EXAR SP26LV431EN-L/TR

SP26LV431
HIGH SPEED +3.3V QUAD RS-422 DIFFERENTIAL LINE DRIVER
FEBRUARY 2009
GENERAL DESCRIPTION
The SP26LV431 is a quad differential line driver that
meets the specifications of the EIA standard RS-422
serial protocol. The SP26LV431 features Exar's
BiCMOS process allowing low power operational
characteristics of CMOS technology while meeting all
of the demands of the RS-422 serial protocol over
60Mbps under load. The RS-422 protocol allows up
to 10 receivers to be connected to a multipoint bus
transmission line. The SP26LV431 features a driver
enable control common to all four drivers that places
the output pins in a high impedance state. Since the
cabling can be as long as 4,000 feet, the RS-422
drivers of the SP26LV431 are equipped with a wide
common-mode output voltage range to accommodate
ground potential differences.
REV. 1.1.0
FEATURES
• Quad Differential Line Drivers
• Compatible with the EIA standard for RS-422 serial
protocol
• High-Z Output Control
• At Least 60Mbps Transmission Rates
• 11ns Typical Driver Propagation Delays
• Less than 1ns Typical Output Skew
• Single +3.3V Supply Operation
• Common Driver Enable Control
• Compatibility with the industry standard 26LV31
• Ideal For Use with SP26LV432, Quad Receivers
FIGURE 1. TYPICAL APPLICATION CIRCUIT
Exar Corporation 48720 Kato Road, Fremont CA, 94538 • (510) 668-7000 • FAX (510) 668-7017 • www.exar.com
SP26LV431
HIGH SPEED +3.3V QUAD RS-422 DIFFERENTIAL LINE DRIVER
REV. 1.1.0
FIGURE 2. PIN OUT ASSIGNMENT
ORDERING INFORMATION
PART NUMBER
PACKAGE
OPERATING TEMPERATURE
RANGE
DEVICE STATUS
SP26LV431CP-L
16-pin Plastic DIP
0°C to +70°C
Active
SP26LV431CN-L
16-pin Narrow SOIC
0°C to +70°C
Active
SP26LV431CN-L/TR
16-pin Narrow SOIC
0°C to +70°C
Active
SP26LV431EN-L
16-pin Narrow SOIC
-40°C to +85°C
Active
SP26LV431EN-L/TR
16-pin Narrow SOIC
-40°C to +85°C
Active
2
SP26LV431
HIGH SPEED +3.3V QUAD RS-422 DIFFERENTIAL LINE DRIVER
REV. 1.1.0
PIN DESCRIPTIONS
Pin Assignments
PIN NUMBER
PIN NAME
TYPE
DESCRIPTION
1
DI1
I
Driver 1 TTL input.
2
DO1A
O
Non-inverted driver 1 output.
3
DO1B
O
Inverted driver 1 output.
4
ENABLE
I
Driver output enable, active HIGH.
5
DO2B
O
Inverted driver 2 output.
6
DO2A
O
Non-inverted driver 2 output.
7
DI2
I
Driver 2 TTL input.
8
GND
Pwr
9
DI3
I
Driver 3 TTL input.
10
DO3A
O
Non-inverted driver 3 output.
11
DO3B
O
Inverted driver 3 output.
12
ENABLE
I
Driver output enable, active LOW.
13
DO4B
O
Inverted driver 4 output.
14
DO4A
O
Non-inverted driver 4 output.
15
DI4
I
Driver 4 TTL input.
16
VCC
Pwr
Ground.
+3.0V to +3.6V power supply.
Pin type: I=Input, O=Output.
3
SP26LV431
HIGH SPEED +3.3V QUAD RS-422 DIFFERENTIAL LINE DRIVER
REV. 1.1.0
ABSOLUTE MAXIMUM RATINGS
These are stress ratings only and functional operation of the device at these ratings or any other above those indicated in the operation sections to the
specifications below is not implied. Exposure to absolute maximum rating conditions for extended periods of time may affect reliability and cause permanent
damage to the device.
