ONSEMI NCV7361AD

NCV7361A
Voltage Regulator with
Integrated LIN Transceiver
The NCV7361A consists of a low drop voltage regulator,
5.0 V/50 mA and a LIN bus transceiver. The LIN transceiver is
suitable for LIN bus systems compatible to
“LIN−Protocol Specification” Rev. 1.3, 2.0 and SAE J2602.
The combination of voltage regulator and bus transceiver make it
ideal for a powerful and inexpensive cost effective slave node in a
LIN Bus system.
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MARKING
DIAGRAM
Features
• Operating Voltage VSUP = 5.5 to 18 V
• Very Low Standby Current Consumption < 110 A in Normal Mode
•
•
•
•
•
•
•
•
(< 50 A in Sleep Mode)
LIN−Bus Transceiver:
♦ PNP−Bipolar Transistor Driver
♦ Slew Rate Control and Wave Shaping for Best EMC Behavior
♦ BUS Input Voltage −24 V to 30 V (Independent of VSUP)
♦ Wake−Up Via LIN Bus
♦ Baud Rate up to 20 kBaud
♦ Compatible to LIN Specification 1.3, 2.0 and SAE J2602
♦ Compatible to ISO9141 Functions
Wake−Up by LIN BUS and Startup Capable Independent of EN
Voltage Level
Linear Low Drop Voltage Regulator:
♦ Output Voltage 5.0 V 2%
♦ Output Current Max. 50 mA
♦ Output Current Limit
♦ Overtemperature Shutdown
Reset Time 100 ms and Reset Threshold Voltage 4.65 V
CMOS Compatible Interface to Microcontroller
Load Dump Protected (40 V Peak)
Resistant Against Transient Pulses According to ISO 7637 at
Pin VSUP, BUS and EN
NCV Prefix for Automotive and Other Applications Requiring Site
and Change Control
 Semiconductor Components Industries, LLC, 2005
March, 2005 − Rev. 0
1
8
SO−8
D SUFFIX
CASE 751
8
1
7361A
ALYW
1
A
L
Y
W
= Assembly Location
= Wafer Lot
= Year
= Work Week
PIN CONNECTIONS
VSUP 1
8
VOUT
EN 2
7
RESET
GND 3
6
TxD
BUS
5
RxD
4
(Top View)
ORDERING INFORMATION
Device
Package
Shipping†
NCV7361AD
SO−8
98 Units / Rail
NCV7361ADR2
SO−8
2500 / Tape & Reel
†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.
Publication Order Number:
NCV7361A/D
NCV7361A
VSUP
VOUT
Control
Amplifier
Aux.
Supply
Current
Limitation
+
Bandgap
VBG
MR
Reset
Generator
−
IVAUX
POR
Adjustment
UVR
4.65 V
VSUP
VOUT
RESET
EN
Mode
Control
Wake−Up
Control
Reset
Timer
Wake−
Filter
OSC
GND
Thermal
Protection
TSHD
VSUP
VOUT
Rec−Filter
RxD
Receiver
30 k
VOUT
Slew Rate
Control
BUS
TSHD
Driver
Control
Filter
MR
MR = Master Reset
TSHD = Thermal Shutdown
VBG = Bandgap Voltage
Figure 1. Block Diagram
PACKAGE PIN DESCRIPTION
Pin
Symbol
1
VSUP
Description
2
EN
3
GND
Ground
4
BUS
LIN bus line.
5
RxD
Receive output (push−pull to VOUT).
6
TxD
Transmit input (pullup−input to VOUT).
7
RESET
8
VOUT
Supply voltage.
Enable input controls the regulator. Active high.
Reset output, active low (pullup to VOUT).
Regulator output 5.0 V/50 mA.
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2
TxD
NCV7361A
ELECTRICAL SPECIFICATIONS
All voltages are referenced to ground (GND). Positive
currents flow into the IC.
The maximum ratings (in accordance with IEC 134)
given in the table below are limiting values that do not lead
to a permanent damage of the device but exceeding any of
these limits may do so. Long term exposure to limiting
values may affect the reliability of the device. Correct
operating of the device can’t be guaranteed if any of these
limits are exceeded.
OPERATING CONDITIONS
Characteristic
Supply Voltage
Symbol
Min
Max
Unit
VSUP
5.25
18
V
Operating Ambient Temperature
TA
−40
+125
°C
Junction Temperature
TJ
−
+150
°C
MAXIMUM RATINGS
Rating
Symbol
Condition
Min
Max
Unit
VSUP
−
−1.0
30
V
T 500 ms
−
40
−
−24
30
T 500 ms
−
40
VSUP−VOUT
−
−0.3
40
V
VINEN
−
−0.3
VSUP +
0.3
V
TxD, RxD, RESET
VIN
−
−0.3
VOUT +
0.3
V
EN, TxD, RxD, RESET
IIN
−
−25
25
mA
IINSH
−
−500
500
mA
ESDBUSHB
Human Body Model, 100 pF via 1.5 k
−1.0
1.0
kV
ESDHB
Human Body Model, 100 pF via 1.5 k
−2.0
2.0
kV
Junction Temperature
TJ
−
−
150
°C
Storage Temperature
TSTG
−
−55
150
°C
Tsld
60 second maximum above 183°C
−5°C/+0°C allowable conditions
−
240 peak
°C
VSUP
BUS
VBUS
Difference VSUP−VOUT
EN
Short Circuit of Pin VSUP and VOUT
ESD Capability TxD Pin
ESD Capability on All Other Pins
Lead Temperature Soldering
Reflow: (SMD styles only)
V
Maximum ratings are those values beyond which device damage can occur. Maximum ratings applied to the device are individual stress limit values
(not normal operating conditions) and are not valid simultaneously. If these limits are exceeded, device functional operation is not implied, damage
may occur and reliability may be affected.
THERMAL RATINGS
Parameter
SO−8 Package
Test Conditions Typical Value
Units
Min−Pad Board (Note 1)
1.0 in Pad Board (Note 2)
Junction−to−Tab (psi−JL2, JL2) (Note 3)
48
43
°C/W
Junction−to−Ambient (RJA, JA)
183
120
°C/W
1. 1 oz copper, 54 mm2 copper area, 0.062” thick FR4.
2. 1 oz copper, 714 mm2 copper area, 0.062” thick FR4.
3. psi−JL2 temperature was made at foot of lead #2.
