Renesas ISL3160E ±10kv esd protected, 125â°c, 40mbps, 5v, full-duplex, full fail-safe rs-485/rs-422 transceiver Datasheet

DATASHEET
ISL3160E
FN8980
Rev.0.00
Mar 21, 2018
±10kV ESD Protected, +125°C, 40Mbps, 5V, Full-Duplex, Full Fail-Safe
RS-485/RS-422 Transceiver
The ISL3160E is a ±10kV IEC61000 ESD protected, 5V
powered, full-duplex transceiver that meets both the
RS-485 and RS-422 standards for balanced
communication. It also features a large differential output
voltage and high data rate (up to 40Mbps) and is offered
in the standard industrial (-40°C to +85°C) and extended
industrial (-40°C to +125°C) temperature ranges. The
low bus currents (+220µA/-150µA) present a 1/5 unit
load to the RS-485 bus. This allows up to 160
transceivers on the network without violating the RS-485
specification’s load limit and without using repeaters.
This transceiver requires a 5V ±10% tolerance supply,
and delivers at least a 2.1V differential output voltage
over this supply range. This translates into better noise
immunity (data integrity), longer reach, or the ability to
drive up to six 120Ω terminations in “star” or other
nonstandard bus topologies at the exceptional 40Mbps
data rate.
SCSI applications benefit from the ISL3160E’s low
receiver and transmitter part-to-part skews. The
ISL3160E is perfect for high speed parallel applications
requiring simultaneous capture of large numbers of bits.
The low bit-to-bit skew eases the timing constraints on
the data latching signal.
Receiver (Rx) inputs feature a “full fail-safe” design,
which ensures a logic high Rx output if Rx inputs are
floating, shorted, or terminated but undriven. Rx outputs
feature high drive levels (typically >30mA at VOL = 1V)
to ease the design of optically isolated interfaces.
Hot plug circuitry ensures that the Tx and Rx outputs
remain in a high impedance state while the power supply
stabilizes.
Features
• High ESD protection on RS-485 I/O pins: ±10kV
• Class 3 HBM ESD level on all other pins: >3kV
• Large differential VOUT 2.8V into 54Ω better noise
immunity, or drive up to 6 terminations
• High data rates: up to 40Mbps
• Specified for +125°C operation (FBZ), +85°C (IBZ)
• 11/13ns (maximum) Tx/Rx propagation delays; 1.5ns
(maximum) skew
• 1/5 unit load allows up to 160 devices on the bus
• Full fail-safe (open, shorted, terminated/undriven)
receiver
• High Rx IOL to drive opto-couplers for isolated
applications
• Hot plug - Tx and Rx outputs remain three-state
during power-up
• Low quiescent supply current: 4mA
• Low current shutdown mode: 1µA
• -7V to +12V common-mode input voltage range
• Three-state Rx and Tx outputs
• Operates from a single +5V supply (10% tolerance)
• Current limiting and thermal shutdown for driver
overload protection
• Pb-free (RoHS compliant)
Applications
• Industrial robotics
Driver (Tx) outputs are short-circuit protected, even for
voltages exceeding the power supply voltage.
Additionally, on-chip thermal shutdown circuitry
disables the Tx outputs to prevent damage if power
dissipation becomes excessive.
• SCSI “fast 40” drivers and receivers
Related Literature
• Security networks
For a full list of related documents, visit our website
• Building environmental control systems
• ISL3160E product page
FN8980 Rev.0.00
Mar 21, 2018
• Motor controller/position encoder systems
• Factory automation
• Field bus networks
• Industrial/process control networks
Page 1 of 20
ISL3160E
+5V
+5V
+
14
VCC
2 RO
R
A 12
0.1µF
0.1µF
RT
+
14
9 Y
B 11
VCC
D
10 Z
DI 5
3 RE
DE 4
4 DE
RE 3
5 DI
Z 10
RT
Y 9
D
11 B
R
12 A
GND
RO 2
GND
6, 7
6, 7
Figure 1. Typical Operating Circuit
FN8980 Rev.0.00
Mar 21, 2018
Page 2 of 20
ISL3160E
1.
1. Overview
Overview
1.1
Ordering Information
Part Number
(Notes 2, 3)
Temp. Range
(°C)
Part Marking
Tape and Reel
(Units)
Package
(RoHS Compliant)
Pkg. Dwg. #
ISL3160EIBZ
ISL3160 EIBZ
-40 to +85
-
14 Ld SOIC
M14.15
ISL3160EIBZ-T (Note 1)
ISL3160 EIBZ
-40 to +85
2.5k
14 Ld SOIC
M14.15
ISL3160EFBZ
ISL3160 EFBZ
-40 to +125
-
14 Ld SOIC
M14.15
ISL3160EFBZ-T (Note 1)
ISL3160 EFBZ
-40 to +125
2.5k
14 Ld SOIC
M14.15
Notes:
1. Refer to TB347 for details about reel specifications.
2. Pb-free plus anneal products employ special Pb-free material sets; molding compounds/die attach materials and 100% matte tin
plate termination finish, which are RoHS compliant and compatible with both SnPb and Pb-free soldering operations. Pb-free
products are MSL classified at Pb-free peak reflow temperatures that meet or exceed the Pb-free requirements of IPC/JEDEC J
STD-020.
