Dialog IW1696-03 Low-power off-line digital green-mode pwm controller Datasheet

iW1696
Low-Power Off-line Digital Green-Mode PWM Controller
1.0 Features
2.0 Description
●● Primary-side feedback eliminates opto-isolators and
simplifies design
●● Adaptive multi-mode PWM/PFM control improves
efficiency
●● Quasi-resonant operation for highest overall efficiency
●● EZ-EMI ® design to easily meet global EMI standards
●● Direct drive of low-cost BJT switch
●● Dynamic base current control
●● Very tight constant voltage and constant current
regulation with primary-side-only feedback
●● No external compensation components required
●● Complies with EPA 2.0 energy-efficiency specifications
with ample margin
●● Able to meet < 30 mW no load power consumption
●● Low start-up current (10 μA typical)
●● Built-in soft start
●● Built-in short circuit protection and output overvoltage
protection
●● Built-in current sense resistor short protection
The iW1696 is a high performance AC/DC power supply
controller which uses digital control technology to build peak
current mode PWM flyback power supplies. The device
directly drives a power BJT and operates in quasi-resonant
mode to provide high efficiency along with a number of key
built-in protection features while minimizing the external
component count, simplifying EMI design and lowering the
total bill of material cost. The iW1696 removes the need
for secondary feedback circuitry while achieving excellent
line and load regulation. It also eliminates the need for loop
compensation components while maintaining stability overall
operating conditions. Pulse-by-pulse waveform analysis
allows for a loop response that is much faster than traditional
solutions, resulting in improved dynamic load response. The
built-in power limit function enables optimized transformer
design in universal off-line applications and allows for a wide
input voltage range.
The ultra-low start-up power and operating current at light
load ensure that the iW1696 is ideal for applications targeting
the newest regulatory standards for average efficiency.
3.0 Applications
●● Low power AC/DC adapter/chargers for cell phones,
PDAs, digital still cameras
●● No audible noise over entire operation range
●● Linear AC/DC replacement
L
+
+
N
VOUT
GND
U1
iW1696
1
VCC
2
GND
3
VSENSE
OUTPUT
5
ISENSE
4
Figure 3.1: iW1696 Typical Application Circuit
Rev. 2.0
iW1696
February 13, 2012
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iW1696
Low-Power Off-line Digital Green-Mode PWM Controller
4.0 Pinout Description
iW1696
Pin #
Name
Type
1
VCC
Power Input
2
GND
Ground
3
VSENSE
4
ISENSE
5
OUTPUT
1
VCC
2
GND
3
VSENSE
OUTPUT
5
ISENSE
4
Pin Description
Power supply for control logic.
Ground.
Analog Input Auxiliary voltage sense (used for primary regulation).
Analog Input Primary current sense. Used for cycle-by-cycle peak current control and limit.
Output
Base drive for BJT.
5.0 Absolute Maximum Ratings
Absolute maximum ratings are the parameter values or ranges which can cause permanent damage if exceeded. For
maximum safe operating conditions, refer to Electrical Characteristics in Section 6.0.
