FAIRCHILD AN-3001

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Application Note AN-3001
Optocoupler Input Drive Circuits
An optocoupler is a combination of a light source and a
photosensitive detector. In the optocoupler, or photon
coupled pair, the coupling is achieved by light being
generated on one side of a transparent insulating gap and
being detected on the other side of the gap without an
electrical connection between the two sides (except for a
minor amount of coupling capacitance). In the Fairchild
Semiconductor optocouplers, the light is generated by an
infrared light emitting diode, and the photo-detector is a
silicon diode which drives an amplifier, e.g., transistor. The
sensitivity of the silicon material peaks at the wavelength
emitted by the LED, giving maximum signal coupling.
dropped across the resistor at the desired IF, determined from
other criteria. A silicon diode is shown installed inversely
parallel to the LED. This diode is used to protect the reverse
breakdown of the LED and is the simplest method of achieving this protection. The LED must be protected from excessive power dissipation in the reverse avalanche region. A
small amount of reverse current will not harm the LED, but it
must be guarded against unexpected current surges.
Where the input to the optocoupler is a LED, the input
characteristics will be the same, independent of the type of
detector employed. The LED diode characteristics are shown
in Figure 1. The forward bias current threshold is shown at
approximately 1 volt, and the current increases exponentially, the useful range of IF between 1 mA and 100 mA
being delivered at a VF between 1.2 and 1.3 volts. The
dynamic values of the forward bias impedance are current
dependent and are shown on the insert graph for RDF and
∆R as defined in the figure. Reverse leakage is in the nanoampere range before avalanche breakdown.
The brightness of the IR LED slowly decreases in an exponential fashion as a function of forward current (IF) and time.
The amount of light degradation is graphed in Figure 6
which is based on experimental data out to 20,000 hours.
A 50% degradation is considered to be the failure point.
This degradation must be considered in the initial design of
optoisolator circuits to allow for the decrease and still remain
within design specifications on the current-transfer-ratio
(CTR) over the design lifetime of the equipment. Also, a
limitation on IF drive is shown to extend useful lifetime of
the device.
The LED equivalent circuit is represented in Figure 2, along
with typical values of the components. The diode equations
are provided if needed for computer modeling and the constants of the equations are given for the IR LED’s. Note that
the junction capacitance is large and increases with applied
forward voltage. An actual plot of this capacitance variation
with applied voltage is shown on the graph of Figure 3. It is
this large capacitance controlled by the driver impedance
which influences the pulse response of the LED. The capacitance must be charged before there is junction current to
create light emission. This effect causes an inherent delay of
10-20 nanoseconds or more between applied current and
light emission in fast pulse conditions.
In some circumstances it is desirable to have a definite
threshold for the LED above the normal 1.1 volts of the
diode VF. This threshold adjustment can be obtained by
shunting the LED by a resistor, the value of which is
determined by a ratio between the applied voltage, the
series resistor, and the desired threshold. The circuit of
Figure 7 shows the relationship between these values.
The calculations will determine the resistor values required
for a given IFT and VA. It is also quite proper to connect
several LED’s in series to share the same IF. The VF of the
series is the sum of the individual VF’s. Zener diodes may
also be used in series.
The LED is used in the forward biased mode. Since the
current increases very rapidly above threshold, the device
should always be driven in a current mode, not voltage
driven. The simplest method of achieving the current drive is
to provide a series current-limiting resistor, as shown in
Figure 4, such that the difference between VAPP and VF is
The forward voltage of the LED has a negative temperature
coefficient of 1.05 mV/°C and the variation is shown in
Figure 5.
Where the input applied voltage is reversible or alternating
and it is desired to detect the phase or polarity of the input,
the bipolar input circuit of Figure 8 can be employed. The
individual optocouplers could control different functions or
be paralleled to become polarity independent. Note that in
this connection, the LED’s protect each other in reverse bias.
