NSC DS78C120J

DS78C120/DS88C120 Dual CMOS Compatible
Differential Line Receiver
General Description
Features
The DS78C120 and DS88C120 are high performance, dual
differential, CMOS compatible line receivers for both balanced and unbalanced digital data transmission. The inputs
are compatible with EIA, Federal and MIL standards.
Input specifications meet or exceed those of the popular
DS7820/DS8820 line receiver.
The line receiver will discriminate a g 200 mV input signal
over a common-mode range of g 10V and a g 300 mV signal over a range of g 15V.
Circuit features include hysteresis and response control for
applications where controlled rise and fall times and/or high
frequency noise rejection are desirable. Threshold offset
control is provided for fail-safe detection, should the input
be open or short. Each receiver includes a 180X terminating
resistor and the output gate contains a logic strobe for time
discrimination. The DS78C120 is specified over a b55§ C to
a 125§ C temperature range and the DS88C120 from 0§ C to
a 70§ C.
Y
Y
Y
Y
Y
Y
Y
Y
Y
Full compatibility with EIA Standards RS232-C, RS422
and RS423, Federal Standards 1020, 1030 and MIL188-114
Input voltage range of g 15V (differential or commonmode)
Separate strobe input for each receiver
1/2 VCC strobe threshold for CMOS compatibility
5k typical input impedance
50 mV input hysteresis
200 mV input threshold
Operation voltage range e 4.5V to 15V
Separate fail-safe mode
Connection Diagram
Dual-In-Line Package
TL/F/5801 – 1
Top View
Order Number DS88C120N
See NS Package Number N16A
For Complete Military 883 Specifications,
see RETS Data Sheet.
Order Number DS78C120J/883
See NS Package Number J16A
TRI-STATEÉ is a registered trademark of National Semiconductor Corporation.
C1996 National Semiconductor Corporation
TL/F/5801
RRD-B30M36/Printed in U. S. A.
http://www.national.com
DS78C120/DS88C120 Dual CMOS Compatible Differential Line Receiver
February 1996
Absolute Maximum Ratings
(Note 1)
Storage Temperature Range
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales
Office/Distributors for availability and specifications.
Supply Voltage
Input Voltage
b 65§ C to a 150§ C
Lead Temperature (Soldering, 4 seconds)
Operating Conditions
18V
Min
4.5
Max
15
Units
V
Temperature (TA)
DS78C120
DS88C120
b 55
0
a 125
a 70
§C
§C
Common-Mode Voltage (VCM)
b 15
a 15
V
g 25V
Strobe Voltage
Output Sink Current
Maximum Power Dissipation* at 25§ C
Cavity Package
Molded Package
260§ C
Supply Voltage (VCC)
18V
50 mA
1433 mW
1362 mW
*Derate cavity package 9.6 mW/§ C above 25§ C; derate molded package
10.9 mW/§ C above 25§ C.
Electrical Characteristics (Notes 2 and 3)
Symbol
VTH
Parameter
Conditions
Min
Typ
Max Units
Differential Threshold
Voltage
IOUT e b200 mA,
VOUT t VCC b 1.2V
b 7V s VCM s 7V
0.06
0.2
V
b 15V s VCM s 15V
0.06
0.3
V
Differential Threshold
Voltage
IOUT e 1.6 mA,VOUT s 0.5V
b 7V s VCM s 7V
b 0.08
b 0.2
V
b 15V s VCM s 15V
b 0.08
b 0.3
V
VTH
Differential Threshold
Voltage Fail-Safe
IOUT e b 200 mA,
VOUT t VCC b 1.2V
b 7V s VCM s 7V
0.47
0.7
V
VTL
Offset e 5V
IOUT e 1.6 mA, VOUT s 0.5V
b 7V s VCM s 7V
RIN
Input Resistance
b 15V s VCM s 15V, 0V s VCC s 15V
RT
Line Termination Resistance TA e 25§ C
RO
Offset Control Resistance
TA e 25§ C
IIND
Data Input Current
(Unterminated)
0V s VCC s 15V
Input Balance
(Note 5)
IOUT e 200 mA, VOUT t
VTL
0.2
0.42
V
4
5
kX
100
180
VCM e 10V
2
3.1
mA
0
b 0.5
mA
b2
b 3.1
mA
0.1
0.4
V
b 0.1
b 0.4
V
b 7V s VCM s 7V
VCC b 1.2V, RS e 500X
IOUT e 1.6 mA, VOUT s 0.5V
RS e 500X
VOH
Logical ‘‘1’’ Output Voltage
IOUT e b200 mA, VDIFF e 1V
VOL
Logical ‘‘0’’ Output Voltage
IOUT e 1.6 mA, VDIFF e b1V
ICC
Power Supply Current
15V s VCM s b15V,
VDIFF e b0.5V (Both Receivers)
IIN(1)
Logical ‘‘1’’ Strobe Input
Current
VSTROBE e 15V, VDIFF e 3V
