Slave
22k Ω
Slave
22k Ω
Slave
Master
Clk Out
22k Ω
RS
Clk In
Slave 4
Slave N
Clk In
Slave 3
Clk In
Slave 2
Clk In
Slave 1
Master
Clk Out
FIGURE 7. Isolating the Clk Out Node.
+VSS 1
+15V
6.8nF (10%)
10µF
0.1µF
2
1
4-20mA
25Ω
+15V
6
+
37 (O/P Low)
+VSS 1
38 (O/P High)
8
3
REF
200
100µA
0.1µF
31
100kΩ
32
–
(5%)
4
ISO212P
1
75kΩ
0.02µF
100kΩ
4mA to 20mA
–5V to +5V
(5%)
3
4mA to 20mA
–10V to +10V
+
OPA27
2 –
6.8nF
(10%)
6
0.1µF
NOTE: All resistors are 0.1%
unless otherwise stated.
–15V
3.12kΩ
22kΩ
22kΩ
FIGURE 8. Isolated 4-20mA Current Receiver with Output Filter.
®
9
ISO212P
+15V
+VISO
REF03
0.1µF
+2.5V
3
–
31
1kΩ
1kΩ
1
OPA1013
+VISO
1kΩ
38
VOUT
ISO212P
99kΩ
1kΩ(1)
37
32
+
5
4
6
2
OPA1013
–2.5V
10µF
100Ω
10µF
–VISO
+VISO –VISO
NOTE: (1) e.g., strain gauge, pressure transducer, RTD, gas detection and analysis.
FIGURE 9. Instrument Bridge Isolation Amplifier.
100kΩ
+15V
4
0.1µF
100kΩ
3
0.1µF
–
31
38
ISO212P
250kΩ
1
VOUT
37
32
+
+VISO
5
Siemens BPW21
6
2
OPA128J
10µF
10µF
–VISO
+VISO –VISO
FIGURE 10. Photodiode Isolation Amplifier.
+15V
–VISO
+VISO
8kΩ
OPA177
4kΩ
1
1MΩ
ISO212JP
–VISO
100Ω
VOUT
4
T.C.
99kΩ
1kΩ
3
–VISO
FIGURE 11. Thermocouple Amplifier with Ground Loop Elimination, Cold Junction Compensation and Down-Scale Burn-Out.
®
ISO212P
10
100kΩ
+500VDC
ISO212P
4
1kΩ
3
–
VD
+15V
1
V D = 50mV (FS)
+
0.1µF
2
DC
Motor
6.8nF
31
+15V
37
100kΩ
38
100kΩ
32
3
2
6.8nF
6
OPA27
–10V
to
+10V
or
90kΩ
120Vrms
100A
–15V
22kΩ
4
3
3-Phase Y-Connected
Power Transformer
22kΩ
–
10kΩ
200kΩ
1
+
2
4.7V
0.1µF
4.7V
200kΩ
FIGURE 12. Isolated Current Monitoring Applications.
+VSS1
8
7.87k Ω
100µA
+15V
7
4
0.1µF
4
3 REF200
5
1
6
2
3
–
31
150Ω
38
ISO212P
200µA
–VSS1
1
37
1 to 5V
32
+
5
6
PT100
–200°C to 850°C
2
10µF
10µF
+VSS1–VSS1
FIGURE 13. Isolated Temperature Sensing and Amplification.
®
11
ISO212P