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NCV7361A
ELECTRICAL CHARACTERISTICS (5.25 V VSUP 18 V, −40°C TA 125°C unless otherwise noted)
Characteristic
Symbol
Condition
Min
Typ
Max
Unit
ISnl
VEN = VSUP = 12 V, VBUS >
VSUP − 0.5 V, Pins 5 to 8 Open
−
−
110
A
Supply Current, “Sleep Mode’’
ISsleep
VSUP = 12 V, VEN = 0 V, VBUS >
VSUP − 0.5 V
−
35
50
A
Thermal Shutdown (Note 5)
TJSHD
−
155
−
175
°C
Thermal Recovery (Note 5)
TJrec
−
126
−
130
°C
VSUP Undervoltage Reset “OFF”
VSUVR_OFF
VSUP Ramp Up
−
3.5
3.9
V
VSUP Undervoltage Reset “ON”
VSUVR_ON
VSUP Ramp Down
−
3.0
3.3
V
VSUP Undervoltage Hysteresis
VSUVR_HYS
VSUVR_OFF − VSUVR_ON
0.2
−
−
V
5.25
12
18
V
VSUP
Supply Current with VOUT
“No Load’’ (Note 4)
Operating Voltage
VSUP
VOUT
VOUTt
5.5 V VSUP 18 V
0 < IOUT < 50 mA
4.90
5.0
5.10
V
VOUTh
VSUP > 18 V
4.90
5.0
5.25
V
VOUTl
IVOUT = 20 mA, VSUP = 3.3 V
−
VSUP−VD
−
V
IVOUT = 50 mA, VSUP = 3.3 V
−
VSUP−VD
−
V
VD
IVOUT = 20 mA
−
−
150
mV
IVOUT = 50 mA
−
−
500
mV
Output Current
IVOUT
3.0 V < VSUP < 18 V
VOUT = 0 V
50
−
150
mA
Load Capacity
Cload
Reference Figure 35
4.7
−
−
F
Input Voltage Low
VENL
−
−0.3
−
1.6
V
Input Voltage High
VENH
−
2.5
−
VSUP
+0.3
V
Hysteresis (Note 5)
VENHYS
−
100
−
−
mV
IpdEN
VEN > VENH
1.0
4.0
7.0
A
VEN < VENL
70
100
130
A
IOUT = 1.0 mA, VSUP > 5.5 V
−
−
0.8
V
10 k RESET to VOUT
VSUP = VOUT = 0.8 V
−
−
0.2
V
Output Voltage
Drop−Out Voltage (Note 6)
VD = VSUP−V
VOUT
ENABLE (EN)
Pulldown Current
RESET
Output Voltage Low
VOL
Ipu
−
−500
−375
−250
A
RESET Threshold
VRES
Referred to VOUT, VSUP > 4.6 V
4.5
4.65
4.8
V
Master Reset Threshold (Note 5)
VMRes
−
3.0
3.15
3.3
V
Pullup Current
4. See Figure 6 for test setup.
5. Not production tested, guaranteed by design and qualification.
6. Measured when the output voltage has dropped 100 mV from the VSUP = 12 V nominal value.
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4
NCV7361A
ELECTRICAL CHARACTERISTICS (5.25 V VSUP 18 V, −40°C TA 125°C unless otherwise noted)
Characteristic
Symbol
Condition
Min
Typ
Max
Unit
0.4 *VSUP
−
0.6
*VSUP
V
0.475
*VSUP
0.5
*VSUP
0.525
*VSUP
0.12 *VSUP
0.135
*VSUP
0.15
*VSUP
LIN BUS INTERFACE
Receive Threshold
Vthr_rec,
Vthr_dom
Receive Center Point
Vthr_cnt = (Vthr_rec + Vthr_dom)/2
Vthr_cnt
Receive Hysteresis
Vthr_hys = Vthr_rec − Vthr_dom
Vthr_hys
BUS Input Current (Recessive)
(Note 7)
IINBUSR
8.0 VBUS 18 V,
VSUP = VBUS − 0.7 V, TxD = 4.5 V
−
−
20
A
BUS Input Current (Recessive)
−IINBUSR
VSUP = 0 V, VBUS = −12 V
−1.0
−
−
mA
BUS Input Current (Recessive)
−IINBUSR
VSUP = Open, VBUS = −18 V
−1.0
−
−
mA
RBUSpu
−
20
30
47
k
BUS Output Voltage (Dominant)
(Note 7)
VBUSdom
7.0 VSUP 18 V, TxD = 0 V,
RL = 500 −
−
1.2
V
BUS Output Voltage (Recessive)
(Notes 7 and 8)
VBUSrec
7.0 VSUP 18 V, TxD = 4.5 V
0.8 *VSUP
−
−
V
ILIM
VBUS > 2.5 V, TxD = 0 V
40
−
120
mA
Rpu_TxD
−
9.5
15
21
k
Input Low Level
VIL
−
−
−
1.25
V
Input High Level
VIH
−
3.75
−
−
V
Output Voltage Low
VOL
IOUT = 1.0 mA
−
−
0.8
V
Output Voltage High
VOH
IOUT = −1.0 mA
4.2
−
−
V
BUS Pullup Resistor
BUS Current Limit
7.0 V VSUP 18 V
TxD
Pullup Resistance
RxD
7. See Figures 7, 8, and 9 for test setup.
8. The recessive voltage on BUS should not be less than 80% direct battery. The LIN specification requires an external reverse battery diode
between the battery and VSUP. VSUP = VBAT −0.7 V.
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NCV7361A
ELECTRICAL CHARACTERISTICS (7.0 V VSUP 18 V, −40°C TA 125°C unless otherwise noted)
Characteristic
Symbol
Condition
Min
Typ
Max
Unit
tRes
−
70
100
140
ms
trr
−
3.0
7.5
15
s
tdeb_BUS
−
1.5
2.8
4.0
s
tWake_BUS
−
25
60
120
s
RESET AC CHARACTERISTICS
Reset Time
Reset Rise Time (Note 9)
BUS Debounce Time (Note 14)
Wake−Up Time
GENERAL LIN BUS INTERFACE AC CHARACTERISTICS
Transmit Propagation Delay
TxD −> BUS (Notes 10 and 11)
tdr_TxD,
tdf_TxD
RL/CL at BUS
1.0 k/1.0 nF
660 /6.8 nF
500 /10 nF
VSUPMIN = 8 V
−
−
4.0
s
Symmetry of Propagation Delay
BUS −> RxD (Note 10)
tdsym_TxD
tdr_TxD − tdf_TxD
VSUPMIN = 8 V
−2.0
−
2.0
s
Receiver Propagation Delay
BUS −> RxD (Notes 10 and 11)
tdr_RxD
tdf_RxD
CL(RxD) = 50 pF
VSUPMIN = 8 V
−
−
6.0
s
Symmetry of Propagation Delay
TxD −> BUS (Note 10)
tdsym_RxD
tdr_RxD − tdf_RxD
VSUPMIN = 8 V
−2.0
−
2.0
s
Slew Rate BUS Rising Edge (Note 9)
dV/dTrise
20% VBUS 80%
CL = 1.0 nF, RL = 1.0 k
VSUPMIN = 8 V
1.0
1.7
2.5
V/s
Slew Rate BUS Falling Edge (Note 9)
dV/dTfall
20% VBUS 80%
CL = 1.0 nF, RL = 1.0 k
VSUPMIN = 8 V
−2.5
−1.7
−1.0
V/s
LIN BUS PARAMETER ACCORDING TO LIN SPEC. REV. 1.3
Slope Time, Transition from Recessive to
Dominant (Notes 11 and 12)
tsdom
VSUP = 8.0 V
RL = 500 /CL = 10 nF
−
−
12
s
Slope Time, Transition from Dominant to
Recessive (Notes 11 and 13)
tsrec
VSUP = 8.0 V
RL = 500 /CL = 10 nF
−
−
12
s
Slope Time Symmetry
tssym
VSUP = 8.0 V
RL = 500 /CL = 10 nF
Tssym = tsdom − tsrec
−7.0
−
1.0
s
Slope Time, Transition from Recessive to
Dominant (Notes 11 and 12)
tsdom
VSUP = 18 V
RL = 500 /CL = 10 nF
−
−
18
s
Slope Time, Transition from Dominant to
Recessive (Notes 11 and 13)
tsrec
VSUP = 18 V
RL = 500 /CL = 10 nF
−
−
18
s
Slope Time Symmetry
tssym
VSUP = 18 V
RL = 500 /CL = 10 nF
Tssym = tsdom − tsrec
−5.0
−
5.0
s
9. Not production tested, guaranteed by design and qualification.
10. See Figures 2 and 3, Timing Diagrams.
11. See Figures 5, 6, 7, 8, and 9 for test setup.
12. tsdom = (tVBUS40% − tVBUS95%) / 0.55.
