High Performance Resonant Mode Controller with Integrated High-Voltage Drivers

NCP1398B/C
High Performance Resonant
Mode Controller with
Integrated High-Voltage
Drivers
The NCP1398 is a high performance controller for half bridge LLC
resonant converters. The integrated high voltage gate driver simplifies
layout and reduces external component count. A unique architecture,
which includes a 750 kHz Voltage Controlled Oscillator whose control
mode permits flexibility when an ORing function is required allows
the NCP1398 to deliver everything needed to build a reliable and
rugged resonant mode power supply. The NCP1398 provides a suite of
protection features with configurable settings allow optimization in
any application. This includes: auto−recovery and latch−off
over−current protection, brown−out detection, open optocoupler
detection, adjustable soft−start and dead−time.
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SOIC−16 NB, Less Pin 13
D SUFFIX
CASE 751AM
MARKING DIAGRAM
16
Features
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High−Frequency Operation from 50 kHz up to 750 kHz
Adjustable Minimum Switching Frequency with ± 3% Accuracy
Adjustable Dead−Time
Startup Sequence Via an Externally Adjustable Soft−Start
Precise and High Impedance Brown−Out Protection
Latched Input for Severe Fault Conditions, e.g. Over Temperature or
OVP
Timer−Based Auto−Recovery Overcurrent Protection
Latched Output Short−Circuit Protection
Open Feedback Loop Protection for NCP1398B Version
Disable Input for ON/OFF Control
Skip Mode with Adjustable Hysteresis
VCC Operation up to 20 V
1 A / 0.5 A Peak Current Sink / Source Drive Capability
Common Collector Optocoupler Connection for Easier ORing
Internal Temperature Shutdown
Designed with Pin−to−Adjacent−Pin Short Testing Safety
Considerations
Designed with Open Pin Testing Safety Considerations
These Devices are Pb−Free and Halogen Free/BFR Free
Typical Applications
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January, 2013 − Rev. 0
1
x
A
WL
Y
WW
G
= B or C
= Assembly Location
= Wafer Lot
= Year
= Work Week
= Pb−Free Package
PIN CONNECTIONS
BO 1
16 Vboot
Ctimer 2
15 HB
14 Mupper
Discharge 3
Fmax 4
Rt 5
12 VCC
DT 6
11 GND
FB 7
10 Mlower
Skip/Disable 8
9 OLP
(Top View)
ORDERING INFORMATION
See detailed ordering and shipping information on page 23 of
this data sheet.
Flat panel Display Power Converters
High Power AC/DC Adapters
Computing Power Supplies
Industrial and Medical Power Sources
Offline Battery Chargers
© Semiconductor Components Industries, LLC, 2013
NCP1398xG
AWLYWW
1
Publication Order Number:
NCP1398/D
NCP1398B/C
HV
Rupper
FB
R1
OK2
+
M1
D1
OK1
C5
R3
R4
U5
1
2
Rdis
3
4
5
6
7
8
Rocp
BO
16
Vboot
Ctimer
Vout
Ls
C1
15
HB
D6
14
Discharge Mupper
M2
Rt
VCC
DT
GND
FB
Mlower
Skip/disable
12
R5
11
R6
10
C6
OCP Input
9
OLP
R10
T1
OK1
Ct
D2
FB
OVP
C8
OK2
D8
R13
C9
C4
C3
RDT
Rt
Rfmax
C2
R1
D4
+
Cs
Css
R11
D7
D3
Rss
R12
+
C7
Fmax
CBO
Cocp
D5
R7
R2
OVP
U1
R9
R8
R2
Rfmin Rfb Rskip_out Rlower
Figure 1. Typical Application Example
PIN FUNCTION DESCRIPTION
Pin N5
Pin Name
Function
Pin Description
1
BO
Brown−Out
Detects low input voltage conditions. When brought above Vlatch (4V),
fully latches off the controller.
2
Ctimer
Fault timer duration
Sets the fault timer and auto−recovery durations
3
Discharge
Overload protection
Implements frequency shift in case of overload.
4
Fmax
Maximum frequency clamp
A resistor connected between this pin and GND sets the maximum frequency excursion. Controller enters skip mode and disables drivers if
the operating frequency exceeds this adjusted value.
5
Rt
Minimum frequency clamp
Connecting a resistor to this pin, sets the minimum oscillator frequency
reached for VFB = 1.1 V. Discharge OCP and Soft Start networks before
startup or reset.
6
DT
Dead−time adjust
7
FB
Feedback
Voltage on this pin modulates operating frequency between adjusted
Fmin and Fmax clamps. Starts Fault timer when FB voltage stays below
0.28 V − function not active on NCP1398C version.
8
Skip/Disable
Skip or Disable input
Defines frequency and thus also FB voltage under which the controller
returns from skip mode. Upon release, a clean startup sequence occurs
if VFB < 0.28 V. During the skip mode, when FB doesn’t drop below
0.28 V, the IC restarts without soft start sequence.
9
OLP
Overload protection detection
input
10
Mlower
Low side output
11
GND
IC ground
12
VCC
Supplies the controller
The controller accepts up to 20 V
13
NC
Not connected
Increases the creepage distance
15
Mupper
High side output
Drives the higher side MOSFET
14
HB
Half−bridge connection
16
Vboot
Bootstrap pin
A simple resistor adjusts the dead−time
Initiates fault timer when asserted. Increases operating frequency via
discharge pin to protect application power stage. This input features
also latch fault comparator that latches off the IC permanently.