VCC
0.5V to 7.0V
VIN (DC Input Voltage)
-1.5V to (VCC + 1.5V)
VOUT (DC Output Voltage)
-0.5V to 7V
IIK, IOK (Clamp Diode Current)
±20mA
IOUT (DC Output Current, per pin)
±150mA
ICC (DC VCC or GND Current, per pin)
±150mA
Storage Temperature Range
-65°C to + 150°C
Power Dissipation 16-pin PDIP
(derate 14.3mW/°C above +70°C)
1150mW
Power Dissipation 16-pin NSOIC
(derate 13.6mW/°C above +70°C)
1100mW
CAUTION:
ESD (Electrostatic Discharge) sensitive device. Permanent damage may occur on unconnected devices subject to high energy electrostatic fields. Unused
devices must be stored in conductive foam or shunts. Personnel should be properly grounded prior to handling this device. The protective foam should be
discharged to the destination socket before devices are removed.
ELECTRICAL CHARACTERISTICS
UNLESS OTHERWISE NOTED: THE FOLLOWING SPECIFICATIONS APPLY FOR VCC = +3.0V TO +3.6V WITH TA =
+25OC AND ALL MIN AND MAX LIMITS APPLY ACROSS THE RECOMMENDED OPERATING TEMPERATURE RANGE.
SYMBOL
VCC
PARAMETERS
Supply Voltage
VIN or VOUT
MIN.
TYP.
3.0
DC Input or Output Voltage
MAX.
UNITS
3.6
V
VCC
V
CONDITIONS
Input Electrical Characteristics
tr or tf
Input Rise or Fall Times
VIH
HIGH Level Input Voltage
VIL
LOW Level Input Voltage
3
ns
2.0
V
0.8
V
Output Electrical Characteristics
V
VOH
HIGH Level Output Voltage
VOL
LOW Level Output Voltage
VT
Differential Output Voltage
T
– V
T
VOS
V
OS
–V
ICC
OS
2.5
2.9
0.2
2.0
0.5
2.7
V
VIN = VIH or VIL, IOUT = -20mA
V
VIN = VIH or VIL, IOUT = 20mA
V
RL = 100Ω, Note 1
Differential Output Voltage
0.4
V
RL = 100Ω, Note 1
Common Mode Output Voltage
3.0
V
RL = 100Ω, Note 1
Difference in Common Mode Output
0.4
V
RL = 100Ω, Note 1
Quiescent Supply Current
100
uA
VIN = VCC or GND, Note 2
4
SP26LV431
HIGH SPEED +3.3V QUAD RS-422 DIFFERENTIAL LINE DRIVER
REV. 1.1.0
UNLESS OTHERWISE NOTED: THE FOLLOWING SPECIFICATIONS APPLY FOR VCC = +3.0V TO +3.6V WITH TA =
+25OC AND ALL MIN AND MAX LIMITS APPLY ACROSS THE RECOMMENDED OPERATING TEMPERATURE RANGE.
SYMBOL
IOZ
PARAMETERS
MIN.
Tri-state Output Leakage Current
TYP.
MAX.
±2.0
UNITS
uA
CONDITIONS
VOUT = VCC or GND,
ENABLE = VIL, ENABLE = VIH
ISC
Output Short Circuit Current
IOFF
IOFF
-30
-150
mA
VIN = VCC or GND, Notes 1 & 3
Output Leakage Current Power Off
100
uA
VCC = 0V, VOUT = 6V, Note 1
Output Leakage Current Power Off
-100
uA
VCC = 0V, VOUT = -0.25V, Note
1
Switching Characteristics
Propagation Delays
11
18
ns
Figure 5
tSKEW
Skew, SP26LV431C_
0.8
2
ns
Figure 5, Note 4,
tSKEW
Skew, SP26LV431E_
3
ns
Figure 5, Note 4
10
ns
Figure 5
tPLHD, tPHLD
tTLH, tTHL
Differential Output Rise/Fall Times
4
tPZH
Output Enable Time
40
ns
Figure 7
tPZL
Output Enable Time
40
ns
Figure 7
tPHZ
Output Disable Time
35
ns
Figure 7, Note 5
tPLZ
Output Disable Time
35
ns
Figure 7, Note 5
CPD
Power Dissipation Capacitance
50
pF
Note 6
CIN
Input Capacitance
6
pF
NOTE:
1.
Refer to EIA specifications for RS-422 serial protocol for exact test conditions.
2.
Measured per input. All other inputs at VCC or GND.
3.
This is the current sourced when a high output is shorted to GND. Only one output at a time should be shorted.
4.
Skew is defined as the difference in propagation delays between complementary outputs at the 50% input.
5.
Output disable time is the delay from ENABLE or ENABLE being switched to the output transistors turning off.
