Panasonic Two Riverfront Plaza, 7th Floor, Newark, NJ 07102-5490 www.panasonic.com/industrial
WHITE PAPER
Not too long ago, all relays performed their switching duties
through electromechanical means. Today, however, engineers
can also opt for solid-state relays that use semiconductors
to switch their output circuits. The choice between traditional
electromechanical relays and the solid-state varieties often
comes down to reliability and performance.
With no moving parts, solid-state relays avoid all the obvious
mechanical failure modes associated with traditional relays. They
also tend to offer desirable electrical characteristics and design
advantages including:
• Low power consumption.
• Low leakage current.
• Stable on-resistance over lifetime.
• High reliability with extremely long life.
• Small size.
• Fast switching speeds.
• High vibration and shock resistance.
• No contact bounce or switching noise.
Keep in mind that solid-state devices are not created equal when
it comes to these performance advantages. Optically-isolated
solid state relays, in particular, can outshine other solid-state
devices that use electrical or magnetic operating principles. In
this paper, you will learn more about the operating principles
of optically-isolated relays, how to apply them in different
applications and how to maximize their already-long lifecycles.
PRINCIPLES OF OPERATION
Optically-isolated relays are characterized by the use of a light
emitting diode (LED) on their input side, MOSFETs on the output
side and an array of photo sensors in between.
In operation, current flows through the LED, which then emits
light. The photo sensor array detects the emitted light, triggering
a voltage drop that drives the MOSFETs. The MOSFETs finally
switch the load circuit.
The design and packaging of the optical and electronic
components are crucial aspects of the relay’s performance. The
LED and photo array, for example, are molded in a translucent
resin that allows light to pass through while providing a dielectric
barrier between the input and output.
The most basic method to drive an optically-isolated relay is
to apply a switchable voltage directly to the input pin of the
Working With Optically-Isolated Relays
Learn how these solid-state relays can improve the performance of data
acquisition systems and industrial machines
Product lineup of PhotoMOS devices
Product lineup of PhotoMOS devicesProduct lineup of PhotoMOS devices
MOSFET
LED
Photo-Cell
PhotoMOS relay
MOSFET
Panasonic Two Riverfront Plaza, 7th Floor, Newark, NJ 07102-5490 www.panasonic.com/industrial
PhotoMOS through a resistor to limit the current through the
LED. Choosing the correct RF value for the resistor will ensure
that the LED reaches full intensity while preventing it from being
overdriven by the input voltage (see Design Tip, “Calculating
Input Resistance (RF) Correctly”).
TEST AND MEASUREMENT USES
Most optically-isolated relays today will ultimately become part of
sophisticated test and measurement systems. To keep pace with
advances in the electronics industry, these systems increasingly
require solid-state relays that combine low capacitance, low on-
resistance, physical isolation and high linearity.
All these characteristics play an important role as data
acquisition devices become faster and more precise:
Low capacitance improves switching times and isolation
characteristics for high frequency load signals.
Low on-resistance reduces power dissipation when switching
high currents and increases switching speeds to improve the
precision of measurement. When considering on-resistance
values, pay close attention to the temperature range the relay
must withstand. Rising temperatures decrease the mobility of
electrons, driving up the on-resistance. Starting with a relay that
has low on-resistance will minimize the effects of temperature
drift.
Physical isolation. Sometimes referred to as galvanic
separation, physical isolation between the relay’s input and
output or between different output channels enhances precision
by minimizing noise. Optically-isolated relays offer a true physical
separation of the input and output, and the best of these
products exhibit isolation voltages as high as 5,000 volts AC.
High linearity ensures accurate measurements.
With a variety of signals at work in a typical test system,
it’s particularly important to find relays that offer the right
combination of electrical characteristics. For example, many
systems have both DC and AC switching needs and will require
relays that combine low-on-resistance and low capacitance:
The low on-resistance minimizes signal loss when switching
DC signals, while low capacitance improves isolation when
switching AC signals.
INDUSTRIAL APPLICATIONS TOO
Not all optically-isolated relays end up in test
and measurement applications. Increasingly,
these relays also switch and protect small motors, power
supplies and control devices with load currents up to 10 amps.