Drives the lower side MOSFET
−
Connects to the half−bridge output
The floating VCC supply for the upper stage
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2
NCP1398B/C
Figure 2. Internal Circuit Architecture – NCP1398C
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3
NCP1398B/C
Figure 3. Internal Circuit Architecture – NCP1398B
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4
NCP1398B/C
MAXIMUM RATINGS
Symbol
Value
Unit
High Voltage bridge pin
Rating
VBRIDGE
−1 to 600
V
Floating supply voltage
VBOOT −
VBRIDGE
0 to 20
V
High side output voltage
VDRV_HI
VBRIDGE−0.3 to
VBOOT+0.3
V
Low side output voltage
VDRV_LO
−0.3 to VCC + 0.3
V
dVBRIDGE/dt
50
V/ns
VCC
−0.3 to 20
V
−
−0.3 to 10
V
Thermal Resistance Junction−to−Air, PDIP version
RqJ−A
100
°C/W
Thermal Resistance Junction−to−Air, SOIC version
RqJ−A
130
°C/W
Storage Temperature Range
−
−60 to +150
°C
ESD Capability, HBM model , Except pins 14, 15, 16
−
2
kV
ESD Capability, Machine Model
−
200
V
Allowable output slew rate
FB and VCC pin voltage (pins 7 and 12)
Maximum voltage, all pins (except pins 7, 12, 14, 15 and 16)
Stresses exceeding Maximum Ratings may damage the device. Maximum Ratings are stress ratings only. Functional operation above the
Recommended Operating Conditions is not implied. Extended exposure to stresses above the Recommended Operating Conditions may affect
device reliability.
1. This device(s) contains ESD protection and exceeds the following tests:
Human Body Model 2000 V per JEDEC Standard JESD22−A114E
Machine Model 200 V per JEDEC Standard JESD22−A115−A
2. This device meets latch−up tests defined by JEDEC Standard JESD78.
ELECTRICAL CHARACTERISTICS
(For typical values TJ = 25°C, for min/max values TJ = −40°C to +125°C, Max TJ = 150°C, VCC = 12 V unless otherwise noted)
Symbol
Rating
Pin
Min
Typ
Max
Unit
Turn−on threshold level, Vcc going up
12
9.7
10.5
11.3
V
VCC(min)
Minimum operating voltage after turn−on
12
8.7
9.5
10.3
V
VbootON
Startup voltage on the floating section
16−15
8
9
10
V
Vboot(min)
Cutoff voltage on the floating section
16−15
7.4
8.4
9.4
V
SUPPLY SECTION
VCCON
Istartup
Startup current, VCC < VCCON
12
−
−
620
mA
VCCreset
VCC level at which the internal logic gets reset
12
−
6.6
−
V
ICC1+Iboot1
Internal IC consumption, no output load on pin 15/14 – 11/10,
Fsw = 300 kHz, Rdt = 10 kW, RT = 31 kW, RFmax = 7.2 kW,
RSkip/Disable = 7.9 kW, VFb = 3.6 V
12−11
16−15
−
5.1
−
mA
ICC2+Iboot2
Internal IC consumption, 1 nF output load on pin 15/14 – 11/10,
Fsw = 300 kHz, Rdt = 10 kW, RT = 31 kW, RFmax = 7.2 kW,
RSkip/Disable = 7.9 kW, VFb = 3.6 V
12−11
16−15
−
13.3
−
mA
ICC3+Iboot3
Consumption in fault or disable mode, All drivers disabled, Rdt
=10 kW, RFmin = 31 kW, RFmax = 7.2 kW, RSkip/Disable =
7.9 kW, VFb = 1 V
12−11
16−15
−
1.05
−
mA
ICC4+Iboot4
Consumption in skip mode , All drivers disabled, Rdt =10 kW,
RFmin = 31 kW, RFmax = 7.2 kW, RSkip/Disable = 7.9 kW,
VFb = 5.7 V
12−11
16−15
−
2.2
−
mA
58.2
57.2
60
60
61.8
61.8
VOLTAGE CONTROL OSCILLATOR (VCO)
Fsw_min
Minimum switching frequency, Rt = 31 kW on pin 5, Vpin 7 =
0.8 V, DT = 300 ns
0 to 125°C
−40 to 125°C
3. Guaranteed by design.
4. Not tested for NCP1398C.
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5
5
kHz
NCP1398B/C
ELECTRICAL CHARACTERISTICS
(For typical values TJ = 25°C, for min/max values TJ = −40°C to +125°C, Max TJ = 150°C, VCC = 12 V unless otherwise noted)
Symbol
Rating
Pin
Min
Typ
Max
Unit
4
465
525
585
kHz
10−14
48
50
52
%
VOLTAGE CONTROL OSCILLATOR (VCO)
Fsw_max
Maximum switching frequency clamp, Rfmax = 7.2 kW on pin 4,
Vpin 7 ramps up above 5.3 V, DT = 300 ns
DC
Operating duty−cycle symmetry
Tdel
Delay before driver re−start from fault, skip or disable mode
−
−
10
−
ms
Reference voltage for Rt pin
5
2.18
2.3
2.42
V
Internal pull−down resistor
7
−
20
−
kW
Vfb_min
Voltage on pin 7 below which the VCO has no action and Fmin
clamp is reached
7
−
1.1
−
V
Vfb_max
Voltage on pin 7 below which the VCO has no action and Fmax
clamp is reached
7
−
5.5
−
V
Vfb_fault
Voltage on pin 7 below which the controller considers the FB fault
(Note 4)
7
240
280
320
mV
Feedback fault comparator hysteresis (Note 4)
7
−
45
−
mV
Vref_Rt
FEEDBACK SECTION
Rfb
Vfb_fault_hyste
DRIVE OUTPUT AND DEAD−TIME CLAMP
Tr
Output voltage rise−time @ CL = 1 nF, 10−90% of output signal
14−15/
12−11
−
40
−
ns
Tf
Output voltage fall−time @ CL = 1 nF, 10−90% of output signal
14−15/
12−11
−
20
−
ns
ROH
Source resistance
14−15/
12−11
−
13
−
W
ROL
Sink resistance
14−15/
12−11
−
5.5
−
W
T_dead_nom
Dead time with RDT = 10 kW from pin 6 to GND
6
250
290
340
ns
T_dead_max
Maximum dead−time with RDT = 71.5 kW from pin 6 to GND
6
−
1.9
−
ms
T_dead_min
Minimum dead−time, RDT = 2.8 kW from pin 6 to GND
6
−
100
−
ns
14, 15,
16
−
−
5
mA
Timer capacitor charge current during feedback fault or when
Vref_fault < Vpin9 < Vref_OCP
3
165
195
215
mA
Timer duration with a 1 mF capacitor and a 1 MW resistor, Itimer1
current applied (Note 3)
3
−
19.3
−
ms
T−timerR
Timer recurrence in permanent fault, same values as above
(Note 3)
3
−
1.4
−
s
VtimerON
Voltage at which pin 3 stops output pulses
3
3.8
4
4.2
V
VtimerOFF
Voltage at which pin 3 re−starts output pulses
3
0.95
1
1.05
V
Rtimer_dis
Timer discharge switch resistance (Note 3)
1
−
100
−
W
Brown−Out input bias current (Note 3)
1
−
−
0.01
mA
Brown−Out level
1
0.98
1.008
1.08
V
Brown−Out comparator hysterisis
1
−
10
−
mV
BO filter duration (Note 3)
