INTERSIL ISL6269CRZ-T

ISL6269
®
Data Sheet
August 7, 2006
High-Performance Notebook PWM
Controller with Bias Regulator and
Audio-Frequency Clamp
Features
• High performance synthetic ripple regulation
The ISL6269 IC is a Single-Phase Synchronous-Buck PWM
controller featuring Intersil's Robust Ripple Regulator (R3)
technology that delivers truly superior dynamic response to
input voltage and output load transients. Integrated
MOSFET drivers, 5V LDO, and bootstrap diode result in
fewer components and smaller implementation area.
Intersil’s R3 technology combines the best features of fixedfrequency PWM and hysteretic PWM while eliminating many
of their shortcomings. R3 technology employs an innovative
modulator that synthesizes an AC ripple voltage signal VR,
analogous to the output inductor ripple current. The AC
signal VR enters a hysteretic comparator where the lower
threshold is the error amplifier output VCOMP, and the upper
threshold is a programmable voltage reference VW, resulting
in generation of the PWM signal. The voltage reference VW
sets the steady-state PWM frequency. Both rising and falling
edges of the PWM are modulated, providing faster response
to input voltage transients and output load transients than
conventional fixed-frequency PWM controllers. Unlike a
conventional hysteretic converter, the ISL6269 has an error
amplifier that provides ±1% voltage regulation at the FB pin.
The ISL6269 has a 1.5ms digital soft-start and can be
started into a pre-biased output voltage. A resistor divider is
used to program the output voltage setpoint. The ISL6269
can be configured to operate in forced-continuousconduction-mode (FCCM) or in diode-emulation-mode
(DEM), which improves light-load efficiency. In FCCM the
controller always operates as a synchronous rectifier,
switching the low-side MOSFET regardless of the output
load, however with DEM enabled, the low-side MOSFET is
disabled preventing negative current flow from the output
inductor during low load operation. An audio filter prevents
the PWM switching frequency from entering the audible
spectrum due to extremely light load while in DEM.
A PGOOD pin indicates when the converter is capable of
supplying regulated voltage. The ISL6269 features a unique
fault-identification capability that can drastically reduce
trouble-shooting time and effort. The pull-down resistance of
the PGOOD pin is 30Ω for an overcurrent fault, 60Ω for an
overvoltage fault, or 90Ω for either an undervoltage fault or
during soft-start. The overcurrent protection is accomplished
by measuring the voltage drop across the rDS(ON) of the
low-side MOSFET. A single resistor programs the
overcurrent and short-circuit points. Overvoltage and
undervoltage protection is monitored at the FB voltage
feedback pin.
1
FN9177.1
• Extremely fast transient response
• External type-two loop compensation
• ±1% regulation accuracy: -10°C to +100°C
• Starts into a pre-biased output
• Wide input voltage range: +7.0V to +25.0V
• Wide output voltage range: +0.6V to +3.3V
• Wide output load range: 0A to 25A
• Programmable PWM frequency: 200kHz to 600kHz
• Power good monitor
• Fault identification by PGOOD pull-down resistance
• Integrated MOSFET drivers with shoot-through protection
• Internal digital soft-start
• Internal 5V LDO for self-biasing from up to 25V
• Configure forced continuous conduction or diode
emulation for increased light load efficiency
• PWM minimum frequency above audible spectrum
• Integrated boot-strap diode
• Low-side MOSFET rDS(ON) overcurrent protection
• Undervoltage protection
• Soft crowbar overvoltage protection
• Over-temperature protection
• Pb-free plus anneal available (RoHS compliant)
Applications
• PCI express graphical processing unit
• Auxiliary power rail
• VRM
• Network adapter
CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures.
1-888-INTERSIL or 1-888-468-3774 | Intersil (and design) is a registered trademark of Intersil Americas Inc.
Copyright Intersil Americas Inc. 2005-2006. All Rights Reserved
All other trademarks mentioned are the property of their respective owners.
ISL6269
Pinout
PGOOD
PHASE
UG
BOOT
16 LD QFN (4mm x 4mm)
TOP VIEW
16
15
14
13
12 PVCC
VIN
1
VCC
2
FCCM
3
10 PGND
EN
4
9
11 LG
6
7
FB
FSET
ISEN
8
VO
5
COMP
GND
Ordering Information
PART NUMBER
PART MARKING
ISL6269CRZ (See Note)
6269CRZ
ISL6269CRZ-T (See Note)
6269CRZ
TEMP. RANGE (°C)
-10 to +100
PACKAGE
16 Ld 4x4 QFN (Pb-Free)
16 Ld 4x4 QFN Tape and Reel (Pb-Free)
PKG. DWG. #
L16.4x4
L16.4x4
NOTE: Intersil Pb-free plus anneal products employ special Pb-free material sets; molding compounds/die attach materials and 100% matte tin plate
termination finish, which are RoHS compliant and compatible with both SnPb and Pb-free soldering operations. Intersil Pb-free products are MSL
classified at Pb-free peak reflow temperatures that meet or exceed the Pb-free requirements of IPC/JEDEC J STD-020.
2
FN9177.1
August 7, 2006
ISL6269
Absolute Voltage Ratings
Thermal Information
ISEN, VIN to GND. . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.3V to +28V
VCC, PGOOD to GND . . . . . . . . . . . . . . . . . . . . . . . . -0.3V to +7.0V
PVCC to PGND. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.3V to +7.0V
GND to PGND. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.3V to +0.3V
EN, FCCM. . . . . . . . . . . . . . . . . . . . . . . . -0.3V to GND, VCC +3.3V
PHASE to GND (DC) . . . . . . . . . . . . . . . . . . . . . . . . . -0.3V to +28V
(<100ns Pulse Width, 10µJ . . . . . . . . . . . . . . . . . . . . . . . . . . -5.0V
BOOT to GND, or PGND . . . . . . . . . . . . . . . . . . . . . . -0.3V to +33V
BOOT to PHASE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.3V to +7V
UG (DC) . . . . . . . . . . . . . . . . . . . . . . -0.3V to PHASE, BOOT +0.3V
(<200ns Pulse Width, 20µJ) . . . . . . . . . . . . . . . . . . . . . . . . . -4.0V
LG (DC). . . . . . . . . . . . . . . . . . . . . . . . -0.3V to PGND, PVCC +0.3V
(<100ns Pulse Width, 4µJ) . . . . . . . . . . . . . . . . . . . . . . . . . . -2.0V
ESD Classification . . . . . . . . . . . . . . . . . . . . . .Level 1 (HBM = 2kV)
Thermal Resistance (Typical, Notes 1, 2) θJA (°C/W)
θJC (°C/W)
QFN Package . . . . . . . . . . . . . . . . . . .
