© Semiconductor Components Industries, LLC, 2017
March, 2018 − Rev. 3
1Publication Order Number:
NCV7344/D
NCV7344
High Speed Low Power
CAN, CAN FD Transceiver
Description
The NCV7344 CAN transceiver is the interface between a
controller area network (CAN) protocol controller and the physical
bus. The transceiver provides differential transmit capability to the bus
and differential receive capability to the CAN controller.
The NCV7344 is an addition to the CAN high−speed transceiver
family complementing NCV734x CAN stand−alone transceivers and
previous generations such as AMIS42665, AMIS3066x, etc.
The NCV7344 guarantees additional timing parameters to ensure
robust communication at data rates beyond 1 Mbps to cope with CAN
flexible data rate requirements (CAN FD). These features make the
NCV7344 an excellent choice for all types of HS−CAN networks, in
nodes that require a low−power mode with wake−up capability via the
CAN bus.
Features
•Compatible with ISO 11898−2:2016
•Specification for Loop Delay Symmetry up to 5 Mbps
•VIO pin on NCV7344−3 Version Allowing Direct Interfacing with
3 V to 5 V Microcontrollers
•Very Low Current Standby Mode with Wake−up via the Bus
•Low Electromagnetic Emission (EME) and High Electromagnetic
Immunity
•Very Low EME without Common−mode (CM) Choke
•No Disturbance of the Bus Lines with an Un−powered Node
•Transmit Data (TxD) Dominant Timeout Function
•Under All Supply Conditions the Chip Behaves Predictably
•Very High ESD Robustness of Bus Pins, >8 kV System ESD Pulses
•Thermal Protection
•Bus Pins Short Circuit Proof to Supply Voltage and Ground
•Bus Pins Protected Against Transients in an Automotive
Environment
•These are Pb−free Devices
Quality
•Wettable Flank Package for Enhanced Optical Inspection
•NCV Prefix for Automotive and Other Applications Requiring
Unique Site and Control Change Requirements; AEC−Q100
Qualified and PPAP Capable
Typical Applications
•Automotive
•Industrial Networks
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See detailed ordering and shipping information on page 11 of
this data sheet.
ORDERING INFORMATION
PIN ASSIGNMENT
MARKING
DIAGRAM
SOIC−8
D1 SUFFIX
CASE 751AZ
NV7344xy= Specific Device Code
x = − or A
y = 0 or 3
− = long filter time
A = short filter time
A = Assembly Location
L = Wafer Lot
Y = Year
W = Work Week
G= Pb−Free Package
NV7344xy
ALYW G
G
1
NCV7344MWx
(Top View)
(Note: Microdot may be in either location)
1
DFN8
MW SUFFIX
CASE 507AB
NV7344xy
ALYWG
G
1
NCV7344D1x
(Top View)
STB
CANH
CANL
TxD
GND
RxD NC (−0)
VIO (−3)
VCC
TxD
GND
RxD
VCC
STB
CANH
CANL
NC (−0)
VIO (−3)
EP Flag
1
NCV7344
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BLOCK DIAGRAM
Mode &
Wake−up
control
Wake−up
Filter
NCV7344−0
STB
GND
RxD
VCC
2
3
7
6
COMP
COMP
Timer
TxD 1
Driver control
Thermal
shutdown
VCC
8
4
VCC
CANH
CANL
5
NC
Figure 1. NCV7344−0 Block Diagram
Mode &
Wake−up
control
Wake−up
Filter
NCV7344−3
STB
GND
RxD
VCC
2
3
7
6
COMP
COMP
Timer
TxD 1
Driver control
Thermal
shutdown
VIO
8
4
VIO
CANH
CANL
5
VIO
Figure 2. NCV7344−3 Block Diagram
NCV7344
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TYPICAL APPLICATION
VCC
Micro−
controller
NC
VBAT
GND
2
5
CANH
CANL
3
6
7
CAN
BUS
5V −reg
RLT =60W
RLT =60W
GND
STB
RxD
TxD 1
4
8
IN OUT
VCC
NCV7344
Figure 3. Application Diagram NCV7344−0
5V −reg
VCC
Micro−
controller
VIO
VBAT
GND
2
5
CANH
CANL
3
6
7
CAN
BUS
3V −reg
RLT =60W
RLT =60W
GND
STB
RxD
TxD 1
4
8
NCV7344−3
IN OUT
IN OUT
Figure 4. Application Diagram NCV7344−3
Table 1. PIN FUNCTION DESCRIPTION
Pin Name Description
1 TxD Transmit data input; low input Ù dominant driver; internal pull−up current
2 GND Ground
3 VCC Supply voltage
4 RxD Receive data output; dominant transmitter Ù low output
5
5
NC
VIO
Not connected. On NCV7344−0 only
Digital Input / Output pins and other functions supply voltage. On NCV7344−3 only
6 CANL Low−level CAN bus line (low in dominant mode)
7 CANH High−level CAN bus line (high in dominant mode)
8 STB Standby mode control input; internal pull−up current
EP Exposed Pad. Recommended to connect to GND or left floating in application (DFN8 package only).
