SN65HVD230D

Order Now Product Folder Support & Community Tools & Software Technical Documents SN65HVD230, SN65HVD231, SN65HVD232 SLOS346O – MARCH 2001 – REVISED APRIL 2018 SN65HVD23x 3.3-V CAN Bus Transceivers 1 Features 2 Applications • • • • 1 • • • • • • • • • (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 μA 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 • • • • 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 3 Description The SN65HVD230, SN65HVD231, and SN65HVD232 controller area network (CAN) transceivers are compatible to the specifications of the ISO 11898-2 High Speed CAN Physical Layer standard (transceiver). These devices are designed for data rates up to 1 megabit per second (Mbps), and include many protection features providing device and CAN network robustness. The SN65HVD23x transceivers are designed for use with the Texas Instruments 3.3 V µPs, MCUs and DSPs with CAN controllers, or with equivalent protocol controller devices. The devices are intended for use in applications employing the CAN serial communication physical layer in accordance with the ISO 11898 standard. 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). Device Information(1) PART NUMBER PACKAGE BODY SIZE (NOM) SN65HVD230 SN65HVD231 SOIC (8) 4.90 mm × 3.91 mm SN65HVD232 (1) For all available packages, see the orderable addendum at the end of the datasheet. Equivalent Input and Output Schematic Diagrams VCC VREF VCC VCC / 2 VCC VCC BIAS UNIT D Thermal Shutdown VCC RS SLOPE CONTROL and MODE LOGIC NC R GND 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. SN65HVD230, SN65HVD231, SN65HVD232 SLOS346O – MARCH 2001 – REVISED APRIL 2018 www.ti.com Table of Contents 1 2 3 4 5 6 7 8 Features .................................................................. Applications ........................................................... Description ............................................................. Revision History..................................................... Description (continued)......................................... Device Comparison Table..................................... Pin Configuration and Functions ......................... Specifications......................................................... 8.1 8.2 8.3 8.4 8.5 8.6 8.7 8.8 8.9 8.10 8.11 1 1 1 2 4 4 5 5 Absolute Maximum Ratings ...................................... 5 ESD Ratings.............................................................. 6 Recommended Operating Conditions....................... 6 Thermal Information .................................................. 6 Electrical Characteristics: Driver ............................... 7 Electrical Characteristics: Receiver .......................... 7 Switching Characteristics: Driver .............................. 8 Switching Characteristics: Receiver.......................... 8 Switching Characteristics: Device ............................. 8 Device Control-Pin Characteristics ......................... 9 Typical Characteristics .......................................... 10 9 Parameter Measurement Information ................ 13 10 Detailed Description ........................................... 19 10.1 10.2 10.3 10.4 Overview ............................................................... Functional Block Diagram ..................................... Feature Description .............................................. Device Functional Modes...................................... 19 19 20 20 11 Application and Implementation........................ 25 11.1 Application Information.......................................... 25 11.2 Typical Application ................................................ 26 11.3 System Example ................................................... 30 12 Power Supply Recommendations ..................... 32 13 Layout................................................................... 33 13.1 Layout Guidelines ................................................. 33 13.2 Layout Example .................................................... 34 14 Device and Documentation Support ................. 35 14.1 14.2 14.3 14.4 14.5 14.6 Related Links ........................................................ Receiving Notification of Documentation Updates Community Resources.......................................... Trademarks ........................................................... Electrostatic Discharge Caution ............................ Glossary ................................................................ 35 35 35 35 35 35 15 Mechanical, Packaging, and Orderable Information ........................................................... 35 4 Revision History NOTE: Page numbers for previous revisions may differ from page numbers in the current version. Changes from Revision N (July 2015) to Revision O Page • Changed Slope Control Resistance - kW To: Slope Control Resistance - kΩ in Figure 33................................................. 22 • Changed Driver Output Signal Slope - V/ms To: Driver Output Signal Slope - V/µs in Figure 33....................................... 22 Changes from Revision M (May 2015) to Revision N • Page Changed the data sheet title From; SN65HVD230x 3.3-V CAN Bus Transceivers To: SN65HVD23x 3.3-V CAN Bus Transceivers .......................................................................................................................................................................... 1 Changes from Revision L (January 2015) to Revision M • Page Changed Figure 44 title From: "Layout Example Schematic" To: "SN65HVD23x Board Layout"........................................ 34 Changes from Revision K (February 2011) to Revision L Page • Added Pin Configuration and Functions section, ESD Ratings 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 • Changed the list of Features, Applications, and Description.................................................................................................. 1 • Added THERMAL SHUTDOWN TEMPERATURE AND HYSTERESIS in the Recommended Operating Conditions table. 6 • Added the THERMAL SHUTDOWN paragraph to the Application Information section ....................................................... 20 • Added Figure 34 and Figure 35............................................................................................................................................ 25 • Added the CAN TERMINATION paragraph to the Application Information section ............................................................. 26 • Added the BUS LOADING, LENGTH AND NUMBER OF NODES paragraph to the Application Information section........ 28 2 Submit Documentation Feedback Copyright © 2001–2018, Texas Instruments Incorporated Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 SN65HVD230, SN65HVD231, SN65HVD232 www.ti.com SLOS346O – MARCH 2001 – REVISED APRIL 2018 Changes from Revision J (January 2009) to Revision K • Page Replaced the DISSIPATION RATING TABLE with the Thermal Information table................................................................ 6 Changes from Revision I (October 2007) to Revision J Page • Deleted Low-to-High Propagation Delay Time vs Common-Mode Input Voltage Characteristics ....................................... 12 • Deleted Driver Schematic Diagram ...................................................................................................................................... 12 • Added Figure 38 ................................................................................................................................................................... 