Fairchild AN-3012 High speed logic compatible Datasheet

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Application Note AN-3012
High Speed Logic Compatible, Half-Pitch Mini-Flat
Optocoupler, FODM8061
Introduction
FODM8061’s Electrical Operation
The FODM8061, a high-speed, high noise immunity
optocoupler, is constructed in a high insulation voltage SO5
mini-flat package. This optocoupler’s optical input uses an
aluminum gallium arsenide, AlGaAs, LED. The LED is
coupled to a high-speed bipolar integrated logic compatible
receiver. One major advantage of this product is that the high
speed optical IC is specified with guaranteed performance at
both 3.3V and 5V logic supplies. The optocoupler’s open
collector Schottky-clamped transistor output insures
compatibility with a wide range of logic families. The
optocoupler’s key AC and DC characteristics are guaranteed
over an operating temperature range of -40°C to +110°C.
The FODM8061 is a two chip optical hybrid. The input chip
is a high speed, low input current, infrared light emitting
diode, LED. The LED generates an optical flux in direct
relationship to the LED’s forward current, IF. The LED’s
output is coupled to a high speed bipolar optical receiver
through a low capacitance, “co-planar” optical coupling. The
receiver IC converts the optical energy into electrical current
and amplifies it to drive a load.
This application note highlights the key electrical and
switching performances of the high speed optocoupler,
FODM8061. It also explores the data communication signal
quality by examining the eye diagrams and the optocoupler’s
common usage in logic interfacing applications.
The SO5 Mini-Flat Package Improves
PCB Layout
The FODM8061 optocoupler is an enhanced version of the
industry standard 6N137. The 6N137 optocoupler’s package
is an 8-pin dual in-line DIP leadform configuration. [Refer to
the Fairchild Semiconductor Optocoupler Selection Catalog
for additional package selections.] The FODM8061’s
smaller SO5 package results in a more condensed PCB
footprint. This small footprint enhances multi-channel
packaging density without sacrificing channel-to-channel
and input-to-output insulation safety. This is a primary
consideration when isolation is needed for parallel and
bidirectional data communication and logic interfacing.
This package utilizes Fairchild's patented “Optoplanar®”
co-planar packaging technology. This packaging technology
enhances the superior common mode transient immunity of
the shielded optical integrated receiver.
This package has received Underwriter’s Laboratories
1577 (UL1577) safety approval for an insulation test voltage
(VISO) of 3,750Vac(RMS), and pending IEC60747-5-2
approval status. This mini-flat package is also compatible
with 260°C surface mount solder reflow assembly processes.
Figure 1 shows the block diagram of the FODM8061
optocoupler. The input consists of the anode and cathode
of an IR LED. This LED has a typical forward voltage, VF ,
of 1.45V when the forward current, IF , is 10mA. The photo
flux is coupled to a reverse-biased photodiode. The
photodiode generates a photocurrent which flows from its
anode into the bipolar amplifier. This linear amplifier has
a typical current gain of 60dB and a 40MHz bandwidth.
The output of this amplifier is a Schottky clamped opencollector NPN transistor. High levels of power supply and
common mode power noise rejection is insured by including
a bias and regulator circuit function. This circuit isolates the
photodiode from power supply, common mode noise that can
be coupled into the VCC, and output of the optocoupler.
Anode 1
Bias & Regulator
6 VCC
Amp
5 VO
Cathode 3
4 GND
Figure 1. FODM8061 Block Diagram
This optocoupler functions as a logic inverter. A logic input
signal which forces a forward current greater than 5mA
through the LED will cause the output transistor to sink
current supplied by an external load. Table 1 illustrates the
truth table for positive logic.