13. tsdom = (tVBUS60% − tVBUS5%) / 0.55.
14. See Figure 18.
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NCV7361A
ELECTRICAL CHARACTERISTICS ( VSUP = 7.0 V to 18 V; BUS loads: 1.0 k / 1 nF; 660 / 6.8 nF; 500 / 10 nF, TxD Signal:
tBit = 50 s, twH = TwL = tBit; trise = tfall < 100 ns, −40°C ≤ TA ≤ 125°C unless otherwise noted)
Characteristic
Symbol
Condition
Min
Typ
Max
Unit
−
40
50
58
s
s
LIN BUS PARAMETER ACCORDING TO LIN SPEC. REV. 2.0
Minimal Recessive Bit Time (Notes 15 and 16)
trec(min)
Maximum Recessive Bit Time (Notes 15 and 16)
trec(max)
−
40
50
58
Duty Cycle 1
D1
D1 = trec(min) / (2 * tBit)
0.396
−
−
Duty Cycle 2
D2
D2 = trec(max) / (2 * tBit)
−
−
0.581
15. See Timing Diagrams.
16. See Test Circuits for Dynamic and Static Characteristics.
TIMING DIAGRAMS
TxD
50%
tdf_TxD
VBUS
100%
95%
BUS
tdr_TxD
50%
50%
5%
0%
tdf_RxD
RxD
tdr_RxD
50%
Figure 2. Timing Diagram for Propagation Delay
According to LIN 1.3 and 2.0
VBUS
100%
95%
60%
BUS
40%
5%
0%
Vdom
tsdom
tsrec
Figure 3. Timing Diagram for Slope Times
According to LIN 1.3
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NCV7361A
tBIT
tBIT
TxD
tdom(max)
VSUP
trec(min)
100%
74.4%
tdom(min)
58.1%
BUS
58.1%
42.2%
28.4%
VSS
28.4%
trec(max)
0%
RxD
Figure 4. Timing Diagram for Duty Cycle According to LIN 2.0
TEST CIRCUITS
NCV7361A
VSUP
VSUP
VOUT
EN
RL
RESET
GND
TxD
BUS
RxD
10 F
+
100 nF
50 pF
CL
Figure 5. Test Circuit for Delay Time, Slope Time, and Duty Cycle
12 V
IS1
A
NCV7361A
VSUP
VOUT
EN
+
RESET
GND
TxD
BUS
RxD
10 F
+
Figure 6. Test Circuit for Supply Current ISnl
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8
100 nF
NCV7361A
TEST CIRCUITS (continued)
NCV7361A
VBAT
VSUP
VOUT
EN
V
RESET
GND
TxD
BUS
RxD
10 F
+
100 nF
VBUSREC
Figure 7. Test Circuit for Bus Voltage “Recessive’’
(VBUSREC)
NCV7361A
VSUP
VSUP
VOUT
EN
RESET
10 F
+
100 nF
500
V
GND
TxD
BUS
RxD
VBUSD
Figure 8. Test Circuit for Bus Voltage “Dominant’’ VBUSDOM
NCV7361A
VBAT
VSUP
VOUT
EN
IINBUSR
A
RESET
GND
TxD
BUS
RxD
+
10 F
100 nF
Figure 9. Test Circuit for Bus Current “Recessive’’ IINBUSR
NCV7361A
13.5 V
VSUP
VOUT
EN
RESET
GND
TxD
BUS
RxD
+
CVAR
100 nF
RL
Figure 10. Test Circuit for VOUT Rise Time vs. Load Capacitance and Resistance
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V VOUT
NCV7361A
TYPICAL OPERATING CHARACTERISTICS
Figure 11. Vout Rise Time with 1 F, 10 F,
100 F, and 150 F Capacitors and 200 Load
using EN to Enable the Output.
Figure 12. Vout Rise Time with a 10 F Load
Capacitor and 1 k, 200 , and 100 Load
using EN to Enable the Output.
Figure 13. Vout Rise Time with a 100 F Load
Capacitor and 1 k, 200 , and 100 Load
using EN to Enable the Output.
Figure 14. Vout Rise Time with a 150 F Load
Capacitor and 1 k, 200 , and 100 Load
using EN to Enable the Output.
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NCV7361A
FUNCTIONAL DESCRIPTION
Operating Modes
The NCV7361A consists of a low drop voltage regulator
5.0 V/50 mA and a LIN Bus transceiver, which is a
bidirectional bus interface for data transfer between the
LIN bus and the LIN protocol controller.
Additionally, the NCV7361A features a RESET output
with a reset delay of 100 ms and a fixed threshold of 4.65 V
and Enable (EN) control for the regulator.
The NCV7361A provides two main operating modes
“normal” and “sleep” and the intermediate states “POR”,
“Ini−state” and “thermal shutdown”. The main modes are
fixed states defined by basic actions (VSUP start, EN or
wake−up). The intermediate states are soft states. They
aren’t defined by logical actions but by changes of voltage
(VSUP, VOUT) or junction temperature.
VSUP POWER ON
Clear All State−FF
Clear RESET Timer
Regulator ON VOUT Ramp Up
RESET = L
Wake−Up Disabled
VSUP > UVR_OFF
POR
Ini−state
VSUP < UVR_ON
VOUT > VRES (4.65 V)
VOUT < VRES
VSUP < UVR_ON
Normal
Mode
VSUP > UVR_OFF and
(EN = L/H or Bus Wake−Up)
EN = H/L
Regulator ON
RESET = L after 100 ms
RESET = H
Wake−Up Disabled
LIN Transceiver ON
Normal Mode and
TJ < TJREC
EN = L
Sleep
Mode
EN = H
Normal Mode and
TJ > TJSHD
Sleep Mode and
TJ < TJREC
Sleep Mode and
TJ < TJSHD
Thermal
Shutdown
Regulator OFF
Wake−Up Enabled (LIN Receiver ON)
LIN Transmitter OFF
Regulator OFF
Wake−Up Disabled
LIN Transceiver OFF
TJ < TJREC
Figure 15. State Diagram of Operating Modes
Normal Mode
Sleep Mode
The whole NCV7361A is active. Switching to normal
mode can be done via the following actions:
• Start of VSUP or after Undervoltage Reset
• Rising Edge at EN (EN = High) (Local Wake−Up)
• Activity on the LIN Bus (Remote Wake−Up)
Sleep mode is most current saving. With a falling edge
on EN (EN = Low) the NCV7361A is switched from
normal mode into sleep mode. The voltage regulator will
be switched off and the LIN transceiver is in
recessive state.