These industrial uses represent the next wave of applications
for optically-isolated relay technology, which has been widely
accepted as a way to switch high-precision data acquisition and
measurement systems.
Like test and measurement systems, industrial equipment can
benefit from high switching speeds, low on-resistance, low
capacitance and small package size.Yet motors, power supplies
and controls can reap additional benefits by moving from
traditional electromechanical relays to optically-isolated relays:
Low Power Consumption. A typical optically-isolated
relay requires 10 to 20 times less power than an equivalent
electromechanical relay. For example, a 5 mA PhotoMOS
can often do the same job as an electromechanical relay
that requires anywhere from 50 to 100 mA, depending on the
electromagnetic force needed to close the coil. A few milliamps
here or there may not sound like a big deal, but in a plant with
many small devices the savings add up quickly.
Protection. Thanks to a built-in protective circuit in our latching-
type models, PhotoMOS can safeguard motors, power supplies
and other industrial devices from possible disturbances on
the output side. These disturbances–such as voltage peaks
or overcurrent conditions–can arise due to short circuits or
improper use. The protective circuit is located on the output
side of the component and recognizes high currents. This
arrangement protects both the DMOSFET on the output side
and the load circuit against overcurrent conditions. As soon
as a dangerous load current arises, the load circuit switches
off completely. It can be switched on again only after the input
signal has been reset.
Elevated Temperature Tolerance. The PhotoMOS protective
circuit can play a particularly important role when the relay
must perform at elevated operating temperatures. Because the
voltage drop across the shunt increases as rising temperatures
drive up resistance in the component, the protective circuit
responds to lower and lower current levels as temperatures rise.
In essence, it exhibits a negative temperature coefficient, which
allows it to offset the increased power dissipation associated
with elevated temperatures.
Reliability. Solid-state relays such as PhotoMOS shine
when it comes to reliability. Without the moving parts of an
electromechanical relay, solid-state relays typically have
an excellent mean time to failure (MTTF). In general, solid-
Panasonic Two Riverfront Plaza, 7th Floor, Newark, NJ 07102-5490 www.panasonic.com/industrial
state relays tolerate shock and vibration loads that threaten
electromechanical relays. Solid-state relays also eliminate the
buzzing that can affect electromechanical relays driven by PWM
and other methods intended to conserve input power.
Low operating cost. Solid-state relays may have a higher
price tag than electromechanical relays. The total cost over
the relay’s life-cycle, however, tips the scales back in favor of
solid-state technology. Most of the operating cost advantages
come from reductions in power consumption and a longer life-
cycle for fewer relay replacements. Factor in the cost benefit of
motor protection and the value proposition becomes even more
compelling. Keep in mind, too, that the savings can be greater in
applications that require the relay to remain in its closed state for
long periods of time. Solid-state relays can be operated closed
without the elevated temperatures and extra current draw of
their electromechanical counterparts.
Saves space, speeds development. Integrating the protective
mechanism in the relay, rather than relying on a separate
component, saves space. And it speeds development time
because there’s one less component to work into your design.
DESIGN TIP
Account For LED Power Losses To Maximize Relay Life
Optically-isolated relays inherently have a long lifespan,
thanks to their lack of moving parts and the robustness of
their solid-state electronics. You can, however, make them
last even longer by accounting for LED power losses.
Keep in mind that LED power does not remain constant over
time. Instead, all LEDs experience a power loss in proportion
to the time that current is applied to them. With optically-
isolated relays, including PhotoMOS, this loss of LED power
affects the device’s operating characteristics and lifecycle.
Rising Currents. As LED power falls, the relay’s operating
currents will rise accordingly. On a typical PhotoMOS relay,
for example, LED power might drop by roughly 3% after a 5
mA input current has been applied for 100,000 hours. As a
result, the relay’s operating (IFon) and turn off (IFoff) currents
would rise from their initial value by 3%.
This change in the electrical characteristics of the PhotoMOS
has lifecycle implications. As LED sensitivity degrades with
continued usage, more current is needed to generate the
same amount of light. This light is used to charge the gates
of internal MOSFETs and ultimately turn the relay on.
