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SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
SLLS394I – SEPTEMBER 1999 – REVISED DECEMBER 2014
SNx5LVDx3xx High-Speed Differential Line Receivers
1 Features
3 Description
•
This family of 4-, 8-, or 16-differential line receivers
(with optional integrated termination) implements the
electrical characteristics of low-voltage differential
signaling (LVDS). This signaling technique lowers the
output voltage levels of 5-V differential standard
levels (such as EIA/TIA-422B) to reduce the power,
increase the switching speeds, and allow operation
with a 3-V supply rail.
1
•
•
•
•
•
•
•
•
•
•
Four- ('390), Eight- ('388A), or Sixteen- ('386) Line
Receivers Meet or Exceed the
Requirements of ANSI TIA/EIA-644 Standard
Integrated 110-Ω Line Termination Resistors on
LVDT Products
Designed for Signaling Rates Up to 250 Mbps
SN65 Versions Bus-Terminal ESD Exceeds
15 kV
Operates From a Single 3.3-V Supply
Typical Propagation Delay Time of 2.6 ns
Output Skew 100 ps (Typical) Part-To-Part Skew
Is Less Than 1 ns
LVTTL Levels Are 5-V Tolerant
Open-Circuit Fail Safe
Flow-Through Pinout
Packaged in Thin Shrink Small-Outline
Package With 20-mil Terminal Pitch
PART NUMBER
Wireless Infrastructure
Telecom Infrastructure
Printer
PACKAGE
BODY SIZE (NOM)
TSSOP (64)
17.00 mm × 6.10 mm
TSSOP (38)
9.70 mm × 4.40 mm
SOIC (16)
9.90 mm × 3.91 mm
TSSOP (16)
5.00 mm × 4.40 mm
SOIC (16)
9.90 mm × 3.91 mm
TSSOP (16)
5.00 mm × 4.40 mm
SOIC (16)
9.90 mm × 3.91 mm
TSSOP (16)
5.00 mm × 4.40 mm
SOIC (16)
9.90 mm × 3.91 mm
TSSOP (16)
5.00 mm × 4.40 mm
SN65LVDS386
SN65LVDT386
SN75LVDS386
SN75LVDT386
SN65LVDS388A
SN65LVDT388A
SN75LVDS388A
SN75LVDT388A
SN65LVDS390
2 Applications
•
•
•
Device Information(1)
SN65LVDT390
SN75LVDS390
SN75LVDT390
(1) For all available packages, see the orderable addendum at
the end of the data sheet.
Typical Application Schematic
Host
Host
Controller
Power
Balanced Interconnect
Power
Target
T
DBn
DBn
Target
Controller
T
DBn–1
DBn–1
T
DBn–2
DBn–2
T
DBn–3
DBn–3
T
DB2
DB2
T
DB1
DB1
T
DB0
DB0
T
TX Clock
RX Clock
LVDx368, LVDx388
LVDx388A, or LVDx390
LVDS Drivers
Indicates twisting of the
conductors.
Indicates the line termination
T circuit.
1
An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,
intellectual property matters and other important disclaimers. PRODUCTION DATA.
SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
SLLS394I – SEPTEMBER 1999 – REVISED DECEMBER 2014
www.ti.com
Table of Contents
1
2
3
4
5
6
7
8
Features ..................................................................
Applications ...........................................................
Description .............................................................
Revision History.....................................................
Description (Continued) ........................................
Device Options.......................................................
Pin Configuration and Functions .........................
Specifications.........................................................
8.1
8.2
8.3
8.4
8.5
8.6
8.7
1
1
1
2
3
3
4
8
Absolute Maximum Ratings ..................................... 8
ESD Ratings.............................................................. 8
Recommended Operating Conditions....................... 8
Thermal Information .................................................. 8
Electrical Characteristics........................................... 9
Switching Characteristics ........................................ 10
Typical Characteristics ............................................ 11
9 Parameter Measurement Information ................ 13
10 Detailed Description ........................................... 16
10.1 Overview ............................................................... 16
10.2 Functional Block Diagram ..................................... 16
10.3 Feature Description............................................... 16
10.4 Device Functional Modes...................................... 18
11 Application and Implementation........................ 19
11.1 Application Information.......................................... 19
11.2 Typical Application ................................................ 19
12 Power Supply Recommendations ..................... 25
13 Layout................................................................... 25
13.1 Layout Guidelines ................................................. 25
13.2 Layout Example .................................................... 27
14 Device and Documentation Support ................. 29
14.1
14.2
14.3
14.4
14.5
14.6
Device Support......................................................
Documentation Support ........................................
Related Links ........................................................
Trademarks ...........................................................
Electrostatic Discharge Caution ............................
Glossary ................................................................
29
29
29
29
30
30
15 Mechanical, Packaging, and Orderable
Information ........................................................... 30
4 Revision History
Changes from Revision H (May 2007) to Revision I
•
2
Page
Added Pin Configuration and Functions section, Handling Rating table, Feature Description section, Device
Functional Modes, Application and Implementation section, Power Supply Recommendations section, Layout
section, Device and Documentation Support section, and Mechanical, Packaging, and Orderable Information
section ................................................................................................................................................................................... 1
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Copyright © 1999–2014, Texas Instruments Incorporated
Product Folder Links: SN65LVDS386 SN65LVDS388A SN65LVDS390 SN65LVDT386 SN65LVDT388A
SN65LVDT390 SN75LVDS386 SN75LVDS388A SN75LVDS390 SN75LVDT386 SN75LVDT388A SN75LVDT390
SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
www.ti.com
SLLS394I – SEPTEMBER 1999 – REVISED DECEMBER 2014
5 Description (Continued)
Any of the differential receivers provides a valid logical output state with a ±100-mV differential input voltage
within the input common-mode voltage range. The input common-mode voltage range allows 1 V of ground
potential difference between two LVDS nodes. Additionally, the high-speed switching of LVDS signals almost
always requires the use of a line impedance matching resistor at the receiving end of the cable or transmission
media. The LVDT products eliminate this external resistor by integrating it with the receiver.
The intended application of this device and signaling technique is for point-to-point baseband data transmission
over controlled impedance media of approximately 100 Ω. The transmission media may be printed-circuit board
traces, backplanes, or cables. The large number of receivers integrated into the same substrate along with the
low pulse skew of balanced signaling, allows extremely precise timing alignment of clock and data for
synchronous parallel data transfers. When used with its companion, the 8- or 16-channel driver (the
SN65LVDS389 or SN65LVDS387, respectively), over 200 million data transfers per second in single-edge
clocked systems are possible with little power.
NOTE
The ultimate rate and distance of data transfer depends on the attenuation characteristics
of the media, the noise coupling to the environment, and other system characteristics.
6 Device Options
PART NUMBER (1)
TEMPERATURE RANGE
NUMBER OF RECEIVERS
BUS-PIN ESD
SYMBOLIZATION
SN65LVDS386DGG
–40°C to 85°C
16
15 kV
LVDS386
SN65LVDT386DGG
–40°C to 85°C
16
15 kV
LVDT386
SN75LVDS386DGG
0°C to 70°C
16
4 kV
75LVDS386
SN75LVDT386DGG
0°C to 70°C
16
4 kV
75LVDT386
SN65LVDS388ADBT
–40°C to 85°C
8
15 kV
LVDS388A
SN65LVDT388ADBT
–40°C to 85°C
8
15 kV
LVDT388A
SN75LVDS388ADBT
0°C to 70°C
8
4 kV
75LVDS388A
SN75LVDT388ADBT
0°C to 70°C
8
4 kV
75LVDT388A
SN65LVDS390D (PW)
–40°C to 85°C
4
15 kV
LVDS390
SN65LVDT390D (PW)
–40°C to 85°C
4
15 kV
LVDT390
SN75LVDS390D (PW)
0°C to 70°C
4
4 kV
75LVDS390
SN75LVDT390D (PW)
0°C to 70°C
4
4 kV
75LVDT390
(1)
This package is available taped and reeled. To order this packaging option, add an R suffix to the part number (for example,
SN65LVDS386DGGR).