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FUNCTIONAL DESCRIPTION
Operating Modes
NCV7344 provides two modes of operation as illustrated
in Table 2. These modes are selectable through pin STB.
Table 2. OPERATING MODES
Pin STB Mode Pin RxD
Low Normal Low when bus
dominant
High when bus
recessive
High Standby Follows the bus
when wake−up
detected
High when no
wake−up
request detected
Normal Mode
In the normal mode, the transceiver is able to
communicate via the bus lines. The signals are transmitted
and received to the CAN controller via the pins TxD and
RxD. The slopes on the bus lines outputs are optimized to
give low EME.
Standby Mode
In standby mode both the transmitter and receiver are
disabled and a very low−power differential receiver
monitors the bus lines for CAN bus activity. The bus lines
are biased to ground and supply current is reduced to a
minimum, typically 10 mA. When a wake−up request is
detected by the low−power differential receiver, the signal
is first filtered and then verified as a valid wake signal after
a time period of twake_filt, the RxD pin is driven low by the
transceiver (following the bus) to inform the controller of
the wake−up request.
Wake−up
When a valid wake−up pattern (phase in order
dominant – recessive – dominant) is detected during the
standby mode the RxD pin follows the bus. Minimum length
of each phase is twake_filt – see Figure 5.
Pattern must be received within twake_to to be recognized
as valid wake−up otherwise internal logic is reset.
CANH
CANL
RxD
twake_filt twake_filt
<t
wake_to
twake_filt
Figure 5. NCV7344 Wake−up Behavior
tdwakerd tdwakedr
Overtemperature Detection
A thermal protection circuit protects the IC from damage
by switching off the transmitter if the junction temperature
exceeds a value of approximately 180°C. Because the
transmitter dissipates most of the power, the power
dissipation and temperature of the IC is reduced. All other
IC functions continue to operate. The transmitter off−state
resets when the temperature decreases below the shutdown
threshold and pin TxD goes high. The thermal protection
circuit is particularly needed when a bus line short circuits.
TxD Dominant Timeout Function
A TxD dominant timeout timer circuit prevents the bus
lines being driven to a permanent dominant state (blocking
all network communication) if pin TxD is forced
permanently low by a hardware and/or software application
failure. The timer is triggered by a negative edge on pin TxD.
If the duration of the low−level on pin TxD exceeds the
internal timer value tdom(TxD), the transmitter is disabled,
driving the bus into a recessive state. The timer is reset by a
positive edge on pin TxD.
This TxD dominant timeout time tdom(TxD) defines
the minimum possible bit rate to 17 kbps.
Fail Safe Features
A current−limiting circuit protects the transmitter output
stage from damage caused by accidental short circuit
to either positive or negative supply voltage, although
power dissipation increases during this fault condition.
Standby undervoltage on VCC pin prevents the chip
sending data on the bus when there is not enough VCC
supply voltage by entering standby mode. Undervoltage
detection on VIO pin (NCV7344−3 version only) also
causes transition to standby mode. Switch−off undervoltage
detection level on supply pin(s) forces transceiver to
disengage from the bus until the supply is recovered. After
supply is recovered TxD pin must be first released to high to
allow sending dominant bits again. Recovery time from
undervoltage detection is equal to td(stb−nm) time.
The pins CANH and CANL are protected from
automotive electrical transients (according to ISO 7637; see
Figure 7). Pins TxD and STB are pulled high internally
should the input become disconnected. Pins TxD, STB and
RxD will be floating, preventing reverse supply should the
VCC supply be removed.