3. For Moisture Sensitivity Level (MSL), refer to the ISL3160E product information page. For more information about MSL, refer to
TB363.
Table 1. Key Differences Between High-Speed Interface Family of Parts
Full/Half Duplex
VCC (V)
VOD (V)
Data Rate (Mbps)
ISL3160E
Part Number
Full
5
2.1
40
ISL3159E
Half
5
2.1
40
ISL3259E
Half
5
2.1
100
ISL3179E
Half
3.3
1.5
40
ISL3180E
Full
3.3
1.5
40
1.2
Pin Configurations
ISL3160E
(14 Ld SOIC)
Top View
FN8980 Rev.0.00
Mar 21, 2018
NC 1
14 VCC
RO 2
13 NC
RE 3
12 A
DE 4
11 B
DI 5
10 Z
GND 6
9 Y
GND 7
8 NC
Page 3 of 20
ISL3160E
1. Overview
1.3
Pin Descriptions
Pin Number
Pin
2
RO
Receiver output.
If A - B ≥ -50mV, RO is high.
If A - B ≤ -200mV, RO is low.
If A and B are unconnected (floating) or shorted, or connected to a terminated bus that is undriven, RO is
high.
Function
3
RE
Receiver output enable.
RO is enabled when RE is low.
RO is high impedance when RE is high.
If the Rx enable function isn’t required, connect RE directly to GND.
4
DE
Driver output enable. The driver outputs, Y and Z, are enabled by bringing DE high. They are high
impedance when DE is low. If the Tx enable function isn’t required, connect DE to VCC through a 1kΩ or
greater resistor.
5
DI
Driver input. A low on DI forces output Y low and output Z high. Similarly, a high on DI forces output Y
high and output Z low.
6, 7
GND
9
Y
±10kV IEC61000 ESD protected RS-485/422 level, non-inverting driver output.
10
Z
±10kV IEC61000 ESD protected RS-485/422 level, inverting rdriver output.
Ground connection.
11
B
±10kV IEC61000 ESD protected RS-485/422 level, inverting receiver input.
12
A
±10kV IEC61000 ESD protected RS-485/422 level, non-inverting receiver input.
14
VCC
System power supply input (4.5V to 5.5V).
1, 8, 13
NC
No internal connection.
1.4
Truth Tables
Driver
Inputs
Outputs
RE
DE
DI
B/Z
A/Y
X
1
1
0
1
X
1
0
1
0
0
0
X
High-Z
High-Z
1
0
X
High-Z (Note 4)
High-Z (Note 4)
Receiver
Inputs
Output
RE
DE
A-B
RO
0
X
VAB ≥-0.05V
1
0
X
-0.05V >VAB >-0.2V
Undetermined
0
X
VAB ≤ -0.2V
0
0
X
Inputs Open/Shorted
1
1
1
X
High-Z
1
0
X
High-Z (Note 4)
Note:
4. Shutdown mode
FN8980 Rev.0.00
Mar 21, 2018
Page 4 of 20
ISL3160E
2.
2. Specifications
Specifications
2.1
Absolute Maximum Ratings
Parameter
Minimum
Maximum
Unit
+7
V
+7
V
-9
+13
V
-0.3
(VCC +0.3)
V
VCC to GND
-0.3
Input Voltages DI, DE, RE
Input/Output Voltages A, B, Y, Z
Input/Output Voltages RO
Short-Circuit Duration Y, Z
Continuous
Refer to “ESD Performance” on page 7
ESD Rating
CAUTION: Do not operate at or near the maximum ratings listed for extended periods of time. Exposure to such conditions may
adversely impact product reliability and result in failures not covered by warranty.
2.2
Thermal Information
Thermal Resistance (Typical)
14 Ld SOIC Package (Notes 5, 6)
JA (°C/W)
JC (°C/W)
80
41
Notes:
5. JA is measured in free air with the component mounted on a high-effective thermal conductivity test board. See TB379.
6. For JC, the “case temp” location is taken at the package top center.
Parameter
Minimum
Maximum Junction Temperature (Plastic Package)
Maximum Storage Temperature Range
-65
Pb-Free Reflow Profile
2.3
Maximum
Unit
+150
°C
+150
°C
Refer to TB493
Recommended Operating Conditions
Parameter
Minimum
Maximum
Unit
Temperature Range ISL3160EFBZ
-40
+125
°C
Temperature Range ISL3160EIBZ
-40
+85
°C
FN8980 Rev.0.00
Mar 21, 2018
Page 5 of 20
ISL3160E
2.4
2. Specifications
Electrical Specifications
Test Conditions: VCC = 4.5V to 5.5V; unless otherwise specified. Typical values are at VCC = 5V, TA = +25°C, Boldface limits apply
across the operating temperature range (Note 7).
