Startseite Schnittstelle I2C & I3C ICs I2C & I3C level shifters, buffers & hubs

P82B96

AKTIV

Bidirektionaler 2-Bit 2- bis 15-V 400-kHz-I2C/SMBus-Puffer/Kabelverlängerer

Produktdetails

Features Buffer Protocols I2C Frequency (max) (MHz) 0.4 VCCA (min) (V) 2 VCCA (max) (V) 15 VCCB (min) (V) 2 VCCB (max) (V) 15 Supply restrictions VCC Single Supply Rating Catalog Operating temperature range (°C) -40 to 85
Features Buffer Protocols I2C Frequency (max) (MHz) 0.4 VCCA (min) (V) 2 VCCA (max) (V) 15 VCCB (min) (V) 2 VCCB (max) (V) 15 Supply restrictions VCC Single Supply Rating Catalog Operating temperature range (°C) -40 to 85
PDIP (P) 8 92.5083 mm² 9.81 x 9.43 SOIC (D) 8 29.4 mm² 4.9 x 6 TSSOP (PW) 8 19.2 mm² 3 x 6.4 VSSOP (DGK) 8 14.7 mm² 3 x 4.9
  • Operating Power-Supply Voltage Range
    of 2 V to 15 V
  • Can Interface Between I2C Buses Operating at
    Different Logic Levels (2 V to 15 V)
  • Longer Cables by allowing bus capacitance of
    400 pF on Main Side (Sx/Sy) and 4000 pF on
    Transmission Side (Tx/Ty)
  • Outputs on the Transmission Side (Tx/Ty) Have
    High Current Sink Capability for Driving Low-
    Impedance or High-Capacitive Buses
  • Interface With Optoelectrical Isolators and Similar
    Devices That Need Unidirectional Input and
    Output Signal Paths by Splitting I2C Bus Signals
    Into Pairs of Forward (Tx/Ty) and Reverse (Rx/Ry)
    Signals
  • 400-kHz Fast I2C Bus Operation Over at Least
    20 Meters of Wire
  • Latch-Up Performance Exceeds 100 mA Per
    JESD 78, Class II
  • ESD Protection Exceeds JESD 22
  • Operating Power-Supply Voltage Range
    of 2 V to 15 V
  • Can Interface Between I2C Buses Operating at
    Different Logic Levels (2 V to 15 V)
  • Longer Cables by allowing bus capacitance of
    400 pF on Main Side (Sx/Sy) and 4000 pF on
    Transmission Side (Tx/Ty)
  • Outputs on the Transmission Side (Tx/Ty) Have
    High Current Sink Capability for Driving Low-
    Impedance or High-Capacitive Buses
  • Interface With Optoelectrical Isolators and Similar
    Devices That Need Unidirectional Input and
    Output Signal Paths by Splitting I2C Bus Signals
    Into Pairs of Forward (Tx/Ty) and Reverse (Rx/Ry)
    Signals
  • 400-kHz Fast I2C Bus Operation Over at Least
    20 Meters of Wire
  • Latch-Up Performance Exceeds 100 mA Per
    JESD 78, Class II
  • ESD Protection Exceeds JESD 22

The P82B96 device is a bus buffer that supports bidirectional data transfer between an I2C bus and a range of other bus configurations with different voltage and current levels.

One of the advantages of the P82B96 is that it supports longer cables/traces and allows for more devices per I2C bus because it can isolate bus capacitance such that the total loading (devices and trace lengths) of the new bus or remote I2C nodes are not apparent to other I2C buses (or nodes). The restrictions on the number of I2C devices in a system due to capacitance, or the physical separation between them, are greatly improved.

The device is able to provide galvanic isolation (optocoupling) or use balanced transmission lines (twisted pairs), because separate directional Tx and Rx signals are provided. The Tx and Rx signals may be connected directly (without causing bus latching), to provide an bidirectional signal line with I2C properties (open-drain driver). Likewise, the Ty and Ry signals may also be connected together to provide an bidirectional signal line with I2C properties (open-drain driver). This allows for a simple communication design, saving design time and costs.