REV. 4.00 4/30/02
AN-3001
APPLICATION NOTE
VF - FORWARD VOLTAGE (VOLTS)
∆R = 300Ω
1.5
30Ω
3Ω
IF RS
1.4
RDF=
13Ω
1.3
1.2
FORWARD BIAS
IF
mA
100
120Ω
TA = 25˚C
1.1
1.0
Cj
D
Vj
D - IDEAL DIODE
I
10KΩ
0.9
60
0.8
0.1
16
RP
SLOPE
V
= RDF =
80
14
VF
SLOPE
1.0
10
100
∆V
= ∆R =
∆I
40
AVALANCHE
18
VF
1KΩ
IF - FORWARD CURRENT (mA)
20
LED
EQUIVALENT
CIRCUIT
0.3Ω
20
12
10
8
6
4
2
0
0.5
1.0
1.5
0
-
-
-
-
1
10
1.0
<10
1.1
V
100 mA
100 300 500
RP >109
THRESHOLD
REVERSE BIAS
55
RS
0.1
BVR
-
Cj
IR
VF VOLTS
RANGE OF
IF
Vj
0.01
VR
-5
1.2
-
pF
1.3
V
0
-
-
-
nA
∞
30
3
0.3
Ω
-
-
-
-
Ω
1.0
IF = IFT exp
10
100
VF - VFT
k
VF = VFT + k log
NOTE CHANGE OF SCALES
mA
IF
IFT
For IRLED (940nm)
IR
VFTH = 0.98V
IFTH = 0.10mA
K = 0.360
Figure 1. Characteristics of IR LED
RS =
0.03V
IF (A)
Figure 2. Equivalent Circuit Equations
JUNCTION CAPACITANCE (Cj) - pF
350
300
250
200
IF
R=
R
VAPP - VF
IF
150
LED
VAPP
VF
100
NOTE SCALE CHANGE
Figure 4. Typical LED Drive Circuit
50
VF
1.5
1.0
VR
0.5
0 1 2 3
APPLIED VOLTAGE
4
5
6
7
8
Figure 3. Voltage Dependence of Junction Capacitance
2
REV. 4.00 4/30/02
APPLICATION NOTE
AN-3001
IFT
1.4
R2 PROVIDES A THRESHOLD
VF
V -V
R1 = A F
R2
IFT
R1
FORWARD VOLTAGE - VF (VOLTS)
IFT =
1.3
VA
T = -55°C
VF
R2
1.2
Figure 7. LED Threshold Adjustment
T = +25°C
1.1
1.0
1
T = +100°C
IF
VF
0.9
R1
2
0.8
0.1
VA
0.2
0.5
1
2
5
10
20
R2
50 100
VF
FORWARD CURRENT - IF (mA)
Figure 8. Bipolar Input Selects LED
NORMALIZED CTR DEGRADATION - %
Figure 5. IR Forward Voltage vs. Forward
Current and Temperature
R1
50
40
30
00
20
IF
=1
IF=
10
IF =
8
6
4
75
60
mA
VA
mA
R2 VF
mA
0 mA
IF = 3
Figure 9. High Threshold Bipolar Input
IF = 10 mA
2
TA = 25°C
1
10
100
1000
10,000
100,000
TIME - HOURS
Figure 6. Brightness Degredation vs.
Forward Current and Time
IF
R1
+
-
EXTERNAL
SWITCH
DEVICE
120V
RMS
60 Hz
VR
2
R2
+
C1
R3
-
Figure 10. AC Input to LED Drive Circuit
Another method of obtaining a high threshold for high level
noise immunity is shown in Figure 9, where the LED’s are in
inverse series with inverse parallel diodes to conduct the
opposite polarity currents. In this circuit, the VF is the total
REV. 4.00 4/30/02
forward drop of the LED and silicon diode in series. The
resistors serve their normal threshold and current limiting
functions. The silicon diodes could be replaced by LED’s
from other optocouplers or visible signal indicators.
3
AN-3001
APPLICATION NOTE
AC Mains Monitoring
Logic to Logic Interface
In some situations it may be necessary to drive the LED from
a 120 VRMS, 60 Hz or 400 Hz source. Since the LED
responds in nanoseconds, it will follow the AC excursions
faithfully, turning on and off at each zero-crossing of the
input. If a constant output is desired from the optocoupler
detector as in AC to logic coupling, it is necessary to rectify
and filter the input to the LED. The circuit of Figure 10
illustrates a simple filtering scheme to deliver a DC current
to the LED. In some cases the filter could be designed into
the detector side of the optocoupler, allowing the LED to
pulse at line frequency. In the circuit of Figure 10, the value
of C1 is selected to reduce the variations in the IF between
half cycles below the current that is detectable by the detector portion. This condition usually means that the detector is
functioning in saturation, so that minor variations of IF will
not be sensed. The values of R1, R2 and R3 are adjusted to
optimize the filtering function, R3C1 time constant, etc.