32 Copyright © 2001–2018, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 3 SN65HVD230, SN65HVD231, SN65HVD232 SLOS346O – MARCH 2001 – REVISED APRIL 2018 www.ti.com 5 Description (continued) Designed for operation in especially harsh environments, these devices feature cross wire protection, loss of ground and overvoltage protection, overtemperature protection, as well as wide common mode range of operation. The CAN transceiver is the CAN physical layer and interfaces the single ended host CAN protocol controller with the differential CAN bus found in industrial, building automation, and automotive applications. These devices operate over a -2 V to 7 V common mode range on the bus, and can withstand common mode transients of ±25 V. The RS pin (pin 8) on the SN65HVD230 and SN65HVD231 provides three different modes of operation: high speed mode, slope control mode, and low-power mode. The high speed mode of operation is selected by connecting the RS pin to ground, allowing the transmitter output transistors to switch on and off as fast as possible with no limitation on the rise and fall slopes. The rise and fall slopes can also be adjusted by connecting a resistor in series between the RS pin and ground. The slope will be proportional to the pin's output current. With a resistor value of 10 kΩ the device will have a slew rate of ~15 V/μs, and with a resistor value of 100 kΩ the device will have a slew rate of ~2 V/μs. See Application Information for more information. The SN65HVD230 enters a low current standby mode (listen only) during which the driver is switched off and the receiver remains active if a high logic level is applied to the RS pin. This mode provides a lower power consumption mode than normal mode while still allowing the CAN controller to monitor the bus for activity indicating it should return the transceiver to normal mode or slope control mode. The host controller (MCU, DSP) returns the device to a transmitting mode (high speed or slope control) when it wants to transmit a message to the bus or if during standby mode it received bus traffic indicating the need to once again be ready to transmit. The difference between the SN65HVD230 and the SN65HVD231 is that both the driver and the receiver are switched off in the SN65HVD231 when a high logic level is applied to the RS pin. In this sleep mode the device will not be able to transmit messages to the bus or receive messages from the bus. The device will remain in sleep mode until it is reactivated by applying a low logic level on the RS pin. 6 Device Comparison Table LOW POWER MODE INTEGRATED SLOPE CONTROL Vref PIN SN65HVD230 Standby mode Yes Yes SN65HVD231 Sleep mode Yes Yes SN65HVD232 No standby or sleep mode No No PART NUMBER (1) (1) 4 TA MARKED AS: VP230 40°C to 85°C VP231 VP232 For the most current package and ordering information, see Mechanical, Packaging, and Orderable Information, or see the TI web site at www.ti.com. Submit Documentation Feedback Copyright © 2001–2018, Texas Instruments Incorporated Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 SN65HVD230, SN65HVD231, SN65HVD232 www.ti.com SLOS346O – MARCH 2001 – REVISED APRIL 2018 7 Pin Configuration and Functions SN65HVD230D (Marked as VP230) SN65HVD231D (Marked as VP231) Top View SN65HVD232D (Marked as VP232) Top View D 1 8 NC CANH GND 2 7 CANH 6 CANL VCC 3 6 CANL 5 Vref R 4 5 NC D 1 8 RS GND 2 7 VCC 3 R 4 Not to scale Not to scale Pin Functions PIN NAME NO. TYPE CAN transmit data input (LOW for dominant and HIGH for recessive bus states), also called TXD, driver input D 1 GND 2 GND VCC 3 Supply R 4 O CAN receive data output (LOW for dominant and HIGH for recessive bus states), also called RXD, receiver output O SN65HVD230 and SN65HVD231: VCC / 2 reference output pin Vref 5 NC I DESCRIPTION Ground connection Transceiver 3.3V supply voltage NC SN65HVD232: No Connect CANL 6 I/O Low level CAN bus line CANH 7 I/O High level CAN bus line RS 8 NC I SN65HVD230 and SN65HVD231: Mode select pin: strong pull down to GND = high speed mode, strong pull up to VCC = low power mode, 10kΩ to 100kΩ pull down to GND = slope control mode I SN65HVD232: No Connect 8 Specifications 8.1 Absolute Maximum Ratings over operating free-air temperature range (unless otherwise noted) (1) (2) MIN Supply voltage, VCC MAX UNIT –0.3 6 V Voltage at any bus terminal (CANH or CANL) –4 16 V Voltage input, transient pulse, CANH and CANL, through 100 Ω (see Figure 24) –25 25 V Digital Input and Output voltage, VI (D or R) –0.5 VCC + 0.5 V Receiver output current, IO –11 11 mA Continuous total power dissipation See Thermal Information Storage temperature, Tstg (1) (2) –40 85 °C 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. Copyright © 2001–2018, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 5 SN65HVD230, SN65HVD231, SN65HVD232 SLOS346O – MARCH 2001 – REVISED APRIL 2018 www.ti.com 8.2 ESD Ratings VALUE Electrostatic discharge V(ESD) (1) (2) Human body model (HBM), per ANSI/ESDA/JEDEC JS001 (1) CANH, CANL and GND ±16000 All pins ±4000 Charged-device model (CDM), per JEDEC specification JESD22-C101 (2) UNIT V ±1000 JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process. JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process. 8.3 Recommended Operating Conditions MIN NOM MAX UNIT Supply voltage, VCC Voltage at any bus terminal (common mode) VIC Voltage at any bus terminal (separately) VI High-level input voltage, VIH D, R Low-level input voltage, VIL D, R 3.6 V 7 V –2.5 7.5 V 2 V –6 6 V 0 VCC V 0.75 VCC VCC V 0 100 kΩ Input voltage, V(Rs) Input voltage for standby or sleep, V(Rs) V 0.8 Differential input voltage, VID (see Figure 22) Wave-shaping resistance, Rs Driver High-level output current, IOH 3 –2 (1) –40 Receiver mA –8 Driver Low-level output current, IOL 48 Receiver 8 Thermal shutdown temperature 165 Thermal shutdown hysteresis 10 Operating free-air temperature, TA (1) mA –40 °C 85 The algebraic convention, in which the least positive (most negative) limit is designated as minimum is used in this data sheet. 8.4 Thermal Information SN65HVD230 THERMAL METRIC (1) SN65HVD231 SN65HVD232 D UNIT 8 PINS RθJA Junction-to-ambient thermal resistance 76.8 101.5 101.5 °C/W RθJC(top) Junction-to-case (top) thermal resistance 33.4 43.3 43.3 °C/W RθJB Junction-to-board thermal resistance 15.3 42.2 42.4 °C/W ψJT Junction-to-top characterization parameter 1.4 4.8 4.8 °C/W ψJB Junction-to-board characterization parameter 14.9 41.8 41.8 °C/W (1) 6 For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application report. Submit Documentation Feedback Copyright © 2001–2018, Texas Instruments Incorporated Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 SN65HVD230, SN65HVD231, SN65HVD232 www.ti.com SLOS346O – MARCH 2001 – REVISED APRIL 2018 8.5 Electrical Characteristics: Driver over recommended operating conditions (unless otherwise noted) PARAMETER TEST CONDITIONS MIN TYP (1) MAX VI = 0 V, See Figure 18 and Figure 20 CANH 2.45 VCC Dominant CANL 0.5 1.25 CANH 2.3 VOL Recessive VI = 3 V, See Figure 18 and Figure 20 CANL 2.3 VOD(D) Dominant VOH Bus output voltage Differential output voltage VOD(R) Recessive See Figure 18 1.5 2 3 VI = 0 V, See Figure 19 1.2 2 3 VI = 3 V, See Figure 18 –120 0 12 VI = 3 V, No load –0.5 –0.2 0.05 High-level input current VI = 2 V IIL Low-level input current VI = 0.8 V IOS Short-circuit output current Co Output capacitance ICC Supply current –30 V mV V μA –30 μA VCANH = -2 V –250 250 VCANL = 7 V –250 250 mA See receiver Standby SN65HVD230 V(Rs) = VCC 370 600 Sleep SN65HVD231 V(Rs) = VCC, D at VCC 0.04 1 Dominant VI = 0 V, No load Dominant 10 17 Recessive VI = VCC, No load Recessive 10 17 All devices (1) V VI = 0 V, IIH UNIT μA mA All typical values are at 25°C and with a 3.3-V supply. 