Renesas IPM6220ACA Advanced triple pwm and dual linear power controller for portable application Datasheet

NOT RECOMM
ENDED FOR N
EW DESIGNS
NO RECOMMEN
DED REPLACE
MENT
contact our Te
chnical Suppor
t Center at
1-888-INTERSI
L or www.inters
il.com/tsc
August 2004
IPM6220A
DATASHEET
FN9032
Rev 1.00
Aug 2004
Advanced Triple PWM and Dual Linear Power Controller for Portable Applications
The IPM6220A provides a highly integrated power control and
protection solution for five output voltages required in highperformance notebook PC applications. The IC integrates
three fixed frequency pulse-width-modulation (PWM)
controllers and two linear regulators along with monitoring and
protection circuitry into a single 24 lead SSOP package.
The two PWM controllers that regulate the system main 5V
and 3.3V voltages are implemented with synchronousrectified buck converters. Synchronous rectification and
hysteretic operation at light loads contribute to high efficiency
over a wide range of input voltage and load variation.
Efficiency is further enhanced by using the lower MOSFET’s
rDS(ON) as the current sense element. Input voltage feedforward ramp modulation, current-mode control, and internal
feed-back compensation provide fast and stable handling of
input voltage load transients encountered in advanced
portable computer chip sets.
The third PWM controller is a boost converter that regulates a
resistor selectable output voltage of nominally 12V.
Two internal linear regulators provide +5V ALWAYS and
+3.3V ALWAYS low current outputs required by the notebook
system controller.
Ordering Information
PART NUMBER
Features
• Provides Five Regulated Voltages
- +5V ALWAYS
- +3.3V ALWAYS
- +5V Main
- +3.3V Main
- +12V
• High Efficiency Over Wide Line and Load Range
- Synchronous Buck Converters on Main Outputs
- Hysteretic Operation at Light Load
• No Current-Sense Resistor Required
- Uses MOSFET’s rDS(ON)
- Optional Current-Sense Resistor for More Precision
• Operates Directly From Battery 5.6 to 22V Input
• Input Undervoltage Lock-Out (UVLO)
• Excellent Dynamic Response
- Voltage Feed-Forward and Current-Mode Control
• Monitors Output Voltages
• Synchronous Converters Operate Out of Phase
• Separate Shut-Down Pins for Advanced Configuration and
Power Interface (ACPI) Compatibility
• 300kHz Fixed Switching Frequency on Main Outputs
TEMP.
RANGE (°C)
PACKAGE
PKG.
DWG. #
• Thermal Shut-Down Protection
• Pb-free Available
IPM6220ACA
-10 to 85
24 Ld SSOP
M24.15
IPM6220ACAZ
(Note)
-10 to 85
24 Ld SSOP (Pb-free)
M24.15
IPM6220ACAZ-T
(Note)
-10 to 85
24 Ld SSOP
Tape & Reel (Pb-free)
M24.15
• Hand-Held Portable Instruments
IPM6220ACAZA-T
(Note)
-10 to 85
24 Ld SSOP
Tape & Reel (Pb-free)
M24.15
Related Literature
IPM6220EVAL1
Applications
• Mobile PCs
Evaluation Board
NOTE: Intersil Pb-free products employ special Pb-free material
sets; molding compounds/die attach materials and 100% matte tin
plate termination finish, which is 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-020B.
FN9032 Rev 1.00
Aug 2004
• Application Note AN9915
Pinout
IPM6220A (SSOP)
TOP VIEW
VBATT 1
24 BOOT1
3.3V ALWAYS 2
23 UGATE1
BOOT2 3
22 PHASE1
UGATE2 4
21 ISEN1
PHASE2 5
20 LGATE1
5V ALWAYS 6
19 PGND1
LGATE2 7
18 VSEN1
PGND2 8
17 SDWN1
ISEN2 9
16 GATE3
VSEN2 10
15 VSEN3
SDWN2 11
14 GND
PGOOD 12
13 SDWNALL
Page 1 of 14
VSEN3
VBATT
GATE3
BOOT1
GND
UVFLT
GATE LOGIC 1
HGDR1
HI
BOOST
CONTROLLER
CLK1
CLK
200ns
RAMP 2
CLK2
CLK1
PHASE1
SHUTOFF
POWER-ON
RESET (POR)
RAMP 1
PWMMD1
POR
DEADTIME
REF
VCC
PWM/HYST
BOOT2
LGDR1
PWM ON
UGATE2
OVP1
HI
PHASE2
SHUTOFF
-
-
REF
HYST COMP2
-
+
OC COMP2
-
+
+

-
POR
SDWN1
LDO1
REFERENCE
VCC
+
UVFLT
Page 2 of 14
LGATE2
OVP1
OVP2
ISEN1
LGATE1
LGATE1
SDWN
LGATE2
VSEN1
+
VOLTSECOND
CLAMP
VBATT
D Q
R
> Q
-
ISEN2
R1 = 20K
-
VCC PWM
LATCH 2
OC
LOGIC2
REF
+
PWM MODE 2 PWMMD2
R1 = 20K
+
- PWM MODE 1
+
-
VOLTSECOND
CLAMP
PWMMD1
2.8V
EA2

+
-
CLK2
+
VSEN2
+
PGND2
HYST ON
EA1
+
LO
-
OC LOGIC1
Q D
R
Q <
PWM ON
CLK1
+
LGDR2
VSEN1
+
PWM VCC
LATCH 1
DEADTIME
PWM/HYST
VCC
OVP2
PGND1
HYST COMP1
PWMMD2
OC COMP1
LGATE2
LGATE1
LO
HYST ON
GATE LOGIC 2
HGDR2
UGATE1
SDWN
OUTPUT
VOLTAGE
MONITOR
REF
3.3V-ALWAYS
PGOOD
FIGURE 1.
AND
SDWN2
SOFT START
LDO2
5V-ALWAYS
2.5V
SDWNALL
IPM6220A
FN9032 Rev 1.00
Aug 2004
Block Diagram
IPM6220A
Simplified Power System Diagram
VBATT
VBATT
Q1
3.3V ALWAYS
5V ALWAYS
LINEAR
CONTROLLER
IPM6220A
3.3V MAIN
Q2
LINEAR
CONTROLLER
VBATT
5V MAIN
PWM1
CONTROLLER
VOLTAGE,
CURRENT
MONITORS
PGOOD
12V BOOST
Q1
PWM2
CONTROLLER
PWM3
CONTROLLER
Q2
FIGURE 2.
