ETC HCPL-7710#060

40 ns Propagation Delay,
CMOS Optocoupler
Technical Data
HCPL-7710
HCPL-0710
Features
Applications
• +5 V CMOS Compatibility
• 8 ns max. Pulse Width
Distortion
• 20 ns max. Prop. Delay Skew
• High Speed: 12 MBd
• 40 ns max. Prop. Delay
• 10 kV/µs Minimum Common
Mode Rejection
• –40 to 100°C Temp. Range
• Safety and Regulatory
Approvals
UL Recognized
2500 V rms for 1 min. per
UL 1577 for HCPL-0710
3750 V rms for 1 min. per
UL 1577 for HCPL-7710
CSA Component Acceptance
Notice #5
VDE 0884 Approved (VDE)
– VIORM = 630 Vpeak for
HCPL-7710 Option 060
VDE 0884 (TUV)
– VIORM = 560 Vpeak for
HCPL-0710 Option 060
• Digital Fieldbus Isolation:
DeviceNet, SDS, Profibus
• AC Plasma Display Panel
Level Shifting
• Multiplexed Data
Transmission
• Computer Peripheral
Interface
• Microprocessor System
Interface
Functional Diagram
**VDD1
1
8
VDD2**
VI
2
7
NC*
*
3
6
VO
5
GND2
IO
LED1
GND1
4
SHIELD
Description
Available in either an 8-pin DIP or
SO-8 package style respectively,
the HCPL-7710 or HCPL-0710
optocouplers utilize the latest
CMOS IC technology to achieve
outstanding performance with
very low power consumption. The
HCPL-x710 require only two
bypass capacitors for complete
CMOS compatibility.
Basic building blocks of the
HCPL-x710 are a CMOS LED
driver IC, a high speed LED and a
TRUTH TABLE
(POSITIVE LOGIC)
VI, INPUT
LED1
VO, OUTPUT
H
L
OFF
ON
H
L
CMOS detector IC. A CMOS logic
input signal controls the LED
driver IC which supplies current
to the LED. The detector IC
incorporates an integrated
photodiode, a high-speed
transimpedance amplifier, and a
voltage comparator with an
output driver.
*Pin 3 is the anode of the internal LED and must be left unconnected for guaranteed data sheet performance.
Pin 7 is not connected internally.
**A 0.1 µF bypass capacitor must be connected between pins 1 and 4, and 5 and 8.
CAUTION: It is advised that normal static precautions be taken in handling and assembly of this
component to prevent damage and/or degradation which may be induced by ESD.
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2
Selection Guide
8-Pin DIP
(300 Mil)
HCPL-7710
Small Outline
SO-8
HCPL-0710
Ordering Information
Specify Part Number followed by Option Number (if desired)
Example
HCPL-7710#XXX
060 = VDE0884 Option.
300 = Gull Wing Surface Mount Option (HCPL-7710 only).
500 = Tape and Reel Packaging Option.
No Option and Option 300 contain 50 units (HCPL-7710), 100 units (HCPL-0710) per tube.
Option 500 contain 1000 units (HCPL-7710), 1500 units (HCPL-0710) per reel.
Option data sheets available. Contact Agilent sales representative or authorized distributor.
Package Outline Drawing
HCPL-7710 8-Pin DIP Package
9.65 ± 0.25
(0.380 ± 0.010)
TYPE NUMBER
8
7
6
7.62 ± 0.25
(0.300 ± 0.010)
5
OPTION 060 CODE*
6.35 ± 0.25
(0.250 ± 0.010)
DATE CODE
A XXXXV
YYWW
1
2
3
1.19 (0.047) MAX.
4
1.78 (0.070) MAX.
5° TYP.
4.70 (0.185) MAX.
+ 0.076
0.254 - 0.051
+ 0.003)
(0.010 - 0.002)
0.51 (0.020) MIN.
2.92 (0.115) MIN.
1.080 ± 0.320
(0.043 ± 0.013)
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0.65 (0.025) MAX.
2.54 ± 0.25
(0.100 ± 0.010)
DIMENSIONS IN MILLIMETERS AND (INCHES).
*OPTION 300 AND 500 NOT MARKED.
3
Package Outline Drawing
HCPL-7710 Package with Gull Wing Surface Mount Option 300
PAD LOCATION (FOR REFERENCE ONLY)
9.65 ± 0.25
(0.380 ± 0.010)
8
1.016 (0.040)
1.194 (0.047)
6
7
5
4.826 TYP.
(0.190)
6.350 ± 0.25
(0.250 ± 0.010)
1
3
2
9.398 (0.370)
9.906 (0.390)
4
1.194 (0.047)
1.778 (0.070)
9.65 ± 0.25
(0.380 ± 0.010)
1.780
(0.070)
MAX.