VIO Supply Pin
The VIO pin (available only on NCV7344−3 version)
should be connected to microcontroller supply pin. By using
VIO supply pin shared with microcontroller the I/O levels
between microcontroller and transceiver are properly
adjusted. See Figure 4. Pin VIO also provides the internal
supply voltage for low−power differential receiver of the
transceiver. This allows detection of wake−up request even
when there is no supply voltage on pin VCC.
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ELECTRICAL CHARACTERISTICS
Definitions
All voltages are referenced to GND (pin 2). Positive
currents flow into the IC. Sinking current means the current
is flowing into the pin; sourcing current means the current
is flowing out of the pin.
ABSOLUTE MAXIMUM RATINGS
Table 3. ABSOLUTE MAXIMUM RATINGS
Symbol Parameter Conditions Min Max Unit
VSUP Supply voltage VCC, VIO −0.3 +6 V
VCANH DC voltage at pin CANH 0 < VCC < 5.25 V; no time limit −42 +42 V
VCANL DC voltage at pin CANL 0 < VCC < 5.25 V; no time limit −42 +42 V
VCANH−CANL DC voltage between CANH and CANL −42 +42 V
VI/O DC voltage at pin TxD, RxD, STB −0.3 +6 V
VesdHBM Electrostatic discharge voltage at all pins,
Component HBM
(Note 1) −8 +8 kV
VesdCDM Electrostatic discharge voltage at all pins,
Component CDM
(Note 2) −750 +750 V
VesdIEC Electrostatic discharge voltage at pins CANH and
CANL, System HBM (Note 4)
(Note 3) −8 +8 kV
Vschaff Voltage transients, pins CANH, CANL. According
to ISO7637−3, Class C (Note 4)
test pulses 1 −100 V
test pulses 2a +75 V
test pulses 3a −150 V
test pulses 3b +100 V
Latch−up Static latch−up at all pins (Note 5) 150 mA
Tstg Storage temperature −55 +150 °C
TJMaximum junction temperature −40 +170 °C
Stresses exceeding those listed in the Maximum Ratings table may damage the device. If any of these limits are exceeded, device functionality
should not be assumed, damage may occur and reliability may be affected.
1. Standardized human body model electrostatic discharge (ESD) pulses in accordance to EIA−JESD22. Equivalent to discharging a 100 pF
capacitor through a 1.5 kW resistor.
2. Standardized charged device model ESD pulses when tested according to AEC−Q100−011
3. System human body model electrostatic discharge (ESD) pulses in accordance to IEC 61000−4−2. Equivalent to discharging a 150 pF
capacitor through a 330 W resistor referenced to GND.
4. Results were verified by external test house.
5. Static latch−up immunity: Static latch−up protection level when tested according to EIA/JESD78.
Table 4. THERMAL CHARACTERISTICS
Parameter Symbol Value Unit
Thermal characteristics, SOIC−8 (Note 6)
Thermal Resistance Junction−to−Air, Free air, 1S0P PCB (Note 7)
Thermal Resistance Junction−to−Air, Free air, 2S2P PCB (Note 8)
RqJA
RqJA
131
81
°C/W
°C/W
Thermal characteristics, DFN8 (Note 6)
Thermal Resistance Junction−to−Air, Free air, 1S0P PCB (Note 7)
Thermal Resistance Junction−to−Air, Free air, 2S2P PCB (Note 8)
RqJA
RqJA
125
58
°C/W
°C/W
6. Refer to ELECTRICAL CHARACTERISTICS, RECOMMENDED OPERATING RANGES and/or APPLICATION INFORMATION for Safe
Operating parameters.
7. Values based on test board according to EIA/JEDEC Standard JESD51−3, signal layer with 10% trace coverage.
8. Values based on test board according to EIA/JEDEC Standard JESD51−7, signal layers with 10% trace coverage.
NCV7344
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ELECTRICAL CHARACTERISTICS
Table 5. ELECTRICAL CHARACTERISTICS VCC = 4.75 V to 5.25 V; VIO = 2.8 to 5.25 V; TJ = −40 to +150°C; RLT = 60 W,
CLT = 100 pF, C1 not used, CRxD = 15 pF unless specified otherwise.