IIN(0)
Logical ‘‘0’’ Strobe Input
Current
VSTROBE e 0V, VDIFF e b3V
VIH
Logical ‘‘1’’ Strobe Input
Voltage
VOL s 0.5V, IOUT e 1.6 mA
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2
X
kX
VCM e 0V
VCM e b10V
VTHB
300
56
b 7V s VCM s 7V
VCC b 1.2 VCC b 0.75
V
0.25
0.5
V
VCC e 5.5V
8
15
mA
VCC e 15V
15
30
mA
15
100
mA
b 0.5
b 100
mA
VCC e 5V
3.5
2.5
V
VCC e 10V
8.0
5.0
V
VCC e 15V
12.5
7.5
V
Electrical Characteristics (Notes 2 and 3) (Continued)
Symbol
VIL
Parameter
Logical ‘‘0’’ Strobe Input
Voltage
IOS
Output Short-Circuit Current
Conditions
VOH VCC b 1.2V,
IOUT e b200 mA
Typ
Max
Units
VCC e 5V
Min
2.5
1.5
V
VCC e 10V
5.0
2.0
V
VCC e 15V
7.5
2.5
V
b 20
b 40
mA
VOUT e 0V, VCC e 15V, VSTROBE e 0V, (Note 4)
b5
Note 1: ‘‘Absolute Maximum Ratings’’ are those values beyond which the safety of the device cannot be guaranteed. Except for ‘‘Operating Temperature Range’’
they are not meant to imply that the devices should be operated at these limits. The table of ‘‘Electrical Characteristics’’ provides conditions for actual device
operation.
Note 2: Unless otherwise specified min/max limits apply across the b 55§ C to a 125§ C temperature range for the DS78C120 and across the 0§ C to a 70§ C range
for the DS88C120. All typical values for TA e 25§ C, VCC e 5V and VCM e 0V.
Note 3: All currents into device pins shown as positive, out of device pins as negative, all voltages referenced to ground unless otherwise noted. All values shown
as max or min on absolute value basis.
Note 4: Only one output at a time should be shorted.
Note 5: Refer to EIA-RS422 for exact conditions.
Switching Characteristics VCC e 5V, TA e 25§ C
Symbol
Parameter
Conditions
Typ
Max
Units
Differential Input to ‘‘0’’ Output
CL e 50 pF
60
100
ns
tpd1(D)
Differential Input to ‘‘1’’ Output
CL e 50 pF
100
150
ns
tpd0(S)
Strobe Input to ‘‘0’’ Output
CL e 50 pF
30
70
ns
tpd1(S)
Strobe Input to ‘‘1’’ Output
CL e 50 pF
100
150
ns
tpd0(D)
Min
AC Test Circuit and Switching Time Waveforms
Differential and Strobe Input Signal
*Includes probe and test fixture capacitance
TL/F/5801 – 3
tr e tf s 10 ns
PRR e 1 MHz
TL/F/5801 – 4
Note: Optimum switching response is obtained by minimizing stray capacitance on Response Control pin (no external connection).
3
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TL/F/5801 – 2
Schematic Diagram ((/2 Circuit Shown)
4
Application Hints
Balanced Data Transmission
TL/F/5801 – 5
Unbalanced Data Transmission
TL/F/5801 – 6
Logic Level Translator
TL/F/5801 – 8
TL/F/5801 – 7
The DS78C120/DS88C120 may be used as a level transistor to interface between g 12V MOS, ECL, TTL and CMOS. To configure, bias either input to a voltage
equal to (/2 the voltage of the input signal, and the other input to the driving gate.
5
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Application Hints (Continued)
LINE DRIVERS
Line drivers which will interface with the DS78C120/
DS88C120 are listed below.
Balanced Drivers
DS26LS31
Quad RS-422 Line Driver
DS7830, DS8830
Dual TTL
DS7831, DS8831
Dual TRI-STATEÉ TTL
DS7832, DS8832
Dual TRI-STATE TTL
DS1691A, DS3691
Quad RS-423/Dual RS-422 TTL
DS1692, DS3692
Quad RS-423/Dual TRI-STATE
RS-422 TTL
DS3587, DS3487
Quad TRI-STATE RS-422
Unbalanced Drivers
DS1488
Quad RS-232
DS14C88
Quad RS-232
DS75150
Dual RS-232
TL/F/5801 – 9
RESPONSE CONTROL AND HYSTERESIS
In unbalanced (RS-232/RS-423) applications it is recommended that the rise time and fall time of the line driver be
controlled to reduce cross-talk. Elimination of switching
noise is accomplished in the DS78C120/DS88C120 by the
50 mV of hysteresis incorporated in the output gate. This
eliminates the oscillations which may appear in a line receiver due to the input signal slowly varying about the threshold
level for extended periods of time.
