MAXIM MAX8855ETJ+

19-0726; Rev 2; 4/09
KIT
ATION
EVALU
E
L
B
AVAILA
Dual, 5A, 2MHz Step-Down Regulator
The MAX8855 high-efficiency, dual step-down regulator
is capable of delivering up to 5A at each output. The
device operates from a 2.35V to 3.6V supply, and provides output voltages from 0.6V to 0.9 x VIN, making it
ideal for on-board point-of-load applications. Total output
error is less than ±1% over load, line, and temperature.
The MAX8855 operates in PWM mode with a switching
frequency ranging from 0.5MHz to 2MHz, set by an
external resistor. It can also be synchronized to an
external clock in the same frequency range. Two internal switching regulators operate 180° out-of-phase to
reduce the input ripple current, and consequently
reduce the required input capacitance. The high
operating frequency minimizes the size of external
components. High efficiency, internal dual-nMOS
design keeps the board cool under heavy loads. The
voltage-mode control architecture and the high-bandwidth (> 15MHz typ) voltage-error amplifier allow a type
III compensation scheme to be utilized to achieve fast
response under both line and load transients, and also
allow for ceramic output capacitors.
Programmable soft-start reduces input inrush current.
Two enable inputs allow the turning on/off of each output individually, resulting in great flexibility for systemlevel designs. A reference input is provided to facilitate
output-voltage tracking applications. The MAX8855 is
available in a 32-pin thin QFN (5mm x 5mm) package
with 0.8mm max height.
Applications
Features
o 27mΩ On-Resistance Internal MOSFETs
o Dual, 5A, PWM Step-Down Regulators
o Fully Protected Against Overcurrent,
Short Circuit, and Overtemperature
o ±1% Output Accuracy Over Load, Line,
and Temperature
o Operates from 2.35V to 3.6V Supply
o REFIN on One Channel for Tracking or
External Reference
o Integrated Boost Diodes
o Adjustable Output from 0.6V to 0.9 x VIN
o Soft-Start Reduces Inrush Supply Current
o 0.5MHz to 2MHz Adjustable Switching,
or FSYNC Input
o All-Ceramic-Capacitor Design
o 180° Out-of-Phase Operation Reduces Input
Ripple Current
o Individual Enable Inputs and PWRGD Outputs
o Safe-Start into Prebiased Output
o Available in 5mm x 5mm Thin QFN Package
o Sink/Source Current in DDR Applications
Ordering Information
PART
TEMP RANGE
PIN-PACKAGE
MAX8855ETJ+
-40°C to +85°C
32 Thin QFN-EP*
+Denotes a lead(Pb)-free/RoHS-compliant package.
*EP = Exposed pad.
ASIC/CPU/DSP Power Supplies
Typical Operating Circuit
DDR Power Supplies
Set-Top Box Power Supplies
Printer Power Supplies
Network Power Supplies
INPUT2
2.35V TO 3.6V
INPUT1
2.35V TO 3.6V
IN1 IN2
BST1
BST2
OUTPUT1
1.2V / 5A
LX1
PGND1
OUTPUT2
1.5V / 5A
LX2
PGND2
MAX8855
FB2
FB1
COMP1
COMP2
TYPE III
COMPENSATION
TYPE III
COMPENSATION
PWRGD1 PWRGD2
ON
OFF
EN1
GND
ON
EN2
OFF
Pin Configuration appears at end of data sheet.
________________________________________________________________ Maxim Integrated Products
For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642,
or visit Maxim’s website at www.maxim-ic.com.
1
MAX8855
General Description
MAX8855
Dual, 5A, 2MHz Step-Down Regulator
ABSOLUTE MAXIMUM RATINGS
IN_, LX_, VDD, VDL, PWRGD_ to GND..................-0.3V to +4.5V
VDD, VDL to IN_.....................................................-0.3V to +4.5V
EN_, SS_, COMP_, FB_, REFIN, FSYNC to GND ......-0.3V to the
lower of (VVDD + 0.3V) and (VVDL + 0.3V)
Continuous LX_ Current (Note 1) ...................................5.5ARMS
BST_ to LX_ ...........................................................-0.3V to +4.5V
PGND_ to GND......................................................-0.3V to +0.3V
Continuous Power Dissipation (TA = +70°C)
32-Pin Thin QFN (5mm x 5mm)
(derate 34.5mW/°C above +70°C) ..........................2758.6mW
Operating Ambient Temperature Range .............-40°C to +85°C
Operating Junction Temperature Range ...........-40°C to +125°C
Storage Temperature Range .............................-65°C to +150°C
Lead Temperature (soldering, 10s) .................................+300°C
θJC ...................................................................................1.7°C/W
Note 1: LX_ have internal clamp diodes to PGND_ and IN_. Applications that forward bias these diodes should take care not to
exceed the IC’s package power-dissipation limits.