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NCV7361A
VSUP
VSUVR_OFF
VSUVR_ON
UVR
POR
POR
EN = H/L
Normal Mode
Sleep Mode
UVR
Normal Mode
VOUT
Figure 16. Operating of Power On and Undervoltage RESET
Switching into sleep mode can be done independently
from the current transceiver state. That means if the
transmitter is in dominant state this state will be cancelled
and it will be switched to recessive state.
independence from the rise time of VSUP. During fast VSUP
edges the Power−on−Reset will be active. If the increasing
of VSUP is very slow (> 1 ms/V) the undervoltage reset unit
initializes the voltage regulator if VSUP > VSUVR_OFF
(typical 3.5 V).
The effects of both POR circuits at different VSUP slopes
as shown in Figure 16.
After POR the voltage regulator starts and VOUT will be
output. If VOUT > VMRes the bus interface will be activated.
If the VOUT voltage level is higher than VRES, the reset time
tRes = 100 ms is started. After tRes the RESET output
switches from low to high (Figure 16).
POR−state
This is the power−on−reset state of the NCV7361A,
while VSUP < VSUVR_OFF. If the prior state was sleep mode,
the NCV7361A switches via the Ini−state to normal mode.
Ini−state
This is an intermediate state, which will pass through
after switch−on of VSUP or VOUT. The NCV7361A remains
in this state if VOUT is below VRES (Reset Output = L) and
VSUP > VSUVR_ON.
Start of Linear Regulator via Wake−Up
The initialization is only being done for the VOUT
circuitry parts. This procedure begins with leaving the
master reset state (VOUT > VMRes) and runs in the same
manner as the VSUP − Power−On.
Thermal Shutdown
If the junction temperature TJ is higher than TJSHD
(>155°C), the NCV7361A will be switched into the
thermal shutdown mode. The behavior within this mode is
comparable with the sleep mode except for LIN transceiver
operating. The transceiver is completely disabled, no
wake−up functionality is available.
If TJ falls below the thermal recovery temperature TJREC
(typical 140°C) the NCV7361A will be recover to the
previous state (normal or sleep).
Wake−Up
If the regulator is put into sleep mode it can be
“waked−up” with the BUS interface. Every pulse on the
BUS (high pulse or low pulse) with a pulse width of
minimum 60 s switches on the regulator.
After the BUS has “waked−up” the regulator, it can only
be switched off with a high level followed by a low level
on the EN pin.
Initialization
VSUP Undervoltage Reset
Initialization is started if the power supply is switched on
as well as every rising edge on of the NCV7361A via the
EN pin.
The undervoltage detection unit inhibit an undefined
behavior of the NCV7361A under low voltage condition.
If VSUP drops below VSUVR_ON (typical 3 V) the
undervoltage detection becomes active and the IC will be
switched to POR state. The following increasing of VSUP
above VSUVR_OFF (typical 3.5 V) cancels this POR state
and the voltage regulator starts with the initialization
sequence.
VSUP − Power On
If VSUP is switched on the NCV7361A starts to normal
mode via the POR− and Ini−state. A combination of
dynamic POR and undervoltage reset circuitry generates a
POR signal, which switches the NCV7361A into normal
mode. This power on behavior is independent from the
status of the EN pin.
Power−on−Reset and undervoltage reset operates
independent from each other, which secures the
VSUP Undervoltage in Normal Mode
Supply Voltages below VSUVR_OFF do not influence the
voltage regulator. The output voltage VOUT follows VSUP.
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NCV7361A
VSUP Undervoltage in Sleep Mode
LIN BUS Transceiver
No exit from the sleep mode will take place if the VSUP
voltage drops down to VSUVR_ON (typical 3.0 V). The
undervoltage reset becomes active (POR−state). As a result
of this operating, the sleep mode is left to the normal mode.
If VSUP rises again above VSUVR_OFF (typical 3.5 V), the
IC initializes the voltage regulator and continues to work
with the normal mode.
The undervoltage reset unit secures stable operating in
the undervoltage range of VSUP down to GND level. The
dynamic Power−On−Reset secures a defined internal state
independent from the duration of the VSUP drop, which
secures a stable restart.
The NCV7361A is a bidirectional bus interface device
for data transfer between the LIN bus and the LIN protocol
controller.
The transceiver consists of a pnp−driver (1.2 V @
40 mA) with slew rate control, wave shaping and current
limit, and a high voltage receiver/comparator followed by
a filter circuit.
Transmit Mode
During transmission the data at the TxD pin will be
transferred to the BUS driver for generating a BUS signal.
To minimize the electromagnetic emission of the bus line,
the BUS driver has integrated slew rate control and wave
shaping circuitry.
Transmitting will be interrupted in the following cases:
• Sleep Mode
• Thermal Shutdown Active
• Master Reset (VOUT < 3.15 V)
The recessive BUS level is generated from the integrated
30 k pullup resistor in series with a diode This diode
prevents reverse current on VBUS when VBUS > VSUP.
No additional termination resistor is necessary to use the
NCV7361A in LIN slave nodes. If this IC is used for LIN
master nodes, it is necessary to terminate the bus pin with
an external 1.0 k resistor in series with a diode to VBAT.
Overtemperature Shutdown
If the junction temperature is 155°C < TJ < 170°C the
overtemperature recognition will be activated and the
regulator voltage will be switched off. The VOUT voltage
drops down, the reset state is entered and the
bus−transceiver is switched off (recessive state).
After TJ falls below 140°C the NCV7361A will be
initialized again (Figure 17) independently from the
voltage levels on EN and BUS. Within the thermal
shutdown mode the transceiver can not be switched to the
normal mode neither with local nor with remote wake−up.
The operation of the NCV7361A is possible between
TAmax (125°C) and the switch−off temperature, but small
parameter differences can appear.
After overtemperature switch−off the IC behaves as
described in Figure 17.
Receive Mode
The data signal from the BUS pin will be transferred
continuously to the pin RxD. Short spikes on the bus are
suppressed by the internal filter circuit ( = 2.8 s).
VSUP
T>TJ
T<TJ
t<trr
VOUT
t<trr
VRES
tRes
trr
tRes
tRes
tRes
RESET
Initialization
Thermal
shutdown
Spike VSUP
Low voltage
VSUP
Figure 17. RESET Behavior
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Spike VCC
Current limitation
active
NCV7361A
VSUP
Vthr_max
60%
BUS
Vthr_hys
50%
Vthr_cnt
40%
Vthr_min
t < tdeb_BUS
t < tdeb_BUS
RxD
Figure 18. Receive Mode Impulse Diagram
The receive threshold values Vthr_max and Vthr_min are
symmetrical to 0.5*VSUP with a hysteresis of 0.135*VSUP .
The LIN specific receive threshold is between 0.4*VSUP
and 0.6 * VSUP .
The constant slew rate principle holds appropriate voltage
levels and can operate within the LIN Protocol
Specification for RC oscillator systems with a matching
tolerance up to 2% between 2 nodes.
Data Rate
TxD Input
The NCV7361A is a constant slew rate transceiver. The
bus driver works with a fixed slew rate range of 1.0 V/s
V/T 2.5 V/s. This principle provides good
symmetry of the slope times between recessive to dominant
and dominant to recessive slopes within the LIN bus load
range (CBUS, Rterm).
The NCV7361A guarantees data rates up to 20 kb within
the complete bus load range under worst case conditions.
The 5.0 V input TxD directly controls the BUS level:
TxD = low → BUS = low (dominant level)
TxD = high → BUS = high (recessive level)
The TxD pin has an internal pullup resistor connected to
VOUT. This guarantees that an open TxD pin generates a
recessive BUS level.