43
11.5
Junction Temperature Range . . . . . . . . . . . . . . . . . -55°C to +150°C
Operating Temperature Range . . . . . . . . . . . . . . . . -10°C to +100°C
Storage Temperature . . . . . . . . . . . . . . . . . . . . . . . -65°C to +150°C
Lead Temperature (soldering, 10s). . . . . . . . . . . . . . . . . . . . +300°C
Recommended Operating Conditions
Ambient Temperature Range . . . . . . . . . . . . . . . . . . -10°C to 100°C
Supply Voltage (VIN to GND) . . . . . . . . . . . . . . . . . . . . . . 7V to 25V
CAUTION: Stress above those listed in “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress only rating and operation of the device
at these or any other conditions above those indicated in the operational section of this specification is not implied.
NOTE:
1. θJA is measured with the component mounted on a highly effective thermal conductivity test board on free air. See Tech Brief TB379 for details
2. For θJC, the “case temp” location is the center of the exposed metal pad on the package underside.
Electrical Specifications
These specifications apply for VIN = 15V, TA = (-10°C) to (+100°C), unless otherwise stated.
All typical specifications TA = ( + 2 5 ° C )
PARAMETER
SYMBOL
TEST CONDITIONS
MIN
TYP
MAX
UNIT
VIN
VIN Voltage Range
VIN
VIN Input Bias Current
IVIN
VIN Shutdown Current
ISHDN
25.0
V
EN and FCCM = 5V, FB = 0.65V, VIN = 7V to 25V
7.0
2.2
3.0
mA
EN = GND, VIN = 25V
0.1
1.0
µA
4.75
5.00
5.25
V
VCC LDO
VCC Output Voltage Range
VCC
VIN = 7V to 25V, ILDO = 0mA to 80mA
VCC POR THRESHOLD
Rising VCC POR Threshold Voltage
VCCTHR
4.35
4.45
4.55
V
Falling VCC POR Threshold Voltage
V
4.10
4.20
4.30
V
CCTHF
REGULATION
Error Amplifier Reference Voltage
VREF
Voltage Regulation Accuracy
VREG
0.6
-1
V
+1
%
PWM
FOSC
Frequency Range
FAUDIO
Frequency-Set Accuracy
FCCM = 5V
200
FCCM = GND
21
600
FOSC = 300kHz
-12
+12
%
0.60
3.30
V
28
VO Range
VVO
VO Input Leakage Current
IVO
VO = 0.60V
VO = 3.30V
1.3
7.0
IFB
FB = 0.60V
kHz
kHz
µA
µA
ERROR AMPLIFIER
FB Input Bias Current
± 20
nA
COMP Source Current
ICOMPSRC FB = 0.40V, COMP = 3.20V
2.5
mA
COMP Sink Current
ICOMPSNK FB = 0.80V, COMP = 0.30V
0.3
mA
COMP High Clamp Voltage
VCOMPHC
FB = 0.40V, Sink 50µA
3.10
3.40
3.65
V
COMP Low Clamp Voltage
VCOMPLC
FB = 0.80V, Source 50µA
0.09
0.15
0.21
V
3
FN9177.1
August 7, 2006
ISL6269
Electrical Specifications
These specifications apply for VIN = 15V, TA = (-10°C) to (+100°C), unless otherwise stated.
All typical specifications TA = ( + 2 5 ° C ) ( C o n t i n u e d )
PARAMETER
SYMBOL
TEST CONDITIONS
MIN
TYP
MAX
UNIT
PGOOD = 5mA Sink
80
95
133
Ω
PGROV
PGOOD = 5mA Sink
53
63
89
Ω
PGROC
PGOOD = 5mA Sink
26
32
46
Ω
IPGOOD
PGOOD = 5V
<0.1
1.0
POWER GOOD
PGRSS
PGRUV
PGOOD pull-down Impedance
PGOOD Leakage Current
PGOOD Maximum Sink Current
5.0
PGOOD Soft-Start Delay
TSS
EN High to PGOOD High
2.20
µA
mA
2.75
3.30
ms
1.5
Ω
GATE DRIVER
UG Pull-Up Resistance
RUGPU
200mA Source Current (Note 2)
1.0
UG Source Current
IUGSRC
VUG to PHASE = 2.5V
2.0
UG Sink Resistance
RUGPD
250mA Sink Current (Note 2)
1.0
UG Sink Current
IUGSNK
VUG to PHASE = 2.5V
2.0
A
1.5
Ω
A
1.5
Ω
LG Pull-Up Resistance
RLGPU
250mA Source Current (Note 2)
1.0
LG Source Current
ILGSRC
VLG to PGND = 2.5V
2.0
LG Sink Resistance
RLGPD
250mA Sink Current (Note 2)
0.5
LG Sink Current
ILGSNK
VLG to PGND = 2.5V
4.0
Delay From UG Falling to LG Rising
tUGFLGR
UG falling to LG rising
21
ns
Delay From LG Falling to UG Rising
tLGFUGR
LG falling to UG rising
14
ns
Forward Voltage
VF
PVCC = 5V, IF = 2mA
0.58
V
Reverse Leakage
IR
VR = 25V
0.2
µA
A
0.9
Ω
A
BOOTSTRAP DIODE
CONTROL INPUTS
EN High Threshold Voltage
VENTHR
EN Low Threshold Voltage
VENTHF
FCCM High Threshold Voltage
VFCCMTHR
FCCM Low Threshold Voltage
VFCCMTHF
EN Leakage Current
FCCM Leakage Current
2.0
V
0.5
V
1.0
V
1.0
µA
2.0
IENL
EN = 0V
IENH
EN = 5.0V
V
<0.1
µA
20
IFCCML
FCCM = 0V
<0.1
IFCCMH
FCCM = 5.0V
2.0
1.0
µA
µA
PROTECTION
ISEN OCP Threshold Current
-33
IOC
-26
-19
µA
µA
-50
ISEN Short-Circuit Threshold Current
ISC
UVP Threshold Voltage
VUV
81
84
87
%
OVP Rising Threshold Voltage
VOVR
113
116
119
%
OVP Falling Threshold Voltage
VOVF
OTP Rising Threshold Temperature
OTP Temperature Hysteresis
103
%
TOTR
(Note 2)
150
°C
TOTHYS
(Note 2)
25
°C
NOTE:
3. Guaranteed by design.
4
FN9177.1
August 7, 2006
ISL6269
Functional Pin Descriptions
VO Pin-8 (Input)
Bottom terminal pad of QFN package
Signal common of the IC. Unless otherwise stated, signals
are referenced to the GND pin, not the PGND pin.