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
ELECTRICAL CHARACTERISTICS
(VIN = VVDD = VVDL = 3.3V, VFB = 0.5V, VSS_ = VREFIN = 600mV, PGND_ = GND, RFSYNC = 10kΩ, L = 0.47µH, CBST_ = 0.1µF, CSS =
0.022µF, PWRGD not connected; TA = -40°C to +85°C, typical values are at TA = +25°C, unless otherwise noted.) (Note 2)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
3.60
V
IN1, IN2, VDL, VDD
IN_, VDL, and VDD Voltage Range
(Note 3)
IN_ Supply Current
1MHz switching, no load
VDD + VDL Supply Current
1MHz switching, VDD = VDL
Shutdown Supply Current
(IIN1 + IIN2 + IVDD + IVDL)
VIN_ = VVDD = VVDL = VBST_
- VLX_ = 3.6V, VEN_ = 0V
IN_, VDD Undervoltage Lockout Threshold
UVLO Monitors VDD, IN1, and IN2
Rising
2.35
VIN = 2.5V
1.9
3.5
VIN = 3.3V
2.8
5
VVDD = 2.5V
7.2
VVDD = 3.3V
10
TA = +25°C
11
TA = +85°C
0.3
2.0
Falling
15
1.8
IN_, VDD Undervoltage Lockout Deglitch
2.2
1.9
2
mA
mA
µA
V
µs
BST1, BST2
Shutdown BST_ Current
VIN_ = VVDD = VVDL = VBST_ =
3.6V, VEN_ = 0V, VLX_ = 0 or 3.6V
TA = +25°C
2
TA = +85°C
0.02
µA
COMP1, COMP2
COMP Clamp Voltage, High
VVDD = VIN_ = 2.3V to 3.6V, VFB_ = 0.7V
1.80
COMP Slew Rate
COMP Shutdown Resistance
2.00
2.25
1.40
From COMP_ to GND, VEN_ = 0V
V
V/µs
7
25
Ω
ERROR AMPLIFIER
FB_ Regulation Voltage
VCOMP_ = 1V to 2V VVDD = VIN = 2.5V to 3.3V
0.594
0.600
0.606
V
FB_ Regulation Voltage with
External Reference
VCOMP_ = 1V to 2V VVDD = VIN = 2.5V to 3.3V
0.594
0.600
0.606
V
VVDD 1.6
V
Error Amplifier Common-Mode-Input Range
0
Error Amplifier Maximum Output Current
FB_ Input Bias Current
2
1
VFB_ = 0.605V
mA
TA = +25°C
40
TA = +85°C
37
_______________________________________________________________________________________
300
nA
Dual, 5A, 2MHz Step-Down Regulator
(VIN = VVDD = VVDL = 3.3V, VFB = 0.5V, VSS_ = VREFIN = 600mV, PGND_ = GND, RFSYNC = 10kΩ, L = 0.47µH, CBST_ = 0.1µF, CSS =
0.022µF, PWRGD not connected; TA = -40°C to +85°C, typical values are at TA = +25°C, unless otherwise noted.) (Note 2)
PARAMETER
CONDITIONS
MIN
TYP
MAX
TA = +25°C
90
500
TA = +85°C
65
UNITS
REFIN, SS2
REFIN Input Bias Current
VFB_ = 0.610V
VVDD = 2.35V to 2.6V
0
VVDD 1.65
0
VVDD 1.70
REFIN Common-Mode Range
nA
V
VVDD = 2.6V to 3.6V
LX1, LX2 (All Pins Combined)
VIN = VBST - VLX_ = 3.3V
31
VIN = VBST - VLX_ = 2.5V
34
LX_ On-Resistance, High
ILX_ = -2A
LX_ On-Resistance, Low
ILX_ = -2A
LX_ Current-Limit Threshold
High-side sourcing and freewheeling
LX_ Leakage Current
LX_ Switching Frequency
VIN = 3.6V,
VEN = 0V
VIN = 3.3V
27
VIN = 2.5V
29
VLX_ = 3.6V
VLX_ = 0V
7.0
8.3
TA = +25°C
46
9.6
mΩ
mΩ
A
+0.1
TA = +85°C
TA = +25°C
52
-0.1
µA
-10
TA = +85°C
-0.1
RFSYNC = 10kΩ
0.9
1.0
1.1
RFSYNC = 4.75kΩ
1.80
2.0
2.2
MHz
LX_ Minimum Off-Time
50
ns
LX_ Minimum On-Time
95
ns
LX_ Maximum Duty Cycle
RFSYNC = 10kΩ
90
Maximum LX_ Output Current
95
%
3
ARMS
EN1, EN2
EN_ Logic-Low
0.7
EN_ Logic-High
1.7
VEN_ = 0 or 3.6V,
VVDD = 3.6V
EN_ Input Current
TA = +25°C
V
-1
TA = +85°C
V
+1
0.01
µA
SS1, SS2
SS_ Charging Current
VSS_ = 300mV
5
8
11
µA
REFIN, SS2
335
Ω
Thermal-Shutdown Threshold
(Independent Channels)
+165
°C
Thermal-Shutdown Hysteresis
20
°C
Discharge Resistance
In shutdown or a fault condition
THERMAL SHUTDOWN
_______________________________________________________________________________________
3
MAX8855
ELECTRICAL CHARACTERISTICS (continued)
ELECTRICAL CHARACTERISTICS (continued)
(VIN = VVDD = VVDL = 3.3V, VFB = 0.5V, VSS_ = VREFIN = 600mV, PGND_ = GND, RFSYNC = 10kΩ, L = 0.47µH, CBST_ = 0.1µF, CSS =
0.022µF, PWRGD not connected; TA = -40°C to +85°C, typical values are at TA = +25°C, unless otherwise noted.) (Note 2)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
2500
kHz
V
FSYNC
FSYNC Capture Range
250
FSYNC Input Threshold
1.3
1.5
1.7
FSYNC Output Voltage
0.975
1.0
1.025
Phase Shift from LX1 to LX2
180
V
Degrees
PWRGD1, PWRGD2
PWRGD1 Threshold Voltage
VFB1 rising with respect to VREFIN,
and VREFIN > 540mV typ
88
90
92
%
PWRGD2 Threshold Voltage
VFB2 rising with respect to VSS2,
and VSS2 > 540mV typ
88
90
92
%
45
55
µs
0.03
0.15
V
PWRGD_ Hysteresis
2.6
PWRGD_ Falling Edge Deglitch
35
PWRGD_ Output-Low Voltage
IPWRGD_ = 4mA
PWRGD_ Leakage Current
VPWRGD = 3.6V,
VFB_ = 0.9V
%
TA = +25°C
1
TA = +85°C
µA
0.01
Note 2: All devices 100% production tested at +25°C. Limits over temperature are guaranteed by design.
Note 3: VVDD must equal VVDL and be equal to or greater than VIN_.
Typical Operating Characteristics
(VIN1 = VIN2 = 3.3V. MAX8855, circuit of Figure 6, TA = +25°C, unless otherwise noted.)