Maximum Recommended Operating Speeds
PART NUMBER
ALL BUFFERS ACTIVE
SN65LVDS386, SN75LVDS386
250 Mbps
SN65LVDS388A, SN75LVDS388A
200 Mbps
SN65LVDS390, SN75LVDS390
200 Mbps
Copyright © 1999–2014, Texas Instruments Incorporated
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Product Folder Links: SN65LVDS386 SN65LVDS388A SN65LVDS390 SN65LVDT386 SN65LVDT388A
SN65LVDT390 SN75LVDS386 SN75LVDS388A SN75LVDS390 SN75LVDT386 SN75LVDT388A SN75LVDT390
3
SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
SLLS394I – SEPTEMBER 1999 – REVISED DECEMBER 2014
www.ti.com
7 Pin Configuration and Functions
’LVDS388A, ’LVDT388A
DBT PACKAGE
(TOP VIEW)
A1A
A1B
A2A
A2B
AGND
B1A
B1B
B2A
B2B
AGND
C1A
C1B
C2A
C2B
AGND
D1A
D1B
D2A
D2B
1
38
2
37
3
36
4
35
5
34
6
33
7
32
8
31
9
30
10
29
11
28
12
27
13
26
14
25
15
24
16
23
17
22
18
21
19
20
GND
VCC
ENA
A1Y
A2Y
ENB
B1Y
B2Y
DGND
DVCC
DGND
C1Y
C2Y
ENC
D1Y
D2Y
END
VCC
GND
See application section for VCC
and GND description.
’LVDS390, ’LVDT390
D OR PW PACKAGE
(TOP VIEW)
1A
1B
2A
2B
3A
3B
4A
4B
4
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1
16
2
15
3
14
4
13
5
12
6
11
7
10
8
9
EN1,2
1Y
2Y
VCC
GND
3Y
4Y
EN3,4
’LVDS386, ’LVDT386
DGG PACKAGE
(TOP VIEW)
A1A
A1B
A2A
A2B
A3A
A3B
A4A
A4B
B1A
B1B
B2A
B2B
B3A
B3B
B4A
B4B
C1A
C1B
C2A
C2B
C3A
C3B
C4A
C4B
D1A
D1B
D2A
D2B
D3A
D3B
D4A
D4B
1
64
2
63
3
62
4
61
5
60
6
59
7
58
8
57
9
56
10
55
11
54
12
53
13
52
14
51
15
50
16
49
17
48
18
47
19
46
20
45
21
44
22
43
23
42
24
41
25
40
26
39
27
38
28
37
29
36
30
35
31
34
32
33
GND
VCC
VCC
GND
ENA
A1Y
A2Y
A3Y
A4Y
ENB
B1Y
B2Y
B3Y
B4Y
GND
VCC
VCC
GND
C1Y
C2Y
C3Y
C4Y
ENC
D1Y
D2Y
D3Y
D4Y
END
GND
VCC
VCC
GND
Copyright © 1999–2014, Texas Instruments Incorporated
Product Folder Links: SN65LVDS386 SN65LVDS388A SN65LVDS390 SN65LVDT386 SN65LVDT388A
SN65LVDT390 SN75LVDS386 SN75LVDS388A SN75LVDS390 SN75LVDT386 SN75LVDT388A SN75LVDT390
SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
www.ti.com
SLLS394I – SEPTEMBER 1999 – REVISED DECEMBER 2014
Pin Functions: SNx5LVDx390
PIN
NAME
NUMBER
I/O
DESCRIPTION
VCC
13
–
Supply voltage
GND
12
–
Ground
1A
1
I
Differential (LVDS) non-inverting input
1B
2
I
Differential (LVDS) inverting input
1Y
15
O
LVTTL output signal
2A
3
I
Differential (LVDS) non-inverting input
2B
4
I
Differential (LVDS) inverting input
2Y
14
O
LVTTL output signal
3A
5
I
Differential (LVDS) non-inverting input
3B
6
I
Differential (LVDS) inverting input
3Y
11
O
LVTTL output signal
4A
7
I
Differential (LVDS) non-inverting input
4B
8
I
Differential (LVDS) inverting input
4Y
10
O
LVTTL output signal
EN1, 2
16
I
Enable for channels 1 and 2
EN3, 4
9
I
Enable for channels 3 and 4
Pin Functions: SNx5LVDx388A
PIN
NAME
VCC
NUMBER
I/O
DESCRIPTION
21, 37
–
Supply voltage
29
–
Digital supply voltage
20, 38
–
Ground
DGND
28, 30
–
Digital ground
AGND
5, 10, 15
–
Analog ground
1
I
Differential (LVDS) non-inverting input
DVCC
GND
A1A
A1B
2
I
Differential (LVDS) inverting input
A1Y
35
O
LVTTL output signal
A2A
3
I
Differential (LVDS) non-inverting input
A2B
4
I
Differential (LVDS) inverting input
A2Y
34
O
LVTTL output signal
B1A
6
I
Differential (LVDS) non-inverting input
B1B
7
I
Differential (LVDS) inverting input
B1Y
32
O
LVTTL output signal
B2A
8
I
Differential (LVDS) non-inverting input
B2B
9
I
Differential (LVDS) inverting input
B2Y
31
O
LVTTL output signal
C1A
11
I
Differential (LVDS) non-inverting input
C1B
12
I
Differential (LVDS) inverting input
C1Y
27
O
LVTTL output signal
C2A
13
I
Differential (LVDS) non-inverting input
C2B
14
I
Differential (LVDS) inverting input
C2Y
26
O
LVTTL output signal
D1A
16
I
Differential (LVDS) non-inverting input
D1B
17
I
Differential (LVDS) inverting input
D1Y
24
O
LVTTL output signal
D2A
18
I
Differential (LVDS) non-inverting input
Copyright © 1999–2014, Texas Instruments Incorporated
Submit Documentation Feedback
Product Folder Links: SN65LVDS386 SN65LVDS388A SN65LVDS390 SN65LVDT386 SN65LVDT388A
SN65LVDT390 SN75LVDS386 SN75LVDS388A SN75LVDS390 SN75LVDT386 SN75LVDT388A SN75LVDT390
5
SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
SLLS394I – SEPTEMBER 1999 – REVISED DECEMBER 2014
www.ti.com
Pin Functions: SNx5LVDx388A (continued)
PIN
NAME
NUMBER
I/O
DESCRIPTION
D2B
19
I
Differential (LVDS) inverting input
D2Y
23
O
LVTTL output signal
ENA
36
I
Enable for channel A
ENB
33
I
Enable for channel B
ENC
25
I
Enable for channel C
END
22
I
Enable for channel D
Pin Functions: SNx5LVDx386
PIN
NAME
NUMBER
I/O
DESCRIPTION
VCC
34, 35, 48,
49, 62, 63
–
Supply voltage
GND
33, 36, 47,
50, 61, 64
–
Ground
A1A
1
I
Differential (LVDS) non-inverting input
A1B
2
I
Differential (LVDS) inverting input
A1Y
59
O
LVTTL output signal
A2A
3
I
Differential (LVDS) non-inverting input
A2B
4
I
Differential (LVDS) inverting input
A2Y
58
O
LVTTL output signal
A3A
5
I
Differential (LVDS) non-inverting input
A3B
6
I
Differential (LVDS) inverting input
A3Y
57
O
LVTTL output signal
A4A
7
I
Differential (LVDS) non-inverting input
A4B
8
I
Differential (LVDS) inverting input
A4Y
56
O
LVTTL output signal
B1A
9
I
Differential (LVDS) non-inverting input
B1B
10
I
Differential (LVDS) inverting input
B1Y
54
O
LVTTL output signal
B2A
11
I
Differential (LVDS) non-inverting input
B2B
12
I
Differential (LVDS) inverting input
B2Y
53
O
LVTTL output signal
B3A
13
I
Differential (LVDS) non-inverting input
B3B
14
I
Differential (LVDS) inverting input
B4Y
52
O
LVTTL output signal
B4A
15
I
Differential (LVDS) non-inverting input
B4B
16
I
Differential (LVDS) inverting input
B2Y
51
O
LVTTL output signal
C1A
17
I
Differential (LVDS) non-inverting input
C1B
18
I
Differential (LVDS) inverting input
C1Y
46
O
LVTTL output signal
C2A
19
I
Differential (LVDS) non-inverting input
C2B
20
I
Differential (LVDS) inverting input
C2Y
45
O
LVTTL output signal
C3A
21
I
Differential (LVDS) non-inverting input
C3B
22
I
Differential (LVDS) inverting input
C3Y
44
O
LVTTL output signal
6
Submit Documentation Feedback
Copyright © 1999–2014, Texas Instruments Incorporated
Product Folder Links: SN65LVDS386 SN65LVDS388A SN65LVDS390 SN65LVDT386 SN65LVDT388A
SN65LVDT390 SN75LVDS386 SN75LVDS388A SN75LVDS390 SN75LVDT386 SN75LVDT388A SN75LVDT390
SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
www.ti.com
SLLS394I – SEPTEMBER 1999 – REVISED DECEMBER 2014
Pin Functions: SNx5LVDx386 (continued)
PIN
NAME
NUMBER
I/O
DESCRIPTION
C4A
23
I
Differential (LVDS) non-inverting input
C4B
24
I
Differential (LVDS) inverting input
C4Y
43
O
LVTTL output signal
D1A
25
I
Differential (LVDS) non-inverting input
D1B
26