Slower Turn-On Time. The turn-on time of optically-isolated
relays slows as LED power falls. Going back to our example
of a 3% degradation of LED power after 100,000 hours at 5
mA, the turn-on time would likewise slow down by 3%. Put
differently, a PhotoMOS with a turn-on time of 0.03 mS out of
the box will have a turn-on time of 0.0309 mS after 100,000
hours of use at 5 mA.
This slowdown occurs because light intensity diminishes,
which reduces the voltage and current output of the photo
diode array in the IC. So it takes longer to bias the MOSFET
gates.
Elevated Temperature Effects. At elevated ambient
temperatures, more LED current is needed to generate the
same amount of lamination. This lamination will then be
converted to produce the necessary electrical voltage and
current to charge the gates of MOSFETs and maintain ON
state.
Careful design is required
to set up the series
limiting resistance of
the input LED to ensure
proper operation of the
relay across the operating
range of the relay.
In many applications, the
electrical change related
to optically-isolated
relays may not make a practical difference. Adding 3% to
an already fast on-time, for instance, won’t matter in every
application.
Yet even incremental changes in performance or lifecycle can
be significant in cutting edge applications. Examples include
high-speed test and measurement systems,
In these cases, the datasheet alone won’t tell you whether
you have picked the right relay for the job. You will have to
evaluate the relay based on the electrical characteristics
that will emerge after an extended period of operation that
corresponds to your application.
Load voltage: 400 V (DC)Load voltage: 400 V (DC)
Continuous load currContinuous load curr
ent: 120 mA (DC)ent: 120 mA (DC)
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0202
0404
0606
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0808
55
-20-20
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0.20.2
0.40.4
0.60.6
0.80.8
1.01.0
Ambient temperaturAmbient temperatur
e °Ce °C
LED turLED tur
n ofn of
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ent mAent mA
Panasonic Two Riverfront Plaza, 7th Floor, Newark, NJ 07102-5490 www.panasonic.com/industrial
DESIGN TIP
Calculating Input Resistance (RF) Correctly
DESIGN TIP
Calculating Mean Time To Failure
When calculating the correct RF value for the resistors used
with optically-isolated relays, make sure you take the forward
voltage (VF) into account.
Since the LED operating current increases as the temperature
rises, we must use the typical recommended IF value of 5 mA
at the maximum operating temperature of 85ºC to ensure
safe operation. The LED forward voltage (VF) depends on the
forward current (IF) and the temperature.
Let’s for example calculate the RF value for a popular
Panasonic optically-isolated relay, the AQV210 PhotoMOS.
Figure 1 shows the LED forward voltage versus ambient
temperature graph for the AQV210 PhotoMOS. The LED VF
with IF of 5 mA at 85ºC is 1.03 V.
The maximum RF value can be calculated as follows:
Assuming a 5%
tolerance and
a temperature
coefficient of 250
ppm (parts per
million) per ºC,
the appropriate RF
value will be the
next lower value
from the standard
resistors: RF=680
Ω. This margin will ensure
safe operation over the entire
temperature range. If the
supply voltage (Vcc) contains a
ripple, the lowest possible Vcc
value should be used for the
calculations.
Although power consumption and drive current for optically-
isolated relays are significantly lower than electromechanical
relays, some logic circuits can not drive the PhotoMOS
directly and require some additional components. Using
a transistor as a control mechanism to switch an external
power supply is one method that is typically used by circuit
designers.
In this scenario, the transistor is controlled by the output of
the logic circuit. When the transistor is turned on, it will create
a path to ground for the power supply Vcc thus turning on
the LED. When calculating the RF in this circuit, we must
account for the voltage drop, typically 0.4 to 0.7 V, between
the collector and the emitter of the transistor.
Using the same example of the AQV210 PhotoMOS, RF
can be calculated as follows: Assuming a 5% tolerance
and a temperature coefficient of 250 ppm per ºC, RF of 680
W can no longer guarantee safe operation over the entire
temperature range. In this case, use the next lower standard
resistor to ensure that RF is lower than the maximum allowed
value of 714 Ω: RF=560 Ω.
Mean Time To Failure (MTTF) equals 1/the failure rate λ.