1.19
(0.047)
MAX.
0.381 (0.015)
0.635 (0.025)
7.62 ± 0.25
(0.300 ± 0.010)
4.19 MAX.
(0.165)
1.080 ± 0.320
(0.043 ± 0.013)
0.635 ± 0.25
(0.025 ± 0.010)
0.635 ± 0.130
2.54
(0.025 ± 0.005)
(0.100)
BSC
DIMENSIONS IN MILLIMETERS (INCHES).
LEAD COPLANARITY = 0.10 mm (0.004 INCHES).
+ 0.076
0.254 - 0.051
+ 0.003)
(0.010 - 0.002)
12° NOM.
Package Outline Drawing
HCPL-0710 Outline Drawing (Small Outline SO-8 Package)
8
7
6
5
5.842 ± 0.203
(0.236 ± 0.008)
710V
YWW
3.937 ± 0.127
(0.155 ± 0.005)
OPTION 060 CODE*
TYPE NUMBER (LAST 3 DIGITS)
PIN 1
ONE
2
3
0.381 ± 0.076
(0.016 ± 0.003)
DATE CODE
4
1.270 BSG
(0.050)
7°
5.080 ± 0.005
(0.200 ± 0.005)
3.175 ± 0.127
(0.125 ± 0.005)
45° X 0.432
(0.017)
0.228 ± 0.025
(0.009 ± 0.001)
1.524
(0.060)
0.152 ± 0.051
(0.006 ± 0.002)
DIMENSIONS IN MILLIMETERS AND (INCHES).
LEAD COPLANARITY = 0.10 mm (0.004 INCHES).
*OPTION 500 NOT MARKED.
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0.305
MIN.
(0.012)
4
TEMPERATURE – °C
Solder Reflow Thermal Profile
260
240
220
200
180
160
∆T = 145°C, 1°C/SEC
∆T = 115°C, 0.3°C/SEC
140
120
100
80
∆T = 100°C, 1.5°C/SEC
60
40
20
0
0
1
2
3
4
5
6
7
8
9
10
11
12
TIME – MINUTES
(NOTE: USE OF NON-CHLORINE ACTIVATED FLUXES IS RECOMMENDED.)
Regulatory Information
CSA
Approved under CSA Component
Acceptance Notice #5,
File CA 88324.
The HCPL-x710 have been
approved by the following
organizations:
UL
Recognized under UL 1577,
component recognition program,
File E55361.
TUV Rheinland
(HCPL-0710 Option 060)
Approved according to
VDE 0884/06.92,
Certificate R9650938.
VDE
(HCPL-7710 Option 060)
Approved according to
VDE 0884/06.92,
File 6591.23-4880-1005.
Insulation and Safety Related Specifications
Parameter
Minimum External Air
Gap (Clearance)
Minimum External
Tracking (Creepage)
Symbol
L(I01)
L(I02)
Minimum Internal Plastic
Gap (Internal Clearance)
Tracking Resistance
(Comparative Tracking
Index)
Isolation Group
CTI
All Agilent data sheets report the
creepage and clearance inherent
to the optocoupler component
itself. These dimensions are
needed as a starting point for the
equipment designer when
determining the circuit insulation
requirements. However, once
mounted on a printed circuit
Value
7710 0710
7.1
4.9
Units
mm
7.4
4.8
mm
0.08
0.08
mm
≥ 175
≥ 175
Volts
IIIa
IIIa
Conditions
Measured from input terminals to output
terminals, shortest distance through air.
Measured from input terminals to output
terminals, shortest distance path along
body.
Insulation thickness between emitter and
detector; also known as distance through
insulation.
DIN IEC 112/VDE 0303 Part 1
Material Group (DIN VDE 0110, 1/89,
Table 1)
board, minimum creepage and
clearance requirements must be
met as specified for individual
equipment standards. For
creepage, the shortest distance
path along the surface of a
printed circuit board between the
solder fillets of the input and
output leads must be considered.
There are recommended
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techniques such as grooves and
ribs which may be used on a
printed circuit board to achieve
desired creepage and clearances.
Creepage and clearance distances
will also change depending on
factors such as pollution degree
and insulation level.
