BB ISO422

®
ISO
ISO422
422
ISO
422
DIFFERENTIAL BUS TRANSCEIVER
FEATURES
DESCRIPTION
● FULL-/HALF-DUPLEX OPERATION
● 1500Vrms ISOLATION (cont)
● 2500Vrms ISOLATION (1 min)
ISO422 provides 1500Vrms isolation for industrial
bus transmission systems. ISO422 may be configured
in full or half duplex modes providing the user with
best flexibility for the application. Transmission rates
of 2.5Mbps can be obtained covering most requirements. A loop-back test facility is included. LBE
allows data on the D input to be routed to the R output
for test purposes.
● 2.5Mbps PERFORMANCE
● LOOP-TEST FACILITY
APPLICATIONS
● BUS TRANSMISSION SYSTEMS
● GROUND LOOP ISOLATION
ISO422 is available in 24-pin PDIP and 24-pin Gull
Wing(1) packages and is specified over the temperature
range –40°C to +85°C.
NOTE: (1) Gull Wing version available Q1’99.
DE
Y
D
Z
LBE
A
R
B
RE
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 • Internet: http://www.burr-brown.com/ • Cable: BBRCORP • Telex: 066-6491 • FAX: (520) 889-1510 • Immediate Product Info: (800) 548-6132
©
1998 Burr-Brown Corporation
PDS-1503A
Printed in U.S.A. December, 1998
SPECIFICATIONS
At TA = +25°C, and VS = +5V, unless otherwise noted.
ISO422P, P-U(1)
PARAMETER
ISOLATION
Rated Continuous Isolation
Partial Discharge Voltage
Barrier Impedance
Leakage Current
VISO
CONDITIONS
MIN
50Hz, 60Hz
1s, 5 x 5pC/per cycle(2)
1500
2500
5kV/µs Edge
D
D
D
D
∆|VOD|
VOC
∆|VOC|
IO
DRIVER SWITCHING CHARACTERISTICS
Differential Output Delay Time
Skew |tDDH - tDDL|
Differential Output Transition Time
Output Enable Time to HIGH
Output Enable Time to LOW
Output Disable Time from HIGH
Output Disable Time from LOW
(Figure 6)
t DD
tDT
tDZH
tDZL
tDHZ
tDLZ
VOH
VOL
I OS
I OZ
VIH
VIL
IL
CIN
VTH
VTL
IBI
VBI
RIN
1
and DE Inputs(3)
and DE Inputs(3)
and DE Inputs(3)
and DE Inputs(3)
VY or VZ
IOY or I OZ = 0
RL = 100Ω
RL = 54Ω
RL = 100Ω or 54Ω(4)
RL = 100Ω or 54Ω
RL = 100Ω or 54Ω(4)
VO = VCC2, Output Disabled
VO = 0V, Output Disabled
VO = VCC2, Continuous
VO = 0V, Continuous
VIH
VIL
IL
CIN
VO
VOD
Short-Circuit Output Current
RECEIVER DC CHARACTERISTICS
High Level Output Voltage
Low Level Output Voltage
Output Short-Circuit Current
Output HI-Z Leakage
Enable Input HIGH Threshold
Enable Input LOW Threshold
Input Leakage Current
Input Capacitance
Differential Input HIGH Threshold
Differential Input LOW Threshold
Input Hysteresis
Line Input Current
Line Voltage
Input Resistance
10
8.6
0.1
DRIVER DC CHARACTERISTICS
High Level Input Voltage
Low Level Input Voltage
Input Leakage Current
Input Capacitance
Output Voltage
Differential Output Voltage
Change in Mag Diff Out Voltage
Common-Mode Output Voltage
Change in Mag CM Out Voltage
Output Current
2
0.8
5
5
0
1.5
2
1.5
3.6
2.8
±40
±40
±10
±10
100
–110
RL = 54Ω
RL = 54Ω
RL = 54Ω
R L = 100Ω
R L = 100Ω
R L = 100Ω
R L = 100Ω
120
25
120
120
120
120
IOH = 6mA
I OL = 6mA
1s max