Typical Application
+VBATT
PROCESSOR
5V MAIN
SDWN1
VCORE
3.3V MAIN
SDWN2
IPM6220A
VI/O
5V ALWAYS
3.3V ALWAYS
C8051
12V
VID CODE
SDWN
PCM
CIA
IPM6210
VCLOCK
I/O
CLOCK
PGOOD
PGOOD
ENABLE
P CORE
RESET
SDWNALL
ON/OFF
FIGURE 3.
FN9032 Rev 1.00
Aug 2004
Page 3 of 14
IPM6220A
Absolute Maximum Ratings
Thermal Information
Input Voltage, VBATT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . +27.0V
Phase, ISEN and SDWNALL Pins . . . . . . . . . . . GND -0.3V to +27.0V
Boot and UGATE Pins. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . +33.0V
BOOT1, 2 with Respect to PHASE1, 2 . . . . . . . . . . . . . . . . . . . +6.5V
All Other Pins. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . +6.5V
Thermal Resistance (Typical, Note 1)
JA (°C/W)
SSOP Package . . . . . . . . . . . . . . . . . . . . . . . . . . . .
110
Maximum Junction Temperature (Plastic Package) . . . . . . . . 150°C
Maximum Storage Temperature Range . . . . . . . . . . . -65°C to 150°C
Maximum Lead Temperature (Soldering 10s) . . . . . . . . . . . . . 300°C
(SSOP - Lead Tips Only)
Operating Conditions
Input Voltage, VBATT . . . . . . . . . . . . . . . . . . . . . . . . +5.6V to +24.0V
Ambient Temperature Range . . . . . . . . . . . . . . . . . . . .-10°C to 85°C
Junction Temperature Range. . . . . . . . . . . . . . . . . . . . 0°C to 125°C
CAUTION: Stresses 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 sections of this specification is not implied.
NOTE:
1. JA is measured with the component mounted on a low effective thermal conductivity test board in free air. See Tech Brief TB379 for details.
Electrical Specifications
Recommended Operating Conditions, Unless Otherwise Noted. Refer to Block and Simplified Power System
Diagrams, and Typical Application Schematic
PARAMETER
Input Quiescent Current
SYMBOL
TEST CONDITIONS
MIN
TYP
MAX
UNITS
2.0
mA
ICC
SDWN1 = SDWN2 = 5V, SDWNALL = VIN,
Outputs open circuited
-
1.4
Stand-by Current
ICCSB
SDWN1 = SDWN2 = 0V, SDWNALL = VIN,
Outputs open circuited
-
300
A
Shut-down Current
ICCSN
SDWNALL = 0V
-
<1.0
A
Input Under-voltage Lock Out
UVLO
Rising VBATT
Input Under-voltage Lock Out
UVLO
VBATT, Hysteresis
4.3
4.7
5.1
300
V
mV
OSCILLATOR
PWM1,2 Oscillator Frequency
Fc1,2
255
300
345
kHz
VREF
-
2.472
-
V
-1.0
-
+1.0
%
-
5
-
A
REFERENCE AND SOFT START
Internal Reference Voltage
Reference Voltage Accuracy
SDWN1, SDWN2 Output Current During
Start-up
ISS
PWM1 CONVERTER, 5V Main
Output Voltage
VOUT1
Line and Load Regulation
Under-Voltage Shut-Down Level
5.0
V
0.0 < IVOUT1 < 5.0A; 5.6V < VBATT < 22.0V
-2
0.5
+2
%
VUV1
2s delay, % Feedback Voltage at VSNS1 pin
70
75
80
%
Current Limit Threshold
IOC2
Current from ISNS1 Pin Through RSNS1
90
135
180
A
Over-Voltage Threshold
VOVP1
2s delay, % Feedback Voltage at VSNS1 pin
110
115
120
%
Maximum Duty Cycle
DCMAX
SDWN1 > 4.0V
94
%
3.3
V
PWM2 CONVERTER, 3.3V Main
Output Voltage
VOUT2
Line and Load Regulation
0.0 < IVOUT2 < 5.0A; 5.6V < VBATT < 24.0V
-2
0.5
+2
%
Under-Voltage Shut-Down Level
VUV2
2s delay, % Feedback Voltage at VSNS2 pin
70
75
80
%
Current Limit Threshold
IOC2
Current from ISNS2 Pin Through RSNS2
90
135
180
A
110
115
120
%
Over-Voltage Threshold
VOVP2
2s delay, % Feedback Voltage at VSNS2 pin
Maximum Duty Cycle
DCMAX
SDWN2 > 4.0V
Internal Resistance to GND on VSNS2 Pin
RVSNS2
FN9032 Rev 1.00
Aug 2004
94
%
66K

Page 4 of 14
IPM6220A
Electrical Specifications
Recommended Operating Conditions, Unless Otherwise Noted. Refer to Block and Simplified Power System
Diagrams, and Typical Application Schematic (Continued)
PARAMETER
SYMBOL
TEST CONDITIONS
MIN
TYP
MAX
UNITS
PWM1 and PWM2 CONTROLLER GATE DRIVERS
Upper Drive Pull-Up Resistance
R2UGPUP
-
5
12

Upper Drive Pull-Down Resistance
R2UGPDN
-
4
10

Lower Drive Pull-Up Resistance
R2LGPUP
-
6
9

Lower Drive Pull-Down Resistance
R2LGPDN
-
5
8

PWM 3 CONVERTER
12V Feedback Regulation Voltage
VSEN3
2.472
12V Feedback Regulation Voltage Input
Current
IVSEN3
0.1
0.0 < IVOUT3 < 120mA, 4.9V< 5VMain <5.1V
-2
VUV3
2s delay, % Feedback Voltage at VSNS3 pin
70
VOVP3
2s delay, % Feedback Voltage at VSNS3 pin
Line and Load Regulation
Under-Voltage Shut-Down Level
Over-Voltage Threshold
PWM3 Oscillator Frequency
85
Fc3
Maximum Duty Cycle
V
1.0
A
+2
%
75
80
%
115
120
%
100
115
kHz
33
%
PWM 3 CONTROLLER GATE DRIVERS
Pull-Up Resistance
R3GPUP
6
12

Pull-Down Resistance
R3GPDN
6
12

5V and 3.3V ALWAYS
Linear Regulator Accuracy
PWM1, 5V Output OFF (SDWN1 = 0V);
5.6V < VBATT < 22V; 0 < ILOAD < 50mA
-2.0
0.5
+2.0
%
5V ALWAYS Output Voltage Regulation
PWM1, 5V Output ON (SDWN1 = 5V);
0 < ILOAD < 50mA
-3.3
1.0
+2.0
%
Maximum Output Current
Combined 5V ALWAYS and 3.3V ALWAYS
50
Current Limit
Combined 5V ALWAYS and 3.3V ALWAYS
100
5V ALWAYS Under-Voltage Shut-Down
Bypass Switch rDS(ON)
PWM1, 5V Output ON (SDWN1 = 5V)
mA
180
mA
75
%
1.3

POWER GOOD AND CONTROL FUNCTIONS
Power Good Threshold for PWM1 and
PWM2 Output Voltages
PGOOD Leakage Current
PGOOD Voltage Low
IPGLKG
VPGOOD
VPULLUP = 5.0V
IPGOOD = -4mA
-14
-12
-10
%
-
-
1.0
A
0.2
0.5
V
10
s
SDWN1, 2, - Low (Off)
0.8
V
SDWN1, 2, - High (On)
4.3
V
SDWNALL - High (On)
2.4
V
PGOOD Minimum Pulse Width
SDWNALL - Low (Off)
TPGmin
40
mV
Over-Temperature Shutdown
150
°C
Over-Temperature Hysteresis
25
°C
FN9032 Rev 1.00
Aug 2004
SDWNALL, Hysteresis
Page 5 of 14
IPM6220A
Functional Pin Descriptions
VBATT (Pin 1)
Supplies all the power necessary to operate the chip. The IC
starts to operate when the voltage on this pin exceeds 4.7V
and stops operating when the voltage on this pin drops below
approximately 4.5V. Also provides battery voltage to the
oscillator for feed-forward rejection to input voltage variations.