VOUT = 2.5V
60
VOUT = 1.2V
80
EFFICIENCY (%)
70
90
VOUT = 1.8V
50
40
50
40
30
20
20
10
10
0
0
1000
LOAD CURRENT (mA)
10,000
VOUT = 1.8V
60
30
100
VOUT = 1.2V
70
2400
MAX8855 toc03
80
SWITCHING FREQUENCY vs. RFSYNC
MAX8855 toc02
90
4
100
MAX8855 toc01
100
EFFICIENCY
vs. LOAD CURRENT WITH 2.5V INPUT
2200
SWITCHING FREQUENCY (kHz)
EFFICIENCY
vs. LOAD CURRENT WITH 3.3V INPUT
EFFICIENCY (%)
MAX8855
Dual, 5A, 2MHz Step-Down Regulator
2000
1800
1600
1400
1200
1000
800
600
400
100
1000
LOAD CURRENT (mA)
10,000
3
6
9
12
RFSYNC (kΩ)
_______________________________________________________________________________________
15
18
21
Dual, 5A, 2MHz Step-Down Regulator
SWITCHING FREQUENCY
vs. TEMPERATURE
FEEDBACK VOLTAGE
vs. TEMPERATURE
1040
1020
1000
980
960
608
606
604
602
600
598
596
940
594
920
592
590
900
-40
9
-15
10
35
60
-40
85
-15
10
60
35
AMBIENT TEMPERATURE (°C)
AMBIENT TEMPERATURE (°C)
SHUTDOWN SUPPLY CURRENT
vs. SUPPLY VOLTAGE
LOAD TRANSIENT
85
MAX8855 toc07
MAX8855 toc06
10
MAX8855 toc05
1060
FEEDBACK VOLTAGE (mV)
SWITCHING FREQUENCY (kHz)
1080
IIN1 + IIN2 + IVDL + IVDD
8
SUPPLY CURRENT (nA)
610
MAX8855 toc04
1100
1.8V OUTPUT
100mV/div
VOUT
7
6
5
3.0A
4
3
IOUT
2
1.5A
1.5A
1A/div
1
0
2.35
2.60
2.85
3.10
3.35
20µs/div
3.60
SUPPLY VOLTAGE (V)
SOFT-START AND SHUTDOWN
SWITCHING WAVEFORMS
MAX8855 toc09
MAX8855 toc08
VLX1
2V/div
IL1
2A/div
VEN2
5V/div
VOUT2
1V/div
VPWRGD
VLX2
2V/div
IL2
2A/div
2V/div
IIN
1A/div
400µs/div
400ns/div
3A LOAD
_______________________________________________________________________________________
5
MAX8855
Typical Operating Characteristics (continued)
(VIN1 = VIN2 = 3.3V. MAX8855, circuit of Figure 6, TA = +25°C, unless otherwise noted.)
Typical Operating Characteristics (continued)
(VIN1 = VIN2 = 3.3V. MAX8855, circuit of Figure 6, TA = +25°C, unless otherwise noted.)
OUTPUT PEAK CURRENT LIMIT
vs. OUTPUT VOLTAGE
OUTPUT SEQUENCING (EN2 = PWRGD1)
SHORT CIRCUIT AND RECOVERY
MAX8855 toc12
MAX8855 toc11
MAX8855 toc10
8
OUTPUT PEAK CURRENT LIMIT (A)
MAX8855
Dual, 5A, 2MHz Step-Down Regulator
7
500mV/div V
OUT1
VOUT1
1V/div
6
1V/div
5
VOUT2
4
2V/div
3
2A/div
2
IL1
1
2V/div
VPWRGD1
VPWRGD2
0A
0
0.8
1.1
1.4
1.7
2.0
2.3
1ms/div
1ms/div
2.6
OUTPUT VOLTAGE (V)
OUTPUT TRACKING (EN1 = EN2)
EXTERNAL SYNCHRONIZATION
MAX8855 toc13
VOUT1
MAX8855 toc14
PULSE GENERATOR SIGNAL. A 10kΩ RESISTOR
IS CONNECTED BETWEEN THE PULSE
GENERATOR AND FSYNC
1V/div
2V/div
1V/div
VOUT2
2V/div
VLX1
2V/div
2V/div
VPWRGD1
VPWRGD2
2V/div
VLX2
1ms/div
400ns/div
DDR TRACKING 1.8V, 0.9V
STARTING INTO PREBIASED OUTPUT
MAX8855 toc15
EN1
VOUT1
PWRGD1
40μs/div
6
_______________________________________________________________________________________
Dual, 5A, 2MHz Step-Down Regulator
PIN
1
NAME
FUNCTION
Power-Good Open-Drain Output for Regulator 1. PWRGD1 is high impedance when VREFIN ≥ 0.54V and
PWRGD1 VFB1 ≥ 0.9 x VREFIN. PWRGD1 is low when VREFIN < 0.54V, EN1 is low, VDD or IN1 is below UVLO, the
thermal shutdown is activated, or when VFB1 < 0.9 x VREFIN.
External Reference Input for Regulator 1. Connect an external reference to REFIN, or connect REFIN to SS1
to use the internal reference. REFIN is discharged to GND through 335Ω when EN1 is low or regulator 1 is
shut down due to a fault condition.
2
REFIN
3
VDD
Supply Voltage. Connect a 10Ω resistor from VDD to VDL and connect a 0.1µF capacitor from VDD to GND.
4
GND
Analog Ground. Connect GND to the analog ground plane. Connect the analog and power ground planes
together at a single point near the IC.
5
N.C.
No Connection
6
VDL
Supply Voltage Input for Low-Side Gate Drive. Connect VDL to IN_ or the highest available supply voltage
less than 3.6V. Connect a 1µF capacitor from VDL to the power ground plane.
7
FSYNC
Frequency Set and Synchronization. Connect a 4.75kΩ to 20.5kΩ resistor from FSYNC to GND to set the
switching frequency or drive with a 250kHz to 2.5MHz clock signal to synchronize switching.
RFSYNC = (T - 0.05µs) x (10kΩ/0.95µs), where T is the oscillator period.
8
Power-Good Open-Drain Output for Regulator 2. PWRGD2 is high impedance when VSS2 ≥ 0.54V and VFB2
PWRGD2 ≥ 0.9 x VSS2. PWRGD2 is low when VSS2 < 0.54V, EN2 is low, VDD or IN2 is below UVLO, the thermal
shutdown is activated, or when VFB2 < 0.9 x VSS2.
9
SS2
Soft-Start for Regulator 2. Connect a capacitor from SS2 to GND to set the soft-start time. See the Setting the SoftStart Time section. SS2 is internally pulled low with 335Ω when EN2 is low or regulator 2 is in a fault condition.
10
FB2
Feedback Input for Regulator 2. Connect FB2 to the center of an external resistor-divider from the output to
GND to set the output voltage from 0.6V to 90% of VIN2. FB2 is high impedance when the IC is shut down.
11
COMP2
Compensation for Regulator 2. COMP2 is the output of the internal voltage-error amplifier. Connect external
compensation network from COMP2 to FB2. See the Compensation Design section. COMP2 is internally
pulled to GND when the output is shut down.