I
Differential (LVDS) inverting input
D1Y
41
O
LVTTL output signal
D2A
27
I
Differential (LVDS) non-inverting input
D2B
28
I
Differential (LVDS) inverting input
D2Y
40
O
LVTTL output signal
D3A
29
I
Differential (LVDS) non-inverting input
D3B
30
I
Differential (LVDS) inverting input
D3Y
39
O
LVTTL output signal
D4A
31
I
Differential (LVDS) non-inverting input
D4B
32
I
Differential (LVDS) inverting input
D4Y
38
O
LVTTL output signal
ENA
60
I
Enable for channel A
ENB
55
I
Enable for channel B
ENC
42
I
Enable for channel C
END
37
I
Enable for channel D
Copyright © 1999–2014, Texas Instruments Incorporated
Submit Documentation Feedback
Product Folder Links: SN65LVDS386 SN65LVDS388A SN65LVDS390 SN65LVDT386 SN65LVDT388A
SN65LVDT390 SN75LVDS386 SN75LVDS388A SN75LVDS390 SN75LVDT386 SN75LVDT388A SN75LVDT390
7
SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
SLLS394I – SEPTEMBER 1999 – REVISED DECEMBER 2014
www.ti.com
8 Specifications
8.1 Absolute Maximum Ratings
over operating free-air temperature (unless otherwise noted) (1)
(2)
VCC
MIN
MAX
UNIT
–0.5
4
V
Enables or Y
–0.5
6
V
A or B
–0.5
4
V
–12
12
mA
1
V
–65
150
°C
Supply voltage range
VI
Voltage range:
IO
Output current
Y
|VID|
Differential input voltage magnitude
SN65LVDT' or SN75LVDT' only
Tstg
Storage temperature
(1)
(2)
Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings
only, and functional operation of the device at these or any other conditions beyond those indicated under Recommended Operating
Conditions is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
All voltage values, except differential I/O bus voltages, are with respect to network ground terminal.
8.2 ESD Ratings
SN65' (A, B, and GND)
Electrostatic discharge (1)
V(ESD)
SN75' (A, B, and GND)
VALUE
UNIT
15000
V
Class 3, B
400
V
Class 2, A
4000
V
Class 2, B
400
Class 3, A
V
Lead temperature 1.6 mm (1/16 in) from case for 10 seconds
(1)
°C
Tested in accordance with MIL-STD-883C Method 3015.7.
8.3 Recommended Operating Conditions
MIN
NOM
MAX
VCC
Supply voltage
3
3.3
3.6
VIH
High-level input voltage
2
VIL
Low-level input voltage
IO
Output current
|VID|
Magnitude of differential input voltage
VIC
Common-mode input voltage, See Figure 1
V
V
0.8
Y
UNIT
V
–8
8
0.1
0.6
V
|
ID
2
V
|V
|
ID
2
mA
|V
2.4 *
VCC – 0.8
TA
Operating free-air temperature
SN75'
0
70
°C
SN65'
–40
85
°C
8.4 Thermal Information
THERMAL METRIC (1)
SN65LVDS386,
SN65LVDT386,
SN75LVDS386,
SN75LVDT386
DGG
DBT
D
PW
38 PINS
16 PINS
16 PINS
Junction-to-ambient thermal resistance
57.3
RθJC(top)
Junction-to-case (top) thermal resistance
13.2
RθJB
Junction-to-board thermal resistance
27.7
ψJT
Junction-to-top characterization parameter
0.4
ψJB
Junction-to-board characterization parameter
27.4
8
SN65LVDS390,
SN65LVDT390,
SN75LVDS390,
SN75LVDT390
64 PINS
RθJA
(1)
SN65LVDS388A,
SN65LVDT388A,
SN75LVDS388A,
SN75LVDT388A
UNIT
mW/°C
For more information about traditional and new thermal metrics, see the IC Package Thermal Metrics application report, SPRA953.
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SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
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SLLS394I – SEPTEMBER 1999 – REVISED DECEMBER 2014
Thermal Information (continued)
SN65LVDS386,
SN65LVDT386,
SN75LVDS386,
SN75LVDT386
THERMAL METRIC (1)
SN65LVDS388A,
SN65LVDT388A,
SN75LVDS388A,
SN75LVDT388A
SN65LVDS390,
SN65LVDT390,
SN75LVDS390,
SN75LVDT390
UNIT
DGG
DBT
D
PW
64 PINS
38 PINS
16 PINS
16 PINS
Power Rating: TA ≤ 25°C
2094
1071
950
774
Power Rating: TA = 70°C
1342
688
608
496
Power Rating: TA = 85°C
1089
556
494
402
mW
8.5 Electrical Characteristics
over recommended operating conditions (unless otherwise noted)
PARAMETER
VIT+
TEST CONDITIONS
MIN
TYP (1)
Positive-going differential input voltage threshold
VIT–
See Figure 9 and
Negative-going differential input voltage threshold Table 1
VOH
High-level output voltage
VOL
Low-level output voltage
ICC
Supply current
IOH = –8 mA
UNIT
100
mV
–100
2.4
IOL = 8 mA
mV
3
V
0.2
0.4
'LVDx386
50
70
'LVDx388A Enabled, No load
22
40
8
18
'LVDx390
'LVDx386
3
'LVDx388A Disabled
'LVDS
Input current (A or B inputs)
'LVDT
V
mA
3
'LVDx390
II
MAX
1.5
VI = 0 V
VI = 2.4 V
–13
–1.2
VI = 0 V, other input
open
VI = 2.4 V, other input
open
–20
–3
–40
µA
±2
µA
2.2
mA
±20
µA
±40
µA
–2.4
IID
Differential input current |IIA – IIB|
'LVDS
VIA = 0 V, VIB = 0.1 V,
VIA= 2.4 V, VIB = 2.3 V
IID
Differential input current (IIA – IIB)
'LVDT
VIA = 0.2 V, VIB = 0 V,
VIA = 2.4 V, VIB = 2.2 V
II(OFF)
Power-off input current (A or B
inputs)
'LVDS
VCC = 0 V, VI = 2.4 V
II(OFF)
Power-off input current (A or B
inputs)
'LVDT
VCC = 0 V, VI = 2.4 V
IIH
High-level input current (enables)
VIH = 2 V
10
µA
IIL
Low-level input current (enables)
VIL = 0.8 V
10
µA
VO = 0 V
±1
VO = 3.6 V
10
IOZ
High-impedance output current
CIN
Input capacitance, A or B input to GND
VID = 0.4sin2.5E09t V
Z(t)
Termination impedance
VID = 0.4sin2.5E09t V
(1)
1.5
12
5
88
µA
pF
132
Ω
All typical values are at 25°C and with a 3.3-V supply.
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9
SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
SLLS394I – SEPTEMBER 1999 – REVISED DECEMBER 2014
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8.6 Switching Characteristics
over recommended operating conditions (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP (1)
MAX
UNIT
tPLH
Propagation delay time, low-to-high-level output
1
2.6
4
ns
tPHL
Propagation delay time, high-to-low-level output
1
2.5
4
ns
tr
Output signal rise time
500
800
1200
ps
tf
Output signal fall time
500
800
1200
ps
tsk(p)
Pulse skew (|tPHL – tPLH|)
150
600
ps
tsk(o)
Output skew (2)
100
400
ps
tsk(pp)
Part-to-part skew (3)
1
ns
tPZH
Propagation delay time, high-impedance-to-highlevel output
7
15
ns
tPZL
Propagation delay time, high-impedance-to-lowlevel output
7
15
ns
7
15
ns
7
15
ns
tPHZ
Propagation delay time, high-level-to-highimpedance output
tPLZ
Propagation delay time, low-level-to-highimpedance output
(1)
(2)
(3)
10
See Figure 10
See Figure 11
All typical values are at 25°C and with a 3.3-V supply.
tsk(o) is the magnitude of the time difference between the tPLH or tPHL of all drivers of a single device with all of their inputs connected
together.
tsk(pp) is the magnitude of the difference in propagation delay times between any specified terminals of any two devices characterized in
this data sheet when both devices operate with the same supply voltage, at the same temperature, and have the same test circuits.