5
VDE 0884 Insulation Related Characteristics (Option 060)
Description
Installation classification per DIN VDE 0110/1.89,
Table 1
for rated mains voltage ≤ 150 V rms
for rated mains voltage ≤ 300 V rms
for rated mains voltage ≤ 450 V rms
Climatic Classification
Pollution Degree (DIN VDE 0110/1.89)
Maximum Working Insulation Voltage
Input to Output Test Voltage, Method b†
VIORM x 1.875 = VPR , 100% Production
Test with tm = 1 sec, Partial Discharge < 5 pC
Input to Output Test Voltage, Method a†
VIORM x 1.5 = VPR, Type and Sample Test,
tm = 60 sec, Partial Discharge < 5 pC
Highest Allowable Overvoltage†
(Transient Overvoltage, tini = 10 sec)
Safety Limiting Values
(Maximum values allowed in the event of a failure,
also see Thermal Derating curve, Figure 11.)
Case Temperature
Input Current
Output Power
Insulation Resistance at TS, V10 = 500 V
Symbol
HCPL-7710
Option 060
HCPL-0710
Option 060
I-IV
I-III
VIORM
VPR
I-IV
I-IV
I-III
55/100/21
2
630
1181
55/100/21
2
560
1050
V peak
V peak
VPR
945
840
V peak
VIOTM
6000
4000
V peak
TS
IS,INPUT
PS,OUTPUT
RIO
175
230
600
≥ 109
150
150
600
≥ 109
°C
mA
mW
Ω
Units
†Refer to the front of the optocoupler section of the Isolation and Control Component Designer’s Catalog, under Product Safety
Regulations section (VDE 0884), for a detailed description.
Note: These optocouplers are suitable for “safe electrical isolation” only within the safety limit data. Maintenance of the safety data
shall be ensured by means of protective circuits.
Note: The surface mount classification is Class A in accordance with CECC 00802.
Absolute Maximum Ratings
Parameter
Storage Temperature
Ambient Operating Temperature
Supply Voltages
Input Voltage
Output Voltage
Input Current
Average Output Current
Lead Solder Temperature
Solder Reflow Temperature Profile
Symbol
Min.
Max.
Units
Figure
TS
–55
125
°C
TA
–40
+100
°C
VDD1, VDD2
0
5.5
Volts
VI
–0.5
VDD1 +0.5
Volts
VO
–0.5
VDD2 +0.5
Volts
II
–10
+10
mA
IO
10
mA
260°C for 10 sec., 1.6 mm below seating plane
See Solder Reflow Temperature Profile Section
Recommended Operating Conditions
Parameter
Ambient Operating Temperature
Supply Voltages
Logic High Input Voltage
Logic Low Input Voltage
Input Signal Rise and Fall Times
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Symbol
TA
VDD1, VDD2
VIH
VIL
t r, t f
Min.
–40
4.5
2.0
0.0
Max.
+100
5.5
VDD1
0.8
1.0
Units
°C
V
V
V
ms
Figure
1, 2
6
Electrical Specifications
Test conditions that are not specified can be anywhere within the recommended operating range.
All typical specifications are at TA = +25°C, VDD1 = VDD2 = +5 V.
Parameter
DC Specifications
Logic Low Input
Supply Current
Logic High Input
Supply Current
Input Supply Current
Output Supply Current
Input Current
High Output
Logic High
Output
Voltage
Logic Low Output
Output
Voltage
Voltage
Symbol
Min.
Typ.
Max. Units
Test Conditions
IDD1L
6.0
10.0
mA
VI = 0 V
IDD1H
1.5
3.0
mA
VI = VDDI
5.5
13.0
11.0
10
mA
mA
µA
V
IDD1
IDD2
II
VOH
–10
4.4
4.0
VOL
Switching Specifications
Propagation Delay Time
tPHL
to Logic Low Output
Propagation Delay Time
tPLH
to Logic High Output
Pulse Width
PW
Data Rate
Pulse Width Distortion
PWD
|tPHL - tPLH|
Propagation Delay Skew
tPSK
Output Rise Time
tR
(10 - 90%)
Output Fall Time
tF
(90 - 10%)
Common Mode
|CMH|
Transient Immunity at
Logic High Output
Common Mode
|CM L|
Transient Immunity at
Logic Low Output
Input Dynamic Power
CPD1
Dissipation
Capacitance
Output Dynamic Power
CPD2
Dissipation
Capacitance
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5.0
4.8
0
0.5
0.1
1.0
V
20
40
ns
23
40
3
12.5
8
Fig. Note
1
IO = –20 µA, VI = VIH 1, 2
IO = -4 mA, VI = VIH
IO = 20 µA, VI = VIL
IO = 4 mA, VI = VIL
CL = 15 pF
CMOS Signal Levels
3, 7
80
2
3
MBd
ns
4, 8
20
5
9
CL = 15 pF
CMOS Signal Levels
8
10
20
10
20
60
10
4
5, 9
6,
10
kV/µs VI = VDD1, VO >
0.8 VDD1,
VCM = 1000 V
VI = 0 V, VO > 0.8 V,
VCM = 1000 V
pF
6
7
7
Package Characteristics
Parameter
Input-Output Momentary
Withstand Voltage
Symbol Min. Typ. Max. Units
0710
VISO
2500
Vrms
7710
Resistance
(Input-Output)
Capacitance
(Input-Output)
Input Capacitance
Input IC Junction-to-Case -7710
Thermal Resistance
-0710
Output IC Junction-to-Case -7710
Thermal Resistance
-0710
Package Power Dissipation
Notes:
1. The LED is ON when VI is low and OFF
when VI is high.