12
EN2
Enable Input for Regulator 2. Drive EN2 high to enable regulator 2, or drive low for shutdown. For always-on
operation, connect EN2 to VDD.
13, 14
IN2
Power-Supply Input for Regulator 2. The voltage range is 2.35V to 3.6V. Connect two 10µF and one 0.1µF
ceramic capacitors from IN2 to PGND2.
15, 16, 17
PGND2
18, 19
LX2
20
BST2
Bootstrap Connection for Regulator 2. Connect a 0.1µF capacitor from BST2 to LX2. BST2 is the supply for
the high-side gate drive. BST2 is charged from VDL with an internal pMOS switch. In shutdown, there is an
internal diode junction from LX2 to BST2 and from VDL to BST2.
21
BST1
Bootstrap Connection for Regulator 1. Connect a 0.1µF capacitor from BST1 to LX1. BST1 is the supply for
the high-side gate drive. BST1 is charged from VDL with an internal pMOS switch. In shutdown, there is an
internal diode junction from LX1 to BST1 and from VDL to BST1.
22, 23
LX1
24, 25, 26
PGND1
Power Ground for Regulator 2. Connect all PGND_ pins to the power ground plane. Connect the power
ground and analog ground planes together at a single point near the IC.
Inductor Connection for Regulator 2. Connect an inductor between LX2 and the regulator output. LX2 is high
impedance when the IC is shut down.
Inductor Connection for Regulator 1. Connect an inductor between LX1 and the regulator output. LX1 is high
impedance when the IC is shut down.
Power Ground for Regulator 1. Connect all PGND_ pins to the power ground plane. Connect the power
ground and analog ground planes together at a single point near the IC.
_______________________________________________________________________________________
7
MAX8855
Pin Description
Dual, 5A, 2MHz Step-Down Regulator
MAX8855
Pin Description (continued)
PIN
NAME
FUNCTION
27, 28
IN1
Power-Supply Input for Regulator 1. The voltage range is 2.35V to 3.6V. Connect two 10µF and one 0.1µF
ceramic capacitors from IN1 to PGND1.
29
EN1
Enable Input for Regulator 1. Drive EN1 high to enable regulator 1, or low for shutdown. For always-on
operation, connect EN1 to VDD.
30
COMP1
Compensation for Regulator 1. COMP1 is the output of the internal voltage-error amplifier. Connect external
compensation network from COMP1 to FB1. See the Compensation Design section. COMP1 is internally
pulled to GND when the output is shut down.
31
FB1
Feedback Input for Regulator 1. Connect FB1 to the center of an external resistor-divider from the output to
GND to set the output voltage from 0.6V to 90% of VIN1. FB1 is high impedance when the IC is shut down.
32
SS1
Soft-Start for Regulator 1. Connect a capacitor from SS1 to GND to set the startup time. See the Setting the
Soft-Start Time section. When E1 is disabled (pulled low), or Regulator 1 is in shutdown mode due to a fault
condition, SS1 is internally pulled low with 335Ω resistor.
—
EP
Exposed Pad. Connect the exposed pad to the power ground plane.
Detailed Description
PWM Controller
The controller logic block is the central processor that
determines the duty cycle of the high-side MOSFET
under different line, load, and temperature conditions.
Under normal operation, where the current-limit and
temperature protection are not triggered, the control
logic block takes the output from the PWM comparator
and generates the driver signals for both high-side and
low-side MOSFETs. It also contains the break-beforemake logic and the timing for charging the bootstrap
capacitors. The error signal from the voltage-error
amplifier is compared with the ramp signal generated
by the oscillator at the PWM comparator and, thus, the
required PWM signal is produced. The high-side switch
is turned on at the beginning of the oscillator cycle and
turns off when the ramp voltage exceeds the VCOMP
signal or the current-limit threshold is exceeded. The
low-side switch is then turned on for the remainder of
the oscillator cycle. The two switching regulators operate at the same switching frequency with 180° phase
shift to reduce the input-capacitor ripple current
requirement. Figure 1 shows the MAX8855 functional
diagram.
Current Limit
The MAX8855 provides both peak and valley current limits
to achieve robust short-circuit protection. During the
high-side MOSFET’s on-time, if the drain-source current
reaches the peak current-limit threshold (specified in
the Electrical Characteristics table), the high-side MOSFET turns off and the low-side MOSFET turns on, allowing the current to ramp down. At the next clock, the
high-side MOSFET is turned on only if the inductor cur8
rent is below the valley current limit. Otherwise, the PWM
cycle is skipped to continue ramping down the inductor
current. When the inductor current stays above the valley
current limit for 12µs and the FB_ is below 0.7 x VREFIN,
the regulator enters hiccup mode. During hiccup mode,
the SS_ capacitor is discharged to zero and the soft-start
sequence begins after a predetermined time period.
Undervoltage Lockout (UVLO)
When the VDD supply voltage drops below the falling
undervoltage threshold (typically 1.9V), the MAX8855
enters its undervoltage lockout mode (UVLO). UVLO
forces the device to a dormant state until the input voltage is high enough to allow the device to function reliably. In UVLO, LX_ nodes of both regulators are in the
high-impedance state. PWRGD1 and PWRGD2 are
forced low in UVLO. When VVDD rises above the rising
undervoltage threshold (typically 2V), the IC powers up
normally as described in the Startup and Sequencing
section.
The UVLO circuitry also monitors the IN1 and IN2 supplies. When the IN_ voltage drops below the falling
undervoltage threshold (typically 1.9V), the corresponding regulator shuts down, and corresponding PWRGD_
goes low. The regulator powers up when VIN_ rises
above the rising undervoltage threshold (typically 2V).
Power-Good Output (PWRGD_)
PWRGD1 and PWRGD2 are open-drain outputs that
indicate when the corresponding output is in regulation.
PWRGD1 is high impedance when VREFIN ≥ 0.54V and
VFB1 ≥ 0.9 x VREFIN. PWRGD1 is low when VREFIN <
0.54V, EN1 is low, VVDD or VIN1 is below VUVLO, the
thermal-overload protection is activated, or when VFB1
< 0.9 x VREFIN.