The actual disable times are less than indicated due to the delay added by the RC time constant of the load.
6.
CPD determines the no load dynamic power consumption, PD = (CPDVCC2f) + (ICCVCC), and the no load dynamic
power consumption, IS = (CPDVCCf) + ICC.
5
SP26LV431
HIGH SPEED +3.3V QUAD RS-422 DIFFERENTIAL LINE DRIVER
FIGURE 3. SP431 BLOCK DIAGRAM
FIGURE 4. AC TEST CIRCUIT
6
REV. 1.1.0
SP26LV431
REV. 1.1.0
HIGH SPEED +3.3V QUAD RS-422 DIFFERENTIAL LINE DRIVER
FIGURE 5. PROPAGATION DELAYS
FIGURE 6. DRIVER SINGLE-ENDED TRI-STATE TEST CIRCUIT
7
SP26LV431
HIGH SPEED +3.3V QUAD RS-422 DIFFERENTIAL LINE DRIVER
FIGURE 7. DRIVER SINGLE-ENDED TRI-STATE WAVEFORMS
FIGURE 8. DIFFERENTIAL RISE AND FALL TIMES
8
REV. 1.1.0
SP26LV431
HIGH SPEED +3.3V QUAD RS-422 DIFFERENTIAL LINE DRIVER
REV. 1.1.0
1.0 PRODUCT DESCRIPTION
The SP26LV431 is a low-power quad differential line driver designed for digital data transmission meeting the
specifications of the EIA standard RS-422 serial protocol. The SP26LV431 features Exar's BiCMOS process
allowing low power operational characteristics of CMOS technology while meeting all of the demands of the
RS-422 serial protocol up to 60Mbps under load in harsh environments.
The RS-422 standard is ideal for multi-drop applications and for long-distance communication. The RS-422
protocol allows up to 10 receivers to be connected to a data bus, making it an ideal choice for multi-drop
applications. Since the cabling can be as long as 4,000 feet, RS-422 drivers are equipped with a wide common
mode output range to accommodate ground potential differences. Because the RS-422 is a differential
interface, data is virtually immune to noise in the transmission line.
The SP26LV431 accepts TTL or CMOS input levels and translates these to RS-422 output levels. The
SP26LV431 features active HIGH and active LOW driver enable controls common to all four driver channels
see Table 1. A logic HIGH on the ENABLE pin (pin 4) or a logic LOW on the ENABLE pin (pin 12) will enable
the differential driver outputs. A logic LOW on the ENABLE pin (pin 4) and a logic HIGH on the ENABLE pin
(pin 12) will force the driver outputs into high impedance (high-Z). Refer to the truth table in Table 1.
All drivers are internally protected against short circuits on their outputs. The driver outputs are short-circuit
limited to 150mA. The driver output skew times are typically 0.8ns. To minimize reflections, the multipoint bus
transmission line should be terminated at both ends in its characteristic impedance, and stub lengths off the
main line should be kept as short as possible.
FIGURE 9. TWO-WIRE BALANCED SYSTEM, RS-422
TABLE 1: TRUTH TABLE, ENABLE/DISABLE FUNCTION COMMON TO ALL FOUR RS-422 DRIVERS
ENABLE
ENABLE
INPUT
NON-INVERTING A
OUTPUT
INVERTING B OUTPUT
LOW
HIGH
don’t care
high-Z
high-Z
HIGH
don’t care
LOW
LOW
HIGH
don’t care
LOW
HIGH
HIGH
LOW
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SP26LV431
HIGH SPEED +3.3V QUAD RS-422 DIFFERENTIAL LINE DRIVER
FIGURE 10. DIFFERENTIAL PROPAGATION DELAY VS TEMPERATURE
FIGURE 11. DIFFERENTIAL PROPAGATION DELAY VS VOLTAGE
10
REV. 1.1.0
SP26LV431
REV. 1.1.0
HIGH SPEED +3.3V QUAD RS-422 DIFFERENTIAL LINE DRIVER
FIGURE 12. DIFFERENTIAL SKEW VS TEMPERATURE
FIGURE 13. DIFFERENTIAL SKEW VS VOLTAGE
11
SP26LV431
HIGH SPEED +3.3V QUAD RS-422 DIFFERENTIAL LINE DRIVER