8.6 Electrical Characteristics: Receiver over recommended operating conditions (unless otherwise noted) PARAMETER TEST CONDITIONS VIT+ Positive-going input threshold voltage VIT- Negative-going input threshold voltage Vhys Hysteresis voltage (VIT+ – VIT–) VOH High-level output voltage –6 V ≤ VID ≤ 500 mV, IO = –8 mA, See Figure 22 VOL Low-level output voltage 900 mV ≤ VID ≤ 6 V, IO = 8 mA, See Figure 22 MIN See Table 1 500 VIH = 7 V, Bus input current MAX UNIT 750 900 mV 650 mV 100 2.4 0.4 VIH = 7 V II TYP (1) VCC = 0 V VIH = -2 V VIH = -2 V, Other input at 0 V, D=3V VCC = 0 V 100 250 100 350 –200 –30 –100 –20 V μA μA CI CANH, CANL input capacitance Pin-to-ground, VI = 0.4 sin(4E6πt) + 0.5 V V(D) = 3 V, 32 pF CDiff Differential input capacitance Pin-to-pin, VI = 0.4 sin(4E6πt) + 0.5 V V(D) = 3 V, 16 pF RDiff Differential input resistance Pin-to-pin, RI CANH, CANL input resistance ICC Supply current (1) V(D) = 3 V 40 70 100 kΩ 20 35 50 kΩ See driver All typical values are at 25°C and with a 3.3-V supply. Copyright © 2001–2018, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 7 SN65HVD230, SN65HVD231, SN65HVD232 SLOS346O – MARCH 2001 – REVISED APRIL 2018 www.ti.com 8.7 Switching Characteristics: Driver over recommended operating conditions (unless otherwise noted) TEST CONDITIONS PARAMETER MIN TYP MAX UNIT SN65HVD230 AND SN65HVD231 tPLH Propagation delay time, low-to-high-level output V(Rs) = 0 V 35 85 RS with 10 kΩ to ground 70 125 RS with 100 kΩ to ground 500 870 70 120 RS with 10 kΩ to ground 130 180 RS with 100 kΩ to ground 870 1200 V(Rs) = 0 V tPHL Propagation delay time, high-to-low-level output V(Rs) = 0 V tsk(p) Pulse skew (|tPHL - tPLH|) CL = 50 pF, See Figure 21 60 RS with 100 kΩ to ground Differential output signal rise time tf Differential output signal fall time tr Differential output signal rise time tf Differential output signal fall time tr Differential output signal rise time tf Differential output signal fall time ns 35 RS with 10 kΩ to ground tr ns ns 370 V(Rs) = 0 V RS with 10 kΩ to ground RS with 100 kΩ to ground 25 50 100 ns 40 55 80 ns 80 120 160 ns 80 125 150 ns 600 800 1200 ns 600 825 1000 ns SN65HVD232 tPLH Propagation delay time, low-to-high-level output 35 85 tPHL Propagation delay time, high-to-low-level output 70 120 tsk(p) Pulse skew (|tPHL - tPLH|) tr Differential output signal rise time 25 50 100 tf Differential output signal fall time 40 55 80 CL = 50 pF, See Figure 21 35 ns 8.8 Switching Characteristics: Receiver over recommended operating conditions (unless otherwise noted) PARAMETER tPLH Propagation delay time, low-to-high-level output tPHL Propagation delay time, high-to-low-level output tsk(p) Pulse skew (|tPHL - tPLH|) tr Output signal rise time tf Output signal fall time TEST CONDITIONS MIN See Figure 23 See Figure 23 TYP MAX UNIT 35 50 ns 35 50 ns 10 ns 1.5 ns 1.5 ns 8.9 Switching Characteristics: Device over recommended operating conditions (unless otherwise noted) PARAMETER t(LOOP1) t(LOOP2) 8 TEST CONDITIONS Total loop delay, driver input to receiver output, recessive to dominant Total loop delay, driver input to receiver output, dominant to recessive Submit Documentation Feedback TYP MAX V(Rs) = 0 V, See Figure 26 MIN 70 115 RS with 10 kΩ to ground, See Figure 26 105 175 RS with 100 kΩ to ground, See Figure 26 535 920 V(Rs) = 0 V, See Figure 26 100 135 RS with 10 kΩ to ground, See Figure 26 155 185 RS with 100 kΩ to ground, See Figure 26 830 990 UNIT ns ns Copyright © 2001–2018, Texas Instruments Incorporated Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 SN65HVD230, SN65HVD231, SN65HVD232 www.ti.com SLOS346O – MARCH 2001 – REVISED APRIL 2018 8.10 Device Control-Pin Characteristics over recommended operating conditions (unless otherwise noted) PARAMETER t(WAKE) SN65HVD230 wake-up time from standby mode with RS SN65HVD231 wake-up time from sleep mode with RS Vref Reference output voltage I(Rs) Input current for high-speed (1) TEST CONDITIONS MIN TYP (1) MAX 0.55 1.5 μs 3 5 μs UNIT See Figure 25 -5 μA < I(Vref) < 5 μA -50 μA < I(Vref) < 50 μA V(Rs) < 1 V 0.45 VCC 0.55 VCC 0.4 VCC 0.6 VCC –450 0 V μA All typical values are at 25°C and with a 3.3-V supply. Copyright © 2001–2018, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 9 SN65HVD230, SN65HVD231, SN65HVD232 SLOS346O – MARCH 2001 – REVISED APRIL 2018 www.ti.com 8.11 Typical Characteristics 22 0 VCC = 3.3 V 60-Ω Load RS at 0 V −2 I I(L) − Logic Input Current − µ A I CC − Supply Current (RMS) − mA 21 20 19 18 17 16 15 −4 −6 −8 −10 −12 −14 14 13 0 250 500 750 −16 1000 0 0.6 1.1 1.6 2.1 2.6 VI − Input Voltage − V f − Frequency − kbps Figure 1. Supply Current (RMS) vs Frequency 160 I OL− Driver Low-Level Output Current − mA I I − Bus Input Current − µ A 300 200 VCC = 0 V 100 0 VCC = 3.6 V −100 −200 −300 −400 −7 −6 −4 −3 −1 0 1 3 4 6 7 8 10 11 140 120 100 80 60 40 20 0 12 0 VI − Bus Input Voltage − V Figure 3. Bus Input Current vs Bus Input Voltage 1 2 3 VO(CANL)− Low-Level Output Voltage − V 4 Figure 4. Driver Low-Level Output Current vs Low-Level Output Voltage 120 3 100 2.5 VCC = 3.6 V VOD− Dominant Voltage − V I OH − Driver High-Level Output Current − mA 3.6 Figure 2. Logic Input Current (Pin D) vs Input Voltage 400 80 60 40 20 0 VCC = 3.3 V VCC = 3 V 2 1.5 1 0.5 0 0.5 1 1.5 2 2.5 3 3.5 VO(CANH) − High-Level Output Voltage − V Figure 5. Driver High-Level Output Current vs High-Level Output Voltage 10 3.1 Submit Documentation Feedback 0 −55 −40 0 25 70 85 125 TA − Free-Air Temperature − °C Figure 6. Dominant Voltage (VOD) vs Free-Air Temperature Copyright © 2001–2018, Texas Instruments Incorporated Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 SN65HVD230, SN65HVD231, SN65HVD232 www.ti.com SLOS346O – MARCH 2001 – REVISED APRIL 2018 38 RS = 0 37 36 VCC = 3 V 35 VCC = 3.3 V 34 VCC = 3.6 V 33 32 31 30 −55 −40 0 25 70 85 125 t PHL− Receiver High-to-Low Propagation Delay Time − ns t PLH − Receiver Low-to-High Propagation Delay Time − ns Typical Characteristics (continued) 40 RS = 0 39 VCC = 3 V 38 VCC = 3.3 V 37 VCC = 3.6 V 36 35 34 −55 TA − Free-Air Temperature − °C VCC = 3 V 45 40 VCC = 3.3 V 35 VCC = 3.6 V 30 25 20 15 10 −55 −40 0 25 70 85 125 RS = 10 kΩ 80 VCC = 3 V VCC = 3.3 V VCC = 3.6 V 40 30 20 10 0 −55 −40 0 25 70 85 125 TA − Free-Air Temperature − °C Figure 11. Driver Low-to-High Propagation Delay Time vs Free-Air Temperature Copyright © 2001–2018, Texas Instruments Incorporated 125 RS = 0 VCC = 3.6 V 85 80 75 VCC = 3.3 V 70 VCC = 3 V 65 60 55 50 −55 −40 0 25 70 85 125 Figure 10. Driver High-to-Low Propagation Delay Time vs Free-Air Temperature t PHL − Driver High-to-Low Propagation Delay Time − ns t PLH − Driver Low-to-High Propagation Delay Time − ns 90 50 85 TA − Free-Air Temperature − °C Figure 9. Driver Low-to-High Propagation Delay Time vs Free-Air Temperature 60 70 90 TA − Free-Air Temperature − °C 70 25 Figure 8. Receiver High-to-Low Propagation Delay Time vs Free-Air Temperature t PHL− Driver High-to-Low Propagation Delay Time − ns t PLH − Driver Low-to-High Propagation Delay Time − ns 55 RS = 0 0 TA − Free-Air Temperature − °C Figure 7. Receiver Low-to-High Propagation Delay Time vs Free-Air Temperature 50 −40 150 RS = 10 kΩ VCC = 3.6 V 140 VCC = 3.3 V 130 VCC = 3 V 120 110 100 90 80 −55 −40 0 25 70 85 125 TA − Free-Air Temperature − °C Figure 12. Driver High-to-Low Propagation Delay Time vs Free-Air Temperature Submit Documentation Feedback Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 11 SN65HVD230, SN65HVD231, SN65HVD232 SLOS346O – MARCH 2001 – REVISED APRIL 2018 www.ti.com 800 t PHL− Driver High-to-Low Propagation Delay Time − ns t PLH − Driver Low-to-High Propagation Delay Time − ns Typical Characteristics (continued) RS = 100 kΩ 700 VCC = 3 V 600 VCC = 3.3 V 500 VCC = 3.6 V 400 300 200 100 0 −55 −40 0 25 70 85 125 1000 VCC = 3.6 V 950 VCC = 3.3 V 900 850 VCC = 3 V 800 750 700 TA − Free-Air Temperature − °C −55 −40 0 25 70 85 125 TA − Free-Air Temperature − °C Figure 