Parameter
Symbol
Test Conditions
Temp
Min
(°C) (Note 16)
Typ
Max
(Note 16)
VCC
Unit
DC Characteristics
Driver Differential VOUT
Change in Magnitude of
Driver Differential VOUT for
Complementary Output
States
VOD
VOD
Driver Common-Mode VOUT
VOC
Change in Magnitude of
Driver Common-Mode VOUT
for Complementary Output
States
VOC
No Load
Full
-
-
RL = 100Ω (RS-422) (Figure 2)
Full
2.6
3.4
-
V
RL = 54Ω (RS-485) (Figure 2)
Full
2.1
2.8
VCC
V
RL = 60Ω, -7V ≤ VCM ≤ 12V (Figure 3,
Note 15)
Full
1.9
2.7
-
V
RL = 54Ω or 100Ω (Figure 2)
Full
-
0.01
0.2
V
RL = 54Ω or 100Ω (Figure 2, Note 15)
Full
-
2
2.5
V
RL = 54Ω or 100Ω (Figure 2)
Full
-
0.02
0.2
V
Logic Input High Voltage
VIH
DI, DE, RE
Full
2
-
-
V
Logic Input Low Voltage
VIL
DI, DE, RE
Full
-
-
0.8
V
Logic Input Current
IIN1
DI = DE = RE = 0V or VCC
Full
-2
-
2
µA
Input Current (A/Y, B/Z)
IIN2
DE = 0V, VCC = 0V or
5.5V
Full
-
-
220
µA
Driver Short-Circuit Current,
VO = High or Low
IOSD1
VIN = 12V
Full
-160
-
-
µA
DE = VCC, -7V ≤ VY or VZ ≤ 12V
VIN = -7V
Full
-
-
±250
mA
Differential Capacitance
CD
A/Y to B/Z
+25
-
9
-
pF
Receiver Differential
Threshold Voltage
VTH
-7V ≤ VCM ≤ 12V
Full
-200
-
-50
mV
Receiver Input Hysteresis
VTH
VCM = 0V
+25
-
28
-
mV
Receiver Output High
Voltage
VOH
IO = -8mA, VID = -50mV
Full
VCC - 0.5
-
-
V
Receiver Output Low
Voltage
VOL
IO = +10mA, VID = -200mV
Full
-
-
0.4
V
Receiver Output Low
Current
IOL
VOL = 1V, VID = -200mV
Full
25
40
-
mA
Three-State (High
Impedance) Receiver
Output Current
IOZR
0.4V ≤ VO ≤ 2.4V
Full
-1
0.015
1
µA
Receiver Input Resistance
RIN
-7V ≤ VCM ≤ 12V
Full
54
80
-
kΩ
Receiver Short-Circuit
Current
IOSR
0V ≤ VO ≤ VCC
Full
±20
-
±110
mA
No-Load Supply Current
(Note 8)
ICC
DI = DE = 0V or VCC
Full
-
2.6
4
mA
Shutdown Supply Current
ISHDN
DE = 0V, RE = VCC, DI = -40oC to +85oC
0V or VCC
-40oC to +125oC
Full
-
0.05
1
µA
1.4
2
µA
Supply Current
FN8980 Rev.0.00
Mar 21, 2018
Full
Page 6 of 20
ISL3160E
2. Specifications
Test Conditions: VCC = 4.5V to 5.5V; unless otherwise specified. Typical values are at VCC = 5V, TA = +25°C, Boldface limits apply
across the operating temperature range (Note 7). (Continued)
Parameter
Symbol
Test Conditions
Temp
Min
(°C) (Note 16)
Typ
Max
(Note 16)
Unit
ESD Performance
RS-485 Pins (A, B, Y, Z)
All Pins
IEC61000-4-2, Air-Gap Discharge Method
+25
-
±4
-
kV
IEC61000-4-2, Contact Discharge Method
+25
-
±5
-
kV
Human Body Model, From Bus Pins to GND
+25
-
±10
-
kV
HBM, per MIL-STD-883 Method 3015
+25
-
> ±3
-
kV
Machine Model
+25
-
> ±150
-
V
Driver Switching Characteristics
Maximum Data Rate
fMAX
VOD ≥ ±1.5V, RD = 54Ω, CL = 100pF
(Figure 8)
Full
40
60
-
Mbps
Driver Differential Output
Delay
tDD
RD = 54Ω, CD = 50pF (Figure 2)
Full
-
11
16
ns
Driver Differential Output
Skew
tSKEW
RD = 54Ω, CD = 50pF (Figure 2)
Full
-
0.5
1.5
ns
Prop Delay Part-to-Part
Skew
tSKP-P
RD = 54Ω, CD = 50pF (Figure 2, Note 14)
Full
-
-
4
ns
Driver Differential Rise or
Fall Time
tR, tF
RD = 54Ω, CD = 50pF (Figure 2)
Full
-
4
8
ns
Driver Enable to Output High
tZH
RL = 110Ω, CL = 50pF, SW = GND
(Figure 6, Note 9)
Full
-
18
25
ns
Driver Enable to Output Low
tZL
RL = 110Ω, CL = 50pF, SW = VCC
(Figure 6, Note 9)
Full
-
16
25
ns