1
−
20
−
ms
IHV_LEAK
Leakage current on high voltage pins to GND
FAULT TIMER
Itimer
T−timer
BROW−OUT PROTECTION
IBO_bias
VBO
VBO_hyst
Tfl_BO
3. Guaranteed by design.
4. Not tested for NCP1398C.
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6
NCP1398B/C
ELECTRICAL CHARACTERISTICS
(For typical values TJ = 25°C, for min/max values TJ = −40°C to +125°C, Max TJ = 150°C, VCC = 12 V unless otherwise noted)
Symbol
Rating
Pin
Min
Typ
Max
Unit
Hysteresis current, Vpin1 < VBO
1
7.5
8.5
9.1
mA
Latching voltage
1
3.7
4
4.3
V
−
5
−
ms
BROW−OUT PROTECTION
IBO
Vlatch
Tfl_BO_latch
BO latch filter duration (Note 3)
SKIP/DISABLE INPUT
Fskip−out
Skip−out frequency, Rskip/disable = 7.9 kW
8
426
480
534
kHz
Idisable
Skip/Disable pin output current below which is the controller
disabled
8
−
12
−
mA
Tfl_skip
Skip/Disable input filter time constant (Note 3)
8
1
ms
OVERLOAD PROTECTION
Vref_Fault_OCP
Hyste_Fault_OCP
Vref_latch_OCP
T_OCP_latch
TSD
TSD_hyste
Reference voltage for Fault comparator
9
0.95
1
1.05
V
Hysteresis for fault comparator input
9
−
100
−
mV
Reference voltage for OCP comparator
9
1.425
1.5
1.575
V
Filtering time constant for OCP latch comparator (Note 3)
9
−
1
−
ms
Temperature shutdown (Note 3)
−
140
−
−
°C
Hysteresis (Note 3)
−
−
30
−
°C
3. Guaranteed by design.
4. Not tested for NCP1398C.
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NCP1398B/C
TYPICAL CHARACTERISTICS
10.6
9.5
9.48
10.55
VCCmin (V)
VCCON (V)
9.46
10.5
10.45
9.44
9.42
9.4
10.4
9.38
10.35
−40 −25 −10
5
20 35 50 65 80
TEMPERATURE (°C)
95 110 125
9.36
−40 −25 −10
60.0
526
59.9
525
59.8
59.7
59.6
59.5
59.4
59.3
59.2
59.1
−40 −25 −10
5
20 35 50 65 80
TEMPERATURE (°C)
20 35 50 65 80
TEMPERATURE (°C)
95 110 125
Figure 5. VCC(min) Threshold
Fmax, FREQUENCY (kHz)
Fmin, FREQUENCY (kHz)
Figure 4. VCC(on) Threshold
5
95 110 125
524
523
522
521
520
519
518
−40 −25 −10
Figure 6. FSW(min) Frequency Clamp
5
20 35 50 65 80
TEMPERATURE (°C)
95 110 125
Figure 7. FSW(max) Frequency Clamp
0.284
21.6
0.283
21.1
0.282
0.281
Vfb_fault (V)
RFB (kW)
20.6
20.1
19.6
19.1
0.28
0.279
0.278
0.277
18.6
0.276
18.1
0.275
17.6
−40 −25 −10
5
20 35 50 65 80
TEMPERATURE (°C)
95 110 125
0.274
−40 −25 −10
Figure 8. Pulldown Resistor (RFB)
5
20 35 50 65 80
TEMPERATURE (°C)
95 110 125
Figure 9. FB Fault Reference (Vfb_Fault)
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8
NCP1398B/C
TYPICAL CHARACTERISTICS
18
9.5
17
9
16
8.5
8
ROL (W)
ROH (W)
15
14
13
12
7
6.5
6
11
5.5
10
5
9
−40 −25 −10
5
20
35
50
65
80
4.5
−40 −25 −10
95 110 125
5
20
35
50
65
80
95 110 125
TEMPERATURE (°C)
TEMPERATURE (°C)
Figure 10. Source Resistance (ROH)
Figure 11. Sink Resistance (ROL)
104
303
102
302
100
301
Tdead_non (ns)
Tdead_min (ns)
7.5
98
96
300
299
94
298
92
297
90
−40 −25 −10
5
20
35
50
65
80
95 110 125
296
−40 −25 −10
5
20
35
50
65
TEMPERATURE (°C)
TEMPERATURE (°C)
Figure 12. Tdead(min)
Figure 13. Tdead(nom)
1855
80
95 110 125
80
95 110 125
4.03
1850
4.025
4.02
1840
Vlatch (V)
Tdead_max (ms)
1845
1835
1830
4.015
4.01
1825
4.005
1820
1815
−40 −25 −10
5
20
35
50
65
80
95 110 125
4
−40 −25 −10
5
20
35
50
65
TEMPERATURE (°C)
TEMPERATURE (°C)
Figure 14. Tdead(max)
Figure 15. Latch Level (Vlatch)
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NCP1398B/C
TYPICAL CHARACTERISTICS
0.9992
1.034
0.999
1.033
0.9988
1.032
0.9986
Vtimer_OFF (V)
VBO (V)
1.031
1.030
1.029
1.028
1.027
0.9982
0.998
0.9978
0.9976
0.9974
1.026
0.9972
1.025
−40 −25 −10
5
20
35
50
65
80
95 110 125
0.997
−40 −25 −10
5
35
50
65
80
95 110 125
TEMPERATURE (°C)
Figure 16. Brown−Out Reference (VBO)
Figure 17. Fault tmr. Reset Voltage (Vtimer(off))
4.045
4.04
196
4.035
Vtimer_ON (V)
194
192
190
188
4.03
4.025
4.02
4.015
4.01
4.005
186
4
184
−40 −25 −10
5
20
35
50
65
80
95 110 125
3.995
−40 −25 −10
5
TEMPERATURE (°C)
20
35
50
65
80
95 110 125
TEMPERATURE (°C)
Figure 18. Ctimer Charging Current (Itimer)
Figure 19. Fault Timer Ending Voltage
(Vtimer(on))
8.70
1.0050
8.65
1.0045
8.60
VrefFault_OCP (V)
8.55
IBO (mA)
20
TEMPERATURE (°C)
198
Itimer (mA)
0.9984
8.50
8.45
8.40
8.35
8.30
8.25
8.20
8.15
−40 −25 −10
1.0040
1.0035
1.0030
1.0025
1.0020
1.0015
5
20
35
50
65
80
95 110 125
1.0010
−40 −25 −10
5
20
35
50
65
80
95 110 125
TEMPERATURE (°C)
TEMPERATURE (°C)
Figure 20. Brown−Out Hysteresis Current (IBO)
Figure 21. OCP Fault Reference
(Vref_Fault_OCP)
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10
NCP1398B/C
TYPICAL CHARACTERISTICS
1.494
1.492
Vref_latch_OCP (V)
1.49
1.488
1.486
1.484
1.482
1.48
1.478
1.476
1.474
−40 −25 −10
5
20
35
50
65
80
95 110 125
TEMPERATURE (°C)
Figure 22. OCP Latch Reference (Vref_latch_OCP)
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11
NCP1398B/C
APPLICATION INFORMATION
• Adjustable fault timer: When a fault is detected on the