voltage status and/or to initiate undervoltage shut down. The
VSEN1 input is also switched internally to the 5V ALWAYS
output if the +5V Main output is enabled.
SDWNALL (Pin 13)
Output of 3.3V ALWAYS linear regulator.
This pin provides enable/disable function for all outputs. The
chip is completely disabled when this pin is pulled to ground.
When this pin is pulled high, the 5V ALWAYS and 3.3 ALWAYS
outputs are on and the other outputs are enabled. The state of
5V Main and 3.3V Main outputs depend on the voltage on
SDWN1 and SDWN2 respectively. See Table 1.
5V ALWAYS (Pin 6)
SDWN1 (Pin 17)
Output of 5V ALWAYS linear regulator or the +5V Main output.
If the +5V Main output is enabled, it is switched internally from
the VSEN1 pin to the 5V ALWAYS output. This improves
efficiency and reduces the power dissipation in the controller.
This pin provides enable/disable function and soft-start for the
PWM1, 5V Main, output. The output is enabled when this pin is
high and SDWNALL is also high. The 5V output is held off
when the pin is pulled to the ground.
BOOT1, BOOT2 (Pins 24 and 3)
SDWN2 (Pin 11)
Power is supplied to the upper MOSFET drivers of PWM1 and
PWM2 converters via the BOOT pins. Connect these pins to
the respective junctions of bootstrap capacitors with the
cathodes of the bootstrap diodes. Anodes of the bootstrap
diodes are connected to pin 6, 5V ALWAYS.
This pin provides enable/disable function and soft-start for
PWM2, 3.3V Main, output. The output is enabled when this pin
is high and SDWNALL is also high. The 3.3V output is held off
when the pin is pulled to the ground.
UGATE1, UGATE2 (Pins 23 and 4)
This input pin is the voltage feedback signal for PWM3, the
boost controller. The boost controller regulates this point to a
voltage divided level of 2.472 VDC. The PGOOD, overvoltage
protection (OVP) and undervoltage shutdown circuits use this
signal to determine output-voltage status and/or to initiate
undervoltage shut down.
3.3V ALWAYS (Pin 2)
These pins provide the gate drive for the upper MOSFETs.
Connect UGATE pins to the respective PWM converter’s upper
MOSFET gate.
PHASE1, PHASE2 (Pins 22 and 5)
The phase nodes are the junctions of the upper MOSFET
sources, output filter inductors, and lower MOSFET drains.
Connect the PHASE pins directly to the respective PWM
converter’s lower MOSFET drain.
VSEN3 (Pin 15)
This pin can also be used to independently disable the PWM3
controller. Connect this pin to 5V ALWAYS if the boost
converter is not populated in your design.
ISEN1, ISEN2 (Pins 21 and 9)
GATE3 (Pin 16)
These pins are used to monitor the voltage drop across the
lower MOSFETs for current feedback and current-limit
protection. For more precise current detection, these inputs
can be connected to optional current sense resistors placed in
series with the sources of the lower MOSFETs.
This pin drives the gate of the boost MOSFET.
LGATE1, LGATE 2 (Pins 20 and 7)
These pins provide the gate drive for the lower MOSFETs.
Connect the lower MOSFET gate of each converter to the
corresponding pin.
PGND1, PGND2 (Pins 19 and 8)
These are the lower MOSFET gate drive return connection for
PWM1 and PWM2 converters, respectively. Tie each lower
MOSFET source directly to the corresponding pin.
VSEN1, VSEN2 (Pins 18, 10)
These pins are connected to the main outputs and provide the
voltage feedback signal for the respective PWM controllers.
The PGOOD, overvoltage protection (OVP) and undervoltage
shutdown circuits use these signals to determine output-
FN9032 Rev 1.00
Aug 2004
PGOOD (Pin 12)
PGOOD is an open drain output used to indicate the status of
the PWM converters’ output voltages. This pin is pulled low
when any of the outputs except PWM3 (12V) is not within -10%
of respective nominal voltages, or when PWM3 (12V) is not
within its undervoltage and overvoltage thresholds.
GND (Pin 14)
Signal ground for the IC. All voltage levels are measured with
respect to this pin.
General Description
The IPM6220A addresses the system electronics power needs
of modern notebook and sub-notebook PCs. The IC integrates
control circuits for two synchronous buck converters for 5V
Main and 3.3V Main buses, two linear regulators for 3.3V
ALWAYS and 5V ALWAYS, and a 12V boost converter.