Driver Enable Time Skew
tENSKEW
|tZH (Y or Z) - tZL (Z or Y)|
Full
-
2.5
-
ns
Driver Disable from Output
High
tHZ
RL = 110Ω, CL = 50pF, SW = GND (Figure 6)
Full
-
15
25
ns
Driver Disable from Output
Low
tLZ
RL = 110Ω, CL = 50pF, SW = VCC (Figure 6)
Full
-
18
25
ns
Full
-
3
-
ns
Driver Disable Time Skew
tDISSKEW |tHZ (Y or Z) - tLZ (Z or Y)|
Full
60
-
600
ns
Driver Enable from
Shutdown to Output High
tZH(SHDN) RL = 110Ω, CL = 50pF, SW = GND
(Figure 6, Notes 11, 12)
Full
-
-
1000
ns
Driver Enable from
Shutdown to Output Low
tZL(SHDN) RL = 110Ω, CL = 50pF, SW = VCC
(Figure 6, Notes 11, 12)
Full
-
-
1000
ns
Full
40
60
-
Mbps
Full
-
10
16.5
ns
Time to Shutdown
tSHDN
(Note 11)
Receiver Switching Characteristics
Maximum Data Rate
Receiver Input to Output
Delay
Receiver Skew | tPLH - tPHL |
Prop Delay Part-to-Part
Skew
fMAX
VID = ±1.5V
tPLH, tPHL (Figure 8)
tSKD
tSKP-P
(Figure 8)
Full
-
0
1.5
ns
(Figure 8, Note 14)
Full
-
-
4
ns
Receiver Enable to Output
High
tZH
RL = 1kΩ, CL = 15pF, SW = GND
(Figure 12, Note 10)
Full
-
10
15
ns
Receiver Enable to Output
Low
tZL
RL = 1kΩ, CL = 15pF, SW = VCC
(Figure 12, Note 10)
Full
-
11
15
ns
Receiver Disable from
Output High
tHZ
RL = 1kΩ, CL = 15pF, SW = GND (Figure 12)
Full
-
10
15
ns
FN8980 Rev.0.00
Mar 21, 2018
Page 7 of 20
ISL3160E
2. Specifications
Test Conditions: VCC = 4.5V to 5.5V; unless otherwise specified. Typical values are at VCC = 5V, TA = +25°C, Boldface limits apply
across the operating temperature range (Note 7). (Continued)
Parameter
Receiver Disable from
Output Low
Time to Shutdown
Symbol
tLZ
tSHDN
Test Conditions
Temp
Min
(°C) (Note 16)
Typ
Max
(Note 16)
Unit
RL = 1kΩ, CL = 15pF, SW = VCC (Figure 12)
Full
-
10
15
ns
(Note 11)
Full
60
-
600
ns
Receiver Enable from
Shutdown to Output High
tZH(SHDN) RL = 1kΩ, CL = 15pF, SW = GND
(Figure 12, Notes 11, 13)
Full
-
-
1000
ns
Receiver Enable from
Shutdown to Output Low
tZL(SHDN) RL = 1kΩ, CL = 15pF, SW = VCC
(Figure 12, Notes 11, 13)
Full
-
-
1000
ns
Notes:
7. All currents into device pins are positive; all currents out of device pins are negative. All voltages are referenced to device ground
unless otherwise specified.
8. Supply current specification is valid for loaded drivers when DE = 0V.
9. Because of the shutdown feature, keep RE = 0 to prevent the device from entering SHDN.
10. Because of the shutdown feature, the RE signal high time must be short enough (typically <100ns) to prevent the device from
entering shutdown.
11. These ICs are put into shutdown by bringing RE high and DE low. If the inputs are in this state for less than 60ns, the parts will
not enter shutdown. If the inputs are in this state for at least 700ns, the parts will enter shutdown. See “Low Power Shutdown
Mode” on page 17.
12. Keep RE = VCC, and set the DE signal low time >700ns to ensure that the device enters shutdown.
13. Set the RE signal high time >700ns to ensure that the device enters shutdown.
14. This is the part-to-part skew between any two units tested with identical test conditions (temperature, VCC, etc.).
15. VCC = 5V ±5%.
16. Parts are 100% tested at +25°C. Over-temperature limits established by characterization and are not production tested.