Symbol Parameter Conditions Min Typ Max Unit
SUPPLY (Pin VCC)
VCC Power supply voltage (Note 9) 4.75 5 5.25 V
ICC Supply current Dominant; VTxD = Low 20 45 70 mA
Recessive; VTxD = High 1.9 5 10 mA
ICCS Supply current in standby mode TJ ≤ 100°C, (Note 10) −10 15 mA
VUVD(VCC)(stby) Standby undervoltage detection VCC pin 3.5 4 4.3 V
VUVD(VCC)(swoff) Switch−off undervoltage detection VCC pin 2.0 2.3 2.6 V
VIO SUPPLY VOLTAGE (Pin VIO) Only for NCV7344−3 version
VIO Supply voltage on pin VIO 2.8 −5.5 V
IIOS Supply current on pin VIO in standby mode TJ ≤ 100°C, (Note 10) − − 11 mA
ICCS Supply current on pin VCC in standby
mode
TJ ≤ 100°C, (Note 10) −0 4.0 mA
IIONM Supply current on pin VIO during normal
mode
Dominant; VTxD = Low 0.45 0.65 0.9 mA
Recessive; VTxD = High 0.32 0.43 0.58
VUVDVIO Undervoltage detection voltage on VIO pin 2.0 2.3 2.6 V
TRANSMITTER DATA INPUT (Pin TxD)
VIH High−level input voltage Output recessive 2.0 − − V
VIL Low−level input voltage Output dominant − − 0.8 V
IIH High−level input current VTxD = VCC/VIO −5 0 +5 mA
IIL Low−level input current VTxD = 0 V −300 −150 −75 mA
CiInput capacitance (Note 10) −5 10 pF
TRANSMITTER MODE SELECT (Pin STB)
VIH High−level input voltage Standby mode 2.0 − − V
VIL Low−level input voltage Normal mode − − 0.8 V
IIH High−level input current VSTB = VCC/VIO −1 0 +1 mA
IIL Low−level input current VSTB = 0 V −15 − −1mA
CiInput capacitance (Note 10) −5 10 pF
RECEIVER DATA OUTPUT (Pin RxD)
IOH High−level output current Normal mode
VRxD = VCC/VIO – 0.4 V
−8−3−1 mA
IOL Low−level output current VRxD = 0.4 V 1 6 12 mA
BUS LINES (Pins CANH and CANL)
Io(rec) Recessive output current at pins CANH
and CANL
−27 V < VCANH, VCANL < +32 V;
Normal mode
−5−+5 mA
ILI Input leakage current 0 W < R(VCC to GND) < 1 MW
VCANL = VCANH = 5 V
−5 0 +5 mA
Vo(rec)(CANH) Recessive output voltage at pin CANH Normal mode, VTxD = High;
RLT and CLT not used
2.0 2.5 3.0 V
Vo(rec)(CANL) Recessive output voltage at pin CANL Normal mode, VTxD = High;
RLT and CLT not used
2.0 2.5 3.0 V
Vo(off)(CANH) Recessive output voltage at pin CANH Standby mode;
RLT and CLT not used
−0.1 0 0.1 V
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Table 5. ELECTRICAL CHARACTERISTICS VCC = 4.75 V to 5.25 V; VIO = 2.8 to 5.25 V; TJ = −40 to +150°C; RLT = 60 W,
CLT = 100 pF, C1 not used, CRxD = 15 pF unless specified otherwise.