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SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
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SLLS394I – SEPTEMBER 1999 – REVISED DECEMBER 2014
8.7 Typical Characteristics
140
2.5
120
Max at VCC = 3 V
2.0
ICC − Supply Current − mA
VIC − Common-Mode Input Voltage − V
Max at VCC > 3.15 V
1.5
1.0
VCC = 3.6 V
100
80
VCC = 3 V
60
VCC = 3.3 V
40
0.5
20
Minimum
0.0
0.0
0
0.1
0.2
0.3
0.4
0.5
0
0.6
50
100
150
200
250
300
350
|VID| − Differential Input Voltage − V
f − Switching Frequency − MHz
Figure 1. Common-Mode Input Voltage vs Differential Input
Voltage
Figure 2. LVDX390 Supply Current vs Switching Frequency
350
600
500
ICC − Supply Current − mA
ICC − Supply Current − mA
300
250
VCC = 3.6 V
200
VCC = 3 V
150
VCC = 3.3 V
100
VCC = 3 V
300
VCC = 3.3 V
200
100
50
0
0
0
50
100
150
200
250
f − Switching Frequency − MHz
0
300
100
150
200
250
300
Figure 4. LVDX386 Supply Current vs Switching Frequency
5.0
4.0
4.5
VOL − Low-Level Output Voltage − V
3.5
3.0
2.5
2.0
1.5
1.0
0.5
0.0
−70
50
f − Switching Frequency − MHz
Figure 3. LVDX388A Supply Current vs Switching
Frequency
VOH − High-Level Output Voltage − V
VCC = 3.6 V
400
4.0
3.5
3.0
2.5
2.0
1.5
1.0
0.5
0.0
−60
−50
−40
−30
−20
−10
0
IOH − High-Level Output Current − mA
Figure 5. High-Level Output Voltage vs High-Level Output
Current
Copyright © 1999–2014, Texas Instruments Incorporated
0
10
20
30
40
50
60
70
80
IOL − Low-Level Output Current − mA
Figure 6. Low-Level Output Voltage vs Low-Level Output
Current
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11
SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
SLLS394I – SEPTEMBER 1999 – REVISED DECEMBER 2014
www.ti.com
12
3.0
t PHL − High-To-Low Propagation Delay Time − ns
t PLH − Low-To-High Propagation Delay Time − ns
Typical Characteristics (continued)
2.9
2.8
VCC = 3 V
2.7
2.6
VCC = 3.6 V
2.5
2.4
VCC = 3.3 V
2.3
2.2
2.1
2.0
−50
−30
−10
10
30
50
70
90
3.0
2.9
2.8
2.7
2.6
2.5
VCC = 3 V
VCC = 3.6 V
2.4
2.3
2.2
VCC = 3.3 V
2.1
2.0
−50
−30
−10
10
30
50
70
90
TA − Free-Air Temperature − °C
TA − Free-Air Temperature − °C
Figure 7. Low-to-High Propagation Delay Time vs Free-Air
Temperature
Figure 8. High-to-Low Propagation Delay Time vs Free-Air
Temperature
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SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
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SLLS394I – SEPTEMBER 1999 – REVISED DECEMBER 2014
9 Parameter Measurement Information
A
V
IA
)V
IB
VID
2
R
VIA
VIC
B
VO
VIB
Figure 9. Voltage Definitions
Table 1. Receiver Minimum and Maximum Input Threshold Test Voltages
APPLIED VOLTAGES
RESULTING DIFFERENTIAL
INPUT VOLTAGE
RESULTING COMMONMODE
INPUT VOLTAGE
VID
VIC
1.2 V
VIA
VIB
1.25 V
1.15 V
100 mV
1.15 V
1.25 V
–100 mV
1.2 V
2.4 V
2.3 V
100 mV
2.35 V
2.3 V
2.4 V
–100 mV
2.35 V
0.1 V
0V
100 mV
0.05 V
0V
0.1 V
–100 mV
0.05 V
1.5 V
0.9 V
600 mV
1.2 V
0.9 V
1.5 V
–600 mV
1.2 V
2.4 V
1.8 V
600 mV
2.1 V
1.8 V
2.4 V
–600 mV
2.1 V
0.6 V
0V
600 mV
0.3 V
0V
0.6 V
–600 mV
0.3 V
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13
SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
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VID
VIA
VIB
CL
10 pF
VO
VIA
1.4 V
VIB
1V
VID
0.4 V
0V
–0.4 V
tPHL
VO
tPLH
VOH
80%
1.5 V
20%
VOL
tf
tr
NOTE: All input pulses are supplied by a generator having the following characteristics: tr or tf ≤ 1 ns, pulse repetition rate
(PRR) = 50 Mpps, pulse width = 10 ± 0.2 ns. CL includes instrumentation and fixture capacitance within 0.06 mm of
the device under test.
Figure 10. Timing Test Circuit and Wave Forms
14
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SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
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SLLS394I – SEPTEMBER 1999 – REVISED DECEMBER 2014
B
1.2 V
500 Ω
A
Inputs
CL
10 pF
EN
+
–
VO
VTEST
NOTE: All input pulses are supplied by a generator having the following characteristics: tr or tf ≤ 1 ns, pulse repetition rate
(PRR) = 0.5 Mpps, pulse width = 500 ± 10 ns. CL includes instrumentation and fixture capacitance within 0.06 mm of
the device under test.
2.5 V
VTEST
A
1V
2V
1.4 V
EN
0.8 V
tPZL
tPLZ
2.5 V
1.4 V
Y
VOL +0.5 V
VOL
0V
VTEST
A
1.4 V
2V
EN
1.4 V
0.8 V
tPZH
Y
VOH –0.5 V
tPHZ
VOH
1.4 V
0V
Figure 11. Enable and Disable Time Test Circuit and Waveforms
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15
SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
SLLS394I – SEPTEMBER 1999 – REVISED DECEMBER 2014
www.ti.com
10 Detailed Description
10.1 Overview
The SNx5LVDS3xx devices are LVDS line receivers. They operate from a single supply that is nominally 3.3 V,
but can be as low as 3.0 V and as high as 3.6 V. The input signals to the SNx5LVDS3xx are differential LVDS
signals. The output of the device is a LVTTL digital signal. This LVDS receiver requires ±100 mV of input signal
to determine the correct state of the received signal. Compliant LVDS receivers can accept input signals with a
common-mode range between 0.05 V and 2.35 V. As the common-mode output voltage of an LVDS driver is 1.2
V, the SNx5LVDS3xx correctly determines the line state when operated with a 1-V ground shift between driver
and receiver.
The SNx5LVDT3xx devices are also LVDS receivers. These devices differ from their LVDS variants in that they
incorporate integrated termination resistors along with the receivers. These terminations would take the place of
the matched-load line termination needed in any LVDS communication channel. The SNx5LVDT3xx can be used
in a point-to-point system or in a multidrop system when it is the last receiver on the multidrop bus. The
SNx5LVDT3xx should not be used at every node in a multidrop system as this would change the loaded bus
impedance throughout the bus resulting in multiple reflections and signal distortion. While the integration of a bus
terminating resistor is always attractive in a point-to-point LVDS communication channel, the value of 8- and 16channel LVDS receivers with their 8 and 16 termination resistors is clear for many reasons: cost, signal integrity,
manufacturing, and so on.
10.2 Functional Block Diagram
’LVDx388A
’LVDx386
’LVDx390
’LVDT386 ONLY
’LVDT390 ONLY
’LVDT388A ONLY
1A
1Y
1B
1A
1Y
1A
1Y
2A
2Y
2B
EN
3A
1B
EN
2A
2B
3Y
3B
4A
4Y
4B
(1/4 of ’LVDx388A shown)
1B
EN
2A
2Y
2Y
2B
3A
3Y
3B
EN
4A
4Y
4B
(1/4 of ’LVDx386 shown)
(’LVDx390 shown)
10.3 Feature Description
10.3.1 Receiver Output States
When the receiver differential input signal is greater than 100 mV, the receiver output is high; and when the
differential input voltage is below –100 mV, the receiver output is low. When the input voltage is between these
thresholds (example: between –100 mV and 100 mV), the receiver output is indeterminate. It may be high or low.