VOUT = 0V to VCC1
RE Input(3)
RE Input(3)
RE Input(3)
RE Input(3)
VO = 2.8V
VO = 0.4V
See Note 5
Power On (GNDB < VBI < VSB)
Power Off (IBI ±10mA max)
5
5
5
5
±200
3
±200
±1000
±1000
150
50
100
150
150
150
150
VCC – 1
0.4
30
±10
±1000
2
0.8
–200
5
5
100
–100
60
±10
±12
200
±1000
1
RECEIVER SWITCHING CHARACTERISTICS (Figure 7)
Propagation Delay L to H
tRLH
VID = –1.5V to 1.5V, CL = 10pF
Propagation Delay H to L
tRHL
VID = 1.5V to –1.5V, CL = 10pF
Skew |tRLH - tRHL|
Output Rise Time
tR
CL = 10pF
Output Fall Time
tF
CL = 10pF
Output Enable Time to HIGH
tRZH
CL = 10pF
Output Enable Time to LOW
tRZL
CL = 10pF
Output Disable Time from HIGH
tRHZ
CL = 10pF
Output Disable Time from LOW
tRLZ
CL = 10pF
®
ISO422
MAX
> 1014 || 10
1
240V, 60Hz
2500V, 50Hz
Creepage Distance
Internal Isolation Distance
Transient Recovery Time
TYP
2
120
120
40
10
10
15
15
15
15
150
150
25
25
25
25
UNITS
V
V
Ω || pF
µA
µA
mm
mm
µs
V
V
nA
pF
V
V
V
V
mV
V
mV
nA
nA
mA
mA
ns
ns
ns
ns
ns
ns
ns
V
V
mA
nA
V
V
nA
pF
mV
mV
mV
nA
V
MΩ
ns
ns
ns
ns
ns
ns
ns
ns
ns
SPECIFICATIONS (CONT)
At TA = +25°C, and VS = +5V, unless otherwise noted.
ISO422P, P-U(1)
PARAMETER
CONDITIONS
POWER
Supply Voltage—Data Side
Supply Current—Data Side
Supply Current—Data Side
Supply Voltage—Bus Side
Supply Voltage—Bus Side
VSA
ISA
ISA
VSB
ISB
MIN
4.5
Output Unloaded, dc
Output Unloaded, max Rate
10
20
4.5
Output Unloaded, dc
Output Unloaded, max Rate
12
20
BUS LIMITS
Input Current
Maximum Differential Input
Maximum Data Rate
TEMPERATURE RANGE
Operating
Storage
Thermal Resistance
TYP
MAX
UNITS
5.5
13
V
mA
mA
V
mA
mA
5.5
20
±10
±5
mA
V
Mbps
+85
+125
°C
°C
°C/W
2.5
–40
–40
θJA
75
NOTES: (1) Gull Wing version available Q1’99. (2) All devices receive a 1s test. Failure criterion is > 5 pulses of > 5pC per cycle. (3) Logic inputs are HCT-type
and thresholds are a function of power supply voltage with approximately 100mV hysteresis. (4) Change in magnitude when the input is changed from HIGH to
LOW. (5) The difference between the differential low to high and high to low transition points.
ABSOLUTE MAXIMUM RATINGS
PIN CONFIGURATION
Top View
Supply Voltage: VSA ............................................................. –0.5V to +6V
VSB ............................................................. –0.5V to +6V
Continuous Isolation Voltage ..................................................... 1500Vrms
Storage Temperature ...................................................... –40°C to +125°C
Lead Temperature (soldering, 10s) ............................................... +300°C
DIP
DE
1
24 RE
D
2
23 R
NC
3
22 LBE
VSA
4
21 GNDA
PACKAGE INFORMATION
PRODUCT
PACKAGE
PACKAGE DRAWING
NUMBER(1)
ISO422P
ISO422P-U
24-Pin Plastic DIP
24-Pin Gull Wing Surface Mount
243-4
243-5
NOTE: (1) For detailed drawing and dimension table, please see end of data
sheet, or Appendix C of Burr-Brown IC Data Book.