Two or more Sx or Sy I/Os must not be connected to each other on the same node. The P82B96 design does not support this configuration. Bidirectional I2C signals do not have a direction control pin so, instead, slightly different logic low-voltage levels are used at Sx/Sy to avoid latching of this buffer. A standard I2C low applied at the Rx/Ry of a P82B96 is propagated to Sx/Sy as a buffered low with a slightly higher voltage level. If this special buffered low is applied to the Sx/Sy of another P82B96, the second P82B96 does not recognize it as a standard I2C bus low and does not propagate it to its Tx/Ty output. The Sx/Sy side of P82B96 may not be connected to similar buffers that rely on special logic thresholds for their operation.

The Sx/Sy side of the P82B96 is intended for I2C logic voltage levels of I2C master and slave devices or Tx/Rx signals of a second P82B96, if required. If Rx and Tx are connected, Sx can function as either the SDA or SCL line. Similarly, if Ry and Ty are connected, Sy can function as either the SDA or SCL line. There are no restrictions on the interconnection of the Tx/Rx and Ty/Ry I/O pins to other P82B96s, for example in a star or multi-point configuration (multiple P82B96 devices share the same Tx/Rx and Ty/Ry nodes) with the Tx/Rx and Ty/Ry I/O pins on the common bus, and the Sx/Sy side connected to the line-card slave devices.

In any design, the Sx pins of different devices should never be linked, because the resulting system would be very susceptible to induced noise and would not support all I2C operating modes.

The P82B96 device is a bus buffer that supports bidirectional data transfer between an I2C bus and a range of other bus configurations with different voltage and current levels.

One of the advantages of the P82B96 is that it supports longer cables/traces and allows for more devices per I2C bus because it can isolate bus capacitance such that the total loading (devices and trace lengths) of the new bus or remote I2C nodes are not apparent to other I2C buses (or nodes). The restrictions on the number of I2C devices in a system due to capacitance, or the physical separation between them, are greatly improved.

The device is able to provide galvanic isolation (optocoupling) or use balanced transmission lines (twisted pairs), because separate directional Tx and Rx signals are provided. The Tx and Rx signals may be connected directly (without causing bus latching), to provide an bidirectional signal line with I2C properties (open-drain driver). Likewise, the Ty and Ry signals may also be connected together to provide an bidirectional signal line with I2C properties (open-drain driver). This allows for a simple communication design, saving design time and costs.

Two or more Sx or Sy I/Os must not be connected to each other on the same node. The P82B96 design does not support this configuration. Bidirectional I2C signals do not have a direction control pin so, instead, slightly different logic low-voltage levels are used at Sx/Sy to avoid latching of this buffer. A standard I2C low applied at the Rx/Ry of a P82B96 is propagated to Sx/Sy as a buffered low with a slightly higher voltage level. If this special buffered low is applied to the Sx/Sy of another P82B96, the second P82B96 does not recognize it as a standard I2C bus low and does not propagate it to its Tx/Ty output. The Sx/Sy side of P82B96 may not be connected to similar buffers that rely on special logic thresholds for their operation.

The Sx/Sy side of the P82B96 is intended for I2C logic voltage levels of I2C master and slave devices or Tx/Rx signals of a second P82B96, if required. If Rx and Tx are connected, Sx can function as either the SDA or SCL line. Similarly, if Ry and Ty are connected, Sy can function as either the SDA or SCL line. There are no restrictions on the interconnection of the Tx/Rx and Ty/Ry I/O pins to other P82B96s, for example in a star or multi-point configuration (multiple P82B96 devices share the same Tx/Rx and Ty/Ry nodes) with the Tx/Rx and Ty/Ry I/O pins on the common bus, and the Sx/Sy side connected to the line-card slave devices.

In any design, the Sx pins of different devices should never be linked, because the resulting system would be very susceptible to induced noise and would not support all I2C operating modes.

