ISO121G - Texas Instruments - Datasheet.Company

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ISOLATION AMPLIFIER

ISO120

ISO121

Signal

Com 2

–V

Gnd 2

Ext Osc

Gnd 1

–V

Signal

Com 1

OUT

Sense

Isolation Barrier

DESCRIPTION

The ISO120 and ISO121 are precision isolation ampli-

fiers incorporating a novel duty cycle modulation-

demodulation technique. The signal is transmitted

digitally across a 2pF differential capacitive barrier.

With digital modulation the barrier characteristics do

not affect signal integrity, which results in excellent

reliability and good high frequency transient immu-

nity across the barrier. Both the amplifier and barrier

capacitors are housed in a hermetic DIP. The ISO120

and ISO121 differ only in package size and isolation

voltage rating.

These amplifiers are easy to use. No external compo-

nents are required for 60kHz bandwidth. With the

addition of two external capacitors, precision specifi-

cations of 0.01% max nonlinearity and 150µV/°C max

VOS drift are guaranteed with 6kHz bandwidth. A

power supply range of ±4.5V to ±18V and low quies-

cent current make these amplifiers ideal for a wide

range of applications.

FEATURES

●100% TESTED FOR PARTIAL DISCHARGE

●ISO120: Rated 1500Vrms

●ISO121: Rated 3500Vrms

●HIGH IMR: 115dB at 60Hz

●USER CONTROL OF CARRIER

FREQUENCY

●LOW NONLINEARITY: ±0.01% max

●BIPOLAR OPERATION: VO = ±10V

●0.3"-WIDE 24-PIN HERMETIC DIP, ISO120

●SYNCHRONIZATION CAPABILITY

●WIDE TEMP RANGE: –55°C to +125°C

(ISO120)

APPLICATIONS

●INDUSTRIAL PROCESS CONTROL: Trans-

ducer Isolator for Thermocouples, RTDs,

Pressure Bridges, and Flow Meters, 4mA

to 20mA Loop Isolation

●GROUND LOOP ELIMINATION

●MOTOR AND SCR CONTROL

●POWER MONITORING

●ANALYTICAL MEASUREMENTS

●BIOMEDICAL MEASUREMENTS

●DATA ACQUISITION

●TEST EQUIPMENT

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 • Cable: BBRCORP • Telex: 066-6491 • FAX: (520) 889-1510 • Immediate Product Info: (800) 548-6132

SBOS158

2ISO120/121

SPECIFICATIONS

ELECTRICAL

At TA = +25°C: VS1 = VS2 = ±15V: and RL = 2kΩ, unless otherwise noted.

*Specifications same as ISO120BG, ISO121BG.

NOTE: (1) Input voltage range = ±10V for VS1, VS2 = ±4.5VDC to ±18VDC. (2) Ripple frequency is at carrier frequency. (3) Overload recovery is approximately three times

the settling time for other values of C2. (4) The SG-grade is specified –55°C to +125°C; performance of the SG in the –25°C to +85°C temperature range is the same

as the BG-grade.

ISO120BG, ISO121BG ISO120G, ISO120SG(4), ISO121G

PARAMETER CONDITIONS MIN TYP MAX MIN TYP MAX UNITS

ISOLATION

Voltage Rated Continuous ISO120: AC 60Hz TMIN to TMAX 1500 * Vrms

DC TMIN to TMAX 2121 * VDC

ISO121: AC 60Hz TMIN to TMAX 3500 * Vrms

DC TMIN to TMAX 4950 * VDC

100% Test (AC 60Hz): ISO120 1s; Partial Discharge ≤ 5pC 2500 * Vrms

ISO121 1s; Partial Discharge ≤ 5pC 5600 * Vrms

Isolation Mode Rejection ISO 120: AC 60Hz 1500Vrms 115 * dB

DC 160 * dB

ISO121: AC60Hz 3500Vrms 115 * dB

DC 160 * dB

Barrier Impedance 1014 || 2 * Ω || pF

Leakage Current VISO = 240Vrms, 60Hz 0.18 0.5 * * µArms

GAIN(4) VO = ±10V

Nominal Gain C1 = C2 = 1000pF 1 1 V/V

Gain Error ±0.04 ±0.1 ±0.05 ±0.25 %FSR

Gain vs Temperature ±5±20 ±10 ±40 ppm/°C

Nonlinearity ±0.005 ±0.01 ±0.01 ±0.05 %FSR

Nominal Gain C1 = C2 = 0 1 1 V/V

Gain Error ±0.04 ±0.25 ±0.05 ±0.25 %FSR

Gain vs Temperature ±40 ±40 ppm/°C

Nonlinearity ±0.02 ±0.1 ±0.04 ±0.1 %FSR

INPUT OFFSET VOLTAGE(4)