FN8980 Rev.0.00
Mar 21, 2018
Page 8 of 20
ISL3160E
3.
3. Test Circuits and Waveforms
Test Circuits and Waveforms
VCC
RL/2
DE
Z
DI
DI
VOD
D
375Ω
DE
VCC
Z
VOD
D
Y
VCM
RL = 60Ω
-7V TO +12V
Y
VOC
RL/2
375Ω
Figure 2. DC Driver Test Circuits VOD and VOC
Figure 3. DC Driver Test Circuits VOD with
Common-Mode Load
3V
DI
1.5V
1.5V
0V
VCC
tPLH
DE
Z
DI
RD
D
tPHL
OUT (Z)
VOH
OUT (Y)
VOL
CD
Y
Signal
Generator
90%
DIFF Out (Y - Z)
+VOD
90%
10%
10%
tR
-VOD
tF
SKEW = |tPLH - tPHL|
Figure 4. Driver Propagation Delay and Differential
Transition Times Test Circuit
FN8980 Rev.0.00
Mar 21, 2018
Figure 5. Driver Propagation Delay and Differential
Transition Times Measurement Points
Page 9 of 20
ISL3160E
3. Test Circuits and Waveforms
DE
Z
DI
110Ω
VCC
D
Signal
Generator
SW
Y
GND
3V
50pF
DE
(Note 11)
1.5V
0V
tZH, tZH(SHDN)
(Note 11)
Parameter
Output
RE
DI
Y/Z
X
1/0
GND
tLZ
Y/Z
X
0/1
VCC
tZH
Y/Z
0 (Note 9)
1/0
GND
tZL
Y/Z
0 (Note 9)
0/1
VCC
tHZ(SHDN)
Y/Z
1 (Note 12)
1/0
GND
tLZ(SHDN)
Y/Z
1 (Note 12)
0/1
tHZ
VOH - 0.5V
50%
OUT (Y, Z)
VOH
0V
tZL, tZL(SHDN)
tLZ
(Note 11)
VCC
OUT (Y, Z)
50%
Output Low
VCC
Figure 6. Driver Enable and Disable Times Test Circuit
VCC
Output High
SW
tHZ
1.5V
VOL + 0.5V V
OL
Figure 7. Driver Enable and Disable Times Measurement
Points
DE
+
Z
DI
54Ω
D
Y
VOD
3V
CL
DI
0V
-
Signal
Generator
CL
+VOD
DIFF Out (Y - Z)
-VOD
Figure 8. Driver Data Rate Test Circuit
15pF
B
A
Figure 9. Driver Data Rate Measurement Points
+3V
RE
+1.5V
0V
R
A
1.5V
1.5V
RO
0V
tPLH
Signal
Generator
tPHL
VCC
RO
1.7V
1.7V
0V
Figure 10. Receiver Propagation Delay Test Circuit
FN8980 Rev.0.00
Mar 21, 2018
Figure 11. Receiver Propagation Delay Measurement
Points
Page 10 of 20
ISL3160E
3. Test Circuits and Waveforms
RE
GND
B
A
1kΩ
RO
R
VCC
SW
Signal
Generator
GND
(Note 11)
15pF
RE
3V
1.5V
1.5V
0V
tZH, tZH(SHDN)
Parameter
DE
A
SW
tHZ
0
+1.5V
GND
tLZ
0
-1.5V
VCC
tZH (Note 10)
0
+1.5V
GND
tZL (Note 10)
0
-1.5V
VCC
(Note 11)
tHZ(SHDN) (Note 13)
0
+1.5V
GND
RO
tLZ(SHDN) (Note 13)
0
-1.5V
VCC
Figure 12. Receiver Enable and Disable Times Test
Circuit
FN8980 Rev.0.00
Mar 21, 2018
(Note 11)
RO
Output High
tHZ
VOH - 0.5V
1.5V
VOH
0V
tZL, tZL(SHDN)
tLZ
VCC
1.5V
Output Low
VOL + 0.5V V
OL
Figure 13. Receiver Enable and Disable Times
Measurement Points
Page 11 of 20
ISL3160E
4.