Symbol UnitMaxTypMinConditionsParameter
BUS LINES (Pins CANH and CANL)
Vo(off)(CANL) Recessive output voltage at pin CANL Standby mode;
RLT and CLT not used
−0.1 0 0.1 V
Vo(off)(diff) Differential bus output voltage
(VCANH − VCANL)
Standby mode;
RLT and CLT not used
−0.2 0 0.2 V
Vo(dom)(CANH) Dominant output voltage at pin CANH VTxD = 0 V; t < tdom(TxD);
50 W < RLT < 65 W
2.75 3.5 4.5 V
Vo(dom)(CANL) Dominant output voltage at pin CANL VTxD = 0 V; t < tdom(TxD);
50 W < RLT < 65 W
0.5 1.5 2.25 V
Vo(dom)(diff) Differential bus output voltage
(VCANH − VCANL)
VTxD = 0 V; dominant;
45 W < RLT < 65 W
1.5 2.25 3.0 V
Vo(dom)(diff)_arb Differential bus output voltage during
arbitration (VCANH − VCANL)
RLT = 2.24 kW (Note 10) 1.5 −5.0 V
Vo(rec)(diff) Differential bus output voltage
(VCANH − VCANL)
VTxD = High; recessive; no load −50 0 +50 mV
Vo(dom)(sym) Dominant output voltage driver symmetry
(VCANH + VCANL)
RLT = 60 W; C1 = 4.7 nF;
TxD = square wave up to 1 MHz
0.9 1.0 1.1 VCC
Io(sc)(CANH) Short circuit output current at pin CANH −3 V < VCANH < +18 V −100 −70 1.5 mA
Io(sc)(CANL) Short circuit output current at pin CANL −3 V < VCANL < +36 V −1.5 70 100 mA
Vi(rec)(diff)_NM Differential input voltage range
recessive state
Normal or Silent mode;
−12 V ≤ VCANH,
VCANL ≤ +12 V; no load
−3.0 −0.5 V
Vi(rec)(diff)_LP Standby or Sleep mode;
−12 V ≤ VCANH,
VCANL ≤ +12 V; no load
−3.0 0.4 V
Vi(dom)(diff)_NM Differential input voltage range
dominant state
Normal or Silent mode;
−12 V ≤ VCANH,
VCANL ≤ +12 V; no load
0.9 − 8.0 V
Vi(dom)(diff)_LP Standby or Sleep mode;
−12 V ≤ VCANH,
VCANL ≤ +12 V; no load
1.05 8.0 V
Vi(diff)(th)_NORM Differential receiver threshold voltage in
normal mode
−12 V ≤ VCANL ≤ +12 V;
−12 V ≤ VCANH ≤ +12 V
0.5 −0.9 V
Vi(diff)(th)_NORM_H Differential receiver threshold voltage in
normal mode, extended range
−30 V < VCANL < +35 V;
−30 V < VCANH < +35 V
0.4 −1.0 V
Vi(diff)(th)_STDBY Differential receiver threshold voltage in
standby mode
−12 V ≤ VCANL ≤ +12 V;
−12 V ≤ VCANH ≤ +12 V
0.4 −1.05 V
Ri(cm)(CANH) Common−mode input resistance at pin
CANH
−2 V ≤ VCANH ≤ +7 V;
−2 V ≤ VCANL ≤ +7 V
15 26 37 kW
Ri(cm)(CANL) Common−mode input resistance at pin
CANL
−2 V ≤ VCANH ≤ +7 V;
−2 V ≤ VCANL ≤ +7 V
15 26 37 kW
Ri(cm)(m) Matching between pin CANH and pin
CANL common mode input resistance
VCANH = VCANL = +5 V −1 0 +1 %
Ri(diff) Differential input resistance −2 V ≤ VCANH ≤ +7 V;
−2 V ≤ VCANL ≤ +7 V
25 50 75 kW
Ci(CANH) Input capacitance at pin CANH VTxD = High; (Note 10) −7.5 20 pF
Ci(CANL) Input capacitance at pin CANL VTxD = High; (Note 10) −7.5 20 pF
Ci(diff) Differential input capacitance VTxD = High; (Note 10) −3.75 10 pF
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Table 5. ELECTRICAL CHARACTERISTICS VCC = 4.75 V to 5.25 V; VIO = 2.8 to 5.25 V; TJ = −40 to +150°C; RLT = 60 W,
CLT = 100 pF, C1 not used, CRxD = 15 pF unless specified otherwise.