2. tPHL propagation delay is measured
from the 50% level on the falling edge
of the VI signal to the 50% level of the
falling edge of the VO signal. tPLH
propagation delay is measured from
the 50% level on the rising edge of the
VI signal to the 50% level of the rising
edge of the VO signal.
3. Mimimum Pulse Width is the shortest
pulse width at which 10% maximum,
Pulse Width Distortion can be guaranteed. Maximum Data Rate is the
inverse of Minimum Pulse Width.
Operating the HCPL-x710 at data rates
above 12.5 MBd is possible provided
PWD and data dependent jitter
increases and relaxed noise margins
are tolerable within the application.
For instance, if the maximum
allowable variation of bit width is 30%,
the maximum data rate becomes 37.5
MBd. Please note that HCPL-x710
RI-O
1012
Ω
Test Conditions Fig.
RH ≤ 50%,
t = 1 min.,
TA = 25°C
VI-O = 500 Vdc
CI-O
0.6
pF
f = 1 MHz
CI
θjci
3.0
145
160
140
135
3750
θjco
PPD
Note
8, 9,
10
8
11
°C/W
150
Thermocouple
located at center
underside of
package
mW
performances above 12.5 MBd are not
guaranteed by Hewlett-Packard.
4. PWD is defined as |t PHL - tPLH|.
%PWD (percent pulse width distortion)
is equal to the PWD divided by pulse
width.
5. t PSK is equal to the magnitude of the
worst case difference in t PHL and/or
t PLH that will be seen between units at
any given temperature within the
recommended operating conditions.
6. CMH is the maximum common mode
voltage slew rate that can be sustained
while maintaining VO > 0.8 VDD2. CML
is the maximum common mode voltage
slew rate that can be sustained while
maintaining VO < 0.8 V. The common
mode voltage slew rates apply to both
rising and falling common mode
voltage edges.
7. Unloaded dynamic power dissipation is
calculated as follows: C PD * VDD2 * f +
I DD * VDD, where f is switching
frequency in MHz.
8. Device considered a two-terminal
device: pins 1, 2, 3, and 4 shorted
together and pins 5, 6, 7, and 8
shorted together.
9. In accordance with UL1577, each
HCPL-0710 is proof tested by applying
an insulation test voltage ≥ 3000 VRMS
for 1 second (leakage detection
current limit, II-O ≤ 5 µA). Each HCPL7710 is proof tested by applying an
insulation test voltage ≥ 4500 V rms
for 1 second (leakage detection
current limit, II-O ≤ 5 µA).
10. The Input-Output Momentary Withstand Voltage is a dielectric voltage
rating that should not be interpreted as
an input-output continuous voltage
rating. For the continuous voltage
rating refer to your equipment level
safety specification or HP Application
Note 1074 entitled “Optocoupler
Input-Output Endurance Voltage.”
11. CI is the capacitance measured at pin
2 (VI).
2.2
0 °C
25 °C
85 °C
3
2
27
1.9
1.8
1
0
29
0 °C
25 °C
85 °C
2.0
VITH (V)
4
VO (V)
2.1
TPLH, TPHL (ns)
5
1.7
0
1
2
3
4
1.6
4.5
5
VI (V)
Figure 1. Typical Output Voltage vs.
Input Voltage.
TPLH
23
TPHL
21
19
17
4.75
5
5.25
5.5
VDD1 (V)
Figure 2. Typical Input Voltage
Switching Threshold vs. Input Supply
Voltage.
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25
15
0
10
20 30
40
50
60 70
80
TA (C)
Figure 3. Typical Propagation Delays
vs. Temperature.
8
4
7
11
6
3
2
TF (ns)
TR (ns)
PWD (ns)
10
5
4
9
1
0
3
20
0
40
60
8
80
20
0
40
TA (C)
60
80
21
19
5
25
17
15
21
TPLH
TR (ns)
4
TPHL
23
PWD (ns)
TPLH, TPHL (ns)
40
Figure 6. Typical Fall Time vs.
Temperature.