_______________________________________________________________________________________
Dual, 5A, 2MHz Step-Down Regulator
MAX8855
CURRENT-LIMIT
COMPARATOR
VDD
VDL
BST CAP
CHARGING
SWITCH
IN1
SHUTDOWN
CONTROL
UVLO
CIRCUITRY
DC
BIAS
GENERATOR
EN1
EN2
VDD
-
+
IN2
-
LX1
CONTROL
LOGIC
LX1
EN1
REF
CLOCK
SOFT-START 1
PGND1
THERMAL
SHUTDOWN1
SS2
IN1
ILIM
THRESHOLD
IN1
VOLTAGE
REFERENCE
SS1
BST1
+
BST CAP
CHARGING
SWITCH
VDL
SOFT-START 2
REFIN
+
FB1
-
CURRENT-LIMIT
COMPARATOR
PWM
COMPARATOR
-
IN2
DC
BST2
+
COMP1
COMP LOW
DETECTOR
PWM
COMPARATOR
-
FROM SS2 (0.6V)
+
+
-
CONTROL
LOGIC
IN2
LX2
EN2
-
FB2
LX2
ILIM
THRESHOLD
-
+
ERROR
AMPLIFIER
+
THERMAL
SHUTDOWN2
CLOCK
ERROR
AMPLIFIER
PGND2
COMP2
CLOCK
COMP LOW
DETECTOR
OSCILLATOR
REFIN
+
+
FB1
REF
THERMAL
SHUTDOWN
SS2
+
SHDN
PWRGD2
-
540mV
MAX8855
-
0.9 x VREFIN
THERMAL
SHUTDOWN2
PWRGD1
-
540mV
THERMAL
SHUTDOWN1
SHDN
FSYNC
FB2
+
0.9 x VSS2
-
GND
Figure 1. Functional Diagram
_______________________________________________________________________________________
9
MAX8855
Dual, 5A, 2MHz Step-Down Regulator
The power-good, open-drain output for regulator 2
(PWRGD2) is high impedance when VSS2 ≥ 0.54V and
VFB2 ≥ 0.9 x VSS2. PWRGD2 is low when VSS2 < 0.54V,
EN2 is low, VVDD or VIN2 is below VUVLO, the thermal-overload protection is activated, or when VFB2 < 0.9 x VSS2.
THERM
SHDN
IN1
TLIM
RRUVB
External Reference Input (REFIN)
UVLO
The MAX8855 has an external reference input. Connect
an external reference between 0 and VVDD - 1.6V to
REFIN to set the FB1 regulation voltage. To use the internal 0.6V reference, connect REFIN to SS1. When the IC
is shut down, REFIN is pulled to GND through 335Ω.
REG1 ON
UVLO
BIAS
GEN
VDD
EN1
Startup and Sequencing
The MAX8855 features separate enable inputs (EN1
and EN2) for the two regulators. Driving EN_ high
enables the corresponding regulator; driving EN_ low
turns the regulator off. Driving both EN1 and EN2 low
puts the IC in low-power shutdown mode, reducing the
supply current typically to 30nA. The MAX8855 regulators power up when the following conditions are met
(see Figure 2):
•
EN_ is logic-high.
•
VVDD is above the UVLO threshold.
•
VIN_ is above the UVLO threshold.
•
The internal reference is powered.
•
The IC is not in thermal overload (TJ < +165°C).
Once these conditions are met, the MAX8855 begins
soft-start. FB2 regulates to the voltage at SS2. During
soft-start, the SS2 capacitor is charged with a constant
8µA current source so that its voltage ramps up for the
REF
EN2
UVLO
UVLO
UVLO
REG2 ON
RRUVB
TLIM
IN2
THERM
SHDN
Figure 2. Startup Control Diagram
soft-start time. See the Setting the Soft-Start Time section to select the SS2 capacitor for the desired soft-start
time. FB1 regulates to the voltage at REFIN. Connect
REFIN to SS1 to use the internal reference with softstart time set independently by the SS1 capacitor (see
Figure 3a).
EN1
OUT1
PWRGD1
EN2
EN1
EN1
10kΩ
VDD
PWRGD1
EN2
EN2
10kΩ
OUT2
PWRGD2
PWRGD2
SS1
Figure 3a. Startup and Sequencing Options—Two Independent Output Startup and Shutdown Waveforms
10
RRUVB
REF
RDY
______________________________________________________________________________________
SS2
REFIN
Dual, 5A, 2MHz Step-Down Regulator
the Setting the Output Voltage section). In Figure 3b,
VOUT1 regulates to half of VOUT2. Note that a capacitance of 1000pF should be connected to SS1 for stability.
Figure 3c shows the output sequencing application
using an external reference.
Sequencing is achieved by connecting EN2 to
PWRGD1. In this mode, regulator 2 starts once regulator
1 reaches regulation.
PWRGD1
EN
EN1
EN
10kΩ
OUT2
VDD
EN2
PWRGD2
PWRGD2
SS2
PWRGD1
SS1
OUT1
10kΩ
REFIN
OUT2
10kΩ
10kΩ
Figure 3b. Startup and Sequencing Options—Ratiometric Tracking Startup and Shutdown Waveforms VOUT1 Track VOUT2
EN1
PWRGD1
OUT1
EN1
10kΩ
VDD
PWRGD1
EN1
EN2
10kΩ
SS2
PWRGD2
OUT2
SS1
REFIN
REFIN
PWRGD2
Figure 3c. Startup and Sequencing Options—Sequencing Startup and Shutdown Waveforms with External Reference
______________________________________________________________________________________
11
MAX8855
For ratiometric tracking applications, connect REFIN to
the center of a voltage-divider from the output of regulator 2 to GND (see Figure 3b). In this application, the EN_
inputs are connected to each other and driven as a single enable input. Regulator 2 starts up with a normal softstart (C SS2 sets the time), and regulator 1 output
ratiometrically tracks the regulator 2 output voltage. The
voltage-divider resistors set the VOUT1/VOUT2 ratio (see
MAX8855
Dual, 5A, 2MHz Step-Down Regulator
EN
PWRGD1
EN1
EN
10kΩ
OUT1
VDD
OUT2
EN2
10kΩ
SS2
PWRGD1
PWRGD2
PWRGD2
SS1
REFIN
Figure 3d. Startup and Sequencing Options—Matching Startup Slopes of Output Voltages with Internal Reference
In Figure 3d, EN1 and EN2 are connected together and
driven as a single input. Although both outputs begin
ramping up at the same time, slope matching is
achieved by selecting the SS_ capacitors. See the
Setting the Soft-Start Time section for information on
selecting the SS_ capacitors. In Figure 3d, the slope of
the output voltages during soft-start is equal. This is
achieved by setting the ratio of the soft-start capacitors
equal to the ratio of the output voltages:
CSS1 VOUT1
=
CSS2 VOUT2
Design Procedure
Setting the Output Voltage
The output voltages for regulator 1 (with REFIN connected to SS1) and regulator 2 are set with a resistor
voltage-divider connected from the output to FB_ to
GND as shown in Figure 4. Select a value for the resistor connected from output to FB_ (R4 in Figure 4)
between 2kΩ and 10kΩ. Use the following equations to
find the value for the resistor connected from FB_ to
GND (R6 in Figure 4):
R6 =
Synchronization (FSYNC)
The MAX8855 operates from 500kHz to 2MHz using
either its internal oscillator, or an externally supplied
clock. See the Setting the Switching Frequency section.