MCU
NCV7361A
VOUT
VCC
RPU_TxD
Typ.
15 k
RC Filter
(10 ns)
IPU_TxD
TxD
Figure 19. TxD Input Circuitry
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NCV7361A
16
RxD Output
The received BUS signal will be output to the 5.0 V RxD
pin:
BUS < Vthr_cnt – 0.5 * Vthr_hys → RxD = low
BUS > Vthr_cnt + 0.5 * Vthr_hys → RxD = high
This output is a push−pull driver between VOUT and
GND with an output current capability of 1.0 mA.
12
lol_RESET (mA)
NCV7361A
14
MCU
10
8
6
4
VOUT
2
RxD
0
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0 4.5
VOUT (V)
Figure 22. Output Current of Reset Output vs.
VOUT Voltage
Initialization
Figure 20. RxD Output Circuitry
The initialization is started if VSUP is switched on. This
is independent of the EN pin.
Linear Regulator
VSUP Power ON
The NCV7361A has an integrated low dropout linear
regulator with a P−Channel MOSFET output driver whose
output is 5.0 V 2% at 50 mA and 5.5 V VSUP 18 V. Figure 21 shows typical current limit based on the
output voltage.
The NCV7361A starts in the normal mode when VSUP is
applied [>3.15 V (typical)]. The internal circuitry on VOUT
as well as the internal regulator starts the initialization with
power−on−reset. The voltage regulator is switched on.
If VOUT > VPOR the bus−interface will be activated.
If VOUT is higher than VRes, the reset time tRes = 100 ms
is started. After tRes the RESET output switches from low
to high (Figure 22).
The initialization procedure at power on is started
independent from the EN state. The regulator can only be
turned off with a high level followed by a low level on the
EN pin.
120
IVOUT (mA)
100
80
60
Mode Input EN
40
The NCV7361A is switched into the sleep mode when
EN goes from high to low. The normal mode will be kept
as long as EN = high.
The regulator can be turned off by switching EN high to
low independent of the state of the bus−transceiver.
The EN input is internally pulled down to guarantee a
low with no connection. In the high state, the pulldown
current will be switched off to reduce the quiescent current.
The maximum input voltage is VSUP. The threshold is
typical 2.1 V and therefore CMOS levels can be used as
input signals. Figure 23 shows the internal circuitry of the
EN pin.
The EN input is internally pulled down to secure that if
this pin is not connected a low level will be generated. It
will be used two different pull down current sources for
high and low level to minimize the sleep mode current.
20
0
0
1
2
3
4
5
6
VOUT (V)
Figure 21. Characteristic of Current Limit
vs. Output Voltage
RESET
RESET switches from low to high if VSUP is switched on
and VOUT > VRES for tRes.
If VOUT drops below VRES, the RESET output goes from
high to low after trr. Short transients will be filtered.
The RESET output driver is driven from VOUT to
guarantee proper operation.
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NCV7361A
The 4 A pulldown current source is used if the input
voltage VIN > high level voltage VENH. If the input voltage
drops below the low level of EN VENL, the second current
source is used. The resulting pulldown current in this case
is 100 A.
The wide input voltage range allows different EN control
possibilities. If the EN input is connected to an CMOS
output of the MCU, a falling edge switches the NCV7361A
into sleep mode (the regulator is also switched off). The
wake−up is only possible via the bus line.
1000
VSUP
RIN_HL
EN
4 A
Enable
Voltage
Limiter
RIN_LH
RIN (k)
100
96 A
10
0
0
0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0
VIN (V)
Figure 23. EN Input Circuitry
Figure 24. RIN Characteristics of EN Input
MCU
NCV7361A
VBAT
VSUP
+
EN
CIN
LIN−BUS
+5 V
VOUT
RESET
GND
TxD
BUS
RxD
200p
+
Cload
Figure 25. EN Controlled via MCU
MCU
NCV7361A
VBAT
VSUP
+
EN
CIN
LIN−BUS
+5 V
VOUT
RESET
GND
TxD
BUS
RxD
+
200p
Cload
Figure 26. Permanent Normal Mode
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NCV7361A
Overtemperature Shutdown
If the application does not need the wake−up capability
of the NCV7361A, a direct connection EN to VSUP is
possible. In this case, the NCV7361A operates in
permanent normal mode. Also possible is the external
(outside of the module) control of the EN line via a VBAT
signal.
The thermal shutdown threshold is 155°C < TJ < 175°C.
When exceeded, the overtemperature shutdown will be
active and the regulator voltage will be switched off. VOUT
drops down, the reset state is entered and the
bus−transceiver is switched off (recessive state).
After TJ falls below 140°C, the NCV7361A will be
initialized (see Figure 17), independent from the voltage
levels on EN and BUS. Within the thermal shutdown mode,
the transceiver can’t be switched to the normal mode with
local or with remote wake−up.
Function of the NCV7361A is possible between TAmax
(125°C) and the switch−off temperature, but small
parameter differences can appear.
After overtemperature switch−off the IC behaves as
described in the RESET chapter.
Wake−Up
If the regulator is in a standby (sleep) mode, it can be
woken up with the BUS interface. Every pulse on the BUS
(high pulse or low pulse) with a pulse width of minimum
25 s switches on the regulator.
After the BUS wake−up for the regulator, it can only be
turned off with a high level followed by a low level on the
EN pin.
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NCV7361A
APPLICATION HINTS
LIN System Parameter
Bus Loading Requirements
Parameter
Symbol
Min
Typ
Max
Unit
VBAT
8.0
−
18
V
VDrop_rev
0.4
0.7
1.0
V
Voltage Drop at the Series Diode in Pull Up Path
VSerDiode
0.4
0.7
1.0
V
Battery Shift Voltage
VShift_BAT
0
−
0.1
VBAT
Ground Shift Voltage
VShift_GND
0
−
0.1
VBAT
Master Termination Resistor
Rmaster
900
1000
1100
Slave Termination Resistor
Rslave
20
30
60
k
Number of System Nodes
N
2
−
16
−
LENBUS
−
−
40
m
Operating Voltage Range
Voltage Drop of Reverse Protection Diode
Total Length of Bus Line
Line Capacitance
CLINE
−
100
150
pF/m
Capacitance of Master Node
CMaster
−
220
−
pF
Capacitance of Slave Node
CSlave
−
220
250
pF
Total Capacitance of the Bus including Slave and Master Capacitance
CBUS
1.0
4.0
10
nF
RNetwork
537
−
863
1.0
−
5.0
s
Network Total Resistance
Time Constant of Overall System
than 700 . Even if the total network capacitance is below
or equal to the maximum specified value of 10 nF, the
network time constant is higher than 7.0 s.
This problem can be solved only by adjusting the master
termination resistor to the required maximum network time
constant of 5.0 s (max).
The LIN bus output driver of the NCV7361A provides a
higher drive capability than necessary (40 mA @ 1.2 V)
within the LIN standard (33.6 mA @ 1.2 V). With this
driver stage the system designer can increase the maximum
LIN networks with a total network capacitance of more
than 10 nF. The total network resistance can be
decreased to:
Recommendations for System Design
The goal of the LIN physical layer standard is to have a
universal definition of the LIN system for plug and play
solutions in LIN networks up to 20 kbd bus speeds.