Initial Offset C1 = C2 = 1000pF ±5±25 ±10 ±50 mV

vs Temperature ±100 ±150 ±150 ±400 µV/°C

Initial Offset C1 = C2 = 0 ±25 ±100 ±40 ±100 mV

vs Temperature ±250 ±500 µV/°C

Initial Offset

vs Supply ±VS1 or ±VS2 = ±4.5V to ±18V ±2±2 mV/V

Noise 44µV/√Hz

INPUT

Voltage Range(1) ±10 ±15 * * V

Resistance 200 * kΩ

OUTPUT

Voltage Range ±10 ±12.5 * * V

Current Drive ±5±15 * * mA

Capacitive Load Drive 0.1 * µF

Ripple Voltage(2) 10 * mVp-p

FREQUENCY RESPONSE

Small Signal Bandwith C1 = C2 = 0 60 * kHz

C1 = C2 = 1000pF 6 * kHz

Slew Rate 2*V/µs

Settling Time VO = ±10V

0.1% C2 = 100pF 50 * µs

0.01% C1 = C2 = 1000pF 350 * µs

Overload Recovery Time(3) 50% Output Overload, 150 * µs

C1 = C2 = 0

POWER SUPPLIES

Rated Voltage 15 * V

Voltage Range ±4.5 ±18 * * V

Quiescent Current: VS1 ±4.0 ±5.5 * * mA

VS2 ±5.0 ±6.5 * * mA

TEMPERATURE RANGE

Specification: BG and G –25 85 –25 85 °C

SG(4) –25 85 –55 125 °C

Operating –55 125 –55 125 °C

Storage –65 150 –55 150 °C

JA: ISO120 40 40 °C/W

ISO121 25 25 °C/W

3ISO120/121

PACKAGE DRAWING

MODEL PACKAGE NUMBER

ISO120G 24-Pin DIP 225

ISO120BG 24-Pin DIP 225

ISO120SG 24-Pin DIP 225

ISO121G 40-Pin DIP 206

ISO121BG 40-Pin DIP 206

NOTE: (1) For detailed drawing and dimension table, please see end of data

sheet, or Appendix D of Burr-Brown IC Data Book.

ABSOLUTE MAXIMUM RATINGS CONNECTION DIAGRAM

Supply Voltage (any supply) ...............................................................18V

VIN, Sense Voltage .......................................................................... ±100V

External Oscillator Input ....................................................................±25V

Signal Common 1 to Ground 1 ........................................................... ±1V

Signal Common 2 to Ground 2 ........................................................... ±1V

Continuous Isolation Voltage: ISO120 ......................................1500Vrms

ISO121.......................................3500Vrms

VISO, dv/dt ...................................................................................... 20kV/µs

Junction Temperature...................................................................... 150°C

Storage Temperature..................................................... –65°C to +150°C

Lead Temperature (soldering, 10s)............................................... +300°C

Output Short Duration ......................................... Continuous to Common

PACKAGE INFORMATION(1)

1/1 

2/2

3/3

4/4



9/17

10/18

11/19

12/20

(1)

C 

+V 

–V 



Com 2

V 

Sense

Gnd 2

1H

1L

S1



OUT

24/40

23/39

22/38

21/37



16/24

15/23

14/22

13/21

Gnd 1

V

Ext Osc

Com 1



–V

+V

C

IN



S2

2L

NOTE: (1) First pin number is for ISO120.

Second pin number is for ISO121.

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.

Electrostatic discharge can cause damage ranging from per-

formance degradation to complete device failure. Burr-Brown

Corporation recommends that all integrated circuits be handled

and stored using appropriate ESD protection methods.