4. Typical Performance Curves
Typical Performance Curves
VCC = 5V, TA = +25°C; unless otherwise specified
110
3.4
+85°C
90
Differential Output Voltage (V)
Driver Output Current (mA)
3.5
RD = 20Ω
+25°C
100
RD = 30Ω
80
+125°C
70
RD = 54Ω
60
50
40
RD = 100Ω
30
20
RD = 100Ω
3.3
3.2
3.1
3.0
2.9
2.8
2.7
RD = 54Ω
2.6
10
0
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
Differential Output Voltage (V)
4.0
4.5
2.5
-40
5.0
-15
10
35
60
85
110
125
Temperature (°C)
Figure 15. Driver Differential Output Voltage vs
Temperature
Figure 14. Driver Output Current vs Differential Output
Voltage
2.55
200
150
2.50
Y or Z = Low
50
ICC (mA)
Output Current (mA)
100
0
2.45
2.40
-50
Y or Z = High
2.35
-100
DE = VCC, RE = X OR DE = GND, RE = GND
-150
-7 -6
-4
-2
0
2
4
Output Voltage (V)
6
8
10
Figure 16. Driver Output Current vs Short-Circuit
Voltage
FN8980 Rev.0.00
Mar 21, 2018
12
2.30
-40
-15
10
35
60
85
110 125
Temperature (°C)
Figure 17. Supply Current vs Temperature
Page 12 of 20
ISL3160E
4. Typical Performance Curves
VCC = 5V, TA = +25°C; unless otherwise specified (Continued)
9.0
0.9
|tPLH - tPHL|
8.8
0.8
8.4
0.7
tPHL
8.2
Skew (ns)
Propagation Delay (ns)
8.6
8.0
7.8
0.6
0.5
7.6
tPLH
7.4
0.4
7.2
-15
10
35
60
85
0.3
-40
110 125
-15
10
Temperature (°C)
5
0
RO
0
Driver Output (V)
Driver Output (V)
2
1
-1
125
110
5
DI
0
5
RO
0
3
3
0
85
RDIFF = 54Ω, CD = 50pF
Receiver Output (V)
Receiver Output (V)
RDIFF = 54Ω, CD = 50pF
5
60
Figure 19. Driver Differential Skew vs Temperature
Driver Input (V)
Figure 18. Driver Differential Propagation Delay vs
Temperature
DI
35
Temperature (°C)
Driver Input (V)
7.0
-40
Y-Z
-2
-3
Time (5ns/DIV)
Figure 20. Driver and Receiver Waveforms
FN8980 Rev.0.00
Mar 21, 2018
2
1
0
-1
Y-Z
-2
-3
Time (5ns/DIV)
Figure 21. Driver and Receiver Waveforms
Page 13 of 20
ISL3160E
4. Typical Performance Curves
RO
0
Driver+cable Delay
(~156ns)
0
5.0
A-B
0
-1.5
-3.0
RO
0
3.0
1.5
5
Driver+cable Delay
1.5
Driver Input (V)
5.0
DI = 40Mbps
Receiver Output (V)
0
3.0
Receiver Input (V)
5
Receiver Input (V)
Receiver Output (V)
DI = 40Mbps
Driver Input (V)
VCC = 5V, TA = +25°C; unless otherwise specified (Continued)
(~480ns)
A-B
0
-1.5
-3.0
Time (10ns/DIV)
Time (10ns/DIV)
Figure 22. Driver and Receiver Waveforms Driving 100ft
(31m) of Cat 5 Cable (Double Terminated with 120Ω)
Figure 23. Driver and Receiver Waveforms Driving 350ft
(107m) of Cat 5 Cable (Double Terminated with 120Ω)
70
VOL, +25°C
Receiver Output Current (mA)
60
VOH, +25°C
VOL, +85°C
50
VOL, +125°C
40
30
VOH, +85°C
VOH, +125°C
20
10
0
0
1
2
3
4
5
Receiver Output Voltage (V)
Figure 24. Receiver Output Current vs Receiver Output Voltage
FN8980 Rev.0.00
Mar 21, 2018
Page 14 of 20
ISL3160E
5.
5. Application Information
Application Information
RS-485 and RS-422 are differential (balanced) data transmission standards for use in long haul or noisy environments.
RS-422 is a subset of RS-485, so RS-485 transceivers are also RS-422 compliant. RS-422 is a point-to-multipoint
(multidrop) standard, which allows only one driver and up to 10 receivers on each bus, assuming one unit load devices.
RS-485 is a true multipoint standard, which allows up to 32 one unit load devices (any mix of drivers and receivers) on
each bus. To allow for multipoint operation, the RS-485 specification requires that drivers must handle bus contention
without sustaining any damage.
Another important advantage of RS-485 is the extended Common-Mode Range (CMR), which specifies that the driver
outputs and receiver inputs withstand signals that range from +12V to -7V. RS-422 and RS-485 are intended for cable
lengths as long as 4000ft (~1200m), so the wide CMR is necessary to handle ground potential differences, as well as
voltages induced in the cable by external fields.
5.1
Receiver (Rx) Features
This transceiver uses a differential input receiver for maximum noise immunity and common-mode rejection. Input
sensitivity is ±200mV, as required by the RS-422 and RS-485 specifications. Receiver inputs function with
common-mode voltages as great as 7V outside the power supplies (that is, +12V and -7V), making them ideal for
long networks, or industrial environments, where induced voltages are a realistic concern.