6
27
3
2
19
13
11
9
7
5
17
1
15
15
0
15
3
20
25
30
35
40
45
50
20
25
CI (pF)
8
7
6
5
4
3
2
1
15
20
40
45
50
0
5
10
25
30
35
20
25
30
35
CI (pF)
Figure 8. Typical Pulse Width
Distortion vs. Output Load
Capacitance.
Figure 9. Typical Rise Time vs. Load
Capacitance.
STANDARD 8 PIN DIP PRODUCT
800
PS (mW)
IS (mA)
700
600
500
400
300
(230)
200
CI (pF)
Figure 10. Typical Fall Time vs. Load
Capacitance.
15
OUTPUT POWER – PS, INPUT CURRENT – IS
9
10
35
OUTPUT POWER – PS, INPUT CURRENT – IS
10
5
30
1
CI (pF)
Figure 7. Typical Propagation Delays
vs. Output Load Capacitance.
FALL TIME (ns)
20
0
TA (C)
Figure 5. Typical Rise Time vs.
Temperature.
29
0
2
80
TA (C)
Figure 4. Typical Pulse Width
Distortion vs. Temperature.
0
60
100
0
0
25
50
75 100 125 150 175 200
TA – CASE TEMPERATURE – °C
SURFACE MOUNT SO8 PRODUCT
800
PS (mW)
IS (mA)
700
600
500
400
300
200
(150)
100
0
0
25
50
75 100 125 150 175 200
TA – CASE TEMPERATURE – °C
Figure 11. Thermal Derating Curve, Dependence of Safety Limiting Value with
Case Temperature per VDE 0884.
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9
Application Information
technology allowing CMOS logic
to be connected directly to the
inputs and outputs.
Bypassing and PC Board
Layout
The HCPL-x710 optocouplers are
extremely easy to use. No
external interface circuitry is
required because the HCPL-x710
use high-speed CMOS IC
VDD1
As shown in Figure 12, the only
external components required for
proper operation are two bypass
capacitors. Capacitor values
should be between 0.01 µF and
VDD2
8
1
0.1 µF. For each capacitor, the
total lead length between both
ends of the capacitor and the
power-supply pins should not
exceed 20 mm. Figure 13
illustrates the recommended
printed circuit board layout for
the HPCL-x710.
C1
C2
VI
710
YWW
2
NC 3
GND1
7 NC
6
VO
5
4
GND2
C1, C2 = 0.01 µF TO 0.1 µF
Figure 12. Recommended Printed Circuit Board Layout.
VDD1
VDD2
710
YWW
VI
C1
C2
VO
GND1
GND2
C1, C2 = 0.01 µF TO 0.1 µF
Figure 13. Recommended Printed Circuit Board Layout.
Propagation Delay, PulseWidth Distortion and
Propagation Delay Skew
Propagation Delay is a figure of
merit which describes how
quickly a logic signal propagates
through a system. The propaga-
tion delay from low to high (tPLH)
is the amount of time required for
an input signal to propagate to
the output, causing the output to
change from low to high.
Similarly, the propagation delay
from high to low (tPHL) is the
INPUT
VI
50%
5 V CMOS
0V
tPLH
OUTPUT
VO
90%
tPHL
90%
10%
Figure 14.
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10%
VOH
2.5 V CMOS
VOL
amount of time required for the
input signal to propagate to the
output, causing the output to
change from high to low. See
Figure 14.
10
Pulse-width distortion (PWD) is
the difference between tPHL and
tPLH and often determines the
maximum data rate capability of a
transmission system. PWD can be
expressed in percent by dividing
the PWD (in ns) by the minimum
pulse width (in ns) being transmitted. Typically, PWD on the
order of 20 - 30% of the minimum
pulse width is tolerable. The PWD
specification for the HCPL-x710
is 8 ns (10%) maximum across
recommended operating conditions. 10% maximum is dictated
by the most stringent of the three
fieldbus standards, PROFIBUS.
Propagation delay skew, tPSK, is
an important parameter to consider in parallel data applications
where synchronization of signals
VI
on parallel data lines is a concern.
If the parallel data is being sent
through a group of optocouplers,
differences in propagation delays
will cause the data to arrive at the
outputs of the optocouplers at
different times. If this difference
in propagation delay is large
enough it will determine the
maximum rate at which parallel
data can be sent through the
optocouplers.
Propagation delay skew is defined
as the difference between the
minimum and maximum propagation delays, either t PLH or tPHL,
for any given group of optocouplers which are operating under
the same conditions (i.e., the
same drive current, supply voltage, output load, and operating
temperature). As illustrated in
Figure 15, if the inputs of a group
of optocouplers are switched
either ON or OFF at the same
time, tPSK is the difference
between the shortest propagation
delay, either tPLH or tPHL, and the
longest propagation delay, either
tPLH or tPHL.