ELECTROSTATIC

DISCHARGE SENSITIVITY

ORDERING INFORMATION

TEMPERATURE

MODEL RANGE

ISO120G –25°C to 85°C

ISO120BG –25°C to 85°C

ISO120SG –55C to 125°C

ISO121G –25°C to 85°C

ISO121BG –25°C to 85°C

4ISO120/121

TYPICAL PERFORMANCE CURVES

TA = +25°C; VS1 = VS2 = ±15V; and RL = 2kΩ, unless otherwise noted.

Frequency (Hz)

60

40

20



PSRR (dB)

PSRR vs FREQUENCY

100 10k 1M

10 1k 100k

–V

, –V

, +V

100

Frequency (Hz)



1k

100

Peak Isolation Voltage

ISOLATION MODE VOLTAGE 

vs FREQUENCY ISO121

10k 1M 100M

1k 100k 10M

Max AC

Rating

Degraded

Performance

Max DC Rating

Typical

Performance

100

Frequency (Hz)



1k

100

Peak Isolation Voltage

ISOLATION MODE VOLTAGE 

vs FREQUENCY ISO120

10k 1M 100M

1k 100k 10M

2.1k Max AC

Rating

Degraded

Performance

Max DC Rating

Typical

Performance

Frequency (Hz)

0.1µA

100mA

10mA

1mA

100µA

10µA

1µA

Leakage Current (rms)

ISOLATION LEAKAGE CURRENT

vs FREQUENCY

100 10k 1M10 1k 100k

240 Vrms

1500 Vrms

3500 Vrms

100

–3dB Frequency (Hz)

100nF

10nF

1000pF



BANDWIDTH vs C

1k 10k 100k

100

Frequency (Hz)

0.1

100

10

Phase Shift (degrees)

PHASE SHIFT vs C

1k 10k 100k

= 0

= 1000pF

5ISO120/121

TYPICAL PERFORMANCE CURVES (CONT)

TA = +25°C; VS1 = VS2 = ±15V; and RL = 2kΩ, unless otherwise noted.

Frequency (Hz)

160

140

120

100

80

60

IMR (dB)

100 10k 1M10 1k 100k

IMR vs FREQUENCY

Frequency (Hz)

10nF



1000pF



SYNCHRONIZATION RANGE at 25°C

±4Vp SINE WAVE INPUT TO EXT OSC

10k 100k 1M

≥ C

Typical

Free Run

Frequency

(Hz)



0



–20



–40

OUT

(dB)

SIGNAL RESPONSE vs CARRIER FREQUENCY

0000f

/2 f

OUT

(Hz)

–20dB/dec (for comparison only)

0.1f–3dB

Normalized Frequency

12

10

8

6

4

Noise, eN (µV/ Hz)

NOISE vs SMALL SIGNAL BANDWIDTH

0.2f–3dB 0.5f–3dB f–3dB

C2 = 2C1

C2 = C1*

*C1 ≤ 5000pF

FPO

BLEED

TO EDGE

OF BOX

Output Voltage (V)

SINE RESPONSE

(f = 2kHz, C2 = 0)

Time (µs)

5000 1000

+10

0

–10

Output Voltage (V)

SINE RESPONSE

(f = 20kHz, C

= 0)

Time (µs)

500 100

+10

0

–10

6ISO120/121

Output Voltage (V)

STEP RESPONSE

Time (µs)

500 100



+10

0

–10



+10

0

–10

Output Voltage (V)

STEP RESPONSE

Time (µs)

2500 500



+10

0

–10



+10

0

–10

TYPICAL PERFORMANCE CURVES (CONT)

TA = +25°C; VS1 = VS2 = ±15V; and RL = 2kΩ, unless otherwise noted.

THEORY OF OPERATION

The ISO120 and ISO121 isolation amplifiers comprise input

and output sections galvanically isolated by matched 1pF

capacitors built into the ceramic barrier. The input is duty-

cycle modulated and transmitted digitally across the barrier.

The output section receives the modulated signal, converts it

back to an analog voltage and removes the ripple component

inherent in the demodulation. The input and output sections

are laser-trimmed for exceptional matching of circuitry com-

mon to both input and output sections.