Parameter
Symbol
Value
Units
DC supply voltage range (pin 1, ICC = 20mA max)
VCC
-0.3 to 18
V
Continuous DC supply current at VCC pin (VCC = 15 V)
ICC
20
mA
Output (pin 5)
-0.3 to 4.0
V
VSENSE input (pin 3, IVsense ≤ 10 mA)
-0.7 to 4.0
V
ISENSE input (pin 4)
-0.3 to 4.0
V
TJ MAX
125
°C
Storage temperature
TSTG
–65 to 150
°C
Lead temperature during IR reflow for ≤ 15 seconds
TLEAD
260
°C
θJA
190
°C/W
ESD rating per JEDEC JESD22-A114
2,000
V
Latch-Up test per JEDEC 78
±100
mA
Maximum junction temperature
Thermal Resistance Junction-to-Ambient
Rev. 2.0
iW1696
February 13, 2012
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iW1696
Low-Power Off-line Digital Green-Mode PWM Controller
6.0 Electrical Characteristics
VCC = 12 V, -40°C ≤ TA ≤ +85°C, unless otherwise specified (Note 1)
Parameter
Symbol
Test Conditions
Min
Typ
Max
Unit
1
μA
1.553
V
VSENSE SECTION (Pin 3)
Input leakage current
IBVS
VSENSE = 2 V
Nominal voltage threshold
VSENSE(NOM)
TA=25°C, negative edge
1.523
1.538
Output OVP threshold -00
VSENSE(MAX)
TA=25°C, negative edge
1.834
V
Output OVP threshold -01 (Note 2)
VSENSE(MAX)
TA=25°C, negative edge
Load = 100 %
1.926
V
Output OVP threshold -03 (Note 2)
VSENSE(MAX)
TA=25°C, negative edge
Load = 100 %
1.972
V
Output OVP threshold -04 (Note 2)
VSENSE(MAX)
TA=25°C, negative edge
Load = 100 %
1.880
V
ISENSE SECTION (Pin 4)
VOCP
1.1
ISENSE regulation upper limit (Note 2)
VIPK(HIGH)
1.0
V
ISENSE regulation lower limit (Note 2)
VIPK(LOW)
0.25
V
Overcurrent threshold
Input leakage current
ILK
ISENSE = 1.0 V
1.15
V
1
μA
6.0
W
OUTPUT SECTION (Pin 5)
Output low level ON-resistance
Switching frequency
(Note 3)
RDS(ON)LO
ISINK = 5 mA
3
fSW
> 50% load
40
kHz
VCC SECTION (Pin 1)
Maximum operating voltage (Note 2)
VCC(MAX)
Start-up threshold
VCC(ST)
VCC rising
11
Undervoltage lockout threshold
VCC(UVL)
VCC falling
5.2
Start-up Current
IIN(ST)
VCC = 10 V
Quiescent current
ICCQ
No IB current
Zener breakdown voltage
VZB
Zener current = 1 mA
TA=25°C
18
16
V
12
13
V
5.5
5.8
V
8
15
μA
2.5
3.5
mA
19
20.5
V
Notes:
Note 1. Adjust VCC above the start-up threshold (VCC(ST)) before setting at 12 V.
Note 2. These parameters are not 100% tested, guaranteed by design and characterization.
Note 3. Operating frequency varies based on the load conditions, see Theory of Operation for more details.
Rev. 2.0
iW1696
February 13, 2012
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iW1696
Low-Power Off-line Digital Green-Mode PWM Controller
7.0 Typical Performance Characteristics
12.20
VCC Start-up Threshold (V)
5.58
VCC UVLO (V)
5.54
5.50
5.46
5.42
5.38
-50
-25
0
25
50
75
100
125
Ambient Temperature (ºC)
Figure 7.1 : VCC UVLO vs. Temperature
11.90
11.80
-25
0
25
50
75
100
Ambient Temperature (ºC)
125
150
Figure 7.2 : Start-Up Threshold vs. Temperature
2.010
Internal Reference Voltage (V)
fsw @ Load > 50% (kHz)
12.00
11.70
-50
150
44
42
40
38
36
34
-50
-25
0
25
50
75
100
Ambient Temperature (ºC)
125
150
Figure 7.3 : Switching Frequency vs. Temperature1
VCC Supply Start-up Current (µA)
12.10
2.006
2.002
1.998
1.994
1.990
-50
-25
0
25
50
75
100
Ambient Temperature (ºC)
125
150
Figure 7.4 : Internal Reference vs. Temperature
10.0
8.0
6.0
4.0
2.0
0.0
0.0
3.5
7.0
VCC (V)
10.5
14.0
Figure 7.5 : VCC vs. VCC Supply Start-up Current
Notes:
Note 1. Operating frequency varies based on the load conditions, see Theory of Operation for more details.
Rev. 2.0
iW1696
February 13, 2012
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iW1696
Low-Power Off-line Digital Green-Mode PWM Controller
8.0 Functional Block Diagram
1 VCC
Start-up
Enable
VSENSE 3
Signal
Conditioning
BJT
Base
Drive
Digital
Logic
Control
VFB
5 Output
OCP
GND
2
VSENSE(NOM)
= 1.538 V
DAC
IPK
1.1 V
4 ISENSE
VIPK
Figure 8.1: iW1696 Functional Block Diagram
9.0 Theory of Operation
The iW1696 is a digital controller which uses a new,
proprietary primary-side control technology to eliminate the
opto-isolated feedback and secondary regulation circuits
required in traditional designs. This results in a low-cost
solution for low power AC/DC adapters. The core PWM
processor uses fixed-frequency Discontinuous Conduction
Mode (DCM) operation at higher power levels and switches
to variable frequency operation at light loads to maximize
efficiency. Furthermore, iWatt’s digital control technology
enables fast dynamic response, tight output regulation, and
full featured circuit protection with primary-side control.