A special case occurs when the input to the receiver is open-circuited, which is covered in Receiver Open-Circuit
Fail-safe. When the receiver is disabled, the receiver outputs will be high-impedance.
10.3.2 Receiver Open-Circuit Fail-safe
One of the most common problems with differential signaling applications is how the system responds when no
differential voltage is present on the signal pair. The LVDS receiver is like most differential line receivers in that
its output logic state can be indeterminate when the differential input voltage is between –100 mV and 100 mV
and within its recommended input common-mode voltage range. The TI LVDS receiver is different in how it
handles the open-input circuit situation, however.
16
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SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
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Feature Description (continued)
Open-circuit means that there is little or no input current to the receiver from the data line itself. This could be
when the driver is in a high-impedance state or the cable is disconnected. When this occurs, the LVDS receiver
pulls each line of the signal pair to near VCC through 300-kΩ resistors, as shown in Figure 12. The fail-safe
feature uses an AND gate with input voltage thresholds at about 2.3 V to detect this condition and force the
output to a high-level, regardless of the differential input voltage.
VCC
300 kΩ
300 kΩ
A
Rt = 100 Ω (Typ)
Y
B
VIT ≈ 2.3 V
Figure 12. Open-Circuit Fail-Safe of the LVDS Receiver
It is only under these conditions that the output of the receiver is valid with less than a 100-mV differential input
voltage magnitude. The presence of the termination resistor, Rt, does not affect the fail-safe function as long as it
is connected as shown in Figure 12. Other termination circuits may allow a dc current to ground that could defeat
the pullup currents from the receiver and the fail-safe feature.
10.3.3 Common-Mode Range
The SNx5LVDx3xx receivers operate over an input common-mode range of ½ × VID V to 2.4 – ½ × VID V. If the
input signal is anywhere within this range and has a differential magnitude greater than or equal to 100 mV, the
receivers correctly output the LVDS bus state.
10.3.4 General Purpose Comparator
While the SNx5LVDx3xx receivers are LVDS standard-compliant receivers, their utility and applications extend to
a wider range of signals. As long as the input signals are within the required differential and common-mode
voltage ranges mentioned above, the receiver output will be a faithful representation of the input signal.
10.3.5 Receiver Equivalent Schematics
The receiver equivalent input and output schematic diagrams are shown in Figure 13. The receiver input is a
high-impedance differential pair in the case of the SNx5LVDS3xx. The SNx5LVDT3xx receivers include internal
termination resistor of 110 Ω across the input port. 7-V Zener diodes are included on each input to provide ESD
protection. The receiver output structure shown is a CMOS inverter with an additional Zener diode, again for ESD
protection.
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17
SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
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Feature Description (continued)
VCC
VCC
300 kΩ
VCC
300 kΩ
400 Ω
5Ω
EN
Y Output
A Input
B Input
7V
7V
300 kΩ
7V
7V
110 Ω
’LVDT Devices Only
Figure 13. Equivalent Input and Output Schematic Diagrams
10.4 Device Functional Modes
Table 2. Function Table
SNx5LVD386/388A/390 and SNx5LVDT386/388A/390
(1)
18
DIFFERENTIAL INPUT (1)
ENABLES (1)
OUTPUT (1)
A-B
EN
Y
VID ≥ 100 mV
H
H
–100 mV < VID ≤ 100 mV
H
?
VID ≤ –100 mV
H
L
X
L
Z
Open
H
H
H = high level, L = low level, X = irrelevant, Z = high-impedance (off), ? = indeterminate
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SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
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SLLS394I – SEPTEMBER 1999 – REVISED DECEMBER 2014
11 Application and Implementation
NOTE
Information in the following applications sections is not part of the TI component
specification, and TI does not warrant its accuracy or completeness. TI’s customers are
responsible for determining suitability of components for their purposes. Customers should
validate and test their design implementation to confirm system functionality.
11.1 Application Information
The SNx5LVDx3xx devices are LVDS receivers. These devices are generally used as building blocks for highspeed, point-to-point data transmission where ground differences are less than 1 V. LVDS drivers and receivers
provide high-speed signaling rates that are often implemented with ECL class devices without the ECL power
and dual-supply requirements.
11.1.1 Analog and Digital Grounds and Power Supplies
Although it is not necessary to separate out the analog and digital supplies and grounds on the
SN65LVDS/T388A and SN75LVDS/T388A devices, the pinout provides the user that option. To help minimize or
perhaps eliminate switching noise being coupled between the two supplies, the user could lay out separate
supply and ground planes for the designated pinout.
Most applications probably have all grounds connected together and all power supplies connected together. This
configuration was used while characterizing and setting the data sheet parameters.
11.2 Typical Application
11.2.1 Point-to-Point Communications
The most basic application for LVDS buffers, as found in this data sheet, is for point-to-point communications of
digital data, as shown in Figure 14.
Figure 14. Point-to-Point Topology
A point-to-point communications channel has a single transmitter (driver) and a single receiver. This
communications topology is often referred to as simplex. In Figure 14 the driver receives a single-ended input
signal and the receiver outputs a single-ended recovered signal. The LVDS driver converts the single-ended
input to a differential signal for transmission over a balanced interconnecting media of 100-Ω characteristic
impedance. The conversion from a single-ended signal to an LVDS signal retains the digital data payload while
translating to a signal whose features are more appropriate for communication over extended distances or in a
noisy environment.
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19
SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
SLLS394I – SEPTEMBER 1999 – REVISED DECEMBER 2014
www.ti.com
Typical Application (continued)
11.2.1.1 Design Requirements
DESIGN PARAMETERS
EXAMPLE VALUE
Driver Supply Voltage (VCCD)
3.0 to 3.6 V
Driver Input Voltage
0.8 to 5.0 V
Driver Signaling Rate
DC to 200 Mbps
Interconnect Characteristic Impedance
100 Ω
Termination Resistance
100 Ω
Number of Receiver Nodes
1
Receiver Supply Voltage (VCCR)
3.0 to 3.6 V
Receiver Input Voltage
0 to 2.4 V
Receiver Signaling Rate
DC to 200 Mbps
Ground shift between driver and receiver
±1 V
11.2.1.2 Detailed Design Procedure
11.2.1.2.1 Driver Supply Voltage
An LVDS driver such as the SN65LVDS387 is operated from a single supply. The device can support operation
with a supply as low as 3 V and as high as 3.6 V. The differential output voltage is nominally 340 mV over the
complete output range. The minimum output voltage stays within the specified LVDS limits (247 mV to 454 mV)
for a 3.3-V supply.
11.2.1.2.2 Driver Bypass Capacitance
Bypass capacitors play a key role in power distribution circuitry. Specifically, they create low-impedance paths
between power and ground. At low frequencies, a good digital power supply offers very-low-impedance paths
between its terminals. However, as higher frequency currents propagate through power traces, the source is
quite often incapable of maintaining a low-impedance path to ground. Bypass capacitors are used to address this
shortcoming. Usually, large bypass capacitors (10 μF to 1000 μF) at the board-level do a good job up into the
kHz range. Due to their size and length of their leads, they tend to have large inductance values at the switching
frequencies of modern digital circuitry. To solve this problem, one must resort to the use of smaller capacitors
(nF to μF range) installed locally next to the integrated circuit.
Multilayer ceramic chip or surface-mount capacitors (size 0603 or 0805) minimize lead inductances of bypass
capacitors in high-speed environments, because their lead inductance is about 1 nH. For comparison purposes,
a typical capacitor with leads has a lead inductance around 5 nH.