FREE-RUNNING MODE

An input amplifier (A1, Figure1) integrates the difference

between the input current (VIN/200kΩ) and a switched

±100µA current source. This current source is implemented

by a switchable 200µA source and a fixed 100µA current

sink. To understand the basic operation of the input section,

assume that VIN = 0. The integrator will ramp in one

direction until the comparator threshold is exceeded. The

comparator and sense amp will force the current source to

switch; the resultant signal is a triangular waveform with a

50% duty cycle. If VIN changes, the duty cycle of the

integrator will change to keep the average DC value at the

output of A1 near zero volts. This action converts the input

voltage to a duty-cycle modulated triangular waveform at

the output of A1 near zero volts. This action converts the

input voltage to a duty-cycle modulated triangular wave-

form at the output of A1 with a frequency determined by the

internal 150pF capacitor. The comparator generates a fast

rise time square wave that is simultaneously fed back to keep

A1 in charge balance and also across the barrier to a

differential sense amplifier with high common-mode rejec-

tion characteristics. The sense amplifier drives a switched

current source surrounding A2. The output stage balances

the duty-cycle modulated current against the feedback cur-

rent through the 200kΩ feedback resistor, resulting in an

average value at the Sense pin equal to VIN. The sample and

hold amplifiers in the output feedback loop serve to remove

undesired ripple voltages inherent in the demodulation process.

SYNCHRONIZED MODE

A unique feature of the ISO120 and ISO121 is the ability to

synchronize the modulator to an external signal source. This

capability is useful in eliminating trouble-some beat fre-

quencies in multi-channel systems and in rejecting AC

signals and their harmonics. To use this feature, external

capacitors are connected at C1 and C2 (Figure 1) to change

the free-running carrier frequency. An external signal is

applied to the Ext Osc pin. This signal forces the current

source to switch at the frequency of the external signal. If

VIN is zero, and the external source has a 50% duty cycle,

operation proceeds as described above, except that the switch-

ing frequency is that of the external source. If the external

signal has a duty cycle other than 50%, its average value is

not zero. At start-up, the current source does not switch until

the integrator establishes an output equal to the average DC

value of the external signal. At this point, the external signal

is able to trigger the current source, producing a triangular

waveform, symmetrical about the new DC value, at the

output of A1. For VIN = 0, this waveform has a 50% duty

cycle. As VIN varies, the waveform retains its DC offset, but

varies in duty cycle to maintain charge balance around A1.

Operation of the demodulator is the same as outlined above.

Synchronizing to a Sine

or Triangle Wave External Clock

The ideal external clock signal for the ISO120/121 is a ±4V

sine wave or ±4V, 50% duty-cycle triangle wave. The ext osc

pin of the ISO120/121 can be driven directly with a ±3V to

±5V sine or 25% to 75% duty-cycle triangle wave and the ISO

amp's internal modulator/demodulator circuitry will synchro-

nize to the signal.

Synchronizing to signals below 400kHz requires the addition

of two external capacitors to the ISO120/121. Connect one

capacitor in parallel with the internal modulator capacitor and

connect the other capacitor in parallel with the internal de-

modulator capacitor as shown in Figure 1.

7ISO120/121

−3dB

≈1. 2

200kΩ150 pF +C

()

FIGURE 1. Block Diagram.

C1, C2 ISO120/121

EXTERNAL CLOCK MODULATOR, DEMODULATOR

FREQUENCY RANGE EXTERNAL CAPACITOR

400kHz to 700kHz none

200kHz to 400kHz 500pF

100kHz to 200kHz 1000pF

50kHz to 100kHz 2200pF

20kHz to 50kHz 4700pF

10kHz to 20kHz 0.01µF

5kHz to 10kHz 0.022µF

The value of the external modulator capacitor, C1, depends on

the frequency of the external clock signal. Table I lists

recommended values.

Synchronizing to a 400kHz to 700kHz

Square-Wave External Clock

At frequencies above 400kHz, an internal clamp and filter

provides signal conditioning so that a square-wave signal can

be used to directly drive the ISO120/121. A square-wave

external clock signal can be used to directly drive the ISO120/

121 ext osc pin if: the signal is in the 400kHz to 700kHz

frequency range with a 25% to 75% duty cycle, and ±3V to

±20V level. Details of the internal clamp and filter circuitry

are shown in Figure 1.