Page 6 of 14
IPM6220A
The two synchronous converters operate out of phase to
substantially reduce the input-current ripple, minimizing input
filter requirements, minimizing battery heating and prolonging
battery life.
The 12V boost controller uses a 100kHz clock derived from the
main clock. This controller uses leading edge modulation with
the maximum duty cycle limited to 33%.
The chip has three input control lines SDWN1, SDWN2 and
SDWNALL. These are provided for Advanced Configuration
and Power Interface (ACPI) compatibility. They turn on and off
all outputs, as well as provide independent control of the 3.3V
Main and +5V Main outputs.
To maximize efficiency for the 5V Main and 3.3V Main outputs, the
current-sense technique is based on the lower MOSFET rDS(ON).
Light-load efficiency is further enhanced by a hysteretic mode of
operation which is automatically engaged at light loads when the
inductor current becomes discontinuous.
3.3V Main and 5V Main Architecture
These main outputs are generated from the unregulated
battery input by two independent synchronous buck
converters. The IC integrates all the components required for
output voltage setpoint and feedback compensation,
significantly reducing the number of external components,
saving board space and parts cost.
The buck PWM controllers employ a 300kHz fixed frequency
current-mode control scheme with input voltage feed-forward
ramp programming for better rejection of input voltage
variations.
Figure 4 shows the out-of-phase operation for the 3.3V Main
and 5V Main outputs. The phase node is the junction of the
upper MOSFET, lower MOSFET and the output inductor. The
phase node is high when the upper MOSFET is conducting
and the inductor current rises accordingly. When the phase
node is low, the lower MOSFET is conducting and the inductor
current is ramping down as shown.
VIN = 10.8V
IL3.3V (2A/DIV.)
5A
3.3V PHASE (10V/DIV.)
0 A, V
5A
IL5V (2A/DIV.)
0 A, V
5V PHASE (10V/DIV.)
1s/DIV.
FIGURE 4. OUT OF PHASE OPERATION
where IOCDC is the desired DC overcurrent limit; RCS is either
the rDS(ON) of the lower MOSFET, or the value of the optional
current-sense resistor, Vo is the output voltage and L is the
output inductor. Also, the value of RCS should be specified for
the expected maximum operating temperature.
The sensed voltage, and the resulting current out of the ISEN
pin through RSNS, is used for current feedback and current
limit protection. This is compared with an internal current limit
threshold. When a sampled value of the output current is
determined to be above the current limit threshold, the PWM
drive is terminated and a counter is initiated. This limits the
inductor current build-up and essentially switches the
converter into current-limit mode. If an overcurrent is detected
between 26s to 53s later, an overcurrent shutdown is
initiated. If during the 26s to 53s period, an overcurrent is
not detected, the counter is reset and sampling continues as
normal.
This current limit scheme has proven to be very robust in
applications like portable computers where fast inductor
current build-up is common due to a large difference between
input and output voltages and a low value of the inductor.
Current Sensing and Current Limit Protection
Light-Load (Hysteretic) Operation
Both PWM converters use the lower MOSFET on-state
resistance, rDS(ON), as the current-sensing element. This
technique eliminates the need for a current sense resistor
and the associated power losses. If more accurate current
protection is desired, current sense resistors may be used in
series with the lower MOSFETs’ source.
In the light-load (hysteretic) mode the output voltage is
regulated by the hysteretic comparator which regulates the
output voltage by maintaining the output voltage ripple as
shown in Figure 5. In Hysteretic mode, the inductor current
flows only when the output voltage reaches the lower limit of
the hysteretic comparator and turns off at the upper limit.
Hysteretic mode saves converter energy at light loads by
supplying energy only at the time when the output voltage
requires it. This mode conserves energy by reducing the power
dissipation associated with continuous switching.
To set the current limit, place a resistor, RSNS, between the
ISEN inputs and the drain of the lower MOSFET (or optional
current sense resistor). The required value of the RSNS
resistor is determined from the following equation:
Rcs
Vo
RSNS = ------------------  Iocdc + ----------------------------------------- – 100
135A 
L  2  300kHz
FN9032 Rev 1.00
Aug 2004
During the time between inductor current pulses, both the
upper and lower MOSFETs are turned off. This is referred to as
‘diode emulation mode’ because the lower MOSFET performs
the function of a diode. This diode emulation mode prevents
Page 7 of 14
IPM6220A
the output capacitor from discharging through the lower
MOSFET when the upper MOSFET is not conducting.
This transition technique prevents jitter of the operation mode
at load levels close to boundary.
The gate drive is synchronized to the main clock, so the out-ofphase timing is maintained in hysteretic mode. Such a scheme
insures a seamless transition between the operational modes.
The other mechanism for changing from hysteretic to PWM is
due to a sudden increase in the output current. This step load
causes an instantaneous decrease in the output voltage due to
the voltage drop on the output capacitor ESR. If the decrease
causes the output voltage to drop below the hysteretic
regulation level, the mode is changed to PWM on the next
clock cycle. This insures the full power required by the
increase in output current.
VOUT
t
IL
t
PHASE
COMP
t
1 2 3 4 5 6 7 8
MODE
OF
OPERATION
PWM
IL
t
HYSTERETIC
t
FIGURE 5. REGULATION IN HYSTERETIC MODE
Operation-Mode Control
The mode-control circuit changes the converter’s mode of
operation based on the voltage polarity of the phase node
when the lower MOSFET is conducting and just before the
upper MOSFET turns on. For continuous inductor current, the
phase node is negative when the lower MOSFET is conducting
and the converters operate in fixed-frequency PWM mode as
shown in Figure 6. When the load current decreases to the
point where the inductor current flows through the lower
MOSFET in the ‘reverse’ direction, the phase node becomes
positive, and the mode is changed to hysteretic.
A phase comparator handles the timing of the phase node
voltage sensing. A low level on the phase comparator output
indicates a negative phase voltage during the conduction time
of the lower MOSFET. A high level on the phase comparator
output indicates a positive phase voltage.
When the phase node is positive (phase comparator high), at
the end of the lower MOSFET conduction time, for eight
consecutive clock cycles, the mode is changed to hysteretic as
shown in Figure 6. The dashed lines indicate when the phase
node goes positive and the phase comparator output goes
high. The solid vertical lines at 1,2,...8 indicate the sampling
time, of the phase comparator, to determine the polarity (sign)
of the phase node. At the transition between PWM and
hysteretic mode, both the upper and lower MOSFETs are
turned off. The phase node will ‘ring’ based on the output
inductor and the parasitic capacitance on the phase node and
settle out at the value of the output voltage.
