NCV73513 NCV73510 NCV7351E NCV7351, NCV7351F High Speed CAN, CAN FD Transceiver The NCV7351 CAN transceiver is the interface between a controller area network (CAN) protocol controller and the physical bus and may be used in both 12 V and 24 V systems. The transceiver provides differential transmit capability to the bus and differential www.onsemi.com receive capability to the CAN controller. The NCV7351 is an addition to the CAN highspeed transceiver MARKING DIAGRAM family complementing NCV734x CAN standalone transceivers and 8 previous generations such as AMIS42665, AMIS3066x, etc. The NCV7351F is an addition to the family based on NCV7351 8 NV7351y ALYW transceiver with improved bit timing symmetry behavior to cope with 1 CAN flexible data rate requirements (CAN FD). SOIC8 Due to the wide commonmode voltage range of the receiver inputs CASE 751AZ 1 and other design features, the NCV7351 is able to reach outstanding NV7351y / NV7351Fy levels of electromagnetic susceptibility (EMS). Similarly, extremely y = 3, 0, or E low electromagnetic emission (EME) is achieved by the excellent F = Flexible data rate version matching of the output signals. (no dash used for CAN FD version) A = Assembly Location Key Features L = Wafer Lot Compatible with the ISO 118982 Standard Y = Year W = Work Week High Speed (up to 1 Mbps) = PbFree Package NCV7351F Version Has Specification for Loop Delay Symmetry (up to 2 Mbps according to ISO118982, up to 5 Mbps for PIN ASSIGNMENT information only) 1 8 TxD S V Pin on NCV7351(F)D13 Version Allowing Direct Interfacing IO 2 7 with 3 V to 5 V Microcontrollers GND CANH EN Pin on NCV7351D1E Version Allowing Switching the 6 3 Transceiver to a Very Low Current OFF Mode V CANL CC Excellent Electromagnetic Susceptibility (EMS) Level Over Full 4 5 Frequency Range. Very Low Electromagnetic Emissions (EME) Low V RxD IO EME also Without Common Mode (CM) Choke NCV7351(F)D13R2G 1 8 Bus Pins Protected Against >15 kV System ESD Pulses TxD S Transmit Data (TxD) Dominant Timeout Function 2 7 Under all Supply Conditions the Chip Behaves Predictably. No GND CANH Disturbance of the Bus Lines with an Unpowered Node 3 6 V CANL CC Bus Pins Short Circuit Proof to Supply Voltage and Ground 4 5 Bus Pins Protected Against Transients in an Automotive NC RxD Environment NCV7351D10R2G Thermal Protection 1 8 TxD S These are PbFree Devices 2 7 Quality GND CANH NCV Prefix for Automotive and Other Applications Requiring 3 6 Unique Site and Control Change Requirements AECQ100 V CANL CC Qualified and PPAP Capable 4 5 EN RxD Typical Applications NCV7351D1ER2G Automotive Industrial Networks ORDERING INFORMATION See detailed ordering and shipping information in the package dimensions section on page 12 of this data sheet. Semiconductor Components Industries, LLC, 2016 1 Publication Order Number: June, 2016 Rev. 3 NCV7351/DNCV7351, NCV7351F Table 1. KEY TECHNICAL CHARACTERISTICS AND OPERATING RANGES Symbol Parameter Conditions Min Max Unit V Power supply voltage 4.5 5.5 V CC V Undervoltage detection voltage 3.5 4.5 V UV on pin V CC V DC voltage at pin CANH 0 < V < 5.5 V no time limit 50 +50 V CANH CC V DC voltage at pin CANL 0 < V < 5.5 V no time limit 50 +50 V CANL CC V DC voltage between CANH and 0 < V < 5.5 V 50 +50 V CANH,L CC CANL pin V DC voltage at pin CANH and 0 < V < 5.5 V, less than one second +58 V CANH,Lmax CC CANL during load dump condition V Electrostatic discharge voltage IEC 6100042 at pins CANH and 15 +15 kV ESD CANL V Differential bus output voltage 45 < R < 65 1.5 3 V O(dif)(bus dom) LT in dominant state CMrange Input commonmode range for Guaranteed differential receiver thresh- 30 +35 V comparator old and leakage current I Supply current Dominant V = 0 V 72 mA CC TxD Recessive V = V 2.5 7.5 TxD CC I Supply current in silent mode 1.4 3.5 mA CCS t Propagation delay TxD to RxD See Figure 5 45 245 ns pd T Junction temperature 40 +150 C J Functional operation above the stresses listed in the Recommended Operating Ranges is not implied. Extended exposure to stresses beyond the Recommended Operating Ranges limits may affect device reliability. www.onsemi.com 2