Referring to the block diagram in Figure 8.1, the digital logic
control block generates the switching on-time and off-time
information based on the output voltage and current feedback
signal and provides commands to dynamically control the
external BJT base current. The system loop is automatically
compensated internally by a digital error amplifier. Adequate
system phase margin and gain margin are guaranteed by
design and no external analog components are required for
loop compensation. The iW1696 uses an advanced digital
control algorithm to reduce system design time and increase
reliability.
Rev. 2.0
Furthermore, accurate secondary constant-current operation
is achieved without the need for any secondary-side sense
and control circuits.
The iW1696 uses adaptive multi-mode PWM/PFM control
to dynamically change the BJT switching frequency for
efficiency, EMI, and power consumption optimization. In
addition, it achieves unique BJT quasi-resonant switching to
further improve efficiency and reduce EMI. Built-in protection
features include overvoltage protection (OVP), output short
circuit protection (SCP), over current protection (OCP),
single pin fault protection and ISENSE fault detection.
iWatt’s digital control scheme is specifically designed to
address the challenges and trade-offs of power conversion
design. This innovative technology is ideal for balancing new
regulatory requirements for green mode operation with more
practical design considerations such as lowest possible cost,
smallest size and high performance output control.
iW1696
February 13, 2012
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iW1696
Low-Power Off-line Digital Green-Mode PWM Controller
9.1 Pin Detail
Start-up
Sequencing
Pin 1 – VCC
VCC(ST)
Power supply for the controller during normal operation. The
controller will start up when VCC reaches 12 V (typical) and
will shut-down when the VCC voltage is 5.5 V (typical). A
decoupling capacitor should be connected between the VCC
pin and GND.
Pin 2 – GND
VCC
ENABLE
Ground.
Pin 3 – VSENSE
Sense signal input from auxiliary winding. This provides the
secondary voltage feedback used for output regulation.
Pin 4 – ISENSE
Primary current sense. Used for cycle-by-cycle peak current
control and limit.
Pin 5 – OUTPUT
Base drive for the external power BJT switch.
Figure 9.1: Start-up Sequencing Diagram
9.3 Understanding Primary Feedback
Figure 9.2 illustrates a simplified flyback converter. When the
switch Q1 conducts during tON(t), the current ig(t) is directly
drawn from rectified sinusoid vg(t). The energy Eg(t) is stored
in the magnetizing inductance LM. The rectifying diode D1
is reverse biased and the load current IO is supplied by the
secondary capacitor CO. When Q1 turns off, D1 conducts
and the stored energy Eg(t) is delivered to the output.
iin(t)
9.2 Start-up
Prior to start-up, the Vcc pin is charged typically through startup resistors. When VCC bypass capacitor is fully charged
to a voltage higher than the start-up threshold VCC(ST), the
ENABLE signal becomes active to enable the control logic,
and the iW1696 commences soft start function. An adaptive
soft-start control algorithm is applied at startup state, during
which the initial output pulses will be small and gradually get
larger until the full pulse width is achieved. The peak current
is limited cycle by cycle by the IPEAK comparator.
If at any time the VCC voltage drops below VCC(UVL) threshold
then all the digital logic is reset. At this time ENABLE signal
becomes low and the VCC capacitor is charged up again
towards the start-up threshold.