Symbol UnitMaxTypMinConditionsParameter
TIMING CHARACTERISTICS (see Figures 6 and 8)
td(TxD−BUSon) Delay TxD to bus active −75 −ns
td(TxD−BUSoff) Delay TxD to bus inactive −85 −ns
td(BUSon−RxD) Delay bus active to RxD −24 −ns
td(BUSoff−RxD) Delay bus inactive to RxD −32 −ns
tpd_dr Propagation delay TxD to RxD dominant to
recessive transition
50 100 210 ns
tpd_rd Propagation delay TxD to RxD recessive
to dominant transition
50 120 210 ns
td(stb−nm) Delay standby mode to normal mode 511 20 ms
twake_filt Filter time for wake−up via bus NCV7344 version 0.5 −5ms
NCV7344A version 0.15 −1.8 ms
tdwakerd Delay to flag wake event
(recessive to dominant transitions)
Valid bus wake−up event 0.5 2.6 6 ms
tdwakedr Delay to flag wake event
(dominant to recessive transitions)
Valid bus wake−up event 0.5 2.6 6 ms
twake_to Bus time for wake−up timeout Standby mode 1−10 ms
tdom(TxD) TxD dominant time for timeout VTxD = Low; Normal mode 1−10 ms
tBit(RxD) Bit time on RxD pin tBit(TxD) = 500 ns 400 −550 ns
tBit(TxD) = 200 ns 120 −220 ns
tBit(Vi(diff)) Bit time on bus (CANH – CANL pin) tBit(TxD) = 500 ns 435 −530 ns
tBit(TxD) = 200 ns 155 −210 ns
DtRec Receiver timing symmetry
DtRec = tBit(RxD) − tBit(Vi(diff))
tBit(TxD) = 500 ns −65 −+40 ns
tBit(TxD) = 200 ns −45 −+15 ns
THERMAL SHUTDOWN
TJ(sd) Shutdown junction temperature Junction temperature rising 160 180 200 °C
9. In the range between VUVD(VCC)(stby) and 4.75 V and from 5.25 V to 6 V the chip is fully functional; some parameters may be outside of
the specification.
10.Values based on design and characterization, not tested in production
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MEASUREMENT SETUPS AND DEFINITIONS
TxD
0.3·VCC *0.3·VCC *
0.7·VCC *
5·tbit(TxD) tbit(TxD)
0.3·VCC *
tbit(RxD)
RxD
500mV
tbit(Vi(diff))
tpd_dr
tpd_rd
900mV
Vi(diff)=V
CANH −VCANL
td(TxD−BUSon)
td(TxD−BUSoff)
0.7·VCC *
td(BUSon−RxD)
Figure 6. Transceiver Timing Diagram
*On NCV7344−3 VCC is replaced by VIO
Edge length below 10 ns
NCV7344
VCC
GND
2
3CANH
CANL
6
7
STB
8
RxD 4
TxD 1
100nF
+5 V
15pF
1nF
1nF
Transient
Generator
VIO
5
Figure 7. Test Circuit for Automotive Transients
Figure 8. Test Circuit for Timing Characteristics
VCC
GND
2
3CANH
CANL
5
6
7
RLT/2
CLT
STB
8
RxD 4
TxD 1
2x 30 W
100 pF
100 nF
+5 V
15 pF
NCV7344
VIO
RLT/2
C1
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Table 6. ISO 11898−2:2016 Parameter Cross−Reference Table
ISO 11898−2:2016 Specification NCV7344
Datasheet
Parameter Notation Symbol
Dominant output characteristics
Single ended voltage on CAN_H VCAN_H Vo(dom)(CANH)
Single ended voltage on CAN_L VCAN_L Vo(dom)(CANL)
Differential voltage on normal bus load VDiff Vo(dom)(diff)
Differential voltage on effective resistance during arbitration VDiff Vo(dom)(diff)_arb
Differential voltage on extended bus load range (optional) VDiff Vo(dom)(diff)
Driver symmetry
Driver symmetry VSYM Vo(dom)(sym)
Driver output current
Absolute current on CAN_H ICAN_H Io(SC)(CANH)
Absolute current on CAN_L ICAN_L Io(SC)(CANL)
Receiver output characteristics, bus biasing active
Single ended output voltage on CAN_H VCAN_H Vo(rec)(CANH)
Single ended output voltage on CAN_L VCAN_L Vo(rec)(CANL)
Differential output voltage VDiff Vo(rec)(diff)
Receiver output characteristics, bus biasing inactive
Single ended output voltage on CAN_H VCAN_H Vo(off)(CANH)
Single ended output voltage on CAN_L VCAN_L Vo(off)(CANL)
Differential output voltage VDiff Vo(off)(diff)