Herunterladen Video mit Transkript ansehen Video

Technische Dokumentation

star =Von TI ausgewählte Top-Empfehlungen für dieses Produkt
Keine Ergebnisse gefunden. Bitte geben Sie einen anderen Begriff ein und versuchen Sie es erneut.
Alle anzeigen 8
Typ Titel Datum
* Data sheet P82B96 I2C Compatible Dual Bidirectional Bus Buffer datasheet (Rev. C) PDF | HTML 14 Mai 2017
Application note Understanding Transient Drive Strength vs. DC Drive Strength in Level-Shifters (Rev. A) PDF | HTML 03 Jul 2024
Design guide I2C Range Extension: I2C with CAN 07 Jan 2019
Application note Choosing the Correct I2C Device for New Designs PDF | HTML 07 Sep 2016
Selection guide I2C Infographic Flyer 03 Dez 2015
Application note Understanding the I2C Bus PDF | HTML 30 Jun 2015
Application note Maximum Clock Frequency of I2C Bus Using Repeaters 15 Mai 2015
Application note I2C Bus Pull-Up Resistor Calculation PDF | HTML 13 Feb 2015

Design und Entwicklung

Weitere Bedingungen oder erforderliche Ressourcen enthält gegebenenfalls die Detailseite, die Sie durch Klicken auf einen der unten stehenden Titel erreichen.

Simulationsmodell

P82B96 IBIS Model

SCPM008.ZIP (62 KB) - IBIS Model
Simulationstool

PSPICE-FOR-TI — PSpice® für TI Design-und Simulationstool

PSpice® für TI ist eine Design- und Simulationsumgebung, welche Sie dabei unterstützt, die Funktionalität analoger Schaltungen zu evaluieren. Diese voll ausgestattete Design- und Simulationssuite verwendet eine analoge Analyse-Engine von Cadence®. PSpice für TI ist kostenlos erhältlich und (...)
Simulationstool

TINA-TI — SPICE-basiertes analoges Simulationsprogramm

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 (...)
Benutzerhandbuch: PDF
Referenzdesigns

TIDA-00420 — ADC-basierter, digital isolierter 16-Kanal-AC/DC-Wandler mit Binäreingang und großem Eingangsspannun

Dieses Referenzdesign zeigt eine kostenoptimierte und skalierbare ADC-basierte AC/DC-Architektur mit Binäreingangsmodul (BIM) und verstärkter Isolierung. Die 16 Kanäle eines 10- oder 12-Bit-SAR-ADCs werden zur Erfassung mehrerer Binäreingänge verwendet. Die Operationsverstärker halten nicht nur die (...)
Design guide: PDF
Schaltplan: PDF
Referenzdesigns

TIDA-060013 — Referenzdesign für I2C-Reichweitenerweiterung: I2C bis CAN

This reference design focuses on extending I2C range from on-board to off-board through transmission cables using CAN transceivers and then converting the signal back to I2C. This approach allows for better signal integrity due to the differential signaling of the CAN transceivers. The (...)
Design guide: PDF
Schaltplan: PDF
Referenzdesigns

TIDA-01608 — Referenzdesign für isolierte Strommessung mit integriertem Shunt-Widerstand und I2C Schnittstelle

This verified design can accurately measure current on a bus that carries hundreds of volts. This design is targeted for solar and server applications due to their wide high-voltage input range requirements. This design uses the INA260 current shunt monitor with integrated shunt resistor for (...)
Design guide: PDF
Schaltplan: PDF
Gehäuse Pins CAD-Symbole, Footprints und 3D-Modelle
PDIP (P) 8 Ultra Librarian
SOIC (D) 8 Ultra Librarian
TSSOP (PW) 8 Ultra Librarian
VSSOP (DGK) 8 Ultra Librarian

Bestellen & Qualität

Beinhaltete Information:
  • RoHS
  • REACH
  • Bausteinkennzeichnung
  • Blei-Finish/Ball-Material
  • MSL-Rating / Spitzenrückfluss
  • MTBF-/FIT-Schätzungen
  • Materialinhalt
  • Qualifikationszusammenfassung
  • Kontinuierliches Zuverlässigkeitsmonitoring
Beinhaltete Information:
  • Werksstandort
  • Montagestandort

Empfohlene Produkte können Parameter, Evaluierungsmodule oder Referenzdesigns zu diesem TI-Produkt beinhalten.

Support und Schulungen

TI E2E™-Foren mit technischem Support von TI-Ingenieuren

Inhalte werden ohne Gewähr von TI und der Community bereitgestellt. Sie stellen keine Spezifikationen von TI dar. Siehe Nutzungsbedingungen.

Bei Fragen zu den Themen Qualität, Gehäuse oder Bestellung von TI-Produkten siehe TI-Support. ​​​​​​​​​​​​​​

Videos