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SN65HVD230DR

The SN65HVD230DR is an electronic component from Texas Instruments. View the full SN65HVD230DR datasheet below including key specifications, electrical characteristics, absolute maximum ratings.

Manufacturer

Texas Instruments

Category

Integrated Circuits

Package

SOIC-8

Lifecycle

Active

Key Specifications

ParameterValue
Data Rate1Mbps
DuplexHalf
Mounting TypeSurface Mount
Number of Drivers/Receivers1/1
Operating Temperature-40°C ~ 85°C
Package / Case8-SOIC (0.154", 3.90mm Width)
ProtocolCANbus
Receiver Hysteresis100 mV
Receiver Hysteresis100 mV
Supplier Device Package8-SOIC
Supplier Device Package8-SOIC
TypeTransceiver
TypeTransceiver
Supply Voltage3V ~ 3.6V

Overview

Part: SN65HVD230, SN65HVD231, SN65HVD232 from Texas Instruments

Type: CAN Bus Transceiver

Description: The SN65HVD23x is a 3.3-V CAN bus transceiver compatible with ISO 11898-2, designed for data rates up to 1 Mbps, featuring bus pin ESD protection exceeding ±16 kV HBM, and supporting up to 120 nodes on a bus.

Operating Conditions:

  • Supply voltage: 3.3 V
  • Operating temperature: -40 to 85 °C
  • Max data rate: 1 Mbps
  • Bus common mode range: -2 V to 7 V

Absolute Maximum Ratings:

Key Specs:

  • Supply voltage: 3.3 V
  • Data rates: up to 1 Mbps
  • Bus pin ESD protection: Exceeds ±16 kV HBM
  • Max nodes on a bus: 120
  • SN65HVD230 Standby current: 370 μA Typical
  • SN65HVD231 Sleep current: 40 nA Typical
  • Bus common mode transient withstand: ±25 V
  • Adjustable driver transition times

Features:

  • Operates with a single 3.3 V Supply
  • Compatible With ISO 11898-2 Standard
  • Low Power Replacement for the PCA82C250 Footprint
  • Bus Pin ESD Protection Exceeds ±16 kV HBM
  • High Input Impedance Allows for Up to 120 Nodes on a Bus
  • Adjustable Driver Transition Times for Improved Emissions Performance
  • SN65HVD230: Low Current Standby Mode - 370 μA Typical
  • SN65HVD231: Ultra Low Current Sleep Mode - 40 nA Typical
  • Designed for Data Rates up to 1 Mbps
  • Thermal Shutdown Protection
  • Open Circuit Fail-Safe Design
  • Glitch Free Power Up and Power Down Protection for Hot Plugging Applications

Applications:

  • Industrial Automation, Control, Sensors and Drive Systems
  • Motor and Robotic Control
  • Building and Climate Control (HVAC)
  • Telecom and Basestation Control and Status
  • CAN Bus Standards Such as CANopen, DeviceNet, and CAN Kingdom

Package:

  • SOIC (8)

Features

  • 1 · Operates with a single 3.3 V Supply
  • Compatible With ISO 11898-2 Standard
  • Low Power Replacement for the PCA82C250 Footprint
  • Bus Pin ESD Protection Exceeds ±16 kV HBM
  • High Input Impedance Allows for Up to 120 Nodes on a Bus
  • Adjustable Driver Transition Times for Improved Emissions Performance
  • -SN65HVD230 and SN65HVD231
  • SN65HVD230: Low Current Standby Mode
  • -370 μ A Typical
  • SN65HVD231: Ultra Low Current Sleep Mode -40 nA Typical
  • Designed for Data Rates (1) up to 1 Mbps
  • Thermal Shutdown Protection
  • Open Circuit Fail-Safe Design
  • Glitch Free Power Up and Power Down Protection for Hot Plugging Applications
  • (1) The signaling rate of a line is the number of voltage transitions that are made per second expressed in the units bps (bits per second).