FIGURE 14. DIFFERENTIAL TRANSITION TIME VS TEMPERATURE
FIGURE 15. DIFFERENTIAL TRANSITION TIME VS VOLTAGE
12
REV. 1.1.0
SP26LV431
REV. 1.1.0
HIGH SPEED +3.3V QUAD RS-422 DIFFERENTIAL LINE DRIVER
FIGURE 16. COMPLEMENTARY SKEW VS TEMPERATURE
FIGURE 17. COMPLEMENTARY SKEW VS VOLTAGE
13
SP26LV431
HIGH SPEED +3.3V QUAD RS-422 DIFFERENTIAL LINE DRIVER
FIGURE 18. DIFFERENTIAL VOUT VS IOUT (TEMPERATURE)
FIGURE 19. DIFFERENTIAL VOUT VS IOUT (VCC)
14
REV. 1.1.0
SP26LV431
REV. 1.1.0
HIGH SPEED +3.3V QUAD RS-422 DIFFERENTIAL LINE DRIVER
FIGURE 20. VOUT HIGH VS IOUT (TEMPERATURE)
FIGURE 21. VOUT HIGH VS IOUT (VCC)
15
SP26LV431
HIGH SPEED +3.3V QUAD RS-422 DIFFERENTIAL LINE DRIVER
FIGURE 22. VOUT LOW VS CURRENT (TEMPERATURE)
FIGURE 23. VOUT LOW VS CURRENT (VCC)
16
REV. 1.1.0
SP26LV431
REV. 1.1.0
HIGH SPEED +3.3V QUAD RS-422 DIFFERENTIAL LINE DRIVER
FIGURE 24. SUPPLY CURRENT VS TEMPERATURE
FIGURE 25. SUPPLY CURRENT VS VOLTAGE
17
SP26LV431
HIGH SPEED +3.3V QUAD RS-422 DIFFERENTIAL LINE DRIVER
FIGURE 26. SUPPLY CURRENT VS DATA RATE
FIGURE 27. ICC (LOADED) VS DATA RATE
18
REV. 1.1.0
SP26LV431
REV. 1.1.0
HIGH SPEED +3.3V QUAD RS-422 DIFFERENTIAL LINE DRIVER
FIGURE 28. SHORT CIRCUIT CURRENT VS TEMPERATURE
FIGURE 29. SHORT CIRCUIT CURRENT VS VOLTAGE
19
SP26LV431
HIGH SPEED +3.3V QUAD RS-422 DIFFERENTIAL LINE DRIVER
PACKAGE DIMENSIONS (16 PIN NSOIC)
20
REV. 1.1.0
SP26LV431
REV. 1.1.0
HIGH SPEED +3.3V QUAD RS-422 DIFFERENTIAL LINE DRIVER
PACKAGE DIMENSIONS (16 PIN PDIP)
21
SP26LV431
HIGH SPEED +3.3V QUAD RS-422 DIFFERENTIAL LINE DRIVER
REV. 1.1.0
REVISION HISTORY
DATE
REVISION
DESCRIPTION
3/08/04
A
Production Release.
2/24/05
B
Include tape and reel p/n’s.
9/05/08
1.0.0
Converted to Exar standard datasheet format. Add -40C to +85C temperature range
option. Changed revision to 1.0.0.
2/19/09
1.1.0
Add 3ns maximum driver skew for industrial temperature option.
NOTICE
EXAR Corporation reserves the right to make changes to the products contained in this publication in order to
improve design, performance or reliability. EXAR Corporation assumes no responsibility for the use of any
circuits described herein, conveys no license under any patent or other right, and makes no representation that
the circuits are free of patent infringement. Charts and schedules contained here in are only for illustration
purposes and may vary depending upon a user’s specific application. While the information in this publication
has been carefully checked; no responsibility, however, is assumed for inaccuracies.
EXAR Corporation does not recommend the use of any of its products in life support applications where the
failure or malfunction of the product can reasonably be expected to cause failure of the life support system or
to significantly affect its safety or effectiveness. Products are not authorized for use in such applications unless
EXAR Corporation receives, in writing, assurances to its satisfaction that: (a) the risk of injury or damage has
been minimized; (b) the user assumes all such risks; (c) potential liability of EXAR Corporation is adequately
protected under the circumstances.
Copyright 2009 EXAR Corporation
Datasheet February 2009.
Send your UART technical inquiry with technical details to hotline: [email protected].
Reproduction, in part or whole, without the prior written consent of EXAR Corporation is prohibited.
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