The value of the bypass capacitors used locally with LVDS chips can be determined by the following formula
according to Johnson, equations 8.18 to 8.21. A conservative rise time of 200 ps and a worst-case change in
supply current of 1 A covers the whole range of LVDS devices offered by Texas Instruments. In this example, the
maximum power supply noise tolerated is 200 mV; however, this figure varies depending on the noise budget
available in your design. (1)
æ DIMaximum Step Change Supply Current ö
Cchip = ç
÷ ´ TRise Time
è DVMaximum Power Supply Noise ø
(1)
æ 1A ö
CLVDS = ç
÷ ´ 200 ps = 0.001 mF
è 0.2V ø
(2)
The following example lowers lead inductance and covers intermediate frequencies between the board-level
capacitor (>10 µF) and the value of capacitance found above (0.001 µF). You should place the smallest value of
capacitance as close as possible to the chip.
(1)
20
Howard Johnson & Martin Graham.1993. High Speed Digital Design – A Handbook of Black Magic. Prentice Hall PRT. ISBN number
013395724.
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SN65LVDT390 SN75LVDS386 SN75LVDS388A SN75LVDS390 SN75LVDT386 SN75LVDT388A SN75LVDT390
SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
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SLLS394I – SEPTEMBER 1999 – REVISED DECEMBER 2014
Figure 15. Recommended LVDS Bypass Capacitor Layout
11.2.1.2.3 Driver Output Voltage
The SNx5LVDSxx driver output is a 1.2-V common-mode voltage, with a nominal differential output signal of 340
mV. This 340 mV is the absolute value of the differential swing (VOD = |V+ – V–|). The peak-to-peak differential
voltage is twice this value, or 680 mV.
11.2.1.2.4 Interconnecting Media
The physical communication channel between the driver and the receiver may be any balanced paired metal
conductors meeting the requirements of the LVDS standard, the key points which will be included here. This
media may be a twisted pair, twinax, flat ribbon cable, or PCB traces.
The nominal characteristic impedance of the interconnect is between 100 Ω and 120 Ω with variation no more
than 10% (90 Ω to 132 Ω).
11.2.1.2.5 PCB Transmission Lines
As per SNLA187, Figure 16 depicts several transmission line structures commonly used in printed-circuit boards
(PCBs). Each structure consists of a signal line and a return path with uniform cross-section along its length. A
microstrip is a signal trace on the top (or bottom) layer, separated by a dielectric layer from its return path in a
ground or power plane. A stripline is a signal trace in the inner layer, with a dielectric layer in between a ground
plane above and below the signal trace. The dimensions of the structure along with the dielectric material
properties determine the characteristic impedance of the transmission line (also called controlled-impedance
transmission line).
When two signal lines are placed close by, they form a pair of coupled transmission lines. Figure 16 shows
examples of edge-coupled microstrips, and edge-coupled or broad-side-coupled striplines. When excited by
differential signals, the coupled transmission line is referred to as differential pair. The characteristic impedance
of each line is called odd-mode impedance. The sum of the odd-mode impedances of each line is the differential
impedance of the differential pair. In addition to the trace dimensions and dielectric material properties, the
spacing between the two traces determines the mutual coupling and impacts the differential impedance. When
the two lines are immediately adjacent; for example, S is less than 2W, the differential pair is called a tightlycoupled differential pair. To maintain constant differential impedance along the length, it is important to keep the
trace width and spacing uniform along the length, as well as maintain good symmetry between the two lines.
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21
SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
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Figure 16. Controlled-Impedance Transmission Lines
11.2.1.2.6 Termination Resistor
As shown earlier, an LVDS communication channel employs a current source driving a transmission line which is
terminated with a resistive load. This load serves to convert the transmitted current into a voltage at the receiver
input. To ensure incident wave switching (which is necessary to operate the channel at the highest signaling
rate), the termination resistance should be matched to the characteristic impedance of the transmission line. The
designer should ensure that the termination resistance is within 10% of the nominal media characteristic
impedance. If the transmission line is targeted for 100-Ω impedance, the termination resistance should be
between 90 Ω and 110 Ω.
The line termination resistance should be located as close as possible to the receiver, thereby minimizing the
stub length from the resistor to the receiver. The limiting case would be to incorporate the termination resistor
into the receiver, which is exactly what is offered with a device like the SN65LVDT386. The SN65LVDT386
provides all the functionality and performance of the SN65LVDT386 receiver, with the added feature of an
integrated termination load.
While we talk in this section about point-to-point communications, a word of caution is useful when a multidrop
topology is used. In such topologies, line termination resistors are to be located only at the end(s) of the
transmission line. In such an environment, SN65LVDT386 receivers could be used for loads branching off the
main bus, with an SN65LVDT386 used only at the bus end.
22
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SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
www.ti.com
SLLS394I – SEPTEMBER 1999 – REVISED DECEMBER 2014
11.2.1.3 Application Curve
All 16 Rx
Switching at 250
Mbps:
TA = 25°C
VCC = 3.6 V
PRBS = 223–1
Ch1 = Xyy
Where x represents the
Rx Group: A, B, C, or D
y represents the Rx: 1,
2, 3, or 4
Figure 17. Typical Eye Pattern SN65LVDS386
All 8 Rx Switching
at 200 Mbps:
TA = 25°C
VCC = 3.6 V
PRBS = 223–1
Ch1 = Xyy
Where: x represents the
Rx Group: A, B, C, or D
y represents the Rx: 1
or 2
Figure 18. Typical Eye Pattern SN65LVDS388A
11.2.2 Multidrop Communications
A second common application of LVDS buffers is a multidrop topology. In a multidrop configuration, a single
driver and a shared bus are present, along with two or more receivers (with a maximum permissible number of
32 receivers). Figure 19 below shows an example of a multidrop system.
Figure 19. Multidrop Topology
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23
SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
SLLS394I – SEPTEMBER 1999 – REVISED DECEMBER 2014
www.ti.com
11.2.2.1 Design Requirements
DESIGN PARAMETERS
EXAMPLE VALUE
Driver Supply Voltage (VCCD)
3.0 to 3.6 V
Driver Input Voltage
0.8 to 3.3 V
Driver Signaling Rate
DC to 200 Mbps
Interconnect Characteristic Impedance
100 Ω
Termination Resistance
100 Ω
Number of Receiver Nodes
2 to 32
Receiver Supply Voltage (VCCR)
3.0 to 3.6 V
Receiver Input Voltage
0 to 2.4 V
Receiver Signaling Rate
DC to 200 Mbps
Ground shift between driver and receiver
±1 V
11.2.2.2 Detailed Design Procedure
11.2.2.2.1 Interconnecting Media
The interconnect in a multidrop system differs considerably from a point-to-point system. While point-to-point
interconnects are straightforward, and well understood, the bus type architecture encountered with multidrop
systems requires more careful attention. We will use Figure 19 above to explore these details.
The most basic multidrop system would include a single driver, located at a bus origin, with multiple receiver
nodes branching off the main line, and a final receiver at the end of the transmission line, co-located with a bus
termination resistor. While this would be the most basic multidrop system, it has several considerations not yet
explored.
The location of the transmitter at one bus end allows the design concerns to be simplified, but this comes at the
cost of flexibility. With a transmitter located at the origin, a single bus termination at the far-end is required. The
far-end termination absorbs the incident traveling wave. The flexibility lost with this arrangement is thus: if the
single transmitter needed to be relocated on the bus, at any location other than the origin, we would be faced
with a bus with one open-circuited end and one properly terminated end. Locating the transmitter say in the
middle of the bus may be desired to reduce (by ½) the maximum flight time from the transmitter to receiver.
Another new feature in Figure 19 is clear in that every node branching off the main line results in stubs. The
stubs should be minimized in any case, but have the unintended effect of locally changing the loaded impedance
of the bus.
To a good approximation, the characteristic transmission line impedance seen into any cut point in the unloaded
multipoint or multidrop bus is defined by √L/C, where L is the inductance per unit length and C is the capacitance
per unit length. As capacitance is added to the bus in the form of devices and interconnections, the bus
characteristic impedance is lowered. This may result in signal reflections from the impedance mismatch between
the unloaded and loaded segments of the bus.
If the number of loads is constant and can be distributed evenly along the line, reflections can be reduced by
changing the bus termination resistors to match the loaded characteristic impedance. Normally, the number of
loads are not constant or distributed evenly and the reflections resulting from any mismatching must be
accounted for in the noise budget.
24
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SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
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SLLS394I – SEPTEMBER 1999 – REVISED DECEMBER 2014
12 Power Supply Recommendations
The LVDS driver and receivers in this data sheet are designed to operate from a single power supply. Both
drivers and receivers operate with supply voltages in the range of 2.4 V to 3.6 V. In a typical application, a driver
and a receiver may be on separate boards, or even separate equipment. In these cases, separate supplies
would be used at each location. The expected ground potential difference between the driver power supply and
the receiver power supply would be less than |±1 V|. Board level and local device level bypass capacitance
should be used and are covered in Driver Bypass Capacitance.