The VO pin makes a direct measurement of the converter
output voltage used exclusively by the R3 PWM modulator.
The VO pin should be connected to the top of feedback
resistor RTOP at the converter output. Refer to Figure 1,
Typical Application Schematic.
VIN Pin-1 (Input)
ISEN Pin-9 (Input)
The VIN pin measures the converter input voltage with
respect to the GND pin. VIN is a required input to the R3
PWM modulator. The VIN pin is also the input source for the
integrated +5V LDO regulator.
The ISEN pin is the input to the overcurrent protection (OCP)
and short-circuit protection (SCP) circuits. Connect a resistor
RSEN between the ISEN pin and the PHASE pin. Select the
value of RSEN that will force the ISEN pin to source the ISEN
threshold current IOC when the peak inductor current
reaches the desired OCP setpoint. The SCP threshold
current ISC is fixed at twice the OCP threshold current IOC
GND Pin
VCC Pin-2 (Output)
The VCC pin is the output of the integrated +5V LDO
regulator, which provides the bias voltage for the IC. The
VCC pin delivers regulated +5V whenever the EN pin is
pulled above VENTHR. For best performance the LDO
requires at least a 1µF MLCC decouple capacitor to the
GND pin.
FCCM Pin-3 (Logic)
The FCCM pin configures the controller to operate in forcedcontinuous-conduction-mode (FCCM) or diode-emulationmode (DEM.) DEM is disabled when the FCCM pin is pulled
above the rising threshold voltage VFCCMTHR, and DEM is
enabled when the FCCM pin is pulled below the falling
threshold voltage VFCCMTHF.
EN Pin-4 (Logic)
The EN pin is the on/off switch of the IC. When the EN pin is
pulled above the rising threshold voltage VENTHR, VCC will
ramp up and begin regulation. The soft-start sequence
begins once VCC ramps above the power-on reset (POR)
rising threshold voltage VCCTHR. When the EN pin is pulled
below the falling threshold voltage VENTHF, PWM
immediately stops and VCC decays below the POR falling
threshold voltage VCCTHF, at which time the IC turns off.
COMP Pin-5 (Signal)
The COMP pin is the output of the control-loop error
amplifier. Loop compensation components connect from the
COMP pin to the FB pin.
FB Pin-6 (Signal)
The FB pin is the inverting input of the control loop error
amplifier. The converter will regulate to 600mV at the FB pin
with respect to the GND pin. Scale the desired output
voltage to 600mV with a voltage divider network made from
resistors RTOP and RBOTTOM. Loop compensation
components connect from the FB pin to the COMP pin.
FSET Pin-7 (Signal)
The FSET pin programs the PWM switching frequency of the
converter. Connect a resistor RFSET and a 10nF capacitor
CFSET from the FSET pin to the GND pin.
5
PGND Pin-10
The PGND pin should be connected to the source of the lowside MOSFET, preferably with an isolated path that is in
parallel with the trace connecting the LG pin to the gate of
the MOSFET. The PGND pin is an isolated path used
exclusively to conduct the turn-off transient current that flows
out the PGND pin, through the gate-source capacitance of
the low-side MOSFET, into the LG pin, and back to the
PGND pin through the pull-down resistance of the LG driver.
The adaptive shoot-through protection circuit, measures the
low-side MOSFET gate voltage with respect to the PGND
pin, not the GND pin.
LG Pin-11 (Output)
The LG pin is the output of the low-side MOSFET gate
driver. Connect to the gate of the low-side MOSFET.
PVCC Pin-12 (Input)
The PVCC pin is the input voltage for the low-side MOSFET
gate driver LG. Connect a +5V power source to the PVCC
pin with respect to the GND pin, a 1µF MLCC bypass
capacitor needs to be connected from the PVCC pin to the
PGND pin, not the GND pin. The VCC output may be used
for the PVCC input voltage source. Connect the VCC pin to
the PVCC pin through a low-pass filter consisting of a
resistor and the PVCC bypass capacitor. Refer to Figure 1,
Typical Application Schematic.
BOOT Pin-13 (Input)
The BOOT pin is the input voltage for the high-side MOSFET
gate driver UG. An MLCC capacitor CBOOT is connected
between the BOOT pin and the PHASE pin, the return
current path for the UG MOSFET driver. Capacitor CBOOT is
charged from the voltage source at the PVCC pin via the
internal diode DBOOT each time the PHASE pin drops below
PVCC minus diode DBOOT forward voltage drop VF.
UG Pin-14 (Output)
The UG pin is the output of the high-side MOSFET gate
driver. Connect to the gate of the high-side MOSFET.
FN9177.1
August 7, 2006
ISL6269
PHASE Pin-15 (Input)
PGOOD Pin-16 (Output)
The PHASE pin is the return current path for the UG
MOSFET driver. The PHASE pin also measures the polarity
of the low-side MOSFET drain voltage for the diode
emulation function. Connect the PHASE pin to the node
consisting of the high-side MOSFET source, the low-side
MOSFET drain, and the output inductor. Refer to Figure 1,
Typical Application Schematic.
The PGOOD pin is an open-drain output that is high
impedance when the converter is in regulation, or when the
EN pin is pulled below the falling threshold voltage VENTHF.
The PGOOD pin has three distinct pull-down impedances
that correspond to an OVP fault, OCP/SCP, or UVP and
soft-start. Connect the PGOOD pin to a pull-up resistor.