9
16 VSB
GNDB 10
15 VSB
GNDB
Y 11
14 A
Z 12
13 B
ELECTROSTATIC
DISCHARGE SENSITIVITY
Electrostatic discharge can cause damage ranging from performance degradation to complete device failure. BurrBrown Corporation recommends that all integrated circuits
be handled and stored using appropriate ESD protection
methods.
ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits
may be more susceptible to damage because very small
parametric changes could cause the device not to meet
published specifications.
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.
®
3
ISO422
TYPICAL PERFORMANCE CURVES
At TA = +25°C, and VS = +5V, unless otherwise noted.
BUS 0 TO 1 TRANSITION
PROPAGATION DELAY
Y-Z
D
Z
Y-Z
Y
20ns/div
2µs/div
BUS 1 TO 0 TRANSITION
TERMINATED 200m CABLE
Y-Z
Y-Z
Y
Z
Z
Y
20ns/div
50ns/div
2kΩ RESISTORS INSERTED IN TERMINATED CABLE
Y-Z
Z
Y
200ns/div
®
ISO422
4
OPERATION
active. The receive enable/disable time is simply the time to
enable/disable the R output (tRLZ) and does not require any
additional barrier transmission time.
ISO422 is an isolated, full-duplex bus transceiver which is
compatible with three-wire data bus systems using EIA
standards RS-422-A and RS-485. It is based on Burr-Brown’s
capacitive barrier technology. The data bus input is designed
to present a very high impedance to the data bus, thus
allowing a virtually unlimited number of receivers on any
data bus section. To allow this feature, the data bus input is
limited to a common-mode range within the magnitude of
the supplies. This limitation requires that all nodes on the
bus are referenced to a common ground. However, systems
attached to the bus through ISO422, are isolated up to
1500Vrms and may, therefore, have local floating ground
potentials up to this isolation voltage. The circuit encodes all
data passed across the barrier to ensure that the input values
and control signals are correctly passed across the barrier
under all power up conditions. The ISO422 also allows data
recovery to the current input state, after any transient upset.
RE
tRLH
B
FIGURE 2. ISO422 Data Receive.
DATA CORRUPTION
If, due to transient upset, the data passed across the barrier
is corrupted, the data will be restored within 100ns from the
end of the corrupting signal.
SYNCHRONIZATION
The data transmitted across the barrier is coded using an
internal clock. This clock also captures the incoming asynchronous data and synchronizes it to the clock edges. This
will give rise to an rms propagation delay jitter of approximately 50ns.
LOOPBACK
A loopback function is provided by the LBE input. If this
input is HIGH, then enabling both the transmitter and the
receiver will cause the device to route the D input to the R
output, in addition to the data bus outputs. Data on the
incoming bus is ignored. This feature allows a simple connection test to be performed during any application. When
LBE is LOW, transmit and receive will operate in the normal
full-duplex mode.
D
tDD
tDLZ
tDZH
tRHL
A
DE
tDD
tRZH
R
TRANSMIT
Data is passed from the D input to the data bus outputs after
a barrier transmission delay (tDD) when the DE input is
HIGH. When DE is LOW, the data bus drivers are switched
off, and assume the high impedance state. When enabling
the data bus output, i.e., switching DE from LOW to HIGH,
the enable signal is passed directly across the barrier and
enables the output, after a barrier transmission delay and
output enable time (tDLZ/tDHZ). Similarly, when disabling the
data bus output, i.e., switching DE from HIGH to LOW, the
disable signal is passed directly across the barrier and
disables the output after a barrier transmission delay and
output disable time (tDLZ/tDHZ).
tDZL
tRZH
tRLZ
tRZL
tDHZ
Y
DATA BUS CONNECTION
Z
ISO422 can be used in half duplex, or full duplex data
communication bus systems. It is capable of continuously
driving a 54Ω load, equivalent to a double-terminated transmission line, at the fully specified data rate. When connecting to the data bus, the voltage on the A and B input lines
must remain between VSB and GNDB. This can be achieved
by using a common bus ground connection, such as GNDB,
as shown in Figures 5 and 6.
FIGURE 1. ISO422 Data Transmit.