+
ig(t)
id(t)
N:1
D1
vg(t)
vin(t)
VO
+
CO
IO
VAUX
–
TS(t)
Q1
Figure 9.2: Simplified Flyback Converter
In order to tightly regulate the output voltage, the information
about the output voltage and load current need to be accurately
sensed. In the DCM flyback converter, this information can
be read via the auxiliary winding or the primary magnetizing
inductance (LM). During the Q1 on-time, the load current
is supplied from the output filter capacitor CO. The voltage
across LM is vg(t), assuming the voltage dropped across Q1
is zero. The current in Q1 ramps up linearly at a rate of:
dig ( t )
dt
=
vg ( t )
LM
(9.1)
At the end of on-time, the current has ramped up to:
Rev. 2.0
iW1696
February 13, 2012
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iW1696
Low-Power Off-line Digital Green-Mode PWM Controller
vg ( t ) × tON
LM
(9.2)
This current represents a stored energy of:
9.4 Constant Voltage Operation
LM
2
× ig _ peak ( t )
2
(9.3)
When Q1, turns off at tO, ig(t) in LM forces a reversal of
polarities on all windings. Ignoring the communication-time
caused by the leakage inductance LK at the instant of turn-off
tO, the primary current transfers to the secondary at a peak
amplitude of:
id =
(t )
NP
× ig _ peak ( t )
NS
(9.4)
Assuming the secondary winding is master, and the auxiliary
winding is slave,
1 VAUX = VO x
VAUX
NS
9.5 Constant Current Operation
To achieve this regulation the iW1696 senses the load
current indirectly through the primary current. The primary
current is detected by the ISENSE pin through a resistor from
the BJT emitter to ground.
NAUX
NP
VNOM
Figure 9.3: Auxiliary Voltage Waveforms
The auxiliary voltage is given by:
VAUX
=
If no voltage is detected on VSENSE it is assumed that the
auxiliary winding of the transformer is either open or shorted
and the iW1696 shuts down.
The constant current (CC mode) is useful in battery charging
applications. During this mode of operation the iW1696 will
regulate the output current at a constant level regardless of
the output voltage, while avoiding continuous conduction
mode.
NAUX
0V
2 VAUX = -VIN x
After soft-start has been completed, the digital control block
measures the output conditions. It determines output power
levels and adjusts the control system according to a light
load or heavy load. If this is in the normal range, the device
operates in the Constant Voltage (CV) mode, and changes
the pulse width (TON) and off time (TOFF) in order to meet the
output voltage regulation requirements.
N AUX
(VO + ∆V )
NS
(9.5)
CV mode
CC mode
E
=
g
feedback voltage VFB. The VFB signal precisely represents
the output voltage under most conditions and is used to
regulate the output voltage.
Output Voltage
ig _ peak ( t ) =
and reflects the output voltage as shown in Figure 9.3.
The voltage at the load differs from the secondary voltage by
a diode drop and IR losses. Thus, if the secondary voltage is
always read at a constant secondary current, the difference
between the output voltage and the secondary voltage will
be a fixed ΔV. Furthermore, if the voltage can be read when
the secondary current is small, ΔV will also be small. With
the iW1696, ΔV can be ignored.
Output Current
IOUT(CC)
Figure 9.4: Power Envelope
The real-time waveform analyzer in the iW1696 reads this
information cycle by cycle. The part then generates a
Rev. 2.0
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February 13, 2012
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iW1696
Low-Power Off-line Digital Green-Mode PWM Controller
9.6 Multi-Mode PWM/PFM Control and
Quasi-Resonant Switching
The iW1696 uses an adaptive multi-mode PWM /PFM
control to dramatically improve the light-load efficiency and
thus the overall average efficiency.
During the constant voltage (CV) operation, the iW1696
normally operates in a pulse-width-modulation (PWM)
mode during heavy load conditions. In the PWM mode, the
switching frequency keeps around constant. As the output
load IOUT is reduced, the on-time tON is decreased, and
the controller adaptively transitions to a pulse-frequencymodulation (PFM) mode. During the PFM mode, the BJT
is turned on for a set duration under a given instantaneous
rectified AC input voltage, but its off time is modulated by
the load current. With a decreasing load current, the off time
increases and thus the switching frequency decreases.
As the load current is further reduced, the iW1696 transitions
to a deep PFM mode (DPFM) which reduces the switching
frequency to a very low level.
While operating in the adaptive multi-mode PWM/PFM
control, iW1696 also incorporates a unique quasi-resonant
switching in both CV and CC operations. Together these
innovative digital control architecture and algorithms enable
iW1696 to achieve highest overall efficiency and lowest
EMI.