The receiver input resistance of 50kΩ surpasses the RS-422 specification of 4kΩ, and is five times the RS-485
“Unit Load” (UL) requirement of 12kΩ minimum. Thus, the ISL3160E is known as a “one-fifth UL” transceiver,
and there can be up to 160 devices on the RS-485 bus while still complying with the RS-485 loading specification.
The receiver is a “full fail-safe” version that assures a high level receiver output if the receiver inputs are
unconnected (floating), shorted together, or connected to a terminated bus with all the transmitters disabled
(terminated/undriven).
Rx outputs deliver large low state currents (typically >30mA) at VOL = 1V (to ease the design of optically coupled
isolated networks).
Receivers easily meet the 40Mbps data rate supported by the driver, and the receiver output is tri-statable using the
active low RE input.
5.2
Driver (Tx) Features
The RS-485/RS-422 driver is a differential output device that delivers at least 2.1V across a 54Ω load (RS-485),
and at least 2.6V across a 100Ω load (RS-422) even with VCC = 4.5V. The drivers feature low propagation delay
skew to maximize bit width and to minimize EMI.
Driver outputs are not slew rate limited, so faster output transition times allow data rates of at least 40Mbps. Driver
outputs are tri-statable using the active high DE input.
For parallel applications, bit-to-bit skews between any two ISL3160E transmitter and receiver pairs are assured to
be no worse than 8ns (4ns max for any two Tx, 4ns max for any two Rx).
5.2.1
High VOD Improves Noise Immunity and Flexibility
The ISL3160E driver design delivers larger differential output voltages (VOD) than the RS-485 standard
requires, or than most RS-485 transmitters can deliver. The minimum ±2.1V VOD assures at least ±600mV
more noise immunity than networks built using standard 1.5V VOD transmitters.
Another advantage of the large VOD is the ability to drive more than two bus terminations, which allows use of
the ISL3160E in “star” and other multiterminated, nonstandard network topologies. Figure 14 on page 12
details the transmitter’s VOD vs IOUT characteristic, and includes load lines for four (30Ω) and six (20Ω) 120Ω
terminations. Figure 14 shows that the driver typically delivers 1.9/1.5V into 4/6 terminations, even at +85°C.
The RS-485 standard requires a minimum 1.5V VOD into two terminations, but the ISL3160E typically delivers
RS-485 voltage levels with 2 to 3 times the number of terminations.
FN8980 Rev.0.00
Mar 21, 2018
Page 15 of 20
ISL3160E
5.3
5. Application Information
ESD Protection
All pins on the ISL3160E include Class 3 (>3kV) Human Body Model (HBM) ESD protection structures, but the
RS-485 pins (driver outputs and receiver inputs) incorporate advanced structures allowing them to survive ESD
events in excess of ±10kV HBM and ±5kV IEC61000-4-2. The RS-485 pins are particularly vulnerable to ESD
strikes because they typically connect to an exposed port on the exterior of the finished product. Simply touching
the port pins, or connecting a cable, can cause an ESD event that can destroy unprotected ICs. These new ESD
structures protect the device whether or not it is powered up and without degrading the RS-485 common-mode
range of -7V to +12V. This built-in ESD protection eliminates the need for board level protection structures (for
example, transient suppression diodes) and the associated undesirable capacitive load they present.
5.4
Hot Plug Function
When a piece of equipment powers up, a period of time occurs in which the processor or ASIC driving the RS-485
control lines (DE, RE) is unable to ensure that the RS-485 Tx and Rx outputs are kept disabled. If the equipment is
connected to the bus, a driver activating prematurely during power-up may crash the bus. To avoid this scenario,
the ISL3160E incorporates a “hot plug” function. Circuitry monitoring VCC ensures that the Tx and Rx outputs remain
disabled during power-up and power-down, regardless of the state of DE and RE, if VCC is less than ~3.2V. This gives
the processor or ASIC a chance to stabilize and drive the RS-485 control lines to the proper states.
RE = GND
3.3V
3.1V
2.5
VCC
0
5.0
RL = 1kΩ
2.5
0
A/Y
ISL3160E
RL = 1kΩ
RO
ISL3160E
5.0
2.5
0
Receiver Output (V)
Driver Y Output (V)
5.0
VCC (V)
DE, DI = VCC
Time (40µs/DIV)
Figure 25. Hot Plug Performance (ISL3160E) vs ISL83086E without Hot Plug Circuitry
5.5
Data Rate, Cables, and Terminations
Twisted pair is the cable of choice for RS-485, RS-422, and PROFIBUS networks. Twisted pair cables tend to pick
up noise and other electromagnetically induced voltages as common-mode signals, which are effectively rejected
by the differential receivers in these ICs.