Synchronizing to a 10% to 90%

Duty-cycle External Clock

With the addition of the signal conditioning circuit shown in

Figure 2, any 10% to 90% duty-cycle square-wave signal can

be used to drive the ISO120/121 ext osc pin. With the values

shown, the circuit can be driven by a 4Vp-p TTL signal. For

a higher or lower voltage input, increase or decrease the 1kΩ

resistor, RX, proportionally. e.g. for a ±4V square wave

(8Vp-p) RX should be increased to 2kΩ.

The value of CX used in the Figure 2 circuit depends on the

frequency of the external clock signal. Table II shows recom-

mended capacitor values.

Note: For external clock frequencies below 400kHz, external

modulator/demodulator capacitors are required on the

ISO120/121 as before.

TABLE I. Recommended ISO120/121 External Modulator/

Demodulator Capacitor Values vs External Clock

Frequency.

The value of the external demodulator capacitor, C2, depends

on the value of the external modulator capacitor. To assure

stability, C2 must be greater than 0.8 • C1. A larger value for

C2 will decrease bandwidth and improve stability:

Where:

f–3dB ≈ –3dB bandwidth of ISO amp with external C2 (Hz)

C2 = External demodulator capacitor (f)

For example, with C2 = 0.01µF, the f–3dB bandwidth of the

ISO120/121 is approximately 600Hz.

1pF

S/H

G = 1 S/H

G = 6

Sense

OUT

Signal

Com 2

Gnd 2 –V

Gnd 1 –V

Signal

Com 1

1(1)

200kΩ150pF

100µA

Sense

200µA

100µA

Sense

200µA

200kΩ

150pF

2(1)

Isolation Barrier

NOTE: (1) Optional. See text.

30kΩ16kΩ

Ext

Osc

16kΩ50pF

8ISO120/121

BASIC OPERATION

Signal and Power Connections

Figure 3 shows proper power and signal connections. Each

power supply pin should be bypassed with 1µF tantalum

capacitor located as close to the amplifier as possible. All

ground connections should be run independently to a com-

mon point if possible. Signal Common on both input and

output sections provide a high-impedance point for sensing

signal ground in noisy applications. Signal Common must

have a path to ground for bias current return and should be

maintained within ±1V of Gnd. The output sense pin may be

EXTERNAL CLOCK

FREQUENCY RANGE CX

400kHz to 700kHz 30pF

200kHz to 400kHz 180pF

100kHz to 200kHz 680pF

50kHz to 100kHz 1800pF

20kHz to 50kHz 3300pF

10kHz to 20kHz 0.01µF

5kHz to 10kHz 0.022µF

10kΩ

X

OPA602

X

1µF

Sq Wave In Triangle Out

to ISO120/121

Ext Osc

1kΩ

FIGURE 2. Square Wave to Triangle Wave Signal Condi-

tioner for Driving ISO120/121 Ext Osc Pin.

TABLE II. Recommended CX Values vs Frequency for

Figure 2 Circuit.

1(1)

–V

–+V

+1µF

Signal 

Com1

Gnd1

Guard

Ext

(2)

Osc

2(1)

–V

–+V

+1µF

Guard

1µF

Gnd 2

Signal 

Com 2

OUT

Sense

Isolation Barrier

NOTE: (1) Optional. See text. (2) Ground if not used.

FIGURE 3. Power and Signal Connections.

connected directly to VOUT or may be connected to a remote

load to eliminate errors due to IR drops. Pins are provided

for use of external integrator capacitors. The C1H and C2H

pins are connected to the integrator summing junctions and

are therefore particularly sensitive to external pickup. This

sensitivity will most often appear as degraded IMR or PSR

performance. AC or DC currents coupled into these pins

results in VERROR = IERROR X 200kΩ at the output. Guarding

of these pins to their respective Signal Common, or C1L and

C2L is strongly recommended. For similar reasons, long

traces or physically large capacitors are not desirable. If

wound-foil capacitors are used, the outside foil should be

connected to C1L and C2L, respectively.