9.7 Variable Frequency Operation Mode
At each of the switching cycles, the falling edge of VSENSE
will be checked. If the falling edge of VSENSE is not detected,
the off-time will be extended until the falling edge of VSENSE
is detected. The maximum allowed transformer reset time is
75 μs. When the transformer reset time reaches 75 μs, the
iW1696 immediately shuts off.
OVP threshold at point 1 indicated in figure 9.3 the iW1696
immediately shuts down.
The iW1696 protects against input line undervoltage
by setting a maximum TON time. Since output power is
proportional to the squared VINTON product then for a given
output power as VIN decreases the TON will increase. Thus
by knowing when the maximum TON time occurs the iW1696
detects that the minimum VIN is reached, and shuts down.
The maximum tON limit is set to 22 μs. Also, the iW1696
monitors the voltage on the VCC pin and when the voltage
on this pin is below UVLO threshold the IC shuts down
immediately. The output voltage is monitored through the
VSENSE pin. When the overvoltage threshold is exceeded, the
iW1696 will shut down immediately.
When any of these faults are met the IC remains biased
to discharge the VCC supply. Once VCC drops below UVLO
threshold, the controller resets itself and then initiates a new
soft-start cycle. The controller continues attempting start-up
until the fault condition is removed.
9.10 PCL, OCP and SRS Protection
Peak-current limit (PCL), over-current protection (OCP) and
sense-resistor short protection (SRSP) are features built-in
to the iW1696. With the ISENSE pin the iW1696 is able to
monitor the peak primary current. This allows for cycle by
cycle peak current control and limit. When the primary peak
current multiplied by the ISENSE resistor is greater than 1.1 V
over current (OCP) is detected and the IC will immediately
turn off the base driver until the next cycle. The output driver
will send out a switching pulse in the next cycle, and the
switching pulse will continue if the OCP threshold is not
reached; or, the switching pulse will turn off again if the
OCP threshold is reached. If the OCP occurs for several
consecutive switching cycles, the iW1696 shuts down.
The iW1696 incorporates an internal Digital Error Amplifier
with no requirement for external loop compensation. For a
typical power supply design, the loop stability is guaranteed
to provide at least 45 degrees of phase margin and -20 dB
of gain margin.
If the ISENSE resistor is shorted there is a potential danger
of the over current condition not being detected. Thus,
the IC is designed to detect this sense-resistor-short fault
after startup and shut down immediately. The VCC will be
discharged since the IC remains biased. Once VCC drops
below the UVLO threshold, the controller resets itself and
then initiates a new soft-start cycle. The controller continues
attempting to startup, but does not fully startup until the fault
condition is removed.
9.9 Voltage Protection Features
9.11 Dynamic Base Current Control
The secondary maximum output DC voltage is limited by
the iW1696. When the VSENSE signal exceeds the output
One important feature of the iW1696 is that it directly drives
a BJT switching device with dynamic base current control to
optimize performance. The BJT base current ranges from
9.8 Internal Loop Compensation
Rev. 2.0
iW1696
February 13, 2012
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iW1696
Low-Power Off-line Digital Green-Mode PWM Controller
10 mA to 31 mA, and is dynamically controlled according to
the power supply load change. The higher the output power,
the higher the base current. Specifically, the base current is
related to VIPK, as shown in Figure 9.5.
35
Base Drive Current (mA)
30
25
20
15
10
5
0
0
0.1
0.2
0.3 0.4
0.5 0.6 0.7 0.8
0.9 1.0 1.1
VIPK (V)
Figure 9.5: Base Drive Current vs. VIPK
9.12 Cable Drop Compensation
The iW1696 incorporates an innovative method to
compensate for any IR drop in the secondary circuitry
including cable and cable connector. A 2.5 W adapter with
5 V DC output has 3% deviation at 0.5 A load current due to
the drop across a 24 AWG, 1.8 meter DC cable without cable
compensation. The iW1696 compensates for this voltage
drop by providing a voltage offset to the feedback signal
based on the amount of load current detected.
To calculate the amount of cable compensation needed, take
the resistance of the cable and connector and multiply by the
maximum output current.