The mode change from hysteretic to PWM can be caused by
one of two events. One event is the same mechanism that
causes a PWM to hysteretic transition. But instead of looking
for eight consecutive positive occurrences on the phase node,
it is looking for eight consecutive negative occurrences on the
phase node. The operation mode will be changed from
hysteretic to PWM when these eight consecutive pulses occur.
FN9032 Rev 1.00
Aug 2004
PHASE
NODE
t
1
2
3
4
5
6
7
8
PHASE
COMP
t
MODE
OF
OPERATION
PWM
HYSTERETIC
t
FIGURE 6. MODE CONTROL WAVEFORMS
Gate Control Logic
The gate control logic translates generated PWM control
signals into the MOSFET gate drive signals providing
necessary amplification, level shifting and shoot-through
protection. Also, it has functions that help optimize the IC
performance over a wide range of operational conditions.
Since MOSFET switching time can vary dramatically from type
to type and with the input voltage, the gate control logic
provides adaptive dead time by monitoring the gate-to-source
voltages of both upper and lower MOSFETs. The lower
MOSFET is not turned on until the gate-to-source voltage of
the upper MOSFET has decreased to less than approximately
1 volt. Similarly, the upper MOSFET is not turned on until the
gate-to-source voltage of the lower MOSFET has decreased to
less than approximately 1 volt. This allows a wide variety of
upper and lower MOSFETs to be used without a concern for
simultaneous conduction, or shoot-through.
3.3V Main and 5V Main Soft Start, Sequencing and
Stand-by
See Table 1 for the output voltage control algorithm. The 5V
Main and 3.3V Main converters are enabled if SDWN1 and
SDWN2 are high and SDWNALL is also high. The stand-by mode
is defined as a condition when SDWN1 and SDWN2 are low and
the PWM converters are disabled but SDWNALL is high (3.3V
Page 8 of 14
IPM6220A
ALWAYS and 5V ALWAYS outputs are enabled). In this power
saving mode, only the low power micro-controller and keyboard
may be powered.
12V Converter Architecture
TABLE 1. OUTPUT VOLTAGE CONTROL
SDWNALL SDWN1
same value of soft-start capacitors, 0.022F, they both reach
regulation at the same time, T3. The soft-start capacitors
continue to charge and are completely charged at T4.
3V AND 5V
SDWN2 ALWAYS 5V MAIN 3V MAIN
0
X
X
OFF
OFF
OFF
1
0
0
ON
OFF
OFF
1
1
0
ON
ON
OFF
1
0
1
ON
OFF
ON
1
1
1
ON
ON
ON
Soft start of the 3.3V Main and 5V Main converters is
accomplished by means of capacitors connected from pins
SDWN1 and SDWN2 to ground. In conjunction with 5A
internal current sources, they provide a controlled rise of the
3.3V Main and 5V Main output voltages. The value of the softstart capacitors can be calculated from the following
expression.
5A  Tss
Css = ---------------------------3.5V
The 12V boost converter generates its output voltage from the
5V Main output. An external MOSFET, inductor, diode and
capacitor are required to complete the circuit. The output signal
is fed back to the controller via an external resistive divider.
The boost controller can be disabled by connecting the VSEN3
pin to 5V ALWAYS.
The control circuit for the 12V converter consists of a 3:1
frequency divider which drives a ramp generator and resets a
PWM latch as shown in Figure 8. The width of the CLK/3
pulses is equal to the period of the main clock, limiting the duty
cycle to 33%. The output of a non-inverting error amplifier is
compared with the rising ramp voltage. When the ramp voltage
becomes higher than the error signal, the PWM comparator
sets the latch and the output of the gate driver is pulled high
providing leading edge, voltage mode PWM. The falling edge
of the CLK/3 pulses resets the latch and pulls the output of the
gate driver low.
VSEN3
By varying the values of the soft-start capacitors, it is possible to
provide sequencing of the main outputs at startup.
-
REF
CLK/3
Figure 7 shows the soft-start initiated by the SDWNALL pin
being pulled high with the Vbatt input at 10.8V and the
resulting 3.3V Main and 5V Main outputs.
CLK
DIVIDER
3:1
CLK/3
EA3
+
+
Where Tss is the desired soft-start time.
GATE3
PWM
PWM
COMPARATOR LATCH 3
S Q
RAMP
R Q
RAMP
GENERATOR
CLK
VIN = 10.8V
SDWNALL,10V/DIV.
t
CLK/3
t
RAMP
SDWN2, 2V/DIV.
3.3VOUT, 2V/DIV.
VEA3
t
GATE3
0V
FIGURE 8. 12V BOOST OPERATION
SDWN1, 2V/DIV.
5VOUT, 2V/DIV.
0V
4ms/DIV.
T0 T1
T2
T3
T4
FIGURE 7. SOFT-START ON 3.3V AND 5V OUTPUTS
While the SDWNALL pin is held low, prior to T0, all outputs are
off. Pulling SDWNALL high enables the 3.3V ALWAYS and 5V
ALWAYS outputs. With the 3.3V Main and 5V Main outputs
enabled, at T1, the internal 5A current sources start charging
the soft start capacitors on the SDWN1 and SDWN2 pins. At
T2 the outputs begin to rise and because they both have the
FN9032 Rev 1.00
Aug 2004
t
The 33% maximum duty cycle of the converter guarantees
discontinuous inductor current and unconditional stability over
all operating conditions.
The boost converter with the limited duty cycle and
discontinuous inductor current can deliver to the load a limited
amount of power before the output voltage starts to drop.
When the duty cycle has reached DMAX, the control loop is
Page 9 of 14
IPM6220A
operating open circuit and the output voltage varies with the
output load resistance, Ro, as given by:
Ro
Vo = Vin  Dmax  -------------------
 2  LxF 
Where Vin is the 5V Main voltage, Dmax = 0.33, L is the value
of the boost inductor, L3, and F = 100kHz. This provides
automatic output current limiting. When the maximum duty
cycle has been reached and for a given inductor, a further
reduction in Ro by one-half will pull the output voltage down to
0.707 of nominal and cause an undervoltage condition.
The 12V converter starts to operate at the same time as the 5V
Main converter. The rising voltage on the 5V Main output and
the 33% duty cycle limit provides a similar soft-start, as the 5V
Main, for the 12V output.