13 Layout
13.1 Layout Guidelines
13.1.1 Microstrip vs. Stripline Topologies
As per SLLD009, printed-circuit boards usually offer designers two transmission line options: Microstrip and
stripline. Microstrips are traces on the outer layer of a PCB, as shown in Figure 20.
Figure 20. Microstrip Topology
On the other hand, striplines are traces between two ground planes. Striplines are less prone to emissions and
susceptibility problems because the reference planes effectively shield the embedded traces. However, from the
standpoint of high-speed transmission, juxtaposing two planes creates additional capacitance. TI recommends
routing LVDS signals on microstrip transmission lines, if possible. The PCB traces allow designers to specify the
necessary tolerances for ZO based on the overall noise budget and reflection allowances. Footnotes 1, 2, and 3
provide formulas for ZO and tPD for differential and single-ended traces. (1) (2) (3)
Figure 21. Stripline Topology
(1)
(2)
(3)
Howard Johnson & Martin Graham.1993. High Speed Digital Design – A Handbook of Black Magic. Prentice Hall PRT. ISBN number
013395724.
Mark I. Montrose. 1996. Printed Circuit Board Design Techniques for EMC Compliance. IEEE Press. ISBN number 0780311310.
Clyde F. Coombs, Jr. Ed, Printed Circuits Handbook, McGraw Hill, ISBN number 0070127549.
Copyright © 1999–2014, Texas Instruments Incorporated
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25
SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
SLLS394I – SEPTEMBER 1999 – REVISED DECEMBER 2014
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Layout Guidelines (continued)
13.1.2 Dielectric Type and Board Construction
The speeds at which signals travel across the board dictates the choice of dielectric. FR-4, or equivalent, usually
provides adequate performance for use with LVDS signals. If rise and fall times of TTL/CMOS signals are less
than 500 ps, empirical results indicate that a material with a dielectric constant near 3.4, such as Rogers™ 4350
or Nelco N4000-13 is better suited. Once the designer chooses the dielectric, there are several parameters
pertaining to the board construction that can affect performance. The following set of guidelines were developed
experimentally through several designs involving LVDS devices:
• Copper weight: 15 g or 1/2 oz start, plated to 30 g or 1 oz
• All exposed circuitry should be solder-plated (60/40) to 7.62 μm or 0.0003 in (minimum).
• Copper plating should be 25.4 μm or 0.001 in (minimum) in plated-through-holes.
• Solder mask over bare copper with solder hot-air leveling
13.1.3 Recommended Stack Layout
Following the choice of dielectrics and design specifications, you must decide how many levels to use in the
stack. To reduce the TTL/CMOS to LVDS crosstalk, it is a good practice to have at least two separate signal
planes as shown in Figure 22.
Figure 22. Four-Layer PCB Board
NOTE
The separation between layers 2 and 3 should be 127 μm (0.005 in). By keeping the
power and ground planes tightly coupled, the increased capacitance acts as a bypass for
transients.
One of the most common stack configurations is the six-layer board, as shown in Figure 23.
Figure 23. Six-Layer PCB Board
In this particular configuration, it is possible to isolate each signal layer from the power plane by at least one
ground plane. The result is improved signal integrity; however, fabrication is more expensive. Using the 6-layer
board is preferable, because it offers the layout designer more flexibility in varying the distance between signal
layers and referenced planes, in addition to ensuring reference to a ground plane for signal layers 1 and 6.
13.1.4 Separation Between Traces
The separation between traces depends on several factors; however, the amount of coupling that can be
tolerated usually dictates the actual separation. Low-noise coupling requires close coupling between the
differential pair of an LVDS link to benefit from the electromagnetic field cancellation. The traces should be 100-Ω
differential and thus coupled in the manner that best fits this requirement. In addition, differential pairs should
have the same electrical length to ensure that they are balanced, thus minimizing problems with skew and signal
reflection.
26
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SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
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Layout Guidelines (continued)
In the case of two adjacent single-ended traces, one should use the 3-W rule, which stipulates that the distance
between two traces must be greater than two times the width of a single trace, or three times its width measured
from trace center to trace center. This increased separation effectively reduces the potential for crosstalk. The
same rule should be applied to the separation between adjacent LVDS differential pairs, whether the traces are
edge-coupled or broad-side-coupled.
Figure 24. 3-W Rule for Single-Ended and Differential Traces (Top View)
You should exercise caution when using autorouters, because they do not always account for all factors affecting
crosstalk and signal reflection. For instance, it is best to avoid sharp 90° turns to prevent discontinuities in the
signal path. Using successive 45° turns tends to minimize reflections.
13.1.5 Crosstalk and Ground Bounce Minimization
To reduce crosstalk, it is important to provide a return path to high-frequency currents that is as close as possible
to its originating trace. A ground plane usually achieves this. Because the returning currents always choose the
path of lowest inductance, they are most likely to return directly under the original trace, thus minimizing
crosstalk. Lowering the area of the current loop lowers the potential for crosstalk. Traces kept as short as
possible with an uninterrupted ground plane running beneath them emit the minimum amount of electromagnetic
field strength. Discontinuities in the ground plane increase the return path inductance and should be avoided.
13.2 Layout Example
At least two or three times the width of an individual trace should separate single-ended traces and differential
pairs to minimize the potential for crosstalk. Single-ended traces that run in parallel for less than the wavelength
of the rise or fall times usually have negligible crosstalk. Increase the spacing between signal paths for long
parallel runs to reduce crosstalk. Boards with limited real estate can benefit from the staggered trace layout, as
shown in Figure 25.
Figure 25. Staggered Trace Layout
This configuration lays out alternating signal traces on different layers; thus, the horizontal separation between
traces can be less than 2 or 3 times the width of individual traces. To ensure continuity in the ground signal path,
TI recommends having an adjacent ground via for every signal via, as shown in Figure 26. Note that vias create
additional capacitance. For example, a typical via has a lumped capacitance effect of 1/2 pF to 1 pF in FR4.
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27
SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
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Layout Example (continued)
Figure 26. Ground Via Location (Side View)
Short and low-impedance connection of the device ground pins to the PCB ground plane reduces ground
bounce. Holes and cutouts in the ground planes can adversely affect current return paths if they create
discontinuities that increase returning current loop areas.
To minimize EMI problems, TI recommends avoiding discontinuities below a trace (for example, holes, slits, and
so on) and keeping traces as short as possible. Zoning the board wisely by placing all similar functions in the
same area, as opposed to mixing them together, helps reduce susceptibility issues.
28
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SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
www.ti.com
SLLS394I – SEPTEMBER 1999 – REVISED DECEMBER 2014
14 Device and Documentation Support
14.1 Device Support
14.1.1 Third-Party Products Disclaimer
TI'S PUBLICATION OF INFORMATION REGARDING THIRD-PARTY PRODUCTS OR SERVICES DOES NOT
CONSTITUTE AN ENDORSEMENT REGARDING THE SUITABILITY OF SUCH PRODUCTS OR SERVICES
OR A WARRANTY, REPRESENTATION OR ENDORSEMENT OF SUCH PRODUCTS OR SERVICES, EITHER
ALONE OR IN COMBINATION WITH ANY TI PRODUCT OR SERVICE.
14.1.2 Other LVDS Products
For other products and application notes in the LVDS and LVDM product families visit our Web site at
http://www.ti.com/sc/datatran.
14.2 Documentation Support
14.2.1 Related Information
IBIS modeling is available for this device. Contact the local TI sales office or the TI Web site at www.ti.com for
more information.
For more application guidelines, see the following documents:
• Low-Voltage Differential Signaling Design Notes (SLLA014)
• Interface Circuits for TIA/EIA-644 (LVDS) (SLLA038)
• Reducing EMI With LVDS (SLLA030)
• Slew Rate Control of LVDS Circuits (SLLA034)
• Using an LVDS Receiver With RS-422 Data (SLLA031)
• Evaluating the LVDS EVM (SLLA033)
14.3 Related Links
Table 3 lists quick access links. Categories include technical documents, support and community resources,
tools and software, and quick access to sample or buy.