The NCP1398 includes all necessary features to help
building a rugged and safe switch−mode power supply. The
below bullets detail the benefits brought by implementing
the NCP1398 controller:
• Wide frequency range: A high−speed Voltage Control
Oscillator allows an output frequency excursion from
50 kHz up to 750 kHz on Mlower and Mupper outputs.
• User adjustable dead−time: Controller provides
possibility to adjust optimum dead−time based on
application parameters. The dead−time is modulated
from this adjusted value with operating frequency i.e.
dead−time period is reducing when frequency goes up.
• Adjustable soft−start: Every time the controller starts
to operate (power on), the switching frequency is
pushed to the programmed starting value that is defined
by external components connected to Rt pin. Frequency
then slowly moves down toward the minimum
frequency, until the feedback loop closes. The Rt pin
discharges the Soft Start capacitor before any IC restart
except the restart from skip mode.
• Adjustable minimum and maximum frequency
excursion: Due to a single external resistor, the
designer can program lowest frequency point, obtained
in lack of feedback voltage (at the end of the startup
sequence or under overload conditions). Internally
trimmed capacitors offer a ±3% precision on the
selection of the minimum switching frequency. The
adjustable upper frequency clam being less precise to
±6%.
• Brown−Out detection: To avoid operation from a low
input voltage, it is interesting to prevent the controller
from switching if the high−voltage rail is not within the
right boundaries. Also, when teamed with a PFC
front−end circuitry, the brown−out detection can ensure
a clean start−up sequence with soft−start, ensuring that
the PFC is stabilized before energizing the resonant
tank. The BO input features an 8.5 mA hysteresis
current to assure the lowest consumption from the
sensed bulk voltage input.
•
•
•
•
OLP input or when the FB path is broken, Ctimer pin
starts to charge an external capacitor. If the fault is
removed, the timer opens charging path and supply
continues in operation without any interruption. When
the timer reaches its selected duration (via a capacitor
on pin 2), all pulses are stopped. The controller now
waits for the discharge via an external resistor on pin 2
to issue a new clean startup sequence via soft−start.
Cumulative fault events: In the NCP1398, the timer
capacitor is not reset when the fault disappears. It
actually integrates the information and cumulates the
occurrences. A resistor placed in parallel with the
capacitor will offer a simple way to adjust the discharge
rate and thus the auto−recovery retry rate.
Overload protection: The overload input (OLP) is
specifically designed to protect LLC application during
overload or short circuit conditions. In case the voltage
on this input grows above first OLP threshold, the
Itimer current source is activated and Fault timer is
initiated. The discharge pin is activated in the same
time to increase operating frequency of the converter
and thus to limit primary current. The second OLP
threshold is implemented to stop the drivers fully in
case of critical fail. The controller then latches off
permanently until VCC goes below VCC_reset.
Skip cycle possibility: The NCP1398 features skip
cycle mode operation with adjustable hysteresis to
allow output regulation under light load or no−load
conditions while keeping high efficiency.
Open feedback loop detection − NCP1398B only:
Upon start-up or anytime during operation, when the
FB signal is missing, the fault timer starts to charge
timer capacitor. If the loop is really broken, the FB
level does not grow-up before the timer ends charging.
The controller then stops all pulses and waits until the
timer pin voltage collapses to 1 V typically before a
new attempt to re-start, via the soft-start. If the
optocoupler is permanently broken, a hiccup takes
place.
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NCP1398B/C
Voltage−Controlled Oscillator
switches between 50 kHz and 750 kHz. The VCO is
configured in such a way that if the feedback pin voltage
goes up, the switching frequency also goes up. Figure 23
shows internal architecture of the VCO.
The VCO section features a high−speed circuitry allowing
operation from 100 kHz up to 1.5 MHz. However, as a
division by two internally creates the two Q and /Q outputs,
the final effective signal on output Mlower and Mupper
VDD
Imin
SS disch.
I Fb
VDD
D
IFmax
Rt
sets Fmin
for Vfb < 1 V
Ict
ONtime
modulation
Vref
+
-
Ct
+
Idt
RDT
DT
+
Vref
+
−
S
Q
R
Q
Ct
VDD
Sets DT
Q
Clk Q
I Rt + I Fb
To skip
I Fmax comparator
Vref
+
Fmax
A
+
-
Sets max.