According to guidelines in the RS-422 and RS-485 specifications, networks operating at data rates in excess of
3Mbps should be limited to cable lengths of 100m (328ft) or less. The ISL3160E’s large differential output swing,
fast transition times, and high drive-current output stages allow operation even at 40Mbps over standard “CAT5”
cables in excess of 100m (328ft). Figure 23 on page 14 details the ISL3160E performance at this condition, with a
120Ω termination resistor at both the driver and the receiver ends. Note that the differential signal delivered to the
receiver at the end of the cable (A-B) still exceeds 1V, so even longer cables could be driven if lower noise margins
are acceptable. Of course, jitter or some other criteria may limit the network to shorter cable lengths than those
discussed here. If more noise margin is desired, shorter cables produce a larger receiver input signal as illustrated in
Figure 22 on page 14. Performance should be even better if using the “Type A” cable.
The ISL3160E may also be used at slower data rates over longer cables, but some limitations apply. The Rx is
optimized for high speed operation, so its output may glitch if the Rx input differential transition times are too slow.
FN8980 Rev.0.00
Mar 21, 2018
Page 16 of 20
ISL3160E
5. Application Information
Keeping the transition times below 500ns, (which equates to the Tx driving a 1000ft (305m) CAT 5 cable) yields
excellent performance across the full operating temperature range.
To minimize reflections, proper termination is imperative when using this high data rate transceiver. In
point-to-point, or point-to-multipoint (single driver on bus) networks, the main cable should be terminated in its
characteristic impedance (typically 120Ω for “Cat 5” and 220Ω for “Type A”) at the end farthest from the driver. In
multireceiver applications, stubs connecting receivers to the main cable should be kept as short as possible.
Multipoint (multidriver) systems require that the main cable be terminated in its characteristic impedance at both
ends. Stubs connecting a transceiver to the main cable should be kept as short as possible.
5.6
Built-In Driver Overload Protection
As stated previously, the RS-485 specification requires that drivers survive worst case bus contentions undamaged.
These transmitters meet this requirement using driver output short-circuit current limits, and on-chip thermal shutdown
circuitry.
The driver output stages incorporate short-circuit current limiting circuitry, which ensures that the output current
never exceeds the RS-485 specification, even at the common-mode voltage range extremes. In the event of a major
short-circuit condition, the device also includes a thermal shutdown feature that disables the drivers whenever the
die temperature becomes excessive. This eliminates the power dissipation, allowing the die to cool. The drivers
automatically reenable after the die temperature drops about 15°C. If the contention persists, the thermal
shutdown/reenable cycle repeats until the fault is cleared. Receivers stay operational during thermal shutdown.
5.7
Low Power Shutdown Mode
This BiCMOS transceiver uses a fraction of the power required by its bipolar counterparts, and it includes a
shutdown feature that reduces the already low quiescent ICC to a 50nA trickle. It enters shutdown whenever the
receiver and driver are simultaneously disabled (RE = VCC and DE = GND) for a period of at least 600ns.
Disabling both the driver and the receiver for less than 60ns assures that the transceiver will not enter shutdown.
Note that receiver and driver enable times increase when the transceiver enables from shutdown. Refer to Notes 9,
10, 11, 12, and 13 on page 8 for more information.
FN8980 Rev.0.00
Mar 21, 2018
Page 17 of 20
ISL3160E
6.
6. Revision History
Revision History
Rev.
Date
0.00
Mar 21, 2018
FN8980 Rev.0.00
Mar 21, 2018
Description
Initial release
Page 18 of 20
ISL3160E
7.
7. Package Outline Drawing
Package Outline Drawing
For the most recent package outline drawing, see M14.15.
M14.15
14 LEAD NARROW BODY SMALL OUTLINE PLASTIC PACKAGE
Rev 1, 10/09
8.65
A 3
4
0.10 C A-B 2X
6
14
DETAIL"A"
0.22±0.03
D
8
6.0
3.9
4
0.10 C D 2X
0.20 C 2X
7
PIN NO.1
ID MARK
5
0.31-0.51
B 3
(0.35) x 45°
4° ± 4°
6
0.25 M C A-B D
TOP VIEW
0.10 C
1.75 MAX
H
1.25 MIN
0.25
GAUGE PLANE C
SEATING PLANE
0.10 C
0.10-0.25
1.27
SIDE VIEW
(1.27)
DETAIL "A"
(0.6)
NOTES:
1. Dimensions are in millimeters.
Dimensions in ( ) for Reference Only.
2. Dimensioning and tolerancing conform to AMSEY14.5m-1994.
3. Datums A and B to be determined at Datum H.
(5.40)
4. Dimension does not include interlead flash or protrusions.
Interlead flash or protrusions shall not exceed 0.25mm per side.
5. The pin #1 indentifier may be either a mold or mark feature.
(1.50)
6. Does not include dambar protrusion. Allowable dambar protrusion
shall be 0.10mm total in excess of lead width at maximum condition.
7. Reference to JEDEC MS-012-AB.
TYPICAL RECOMMENDED LAND PATTERN
FN8980 Rev.0.00
Mar 21, 2018
Page 19 of 20
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