6
FN9177.1
August 7, 2006
ISL6269
Typical Application
ISL6269
VIN
7V-25V
PGOOD
VIN
CIN
RPGOOD
QHIGH_SIDE
PVCC
UG
RPVCC
VCC
BOOT
CVCC
CPVCC
CBOOT
GND
VOUT
LOUT
0.6V-3.3V
PHASE
COUT
RSEN
FCCM
ISEN
QLOW_SIDE
EN
LG
RCOMP
COMP
PGND
CCOMP1
FB
VO
CCOMP2
FSET
RFSET
RBOTTOM
CFSET
RTOP
FIGURE 1. TYPICAL APPLICATION SCHEMATIC
7
FN9177.1
August 7, 2006
Block Diagram
VIN
VO
PACKAGE BOTTOM
LDO
PWM FREQUENCY
CONTROL
VCC
+
VREF
VW
−
8
+
−
gmVIN
EN
−
FSET
−
GND
+
R
PWM
Q
OVP
+
gmVO
−
−
UVP
CR
VCOMP
+
S
+
BOOT
+
EA
DRIVER
−
POR
DIGITAL SOFT-START
PWM CONTROL
FB
COMP
−
ISEN
OCP
+
IOC
30Ω
90Ω
UG
60Ω
PHASE
SHOOT THROUGH
PROTECTION
PVCC
DRIVER
LG
150°OT
PGND
PGOOD
FCCM
FN9177.1
August 7, 2006
FIGURE 2. SCHEMATIC BLOCK DIAGRAM
ISL6269
+
−
VR
−
+
ISL6269
Theory of Operation
voltages into currents that charge and discharge the ripple
capacitor CR. The positive slope of VR can be written as:
Modulator
V RPOS = ( gm ) • ( V IN – V O )
The ISL6269 is a hybrid of fixed frequency PWM control, and
variable frequency hysteretic control. The term “Ripple” in
the name “Robust-Ripple-Regulator” refers to the converter
output inductor ripple current, not the converter output ripple
voltage. The output voltage is regulated to 600mV at the FB
pin with respect to the GND pin. The FB pin is the inverting
input of the error amplifier. The frequency response of the
feedback control loop is tuned with a type-two compensation
network connected across the FB pin and COMP pin.
(EQ. 1)
The negative slope of VR can be written as:
V RNEG = gm • V O
(EQ. 2)
A voltage VW is referenced with respect to the error amplifier
output voltage VCOMP, creating a window-voltage envelope
into which voltage VR is compared. The VR, VCOMP, and VW
signals feed into a hysteretic window comparator in which
VCOMP is the lower threshold voltage and VW is the higher
threshold voltage. PWM pulses are generated as VR
traverses the VW and VCOMP thresholds. The charging and
discharging rates of capacitor CR determine the PWM
switching frequency for a given amplitude of VW with respect
to VCOMP. The R3 regulator simultaneously affects switching
frequency and duty cycle because it modulates both edges
of the PWM pulses.
The R3 modulator synthesizes an AC signal VR, which is an
ideal representation of the output inductor ripple current. The
duty-cycle of VR is derived from the voltage measured at the
VIN pin and VO pin with respect to the GND pin.
Transconductance amplifiers convert the VIN and VO
RIPPLE CAPACITOR VOLTAGE CR
VOLTS
WINDOW VOLTAGE VW
ERROR AMPLIFIER VOLTAGE VCOMP
PWM
µs
FIGURE 3. MODULATOR WAVEFORMS DURING LOAD TRANSIENT
9
FN9177.1
August 7, 2006
ISL6269
LDO
MOSFET Gate-Drive Outputs
Voltage applied to the VIN pin with respect to the GND pin is
regulated to +5VDC by an internal low-dropout voltage
regulator (LDO). The output of the LDO is called VCC, which
is the bias voltage used by the IC internal circuitry. The LDO
output is routed to the VCC pin and requires a ceramic
capacitor connected to the GND pin to stabilize the LDO and
to decouple load transients.
The ISL6269 incorporates a MOSFET driver that controls
both high-side and low-side N-Channel MOSFETS. The
drivers are optimized for low duty-cycle applications
prevalent with large step down voltages. At low duty-cycle,
the low-side MOSFET conducts for a much longer time in a
switching period than the high-side MOSFET, necessitating
lower rDS(ON) at the expense of larger parasitic capacitance.
The low-side gate driver is therefore sized much larger to
meet this application requirement. The larger sink current
capability enables the low-side gate driver to hold the gatesource voltage of the MOSFET below its VGSTH as current
conducts through the drain-to-gate parasitic capacitance.
Both drivers incorporate adaptive shoot-through protection
to prevent high-side and low-side MOSFETS from
conducting simultaneously and shorting the input supply.
During turn-off of the low-side MOSFET, the LG to PGND
voltage is monitored until it reaches a 1V threshold, at which
time the UG driver is allowed to switch. During turn-off of the
high-side MOSFET, the UG to PHASE voltage is monitored
until it reaches a 1V threshold, at which time the LG driver is
allowed to switch.
When the EN pin rises above the VENR threshold, VCC will
turn on and rise to its regulation voltage. The LDO regulates
VCC by pulling up towards the voltage at the VIN pin; the
LDO has no pull-down capability.
POR and Soft-Start
The power-on reset (POR) circuit monitors VCC for the
VCCR (rising) and VCCF (falling) voltage thresholds. The
purpose of soft-start is to limit the inrush current through the
output capacitors when the converter first turns on.The PWM
soft-start sequence initializes once VCC rises above the
VCCR threshold, beginning from below the VCCF threshold.
The ISL6269 uses a digital soft-start circuit to ramp the
output voltage of the converter to the programmed regulation
setpoint in approximately 1.5ms. The converter regulates to
600mV at the FB pin with respect to the GND pin. During
soft-start a digitally derived voltage reference forces the
converter to regulate from 0V to 600mV at the FB pin.
When the EN pin is pulled below the VENF threshold, the
LDO stops regulating and PWM immediately stops,
regardless of the falling VCC voltage. The soft-start
sequence can be reinitialized and fault latches reset, once
VCC falls below the VCCF threshold.
The input power for the LG driver circuit is sourced directly
from the PVCC pin. The input power for the UG driver circuit
is sourced from a “boot” capacitor connected from the BOOT
pin to the PHASE pin. The same supply that is connected to
the PVCC pin is used to charge the boot capacitor via the
internal Schottky diode of the IC.
tLGFUGR
tUGFLGR
UG
LG
FIGURE 4. GATE DRIVE TIMING DIAGRAM
10
FN9177.1
August 7, 2006
ISL6269
Diode Emulation
Positive inductor current can flow from the source of the
high-side MOSFET or from the drain of the low-side
MOSFET. Negative inductor current flows into the drain of
the low-side MOSFET. When the low-side MOSFET
conducts positive inductor current, the phase voltage will be
negative with respect to the GND pin. Conversely, when the
low-side MOSFET conducts negative inductor current, the
phase voltage will be positive with respect to the GND pin.