13. Driver Low-to-High Propagation Delay Time vs Free-Air Temperature Figure 14. Driver High-to-Low Propagation Delay Time vs Free-Air Temperature t f − Differential Driver Output Fall Time − µs 50 I O − Driver Output Current − mA RS = 100 kΩ 40 30 20 10 1.50 1.40 1.30 VCC = 3.3 V 1.20 1.10 1.00 VCC = 3.6 V 0.90 0.80 0.70 0.60 VCC = 3 V 0.50 0.40 0.30 0.20 0.10 0 0 1 1.5 2 2.5 3 3.5 4 0 VCC − Supply Voltage − V 50 100 150 200 Rs − Source Resistance − kΩ Figure 15. Driver Output Current vs Supply Voltage Figure 16. Differential Driver Output Fall Time vs Source Resistance (Rs) 3 V ref − Reference Voltage − V 2.5 2 VCC = 3.6 V 1.5 VCC = 3 V 1 0.5 0 −50 −5 5 50 Iref − Reference Current − µA Figure 17. Reference Voltage vs Reference Current 12 Submit Documentation Feedback Copyright © 2001–2018, Texas Instruments Incorporated Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 SN65HVD230, SN65HVD231, SN65HVD232 www.ti.com SLOS346O – MARCH 2001 – REVISED APRIL 2018 9 Parameter Measurement Information VCC IO II D IO 60 Ω 0 V or 3 V VOD CANH VI CANL Figure 18. Driver Voltage and Current Definitions 167 Ω VOD 0V 60 Ω 167 Ω ± –2 V ≤ VTEST ≤ 7 V Figure 19. Driver VOD Dominant CANH Recessive CANL ≈3V VOH ≈ 2.3 V VOL ≈1V VOH CANH CANL Figure 20. Driver Output Voltage Definitions Copyright © 2001–2018, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 13 SN65HVD230, SN65HVD231, SN65HVD232 SLOS346O – MARCH 2001 – REVISED APRIL 2018 www.ti.com Parameter Measurement Information (continued) RL = 60 Ω Signal Generator (see Note A) CL = 50 pF (see Note B) VO 50 Ω RS = 0 Ω to 100 kΩ for SN65HVD230 and SN65HVD231 N/A for SN65HVD232 3V Input 1.5 V 0V tPLH tPHL VOD(D) 90% 0.9 V Output 0.5 V 10% tr VOD(R) tf A. The input pulse is supplied by a generator having the following characteristics: PRR ≤ 500 kHz, 50% duty cycle, tr ≤ 6 ns, tf ≤ 6 ns, Zo = 50 Ω. B. CL includes probe and jig capacitance. Figure 21. Driver Test Circuit and Voltage Waveforms IO VID V )V CANL VIC + CANH 2 VCANH VO VCANL Figure 22. Receiver Voltage and Current Definitions 14 Submit Documentation Feedback Copyright © 2001–2018, Texas Instruments Incorporated Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 SN65HVD230, SN65HVD231, SN65HVD232 www.ti.com SLOS346O – MARCH 2001 – REVISED APRIL 2018 Parameter Measurement Information (continued) Output Signal Generator (see Note A) 50 Ω 1.5 V CL = 15 pF (see Note B) 2.9 V Input 2.2 V 1.5 V tPLH tPHL VOH 90% Output 1.3 V 10% tr VOL tf A. The input pulse is supplied by a generator having the following characteristics: PRR ≤ 500 kHz, 50% duty cycle, tr ≤ 6 ns, tf ≤ 6 ns, Zo = 50 Ω. B. CL includes probe and jig capacitance. Figure 23. Receiver Test Circuit and Voltage Waveforms 100 Ω Pulse Generator, 15 µs Duration, 1% Duty Cycle Figure 24. Overvoltage Protection Copyright © 2001–2018, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 15 SN65HVD230, SN65HVD231, SN65HVD232 SLOS346O – MARCH 2001 – REVISED APRIL 2018 www.ti.com Parameter Measurement Information (continued) Table 1. Receiver Characteristics Over Common Mode With V(Rs) = 1.2 V VIC VID VCANH VCANL R OUTPUT -2 V 900 mV -1.55 V -2.45 V L 7V 900 mV 8.45 V 6.55 V L 1V 6V 4V -2 V L 4V 6V 7V 1V L -2 V 500 mV -1.75 V -2.25 V H 7V 500 mV 7.25 V 6.75 V H 1V -6 V -2 V 4V H 4V -6 V 1V 7V H X X Open Open H VOL VOH VCC 10 kΩ D R 60 Ω 0V Output CL = 15 pF RS Generator PRR = 150 kHz 50% Duty Cycle tr, tf < 6 ns Zo = 50 Ω Signal Generator 50 Ω + V(Rs) – VCC 1.5 V V(Rs) 0V t(WAKE) R Output 1.3 V Figure 25. t(WAKE) Test Circuit and Voltage Waveforms 16 Submit Documentation Feedback Copyright © 2001–2018, Texas Instruments Incorporated Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 SN65HVD230, SN65HVD231, SN65HVD232 www.ti.com SLOS346O – MARCH 2001 – REVISED APRIL 2018 0 Ω, 10 kΩ or 100 kΩ ±5% RS DUT CANH VI D 60 Ω ±1% CANL R + 15 pF ±20% VO VCC VI 50% 50% 0V t(LOOP2) t(LOOP1) VOH VO 50% 50% VOL A. All VI input pulses are supplied by a generator having the following characteristics: tr or tf ≤ 6 ns, Pulse Repetition Rate (PRR) = 125 kHz, 50% duty cycle. Figure 26. t(LOOP) Test Circuit and Voltage Waveforms Copyright © 2001–2018, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 17 SN65HVD230, SN65HVD231, SN65HVD232 SLOS346O – MARCH 2001 – REVISED APRIL 2018 www.ti.com CANH and CANL Inputs D Input VCC VCC 110 kΩ 16 V 9 kΩ 100 kΩ 45 kΩ Input 1 kΩ Input 20 V 9 kΩ 9V CANH and CANL Outputs R Output VCC VCC 16 V 5Ω Output Output 9V 20 V Figure 27. Equivalent Input and Output Schematic Diagrams 18 Submit Documentation Feedback Copyright © 2001–2018, Texas Instruments Incorporated Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 SN65HVD230, SN65HVD231, SN65HVD232 www.ti.com SLOS346O – MARCH 2001 – REVISED APRIL 2018 10 Detailed Description 10.1 Overview ISO 11898 family of standards are the international standard for high speed serial communication using the controller area network (CAN) bus protocol and physical layers (transceivers). It supports multimaster operation, real time control, programmable data rates up to 1 Mbps, and powerful redundant error checking procedures that provide reliable data transmission. It is suited for networking intelligent devices as well as sensors and actuators within the rugged electrical environment of a machine chassis or factory floor. The SN65HVD23x family of 3.3 V CAN transceivers implement the lowest layers of the ISO/OSI reference model, the ISO11898-2 standard. This is the interface with the physical signaling output of the CAN controller of the Texas Instruments µPs, MCUs and DSPs, such as TMS320Lx240x 3.3 V DSPs, as illustrated in Figure 28. ISO 11898 Specification Implementation Application Specific Layer TMS320Lx2403/6/7 3.3-V DSP Logic Link Control Data-Link Layer Embedded CAN Medium Access Control Controller Physical Signaling Physical Layer Physical Medium Attachment SN65HVD230 Medium Dependent Interface CAN Bus-Line Figure 28. Layered ISO 11898 Standard Architecture 10.2 Functional Block Diagram SN65HVD230, SN65HVD231 Logic Diagram (Positive Logic) VCC 3 5 SN65HVD232 Logic Diagram (Positive Logic) Vref D D RS R 1 1 8 R 7 4 6 7 4 6 CANH CANL CANH CANL Figure 29. Logic Diagram (Positive Logic) Copyright © 2001–2018, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 19 SN65HVD230, SN65HVD231, SN65HVD232 SLOS346O – MARCH 2001 – REVISED APRIL 2018 www.ti.com 10.3 Feature Description The SN65HVD230/231/232 are pin-compatible (but not functionally identical) with one another and, depending upon the application, may be used with identical circuit boards. These transceivers feature single 3.3 V supply operation and standard compatibility with signaling rates up to 1 Mbps, ±16 kV HBM ESD protection on the bus pins, thermal shutdown protection, bus fault protection, and opencircuit receiver failsafe. The fail-safe design of the receiver assures a logic high at the receiver output if the bus wires become open circuited. The bus pins are also maintained in a high-impedance state during low VCC conditions to ensure glitch-free power-up and power-down bus protection for hot-plugging applications. This high-impedance condition also means that an unpowered node does not disturb the bus. Transceivers without this feature usually have a very low output impedance. This results in a high current demand when the transceiver is unpowered, a condition that could affect the entire bus. 10.3.1 Vref Voltage Reference The Vref pin (pin 5) on the SN65HVD230 and SN65HVD231 is available as a VCC/2 voltage reference. This pin can be connected to the common mode point of a split termination to help further stabilize the common mode voltage of the bus. If the Vref pin is not used it may be left floating. 