In case of small and medium LIN networks, it’s
recommended to adjust the total network capacitance to at
least 4.0 nF for good EMC and EMI behavior. This can be
done by setting only the master node capacitance. The
slave node capacitance should have a unit load of typically
220 pF for good EMC/EMI behavior.
In large networks with long bus lines and the maximum
number of nodes, some system parameters can exceed the
defined limits and the LIN system designer must intervene.
The whole capacitance of a slave node is not only the unit
load capacitor itself. Additionally, there is the capacitance
of wires and connectors, and the internal capacitance of the
LIN transmitter. This internal capacitance is strongly
dependent on the technology of the IC manufacturer and
should be in the range of 30 pF to 150 pF. If the bus lines
have a total length of nearly 40m, the total bus capacitance
can exceed the LIN system limit of 10 nF.
A second parameter of concern is the integrated slave
termination resistor tolerance. If most of the slave nodes
have a slave termination resistance near by the allowed
maximum of 60 k, the total network resistance is more
Rtl_min (VBat_max VBUSdom)IBUS_max
(18 V 1.2 V)40 mA 420 NOTE: The NCV7361A meets the requirements for
implementation in RC−based slave nodes. The LIN
Protocol Specification requires the deviation of the slave
node clock to the master node clock after synchronization
must not differ by more than 2%.
Setting the network time constant is necessary in large
networks (primary resistance) and also in small networks
(primary capacitance).
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NCV7361A
MIN/MAX SLOPE TIME CALCULATION
VBUS
100%
95%
60%
BUS
40%
5%
Vdom
0%
tsdom
tsrec
Figure 27. Slope Time Calculation
50
The slew rate of the bus voltage is measured between
40% and 60% of the output voltage swing (linear region).
The output voltage swing is the difference between
dominant and recessive bus voltage.
45
40
35
PD (mW)
dVdt 0.2 * Vswing(t40%−t60%)
The slope time is the extension of the slew rate tangent
until the upper and lower voltage swing limits:
tslope 5 * (t40%−t60%)
30
25
20
15
The slope time of the recessive to dominant edge is directly
determined by the slew rate control of the transmitter:
10
tslope VswingdVdt
0
5
5
The dominant to recessive edge is influenced from the
network time constant and the slew rate control, because
it’s a passive edge. In case of low battery voltages and high
bus loads the rising edge is only determined by the network.
If the rising edge slew rate exceeds the value of the
dominant one, the slew rate control determines the rising
edge.
6
7
8
9 10 11 12 13 14 15 16 17 18 19
VSUP (V)
Figure 28. Power Dissipation LIN Transceiver
@ 20 kbit
The permitted package power dissipation can be
calculated:
T TA
PDmax J
RJ−A
Power Dissipation and Operating Range
The max power dissipation depends on the thermal
resistance of the package and the PCB, the temperature
difference between Junction and Ambient as well as the
airflow.
The power dissipation can be calculated with:
If we consider that PD_TX_max = f(VSUP), it can be
calculated the max output current IVOUT on VOUT:
TJ−TA
IVOUTmax RJ−A
PD (VSUP VOUT) * IVOUT PD_TX
PD_TX_max @ VSUP
VSUP VOUT
TJ−TA is the temperature difference between junction
and ambient, and Rth is the thermal resistance of the
package. The thermal energy is transferred via the package
and the pins to the ambient. This transfer can be improved
with additional ground areas on the PCB as well as ground
areas under the IC.
The power dissipation of the transmitter PD_TX depends
on the transceiver configuration and its parameters as well
as on the bus voltage VBUS = VBAT − VD, the resulting
termination resistance RL, the capacitive bus load CL and
the bit rate. Figure 28 shows the dependence of power
dissipation of the transmitter as function of VSUP. The
conditions for calculation the power dissipation was:
RL = 500 , CL = 10 nF, Bitrate = 20 kbit and duty cycle
on TxD of 50%.
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NCV7361A
Table 1. SO−8 Thermal RC Network Models*
54 mm2
Copper Area (1 oz thick)
(SPICE Deck Format)
714 mm2
54 mm2
Cauer Network
714 mm2
Foster Network
54 mm2
714 mm2
Units
Tau
Tau
Units
C_C1
Junction
GND
1.08E−05
1.08E−05
W−s/C
1.00E−06
1.00E−06
sec
C_C2
node1
GND
4.10E−05
4.10E−05
W−s/C
1.00E−05
1.00E−05
sec
C_C3
node2
GND
1.13E−04
1.13E−04
W−s/C
1.00E−04
1.00E−04
sec
C_C4
node3
GND
4.42E−04
4.40E−04
W−s/C
5.00E−04
5.00E−04
sec
C_C5
node4
GND
1.74E−03
1.71E−03
W−s/C
1.00E−03
1.00E−03
sec
C_C6
node5
GND
1.39E−03
1.34E−03
W−s/C
1.00E−02
1.00E−02
sec
C_C7
node6
GND
2.08E−02
1.78E−02
W−s/C
1.00E−01
1.00E−01
sec
C_C8
node7
GND
1.08E−02
9.75E−03
W−s/C
1.00E+00
1.00E+00
sec
C_C9
node8
GND
1.14E−01
1.84E−01
W−s/C
1.00E+01
1.00E+01
sec
C_C10
node9
GND
8.11E−01
3.00E+00
W−s/C
5.00E+01
5.00E+01
sec
R’s
R’s
R_R1
Junction
node1
0.119
0.119
C/W
0.070
0.070
C/W
R_R2
node1
node2
0.286
0.286
C/W
0.152
0.152
C/W
R_R3
node2
node3
0.857
0.859
C/W
0.481
0.481
C/W
R_R4
node3
node4
1.181
1.189
C/W
0.690
0.690
C/W
R_R5
node4
node5
1.241
1.276
C/W
0.584
0.584
C/W
R_R6
node5
node6
2.574
2.690
C/W
3.223
3.223
C/W
R_R7
node6
node7
18.065
21.708
C/W
0.823
0.823
C/W
R_R8
node7
node8
27.965
26.035
C/W
26.801
35.166
C/W
R_R9
node8
node9
80.896
49.821
C/W
63.710
52.538
C/W
R_R10
node9
GND
49.468
15.252
C/W
86.119
25.510
C/W
*Bold face items in the tables above represent the package without the external thermal system.
The Cauer networks generally have physical
significance and may be divided between nodes to separate
thermal behavior due to one portion of the network from
another. The Foster networks, though when sorted by time
constant (as above) bear a rough correlation with the Cauer
networks, are really only convenient mathematical models.
Cauer networks can be easily implemented using circuit
R1
Junction
C1
R2
C2
simulating tools, whereas Foster networks may be more
easily implemented using mathematical tools (for instance,
in a spreadsheet program), according to the following
formula:
R(t) n
−ttaui Ri 1−e
i1
R3
Rn
Cn
C3
Time constants are not simple RC products.
Amplitudes of mathematical solution are not the resistance values.