Speed of turn-off may be a determining factor. More complicated transistor filtering may be required, such as that shown
in Figure 11, where a definite time delay, rise time and fall
time can be designed in. In this circuit, C1 and R3 serve the
same basic function as in Figure 10. The transistor provides a
high impedance load to the R4C2 filter network, which once
reaching the VF value, suddenly turns on the LED and pulls
the transistor quickly into saturation. The turn-off transient
consists of the discharge of C1, through R3 and the LED.
In logic-to logic coupling using the optocoupler, a simple
transistor drive circuit can be used as shown in Figure 12.
In the normally-off situation, the LED is energized only
when the transistor is in saturation. The design equations are
given for calculating the value of the series current limiting
resistor. With the transistor off, only minor collector leakage
current will flow through the LED. If this small leakage is
detectable in the optocoupler detector, the leakage can be
bypassed around the LED by the addition of another resistor
in parallel with the LED shown as R1. The value of R1 can
be large, calculated so that the leakage current develops less
than threshold VF (~0.8 volt) from Figure 5. The drive
transistor can be the normal output current sink of a TTL or
DTL integrated circuit, which will sink 16 mA at 0.2 volt
nominal and up to 50 mA in saturation.
If the logic is not capable of sinking the necessary IF, an auxiliary drive transistor can be employed to boost current capability. The circuit of Figure 13 shows how a PNP transistor is
connected as an emitter follower, or common collector, to
obtain current gain. When the output of the gate (G1) is low,
Q1 is turned on and current flows through the LED. The
calculation of R1 must now include the base-emitter forward
biased voltage drop, VBE, as shown in the figure.
DC
INPUT
FROM
BRIDGE
RECTIFIER
IF
R3
+
R4
C1
VF
10K=R1
C2
R2=10K
-
Figure 11. R-C-Transistor Filter Circuit
VCC
+
IF
R
VCC = 5 V
IF
= 20 mA
VSAT = 0.4 V
VF = 1.2 V
R=
R1
R1 =
VCC - VF - VBE - VCE(SAT)GATE
IF
VBE(Q1) = 0.6 V
VCE(SAT)(G1) = 0.4 V
R1
10K
IF
OUTPUT
VCC - VF - VSAT
IF
= 5 - 1.2 - 0.4 = 3.4
20
20
VF
VCC
VCC
VF
R = 170Ω
INPUT
(VSAT)
G1
VBE
Q1
VCE(SAT)
Figure 12. Transistor Drive, Normally Off
4
Figure 13. Logic to LED Series Booster
REV. 4.00 4/30/02
APPLICATION NOTE
AN-3001
In the normally on situation of Figure 14, the transistor is
required to shunt the IF around the LED, with a VSAT of less
than threshold VF. Typical switching transistors have saturation voltages less than 0.4 volts at IC=20 mA or less. The
value of the series resistor is determined to provide the
required IF with the transistor off.
situations a “pulse” is defined as an on-off transient occurring and ending before thermal equilibrium is established
between the LED, the lead frame, and the ambient. This
equilibrium will normally occur within one millisecond.
For a pulse width in the microsecond range, the IF can be
driven above the DC ratings, if the duty cycle is low.
The chart of Figure 16 shows the relationship between the
amount of overdrive, duty cycle, and pulse width. The overdrive is normalized to the IDC value listed as maximum on
the device data sheet. Average power dissipation is the limiting parameter at high duty cycles and short pulse widths. For
longer pulse widths, the equilibrium temperature occurs at
lower duty cycle values, and peak power is the limiting
parameter.
Again, if the logic cannot sink the IF, a booster transistor
can be employed as shown in Figure 15. With the output of
the gate low, the transistor Q1 will be on and the sum of
VCE (SAT) of G1 and VBE of Q1, will be less than the
threshold VF of the LED. With the gate high, Q1 is not
conducting and LED is on. The value of R1 is calculated
normally, but shunt current will be greater than IF. The
normally-on or normally-off conditions are selected depending on the required function of the detector portion of the
optocoupler and fail-safe operation of the circuits.