10.3.2 Thermal Shutdown If a high ambient temperature or excessive output currents result in thermal shutdown, the driver will be disabled and the bus pins become high impedance. During thermal shutdown the D pin to bus transmission path is blocked and the CAN bus pins are high impedance and biased to a recessive level. Once the thermal shutdown condition is cleared and the junction temperature drops below the thermal shutdown temperature the driver will be reactivated and resume normal operation. During a thermal shutdown the receiver to R pin path remains operational. 10.4 Device Functional Modes The RS pin (Pin 8) of the SN65HVD230 and SN65HVD231 provides three different modes of operation: highspeed mode, slope-control mode, and low-power mode. 10.4.1 High-Speed Mode The high-speed mode can be selected by applying a logic low to the RS pin (pin 8). The high-speed mode of operation is commonly employed in industrial applications. High-speed allows the output to switch as fast as possible with no internal limitation on the output rise and fall slopes. If the high speed transitions are a concern for emissions performance slope control mode can be used. If both high speed mode and the low-power standby mode is to be used in the application, direct connection to a µP, MCU or DSP general purpose output pin can be used to switch between a logic-low level (< 1.2 V) for high speed operation, and the logic-high level (> 0.75 VCC) for standby. Figure 30 shows a typical DSP connection, and Figure 31 shows the HVD230 driver output signal in high-speed mode on the CAN bus. D GND VCC R 1 8 2 7 3 6 4 5 RS CANH CANL Vref IOPF6 TMS320LF2406 or TMS320LF2407 Figure 30. RS (Pin 8) Connection to a TMS320LF2406/07 for High Speed/Standby Operation 20 Submit Documentation Feedback Copyright © 2001–2018, Texas Instruments Incorporated Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 SN65HVD230, SN65HVD231, SN65HVD232 www.ti.com SLOS346O – MARCH 2001 – REVISED APRIL 2018 Device Functional Modes (continued) 1 Mbps Driver Output NRZ Data 1 Figure 31. Typical High Speed SN65HVD230 Output Waveform into a 60-Ω Load 10.4.2 Slope Control Mode Electromagnetic compatibility is essential in many applications while still making use of unshielded twisted pair bus cable to reduce system cost. Slope control mode was added to the SN65HVD230 and SN65HVD231 devices to reduce the electromagnetic interference produced by the rise and fall times of the driver and resulting harmonics. These rise and fall slopes of the driver outputs can be adjusted by connecting a resistor from RS (pin 8) to ground or to a logic low voltage, as shown in Figure 32. The slope of the driver output signal is proportional to the pin's output current. This slope control is implemented with an external resistor value of 10 kΩ to achieve a ~15 V/μs slew rate, and up to 100 kΩ to achieve a ~2.0 V/μs slew rate as displayed in Figure 33. D GND VCC R 1 8 2 7 3 6 4 5 RS CANH CANL Vref 10 kΩ to 100 kΩ IOPF6 TMS320LF2406 or TMS320LF2407 Figure 32. Slope Control/Standby Connection to a DSP Copyright © 2001–2018, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 21 SN65HVD230, SN65HVD231, SN65HVD232 SLOS346O – MARCH 2001 – REVISED APRIL 2018 www.ti.com Device Functional Modes (continued) Driver Outout Signal Slope – V/ms 25 20 15 10 5 0 0 10 4.7 20 30 40 50 33 60 47 70 6.8 10 15 22 Slope Control Resistance – kW 80 68 90 100 Figure 33. HVD230 Driver Output Signal Slope vs Slope Control Resistance Value 10.4.3 Standby Mode (Listen Only Mode) of the HVD230 If a logic high (> 0.75 VCC) is applied to RS (pin 8) in Figure 30 and Figure 32, the circuit of the SN65HVD230 enters a low-current, listen only standby mode, during which the driver is switched off and the receiver remains active. In this listen only state, the transceiver is completely passive to the bus. It makes no difference if a slope control resistor is in place as shown in Figure 32. The µP can reverse this low-power standby mode when the rising edge of a dominant state (bus differential voltage > 900 mV typical) occurs on the bus. The µP, sensing bus activity, reactivates the driver circuit by placing a logic low (< 1.2 V) on RS (pin 8). 10.4.4 The Babbling Idiot Protection of the HVD230 Occasionally, a runaway CAN controller unintentionally sends messages that completely tie up the bus (what is referred to in CAN jargon as a babbling idiot). When this occurs, the µP, MCU or DSP can engage the listen-only standby mode of the transceiver to disable the driver and release the bus, even when access to the CAN controller has been lost. When the driver circuit is deactivated, its outputs default to a high-impedance state (recessive). 10.4.5 Sleep Mode of the HVD231 The unique difference between the SN65HVD230 and the SN65HVD231 is that both driver and receiver are switched off in the SN65HVD231 when a logic high is applied to RS (pin 8). The device remains in a very low power-sleep mode until the circuit is reactivated with a logic low applied to RS (pin 8). While in this sleep mode, the bus-pins are in a high-impedance state, while the D and R pins default to a logic high. 10.4.6 Summary of Device Operating Modes Table 2 shows a summary of the operating modes for the SN65HVD230 and SN65HVD231. Please note that the SN65HVD232 is a basic CAN transceiver has only the normal high speed mode of operation; pins 5 and 8 are no connection (NC). 22 Submit Documentation Feedback Copyright © 2001–2018, Texas Instruments Incorporated Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 SN65HVD230, SN65HVD231, SN65HVD232 www.ti.com SLOS346O – MARCH 2001 – REVISED APRIL 2018 Device Functional Modes (continued) Table 2. SN65HVD230 and SN65HVD231 Operating Modes RS Pin MODE DRIVER RECEIVER RXD Pin LOW, V(Rs) < 1.2 V, strong pull down to GND High Speed Mode Enabled (ON) High Speed Enabled (ON) Mirrors Bus State (1) LOW, V(Rs) < 1.2 V, 10 kΩ to 100 kΩ pull down to GND Slope Control Mode Enabled (ON) with Slope Control Enabled (ON) Mirrors Bus State Disabled (OFF) Enabled (ON) Mirrors Bus State Disabled (OFF) High HIGH, V(Rs) > 0.75 VCC Low Current SN65HVD230: Standby Mode Mode SN65HVD231: Sleep Mode (1) Mirrors bus state: low if CAN bus is dominant, high if CAN bus is recessive. Table 3. SN65HVD230 and SN65HVD231 Driver Functions DRIVER (SN65HVD230, SN65HVD231) (1) INPUT D RS L BUS STATE CANL V(Rs) < 1.2 V (including 10 kΩ to 100 kΩ pull down to GND) H L Dominant Z Z Recessive Open X Z Z Recessive X V(Rs) > 0.75 VCC Z Z Recessive H (1) OUTPUTS CANH H = high level; L = low level; X = irrelevant; ? = indeterminate; Z = high impedance Table 4. SN65HVD230 Receiver Functions RECEIVER (SN65HVD230) (1) (1) DIFFERENTIAL INPUTS RS OUTPUT R L VID ≥ 0.9 V X 0.5 V < VID < 0.9 V X ? VID ≤ 0.5 V X H Open X H H = high level; L = low level; X = irrelevant; ? = indeterminate Table 5. SN65HVD231 Receiver Functions RECEIVER (SN65HVD231) (1) DIFFERENTIAL INPUTS RS OUTPUT R VID ≥ 0.9 V 0.5 V < VID < 0.9 V L V(Rs) < 1.2 V (including 10 kΩ to 100 kΩ pull down to GND) ? VID ≤ 0.5 V (1) H X V(Rs) > 0.75 VCC H X 1.2 V < V(Rs) < 0.75 VCC ? Open X H H = high level; L = low level; X = irrelevant; ? = indeterminate Copyright © 2001–2018, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 23 SN65HVD230, SN65HVD231, SN65HVD232 SLOS346O – MARCH 2001 – REVISED APRIL 2018 www.ti.com Table 6. SN65HVD232 Receiver Functions RECEIVER (SN65HVD232) (1) (1) DIFFERENTIAL INPUTS OUTPUT R VID ≥ 0.9 V L 0.5 V < VID < 0.9 V ? VID ≤ 0.5 V H Open H H = high level; L = low level; X = irrelevant; ? = indeterminate Table 7. SN65HVD232 Driver Functions DRIVER (SN65HVD232) (1) OUTPUTS INPUT D (1) 24 CANH BUS STATE CANL L H L Dominant H Z Z Recessive Open Z Z Recessive H = high level; L = low level; Z = high impedance Submit Documentation Feedback Copyright © 2001–2018, Texas Instruments Incorporated Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 SN65HVD230, SN65HVD231, SN65HVD232 www.ti.com SLOS346O – MARCH 2001 – REVISED APRIL 2018 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 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. 