F
clamp
SW
VCC
B
to DRV logic
Vfb_min
+
-
FB fault
+
Vb_fault
FB
RFB
20 k
GND
Figure 23. The Simplified VCO Architecture
When designing a resonant SMPS the designer needs to
program the minimum and maximum switching frequencies
to assure correct and reliable operation. The minimum
switching frequency clamp adjustment accuracy is critical
because this parameter defines maximum power the
converter can deliver for given bulk voltage. The Fmin
parameter is thus trimmed to ±3% tolerance in the NCP1398
controller to assure application reproducibility in
manufacturing. The minimum frequency clamp, that is fully
user adjustable via a resistor connected to the Rt pin, is
reached when the feedback loop is not closed. It can happen
during the startup sequence, a strong output transient
loading or during short−circuit conditions.
The maximum operating frequency clamp, that is defined
by the value of resistor connected between Fmax pin and
GND, dictates the minimum output power that is needed to
maintain output voltage regulation. This parameter, adjusts
the threshold of when the part enters skip mode. Precision of
the Fmax clamp is thus guaranteed to ±12 %.
The operating frequency is modulated by the secondary
regulator via the FB pin in most applications. The frequency
changes between minimum (Fmin) and maximum (Fmax)
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NCP1398B/C
adjusted clamps when the FB volatge swigs from 1.1 V to
5.5 V – refer to Figure 24. The internal resistor pulls the FB
pin naturally down when the regulation loop is opened or if
the application is in overload. The FB fault comparator
initiates fault timer for NCP1398B version (refer to the Fault
Timer section on Page 21) once the FB pin voltage drops
below 0.28 V. By implementing this feature the NCP1398B
controller increases application safety by keeping it turned
off for a significant portion of time once an FB fault occurs.
If we take the default FB pin excursion numbers, 1.1 V −
50 kHz, 5.5 V − 750 kHz, then the VCO maximum slope will
be:
750k * 50k
+ 159 kHzńV
4.4
(eq. 1)
Figures 24 and 25 portray the frequency evolution
depending on the feedback pin voltage level for a different
frequency clamp combinations.
Figure 25. Here a Different Minimum Frequency Was
Programmed as Well as the Maximum Frequency
Clamp
Please note that the previous small−signal VCO slope
from Figure 24 has now been reduced to 300k / 4.4 =
68 kHz/V on Mupper and Mlower outputs. This offers a
mean to magnify the feedback excursion on systems where
the load range does not generate a wide switching frequency
excursion. Due to this option, it is possible to implement skip
cycle at light loads.
The selection of the three setting resistors Fmin,
dead−time and Fmax clamp) requires the usage of the
selection charts displayed below:
750
650
Figure 24. Maximal Default Excursion, Rt = 34.7 kW
on Fmin Pin and Rfmax = 7.2 kW on Fmin Pin
Fmax (kHz)
550
450
350
250
150
50
5
15
25
35
Rfmax (kW)
45
55
Figure 26. Maximum Switching Frequency Resistor
Selection Depending on the Adopted Minimum
Switching Frequency
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14
NCP1398B/C
500
stopping pulses), then it is possible to pull up the FB pin
using other sweeping loops than regular feedback. Several
diodes can easily be used to perform the job in case of
reaction to a fault event or to regulate on the output current
(CC operation). Figure 30 shows how to do implement this
technique.
450
Fmin (kHz)
400
350
300
Vcc
250
200
In1
150
100
3.5
In2
5.5
7.5
9.5
11.5
13.5
Rfmin (kW)
Fmin = 100 kHz to 500 kHz
20k
15.5
Figure 30. Due to the FB Configuration, Loop ORing
is Easy to Implement
Figure 27. Minimum Switching Frequency Resistor
Selection
The oscillator configuration used in this IC also offers an
easy way to connect additional pull down element (like
optocoupler or bipolar transistor) directly to the Rt pin to
modulate switching frequency if needed – refer to Figure 31.
100
90
80
Fmin (kHz)
VCO
FB
70
60
50
40
30
20
10
20
30
40
50
60
70
Rfmin (kW)
Fmin = 20 kHz to 100 kHz
80
Figure 31. Other Possibilities How to Modulate
Operating Frequency of the NCP1398 Using Direct
Connection to Rt Pin
90
Figure 28. Minimum Switching Frequency Resistor
Selection
Dead−Time Control
Dead−time control is an absolute necessity when the
half−bridge topology is used. The dead−time technique
consists of inserting a period during which both high and low
side switches are off. The needed dead−time amount
depends on several application parameters like:
magnetizing inductance, total parasitic capacitance of the
bridge and maximum operating frequency.
The needed dead−time (or off time for ZVS preparation)
is defined by RDT resistor connected between pin 6 and
GND. The dead−time can be adjusted from 100 ns to 2 ms –
refer to DT adjust characteristic in Figure 29. The dead−time
period is placed by dead−time generator in the beginning of
each on−time cycle – refer to Figure 2 and 32.
Note that external dead−time modulation is possible if
needed. This can be achieved similarly to operating
frequency modulation – refer to Figure 31 i.e. by injecting
or pulling out current into DT pin.
Figure 29. Dead−Time Clamp Resistor Selection
ORing Capability
If for any particular reason, there is a need for a frequency
variation linked to an event appearance (instead of abruptly
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NCP1398B/C
VDD
from on−time
generator
Icharge
D
+
DT
Vref
Clk
−
Ct
+
RDT
Q
Q
S
Q
R
Q
A
B
to DRV logic
GND
Figure 32. Dead−Time Generation
Soft−Start Sequence
Please note that the soft−start and OCP capacitors are
discharged before following sequences:
• startup sequence
• auto−recovery burst mode
• brown−out recovery
• temperature shutdown recovery
• recovery from disable mode if Vfb < Vfb_fault
The skip mode undergoes a special treatment. Since we
want to implement skip cycle we cannot activate the
soft−start every time when the controller stops the
operations in low power mode. Therefore, no soft−start
occurs when controller returns from skip mode to offer the
best skip cycle behavior. However, it is very possible to
combine skip cycle and true disable modes e.g. by driving
Skip/disable pin by external current to disable controller
operation. In that case, if a disable signal maintains the
skip/disable input activated long enough to bring the
feedback level down (below Vfb_fault level), then the
soft−start discharge is activated.