Optional transmit dominant timeout
Transmit dominant timeout, long tdom tdom(TxD)
Transmit dominant timeout, short tdom NA
Static receiver input characteristics, bus biasing active
Recessive state differential input voltage range VDiff Vi(rec)(diff)_NM
Dominant state differential input voltage range VDiff Vi(dom)(diff)_NM
Static receiver input characteristics, bus biasing inactive
Recessive state differential input voltage range VDiff Vi(rec)(diff)_LP
Dominant state differential input voltage range VDiff Vi(dom)(diff)_LP
Receiver input resistance
Differential internal resistance RDiff Ri(diff)
Single ended internal resistance RCAN_H
RCAN_L
Ri(cm)(CANH)
Ri(cm)(CANL)
Receiver input resistance matching
Matching a of internal resistance mRRi(cm)(m)
Implementation loop delay requirement
Loop delay tLoop tpd_rd
tpd_dr
Optional implementation data signal timing requirements for use with bit rates above 1 Mbit/s and up to 2 Mbit/s
Transmitted recessive bit width @ 2 Mbit/s tBit(Bus) tBit(Vi(diff))
Received recessive bit width @ 2 Mbit/s tBit(RXD) tBit(RxD)
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Table 6. ISO 11898−2:2016 Parameter Cross−Reference Table
Parameter SymbolNotation
Receiver timing symmetry @ 2 Mbit/s DtRec DtRec
Optional implementation data signal timing requirements for use with bit rates above 2 Mbit/s and up to 5 Mbit/s
Transmitted recessive bit width @ 5 Mbit/s tBit(Bus) tBit(Vi(diff))
Transmitted recessive bit width @ 5 Mbit/s tBit(RXD) tBit(RxD)
Received recessive bit width @ 5 Mbit/s DtRec DtRec
Maximum ratings of VCAN_H, VCAN_L and VDiff
Maximum rating VDiff VDiff VCANH−CANL
General maximum rating VCAN_H and VCAN_L VCAN_H
VCAN_L
VCANH
VCANL
Optional: Extended maximum rating VCAN_H and VCAN_L VCAN_H
VCAN_L
NA
Maximum leakage currents on CAN_H and CAN_L, unpowered
Leakage current on CAN_H, CAN_L ICAN_H
ICAN_L
ILI
Bus biasing control timings
CAN activity filter time, long tFilter twake_filt
CAN activity filter time, short tFilter twake_filt
Wake−up timeout, short tWake NA
Wake−up timeout, long tWake twake_to
Timeout for bus inactivity (Required for selective wake−up implementation only) tSilence NA
Bus Bias reaction time (Required for selective wake−up implementation only) tBias NA
DEVICE ORDERING INFORMATION (High Speed Low Power CAN, CANFD Transceiver)
Part Number Long FT Short FT Vio NC
Temperature
Range Package Shipping†
NCV7344D10R2G X X
−40°C to +150°C
SOIC 150 8 GREEN (Matte
Sn, JEDEC MS−012)
(Pb−Free)
3000 / Tape &
Reel
NCV7344D13R2G X X
NCV7344AD10R2G X X
NCV7344AD13R2G X X
NCV7344MW0R2G X X
DFN 8
Wettable Flank
(Pb−Free)
NCV7344MW3R2G X X
NCV7344AMW0R2G X X
NCV7344AMW3R2G X X
†For information on tape and reel specifications, including part orientation and tape sizes, please refer to our Tape and Reel Packaging
Specifications Brochure, BRD8011/D.
NCV7344
www.onsemi.com
12
PACKAGE DIMENSIONS
SOIC−8
CASE 751AZ
ISSUE B
7.00
8X
0.76
8X
1.52
1.27
DIMENSIONS: MILLIMETERS
1
PITCH
*For additional information on our Pb−Free strategy and soldering
details, please download the ON Semiconductor Soldering and
Mounting Techniques Reference Manual, SOLDERRM/D.
SOLDERING FOOTPRINT*
RECOMMENDED
NOTES:
1. DIMENSIONING AND TOLERANCING PER ASME Y14.5M, 1994.
2. CONTROLLING DIMENSION: MILLIMETERS.
3. DIMENSION b DOES NOT INCLUDE DAMBAR PROTRUSION.
ALLOWABLE PROTRUSION SHALL BE 0.004 mm IN EXCESS OF
MAXIMUM MATERIAL CONDITION.