Negative inductor current occurs when the output load
current is less than ½ the inductor ripple current.
The ISL6269 can be configured to operate in forcedcontinuous-conduction-mode (FCCM) or in diode-emulationmode (DEM), which can improve light-load efficiency. In
FCCM, the controller always operates as a synchronous
rectifier, switching the low-side MOSFET regardless of the
polarity of the output inductor current. In DEM, the low-side
MOSFET is disabled during negative current flow from the
output inductor. DEM is permitted when the FCCM pin is
pulled low, and disabled when pulled high.
When DEM is permitted, the converter will automatically
select FCCM or DEM according to load conditions. If positive
PHASE pin voltage is measured for eight consecutive PWM
pulses, then the converter will enter diode-emulation mode
on the next PWM cycle. If a negative PHASE pin voltage is
measured, the converter will exit DEM on the following PWM
pulse. An audio filter is incorporated into the PWM
generation circuitry that prevents the switching frequency
from entering the audible spectrum at low load conditions.
Overcurrent and Short-Circuit Protection
When an OCP or SCP fault is detected, the ISL6269
overcurrent and short-circuit protection circuit will pull the
PGOOD pin low and latch off the converter. The fault will
remain latched until the EN pin is pulled below VENF or if the
voltage at the VIN pin is reduced to the extent that VCC has
fallen below the POR VCCF threshold. Selecting the
appropriate value of resistor RSEN programs the OCP
threshold. The resistor RSEN is connected from the ISEN pin
to the PHASE pin. The PHASE pin is connected to the drain
terminal of the low-side MOSFET.
The OCP circuit measures positive-flowing, peak-current
through the output inductor, not the DC current flowing from
the converter to the load. The low-side MOSFET drain
current is assumed to be equal to the positive output
inductor current when the high-side MOSFET is turn off.
Current briefly conducts through the low-side MOSFET body
diode until the LG driver goes high. The peak inductor
current develops a voltage across the rDS(ON) of the
low-side MOSFET just as if it were a discrete current-sense
resistor. An OCP fault will occur when the ISEN pin has
measured more than the OCP threshold current IOC, on
consecutive PWM pulses, for a period exceeding 20µs. It
does not matter how many PWM pulses are measured
11
during the 20µs period. If a measurement falls below IOC
before 20µs has elapsed, then the timer is reset to zero. An
SCP fault will occur when the ISEN pin has measured more
than the short-circuit threshold current ISC, in less than
10µs, on consecutive PWM pulses. The relationship
between ID and ISEN can be written as:
– I SEN • R SEN = – I D • r DS ( ON )
(EQ. 3)
The value of RSEN can then be written as:
I PP
I FL + -------- • OC SP • r DS ( ON )
2
R SEN = ---------------------------------------------------------------------------I OC
(EQ. 4)
Where:
- RSEN (Ω) is the resistor used to program the overcurrent setpoint
- ISEN is the current sense current that is sourced from
the ISEN pin
- IOC is the ISEN threshold current value sourced from the
ISEN pin that will activate the OCP circuit
- IFL is the maximum continuous DC load current
- IPP is the inductor peak-to-peak ripple current
- OCSP is the desired overcurrent setpoint expressed as
a multiplier relative to IFL
Overvoltage
When an OVP fault is detected, the ISL6269 overvoltage
protection circuit will pull the PGOOD pin low and latch off
the converter. The fault will remain latched until the EN pin is
pulled below VENF or if the voltage at the VIN pin is reduced
to the extent that VCC has fallen below the POR VCCF
threshold.
When the voltage at the FB pin relative to the GND pin, has
exceeded the rising overvoltage threshold VOVR, the
converter will latch off however, the LG driver output will stay
high, forcing the low-side MOSFET to pull-down the output
voltage of the converter. The low-side MOSFET will continue
to pull-down the output voltage until the voltage at the FB pin
relative to the GND pin, has decayed below the falling
overvoltage threshold VOVF, at which time the LG driver
output is driven low, forcing the low-side MOSFET off. The
LG driver output will continue to switch on at VOVR and
switch off at VOVF until the EN pin is pulled below VENF or if
the voltage at the VIN is reduced to the extent that VCC has
fallen below the POR VCCF threshold.
FN9177.1
August 7, 2006
ISL6269
Undervoltage
When an UVP fault is detected, the ISL6269 undervoltage
protection circuit will pull the PGOOD pin low and latch off
the converter. The UVP fault occurs when the voltage at the
FB pin relative to the GND pin, has fallen below the undervoltage threshold VUV. The fault will remain latched until the
EN pin is pulled below VENF or if the voltage at the VIN is
reduced to the extent that VCC has fallen below the POR
VCCF threshold.
Over-Temperature
When an OTP fault is detected, the ISL6269 overtemperature protection circuit suspends PWM, but will not
affect the PGOOD pin, or latch off the converter. The overtemperature protection circuit measures the temperature of
the silicon and activates when the rising threshold
temperature TOTR has been exceeded. The PWM remains
suspended until the silicon temperature falls below the
temperature hysteresis TOTHYS at which time normal
operation is resumed. All other protection circuits will
function normally during OTP however, since PWM is
inhibited, it is likely that the converter will immediately
experience an undervoltage fault, latch off, and pull PGOOD
low. If the EN pin is pulled below VENF or if the voltage at the
VIN is reduced to the extent that VCC has fallen below the
POR VCCF threshold, normal operation will resume
however, the temperature hysteresis TOTHYS is reset.
PGOOD
The PGOOD pin connects to three open drain MOSFETS
each of which has a different rDS(ON). Consult the Electrical
Specifications Table for the pull-down resistance of PGOOD
for the corresponding fault. The PGOOD pin is high
impedance whenever VCC is below the rising POR threshold
VOVR, the falling POR threshold VOVF, after delay TSS
elapses, without an OVP, OCP, SCP, or UVP fault. This faultidentification capability is a useful tool for trouble-shooting.
TABLE 1. PGOOD PULL-DOWN RESISTANCE
CONDITION
PGOOD RESISTANCE
IC Off
Open
Soft Start
95Ω
Undervoltage Fault
95Ω
Overvoltage Fault
60Ω
Overcurrent Fault
30Ω
GND pin when the converter is regulating at the desired
output voltage.
Programming the output voltage can be written as:
R BOTTOM
V REF = V OUT • -------------------------------------------------R
+R
TOP
(EQ. 5)
BOTTOM
Where:
- VOUT is the desired output voltage of the converter.