0.6
× R4
V
( OUT − 0.6)
L
OUTPUT
LX_
Thermal-Overload Protection
Thermal-overload protection limits the total power dissipation of the MAX8855. Internal thermal sensors monitor
the junction temperature at each of the regulators. When
the junction temperature exceeds +165°C, the corresponding regulator is shut down, allowing the IC to cool.
The thermal sensor turns the regulator on after the junction temperature cools by +20°C. In a continuous thermal-overload condition, this results in a pulsed output.
CO
R8
R4
MAX8855
C11
FB_
R7
C9
R6
COMP_
C10
Figure 4. Type III Compensation Network
12
______________________________________________________________________________________
Dual, 5A, 2MHz Step-Down Regulator
VOUT1
R19
=
VOUT2 R1 + R19
Setting the Switching Frequency
The MAX8855 has an adjustable internal oscillator that
can be set to any frequency from 500kHz to 2MHz. To
set the switching frequency, connect a resistor from
FSYNC to GND. Calculate the resistor value from the
following equation:
⎛1
⎞ ⎛ 10kΩ ⎞
RFSYNC = ⎜ − 50ns⎟ ⎜
⎟
⎝ fS
⎠ ⎝ 950ns ⎠
The MAX8855 can also be synchronized to an external
clock from 500kHz to 2MHz by connecting the clock
signal to FSYNC through a 10kΩ isolation resistor. The
external sync frequency must be higher than the frequency that would be produced by RFSYNC. The two
regulators switch at the same frequency as the FSYNC
clock, and are 180° out-of-phase with each other. The
external clock duty cycle may range between 10% and
90% to ensure 180° out-of-phase operation.
Setting the Soft-Start Time
The two step-down regulators have independent
adjustable soft-start. Capacitors from SS_ to GND are
charged from a constant 8µA (typ) current source to the
feedback-regulation voltage. The value of the soft-start
capacitors is calculated from the desired soft-start time
as follows:
⎛ 8µA ⎞
CSS _ = t SS × ⎜
⎟
⎝ 0.6V ⎠
Inductor Selection
There are several parameters that must be examined
when determining which inductor to use: maximum
input voltage, output voltage, load current, switching
frequency, and LIR. LIR is the ratio of inductor current
ripple to DC load current. A higher LIR value allows for
a smaller inductor, but results in higher losses and
higher output ripple. On the other hand, higher inductor
values increase efficiency, but eventually resistive losses due to extra turns of wire exceed the benefit gained
from lower AC current levels. A good compromise
between size and efficiency is a 30% LIR. For applica-
tions in which size and transient response are important, an LIR of around 40% to 50% is recommended.
Once all the parameters are chosen, the inductor value
is determined as follows:
L=
VOUT × (VIN − VOUT )
fS × VIN × LIR × IOUT(MAX)
where fS is the switching frequency. Choose a standard
value close to the calculated value. The exact inductor
value is not critical and can be adjusted to make tradeoffs among size, cost, and efficiency. Find a low-loss
inductor with the lowest possible DC resistance that fits
the allotted dimensions. The peak inductor current is
determined as:
⎛ LIR ⎞
IPEAK = ⎜1 +
⎟ × IOUT(MAX)
⎝
2 ⎠
IPEAK must not exceed the chosen inductor’s saturation
current rating or the minimum current-limit specification
for the MAX8855.
Input-Capacitor Selection
The input capacitor for each regulator serves to reduce
the current peaks drawn from the input power supply
and reduces switching noise in the IC. The total input
capacitance for each rail must be equal to or greater
than the value given by the following equation to keep
the input-voltage ripple within specifications and minimize the high-frequency ripple current being fed back
to the input source:
CIN _ MIN _ =
D _ × IOUT _
fSW × VIN _ RIPPLE _
where D_ is the quiescent duty cycle (VOUT/VIN); fSW is
the switching frequency; and VIN_RIPPLE_ is the peakto-peak input-ripple voltage, which should be less than
2% of the minimum DC input voltage.
The impedance of the input capacitor at the switching
frequency should be less than that of the input source
so high-frequency switching currents do not pass
through the input source but are instead shunted
through the input capacitor. High source impedance
requires high-input capacitance. The input capacitor
must meet the ripple current requirement imposed by
the switching currents. The RMS input ripple current,
IRIPPLE_, is given by:
IRIPPLE _ = IOUT _ × D _ × (1 − D _)
______________________________________________________________________________________
13
MAX8855
In DDR tracking applications such as Figure 7, the FB1
regulation voltage tracks the voltage at REFIN. In Figure
7, the output of regulator 1 tracks VOUT2, and the ratio
of the output voltages is set as follows:
MAX8855
Dual, 5A, 2MHz Step-Down Regulator
Output-Capacitor Selection
The key selection parameters for the output capacitor
are capacitance, ESR, ESL, and voltage-rating requirements. These affect the overall stability, output ripple
voltage, and transient response of the DC-DC converter. The output ripple occurs due to variations in the
charge stored in the output capacitor, the voltage drop
due to the capacitor’s ESR, and the voltage drop due to
the capacitor’s ESL. Calculate the output-voltage ripple
due to the output capacitance, ESR, and ESL as:
VRIPPLE = VRIPPLE(C) + VRIPPLE(ESR) + VRIPPLE(ESL)
where the output ripple due to output capacitance,
ESR, and ESL is:
VRIPPLE(C) =
IP−P
8 × COUT × fS
VRIPPLE(ESR) = IP−P × ESR
I
VRIPPLE(ESL) = P−P × ESL
t ON
or:
I
VRIPPLE(ESL) = P−P × ESL
t OFF
whichever is greater.