Table 1. Truth Table
LED
Output
Off
High
On
Low
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APPLICATION NOTE
The “Optoplanar” package increases the common mode
noise rejection by reducing the package and common mode
coupling capacitance, CCM. The CCM is further reduced by a
proprietary electric shield that covers the receiver IC. The
shield shunts common mode noise away from the input of
the optical amplifier to the ground connection of the optical
amplifier. This shield is shown as the dotted line between the
LED and receiver IC. The combination of “Optoplanar”
construction and the electric shield provides a common
mode transient immunity, CMTI, in excess of 20kV/us for a
1kV pulse. More details are discussed in application note,
“Common Mode Transient Immunity (CMTI) of High
Performance Optocoupler”
ICE – COLLECTOR-EMITTER CURRENT (mA)
AN-3012
ICE – COLLECTOR-EMITTER CURRENT (mA)
70
60
50
40
30
20
IF = 1mA
0
1.0
2.0
3.0
VCE = 1.5V
40
30
20
VCE = 0.4V
10
0
2.0
4.0
6.0
8.0
4.0
5.0
VCE – COLLECTOR-EMITTER VOLTAGE (V)
Figure 3. Saturated & Non-Saturated ICE vs IF
Figure 4 shows the saturated and non-saturated CTR for the
FODM8061. This curve illustrates the consistency of the
saturated CTR (approx 160%) over an LED forward current
of 4mA through 10mA. This curve can be used to estimate
the minimum LED current required to force a specific load
into saturation at a given operating VCC. The data sheet uses
a 350Ω collector load resistor for most of the switching
specifications. If the VCC is 3.3V, then the saturated,
(VCE = 0.4V) ICE is 8.3mA for a 350Ω load. The saturated
CTR from Figure 4 is 160%. Recall that the LED current is
equal to the ICE divided by the CTR, or 8.3mA/160%.
Given this, the LED current should be 5.2mA or greater to
insure a logic level low at room temperature. When the
VCC is increased to 5V and the same load is used, the LED
current must be increased to insure saturated operation.
With VCC = 5V, the 350Ω load current is 13mA. Again,
assuming a typical saturated CTR (VCE = 0.4V) of 160%,
the LED current should be 8.2mA or greater.
Figure 2. ICE vs VCE Family , IF = 1mA steps
700
CTR – CURRENT TRANSFER RATIO (%)
Figure 2 shows the family of collector-emitter current, ICE,
vs collector-emitter voltage, VCE , as a function of LED
forward current, IF . The LED is stepped in 1mA increments.
Figure 2 shows the near linear operation for LED current
operation from 1mA through 4mA. Figure 3 sweeps the LED
current and shows the resulting collector current under the
linear (VCE = 1.5V, upper curve)) and saturated
(VCE = 0.4V, lower curve) operation. Note that the output
ICE when in saturation (VCE = 0.4V) is 8.05mA with a LED
current of 5mA. The non saturated ICE is 33mA under the
same LED drive. This difference in output current is a
function of the output transistor, not the photo-amplifier.
VCE(UNSAT)
600
500
400
300
200
VCE(SAT)
100
0
0
2.0
4.0
6.0
8.0
IF – FORWARD CURRENT (mA)
Figure 4. Saturated and non-saturated CTR
2
10.0
IF – FORWARD CURRENT (mA)
The FODM8061 is an optocoupler that includes a linear
amplifier that drives the output transistor into saturation.
Given this characteristic, it is appropriate to discuss current
transfer ratio under non saturated and saturated VCE
conditions.
0
50
0
Current Transfer Ratio
10
60
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10.0
APPLICATION NOTE
AN-3012
The data sheet offers a minimum CTR of 260% and a typical
CTR of 380% for VCE = 6V. This data is consistent with the
expected CTR sensitivity to VCE operation as presented in
Figure 4.
LED Forward Current Switching
Threshold
VCE – COLLECTOR-EMITTER VOLTAGE (V)
The CTR of the FODM8061 can be discussed in terms of
an LED threshold current. Figure 5 illustrates the required
LED current for an IOL of 10mA, under the condition of
VCC = 3.3V (lower curve) and 5V (upper curve). These
curves illustrate that VCC has a minor effect on the LED
switching threshold.
Switching Performance
The FODM8061 is an optocoupler that contains a linear
optical amplifier which is designed to function as an isolated
logic inverter. The switching performance of the FODM8061
optocoupler is quantified in terms of propagation delay,
pulse width distortion, and pulse skew.
6
IF = 7.5mA
5
VCC = 3.3V
3
6
R1
100Ω
5
2
R3
350Ω
VO – Output
R2
100Ω
15pF
3
1
VCC = 3.3V, 5V
C1
0.1µF
Pulse
Generator
ZO = 50Ω
tR = tF = 5ns
Period =
200ns
DF = 50%
4
4
Figure 7. Switching Test Circuit
0
1.0
2.0
3.0
4.0
5.0
IF – FORWARD CURRENT (mA)
Figure 5. LED Threshold Current at VCC= 3.3 and 5V
The threshold does have modest temperature dependence.
This is shown in Figure 6.