- VREF is the voltage that the converter regulates to at the
FB pin.
- RTOP is the voltage-programming resistor that connects
from the FB pin to the VO pin. It is usually chosen to set
the gain of the control-loop error amplifier. It follows that
RBOTTOM will be calculated based upon the already
selected value of RTOP.
- RBOTTOM is the voltage-programming resistor that
connects from the FB pin to the GND pin.
Calculating the value of RBOTTOM can now be written as:
V REF • R
TOP
R BOTTOM = -----------------------------------V OUT – V REF
(EQ. 6)
Programming the PWM Switching Frequency
The PWM switching frequency FOSC is programmed by the
resistor RFSET that is connected from the FSET pin to the
GND pin. Programming the approximate PWM switching
frequency can be written as:
1
F OSC = ----------------------------------------------------------– 12
60 • R FSET • [ 1 ×10
]
(EQ. 7)
Estimating the value of RFSET can now be written as:
1
R FSET = -------------------------------------------------------– 12
60 • F OSC • [ 1 ×10
]
(EQ. 8)
Where:
- FOSC is the PWM switching frequency.
- RFSET is the FOSC programming resistor.
- 60 x [1 x 10-12] is a constant.
Selection of the LC Output Filter
The duty cycle of a buck converter is ideally a function of the
input voltage and the output voltage. This relationship can be
written as:
V OUT
D ( V IN ) = --------------V IN
(EQ. 9)
Where:
Component Selection
Programming the Output Voltage
When the converter is in regulation there will be 600mV from
the FB pin to the GND pin. Connect a two-resistor voltage
divider across the VO pin and the GND pin with the output
node connected to the FB pin. Scale the voltage-divider
network such that the FB pin is 600mV with respect to the
12
- D is the PWM duty cycle.
- VIN is the input voltage to be converted.
- VOUT is the regulated output voltage of the converter.
The output inductor peak-to-peak ripple current can be
written as:
V OUT • [ 1 – D ( V IN ) ]
I PP = ---------------------------------------------------F OSC • L O
(EQ. 10)
FN9177.1
August 7, 2006
ISL6269
Where:
- IPP is the peak-to-peak output inductor ripple current.
- FOSC is the PWM switching frequency.
- LO is the nominal value of the output inductor.
A typical step-down DC/DC converter will have an IPP of
20% to 40% of the nominal DC output load current. The
value of IPP is selected based upon several criteria such as
MOSFET switching loss, inductor core loss, and the
resistance the inductor winding, DCR. The DC copper loss of
the inductor can be estimated by:
P COPPER = [ I LOAD ] 2 • DCR
(EQ. 11)
The inductor copper loss can be significant in the total
system power loss. Attention has to be given to the DCR
selection. Another factor to consider when choosing the
inductor is its saturation characteristics at elevated
temperature. A saturated inductor could cause destruction of
circuit components, as well as nuisance OCP faults.
A DC/DC buck regulator must have output capacitance CO
into which ripple current IPP can flow. Current IPP develops a
corresponding ripple voltage VPP across CO, which is the
sum of the voltage drop across the capacitor ESR and of the
voltage change stemming from charge moved in and out of
the capacitor. These two voltages can be written as:
∆V ESR = I PP • E SR
(EQ. 12)
and
I PP
∆V C = ---------------------------------8 • CO • F
(EQ. 13)
OSC
If the output of the converter has to support a load with high
pulsating current, several capacitors will need to be
paralleled to adjust the ESR to achieve the required VPP.
The inductance of the capacitor can cause a brief voltage dip
when the load transient has an extremely high slew rate.
Low inductance capacitors constructed with reverse
package geometry are available.
A capacitor dissipates heat as a function of RMS current. Be
sure that IPP is shared by a sufficient quantity of paralleled
capacitors so that they operate below the maximum rated
RMS current. Take into account that the specified value of a
capacitor can drop as much as 50% as the DC voltage
across it increases.
Selection of the Input Capacitor
The important parameters for the bulk input capacitance are
the voltage rating and the RMS current rating. For reliable
operation, select bulk capacitors with voltage and current
ratings above the maximum input voltage and capable of
supplying the RMS current required by the switching circuit.
Their voltage rating should be at least 1.25 times greater
than the maximum input voltage, while a voltage rating of 1.5
times is a preferred rating. For most cases, the RMS current
rating requirement for the input capacitors of a buck
13
regulator is approximately 1/2 the DC output load current.
The maximum RMS current required by the regulator can be
approximated through the following equation:
I RMS = I LOAD • [ D ] – [ D ]
2
(EQ. 14)
Where:
- D is the converter duty cycle.
- IRMS is the input capacitance RMS ripple current.
- ILOAD is the converter output DC load current.
In addition to the bulk capacitance, some low ESL ceramic
capacitance is recommended to decouple between the drain
terminal of the high-side MOSFET and the source terminal
of the low-side MOSFET, in order to reduce the voltage
ringing created by the switching current across parasitic
circuit elements.
MOSFET Selection and Considerations
Typically, MOSFETS cannot tolerate even brief excursions
beyond their maximum drain to source voltage rating. The
MOSFETS used in the power conversion stage of the
converter should have a maximum VDS rating that exceeds
the upper voltage tolerance of the input power source, and
the voltage spike that occurs when the MOSFET switches
off. Placing a low ESR ceramic capacitor as close as
practical across the drain of the high-side MOSFET and the
source of the low-side MOSFET will reduce the amplitude of
the turn-off voltage spike.
The MOSFET input capacitance CISS, and on-state drain to
source resistance rDS(ON), are to an extent, inversely
related; reduction of rDS(ON) typically results in an increase
of CISS. These two parameters affect the efficiency of the
converter in different ways. The rDS(ON) affects the power
loss when the MOSFET is completely turned on and
conducting current. The CISS affects the power loss when
the MOSFET is actively switching. Switching time increases
as CISS increases. When the MOSFET switches it will briefly
conduct current while the drain to source voltage is still
present. The power dissipation during this time is substantial
so it must be kept as short as practical. Often the high-side
MOSFET and the low-side MOSFET are different devices
due to the trade-offs that have to be made between CISS
and rDS(ON).