11.1.1 CAN Bus States Typical Bus Voltage (V) 1 2 3 4 The CAN bus has two states during powered operation of the device; dominant and recessive. A dominant bus state is when the bus is driven differentially, corresponding to a logic low on the D and R pin. A recessive bus state is when the bus is biased to VCC / 2 via the high-resistance internal resistors RI and RDiff of the receiver, corresponding to a logic high on the D and R pins. See Figure 34 and Figure 35. CANH Vdiff(D) Vdiff(R) CANL Recessive Logic H Dominant Logic L Recessive Logic H Time, t Figure 34. CAN Bus States (Physical Bit Representation) CANH RXD VCC/2 CANL Figure 35. Simplified Recessive Common Mode Bias and Receiver Copyright © 2001–2018, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 25 SN65HVD230, SN65HVD231, SN65HVD232 SLOS346O – MARCH 2001 – REVISED APRIL 2018 www.ti.com 11.2 Typical Application Figure 36 illustrates a typical application of the SN65HVD23x family. The output of the host µP's CAN controller (TXD) is connected to the transceivers driver input, pin D, and the transceivers receiver output, pin R, is connected to the input of the CAN controller (RXD). The transceiver is attached to the differential bus lines at pins CANH and CANL. Typically, the bus is a twisted pair of wires with a characteristic impedance of 120 Ω, in the standard half-duplex multipoint topology of Figure 37. Each end of the bus is terminated with 120 Ω resistors in compliance with the standard to minimize signal reflections on the bus. Electronic Control Unit (ECU) TMS320Lx2403/6/7 CAN-Controller CANTX/IOPC6 CANRX/IOPC7 D R SN65HVD230 CANH CANL CAN Bus Line Figure 36. Details of a Typical CAN Node ECU 1 ECU 2 ECU n CANH 120 Ω CAN Bus Line 120 Ω CANL Figure 37. Typical CAN Network 11.2.1 Design Requirements 11.2.1.1 CAN Termination The ISO11898 standard specifies the interconnect to be a single twisted pair cable (shielded or unshielded) with 120 Ω characteristic impedance (ZO). Resistors equal to the characteristic impedance of the line should be used to terminate both ends of the cable to prevent signal reflections. Unterminated drop lines (stubs) connecting nodes to the bus should be kept as short as possible to minimize signal reflections. The termination may be on the cable or in a node, but if nodes may be removed from the bus the termination must be carefully placed so that it is not removed from the bus. 26 Submit Documentation Feedback Copyright © 2001–2018, Texas Instruments Incorporated Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 SN65HVD230, SN65HVD231, SN65HVD232 www.ti.com SLOS346O – MARCH 2001 – REVISED APRIL 2018 Typical Application (continued) Node n (with termination) Node 1 Node 2 Node 3 MCU or DSP MCU or DSP MCU or DSP CAN Controller CAN Controller CAN Controller CAN Transceiver CAN Transceiver CAN Transceiver MCU or DSP CAN Controller CAN Transceiver RTERM RTERM Figure 38. Typical CAN Bus Termination is typically a 120 Ω resistor at each end of the bus. If filtering and stabilization of the common mode voltage of the bus is desired, then split termination may be used (see Figure 39). Split termination utilizes two 60Ω resistors with a capacitor in the middle of these resistors to ground. Split termination improves the electromagnetic emissions behavior of the network by eliminating fluctuations in the bus common mode voltages at the start and end of message transmissions. Care should be taken in the power ratings of the termination resistors used. Typically the worst case condition would be if the system power supply was shorted across the termination resistance to ground. In most cases the current flow through the resistor in this condition would be much higher than the transceiver's current limit. Standard Termination CANH Split Termination CANH RTERM/2 CAN CAN Transceiver RTERM Transceiver CSPLIT RTERM/2 CANL CANL Figure 39. CAN Bus Termination Concepts 11.2.1.2 Loop Propagation Delay Transceiver loop delay is a measure of the overall device propagation delay, consisting of the delay from the driver input (D pin) to the differential outputs (CANH and CANL pins), plus the delay from the receiver inputs (CANH and CANL) to its output (R pin). Copyright © 2001–2018, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 27 SN65HVD230, SN65HVD231, SN65HVD232 SLOS346O – MARCH 2001 – REVISED APRIL 2018 www.ti.com Typical Application (continued) A typical loop delay for the SN65HVD230 transceiver is displayed in Figure 40. This loop delay will increase as the slope of the driver output is slowed during slope control mode. This increased loop delay means that there is a tradeoff between the total bus length able to be used and the driver's output slope used via the slope control pin of the device. For example, the loop delay for a 10-kΩ resistor from the RS pin to ground is ~100 ns, and the loop delay for a 100-kΩ resistor is ~500 ns. Therefore, if we use the following rule-of-thumb that the propagation delay of typical twisted pair bus cable is 5 ns/m, we can calculate an approximate cable length trade-off between normal high-speed mode and slope control mode with a 100-kΩ resistor. Using typical values, the loop delay for a recessive to dominant bit with RS tied directly to ground is 70ns, and with a 100-kΩ resistor is 535 ns. At 5ns/m of propagation delay, which you have to count in both directions the difference is 46.5 meters (535-70)/(2*5). Another option to improving the elctromagnetic emissions of the device besides slowing down the edge rates of the driver in slope control mode is using quality shielded bus cabling. ( ) Figure 40. 70.7-ns Loop Delay Through the HVD230 With RS = 0 11.2.1.3 Bus Loading, Length and Number of Nodes The ISO11898 Standard specifies up to 1 Mbps data rate, maximum bus length of 40 meters, maximum drop line (stub) length of 0.3 meters and a maximum of 30 nodes. However, with careful network design, the system may have longer cables, longer stub lengths, and many more nodes. Many CAN organizations and standards have scaled the use of CAN for applications outside the original ISO11898 standard. They have made system level trade-offs for data rate, cable length, and parasitic loading of the bus. Examples of some of these specifications are ARINC825, CANopen, CAN Kingdom, DeviceNet and NMEA200. A high number of nodes requires a transceiver with high input impedance and wide common mode range such as the SN65HVD23x CAN family. ISO11898-2 specifies the driver differential output with a 60 Ω load (two 120 Ω termination resistors in parallel) and the differential output must be greater than 1.5 V. The SN65HVD23x devices are specified to meet the 1.5 V requirement with a 60 Ω load, and additionally specified with a differential output voltage minimum of 1.2 V across a common mode range of –2 V to 7 V via a 167 Ω coupling network. This network represents the bus loading of 120 SN65HVD23x transceivers based on their minimum differential input resistance of 40 kΩ. Therefore, the SN65HVD23x supports up to 120 transceivers on a single bus segment with margin to the 1.2 V minimum differential input voltage requirement at each node. For CAN network design, 28 Submit Documentation Feedback Copyright © 2001–2018, Texas Instruments Incorporated Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 SN65HVD230, SN65HVD231, SN65HVD232 www.ti.com SLOS346O – MARCH 2001 – REVISED APRIL 2018 Typical Application (continued) margin must be given for signal loss across the system and cabling, parasitic loadings, network imbalances, ground offsets and signal integrity thus a practical maximum number of nodes may be lower. Bus length may also be extended beyond the original ISO11898 standard of 40 meters by careful system design and data rate tradeoffs. For example, CANopen network design guidelines allow the network to be up to 1 km with changes in the termination resistance, cabling, less than 64 nodes and significantly lowered data rate. This flexibility in CAN network design is one of the key strengths of the various extensions and additional standards that have been built on the original ISO11898 CAN standard. In using this flexibility comes the responsibility of good network design. 