D
In resonant controllers, a soft−start is needed to avoid
applying the full current suddenly into the resonant circuit.
The soft−start duration is fully adjustable using external
components on this controller. There are normally two RC
networks connected to the Rt pin when using NCP1398 –
refer to Figure 33. The first network, formed by Rss and Css,
is used to program main soft−start period duration. This
soft−start period usually lasts from 5 ms to 10 ms, depends
on application. The second RC network, formed by Rocp
and Cocp components, is implemented to prepare overload
protection via discharge pin when OLP input detects fault.
The time constant of this RC network is usually selected to
< 1 ms to assure fast enough transient response of the OLP
system. It should be noted that both RC networks are
discharged before application startup thus the “dual
soft−start” sequence is present in the application. The startup
frequency is given by parallel combination of Rocp, Rss and
Rt resistors. The Cocp capacitor then charges in relatively
short time so the regular soft−start continues until the Css
capacitor charges to Vref_Rt level. As the soft−start
capacitor charges up, the frequency smoothly decreases
down, towards adjusted Fmin clamp. Of course, practically,
the feedback loop is supposed to take over the VCO lead as
soon as the output voltage has reached the target. If not, then
the minimum switching frequency is reached and a fault is
detected on the feedback and OLP pins.
The Rt pin is held low when controller is disabled, except
in skip mode. The Css and Cocp capacitors are thus
discharged before new restart. The Css capacitor is
discharging via Rss resistor thus some minimum off time is
needed before restart to assure correct soft−start. Optional
discharge diode Ddis can be used between Css capacitor and
Rt pin in applications where short restart period is required.
Rdicharge
Discharge
Rt
GND
Rocp
Rss
Ddis
Cocp
Rt
NCP1398
Css
Figure 33. Soft−Start and OLP Components
Arrangement
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NCP1398B/C
designed bulk voltage level would result in current
overstress of converter primary power stage. The NCP1398
offers Brown−Out input (BO) that allows for precise bulk
voltage turn−on and turn−off levels adjustment. The internal
circuitry, depicted by Figure 35, offers a way to observe the
high−voltage (Vbulk) rail. A high−impedance resistive
divider made of Rupper and Rlower, brings a portion of the
Vbulk rail to BO pin. The Current sink (IBO) is active below
the Vbulk turn−on level. Therefore, the turn−on level is
higher than the one given by the division ratio of resistive
divider. To the contrary, when the internal BO_OK signal is
high, i.e. application is running, the IBO sink is disabled.
The Vbulk turn−off level is thus given by BO comparator
reference voltage and resistor divider ratio only. Advantage
of this solution is that the Vbulk turn−off level reaches
minimum error. This error is given only by VBO reference
and resistor divider precisions and is not affected by IBO
hysteresis current tolerance. The NCP1398 thus allows
better resonant tank optimization.
Figure 34. A Typical Start−up Sequence on a LLC
Converter Using NCP1398
Brown−Out Protection
The resonant tank of an LLC converter is always designed
for specific input voltage range. Operation below minimum
Vbulk
IBO
Rupper
BO
+
−
Rlower
20
s
lter
BO_OK
+
VBO
UVLO
Figure 35. The Internal Brown−out Input Configuration
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NCP1398B/C
The turn−on and turn−off levels can be calculated using below equations:
IBO is on
V BO ) V BOhyst + V bulk_ON @
R lower
R lower ) R upper
* IBO @
ǒ
R lower @ R upper
Ǔ
R lower ) R upper
(eq. 2)
IBO is off
V BO + V bulk_OFF @
R lower
(eq. 3)
R lower ) R upper
We can extract Rlower from Equation 3 and plug it into Equation 2, then solve for Rupper:
Vbulk_ON@VBO
R lower +
Vbulk_OFF
ǒ
* V BO * V BOhyst
IBO @ 1 *
R upper + R lower @
VBO
Vbulk_OFF
(eq. 4)
Ǔ
V bulk_OFF * V BO
(eq. 5)
V BO
If we decide to turn−on our converter for Vbulk_ON equal
to 400 V and turn it off for Vbulk_OFF equal to 350 V, then for
IBO = 8.5 mA, VBOhyst = 10 mV and VBO = 1.008 V we
obtain:
the other hand, the high impedance divider could be noise
sensitive due to capacitive coupling to HV switching traces
in the application. Thus the 20 ms filter is added after the BO
comparator to increase noise immunity. Despite the internal
filter, it is recommended to keep correct layout for BO
divider resistors and use external filtering capacitor on BO
pin if one wants to achieve precise BO detection.
Rupper = 5.47 MW
Rlower = 15.81 kW
Figure 36 simulation results confirms our calculations.
The power dissipation for Vbulk = 325 Vdc (i.e. for the
case the PFC and LLC stages are off but bulk is still
connected to rectified 230 Vac mains – like in standby mode)
can be calculated as: 3252 / 5.516 MW = 19 mW.
Note that the BO pin is pulled down by internal switch
until the VCC−on level is available on pin 10. This feature
assures that the BO pin won’t charge up before IC starts
operation. The IBO hysteresis current sink is activated and
BO discharge switch disabled once the VCC crosses
VCC_on threshold. The BO pin voltage then ramps up
naturally according to BO divider information. The BO
comparator then authorizes operation or not – depends on
the Vbulk level.
Small IBO hysteresis current of the NPC1398 allows
increasing the BO divider resistance and thus reducing
application power consumption during standby mode. On
Figure 36. Simulation Results for Calculated BO
Adjustment
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NCP1398B/C
VCC
Vbulk
5 ms
+
−
Q1
+
Vout
Rupper
+
−
Rlower
To permanent
latch
Vlatch
IBO
BO
NTC
RC
20 ms
Filter
BO_OK
+
VBO
UVLO
Figure 37. Adding a Comparator on the BO Pin Offers a Way to Latch−off the Controller
Latch−off Protection
OCP network can be omitted in some applications where the
Soft Start capacitor with low capacitance is used. The Rshift
resistor is then connected directly to the Soft Start capacitor
to implement frequency shift during overload.