Applications

  • Industrial Automation, Control, Sensors and Drive Systems
  • Motor and Robotic Control
  • Building and Climate Control (HVAC)
  • Telecom and Basestation Control and Status
  • CAN Bus Standards Such as CANopen, DeviceNet, and CAN Kingdom

Pin Configuration

Not to scale

Electrical Characteristics

over recommended operating conditions (unless otherwise noted)

PARAMETERPARAMETERPARAMETERPARAMETERTEST CONDITIONSTEST CONDITIONSTEST CONDITIONSMINTYP (1)MAXUNIT
V OHBus outputDominantV I = 0 V,V I = 0 V,CANH2.45V CCV
V OHBus outputSee Figure 18 and Figure 20See Figure 18 and Figure 20CANL0.51.25V
V OLvoltageRecessiveV I = 3 V,V I = 3 V,CANH2.3V
V OLvoltageSee Figure 18 and Figure 20See Figure 18 and Figure 20CANL2.3V
V OD(D)DominantV I = 0 V,See Figure 181.523V
V OD(D)DifferentialV I = 0 V,See Figure 191.223V
V OD(R)output voltageRecessiveV I = 3 V,See Figure 18-120012mV
V OD(R)output voltageV I = 3 V,No load-0.5-0.20.05V
I IHHigh-level input currentHigh-level input currentHigh-level input currentV I = 2 V-30μ A
I ILLow-level input currentLow-level input currentLow-level input currentV I = 0.8 V-30μ A
I OSV CANH = -2 V-250250mA
I OSShort-circuit output currentShort-circuit output currentShort-circuit output currentV CANL = 7 V-250250mA
C oOutput capacitanceOutput capacitanceOutput capacitanceSee receiverSee receiverSee receiver
I CCSupply currentStandbySN65HVD230V (Rs) = V CC370600μ A
I CCSleepSN65HVD231V (Rs) = V CC , D at V CCV (Rs) = V CC , D at V CCV (Rs) = V CC , D at V CC0.041μ A
I CCAll devicesDominantV I = 0 V,No loadDominant1017mA
I CCRecessiveV I = V CC ,No loadRecessive1017mA

Absolute Maximum Ratings

over operating free-air temperature range (unless otherwise noted) (1)(2)

MINMAXUNIT
Supply voltage, V CC-0.36V
Voltage at any bus terminal (CANH or CANL)-416V
Voltage input, transient pulse, CANH and CANL, through 100 Ω (see Figure 24)-2525V
Digital Input and Output voltage, V I (D or R)-0.5V CC + 0.5V
Receiver output current, I O-1111mA
Continuous total power dissipationSee Thermal InformationSee Thermal Information
Storage temperature, T stg-4085°C

Not to scale

Recommended Operating Conditions

MINNOMMAXUNIT
Supply voltage, V CCSupply voltage, V CC33.6V
Voltage at any bus terminal (common mode) V ICVoltage at any bus terminal (common mode) V IC-2 (1)7V
Voltage at any bus terminal (separately) V IVoltage at any bus terminal (separately) V I-2.57.5V
High-level input voltage, V IHD, R2V
Low-level input voltage, V ILD, R0.8V
Differential input voltage, V ID (see Figure 22)Differential input voltage, V ID (see Figure 22)-66V
Input voltage, V (Rs)Input voltage, V (Rs)0V CCV
Input voltage for standby or sleep, V (Rs)Input voltage for standby or sleep, V (Rs)0.75 V CCV CCV
Wave-shaping resistance, RsWave-shaping resistance, Rs0100k Ω
High-level output current, I OHDriver-40mA
High-level output current, I OHReceiver-8mA
Low-level output current, I OLDriver48mA
Low-level output current, I OLReceiver8
Thermal shutdown temperatureThermal shutdown temperature165
Thermal shutdown hysteresisThermal shutdown hysteresis10°C
Operating free-air temperature, T AOperating free-air temperature, T A-4085

Thermal Information

SN65HVD230SN65HVD231SN65HVD232
THERMAL METRIC (1)DDD
8 PINS8 PINS8 PINS
R θ JAJunction-to-ambient thermal resistance76.8101.5101.5
R θ JC(top)Junction-to-case (top) thermal resistance33.443.343.3
R θ JBJunction-to-board thermal resistance15.342.242.4
ψ JTJunction-to-top characterization parameter1.44.84.8
ψ JBJunction-to-board characterization parameter14.941.841.8

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Typical Application

This application section provides information concerning the implementation of the physical medium attachment layer in a CAN network according to the ISO 11898 standard. It presents a typical application circuit and test results, as well as discussions on slope control, total loop delay, and interoperability in 5-V CAN systems.

Related Variants

The following components are covered by the same datasheet.

Part NumberManufacturerPackage
SN65HVD230Texas InstrumentsSOIC (8)
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