For duty cycles of 1% or less the pulse becomes similar to a
nonrecurrent surge allowing additional ratings such as the I2t
used in rectifier diodes. Average current is used for lifetime
calculation. The pulse response of the detector must be considered in choosing drive conditions.
In many applications it is found necessary to pulse drive the
LED to values beyond the DC ratings of the device. In these
VCC - VF
IF
3.8
=
= 190Ω
20
VCC
R=
IF
R1 =
VCC - VF
IF
R
R1
INPUT
(VSAT)
VF
G1
VCC
VCC
IF
10K
OUTPUT
VBE
Q1
VCE(SAT)
Figure 14. Transistor Drive, Normally On
Figure 15. Logic to LED Shunt Booster
100
1 µS
5 µS
10 µS
IPK
IDC
PW = 30 µsec
10
100 µS
300 µS
1
0.1
1.0
10
100
DUTY CYCLE - %
Figure 16. Maximum Peak IF Pulse Normalized to Max IDC
for Pulse Width (PW) and Duty Cycle (%)
REV. 4.00 4/30/02
5
AN-3001
APPLICATION NOTE
LED Current Shunting Techniques
There are situations where it is not desirable to pass all of the
input current through the LED. One method to achieve this is
to provide a bypass resistor as suggested in Figure 7 for
threshold adjustment. This method is satisfactory where the
input current is switched on and off completely, but if the
information on the current is only a small variation riding on
a constant DC level, the bypass resistor also bypasses a large
portion of the desired signal around the LED. Two methods
can be used to retrieve the signal with little attenuation. If the
signal has a rapid variation (e.g., the audio signal on a telephone line), the DC component can be cancelled in the
detector by feedback circuits. If the variation is slow, a
dynamic shunt can be used instead of the fixed resistor.
If a constant-current device or circuit is used in parallel with
the LED, as shown in Figure 17, the adjusted component of
the DC will flow through the dynamic impedance, and any
current variations will result in a change of terminal voltage.
Therefore, the total current change will flow through the
paralleled LED circuit. The graph of Figure 18 shows the
performance of this particular circuit adjusted to center on
IL=120mA and a circuit node voltage of 3.4 volts. In the
circuit shown, the detector portions of the CNY17-1 and
CNY17-4 were employed for convenience. Note that in
Figure 18 most of the current variation occurs as IF. The ratio
between the DC resistance (RD) and dynamic impedance
(Rd) for the shunt is 50, which represents the signal transfer
gain achieved over a fixed resistor.
125
IL
2.7K
ITH
IL2W
IF = 10 mA
3.4V
LED
R = 200Ω
HIIB2
1.7V
220Ω
β>10K
VA
I - mA
120
115
MCT2
β>200
0.5V
CNY17-4
LED
30Ω
110
IL SANS LED
1
R = 1.6K
105
3.0
3.1
3.2
3.4
3.6
3.8
4.0
TERMINAL VOLTAGE - VA
Figure 17. Constant-Current Shunt Impedance
Figure 18. Shunt Impedance Performance
6
REV. 4.00 4/30/02
AN-3001
APPLICATION NOTE
DISCLAIMER
FAIRCHILD SEMICONDUCTOR RESERVES THE RIGHT TO MAKE CHANGES WITHOUT FURTHER NOTICE TO ANY
PRODUCTS HEREIN TO IMPROVE RELIABILITY, FUNCTION OR DESIGN. FAIRCHILD DOES NOT ASSUME ANY
LIABILITY ARISING OUT OF THE APPLICATION OR USE OF ANY PRODUCT OR CIRCUIT DESCRIBED HEREIN; NEITHER
DOES IT CONVEY ANY LICENSE UNDER ITS PATENT RIGHTS, NOR THE RIGHTS OF OTHERS.
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which, (a) are intended for surgical implant into the body,
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when properly used in accordance with instructions for use
provided in the labeling, can be reasonably expected to
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2. A critical component is any component of a life support
device or system whose failure to perform can be
reasonably expected to cause the failure of the life support
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