Overload protection system implemented on OLP input
composes of three particular subsystems with following
functionality:
1. The fault timer charging current is activated when
the OLP input voltage exceeds 1 V threshold. The
controller stops operation and enters
auto−recovery phase when the overload conditions
last for longer time than the adjusted fault timer
duration on Ctimer pin (Ct charged to 4 V). The
controller then places full restart (including soft
start) when auto−recovery period elapses i.e. when
Ctimer capacitor discharges back below 1 V.
2. The second overload protection mode is activated
additionally to the first one i.e. when the OLP pin
voltage exceeds 1 V. The frequency shift is
implemented via Rt and Discharge pins in this case
by pulling the discharge switch down from
Vref_Rt to ground – refer also to Figure 38 for
Vdisable evaluation with OLP input voltage. The
Discharge pin is connected to the Rocp and Cocp
network, that is present on the Rt pin, via resistor
Rshift. This configuration allows to adjust OCP
frequency shift depth and reaction time and thus
ease overload system implementation in any
application.
The Rt pin OCP components are normally
designed in such a way that the OCP system shifts
and regulates the operating frequency of the LLC
converter during overload or secondary side short
circuit conditions to maintain primary current at a
save level and keep zero voltage switching
operation.
There are some situations under which should be the
converter fully turned−off and stay latched. This can happen
in presence of an over−voltage (the feedback loop is
drifting) or when an over temperature is detected. Due to the
addition of a comparator on the BO pin, a simple external
circuit can lift up this pin above VLATCH (4 V typical) and
permanently disable pulses. The VCC pin voltage needs to
be cycled down below 6.6 V typically to reset the controller.
On Figure 37, Q1 is blocked and does not bother the BO
measurement as long as the NTC and the optocoupler are not
activated. As soon as the secondary optocoupler senses an
OVP condition, or the NTC reacts to a high ambient
temperature, Q1 base is pulled down to ground and the BO
pin goes up, permanently latching off the controller.
Overload Protection
This resonant controller features a proprietary overload
protection system that assures application power stage
safety under all possible fault conditions. This system
consists of an OLP input for primary current sensing and a
Discharge pin to enable a controlled frequency shift via the
Rt pin once an overload condition occurs. Internal block
diagram of the overload system with a typical application
connection can be seen in Figures 39 and 40.
The primary current is sensed indirectly using charge
pump (R1, R2, D1, D2, C1 and C2) connected between
resonant capacitor and OLP input. When the primary current
increases, the voltage on the OLP input grows up as well. It
should be noted that other primary current sensing methods
(like current sense transformer) can be used instead of
charge pump if required by application.
The OCP network (Rshift, Rocp, Cocp), that is present on
the Rt pin in addition to the Fmin adjust resistor and Soft
Start network, plays important role in overload system
implementation. This additional network is used to allow
independent OCP and Soft Start parameters adjustment. The
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NCP1398B/C
3. The third overload protection is activated in case
the OLP pin voltage exceeds 1.5 V threshold. This
can happen during secondary side short circuit
event or in case the adjusted frequency shift is not
sufficient to limit primary current or the OCP
network on RT pin fails (like open Soft Start pin
event). The IC then stops operation after 1 ms
delay to overcome excessive overloading of the
power stage components. Both controller version
i.e. NCP1398B and also NCP1398C latch fully off
and keep the latched state until the VCC drops
down below VCC reset level.
Figure 38. OLP to Discharge Pin Transfer
Characteristic
Discharge
Rshift
Rocp
Rss
Cocp
Css
Rt
Rt
VDD
Itimer
+
−
Vref_latch
OCP
1 us
RC
filter
To DRV logic,
VCO and Vcc
management
Ctimer
Ct
Rt
+
OCP
fault
Vref_fault
OCP
To latch
Fault
timer
logic
+
+
C2
−
R2
OLP
+
To resonant
capacitor
D2
D1
−
C1 R1
VtimerON/
VtimerOFF
+
GND
Figure 39. Overload Protection Input Connection NCP1398C − Fault Timer is Not Activated when FB Fault is
Present
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NCP1398B/C
Discharge
Rshift
Rocp
Rss
Cocp
Rt
Rt
FB fault
Css
VDD
Itimer
+
−
Vref_latch
OCP
1 us
RC
filter
To DRV logic,
VCO and Vcc
management
Ct
Rt
+
OCP
fault
Vref_fault
OCP
To latch
Ctimer
Fault
timer
logic
+
+
C2
−
R2
OLP
+
To resonant
capacitor D2
D1
−
C1 R1
VtimerON/
VtimerOFF
+
GND
Figure 40. Overload Protection Input Connection NCP1398B
Fault Timer
remains present in the application (overload conditions or
secondary side short circuit). The Fault timer is from the
principle of operation a cumulative type of timer i.e. the
Ctimer pin voltage integrates if there are multiple faults
coming during short time period – refer to Figure 41.
The fault timer can be initiated by several fault sources:
1st – when feedback voltage drops below VFB_fault
threshold. This could happen when the FB loop is opened i.e.
during secondary regulator or optocoupler fail or open FB
pin events. Note that the fault timer is not activated by FB
fault detection circuitry for NCP1398C version.
2nd − when the OLP input voltage exceeds Vref_Fault_OCP
threshold. This situation happens during overload. The fault
timer is activated on both IC versions in this case.
The NCP1398 implements fault timer with fully
adjustable fault and auto−recovery periods – refer to
Figure 40 in OLP section. External capacitor Ct is used in
combination with internal current source and voltage
comparator to implement this function. Once the fault
condition occurs the Ctimer pin sources current (Itimer)
which charges Ct capacitor. The fault is confirmed and
drivers are disabled once the Ctimer pin voltage exceeds
Vtimer_off threshold. The Itimer current source is then
disabled and Ct capacitor discharges via parallel resistor Rt.