6
1
VCC = 5V
0
IOL = 13mA
Propagation delay through this optocoupler is related to peak
LED drive, power supply voltage, load resistor, and
temperature. As shown in Figure 7, this device is optimized
for operation with 7.5mA of LED drive, a 5V supply voltage,
and a 350Ω load resistor. Under this condition, a typical
device offers a symmetrical high-to-low and low-to- high
propagation delay of approximately 36ns. Figure 8 shows the
typical delay performance over the recommended operating
temperature range of -40ºC to 110ºC.
70
5
4
t P – PROPAGATION DELAY (ns)
IFHT – THRESHOLD INPUT CURRENT (mA)
The LED’s light output will decrease with increased junction
temperature when driven by a constant drive current. The
photo amplifier’s DC gain increases with increased ambient
temperature. In most cases, these two relationships are
designed to cancel each other, as is the case for the
FODM8061.
VCC = 5.0V
VCC = 3.3V
3
2
1
-40
-20
0
20
40
60
80
TA – AMBIENT TEMPERATURE (°C)
100
Figure 6. Input Threshold Current vs.
Ambient Temperature
Frequency = 5MHz
Duty Cycle = 50%
IF = 10mA
RL = 350Ω
60
50
tPLH @ VCC = 3.3V
tPLH @ VCC = 5.0V
40
tPHL @ VCC = 3.3V
t PHL@ VCC = 5.0V
120
30
-40
-20
0
20
40
60
80
100
120
TA – AMBIENT TEMPERATURE (°C)
Figure 8. Propagation Delay vs Temperature
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3
AN-3012
APPLICATION NOTE
Figure 9 provides insight on how the pulse width distortion
changes with temperature. The typical pulse width
distortion, PWD, [tPHL – tPLH] is 2ns. These performance
characteristics allow high serial data (> 20Mbaud)
communication through the optocoupler.
(tPHL – tPLH) – PULSE WIDTH DISTORTION (ns)
10
Frequency = 5MHz
Duty Cycle = 50%
IF = 10mA
RL= 350Ω
5
0
VCC = 5.0V
Signal Performance
One of the best indicators of data communication signal
quality is an eye diagram. The eye diagram is created by
driving the LED with a pseudorandom binary data sequence,
PRBS, and triggering the scope with the serial data clock.
Figure 10 shows a 10MBd eye diagram using the test circuit
found in Figure 7. This diagram shows a duty cycle
distortion of only 2.18ns. This is very close to the typical
PWD of 2ns. The LED current was adjusted for optimal
crossing, under this condition, the rise and fall times are
symmetrical and less than 20ns.
-5
VCC = 3.3V
-10
-15
-20
-25
-40
-20
0
20
40
60
80
100
120
TA – AMBIENT TEMPERATURE (°C)
Figure 9. Pulse Width Distortion vs Temperature
There are various assumptions which are made in relation
of switching speed to baud rate, such as binary
Non-Return-Zero (NRZ) data stream, 1 bit time equating
1 baud (or signaling rate) and a square wave pattern.
Therefore, a 5MHz square wave (duty factor of 50%) is a
10Mbit or 10MBaud signal.
For serial communications (RS standards), propagation
delay only affects latency or data throughput. The maximum
data rate is related to PWD performance and the number of
samples per bit used by the UART to validate the 1 or 0 data.
The minimum acceptable sample rate is 4, which is half the
Nyquist recommended rate. Thus, the recommended
maximum data rate is usually 4 times that of the PWD. In the
case of FODM8061, with a maximum PWD of 25ns the
maximum data rate is 10MBd.
Ideally, the delay skew, tPSK, should be specified at about
2 times the maximum PWD. It is important to note that
tPSK is equal to the magnitude of the worst case difference
in tPHL and/or tPLH that will be seen between any two units
from the same manufacturing date code that are operated
at same operating conditions; same case temperature, equal
loads (RL = 350Ω and CL = 15pF), and with an input rise
time less than 5ns.
4
Figure 10. 10MBd Eye Diagram
Figure 11 illustrates the typical and respectable eye diagram
for 20MBd PRBS data.
Figure 11. 20MBd Eye Diagram
REV. 1.0 3/9/10
APPLICATION NOTE
AN-3012
Output Power Consumption versus
Propagation Delay
When a non-inverting interface is needed, the LED shunt
drive is used. This circuit schematic is shown in Figure 14.
tpHL, tpLH – PROPAGATION DELAY (ns)
The passive resistive pull-up resistor does dissipate power
when the output of the optocoupler is switched into the logic
low state. Increasing the collector load resistor does reduce
power consumption at the price of longer turn-off delay and
larger pulse width distortion. Figure 12 shows the expected
increase propagation delay from the logic low to logic high.