Ambient
(thermal ground)
Figure 29. Grounded Capacitor Thermal Network (“Cauer” Ladder)
Junction
R1
R2
R3
Rn
C1
C2
C3
Cn
Each rung is exactly characterized by its RC−product time constant; Amplitudes are the resistances
Figure 30. Non−Grounded Capacitor Thermal Ladder (“Foster” Ladder)
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Ambient
(thermal ground)
NCV7361A
190
180
JA (°C/W)
170
160
1.0 oz. Cu
150
140
2.0 oz. Cu
130
120
110
100
0
100
200
300
400
500
600
700
800
Copper Area (mm2)
Figure 31. SO−8, JA as a Function of the Pad Copper Area Including Traces,
Board Material
1000
Cu Area = 53.9 mm2 1.0 oz.
Cu Area = 89.7 mm2 1.0 oz.
R (°C/W)
100
Cu Area = 713.9 mm21.0 oz.
10
1
0.1
0.01
0.000001
0.00001
0.0001
0.001
0.01
0.1
1
10
100
1000
Time (s)
Figure 32. SO−8 Thermal Transient Response on Typical Test Boards
R (°C/W)
EFFECTIVE THERMAL RESISTANCE
1000
Cu Area = 713.9 mm21.0 oz.
100
50% Duty Cycle
10%
10 5%
2%
Notes:
1 1%
PDM
t1
t2
0.1
t1
Duty Cycle, D = t
2
Single Pulse
0.01
0.000001
0.00001
0.0001
0.001
0.01
0.1
1
10
Time (s)
Figure 33. SO−8 Thermal Duty Cycle Curves on 1.0 in. Spreader Test Board
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100
1000
NCV7361A
60
Input Capacity on VSUP CIN
It is necessary to have an input capacity of CIN = 4.7 F.
Higher capacity values improve the line transient response
and the supply noise rejection behavior. The combination
of electrolytic capacity (e.g.100 F) in parallel with a
ceramic RF−capacity (e.g. 100 nF) archives good
disturbance suppressing.
The input capacity should be placed as close as possible
(< 1 cm) to the VSUP pin.
maximum current
40
SOIC8
TA = 85°C
TJ = 150°C
SOIC8
TA = 125°C
TJ = 150°C
30
20
SOIC8
TA = 85°C
TJ = 125°C
10
max. supply voltage
IVCC_max (mA)
50
Load Capacity on VOUT CL
The regulator is stabilized by the output capacitor CL.
The NCV7361A requires a minimum of 4.7 F capacity
connected to the 5.0 V output to insure stability. This
capacitor should maintain its ESR in the stable region of the
ESR curve (Figure 35) over the full operating temperature
range of the application. The capacity value and the ESR
of a capacitor changes with temperature. The minimal
capacity value must be kept within the whole operating
temperature range.
0
5
6
7
8
9 10 11 12 13 14 15 16 17 18 19
VSUP (V)
Figure 34. Safe Operating Area
The linear regulator of the NCV7361A operates with
input voltages up to 18 V and can output a current of
50 mA. The maximum power dissipation limits the
maximum output current at high input voltages and high
ambient temperatures. The output current of 50 mA at an
ambient temperature of TA = 125°C is only possible with
small voltage differences between VSUP and VCC. See
Figure 34 for safe operating areas for different ambient and
junction temperatures.
Example 1:
The regulator is stabilized using a 47 F aluminum
electrolytic capacitor load (ESR = 0.7 @ 25°C). The
capacitance decreases to 42 F and the ESR increases to
8.9 at an ambient temperature of −40°C. The ESR value
is located in the unstable region. The regulator will be
unstable at −40°C.
Regulator Circuitry
Example 2:
The regulator is stabilized using a 47 F tantalum
capacitor load (ESR = 0.1 @ 25°C). The capacitance
decreases to 45 F and the ESR increases to 0.11 at an
ambient temperature of −40°C. The ESR value is located
in the stable region. The regulator will be stable at −40°C.
Low Dropout Regulator
The voltage regulator of the NCV7361A is a low dropout
regulator (LDO) with a P−MOSFET as the
driving transistor.
This type of regulator has a standard pole, generated
from the internal frequency compensation and an
additional pole, which is dependent from the load and the
load capacity. This additional pole can cause an instable
behavior of the regulator! It requires a zero point to
compensate this additional pole. It can be realized via an
additional load resistor in series with a load capacity. It is
used
for
this
compensation
the
Equivalent Series Resistance (ESR) of the load capacity.
Every real capacity is characterized with an ESR value.
With the help of this ESR value an additional zero point is
implemented into the amplification loop and therefore the
result of the negative phase shift is compensated.
Because of this correlation the regulator has a stable
operating area which is defined by the load resistance RL,
the load capacity CL and the corresponding ESR value. The
load resistance resp. load current is defined by the
application itself and therefore the compensation of the
pole can only be done via variation of the load capacity and
ESR value.
ESR @ 100 kHz (Ohm)
100
Unstable Region
10
1
Stable Region
0.1
Unstable Region
0.01
0
10
20
30
40
50
Load Current (mA)
Figure 35. ESR Curves for 6.8 F CL 100 F and
Frequency of 100 kHz
The value and type of the output capacitor can be
selected by using the diagram shown in Figure 35.
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NCV7361A
Capacity Value
Normally the specified ESR values for a capacitor is valid
at a temperature of TA = 25°C and a frequency of
f = 100 kHz.
The temperature coefficient is negative, which means
with increasing of the temperature the ESR value
decreases. In the choice of the capacity has to be taken into
account that the ESR can decrease at TA = −40°C
dramatically that the valid operating area can be left, which
causes that the regulator will be instable.
The capacity value of an electrolytic capacitor is
dependence from the voltage, temperature and the
frequency. The temperature coefficient of the capacity
value is positive, that means that the value increases with
increasing of the temperature. The capacity value
decreases with increasing of the frequency. This behavior
of a capacitor can cause that at TA = −40°C the capacity
value falls below the minimum required capacity for the
regulator. In this case the regulator becomes instable,
which means the regulator starts oscillation. The nominal
value of the capacitor at TA = 25°C has to be chosen with
enough margin under consideration of the capacitor
specification. The instable behavior will be amplified
because of the decreasing of the capacity with this
oscillation.
Tantalum Capacitors
This type of capacitor has a low dependence of the
capacity and the ESR from the temperature and is therefore
well suitable as VOUT load capacity.
Aluminum Capacitors
These capacitors show a strong influence of the capacity
and the ESR from the temperature. These characteristic
restrains the usability as load capacity for the low drop
regulator of NCV7361A.
ESR
The Equivalent Serial Resistance is the resistor part of
the equivalent circuit diagram of a capacitor. The ESR
value is dependent from the temperature and frequency.
Reverse
Protection−Diode
VBAT
VSUP
+
100 F
C
NCV7361A
100 nF
LIN−BUS
+5 V
VOUT
EN
RESET
GND
TxD
BUS
RxD
+
220 pF
10 F...100 F
100 nF
or
Optional
33 H
10
RC−Filter
100 p
LC−Filter
82p
Figure 36. Application Circuit (Slave Node)
EMI Suppressing
filter capacitor influences the effectiveness of the EMI
suppressing in conformance to the maximum LIN bus
capacity of 10 nF.
LC−filters or RC−filters can also be used. The value of
C, L or R, depends on the corner frequency, the maximum
LIN bus capacity (10 nF) and the compliance with the DC−
and AC LIN bus parameters.
To minimize the influence of EMI from the bus line, a
220 pF capacitor should be directly connected to the BUS
pin (see Figure 36).
