SN75LVDT390

ACTIVE

250-Mbps quad LVDS receiver with flow-through pinout

Product details

Function Receiver Protocols LVDS Number of transmitters 0 Number of receivers 4 Supply voltage (V) 3.3 Signaling rate (Mbps) 250 Input signal LVDS Output signal LVTTL Rating Catalog Operating temperature range (°C) 0 to 70
Function Receiver Protocols LVDS Number of transmitters 0 Number of receivers 4 Supply voltage (V) 3.3 Signaling rate (Mbps) 250 Input signal LVDS Output signal LVTTL Rating Catalog Operating temperature range (°C) 0 to 70
SOIC (D) 16 59.4 mm² 9.9 x 6 TSSOP (PW) 16 32 mm² 5 x 6.4
  • 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
  • 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

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.

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.

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.

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.

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.

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.

Download View video with transcript Video

Technical documentation

star =Top documentation for this product selected by TI
No results found. Please clear your search and try again.
View all 5
Type Title Date
* Data sheet High-Speed Differential Line Receivers. datasheet (Rev. I) 29 Jul 2014
Application brief LVDS to Improve EMC in Motor Drives 27 Sep 2018
Application brief How Far, How Fast Can You Operate LVDS Drivers and Receivers? 03 Aug 2018
Application brief How to Terminate LVDS Connections with DC and AC Coupling 16 May 2018
Application note An Overview of LVDS Technology 05 Oct 1998

Design & development

For additional terms or required resources, click any title below to view the detail page where available.

Simulation model

SN65LVDT390, SN75LVDT390 IBIS Model

SLLC047.ZIP (4 KB) - IBIS Model
Simulation tool

PSPICE-FOR-TI — PSpice® for TI design and simulation tool

PSpice® for TI is a design and simulation environment that helps evaluate functionality of analog circuits. This full-featured, design and simulation suite uses an analog analysis engine from Cadence®. Available at no cost, PSpice for TI includes one of the largest model libraries in the (...)
Simulation tool

TINA-TI — SPICE-based analog simulation program

TINA-TI provides all the conventional DC, transient and frequency domain analysis of SPICE and much more. TINA has extensive post-processing capability that allows you to format results the way you want them. Virtual instruments allow you to select input waveforms and probe circuit nodes voltages (...)
User guide: PDF
Package Pins CAD symbols, footprints & 3D models
SOIC (D) 16 Ultra Librarian
TSSOP (PW) 16 Ultra Librarian

Ordering & quality

Information included:
  • RoHS
  • REACH
  • Device marking
  • Lead finish/Ball material
  • MSL rating/Peak reflow
  • MTBF/FIT estimates
  • Material content
  • Qualification summary
  • Ongoing reliability monitoring
Information included:
  • Fab location
  • Assembly location

Support & training

TI E2E™ forums with technical support from TI engineers

Content is provided "as is" by TI and community contributors and does not constitute TI specifications. See terms of use.

If you have questions about quality, packaging or ordering TI products, see TI support. ​​​​​​​​​​​​​​

Videos