VDD1 = 3.0V–3.6V
C1
0.1µF
VDD2 = 3.3V–5V
Input
160
tA = 23°C
VCC = 3.3V
IF = 10mA
Period = 1ms
PW = 100µs
140
R1
220Ω
1
6
R2
350Ω
74LCX07
Output
5
120
tpLH (ns)
100
C2
0.1µF
3
80
4
FODM8061
tpHL (ns)
60
Figure 14. Non-inverting Logic interface
40
0
2
4
6
8
RLOAD – COLLECTOR LOAD RESISTOR (kΩ)
10
12
Figure 12. Propagation vs Collector Load Resistor
Logic Interfacing
The FODM8061 is a versatile logic-to-logic interface
optocoupler. The low forward voltage of the LED permits
operation among logic families with supply ranges from
2.3V to 15V. Figure 13 shows an inverting interface between
a 3V 74LCX07 open drain buffer to output logic families
from 3.3V to 5V. The current to the LED is set by R1 (82Ω)
to approximately 10mA. R2 (430Ω) provides the pull-up
needed by the open drain ’07 gate.
VDD1 = 3.0V–3.6V
VDD2 = 3.3V–5V
1
6
C1
100nF
R3
350Ω
R2
430Ω
R1
82Ω
Input
Interface Circuit for VCC Greater
than 5.5V
Industrial systems today still use the 15V CD4xxx logic
gates, which offer exceptional logic noise immunity, mainly
due to their high switching thresholds and slow operating
speed. When a low voltage high speed optocoupler is needed
to interface into logic families with supply voltages greater
than 5.5V, a buffer transistor is needed. Figure 15 shows the
use of a cascode amplifier interface, which uses an
inexpensive bipolar 2N2222 NPN transistor with a Schottky
“Baker Clamp”. This circuit switches a 25mA load from a
25V supply. The cascode circuit maintains the same logic
sense as the original optocoupler interface and as Figure 20
shows the rise and fall times, and the propagation delays well
under 100ns. The 5V supply voltage of the optocoupler can
be supplied by a Zener diode, from a regulated supply.
C2
100nF
3
74LCX07
Output
5
The output transistor of the 74LCX07 shunts the drive
current away from the LED when its output is forced low.
This type of interface offers the lowest LED off-state
impedance resulting in improved LED noise immunity.
4
FODM8061
Figure 13. Inverting Series LED drive
REV. 1.0 3/9/10
5
AN-3012
APPLICATION NOTE
V = 25V
C3
22µF
C2
0.1µF
D1
1N5712
R4
1k2Ω
Output
Q1
2N222
R3
220Ω
1
LED Current = 10mA
6
VCC = 5.0V
C1
0.1µF
R1
100Ω
5
R2
100Ω
3
4
FODM8061
Figure 15. Bipolar Cascode Interface
Figure 16. Bipolar HV Cascode Timing
6
REV. 1.0 3/9/10
APPLICATION NOTE
AN-3012
Interfacing to Voltages Greater than 25V
Using a high voltage low current signal MOSFET, it is
possible to drive loads with supply voltages much greater
than 25V. The BSS123 can be used for supplies up to 100V.
If higher interface voltages are needed the BSS125 can
support supplies to 600V.
Figure 17 shows a MOSFET cascode interface operating
from a 50V source. The load current is 25mA. The 5V
supply voltage needed by the FODM8061 can be supplied
from an external regulated power supply or via a Zener or
other regulator deriving its power from the high voltage
source.
V = 25V
C3
22µF
C2
0.1µF
R4
2kΩ
Output
D
G
BSS123
1
LED Current = 10mA
6
VCC = 5.0V
R3
1kΩ
R1
100Ω
S
C1
0.1µF
5
R2
100Ω
3
4
FODM8061
Figure 17. Optocoupler MOSFET Cascode Interface
Figure 18 shows the timing performance of the MOSFET
high voltage cascode interface. The dv/dt of the leading
falling edge is about 1.5kV/µs, which is a respectable
transition time.
Conclusion
The FODM8061 high speed optocoupler is an easy to use,
multi-purpose optocoupler ideal for isolating communication
links with bandwidths of 10MBaud. The FOM8061’s
compact package and proven reliable galvanic isolation
makes it ideal ensuring safe operation in terms of both safety
and signal integrity.
Figure 18. HV MOSFET Cascode Interface
REV. 1.0 3/9/10
7
AN-3012
APPLICATION NOTE
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