The low-side MOSFET power loss is dominated by rDS(ON)
because it conducts current for the majority of the PWM
switching cycle; the rDS(ON) should be small. The switching
loss is small for the low-side MOSFET even though CISS is
large due to the low rDS(ON) of the device, because the drain
to source voltage is clamped by the body diode. The
high-side MOSFET power loss is dominated by CISS
because it conducts current for the minority of the PWM
switching cycle; the CISS should be small. The switching
loss of the high-side MOSFET is large compared to the lowside MOSFET because the drain to source voltage is not
clamped. For the lower MOSFET, its power loss can be
FN9177.1
August 7, 2006
ISL6269
assumed to be the conduction loss only and can be written
as:
P CONLS D ( V IN ) ≈ [ I LOAD ]
2
⋅
•
r DS ( ON )LS • [ 1 – D ( V IN ) ]
(EQ. 15)
For the high-side MOSFET, its conduction loss can be
written as:
P CONHS D ( V IN ) = [ I LOAD ]
⋅
2
•
r DS ( ON )HS • D ( V IN )
(EQ. 16)
For the high-side MOSFET, its switching loss can be written
as:
V IN • I VAL • T ON • F
V IN • I PEAK • T OFF • F
OSC
OSC
P SWHS ( V IN ) = ------------------------------------------------------------ + -------------------------------------------------------------------2
2
bottom MOSFET, output inductor, and output capacitor,
should be very small.
A guard-ring placed around high impedance inputs FB and
FSET is recommended.
Component Placement
Power MOSFETs should be placed close to the IC so that
VIN, LG, UG, PHASE, BOOT, and ISEN traces can be short.
Place components in such a way that the area near the
FSET, FB, COMP, and VO pins avoid traces with high dv/dt
and di/dt, such as gate signals and phase node signals.
(EQ. 17)
-
The peak and valley current of the inductor can be obtained
based on the inductor peak-to-peak current and the load
current. The turn-on and turn-off time can be estimated with
the given gate driver parameters in the Electrical
Specification Table.
Selecting The Bootstrap Capacitor
The selection of the bootstrap capacitor can be written as:
Qg
C BOOT = ----------------------∆V BOOT
VIN
+
Vo
+
(EQ. 18)
Where:
- Qg is the total gate charge required to switch the
high-side MOSFET
- ∆VBOOT, is the maximum allowed voltage decay across
the boot capacitor each time the MOSFET is switched
on
As an example, suppose the high-side MOSFET has a total
gate charge QG, of 25nC at VGS = 5V, and a ∆VBOOT of
200mV. The calculated bootstrap capacitance is 0.125µF;
select at least the first standard component value of greater
capacitance than calculated, that being 0.15µF. Use an X7R
or X5R ceramic capacitor.
Layout Considerations
Power and Signal Layer Placement on the PCB
As a general rule, power layers should be adjacent to one
another towards one side of the board, with signal layers
adjacent to one another towards the opposite side of the
board. For example, prospective layer arrangement on a 4
layer board is shown below:
1. Top Layer: ISL6269 signal lines
2. Signal Ground
3. Power Layers: Power Ground
4. Bottom Layer: Power MOSFET, Inductors and other
Power traces
It is a good engineering practice to separate the power
conductors from the signal conductors. The controller IC will
stay on the signal layer, which is isolated by the signal
ground to the power signal traces. The loop formed by the
14
Lo
Lo
FIGURE 5. TYPICAL POWER COMPONENT PLACEMENT
Signal Ground and Power Ground Connection
The bottom of the ISL6269 QFN package is the analog and
logic ground terminal (GND) of the IC. Connect the GND pad
of the ISL6269 to the signal ground layer of the pcb using at
least five vias, for a robust thermal and electrical conduction
path. The best tie-point between the signal ground and the
power ground is at the negative side of the output capacitors
that is not in the return path of the inductor ripple current
flowing through the output capacitors.
Pin 1 (VIN)
The VIN pin should be connected to the drain of the
high-side MOSFET, using a low resistance and low
inductance path.
Pin 2 VCC
For best performance the LDO requires at least a 1µF MLCC
decouple capacitor connected from the VCC pin to the GND
pin.
Pin 3 (FCCM) and Pin 4 (EN)
These are logic inputs that are referenced to the GND pin.
Treat as a typical logic signal.
FN9177.1
August 7, 2006
ISL6269
Pin 5 (COMP)
The loop compensation components connect from the
COMP pin to the FB pin. Place the components close to the
FB pin to make the traces as short as possible.
Pin 6 (FB)
There is usually a resistor divider connecting the output
voltage of the converter to the FB pin. The correct layout
should bring the output voltage from the regulation point to
the FB pin with kelvin traces. The input impedance of the FB
pin is high, so place the resistor divider close to the pin,
keeping the high impedance trace short.
Pin 7 (FSET)
These two traces should be short, wide, and away from
other traces. There should be no other weak signal traces in
parallel with these traces on any layer.
Pin 15 (PHASE)
Connect to the low-side MOSFET drain terminal. The phase
node has a very high dv/dt with a voltage swing from the input
voltage to ground. This trace should be short, and positioned
away from other weak signal traces.
Pin 16 (PGOOD)
A very robust pin. Treat as a typical logic signal.
Copper Size for the Phase Node
Pin 8 (VO)
The parasitic capacitance and parasitic inductance of the
phase node should be kept very low to minimize ringing. If
ringing is excessive, it could easily affect current sample
information. It would be best to limit the size of the PHASE
node copper in strict accordance with the current and
thermal management of the application.
The VO pin should be connected to the Kelvin traces at the
FB voltage divider.
Identify the Power and Signal Ground
This pin requires a quiet environment. The resistor RFSET
and capacitor CFSET should be placed directly adjacent to
this pin. Keep fast moving nodes away from this pin.
Pin 9 (ISEN)
The ISEN trace should be routed away from the traces and
components connected to the FB pin, COMP pin, and FSET
pin.
Pin 10 (PGND)
This is the pull-down return path for the LG low-side
MOSFET gate drive. This should be an isolated lowresistance, low-inductance trace that connects to the source
of the low-side MOSFET.
Pin 11 (LG)
Connect to the gate terminal of the low-side MOSFET. The
signal going through this trace is both high dv/dt and high
di/dt, with high peak charging and discharging current. Route
this trace in parallel with the trace from the PGND pin. These
two traces should be short, wide, and away from other
traces. There should be no other weak signal traces in
parallel with these traces on any layer.
Pin 12 (PVCC)
A ceramic decoupling capacitor connects from the PVCC pin
to the PGND pin, not the GND pin. Closely place the
capacitor on the same side of the board as the ISL6269 IC.