As mentioned earlier, tPSK can
determine the maximum parallel
data transmission rate. Figure 16
is the timing diagram of a typical
parallel data application with both
the clock and data lines being
sent through the optocouplers.
The figure shows data and clock
signals at the inputs and outputs
of the optocouplers. In this case
the data is assumed to be clocked
off of the rising edge of the clock.
50%
DATA
VO
INPUTS
2.5 V,
CMOS
CLOCK
tPSK
VI
50%
DATA
OUTPUTS
VO
2.5 V,
CMOS
tPSK
CLOCK
tPSK
Figure 15. Propagation Delay Skew Waveform.
Propagation delay skew represents the uncertainty of where an
edge might be after being sent
through an optocoupler.
Figure 16 shows that there will be
uncertainty in both the data and
clock lines. It is important that
these two areas of uncertainty not
overlap, otherwise the clock
signal might arrive before all of
the data outputs have settled, or
Figure 16. Parallel Data Transmission Example.
some of the data outputs may
start to change before the clock
signal has arrived. From these
considerations, the absolute
minimum pulse width that can be
sent through optocouplers in a
parallel application is twice tPSK.
A cautious design should use a
slightly longer pulse width to
ensure that any additional
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uncertainty in the rest of the
circuit does not cause a problem.
The HCPL-x710 optocouplers
offer the advantage of guaranteed
specifications for propagation
delays, pulse-width distortion, and
propagation delay skew over the
recommended temperature and
power supply ranges.
11
Digital Field Bus
Communication
Networks
To date, despite its many drawbacks, the 4 - 20 mA analog
current loop has been the most
widely accepted standard for
implementing process control
systems. In today’s manufacturing
environment, however, automated
systems are expected to help
CONTROLLER
manage the process, not merely
monitor it. With the advent of
digital field bus communication
networks such as DeviceNet,
PROFIBUS, and Smart Distributed
Systems (SDS), gone are the days
of constrained information.
Controllers can now receive
multiple readings from field
devices (sensors, actuators, etc.)
in addition to diagnostic
information.
The physical model for each of
these digital field bus communication networks is very similar as
shown in Figure 17. Each
includes one or more buses, an
interface unit, optical isolation,
transceiver, and sensing and/or
actuating devices.
BUS
INTERFACE
OPTICAL
ISOLATION
TRANSCEIVER
FIELD BUS
TRANSCEIVER
TRANSCEIVER
TRANSCEIVER
TRANSCEIVER
OPTICAL
ISOLATION
OPTICAL
ISOLATION
OPTICAL
ISOLATION
OPTICAL
ISOLATION
BUS
INTERFACE
BUS
INTERFACE
BUS
INTERFACE
BUS
INTERFACE
XXXXXX
SENSOR
YYY
DEVICE
CONFIGURATION
MOTOR
CONTROLLER
MOTOR
STARTER
Figure 17. Typical Field Bus Communication Physical Model.
Optical Isolation for
Field Bus Networks
To recognize the full benefits of
these networks, each recommends providing galvanic
isolation using Agilent
optocouplers. Since network
communication is bi-directional
(involving receiving data from
and transmitting data onto the
network), two Agilent
optocouplers are needed. By
providing galvanic isolation, data
integrity is retained via noise
reduction and the elimination of
false signals. In addition, the
network receives maximum
protection from power system
faults and ground loops.
Within an isolated node, such as
the DeviceNet Node shown in
Figure 18, some of the node’s
components are referenced to a
ground other than V- of the
network. These components could
include such things as devices
with serial ports, parallel ports,
RS232 and RS485 type ports. As
shown in Figure 18, power from
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the network is used only for the
transceiver and input (network)
side of the optocouplers.
Isolation of nodes connected to
any of the three types of digital
field bus networks is best
achieved by using the HCPL-x710
optocouplers. For each network,
the HCPL-x710 satisify the
critical propagation delay and
pulse width distortion requirements over the temperature range
of 0°C to +85°C, and power
supply voltage range of 4.5 V
to 5.5 V.
12
AC LINE
NODE/APP SPECIFIC
LOCAL
NODE
SUPPLY
uP/CAN
HCPL
x710
GALVANIC
ISOLATION
BOUNDARY
HCPL
x710
5 V REG.
TRANSCEIVER
DRAIN/SHIELD
V+ (SIGNAL)
V– (SIGNAL)
V+ (POWER)
V– (POWER)
SIGNAL
POWER
NETWORK
POWER
SUPPLY
Figure 18. Typical DeviceNet Node.