Controller places new try for restart (featuring Soft Start)
once the Ctimer pin voltage drops below Vtimer_ON
threshold. Controller will work in hiccup mode, repeating
fault and auto−recovery sequences, if the fault condition
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NCP1398B/C
Figure 41. Ctimer Pin Voltage Evaluation When Multiple Faults Occur During Short Time Period
Skip/Disable
– like standby. The NCP1398 controller allows for skip−in
and also skip−out frequency adjustment. User has thus
possibility to control output voltage ripple during skip mode
and by this way also affect no−load consumption of the
whole power stage.
The Skip/Disable input (refer to Figure 42) together with
Fmax adjust pin offer possibility to implement burst mode
operation during light load conditions or just simply disable
LLC stage operation using signal coming from other system
VDD
Vcc
Skip
I Rt + IFB
I Fmax
1 s
RC filter
OK2
Disable
goes high when IRt+IFB > IFmax
goes low when IRt+IFB < Iskip out
Skip cmp.
To
DRV logic
I skip out
Rdisable
Skip/Disable
Vref
Disable
to DRV logic
Idisable
Rskip
FB fault
OCP fault
GND
Figure 42. Skip/Disable Input Connection
of 10 ms is placed by the NCP1398 before restarting from
skip mode. Note that skip function is disabled in case the FB
or OCP faults are present in the application. Operating
frequency of the controller can be thus increased above
adjusted maximum on the Fmax pin during soft start period
and overload conditions.
In addition to the skip−out threshold adjustment, the
Skip/Disable pin will disable the drivers in case its current
drops below Idisable threshold (12 mA typically). This
feature is implemented to provide user with possibility to
use this pin as a disable input. Application can thus be simply
disabled by injecting current into the pin from external
circuitry (like optocoupler in Figure 42 example).
The skip−in frequency threshold is given by the Fmax pin
resistor. The skip−out frequency threshold is then given by
the current flowing out from the Skip/Disable pin. The
skip−out adjust characteristic is identical with the Fmax
adjust characteristic – refer to Figure 26.
Controller turns−off the drivers once the internal current,
that is given by sum of IRt and IFb currents, exceeds current
adjusted by Fmax pin resistor. The FB pin voltage then
naturally drops down thanks to the secondary regulator
action. The NCP1398 enable drivers once the internal
current IRt+IFb drops below level adjusted on the
Skip/Disable pin. User has thus possibility of skip mode
hysteresis adjustment and thus application no−load
consumption optimization. Note that minimum restart delay
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NCP1398B/C
There is implemented internal 1 us RC network on the
Skip input in order to filter out noise that can be created by
power stage and driver currents on the GND bonding and
layout parasitic inductances.
The High−Voltage Driver
The driver features a traditional bootstrap circuitry,
requiring an external high−voltage diode for the capacitor
refueling path. Figure 44 shows the internal architecture of
the high−voltage section.
Figure 43. Typical Skip Mode Operation During Light
Load Conditions When Using NCP1398 Resonant
Controller
Figure 44. The Internal High−Voltage Section of the NCP1398B/C
The device incorporates an upper UVLO circuitry that
makes sure enough Vgs is available for the upper side
MOSFET. The A and B outputs are delivered by the internal
DRV and fault logic refer to Figures 2 and 3. A delay is
inserted in the lower rail to ensure good matching between
these propagating signals.
As stated in the maximum ratings section, the floating
portion can go up to 600 VDC and makes the IC perfectly
suitable for offline applications featuring a 400 V PFC
front−end stage.
ORDERING INFORMATION
Package
Shipping†
NCP1398BDR2G
SOIC−16, Less Pin 13
(Pb−Free)
2500 / Tape & Reel
NCP1398CDR2G
SOIC−16, Less Pin 13
(Pb−Free)
2500 / Tape & Reel
Device
†For information on tape and reel specifications, including part orientation and tape sizes, please refer to our Tape and Reel Packaging
Specification Brochure, BRD8011/D.
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NCP1398B/C
PACKAGE DIMENSIONS
SOIC−16 NB, LESS PIN 13
CASE 751AM
ISSUE O
D
16
A B
9
E
H
0.25
M
B
M
1
8
e
15X
C
b
C
L
15X
0.25
M
T A
S
B
DIM
A
A1
b
C
D
E
e
H
h
L
M
S
A1
SEATING
PLANE
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
0.13 TOTAL IN EXCESS OF THE b DIMENSION AT
MAXIMUM MATERIAL CONDITION.
4. DIMENSIONS D AND E DO NOT INCLUDE MOLD
PROTRUSIONS.
5. MAXIMUM MOLD PROTRUSION 0.15 PER SIDE.
h x 45 _
A
M
MILLIMETERS
MIN
MAX
1.35
1.75
0.10
0.25
0.35
0.49
0.19
0.25
9.80
10.00
3.80
4.00
1.27 BSC
5.80
6.20
0.25
0.50
0.40
1.25
0_
7_
SOLDERING FOOTPRINT*
6.40
15X
1
1.12
16
15X
0.58
1.27
PITCH
8
9
DIMENSIONS: MILLIMETERS
*For additional information on our Pb−Free strategy and soldering
details, please download the ON Semiconductor Soldering and
Mounting Techniques Reference Manual, SOLDERRM/D.
ON Semiconductor and
are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC owns the rights to a number of patents, trademarks,
copyrights, trade secrets, and other intellectual property. A listing of SCILLC’s product/patent coverage may be accessed at www.onsemi.com/site/pdf/Patent−Marking.pdf. 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 its patent rights nor the rights of others. SCILLC products are not designed, intended, or authorized for use as components in systems intended for
surgical implant into the body, or other applications intended to support or sustain life, or for any other application in which the failure of the SCILLC product could create a situation where
personal injury or death may occur. Should Buyer purchase or use SCILLC products for any such unintended or unauthorized application, Buyer shall indemnify and hold SCILLC and
its officers, employees, subsidiaries, affiliates, and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly,
any claim of personal injury or death associated with such unintended or unauthorized use, even if such claim alleges that SCILLC was negligent regarding the design or manufacture
of the part. SCILLC is an Equal Opportunity/Affirmative Action Employer. This literature is subject to all applicable copyright laws and is not for resale in any manner.
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