It should be noted that the above ripple voltage components add vectrorially rather than algebraically, thus
making VRIPPLE a conservative estimate.
The peak inductor current (IP-P) is:
V −V
V
IP−P = IN OUT × OUT
fS × L
VIN
Use these equations for initial capacitor selection.
Determine final values by testing a prototype or an evaluation circuit. A smaller ripple current results in less output-voltage ripple. Since the inductor ripple current is a
function of the inductor value, the output-voltage ripple
decreases with larger inductance. Use ceramic capacitors for low ESR and low ESL at the switching frequency
of the converter. The low ESL of ceramic capacitors
makes ripple voltages due to ESL negligible.
Load-transient response depends on the selected output capacitance. During a load transient, the output
instantly changes by ESR x ∆ILOAD. Before the controller can respond, the output deviates further,
depending on the inductor and output capacitor values.
14
After a short time, the controller responds by regulating
the output voltage back to its predetermined value. The
controller response time depends on the closed-loop
bandwidth. A higher bandwidth yields a faster
response time, preventing the output from deviating further from its regulating value. See the Compensation
Design and Safe-Starting into a Prebiased Output sections for more details.
Compensation Design
The power-stage transfer function consists of one double pole and one zero. The double pole is introduced
by the output filtering inductor, L, and the output filtering capacitor, C O . The ESR of the output filtering
capacitor determines the zero. The double pole and
zero frequencies are given as follows:
1
fP1_ LC = fP2 _ LC =
⎛ R + ESR ⎞
2π × L × C O × ⎜ O
⎟
⎝ RO + RL ⎠
fZ _ ESR =
1
2π × ESR × CO
where RL is equal to the sum of the output inductor’s
DC resistance and the internal switch resistance,
RDS(ON). A typical value for RDS(ON) is 35mΩ. RO is the
output load resistance, which is equal to the rated output voltage divided by the rated output current. ESR is
the total ESR of the output-filtering capacitor. If there is
more than one output capacitor of the same type in parallel, the value of the ESR in the above equation is
equal to that of the ESR of a single-output capacitor
divided by the total number of output capacitors.
The high-switching-frequency range of the MAX8855
allows the use of ceramic output capacitors. Since the
ESR of ceramic capacitors is typically very low, the frequency of the associated transfer-function zero is higher than the unity-gain crossover frequency, fC, and the
zero cannot be used to compensate for the double pole
created by the output filtering inductor and capacitor.
The double pole produces a gain drop of 40dB and a
phase shift of 180° per decade. The error amplifier
must compensate for this gain drop and phase shift to
achieve a stable high-bandwidth closed-loop system.
Therefore, use type III compensation as shown in
Figure 4. Type III compensation possesses three poles
and two zeros with the first pole, fP1_EA, located at 0Hz
(DC). Locations of other poles and zeros of type III
compensation are given by:
fZ1_ EA =
1
2π × R7 × C9
______________________________________________________________________________________
Dual, 5A, 2MHz Step-Down Regulator
1
2π × R4 × C11
fP2 _ EA =
1
2π × R7 × C10
fP3 _ EA =
1
2π × R8 × C11
C9 =
These equations are based on the assumptions that C9
>> C10, and R4 >> R8, which are true in most applications. Placement of these poles and zeros is determined by the frequencies of the double pole and ESR
zero of the power stage transfer function. It is also a
function of the desired closed-loop bandwidth. Figure 5
shows the pole zero cancellations in the type III compensation design.
The following section outlines the step-by-step design
procedure to calculate the required compensation components. Begin by setting the desired output voltage as
described in the Setting the Output Voltage section.
The crossover frequency fC (or closed-loop, unity-gain
bandwidth of the regulator) should be between 10%
and 20% of the switching frequency, f S . A higher
crossover frequency results in a faster transient
response. Too high of a crossover frequency can result
in instability. Once fC is chosen, calculate C9 (in farads)
from the following equation:
2.5 × VIN
⎛ R ⎞
2π × fC × R4 × ⎜1 + L ⎟
⎝ RO ⎠
where V IN is the input voltage in volts, f C is the
crossover frequency in Hertz, R4 is the upper feedback
resistor (in ohms), RL is the sum of the inductor resistance and the internal switch on-resistance, and RO is
the output load resistance (VOUT/IOUT).
Due to the underdamped nature of the output LC double
pole, set the two zero frequencies of the type III compensation less than the LC double-pole frequency to
provide adequate phase boost. Set the two zero frequencies to 80% of the LC double-pole frequency.
Hence:
R7 =
L × CO × (RO + ESR)
1
×
RL + RO
0.8 × C9
C11 =
L × CO × (RO + ESR)
1
×
RL + RO
0.8 × R4
Set the third compensation pole, f P3_EA, at f Z_ESR,
which yields:
R8 =
CO × ESR
C11
OPEN-LOOP GAIN
COMPENSATION TRANSFER FUNCTION
THIRD POLE
GAIN
DOUBLE POLES
SECOND POLE
POWER-STAGE TRANSFER FUNCTION
FIRST AND SECOND ZEROS
FREQUENCY
Figure 5. Pole Zero Cancellations in Compensation Design
______________________________________________________________________________________
15
MAX8855
fZ2 _ EA =
MAX8855
Dual, 5A, 2MHz Step-Down Regulator
Set the second compensation pole at 1/2 the switching
frequency. Calculate C10 as follows:
•
Place the input ceramic decoupling capacitor
directly across and as close as possible to IN_ and
PGND_. This is to help contain the high switching
currents within a small loop.
•
The recommended range for R4 is 2kΩ to 10kΩ. Note
that the loop compensation remains unchanged if only
R6’s resistance is altered to set different outputs.
Connect IN_ and PGND_ separately to large copper
areas to help cool the IC and further improve efficiency and long-term reliability.
•
Connect input, output, and VDL capacitors to the
power ground plane (PGND_).
Safe-Starting into a Prebiased Output
•
Keep the path of switching currents short and minimize the loop area formed by LX_, the output
capacitor(s), and the input capacitor(s).
•
Place the IC decoupling capacitors as close as
possible to the IC pins, connecting all other groundterminated capacitors, resistors, and passive components to the reference or analog ground plane
(AGND).