4. DIMENSION D DOES NOT INCLUDE MOLD FLASH, PROTRUSIONS
OR GATE BURRS. MOLD FLASH, PROTRUSIONS OR GATE BURRS
SHALL NOT EXCEED 0.006 mm PER SIDE. DIMENSION E1 DOES
NOT INCLUDE INTERLEAD FLASH OR PROTRUSION. INTERLEAD
FLASH OR PROTRUSION SHALL NOT EXCEED 0.010 mm PER SIDE.
5. THE PACKAGE TOP MAY BE SMALLER THAN THE PACKAGE BOT
TOM. DIMENSIONS D AND E1 ARE DETERMINED AT THE OUTER
MOST EXTREMES OF THE PLASTIC BODY AT DATUM H.
6. DIMENSIONS A AND B ARE TO BE DETERMINED AT DATUM H.
7. DIMENSIONS b AND c APPLY TO THE FLAT SECTION OF THE LEAD
BETWEEN 0.10 TO 0.25 FROM THE LEAD TIP.
8. A1 IS DEFINED AS THE VERTICAL DISTANCE FROM THE SEATING
PLANE TO THE LOWEST POINT ON THE PACKAGE BODY.
14
85
SEATING
PLANE
DETAIL A
0.10 C
A1
DIM MIN MAX
MILLIMETERS
h0.25 0.41
A--- 1.75
b0.31 0.51
L0.40 1.27
e1.27 BSC
c0.10 0.25
A1 0.10 0.25
L2
M
0.25 A-B
b8X
CD
A
B
C
TOP VIEW
SIDE VIEW
0.25 BSC
E1 3.90 BSC
E6.00 BSC
D
e
D
0.20 C
0.10 C
2X
NOTE 6
NOTES 4&5
NOTES 4&5
SIDE VIEW
END VIEW
E E1
D
0.10 C D
D
NOTES 3&7
NOTE 6
NOTE 8
A
A2
A2 1.25 ---
D4.90 BSC
H
SEATING
PLANE
DETAIL A
LC
L2
h
45 CHAMFER5
c
NOTE 7
NCV7344
www.onsemi.com
13
PACKAGE DIMENSIONS
DFNW8 3x3, 0.65P
CASE 507AB
ISSUE C
NOTES:
1. DIMENSIONING AND TOLERANCING PER
ASME Y14.5M, 1994.
2. CONTROLLING DIMENSION: MILLIMETERS.
3. DIMENSION b APPLIES TO PLATED TERMINAL
AND IS MEASURED BETWEEN 0.10 AND
0.20mm FROM THE TERMINAL TIP.
4. COPLANARITY APPLIES TO THE EXPOSED
PAD AS WELL AS THE TERMINALS.
5. THIS DEVICE CONTAINS WETTABLE FLANK
DESIGN FEATURES TO AID IN FILLET FORMA-
TION ON THE LEADS DURING MOUNTING.
ÉÉÉ
ÉÉÉ
ÉÉÉ
A
B
E
D
D2
E2
BOTTOM VIEW
b
e
8X
0.10 B
0.05
AC
CNOTE 3
PIN ONE
REFERENCE
TOP VIEW
A
A3
0.05 C
0.05 C
CSEATING
PLANE
SIDE VIEW
L
8X
14
58
*For additional information on our Pb−Free strategy and soldering
details, please download the ON Semiconductor Soldering and
Mounting Techniques Reference Manual, SOLDERRM/D.
RECOMMENDED
DETAIL B
DETAIL A
NOTE 4
e/2
SOLDERING FOOTPRINT*
DIM MIN NOM
MILLIMETERS
A0.80 0.85
A1 −−− −−−
b0.25 0.30
D
D2 2.30 2.40
E
E2 1.50 1.60
e0.65 BSC
L0.35 0.40
A3 0.20 REF
2.95 3.00
K
A4
L3
MAX
2.95 3.00
0.90
0.05
0.35
2.50
1.70
0.45
3.05
3.05
0.00 0.05 0.10
ALTERNATE
CONSTRUCTION
DETAIL A
L3
SECTION C−C
PLATED
A4
SURFACES
L3
L3
L
DETAIL B
PLATING
EXPOSED
COPPER
A4
A1
L
C
C
PACKAGE
OUTLINE
14
85
8X
0.75
2.55
1.76
0.33
0.65
PITCH
3.30
8X
DIMENSIONS: MILLIMETERS
2.28
K
0.30 REF
0.13 REF
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NCV7344/D
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