3V ALWAYS, 5V ALWAYS Linear Regulators
The 3.3V ALWAYS and 5V ALWAYS outputs are derived from
the battery voltage and are the first voltages available in the
notebook when power on is initiated. The 5V ALWAYS output
is generated directly from the battery voltage by a linear
regulator. It is used to power the system micro- controller and
to internally power the chip and the gate drivers. The 3.3V
ALWAYS output is generated from the 5V ALWAYS output and
may be used to power the keyboard controller or other
peripherals. The combined current capability of these outputs
is 50mA. When the 5V Main output is greater than it’s
undervoltage level, it is switched to the 5V ALWAYS output via
an internal 1.3 MOSFET switch. Simultaneously, the 5V
ALWAYS linear regulator is disabled to prevent excessive
power dissipation.
The rise time of the 5V ALWAYS is determined by the value of
the output capacitance on the 5V and 3.3V ALWAYS outputs.
The internal regulator is current limited to about 180mA, so the
startup time is approximately:
5V
t = C OUT  ------------------180mA
Where COUT is the sum of the capacitances on the 5V and
3.3V ALWAYS outputs.
Power Good Status
The IPM6220A monitors all the output voltages except for the
3.3V ALWAYS. A single power-good signal, PGOOD, is issued
when soft-start is completed and all monitored outputs are
within 10% of their respective set points. After the soft-start
sequence is completed, undervoltage protection latches the
chip off when any of the monitored outputs drop below 75% of
its set point.
A ‘soft-crowbar’ function is implemented for an overvoltage on
the 3.3V Main or 5V Main outputs. If the output voltage goes
above 115% of their nominal output level, the upper MOSFET
is turned off and the lower MOSFET is turned on. This ‘softcrowbar’ condition will be maintained until the output voltage
FN9032 Rev 1.00
Aug 2004
returns to the regulation window and then normal operation will
continue.
This ‘soft-crowbar’ and monitoring of the output, prevents the
output voltage from ringing negative as the inductor current
flows in the ‘reverse’ direction through the lower MOSFET and
output capacitors.
Over-Temperature Protection
The IC incorporates an over-temperature protection circuit that
shuts all the outputs down when the die temperature exceeds
150°C. Normal operation is automatically restored when the
die temperature cools to 125°C.
Component Selection Guidelines
Output Capacitor Selection
The output capacitors for each output have unique
requirements. In general, the output capacitors should be
selected to meet the dynamic regulation requirements
including ripple voltage and load transients.
3.3V Main and 5V Main PWM Output Capacitors
Selection of the output capacitors is also dependent on the
output inductor so some inductor analysis is required to select
the output capacitors.
One of the parameters limiting the converter’s response to a
load transient is the time required for the inductor current to
slew to its new level. Given a sufficiently fast control loop
design, the IPM6220A will provide either 0% or 94% duty cycle
in response to a load transient. The response time is the time
interval required to slew the inductor current from an initial
current value to the load current level. During this interval the
difference between the inductor current and the transient
current level must be supplied by the output capacitor(s).
Minimizing the response time can minimize the output
capacitance required. Also, if the load transient rise time is
slower than the inductor response time, as in a hard drive or
CD drive, this reduces the requirement on the output capacitor.
The maximum capacitor value required to provide the full,
rising step, transient load current during the response time of
the inductor is:
I TRAN
L O  I TRAN
C OUT = ----------------------------------------------  ------------------- V IN – V OUT   2 DV OUT
Where: COUT is the output capacitor(s) required, LO is the
output inductor, ITRAN is the transient load current step, VIN is
the input voltage, VOUT is output voltage, and VOUT is the
drop in output voltage allowed during the load transient.
High frequency capacitors initially supply the transient current
and slow the load rate-of-change seen by the bulk capacitors.
The bulk filter capacitor values are generally determined by the
ESR (Equivalent Series Resistance) and voltage rating
requirements as well as actual capacitance requirements. The
Page 10 of 14
IPM6220A
V RIPPLE = I L  ESR
where, IL is calculated in the Inductor Selection section.
High frequency decoupling capacitors should be placed as
close to the power pins of the load as physically possible. Be
careful not to add inductance in the circuit board wiring that
could cancel the usefulness of these low inductance
components. Consult with the manufacturer of the load
circuitry for specific decoupling requirements.
Use only specialized low-ESR capacitors intended for
switching-regulator applications, at 300kHz, for the bulk
capacitors. In most cases, multiple electrolytic capacitors of
small case size perform better than a single large case
capacitor.
The stability requirement on the selection of the output
capacitor is that the ‘ESR zero’, fZ, be between 1.2kHz and
30kHz. This range is set by an internal, single compensation
zero at 6kHz. The ESR zero can be a factor of five on either
side of the internal zero and still contribute to increased phase
margin of the control loop. Therefore:
1
C OUT = ------------------------------------------2    ESR  f Z
In conclusion, the output capacitors must meet three criteria: By
varying the values of the soft-start capacitors, it is possible to
provide sequencing of the main outputs at start-up.
1. They must have sufficient bulk capacitance to sustain the
output voltage during a load transient while the output
inductor current is slewing to the value of the load transient
2. The ESR must be sufficiently low to meet the desired output
voltage ripple due to the output inductor current, and
3. The ESR zero should be placed, in a rather large range, to
provide additional phase margin.
3.3V ALWAYS and 5V ALWAYS Output Capacitors
The output capacitors for the linear regulators insure stability
and provide dynamic load current. The 3.3V ALWAYS and the
5V ALWAYS linear regulators should have, as a minimum,
10F capacitors on their outputs.
3.3V Main and 5V Main PWM Output Inductor
Selection
The PWM converters require output inductors. The output
inductor is selected to meet the output voltage ripple
requirements. The inductor value determines the converter’s
ripple current and the ripple voltage is a function of the ripple
current and output capacitor(s) ESR. The ripple voltage
expression is given in the capacitor selection section and the
ripple current is approximated by the following equation:
V IN – V OUT V OUT
I L = --------------------------------  ---------------V IN
FS  L
FN9032 Rev 1.00
Aug 2004
Input Capacitor Selection
The important parameters for the bulk input capacitor(s) are
the voltage rating and the RMS current rating. For reliable
operation, select bulk input capacitors with voltage and current
ratings above the maximum input voltage and largest RMS
current required by the circuit. The capacitor voltage rating
should be at least 1.25 times greater than the maximum input
voltage and 1.5 times is a conservative guideline.