High frequency noise which is superimposed on the input
signal which may exceed 50 mV can be reduced in amplitude by filtering the device input. On the DS78C120/
DS88C120, a high impedance response control pin in the
input amplifier is available to filter the input signal without
affecting the termination impedance of the transmission
line. Noise pulse width rejection vs the value of the response control capacitor is shown in Figures 1 and 2 . This
combination of filters followed by hysteresis will optimize
performance in a worse case noise environment.
FIGURE 1. Noise Pulse Width vs
Response Control Capacitor
TL/F/5801 – 10
TRANSMISSION LINE TERMINATION
On a transmission line which is electrically long, it is advisable to terminate the line in its characteristic impedance to
prevent signal reflection and its associated noise/crosstalk. A 180X termination resistor is provided in the
DS78C120/DS88C120 line receiver. To use the termination
resistor, connect pins 2 and 3 together and pins 13 and 14
together. The 180X resistor provides a good compromise
between line reflections, power dissipation in the driver, and
IR drop in the transmission line. If power dissipation and IR
drop are still a concern, a capacitor may be connected in
series with the resistor to minimize power loss.
The value of the capacitor is recommended to be the line
length (time) divided by 3 times the resistor value. Example:
if the transmission line is 1,000 feet long, (approximately
1000 ns) the capacitor value should be 1852 pF. For additional application details, refer to application notes AN-22
and AN-108.
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TL/F/5801 – 11
FIGURE 2
6
Application Hints (Continued)
performance of the receiver over its common-mode operating range, and will not change the input impedance balance
of the receiver.
FAIL-SAFE OPERATION
Communication systems require elements of a system to
detect the presence of signals in the transmission lines, and
it is desirable to have the system shut-down in a fail-safe
mode if the transmission line is open or shorted. To facilitate
the detection of input opens or shorts, the DS78C120/
DS88C120 incorporates an input threshold voltage offset.
This feature will force the line receiver to a specific logic
state if presence of either fault is a condition.
Given that the receiver input threshold is g 200 mV, an input
signal greater than g 200 mV insures the receiver will be in
a specific logic state. When the offset control input (pins 1
and 15) is connected to VCC e 5V, the input thresholds are
offset from 200 mV to 700 mV, referred to the non-inverting
input, or b200 mV to b700 mV, referred to the inverting
input. Therefore, if the input is open or shorted, the input will
be greater than the input threshold and the receiver will
remain in a specified logic state.
The input circuit of the receiver consists of a 5k resistor
terminated to ground through 120X on both inputs. This network acts as an attenuator, and permits operation with common-mode input voltages greater than g 15V. The offset
control input is actually another input to the attenuator, but
its resistor value is 56k. The offset control input is connected to the inverting input side of the attenuator, and the input
voltage to the amplifier is the sum of the inverting input plus
0.09 times the voltage on the offset control input. When the
offset control input is connected to 5V the input amplifier will
see VIN(INVERTING) a 0.45V or VIN(INVERTING) a 0.9V
when the control input is connected to 10V. The offset control input will not significantly affect the differential
It is recommended that the receiver be terminated (500X or
less) to insure it will detect an open circuit in the presence
of noise.
The offset control can be used to insure fail-safe operation
for unbalanced interface (RS-423) or for balanced interface
(RS-422) operation.
For unbalanced operation, the receiver would be in an indeterminate logic state if the offset control input was open.
Connecting the offset to 5V offsets the receiver threshold
0.45V. The output is forced to a logic zero state if the input
is open or shorted.
For balanced operation with inputs shorted or open, receiver C will be in an indeterminate logic state. Receivers A and
B will be in a logic zero state allowing the NOR gate to
detect the short or open condition. The strobe will disable
receivers A and B and may therefore be used to sample the
fail-safe detector. Another method of fail-safe detection
consists of filtering the output of the NOR gate D so it would
not indicate a fault condition when receiver inputs pass
through the threshold region, generating an output transient.
In a communications system, only the control signals are
required to detect input fault condition. Advantages of a balanced data transmission system over an unbalanced transmission system are:
1. High noise immunity
2. High data ratio
3. Long line lengths
Unbalanced RS-423 and RS-232 Fail-Safe
TL/F/5801 – 12
7
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Application Hints (Continued)
Balanced RS-422 Fail-Safe
TL/F/5801 – 13
TL/F/5801–14
TL/F/5801 – 15
TL/F/5801 – 16
Truth Table (For Balanced Fail-Safe)
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Input
Strobe
A-OUT
B-OUT
C-OUT
D-OUT
0
1
X
0
1
X
1
1
1
0
0
0
0
1
0
1
1
1
1
0
0
1
1
1
0
1
X
0
0
0
0
0
1
0
0
0
8
Physical Dimensions inches (millimeters)
Ceramic Dual-In-Line Package (J)
Order Number DS78C120J/883
NS Package Number J16A
9
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DS78C120/DS88C120 Dual CMOS Compatible Differential Line Receiver
Physical Dimensions inches (millimeters) (Continued)
Molded Dual-In-Line Package (N)
Order Number DS88C120N
NS Package Number N16A
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