Pin 13 (BOOT)
The di/dt and dv/dt of this pin are as high as that of the LG
pin, UG pin, and the PHASE pin; therefore, the traces should
be as short as possible.
The input and output capacitors of the converter, the source
terminal of the low-side MOSFET, and the PGND pin should
be closely connected to the power ground. The other
components should connect to signal ground. Signal and
power ground are tied together at the negative terminal of
the output capacitors.
Decoupling Capacitor for Switching MOSFET
Ceramic capacitors should be closely connected to the drain
side of the high-side MOSFET, and the source of the lowside MOSFET. This capacitor reduces the amplitude of the
turn-off voltage spike.
Control Loop
The control loop model of the ISL6269 is partitioned into
function blocks consisting of:
- The Duty cycle to Vo transfer function Gvd(s) which is
determined by the value of the output power
components, input voltage, and output voltage.
- The Vcomp to Duty cycle transfer function Fm(s) which
is determined by the PWM frequency, input voltage,
output voltage, resistor RFSET, and capacitor CFSET.
- The product of the Gvd(s) and Fm(s) transfer functions
is expressed as the Vcomp to Vo transfer function
Gvovc(s).
- The type-two compensation network Gcomp(s) that
connects across the COMP and FB pins.
- The product of the Gcomp(s) and Gvovc(s) transfer
functions is expressed as the loop transfer function T(s).
Pin 14 (UG)
Connect to the gate terminal of the high-side MOSFET. The
signal going through this trace is both high dv/dt and high
di/dt, with high peak charging and discharging current. Route
this trace in parallel with the trace from the PHASE pin.
15
FN9177.1
August 7, 2006
ISL6269
The compensator zero fz1 is written as:
T(s)=GCOMP(s) + GVOVC(s)
VCOMP
VREF
GCOMP(s)
+
1
ω z1 = ------------------------------------------R comp • C comp2
(EQ. 19)
ω z1
f z1 = --------2•π
(EQ. 20)
Vo
GVOVC(s)
−
The compensator pole fp1 is written as:
FIGURE 6. SYSTEM CONTROL BLOCK DIAGRAM
1
1
ω p1 = --------------------- + --------------------C comp1 C comp2
•
1 ----------------R comp
(EQ. 21)
90
100
60
80
30
60
0
40
30
20
60
0
90
20
120
40
10
3
1 .10
100
4
1 .10
5
1 .10
ω p1
f p1 = --------2•π
Phase
Gain (db)
Vcomp to Vo Transfer Function Gvovc(s)
120
(EQ. 22)
The compensator gain is written as:
1
ω i = ----------------------------------------------------------------------------R comp • [ C comp1 + C comp2 ]
(EQ. 23)
The compensator transfer function is written as:
150
6
1 .10
s
ω i • 1 + ---------ω z1
G comp ( s ) = ---------------------------------s
s • 1 + ---------ω p1
Frequency (Hz)
Gain (Gvovc)
Phase (Gvovc)
(EQ. 24)
FIGURE 7. OPEN LOOP TRANSFER FUNCTION
CCOMP1
CCOMP2
RCOMP
90
100
75
80
60
60
45
40
30
20
15
0
0
20
RBOTTOM
Phase
120
FB
VREF
−
ERROR
AMPLIFIER
COMP
+
Gain (db)
Voltage Loop Gain T(s)
15
40
10
100
1 .10
1 .10
3
4
1 .10
5
1 .10
30
6
FIGURE 9. SYSTEM CONTROL BLOCK DIAGRAM
Frequency (Hz)
Gain (Tv)
Phase (Tv)
FIGURE 8. CLOSED LOOP TRANSFER FUNCTION
16
FN9177.1
August 7, 2006
ISL6269
Quad Flat No-Lead Plastic Package (QFN)
Micro Lead Frame Plastic Package (MLFP)
L16.4x4
16 LEAD QUAD FLAT NO-LEAD PLASTIC PACKAGE
(COMPLIANT TO JEDEC MO-220-VGGC ISSUE C)
MILLIMETERS
SYMBOL
MIN
NOMINAL
MAX
NOTES
A
0.80
0.90
1.00
-
A1
-
-
0.05
-
A2
-
-
1.00
A3
b
0.23
D
0.28
9
0.35
5, 8
4.00 BSC
D1
D2
9
0.20 REF
-
3.75 BSC
1.95
2.10
9
2.25
7, 8
E
4.00 BSC
-
E1
3.75 BSC
9
E2
1.95
e
2.10
2.25
7, 8
0.65 BSC
-
k
0.25
-
-
-
L
0.50
0.60
0.75
8
L1
-
-
0.15
10
N
16
2
Nd
4
3
Ne
4
3
P
-
-
0.60
9
θ
-
-
12
9
Rev. 5 5/04
NOTES:
1. Dimensioning and tolerances conform to ASME Y14.5-1994.
2. N is the number of terminals.
3. Nd and Ne refer to the number of terminals on each D and E.
4. All dimensions are in millimeters. Angles are in degrees.
5. Dimension b applies to the metallized terminal and is measured
between 0.15mm and 0.30mm from the terminal tip.
6. The configuration of the pin #1 identifier is optional, but must be
located within the zone indicated. The pin #1 identifier may be
either a mold or mark feature.
7. Dimensions D2 and E2 are for the exposed pads which provide
improved electrical and thermal performance.
8. Nominal dimensions are provided to assist with PCB Land Pattern
Design efforts, see Intersil Technical Brief TB389.
9. Features and dimensions A2, A3, D1, E1, P & θ are present when
Anvil singulation method is used and not present for saw
singulation.
10. Depending on the method of lead termination at the edge of the
package, a maximum 0.15mm pull back (L1) maybe present. L
minus L1 to be equal to or greater than 0.3mm.
All Intersil U.S. products are manufactured, assembled and tested utilizing ISO9000 quality systems.
Intersil Corporation’s quality certifications can be viewed at www.intersil.com/design/quality
Intersil products are sold by description only. Intersil Corporation reserves the right to make changes in circuit design, software and/or specifications at any time without
notice. Accordingly, the reader is cautioned to verify that data sheets are current before placing orders. Information furnished by Intersil is believed to be accurate and
reliable. However, no responsibility is assumed by Intersil or its subsidiaries for its use; nor for any infringements of patents or other rights of third parties which may result
from its use. No license is granted by implication or otherwise under any patent or patent rights of Intersil or its subsidiaries.
For information regarding Intersil Corporation and its products, see www.intersil.com
17
FN9177.1
August 7, 2006