The AC RMS input current varies with load as shown in Figure
9. Depending on the specifics of the input power and its
impedance, most (or all) of this current is supplied by the input
capacitor(s). Figure 9 also shows the advantage of having the
PWM converters operating out of phase. If the converters were
operating in-phase, the combined RMS current would be the
algebraic sum, which is a much larger value as shown. The
combined out-of-phase current is the square root of the sum of
the square of the individual reflected currents and is
significantly less than the combined in-phase current.
INPUT RMS CURRENT
output voltage ripple is due to the inductor ripple current and
the ESR of the output capacitors as defined by:
5
4.5
4
3.5
3
2.5
2
1.5
1
0.5
0
IN PHASE
OUT OF PHASE
5V
3.3V
0
1
2
3
3.3V AND 5V LOAD CURRENT
4
5
FIGURE 9. INPUT RMS CURRENT vs LOAD
Use a mix of input bypass capacitors to control the voltage
ripple across the MOSFETs. Use ceramic capacitors for the
high frequency decoupling and bulk capacitors to supply the
RMS current. Small ceramic capacitors can be placed very
close to the upper MOSFET to suppress the voltage induced in
the parasitic circuit impedances.
For board designs that allow through-hole components, the
Sanyo OS-CON® series offer low ESR and good temperature
performance.
For surface mount designs, solid tantalum capacitors can be
used, but caution must be exercised with regard to the
capacitor surge current rating. These capacitors must be
capable of handling the surge-current at power-up. The TPS
series available from AVX is surge current tested.
+12V Boost Converter Inductor Selection
The inductor value is chosen to provide the required output
power to the load.
Vinmin 2  Dmax 2  Ro
Lmax = ---------------------------------------------------------------2  Vo 2  F
where, Vinmin is the minimum input voltage, 4.9V; Dmax = 1/3,
the maximum duty cycle; Ro is the minimum load resistance;
Page 11 of 14
IPM6220A
Vo is the nominal output voltage and F is the switching
frequency, 100kHz.
+12V Boost Converter Output Capacitor Selection
The total capacitance on the 12V output should be chosen
appropriately, so that the output voltage will be higher than the
undervoltage limit (9V) when the 5V Main soft-start time has
elapsed. This will avoid triggering of the 12V undervoltage
protection.
The maximum value of the boost capacitor, Comax that will
charge to 9V in the soft-start time, Tss, is shown below, where
L is the value of the boost inductor.
Tss
Comax = ----------  0.115F
L
The output capacitor ESR and the boost inductor ripple current
determines the output voltage ripple. The ripple voltage is
given by:
V RIPPLE = I L  ESR
and the maximum ripple current, IL, is given by:
5V
I L = -------  3.3 
L
where L is the boost inductor calculated above, 5V is the boost
input voltage and 3.3 is the maximum on time for the boost
MOSFET.
MOSFET Considerations
The logic level MOSFETs are chosen for optimum efficiency
given the potentially wide input voltage range and output power
requirements. Two N-channel MOSFETs are used in each of
the synchronous-rectified buck converters for the PWM1 and
PWM2 outputs. These MOSFETs should be selected based
upon rDS(ON) , gate supply requirements, and thermal
management considerations.
The power dissipation includes two loss components;
conduction loss and switching loss. These losses are
distributed between the upper and lower MOSFETs according
to duty cycle (see the following equations). The conduction
losses are the main component of power dissipation for the
lower MOSFETs. Only the upper MOSFET has significant
switching losses, since the lower device turns on and off into
near zero voltage.
2
I O  r DS  ON   V OUT I O  V IN  t SW  F S
P UPPER = ------------------------------------------------------------ + ---------------------------------------------------V IN
2
2
I O  r DS  ON    V IN – V OUT 
P LOWER = --------------------------------------------------------------------------------V IN
The equations assume linear voltage-current transitions and
do not model power loss due to the reverse-recovery of the
lower MOSFET’s body diode. The gate-charge losses are
dissipated by the IPM6220A and do not heat the MOSFETs.
However, a large gate-charge increases the switching time,
tSW, which increases the upper MOSFET switching losses.
Ensure that both MOSFETs are within their maximum junction
FN9032 Rev 1.00
Aug 2004
temperature at high ambient temperature by calculating the
temperature rise according to package thermal-resistance
specifications.
Layout Considerations
MOSFETs switch very fast and efficiently. The speed with which
the current transitions from one device to another causes
voltage spikes across the interconnecting impedances and
parasitic circuit elements. The voltage spikes can degrade
efficiency, radiate noise into the circuit, and lead to device
overvoltage stress. Careful component layout and printed circuit
design minimizes the voltage spikes in the converter. Consider,
as an example, the turn-off transition of one of the upper PWM
MOSFETs. Prior to turn-off, the upper MOSFET is carrying the
full load current. During the turn-off, current stops flowing in the
upper MOSFET and is picked up by the lower MOSFET. Any
inductance in the switched current path generates a voltage
spike during the switching interval. Careful component selection,
tight layout of the critical components, and short, wide circuit
traces minimize the magnitude of voltage spikes. See the
Application Note AN9915 for the evaluation board component
placement and the printed circuit board layout details.
There are two sets of critical components in a DC-DC
converter using an IPM6220A controller. The switching power
components are the most critical because they switch large
amounts of energy, and as such, they tend to generate equally
large amounts of noise. The critical small signal components
are those connected to sensitive nodes or those supplying
critical bias currents.
Power Components Layout Considerations
The power components and the controller IC should be placed
first. Locate the input capacitors, especially the high-frequency
ceramic decoupling capacitors, close to the power MOSFETs.
Locate the output inductor and output capacitors between the
MOSFETs and the load. Locate the PWM controller close to
the MOSFETs.
Insure the current paths from the input capacitors to the
MOSFETs, to the output inductors and output capacitors are as
short as possible with maximum allowable trace widths.
A multi-layer printed circuit board is recommended. Dedicate
one solid layer for a ground plane and make all critical
component ground connections with vias to this layer. Dedicate
another solid layer as a power plane and break this plane into
smaller islands of common voltage levels. The power plane
should support the input power and output power nodes. Use
copper filled polygons on the top and bottom circuit layers for the
phase nodes, but do not unnecessarily oversize these particular
islands. Since the phase nodes are subjected to very high dV/dt
voltages, the stray capacitor formed between these islands and
the surrounding circuitry will tend to couple switching noise. Use
the remaining printed circuit layers for small signal wiring. The
wiring traces from the control IC to the MOSFET gate and
source should be sized to carry 2A peak currents.