Table 3. Related Links
PARTS
PRODUCT FOLDER
SAMPLE & BUY
TECHNICAL
DOCUMENTS
TOOLS &
SOFTWARE
SUPPORT &
COMMUNITY
SN65LVDS386
Click here
Click here
Click here
Click here
Click here
SN65LVDS388A
Click here
Click here
Click here
Click here
Click here
SN65LVDS390
Click here
Click here
Click here
Click here
Click here
SN65LVDT386
Click here
Click here
Click here
Click here
Click here
SN65LVDT388A
Click here
Click here
Click here
Click here
Click here
SN65LVDT390
Click here
Click here
Click here
Click here
Click here
SN75LVDS386
Click here
Click here
Click here
Click here
Click here
SN75LVDS388A
Click here
Click here
Click here
Click here
Click here
SN75LVDS390
Click here
Click here
Click here
Click here
Click here
SN75LVDT386
Click here
Click here
Click here
Click here
Click here
SN75LVDT388A
Click here
Click here
Click here
Click here
Click here
SN75LVDT390
Click here
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Click here
Click here
Click here
14.4 Trademarks
Rogers is a trademark of Rogers Corporation.
All other trademarks are the property of their respective owners.
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29
SN65LVDS386, SN65LVDS388A
SN65LVDS390, SN65LVDT386, SN65LVDT388A, SN65LVDT390, SN75LVDS386
SN75LVDS388A, SN75LVDS390, SN75LVDT386, SN75LVDT388A, SN75LVDT390
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www.ti.com
14.5 Electrostatic Discharge Caution
These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam
during storage or handling to prevent electrostatic damage to the MOS gates.
14.6 Glossary
SLYZ022 — TI Glossary.
This glossary lists and explains terms, acronyms, and definitions.
15 Mechanical, Packaging, and Orderable Information
The following pages include mechanical, packaging, and orderable information. This information is the most
current data available for the designated devices. This data is subject to change without notice and revision of
this document. For browser-based versions of this data sheet, refer to the left-hand navigation.
30
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PACKAGE OPTION ADDENDUM
www.ti.com
14-Oct-2022
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package Pins Package
Drawing
Qty
Eco Plan
(2)
Lead finish/
Ball material
MSL Peak Temp
Op Temp (°C)
Device Marking
(3)
Samples
(4/5)
(6)
SN65LVDS386DGG
ACTIVE
TSSOP
DGG
64
25
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
-40 to 85
LVDS386
Samples
SN65LVDS386DGGR
ACTIVE
TSSOP
DGG
64
2000
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
-40 to 85
LVDS386
Samples
SN65LVDS388ADBT
ACTIVE
TSSOP
DBT
38
50
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
-40 to 85
LVDS388A
Samples
SN65LVDS388ADBTR
ACTIVE
TSSOP
DBT
38
2000
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
-40 to 85
LVDS388A
Samples
SN65LVDS390D
ACTIVE
SOIC
D
16
40
RoHS & Green
NIPDAU
Level-1-260C-UNLIM
-40 to 85
LVDS390
Samples
SN65LVDS390DR
ACTIVE
SOIC
D
16
2500
RoHS & Green
NIPDAU
Level-1-260C-UNLIM
-40 to 85
LVDS390
Samples
SN65LVDS390PW
ACTIVE
TSSOP
PW
16
90
RoHS & Green
NIPDAU
Level-1-260C-UNLIM
-40 to 85
LVDS390
Samples
SN65LVDS390PWR
ACTIVE
TSSOP
PW
16
2000
RoHS & Green
NIPDAU
Level-1-260C-UNLIM
-40 to 85
LVDS390
Samples
SN65LVDT386DGG
ACTIVE
TSSOP
DGG
64
25
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
-40 to 85
LVDT386
Samples
SN65LVDT386DGGG4
ACTIVE
TSSOP
DGG
64
25
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
-40 to 85
LVDT386
Samples
SN65LVDT386DGGR
ACTIVE
TSSOP
DGG
64
2000
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
-40 to 85
LVDT386
Samples
SN65LVDT386DGGRG4
ACTIVE
TSSOP
DGG
64
2000
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
-40 to 85
LVDT386
Samples
SN65LVDT388ADBT
ACTIVE
TSSOP
DBT
38
50
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
-40 to 85
LVDT388A
Samples
SN65LVDT388ADBTR
ACTIVE
TSSOP
DBT
38
2000
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
-40 to 85
LVDT388A
Samples
SN65LVDT390D
ACTIVE
SOIC
D
16
40
RoHS & Green
NIPDAU
Level-1-260C-UNLIM
-40 to 85
LVDT390
Samples
SN65LVDT390PW
ACTIVE
TSSOP
PW
16
90
RoHS & Green
NIPDAU
Level-1-260C-UNLIM
-40 to 85
LVDT390
Samples
SN65LVDT390PWR
ACTIVE
TSSOP
PW
16
2000
RoHS & Green
NIPDAU
Level-1-260C-UNLIM
-40 to 85
LVDT390
Samples
SN75LVDS386DGG
ACTIVE
TSSOP
DGG
64
25
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
0 to 70
75LVDS386
Samples
SN75LVDS386DGGR
ACTIVE
TSSOP
DGG
64
2000
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
0 to 70
75LVDS386
Samples
SN75LVDS388ADBT
ACTIVE
TSSOP
DBT
38
50
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
0 to 70
75LVDS388A
Samples
Addendum-Page 1
PACKAGE OPTION ADDENDUM
www.ti.com
Orderable Device
14-Oct-2022
Status
(1)
Package Type Package Pins Package
Drawing
Qty
Eco Plan
(2)
Lead finish/
Ball material
MSL Peak Temp
Op Temp (°C)
Device Marking
(3)
Samples
(4/5)
(6)
SN75LVDS390D
ACTIVE
SOIC
D
16
40
RoHS & Green
NIPDAU
Level-1-260C-UNLIM
0 to 70
75LVDS390
Samples
SN75LVDS390DR
ACTIVE
SOIC
D
16
2500
RoHS & Green
NIPDAU
Level-1-260C-UNLIM
0 to 70
75LVDS390
Samples
SN75LVDS390PW
ACTIVE
TSSOP
PW
16
90
RoHS & Green
NIPDAU
Level-1-260C-UNLIM
0 to 70
DS390
Samples
SN75LVDS390PWR
ACTIVE
TSSOP
PW
16
2000
RoHS & Green
NIPDAU
Level-1-260C-UNLIM
0 to 70
DS390
Samples
SN75LVDT386DGG
ACTIVE
TSSOP
DGG
64
25
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
0 to 70
75LVDT386
Samples
SN75LVDT386DGGG4
ACTIVE
TSSOP
DGG
64
25
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
0 to 70
75LVDT386
Samples
SN75LVDT386DGGR
ACTIVE
TSSOP
DGG
64
2000
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
0 to 70
75LVDT386
Samples
SN75LVDT388ADBT
ACTIVE
TSSOP
DBT
38
50
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
0 to 70
75LVDT388A
Samples
SN75LVDT388ADBTG4
ACTIVE
TSSOP
DBT
38
50
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
0 to 70
75LVDT388A
Samples
SN75LVDT388ADBTR
ACTIVE
TSSOP
DBT
38
2000
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
0 to 70
75LVDT388A
Samples
SN75LVDT388ADBTRG4
ACTIVE
TSSOP
DBT
38
2000
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
0 to 70
75LVDT388A
Samples
SN75LVDT390D
ACTIVE
SOIC
D
16
40
RoHS & Green
NIPDAU
Level-1-260C-UNLIM
0 to 70
75LVDT390
Samples
SN75LVDT390DR
ACTIVE
SOIC
D
16
2500
RoHS & Green
NIPDAU
Level-1-260C-UNLIM
0 to 70
75LVDT390
Samples
SN75LVDT390PW
ACTIVE
TSSOP
PW
16
90
RoHS & Green
NIPDAU
Level-1-260C-UNLIM
0 to 70
DG390
Samples
SN75LVDT390PWR
ACTIVE
TSSOP
PW
16
2000
RoHS & Green
NIPDAU
Level-1-260C-UNLIM
0 to 70
DG390
Samples
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance
do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may
reference these types of products as "Pb-Free".
RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.
Addendum-Page 2
PACKAGE OPTION ADDENDUM
www.ti.com
14-Oct-2022
Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of