The value of the filter capacity can be adjusted to the size
of the LIN network. 220 pF should be used for bigger
networks. Values from 333 pF up to 1.0 nF should be used
for middle to small LIN networks. Finally the size of the
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NCV7361A
VBAT
VIN
+
VOUT
100nF
+
100F
GND
100nF
+5 V
100nF
NCV7380*
1k
220pF
NC
RxD
VS
NC
BUS
VCC
GND
TxD
P
100nF
LIN−BUS
Master Node
NCV7361A
VSUP
+
100F
+5 V
VOUT
1k
100nF
100nF
EN
RESET
GND
TxD
BUS
RxD
C
220pF
+
100F
100nF
Slave Node
*Not representative of actual pinout.
Figure 37. Application Circuit for LIN Sub−Bus with NCV7361A as Slave Node
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NCV7361A
Connection to Flash−MCU
diode must be used between the MCU and the RxD pin to
avoid loading of the programming data.
The programming of the flash is also possible via the
LIN pin, if the MCU supports this kind of flash mode.
During programming of a flash MCU the NCV7361A
should be disconnected from the MCU. This can be done
by disconnecting the supply voltage of the NCV7361A or
by turning off the NCV7361A with the EN pin. A blocking
Prog.−Data
10F...47F
NCV7361A
+
VOUT
C
47nF...100nF
RESET
TxD
RxD
0.7 V
Vhigh_RxD > 4.7 V at VDD = 5 V
Vlow_RxD = 0.8 V
Vhigh = 4 V at VDD = 5 V
Figure 38. Example Circuitry for Connection of RxD to MCU for Flash Programming
Operating During Disturbance
Short Circuit VOUT to GND
Operating Without VSUP or GND
The VOUT pin is protected via a current limit. This state
is comparable with the behavior in the sleep mode.
The BUS pin is designed for voltages of GND − 24 V up
to GND + 30 V. This prevents loss of communication
between other bus nodes with the loss of VSUP or loss of
GND. The BUS pin will remain at VBAT and current draw
will be minimal with the loss of GND or VSUP.
Overload of VOUT
Thermal Switch−Off
The power dissipation is increasing if the load current is
between IVOUT_max and ILVOUT. If the IC exceeds the
thermal shutdown threshold of > 155°C, the transceiver
will be switched off. The voltage regulator will also be
switched off and a reset signal is forced.
Short Circuit BUS to VBAT
• Recessive
• Dominant
LIN bus is blocked, no influence to the
NCV7361A
Current limit, thermal shutdown of
NCV7361A if power dissipation raises TJ
Overcurrent
If the current limit is active the voltage on VOUT drops
down. If this voltage is below the threshold VRES, a reset
will be forced.
Short Circuit BUS to GND
The LIN bus is blocked. There is no influence to the
NCV7361A.
Undervoltage VSUP, VOUT
The reset circuit guarantees the correct behavior of the
driver during undervoltage. The BUS pin generates the
recessive state if VOUT < VMRes. The inputs EN and TxD
have pull−down and pull−up circuits respectively.
If VMRes VOUT 4.5 V the TxD signal is transmitted
to the bus. The receive mode is also active.
Short Circuit TxD to GND
The LIN transceiver is permanent in the dominant state
as is the LIN bus. This state can only be detected from the
LIN controller. In this case the controller must switch−off
the LIN node via the EN input of the NCV7361A and look
for a recessive state. A thermal shutdown of NCV7361A
will appear if the thermal shutdown threshold is exceeded.
Short Circuit RxD, RESET to GND or VOUT
Both outputs are short circuit proof to VOUT and ground.
TxD Open
The internal pullup resistor forces the LIN node to the
recessive state. The communication between the other
bus−nodes will not be disturbed.
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NCV7361A
ESD/EMC Remarks
ESD Test
General Remarks
The NCV7361A is tested according to MIL883−3015.7
(Human Body Model).
Electronic semiconductor products are sensitive to
Electro Static Discharge (ESD). Always observe Electro
Static Discharge control procedures whenever handling
semiconductor products.
EMC
The test on EMC impacts is done according to ISO
7637−1 for power supply pins and ISO 7637−3 for data and
signal pins.
POWER SUPPLY PIN VSUP
Test Pulse
Condition
Duration
1
t1 = 5.0 s/US = −100 V/tD = 2.0 ms
5000 Pulses
2
t1 = 0.5 s/US = 100 V/tD = 0.05 ms
5000 Pulses
3a/b
5
US = −150 V/US = 100 V
Burst 100 ns/10 ms/90 ms Break
Ri = 0.5 , tD = 400 ms
tr = 0.1 ms/UP + US = 40 V
1h
10 Pulses Every 1 Min
DATA AND SIGNAL PINS EN, BUS
Test Pulse
Condition
Duration
1
t1 = 5.0 s/US = −100 V/tD = 2.0 ms
1000 Pulses
2
t1 = 0.5 s/US = 100 V/tD = 0.05 ms
1000 Pulses
3a/b
US = −150 V/US = 100 V
Burst 100 ns/10 ms/90 ms Break
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1000 Burst
NCV7361A
PACKAGE DIMENSIONS
SOIC−8 NB
CASE 751−07
ISSUE AE
NOTES:
1. DIMENSIONING AND TOLERANCING PER
ANSI Y14.5M, 1982.
2. CONTROLLING DIMENSION: MILLIMETER.
3. DIMENSION A AND B DO NOT INCLUDE
MOLD PROTRUSION.
4. MAXIMUM MOLD PROTRUSION 0.15 (0.006)
PER SIDE.
5. DIMENSION D DOES NOT INCLUDE DAMBAR
PROTRUSION. ALLOWABLE DAMBAR
PROTRUSION SHALL BE 0.127 (0.005) TOTAL
IN EXCESS OF THE D DIMENSION AT
MAXIMUM MATERIAL CONDITION.
6. 751−01 THRU 751−06 ARE OBSOLETE. NEW
STANDARD IS 751−07.
−X−
A
8
5
0.25 (0.010)
S
B
1
M
Y
M
4
K
−Y−
G
C
N
X 45 SEATING
PLANE
−Z−
0.10 (0.004)
H
D
0.25 (0.010)
M
Z Y
S
X
M
J
S
RECOMMENDED FOOTPRINT
1.52
0.060
7.0
0.275
4.0
0.155
0.6
0.024
1.270
0.050
SCALE 6:1
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mm inches
DIM
A
B
C
D
G
H
J
K
M
N
S
MILLIMETERS
MIN
MAX
4.80
5.00
3.80
4.00
1.35
1.75
0.33
0.51
1.27 BSC
0.10
0.25
0.19
0.25
0.40
1.27
0 8 0.25
0.50
5.80
6.20
INCHES
MIN
MAX
0.189
0.197
0.150
0.157
0.053
0.069
0.013
0.020
0.050 BSC
0.004
0.010
0.007
0.010
0.016
0.050
0 8 0.010
0.020
0.228
0.244
NCV7361A
ON Semiconductor and
are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC reserves the right to make changes without further notice
to any products herein. SCILLC makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does SCILLC assume any
liability arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation special, consequential or incidental
damages. “Typical” parameters which may be provided in SCILLC data sheets and/or specifications can and do vary in different applications and actual performance may vary over
time. All operating parameters, including “Typicals” must be validated for each customer application by customer’s technical experts. SCILLC does not convey any license under
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NCV7361A/D