Page 12 of 14
IPM6220A
6. The bypass capacitors for VBATT and the soft-start
capacitors, CSS1 and CSS2 should be located close to their
connecting pins on the control IC. Minimize any leakage
current paths from SDWN1 and SDWN2 nodes, since the
internal current source is only 5A.
Small Components Signal Layout Considerations
4. The VSNS1 and VSNS2 inputs should be bypassed with a
1.0F capacitor close to their respective IC pins.
5. A ‘T’ filter consisting of a ‘split’ RSNS and a small, 100pF,
capacitor as shown in Figure 10, may be helpful in reducing
noise coupling into the ISEN input. For example, if the
calculated value of RSNS1 is 2.2k, dividing it as shown
with a 100pF capacitor provides filtering without changing
the current limit set point. For any calculated value of
RSNS, keep the value of the R9 portion to approximately
200, and the remainder of the resistance in the R19
position. The 200 resistor and 100pF capacitor provide
effective filtering for noise above 8MHz.
7. Refer to the Application Note AN9915 for a recommended
component placement and interconnections.
Figure 11 shows an application circuit of a power supply for a
notebook PC microprocessor system. The power supply provides
+5V ALWAYS, +3.3V ALWAYS, +5.0V, +3.3V, and 12V from +5.622VDC battery voltage. For detailed information on the circuit,
including a Bill of Materials and circuit board description, see
Application Note AN9915. Also see Intersil’s web site
(www.intersil.com) for the latest information.
This filter configuration may be helpful on both the 3.3V and 5V
Main outputs.
RSNS = R19 + R9
R19
2K
ISEN1
R9
200
C12
100pF
FROM PHASE
NODE
FIGURE 10. NOISE FILTER FOR ISEN1 INPUT
+5.6-22VIN
C4
56F
C3, 6, 10
3x1F
D2
BAT54WT1
GND
VBATT
1
+3.3V ALWAYS
(50mA)
3.3V ALWAYS
+
+5V ALWAYS
(50mA)
+
5V ALWAYS
C1
100F
+3.3V
(5A)
Q2
HUF76112SK8
R10, 11 ISEN2
C22
330F
6
22
BOOT1
20
19
4
Q4
HUF76112SK8
LGATE2
PGND2
VSEN2
SDWN2
C16
0.022F
PGOOD
C9
0.15F
PHASE1
L4
2.7H
ISEN1 R9, 19
2.2K
IPM6220A
3
Q3
HUF76112SK8
UGATE1
LGATE1
PGND1
9
18
7
16
+5V
(5A)
L2
8.2H
+
Q5
HUF76112SK8
L3
6.8H
+
C21, 32
2x330F
C36
22F
5
VSEN1
2.2K
8.2H
+
UGATE2
PHASE2
L1
23
21
D1
BAT54WT1
BOOT2
C7
0.15F
24
2
C2
10F
GATE3
+12V
(120mA)
D3
Q5
HUF76112SK8
+
R14
97.6K
C24, 33
2x47F
8
10
15
11
17
12
14
13
R13
24.9K
VSEN3
SDWN1
C17
0.022F
SDWNALL
GND
FIGURE 11. APPLICATIONS CIRCUIT
FN9032 Rev 1.00
Aug 2004
Page 13 of 14
IPM6220A
Shrink Small Outline Plastic Packages (SSOP)
Quarter Size Outline Plastic Packages (QSOP)
M24.15
N
INDEX
AREA
H
0.25(0.010) M
E
2
SYMBOL
3
0.25
0.010
SEATING PLANE
-A-
INCHES
GAUGE
PLANE
-B1
24 LEAD SHRINK SMALL OUTLINE PLASTIC PACKAGE
(0.150” WIDE BODY)
B M
A
D
h x 45°
-C-
e
0.17(0.007) M

A2
A1
B
L
C
0.10(0.004)
C A M
B S
NOTES:
1. Symbols are defined in the “MO Series Symbol List” in Section 2.2
of Publication Number 95.
2. Dimensioning and tolerancing per ANSI Y14.5M-1982.
MIN
MAX
MILLIMETERS
MIN
MAX
NOTES
A
0.053
0.069
1.35
1.75
-
A1
0.004
0.010
0.10
0.25
-
A2
-
0.061
-
1.54
-
B
0.008
0.012
0.20
0.30
9
C
0.007
0.010
0.18
0.25
-
D
0.337
0.344
8.55
8.74
3
E
0.150
0.157
3.81
3.98
4
e
0.025 BSC
0.635 BSC
-
H
0.228
0.244
5.80
6.19
-
h
0.0099
0.0196
0.26
0.49
5
L
0.016
0.050
0.41
1.27
6
N

24
0°
24
8°
0°
3. Dimension “D” does not include mold flash, protrusions or gate
burrs. Mold flash, protrusion and gate burrs shall not exceed
0.15mm (0.006 inch) per side.
7
8°
Rev. 2 6/04
4. Dimension “E” does not include interlead flash or protrusions. Interlead flash and protrusions shall not exceed 0.25mm (0.010 inch)
per side.
5. The chamfer on the body is optional. If it is not present, a visual index feature must be located within the crosshatched area.
6. “L” is the length of terminal for soldering to a substrate.
7. “N” is the number of terminal positions.
8. Terminal numbers are shown for reference only.
9. Dimension “B” does not include dambar protrusion. Allowable dambar protrusion shall be 0.10mm (0.004 inch) total in excess of “B”
dimension at maximum material condition.
10. Controlling dimension: INCHES. Converted millimeter dimensions
are not necessarily exact.
© Copyright Intersil Americas LLC 2004. All Rights Reserved.
All trademarks and registered trademarks are the property of their respective owners.
For additional products, see www.intersil.com/en/products.html
Intersil products are manufactured, assembled and tested utilizing ISO9001 quality systems as noted
in the quality certifications found at www.intersil.com/en/support/qualandreliability.html
Intersil products are sold by description only. Intersil may modify the circuit design and/or specifications of products at any time without notice, provided that such
modification does not, in Intersil's sole judgment, affect the form, fit or function of the product. Accordingly, the reader is cautioned to verify that datasheets 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
FN9032 Rev 1.00
Aug 2004
Page 14 of 14
Similar pages