Optional Gain and Offset Adjustments

Rated gain accuracy and offset performance can be achieved

with no external adjustments, but the circuit of Figure 4a

may be used to provide a gain trim of ±0.5% for values

shown; greater range may be provided by increasing the size

of R1 and R2. Every 2kΩ increase in R1 will give an

additional 1% adjustment range, with R2 ≥ 2R1. If safety or

convenience dictates location of the adjustment potenti-

ometer on the other side of the barrier from the position

shown in Figure 4a, the positions of R1 and R2 may be

reversed. Gains greater than one may be obtained by using

the circuit of Figure 4b. Note that the effect of input offset

errors will be multiplied at the output in proportion to the

increase in gain. Also, the small-signal bandwidth will be

decreased in inverse proportion to the increase in gain. In

most instances, a precision gain block at the input of the

isolation amplifier will provide better overall performance.

Figure 5 shows a method for trimming VOS of the ISO120

and ISO121. This circuit may be applied to either Signal

Com (input or output) as desired for safety or convenience.

With the values shown, ±15V supplies and unity gain, the

circuit will provide ±150mV adjustment range and 0.25mV

9ISO120/121

output are not significant under these circumstances unless

the input signal contains significant components above

250kHz.

There are two ways to use these characteristics. One is to

move the carrier frequency low enough that the troublesome

signal components are attenuated to an acceptable level as

shown in Signal Response vs Carrier Frequency. This in

effect limits the bandwidth of the amplifier. The Synchroni-

zation Range performance curve shows the relationship

between carrier frequency and the value of C1. To maintain

stability, C2 must also be connected and must be equal to or

larger in value than C1. C2 may be further increased in value

for additional attenuation of the undesired signal compo-

nents and provides the additional benefit of reducing the

residual carrier ripple at the output. See the Bandwidth vs C2

performance curve.

When periodic noise from external sources such as system

clocks and DC/DC converters are a problem, ISO120 and

ISO121 can be used to reject this noise. The amplifier can be

synchronized to an external frequency source, fEXT, placing

the amplifier response curve at one of the frequency and

amplitude nulls indicated in the Signal Response vs Carrier

Frequency performance curve. For proper synchronization,

choose C1 as shown in the Synchronization Range perfor-

mance curve. Remember that C2 ≥ C1 is a necessary condi-

tion for stability of the isolation amplifier. This curve shows

the range of lock at the fundamental frequency for a 4V

sinusoidal signal source. The applications section shows the

ISO120 and ISO121 synchronized to isolation power sup-

plies, while Figure 6 shows circuitry with opto-isolation

suitable for driving the Ext Osc input from TTL levels.

FIGURE 4a. Gain Adjust.

FIGURE 4b. Gain Setting.

or +V

Signal Com 1

or

Signal Com 2

–V

or –V

100kΩ1MΩ

10kΩ

FIGURE 5. VOS Adjust.

resolution with a typical trim potentiometer. The output will

have some sensitivity to power supply variations. For a

±100mV trim, power supply sensitivity is 8mV/V at the

output.

CARRIER FREQUENCY CONSIDERATIONS

As previously discussed, the ISO120 and ISO121 amplifiers

transmit the signal across the iso-barrier by a duty-cycle

modulation technique. This system works like any linear

amplifier for input signals having frequencies below one

half the carrier frequency, fC. For signal frequencies above

fC/2, the behavior becomes more complex. The Signal Re-

sponse vs Carrier Frequency performance curve describes

this behavior graphically. The upper curve illustrates the

response for input signals varying from DC to fC/2. At input

frequencies at or above fC/2, the device generates an output

signal component that varies in both amplitude and fre-

quency, as shown by the lower curve. The lower horizontal

scale shows the periodic variation in the frequency of the

output component. Note that at the carrier frequency and its

harmonics, both the frequency and amplitude of the re-

sponse go the zero. These characteristics can be exploited in

certain applications. It should be noted that when C1 is zero,

the carrier frequency is nominally 500kHz and the –3dB

point of the amplifier is 60kHz. Spurious signals at the

FIGURE 6. Synchronization with Isolated Drive Circuit for

Ext Osc Pin.