λ is expressed in terms of failures per unit of time (FIT), where 1 FIT=1 failure per billion device hours.
The failure rate of Panasonic’s PhotoMOS optically-isolated relays is 20 FIT which means that MTTF is
1/(20*10*-9) based on the THB test per MIL HDBK-217F.
Based on the MTTF, expected time to first failure exceeds 50 million hours of operation.
0
02
04
06
08
08
5
-2
0
-4
0
1.0
1.1
1.2
1.3
1.4
Figur
e 1:
LED forwar
d voltage vs. ambient temperatur
e
Ambient temperatur
e °C
LED dr
opout voltage.
V
50m
50m
A
30m
30m
A
20m
20m
A
10m
10m
A
5mA
5mA
RF === 794Ω
Vcc - V
F
IFon
5V - 1.03V
5mA
Panasonic Two Riverfront Plaza, 7th Floor, Newark, NJ 07102-5490 www.panasonic.com/industrial
Part Number Builder
# Term Output Type V-load FunctionIsolation PKG. T/R-Tube
AQ ABCDEFGH
A
Y: 4 pin
V: 6 pin
W: 8 pin
S: 16 pin
Z: SIL 4
E
nil: Std
D: V Drive
E: Std
G: High Current
L: Current Limit
N: Low Cout
K: ShortCkt Prtctn
KL: SC Self Reset
M: SoftOn/Off
P: DAA
R: Low Ron
T: Optocoupler
T2: 2-Optocoupler
V: Varistor Prtctn
B
1: 1FA (DC)
2: 1FA (AC/DC)
4: 1FB (AC/DC)
6: 1FA/B (AC/DC)
Fnil: 1,500 V
H: 5,000 V
C
0: HF (Low Ron)
1: GU (General Use)
2: RF (Low Ron Low Co)
3: HS (High Sensitivity)
5: HE (Low Ron)
8: GU (General Use)
G
nil: DIP (Through Hole)
A: DIP (Surface Mount)
M: SON
S: SOP
T: VSSOP
V: SSOP
D
0: 350V
1: 30~40V
2: 60~80V
3: 250V
4: 400V
5: 100~150V
6: 600V
7: 200V
8: 1,500V
9: 1,000V
H
nil: Plastic Tube
W: T/R 3.5k
X: T/R 1k
Y: T/R 3.5k
Z: T/R 1k
PRODUCT GUIDE
Many Types of PhotoMOS Relays
More than 300 different types of PhotoMOS optically-isolated
relays are available to meet a wide variety of electrical and
package size requirements. The PhotoMOS products most
suited to motor protection and other industrial uses include:
AQZ207 SIL package with 1 A load current.
AQY277A DIP4 SMD with 0.65 A load current.
AQV252G with 2.5 A load current.
For test and measurement applications, consider our Low
CxR PhotoMOS Model AQY221N2M. It offers:
• Low capacitance of 1.1 pF. A laterally diffused metal-
oxide-semiconductor (MOSFET LDMOS) lowers the
relay’s capacitance.
• Low on-resistance of 9.5 ohm. A vertical-type double-
diffused metal-oxide-semiconductor (DMOS) limits the
relay’s on-resistance.
• Fast Switching and Physical Isolation. Thanks to the
low capacitance and on-resistance values, this relay
supports switching times as fast as 20 µs and provides
the isolation required to switch high-frequency load
signals.
• Linearity. Optical MOSFET-based relays like PhotoMOS
have highly linear input and output characteristics
that outshine those of alternatives such as Triacs or
OptoCouplers. PhotoMOS relays can also control small
analog signals without distortion, unlike Triacs and
Bipolar transistors whose offset voltages distort and clip
signals.
• Minimal Signal Propagation Delay. Measurement
applications benefit from a reduced length of internal
bonding and flat lead terminals, which results in reduced
signal propagation delay.
Besides using Low CxR PhotoMOS relays for switching
signals and I/O lines to devices being tested, these relays
may also be employed in data acquisition circuits. For
instance, they can be used to select the gain of operational
amplifiers. With the help of an optically-isolated relay, the
device’s digital control unit and the analog signal system can
be physically isolated, enhancing the precision of the device
by minimizing noise.