Rev. 2.0
iW1696
February 13, 2012
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iW1696
Low-Power Off-line Digital Green-Mode PWM Controller
10.0 Physical Dimensions
5-Lead SOT Package
5
4
E
E1
1
2
3
Symbol
D
MIN
MAX
A
-
1.45
A1
0.0
0.15
A2
0.90
1.30
B
0.30
0.50
C
0.08
0.22
e
e1
D
A1
A2
B
COPLANARITY
0.10
A
SEATING
PLANE
α
Millimeters
2.90 BSC
E
2.80 BSC
E1
1.60 BSC
e
0.95 BSC
e1
L
C
1.90 BSC
L
0.30
0.60
α
0°
8°
Figure 10.1: Physical dimensions, 5-lead SOT-23 package
Compliant to JEDEC Standard MO178
Controlling dimensions are in millimeters
This package is RoHS compliant, and conform to Halide free limits.
Soldering Temperature Resistance:
[a] Package is IPC/JEDEC Std 020D Moisture Sensitivity Level 1
[b] Package exceeds JEDEC Std No. 22-A111 for Solder Immersion resistance;
packages can withstand 10 s immersion @ < 270 °C
Dimension D does not include mold flash, protrusions or gate burrs. Mold flash, protrusions
or gate burrs shall not exceed 0.25 mm per end. Dimension E1 does not include interlead flash
or protrusion. Interlead flash or protrusion shall not exceed 0.25 mm per side.
The package top may be smaller than the package bottom. Dimension D and E1 are determined
at the outermost extremes of the plastic body exclusive of mold flash, tie bar burrs, gate burrs and
interlead flash, but including any mismatch between the top and bottom of the plastic body.
11.0 Ordering Information
Part Number
Options
Package
Description
iW1696-00
Cable Comp = 0 mV
SOT-23
Tape & Reel1
iW1696-01
Cable Comp = 300 mV
SOT-23
Tape & Reel1
iW1696-03
Cable Comp = 450 mV
SOT-23
Tape & Reel1
iW1696-04
Cable Comp = 150 mV
SOT-23
Tape & Reel1
Note 1: Tape & Reel packing quantity is 3,000 per reel. Minimum ordering quantity is 3,000.
Rev. 2.0
iW1696
February 13, 2012
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iW1696
Low-Power Off-line Digital Green-Mode PWM Controller
About iWatt
iWatt Inc. is a fabless semiconductor company that develops intelligent power management ICs for computer, communication,
and consumer markets. The company’s patented pulseTrain™ technology, the industry’s first truly digital approach to power
system regulation, is revolutionizing power supply design.
Trademark Information
© 2012 iWatt, Inc. All rights reserved. iWatt, EZ-EMI, and pulseTrain are trademarks of iWatt, Inc. All other trademarks and
registered trademarks are the property of their respective companies.
Contact Information
Web: https://www.iwatt.com
E-mail: [email protected]
Phone: 408-374-4200
Fax: 408-341-0455
iWatt Inc.
675 Campbell Technology Parkway, Suite 150
Campbell, CA 95008
Disclaimer
iWatt reserves the right to make changes to its products and to discontinue products without notice. The applications
information, schematic diagrams, and other reference information included herein is provided as a design aid only and are
therefore provided as-is. iWatt makes no warranties with respect to this information and disclaims any implied warranties of
merchantability or non-infringement of third-party intellectual property rights.
iWatt cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in an iWatt product. No
circuit patent licenses are implied.
Certain applications using semiconductor products may involve potential risks of death, personal injury, or severe property
or environmental damage (“Critical Applications”).
IWATT SEMICONDUCTOR PRODUCTS ARE NOT DESIGNED, INTENDED, AUTHORIZED, OR WARRANTED TO
BE SUITABLE FOR USE IN LIFE‑SUPPORT APPLICATIONS, DEVICES OR SYSTEMS, OR OTHER CRITICAL
APPLICATIONS.
Inclusion of iWatt products in critical applications is understood to be fully at the risk of the customer. Questions concerning
potential risk applications should be directed to iWatt, Inc.
iWatt semiconductors are typically used in power supplies in which high voltages are present during operation. High-voltage
safety precautions should be observed in design and operation to minimize the chance of injury.
Rev. 2.0
iW1696
February 13, 2012
Page 11
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