Ext Osc on

ISO120 (pin 22)

10kΩ

TTL

2.5kΩ

200Ω

+15V+5V

140E-6

()

= – 350pF

= 10 X C

, with a minimum 10nF

2.5kΩ

6N136

ISOLATION MODE VOLTAGE

Isolation mode voltage (IMV) is the voltage appearing be-

tween isolated grounds Gnd 1 and Gnd 2. IMV can induce

error at the output as indicated by the plots of IMV vs

Frequency. It should be noted that if the IMV frequency

exceeds fC/2, the output will display spurious outputs in a

manner similar to that described above, and the amplifier

response will be identical to that shown in the Signal Re-

sponse vs Carrier Frequency performance curve. This occurs

2

IN

OUT

1

Sense

2

1

200k

Gain = 1 + + R

1

( )

2

GND1

1kΩ 2kΩ

1

2

IN

OUT

GND1

Sense

10ISO120/121

because IMV-induced errors behave like input-referred error

signals. To predict the total IMR, divide the isolation voltage

by the IMR shown in IMR vs Frequency performance curve

and compute the amplifier response to this input-referred

error signal from the data given in the Signal Response vs

Carrier Frequency performance curve. Due to effects of very

high-frequency signals, typical IMV performance can be

achieved only when dV/dT of the isolation mode voltage

falls below 1000V/µs. For convenience, this is plotted in the

typical performance curves for the ISO120 and ISO121 as a

function of voltage and frequency for sinusoidal voltages.

When dV/dT exceeds 1000V/µs but falls below 20kV/µs,

performance may be degraded. At rates of change above

20kV/µs, the amplifier may be damaged, but the barrier

retains its full integrity. Lowering the power supply voltages

below ±15V may decrease the dV/dT to 500V/µs for typical

performance, but the maximum dV/dT of 20kV/µs remains

unchanged.

Leakage current is determined solely by the impedance of

the 2pF barrier capacitance and is plotted in the Isolation

Leakage Current vs Frequency curve.

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 higher voltage for some shorter time. The

relationship between actual test voltage and the continuous

derated maximum specification is an important one. Histori-

cally, Burr-Brown has chosen a deliberately conservative

one: VTEST = (2 X ACrms continuous rating) + 1000V for 10

seconds, followed by a test at rated ACrms voltage for one

minute. This choice was appropriate for conditions where

system transients are not well defined.

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 ISO120 and ISO121.

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 ion-

ization requires a higher applied voltage to start the dis-

charge and lower voltage to maintain it or extinguish it once

started. The higher start voltage is known as the inception

voltage, while the extinction voltage is that level of voltage

stress at which the discharge ceases. Just as the total insula-

tion system has an inception voltage, so do the individual

voids. A voltage will build up across a void until its incep-

tion voltage is reached, at which point the void will ionize,

effectively shorting itself out. This action redistributes elec-

trical charge within the dielectric and is known as partial

discharge. If, as is the case with AC, 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 still useful in rating the devices and providing quality

control of the manufacturing process. Since the ISO120 and

ISO121 do not use organic insulation, partial discharge is

non-destructive.

The inception voltage for these voids tends to be constant, so

that the measurement of total charge being redistributed

within the dielectric is a very good indicator of the size of

the voids and their likelihood of becoming an incipient

failure. The bulk inception voltage, on the other hand, varies

with the insulation system, and the number of ionization

defects and directly establishes the absolute maximum volt-

age (transient) that can be applied across the test device

before destructive partial discharge can begin. Measuring

the bulk extinction voltage provides a lower, more conserva-

tive voltage from which to derive a safe continuous rating.

In production, measuring at a level somewhat below the

expected inception voltage and then derating by a factor

related to expectations about system transients is an

accepted practice.

Partial Discharge Testing

Not only does this test method provide far more qualitative

information about stress-withstand levels than did previous

stress tests, but it provides quantitative measurements from

which quality assurance and control measures can be based.

Tests similar to this test have been used by some manufac-

turers, 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 quantify partial

discharge. VDE, the national standards group in Germany

and an acknowledged leader in high-voltage test standards,

has developed a standard test method to apply this powerful

technique. Use of partial discharge testing is an improved

method for measuring the integrity of an isolation barrier.

To accommodate poorly-defined transients, the part under

test is exposed to voltage that is 1.6 times the continuous-

rated voltage and must display ≤5pC partial discharge level

in a 100% production test.

11 ISO120/121

APPLICATIONS

The ISO120 and ISO121 isolation amplifiers are used in

three categories of applications:

1. Accurate isolation of signals from high voltage ground

potentials,

APPLICATION CIRCUITS

FIGURE 7. Eight-channel Isolated 0-20mA Loop Driver.