•
Separate the power and analog ground planes,
using a single-point common connection point (typically, at the CIN cathode.
•
Connect the exposed pad to the analog ground
plane, allowing sufficient copper area to help cool
the device. If the exposed pad is used as a common PGND_-to-AGND connection point, avoid running high current through the exposed pad by
using separate vias to connect the PGND_ pins to
the power ground plane rather than connecting
them to the exposed pad on the top layer.
•
Use caution when routing feedback and compensation node traces; avoid routing near high dV/dt
nodes (LX_) and high-current paths. Place the feedback and compensation components as close as
possible to the IC pins.
•
Reference the MAX8855 Evaluation Kit for an example layout.
C10 =
1
π × R7 × fS
The MAX8855 is capable of safe-starting up into a prebiased output without discharging the output capacitor.
This type of operation is also termed monotonic startup.
However, in order to avoid output voltage glitches during safe-start it should be ensured that the inductor current is in continuous conduction mode during the end
of the soft-start period, this is done by satisfying the following equation:
CO ×
VO
I
≥ P −P
tSS
2
where CO is the output capacitor, VO is the output voltage, tSS is the soft-start time set by the soft-start capacitor CSS, and IP-P is the peak inductor ripple current (as
defined in the Output-Capacitor Selection section).
Depending on the application, one of these parameters
may drive the selection of the others. See Starting into
Prebiased Output waveforms in the Typical Operating
Characteristics section for an example selection of the
above parameters.
Applications Information
PCB Layout Guidelines
Careful PCB layout is critical to achieve low switching
losses and clean, stable operation. The switching
power stage requires particular attention. It is highly
recommended to duplicate the MAX8855 layout for
optimum performance. If deviation is necessary, follow
these guidelines for a good PCB layout:
• A multilayer PCB is recommended. Use inner-layer
ground (and power) planes to minimize noise coupling.
16
______________________________________________________________________________________
Dual, 5A, 2MHz Step-Down Regulator
MAX8855
INPUT 2.35V TO 3.6V
C16
0.1µF
IN1
VDD
R11
10Ω
VDL
VDD
C2
0.1µF
R4
10kΩ
L1
0.56µH
BST1
BST2
C6
0.1µF
C17
0.1µF
LX1
C19
22µF
L2
0.56µH
R9
1kΩ
GND
R7
10kΩ
C11
1000pF
C9
330pF
C10
OPEN
VDD
C5
0.022µF
PWRGD1
FB1
FB2
REFIN
SS2
SS1
PWRGD2
ON
R13
40.2kΩ
C13
150pF
R12
20kΩ
C14
OPEN
C12
0.022µF
VDD
R10
20kΩ
FSYNC
EN1
OFF
R10
27kΩ
COMP2
PWRGD1
EN1
C15
220pF
MAX8855
COMP1
R6
10kΩ
C20
0.1µF OUT2
1.8V/5A
LX2
R8
200Ω
R15
20kΩ
C23
10µF
PGND2
PGND1
C18
47µF
IN2
C3
0.1µF
C1
10µF
C4
OUT1 0.1µF
1.2V/5A
C8
0.22µF
R5
10kΩ
PWRGD2
EN2
EN2
EXPOSED PAD
ON
OFF
Figure 6. 1MHz Typical Application Circuit
______________________________________________________________________________________
17
MAX8855
Dual, 5A, 2MHz Step-Down Regulator
INPUT 2.5V TO 3.6V
C16
0.1µF
IN1
VDD
R11
10Ω
VDL
VDD
C2
0.1µF
PGND1
C18
47µF
L1
1µH
C23
10µF
PGND2
BST1
BST2
C6
0.1µF
C17
0.1µF
LX1
C19
22µF
L2
1µH
R9
1kΩ
GND
R7
10kΩ
C11
1000pF
C9
330pF
C20
0.1µF OUT2
1.8V/5A
LX2
R8
200Ω
R4
10kΩ
IN2
C3
0.1µF
C1
10µF
C4
OUT1 0.1µF
0.9V/5A
C8
0.22µF
C15
220pF
MAX8855
COMP1
R10
27kΩ
R13
40.2kΩ
C13
150pF
COMP2
OUT2
R12
20kΩ
PGND2
C10
OPEN
R1
1kΩ
VDD
R19
1kΩ
R15
20kΩ
PWRGD1
FB1
FB2
REFIN
C7
1000pF
SS1
ON
VDD
R10
20kΩ
FSYNC
PWRGD2
EN1
OFF
C12
0.022µF
SS2
PWRGD1
EN1
C14
OPEN
R5
5kΩ
PWRGD2
EN2
EN2
EXPOSED PAD
ON
OFF
Figure 7. Tracking DDR Application Circuit
18
______________________________________________________________________________________
Dual, 5A, 2MHz Step-Down Regulator
Chip Information
BST2
LX2
LX2
PGND2
23
LX1
24
BST1
LX1
TOP VIEW
PGND1
PROCESS: BiCMOS
22
21
20
19
18
17
PGND1 25
16
PGND2
PGND1 26
15
PGND2
IN1 27
14
IN2
13
IN2
Package Information
12
EN2
11
COMP2
10
FB2
9
SS2
For the latest package outline information and land patterns, go
to www.maxim-ic.com/packages. Note that a “+”, “#”, or “-” in
the package code indicates RoHS status only. Package drawings may show a different suffix character, but the drawing pertains to the package regardless of RoHS status.
IN1 28
MAX8855
EN1 29
COMP1 30
FB1 31
+
6
VDL
5
7
FSYNC
4
N.C.
VDD
3
GND
2
REFIN
PWRGD1
1
8
PACKAGE TYPE
PACKAGE CODE
DOCUMENT NO.
PWRGD2
SS1 32
32 TQFN-EP
T3255-4
21-0140
THIN QFN
(5mm x 5mm)
______________________________________________________________________________________
19
MAX8855
Pin Configuration
MAX8855
Dual, 5A, 2MHz Step-Down Regulator
Revision History
REVISION
NUMBER
REVISION
DATE
DESCRIPTION
0
8/07
Initial release
1
6/08
Revised Features section and corrected Figure 6.
2
4/09
Revised Features, Typical Operating Characteristics, and Output-Capacitor
Selection sections.
PAGES
CHANGED
—
1, 17
1, 6, 14, 16
Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are
implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.
20 ____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600
© 2009 Maxim Integrated Products
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