Implementing DeviceNet
and SDS with the
HCPL-x710
With transmission rates up to 1
Mbit/s, both DeviceNet and SDS
are based upon the same
broadcast-oriented, communications protocol — the Controller
Area Network (CAN). Three types
of isolated nodes are
recommended for use on these
networks: Isolated Node Powered
by the Network (Figure 19),
Isolated Node with Transceiver
Powered by the Network (Figure
20), and Isolated Node Providing
Power to the Network
(Figure 21).
Isolated Node Powered by the
Network
This type of node is very flexible
and as can be seen in Figure 19,
is regarded as “isolated” because
not all of its components have the
same ground reference. Yet, all
components are still powered by
the network. This node contains
two regulators: one is isolated and
powers the CAN controller, nodespecific application and isolated
(node) side of the two optocouplers while the other is nonisolated. The non-isolated
regulator supplies the transceiver
and the non-isolated (network)
half of the two optocouplers.
NODE/APP SPECIFIC
uP/CAN
HCPL
x710
ISOLATED
SWITCHING
POWER
SUPPLY
HCPL
x710
GALVANIC
ISOLATION
BOUNDARY
REG.
TRANSCEIVER
DRAIN/SHIELD
V+ (SIGNAL)
V– (SIGNAL)
V+ (POWER)
V– (POWER)
SIGNAL
POWER
NETWORK
POWER
SUPPLY
Figure 19. Isolated Node Powered by the Network.
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13
Isolated Node with
Transceiver Powered by the
Network
Figure 20 shows a node powered
by both the network and another
source. In this case, the transceiver and isolated (network) side
of the two optocouplers are
powered by the network. The rest
of the node is powered by the AC
line which is very beneficial when
an application requires a
significant amount of power. This
method is also desirable as it does
not heavily load the network.
More importantly, the unique
“dual-inverting” design of the
HCPL-x710 ensure the network
will not “lock-up” if either AC line
power to the node is lost or the
node powered-off. Specifically,
when input power (VDD1) to the
HCPL-x710 located in the
transmit path is eliminated, a
RECESSIVE bus state is ensured
as the HCPL-x710 output voltage
(VO ) go HIGH.
*Bus V+ Sensing
It is suggested that the Bus V+
sense block shown in Figure 20
be implemented. A locally
powered node with an unpowered isolated Physical Layer
will accumulate errors and
become bus-off if it attempts to
transmit. The Bus V+ sense
AC LINE
NODE/APP SPECIFIC
NON ISO
5V
uP/CAN
HCPL
x710
HCPL
x710
*HCPL
x710
GALVANIC
ISOLATION
BOUNDARY
REG.
TRANSCEIVER
DRAIN/SHIELD
V+ (SIGNAL)
V– (SIGNAL)
V+ (POWER)
V– (POWER)
SIGNAL
POWER
NETWORK
POWER
SUPPLY
* OPTIONAL FOR BUS V + SENSE
Figure 20. Isolated Node with Transceiver Powered by the Network.
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signal would be used to change
the BOI attribute of the DeviceNet
Object to the “auto-reset” (01)
value. Refer to Volume 1, Section
5.5.3. This would cause the node
to continually reset until bus
power was detected. Once power
was detected, the BOI attribute
would be returned to the “hold in
bus-off” (00) value. The BOI
attribute should not be left in the
“auto-reset” (01) value since this
defeats the jabber protection
capability of the CAN error
confinement. Any inexpensive low
frequency optical isolator can be
used to implement this feature.
14
Isolated Node Providing
Power to the Network
Figure 21 shows a node providing
power to the network. The AC line
powers a regulator which
provides five (5) volts locally. The
AC line also powers a 24 volt
isolated supply, which powers the
network, and another five-volt
regulator, which, in turn, powers
the transceiver and isolated
(network) side of the two
optocouplers. This method is
recommended when there are a
limited number of devices on the
network that don’t require much
power, thus eliminating the need
for separate power supplies.
More importantly, the unique
“dual-inverting” design of the
HCPL-x710 ensure the network
will not “lock-up” if either AC line
power to the node is lost or the
node powered-off. Specifically,
when input power (VDD1) to the
HCPL-x710 located in the
transmit path is eliminated, a
RECESSIVE bus state is ensured
as the HCPL-x710 output voltage
(VO) go HIGH.
AC LINE
DEVICENET NODE
NODE/APP SPECIFIC
5 V REG.
uP/CAN
HCPL
x710
ISOLATED
SWITCHING
POWER
SUPPLY
HCPL
x710
GALVANIC
ISOLATION
BOUNDARY
5 V REG.
TRANSCEIVER
DRAIN/SHIELD
SIGNAL
POWER
Figure 21. Isolated Node Providing Power to the Network.