11.2.2 Detailed Design Procedure The following system level considerations should be looked at when designing your application. There are tradeoffs between the total number of nodes, the length of the bus, and the slope of the driver output that need to be evaluated when building up a system 11.2.2.1 Transient Protection Typical applications that use CAN will sometime require some form of ESD, burst, or surge protection performance at the system level. If these requirements are higher than those of the device some form of external protection may be needed to shield the transceiver against these high power transients that can cause damage. Transient voltage suppressor (TVS) are very commonly used and can help clamp the amount of energy that reaches the transceiver. 11.2.2.2 Transient Voltage Suppressors Transient voltage suppressors are the preferred protection components for CAN bus applications due to their low capacitance, fast response times and high peak power dissipation limits. The low bus capacitance allows these devices to be used at many, if not all, nodes on the network without having to reduce the data rate. The quick response times in the order of a few picoseconds enable these devices to clamp the energy of very fast transients like ESD and EFT. Lastly, the high peak power ratings enable these devices to handle high energy surge pulses without being damaged. 11.2.3 Application Curve Typical driver output waveforms from a pulse input signal with different slope control resistances are displayed in Figure 41. The top waveform show the typical differential signal when transitioning from a recessive level to a dominant level on the CAN bus with RS tied to GND through a zero ohm resistor. The second waveform shows the same signal for the condition with a 10k ohm resistor tied from RS to ground. The bottom waveform shows the typical differential signal for the case where a 100k ohm resistor is tied from the RS pin to ground. Copyright © 2001–2018, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 29 SN65HVD230, SN65HVD231, SN65HVD232 SLOS346O – MARCH 2001 – REVISED APRIL 2018 www.ti.com Typical Application (continued) RS = 0 Ω RS = 10 kΩ RS = 100 kΩ Figure 41. Typical SN65HVD230 250-kbps Output Pulse Waveforms With Slope Control 11.3 System Example 11.3.1 ISO 11898 Compliance of SN65HVD23x Family of 3.3 V CAN Transceivers 11.3.1.1 Introduction Many users value the low power consumption of operating their CAN transceivers from a 3.3 V supply. However, some are concerned about the interoperability with 5 V supplied transceivers on the same bus. This report analyzes this situation to address those concerns. 11.3.1.2 Differential Signal CAN is a differential bus where complementary signals are sent over two wires and the voltage difference between the two wires defines the logical state of the bus. The differential CAN receiver monitors this voltage difference and outputs the bus state with a single-ended output signal. 30 Submit Documentation Feedback Copyright © 2001–2018, Texas Instruments Incorporated Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 SN65HVD230, SN65HVD231, SN65HVD232 www.ti.com SLOS346O – MARCH 2001 – REVISED APRIL 2018 System Example (continued) NOISE MARGIN 900 mV Threshold RECEIVER DETECTION WINDOW 75% SAMPLE POINT 500 mV Threshold NOISE MARGIN Figure 42. Typical SN65HVD230 Differential Output Voltage Waveform The CAN driver creates the differential voltage between CANH and CANL in the dominant state. The dominant differential output of the SN65HVD23x is greater than 1.5 V and less than 3 V across a 60 ohm load as defined by the ISO 11898 standard. These are the same limiting values for 5 V supplied CAN transceivers. Typically, the bus termination resistors drive the bus back to the recessive bus state and not the CAN driver. A CAN receiver is required to output a recessive state when less than 500 mV of differential voltage exists on the bus, and a dominant state when more than 900 mV of differential voltage exists on the bus. The CAN receiver must do this with common-mode input voltages from -2 V to 7 volts per the ISO 11898-2 standard. The SN65HVD23x family receivers meet these same input specifications as 5 V supplied receivers. 11.3.1.2.1 Common Mode Signal A common-mode signal is an average voltage of the two signal wires that the differential receiver rejects. The common-mode signal comes from the CAN driver, ground noise, and coupled bus noise. Since the bias voltage of the recessive state of the device is dependent on VCC, any noise present or variation of VCC will have an effect on this bias voltage seen by the bus. The SN65HVD23x family has the recessive bias voltage set higher than 0.5*VCC to comply with the ISO 11898-2 CAN standard which states that the recessive bias voltage must be between 2 V and 3 V. The caveat to this is that the common mode voltage will drop by a couple hundred millivolts when driving a dominant bit on the bus. This means that there is a common mode shift between the dominant bit and recessive bit states of the device. While this is not ideal, this small variation in the driver common-mode output is rejected by differential receivers and does not effect data, signal noise margins or error rates. 11.3.1.3 Interoperability of 3.3-V CAN in 5-V CAN Systems The 3.3 V supplied SN65HVD23x family of CAN transceivers are fully compatible with 5 V CAN transceivers. The differential output voltage is the same, the recessive common mode output bias is the same, and the receivers have the same input specifications. The only difference is in the dominant common mode output voltage is lower in 3.3 V CAN transceivers than with 5 V supplied transceiver (by a few hundred millivolts). To help ensure the widest interoperability possible, the SN65HVD23x family has successfully passed the internationally recognized GIFT ICT conformance and interoperability testing for CAN transceivers which is shown in . Electrical interoperability does not always assure interchangeability however. Most implementers of CAN buses recognize that ISO 11898 does not sufficiently specify the electrical layer and that strict standard compliance alone does not ensure full interchangeability. This comes only with thorough equipment testing. Copyright © 2001–2018, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 31 SN65HVD230, SN65HVD231, SN65HVD232 SLOS346O – MARCH 2001 – REVISED APRIL 2018 www.ti.com System Example (continued) Trigger Input TEKTRONIX HFS-9003 Pattern Generator TEKTRONIX 784D Oscilloscope TEKTRONIX P6243 Single-Ended Probes One Meter Belden Cable # 3105A 120 W 120 W SN65HVD230 SN65HVD230 Competitor X251 SN65HVD251 – + HP E3516A 3.3-V Power Supply – + HP E3516A 5-V Power Supply Figure 43. 3.3-V and 5-V CAN Transceiver System Testing 12 Power Supply Recommendations The SN65HVD23x 3.3 V CAN transceivers provide the interface between the 3.3 V µPs, MCUs and DSPs and the differential bus lines, and are designed to transmit data at signaling rates up to 1 Mbps as defined by the ISO 11898 standard. To ensure reliable operation at all data rates and supply voltages, the VCC supply pin of each CAN transceiver should be decoupled with a 100-nF ceramic capacitor located as close to the VCC and GND pins as possible. The TPS76333 is a linear voltage regulator suitable for supplying the 3.3-V supply. 