4322

912 11

PWS740-3

PWS740-1

0.3µF

PWS740-2

0.3µF

10µF

+15V +'E

20µH

1.0µF

–V

To other 

channels 20kΩ

20pF

1.0µF

–15V 1.0µF

≤ 600Ω

= 0-20mA

VN2222

1/4W

250Ω

0.1%

6.2V

400mW

–15V

+15V

20kΩ

ISO120

1.0µF

0-5V

System Uses:

1 - Oscillator/Driver

8 - Transformers

8 - Bridges

8 - ISO120s

8 - Transistors VN2222

8 - Zener Diodes, 6.2V, 400mW, 20%

Not all components shown.

8+V

+15V

2. Accurate isolation of signals from severe ground noise

and,

3. Fault protection from high voltages in analog measure-

ments.

Figures 7 through 12 show a variety of Application Circuits.

12ISO120/121

FIGURE 9. Right-Leg Driven ECG Amplifier (with defibrillator protection and calibration).

–

0.001µF

10 9ISO

120

INA110

415 16

–V

200kΩ

0.005 Power Resistor

120Vrms

100A

3θ Y-Connected Power Transformer

–V

912

OUT

= 1000pF

= 1000pF

Differential input accurately senses power resistor voltage.

Two resistors protect INA110 from open power resistor.

High frequency spike reject filter has f

= 400Hz.

FIGURE 8. Isolated Powerline Monitor.

15

4

7

5

6

14

+

–

37

40

38

39

1 2 21 22

18

19

20

23

24

4

3

PWS 726A

32

29

1 4

1

0.3

14 16

20kΩ

20pF

–V

S1

S2

20µH

S1

–V

S1

–V

S2

2

1

Calibration Signal

5.00V

0V

1/2W

300kΩ 50kΩ

1/2W

300kΩ 50kΩ

1/2W

300kΩ 180kΩ

Calibration

On

Left Arm

On

Right Arm

Calibration

Right Leg NE2H

NE2H

NE2H

(2)

500pF

200pF

7

4 3

2

–V

S1

–V

S1

–V

S1

12 0.0082

(1)

0.0082

–V

S1

9 8

10

11

13

5MΩ

1kΩ

1mV

Gain = 1000

17

ISO

121

INA102

OPA121

NOTE: (1) All capacitor values in µF unless otherwise

noted. Diodes are IN4148. (2) NE2H: Neon bulb, max

striking voltage 95V

.

6

13 ISO120/121

FIGURE 10. Battery Monitor for a 600V Battery Power System.

FIGURE 11. Isolated 4-20mA Instrument Loop. (RTD shown).

23 315

=12V

9, 12 10

–V

5kΩ

23 315

10kΩ

9, 12 10

–V

5kΩ

10kΩ

=12V

=12V 10kΩ

10kΩ

Charge/Discharge Control

INA105

25kΩ

V = 2

+V –V

V = 2

Multiplexer

Control

Section

ISO

120

ISO

120

2.5kΩ

INA105 ISO

120

XTR101

150Ω

100Ω

0.01µF

RTD

(PT100)

1mA1mA

2mA

250Ω250Ω6

241

24 49

11 10

Sync

Gnd

–V

= –15V

on PWS740

OUT

= 15V on PWS740

NOTE: Some ISO120 connections left out for clarity.

14ISO120/121

FIGURE 12. Synchronized-Multichannel Isolation System.

IN2

ISO

120

10 9

12 15

Ext Osc

0.3µF

PWS740-3

20pF

63 312

20kΩ

Gnd2

465 PWS740-2

–V

V+V–

OUT2

IN1

ISO

120

10 9

12 15

Ext Osc

PWS740-3

20pF

63 312

20kΩ

Gnd1

465 PWS740-2

–V

V+V–

OUT1

0.3µF

PWS740-1

V+

20µH

10µF 0.3µF 0.3µF

Up to 6

more 

channels

PACKAGING INFORMATION

Orderable Device Status (1) Package

Type Package

Drawing Pins Package

Qty Eco Plan (2) Lead/Ball Finish MSL Peak Temp (3)

ISO120BG NRND CDIP SB JVA 16 1 Green (RoHS &