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V+ (SIGNAL)
V– (SIGNAL)
V+ (POWER)
V– (POWER)
15
Power Supplies and Bypassing
The recommended DeviceNet
application circuit is shown in
Figure 22. Since the HCPL-x710
are fully compatible with CMOS
logic level signals, the optocoupler is connected directly to the
CAN transceiver. Two bypass
capacitors (with values between
0.01 and 0.1 µF) are required and
should be located as close as
possible to the input and output
power-supply pins of the HCPLx710. For each capacitor, the
GALVANIC
ISOLATION
BOUNDARY
ISO 5 V
5V
1 VDD1
TX0
2 VIN
0.01 µF
3
LINEAR OR
SWITCHING
REGULATOR
VDD2 8
+
0.01
µF
7
HCPL-x710
TxD
VO 6
4 GND1
VCC
5 V+
GND2 5
+
C4
0.01 µF
3 SHIELD
REF
GND
1 V–
VREF
RXD
0.01
µF
3
2 CAN–
CANL
GND1 4
6 VO
4 CAN+
82C250
Rs
5 GND2
+
CANH
GND
RX0
total lead length between both
ends of the capacitor and the
power supply pins should not
exceed 20 mm. The bypass capacitors are required because of the
high-speed digital nature of the
signals inside the optocoupler.
D1
30 V
HCPL-x710
0.01 µF
7
8 VDD2
ISO 5 V
VIN 2
VDD1 1
5V
Figure 22. Recommended DeviceNet Application Circuit.
Implementing PROFIBUS
with the HCPL-x710
An acronym for Process Fieldbus,
PROFIBUS is essentially a
twisted-pair serial link very
similar to RS-485 capable of
achieving high-speed communication up to 12 MBd. As shown in
Figure 23, a PROFIBUS Controller (PBC) establishes the connection of a field automation unit
(control or central processing
station) or a field device to the
transmission medium. The PBC
consists of the line transceiver,
optical isolation, frame character
transmitter/receiver (UART), and
the FDL/APP processor with the
interface to the PROFIBUS user.
PROFIBUS USER:
CONTROL STATION
(CENTRAL PROCESSING)
OR FIELD DEVICE
USER INTERFACE
FDL/APP
PROCESSOR
UART
PBC
OPTICAL ISOLATION
TRANSCEIVER
MEDIUM
Figure 23. PROFIBUS Controller (PBC).
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C1
0.01 µF
500 V
R1
1M
Power Supplies and Bypassing
The recommended PROFIBUS
application circuit is shown in
Figure 24. Since the HCPL-x710
are fully compatible with CMOS
logic level signals, the
optocoupler is connected directly
to the transceiver. Two bypass
capacitors (with values between
0.01 and 0.1 µF) are required and
should be located as close as
possible to the input and output
power-supply pins of the
HCPL-x710. For each capacitor,
the total lead length between both
ends of the capacitor and the
power supply pins should not
exceed 20 mm. The bypass
capacitors are required because
of the high-speed digital nature of
the signals inside the optocoupler.
Being very similar to multi-station
RS485 systems, the HCPL-061N
optocoupler provides a transmit
disable function which is
necessary to make the bus free
after each master/slave
transmission cycle. Specifically,
the HCPL-061N disables the
transmitter of the line driver by
putting it into a high state mode.
In addition, the HCPL-061N
switches the RX/TX driver IC into
the listen mode. The HCPL-061N
offers HCMOS compatibility and
the high CMR performance
(1 kV/µs at VCM = 1000 V)
essential in industrial
communication interfaces.
GALVANIC
ISOLATION
BOUNDARY
5V
ISO 5 V
8 VDD2
VDD1 1
VIN 2
7
0.01 µF
ISO 5 V
HCPL-x710
6 VO
Rx
3
5 GND2
1
0.01
µF
GND1 4
3
ISO 5 V
1 VDD1
2 VIN
Tx
D
0.01
µF
7
+
RT
B
7
SHIELD
–
DE
2 RE
VDD2 8
A 6
SN75176B
4
5V
R
0.01
µF
8
VCC
GND
5
0.01 µF
1M
HCPL-x710
VO 6
3
0.01 µF
4 GND1
GND2 5
ISO 5 V
VCC 8
1
5V
Tx ENABLE
1, 0 kΩ
680 Ω
VE 7
2 ANODE
0.01
µF
VO 6
3 CATHODE
4
GND 5
HCPL-061N
www.semiconductor.agilent.com
Data subject to change.
Figure 24. Recommended PROFIBUS Application Circuit.
Copyright © 1999 Agilent Technologies
Obsoletes 5968-2818E
5968-7458E (11/99)
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