RECIEVE
The receive data is determined by the data bus differential
signal after a barrier transmission delay (tRZL). When the
difference between the A input and the B input (A-B) is
greater than +200mV, the R output will be HIGH. If A-B is
more negative than –200mV, the R output is undefined.
Since the reciver has a high impedance input, no disable
signal is required for the data bus input, which is always
For any system connected to the bus, the isolation provided
by ISO422 allows the independent local ground potential to
be as high as 1500Vrms with respect to the date bus ground
reference. This feature replaces the limited +12V to –7V
range of the RS-485 standard with the full-isolation voltage
capability of the ISO422.
®
5
ISO422
DE
1
24 RE
DE
1
24 RE
D
2
23 R
D
2
23 R
NC
3
22 LBE
NC
3
22 LBE
VCC
4
21 GNDA
VCC
4
21 GNDA
GNDB
9
16 VCC
GNDB
9
16 VCC
GNDB 10
15 VCC
GNDB 10
15 VCC
Y 11
14 A
Y 11
14 A
Z 12
13 B
Z 12
13 B
Loopback Enabled
Transmit and Receive Active
Loopback Disabled
Transmit and Receive Active
FIGURE 3. Loopback.
CONNECTION TO CAN BUS
Since the bus can be enabled and disabled at the same rate
as the data (2.5MHz), it is possible to use ISO422 as an
isolated bus driver in CAN systems. Again, the ISO422 bus
line must be constrained within the supply voltages.
DE
Y
Figure 4 shows the connections which allow ISO422 to be
used in CANbus systems. The DE input of the ISO422 is
used as the CAN TX0 input and is used to transmit the data
by enabling and disabling the Y and Z outputs. The D and
RE inputs of the ISO422 are tied to GNDA. This ensures that
the Y output can only pull down, and the Z output can only
pull up. With D tied to GNDA, the DE input of ISO422 (TX0
of CAN) activates the Y output as an open drain pull-down
driver, and activates the Z output as an open drain pull-up
driver. Therefore, the Y line acts as CANL and the Z line acts
as CANH. When DE (TX0) is HIGH, ISO422 makes the bus
state dominant i.e., Y pulls LOW and Z pulls HIGH. With
DE (TX0) LOW, Y and Z are high impedance and the bus
state is recessive. Data is received in the normal manner
which is half duplex. Line A is connected to CANH, and line
B is connected to CANL. The R output becomes RX0. RE
is tied to GNDA to keep R (RX0) enabled. If required, RE
may be used to disable the RX0 output.
Z
TX0
A
R
RX0
RE
B
CANL
ISO422
FIGURE 4. CANBus Connection.
TX0
CANH
CANL
BUS
H
H
L
Dominant
L
L
Hi-Z
Hi-Z
Recessive
H
TABLE I. CAN.
®
ISO422
CANH
D
6
RX0
Shielded Twisted Pair EIA485
GNDB
GNDB
FIGURE 5. Half-Duplex Connection.
Shielded Twisted Pair EIA485
GNDB
GNDB
FIGURE 6. Full-Duplex Connection.
®
7
ISO422
R
120Ω
1.2kΩ
1.2kΩ
Half-duplex and Full-duplex resistor
values are the same. Half-duplex line
should be terminated at both ends.
Half Duplex
Full Duplex
FIGURE 7. Suggested Bus Termination Methods.
+5V
+5V
MAX202
MAX202
+5V Isolated
+5V Isolated
1.2kΩ(1)
D9
D25
3
2
TD
2
3
RD
5
7
SG
4
20 DTR
6
6
DSR
1
8
CD
7
4
RTS
8
5
CTS
8
9
7
10
1.2kΩ(1)
R
120Ω
R
120Ω
ISO422
1.2kΩ(1)
1.2kΩ(1)
10
7
9
8
RD
ISO422
TD
SG
DTR
GNDA
GND Isolation
GND Isolation
GNDB
DSR
CD
RTS
CTS
NOTE: (1) If using screened cable or ground
wire, connected as shown, shaded resistors
may be omitted. If using only twisted pairs,
shaded resistors are recommended.
FIGURE 8. Isolated RS232 to RS422. Null Modem Configuration.
®
ISO422
8