32 Submit Documentation Feedback Copyright © 2001–2018, Texas Instruments Incorporated Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 SN65HVD230, SN65HVD231, SN65HVD232 www.ti.com SLOS346O – MARCH 2001 – REVISED APRIL 2018 13 Layout 13.1 Layout Guidelines In order for the PCB design to be successful, start with design of the protection and filtering circuitry. Because ESD and EFT transients have a wide frequency bandwidth from approximately 3 MHz to 3 GHz, high frequency layout techniques must be applied during PCB design. On chip IEC ESD protection is good for laboratory and portable equipment but is usually not sufficient for EFT and surge transients occurring in industrial environments. Therefore robust and reliable bus node design requires the use of external transient protection devices at the bus connectors. Placement at the connector also prevents these harsh transient events from propagating further into the PCB and system. Use VCC and ground planes to provide low inductance. Note: high frequency current follows the path of least inductance and not the path of least resistance. Design the bus protection components in the direction of the signal path. Do not force the transient current to divert from the signal path to reach the protection device. An example placement of the Transient Voltage Suppression (TVS) device indicated as D1 (either bi-directional diode or varistor solution) and bus filter capacitors C8 and C9 are shown in . The bus transient protection and filtering components should be placed as close to the bus connector, J1, as possible. This prevents transients, ESD and noise from penetrating onto the board and disturbing other devices. Bus termination: Figure 44 shows split termination. This is where the termination is split into two resistors, R7 and R8, with the center or split tap of the termination connected to ground via capacitor C7. Split termination provides common mode filtering for the bus. When termination is placed on the board instead of directly on the bus, care must be taken to ensure the terminating node is not removed from the bus as this will cause signal integrity issues of the bus is not properly terminated on both ends. See the application section for information on power ratings needed for the termination resistor(s). Bypass and bulk capacitors should be placed as close as possible to the supply pins of transceiver, examples C2, C3 (VCC). Use at least two vias for VCC and ground connections of bypass capacitors and protection devices to minimize trace and via inductance. To limit current of digital lines, serial resistors may be used. Examples are R1, R2, R3 and R4. To filter noise on the digital IO lines, a capacitor may be used close to the input side of the IO as shown by C1 and C4. Since the internal pull up and pull down biasing of the device is weak for floating pins, an external 1k to 10k ohm pull-up or down resistor should be used to bias the state of the pin more strongly against noise during transient events. Pin 1: If an open drain host processor is used to drive the D pin of the device an external pull-up resistor between 1k and 10k ohms should be used to drive the recessive input state of the device (R1). Pin 8: is shown assuming the mode pin, RS, will be used. If the device will only be used in normal mode or slope control mode, R3 is not needed and the pads of C4 could be used for the pull down resistor to GND. Pin 5 in is shown for the SN65HVD230 and SN65HVD231 devices which have a Vref output voltage reference. If used, this pin should be tied to the common mode point of the split termination. If this feature is not used, the pin can be left floating. For the SN65HVD232, pins 5 and 8 are no connect (NC) pin. This means that the pins are not internally connected and can be left floating. Copyright © 2001–2018, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 33 SN65HVD230, SN65HVD231, SN65HVD232 SLOS346O – MARCH 2001 – REVISED APRIL 2018 www.ti.com 13.2 Layout Example GND C8 R7 GND C7 R3 C9 R8 J1 U1 U1 D1 C3 C2 VCC RXD GND C1 R2 TXD C4 R1 R4 RS VCC GND Vref can be routed under the device Figure 44. SN65HVD23x Board Layout 34 Submit Documentation Feedback Copyright © 2001–2018, Texas Instruments Incorporated Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 SN65HVD230, SN65HVD231, SN65HVD232 www.ti.com SLOS346O – MARCH 2001 – REVISED APRIL 2018 14 Device and Documentation Support 14.1 Related Links The table below lists quick access links. Categories include technical documents, support and community resources, tools and software, and quick access to sample or buy. Table 8. Related Links PARTS PRODUCT FOLDER SAMPLE & BUY TECHNICAL DOCUMENTS TOOLS & SOFTWARE SUPPORT & COMMUNITY SN65HVD230 Click here Click here Click here Click here Click here SN65HVD231 Click here Click here Click here Click here Click here SN65HVD232 Click here Click here Click here Click here Click here 14.2 Receiving Notification of Documentation Updates To receive notification of documentation updates, navigate to the device product folder on ti.com. In the upper right corner, click on Alert me to register and receive a weekly digest of any product information that has changed. For change details, review the revision history included in any revised document. 14.3 Community Resources The following links connect to TI community resources. Linked contents are provided "AS IS" by the respective contributors. They do not constitute TI specifications and do not necessarily reflect TI's views; see TI's Terms of Use. TI E2E™ Online Community TI's Engineer-to-Engineer (E2E) Community. Created to foster collaboration among engineers. At e2e.ti.com, you can ask questions, share knowledge, explore ideas and help solve problems with fellow engineers. Design Support TI's Design Support Quickly find helpful E2E forums along with design support tools and contact information for technical support. 14.4 Trademarks E2E is a trademark of Texas Instruments. All other trademarks are the property of their respective owners. 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. Copyright © 2001–2018, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Links: SN65HVD230 SN65HVD231 SN65HVD232 35 PACKAGE OPTION ADDENDUM www.ti.com 13-Aug-2021 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) (4/5) (6) SN65HVD230D ACTIVE SOIC D 8 75 RoHS & Green NIPDAU Level-1-260C-UNLIM -40 to 85 VP230 SN65HVD230DG4 ACTIVE SOIC D 8 75 RoHS & Green NIPDAU Level-1-260C-UNLIM -40 to 85 VP230 SN65HVD230DR ACTIVE SOIC D 8 2500 RoHS & Green NIPDAU Level-1-260C-UNLIM -40 to 85 VP230 SN65HVD230DRG4 ACTIVE SOIC D 8 2500 RoHS & Green NIPDAU Level-1-260C-UNLIM -40 to 85 VP230 SN65HVD231D ACTIVE SOIC D 8 75 RoHS & Green NIPDAU Level-1-260C-UNLIM -40 to 85 VP231 SN65HVD231DG4 ACTIVE SOIC D 8 75 RoHS & Green NIPDAU Level-1-260C-UNLIM -40 to 85 VP231 SN65HVD231DR ACTIVE SOIC D 8 2500 RoHS & Green NIPDAU Level-1-260C-UNLIM -40 to 85 VP231 SN65HVD231DRG4 ACTIVE SOIC D 8 2500 RoHS & Green NIPDAU Level-1-260C-UNLIM -40 to 85 VP231 SN65HVD232D ACTIVE SOIC D 8 75 RoHS & Green NIPDAU Level-1-260C-UNLIM -40 to 85 VP232 SN65HVD232DG4 ACTIVE SOIC D 8 75 RoHS & Green NIPDAU Level-1-260C-UNLIM -40 to 85 VP232 SN65HVD232DR ACTIVE SOIC D 8 2500 RoHS & Green NIPDAU Level-1-260C-UNLIM -40 to 85 VP232 SN65HVD232DRG4 ACTIVE SOIC D 8 2500 RoHS & Green NIPDAU Level-1-260C-UNLIM -40 to 85 VP232 (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. Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of