NSC LM2770SD-1215

LM2770
High Efficiency Switched Capacitor Step-Down DC/DC
Regulator with Sleep Mode
General Description
Features
The LM2770 is a switched capacitor step-down regulator
that is ideal for powering low-voltage applications in portable
systems. The LM2770 can supply load currents up to 250mA
and operates over an input voltage range of 2.7V to 5.5V.
This makes the LM2770 a great choice for systems powered
by 1-cell Li-Ion batteries and chargers. The output voltage of
the LM2770 can be dynamically switched between two output levels with a logic input pin. Output voltage pairs currently available include 1.2V/1.5V and 1.2V/1.575V. Other
pairs of voltage options can be developed upon request.
LM2770 efficiency is superior to both fixed-gain switched
capacitor buck regulators and low-dropout linear regulators
(LDO’s). Multiple fractional gains maximize power efficiency
over the entire input voltage and output current ranges. The
LM2770 can also be switched into a low-power sleep mode
when load currents are light (≤ 20mA). In sleep mode, the
charge pump is off, and the output is driven with a low-noise,
low-power linear regulator.
Soft-start, short-circuit protection, current-limit protection,
and thermal-shutdown protection are also included. The
LM2770 is available in National’s small 10-pin Leadless
Leadframe Package (LLP-10).
n High Efficiency Multi-Gain Architecture: Peak Power
Efficiency > 85%
n Output Voltage Pairs: 1.2V/1.5V and 1.2V/1.575V
n Dynamic Output Voltage Selection
n ± 3% Output Voltage Accuracy
n Output Currents up to 250mA
n 2.7V to 5.5V Input Range
n Low-Supply-Current Sleep Mode
n 55µA Quiescent Supply Current in Full-Power Mode
n Soft-Start
n Short-Circuit Protection in Full-Power Mode
n Current-Limit Protection in Sleep Mode
n LLP-10 Package (3mm x 3mm x 0.8mm)
Applications
n
n
n
n
DSP Power Supplies
Baseband Power Supplies
Mobile Phones and Pagers
Portable Electronic Equipment
Typical Application Circuit
LM2770 Efficiency vs.
Low-Dropout Linear Regulator (LDO) Efficiency
20126011
20126001
© 2004 National Semiconductor Corporation
DS201260
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LM2770 High Efficiency Switched Capacitor Step-Down DC/DC Regulator with Sleep Mode
December 2004
LM2770
Connection Diagram and Package Mark Information
10-Pin Non-Pullback Leadless Frame Package (LLP-10)
National Semiconductor Package Number SDA10A
20126002
Pin Description
Pin #
Name
Description
1
VSEL
Output Voltage Select Logic Input. If VSEL is high, VOUT = high voltage. If VSEL
is low, VOUT = low voltage. (See Order Information for available voltage
options)
2
EN
Enable Pin Logic Input. If high, part is enabled. If low, part is in shutdown.
3
C2+
Flying Capacitor 2: Positive Termial
4
GND
Ground
5
C2-
10
SLEEP
9
VIN
Input Voltage. Recommended VIN operating range: 2.7V to 5.5V
8
C1+
Flying Capacitor 1: Positive Terminal
7
C1-
Flying Capacitor 1: Negative Terminal
6
VOUT
Flying Capacitor 2: Negative terminal
Sleep Mode Logic Input. If high, the part operates in sleep mode, and the
output is driven by a low power linear regulator. If low, the part operates in
full-power mode, and the output is driven by the switched capacitor regulator
Output Voltage
Order Information
Output Voltages
Order Number
1.2V / 1.5V
LM2770SD-1215
L162B
1.2V / 1.5V
LM2770SDX-1215
L162B
1.2V / 1.575V
LM2770SD-12157
L166B
1.2V / 1.575V
LM2770SDX-12157
L166B
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Package Mark ID
Package
Supplied as:
1000 Units, Tape and Reel
SDA10A
Non-Pullback LLP
4500 Units, Tape and Reel
1000 Units, Tape and Reel
4500 Units, Tape and Reel
2
Operating Ratings
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
VIN Pin Voltage
Input Voltage Range
Continuous Power Dissipation
(Note 3)
-0.3V to (VIN+0.3V)
w/ 6.0V max
Internally Limited
VOUT Short to GND Duration
(Note 4)
Infinite
Junction Temperature (TJ-MAX)
150oC
Storage Temperature Range
-65oC to +150o C
Maximum Lead Temperature
(Note 5)
265oC
ESD Rating (Note 6)
Human Body Model:
Machine Model
Electrical Characteristics
2.7V to 5.5V
Recommended Load Current Range
-0.3V to 6.0V
EN, SLEEP, and VSEL Pin Voltages
(Notes 1, 2)
0mA to 250mA
Junction Temperature (TJ) Range
-30˚C to +105˚C
Ambient Temperature (TA) Range
(Note 6)
-30˚C to +85˚C
Thermal Properties
55˚C/W
Juntion-to-Ambient Thermal
Resistance (θJA), LLP10 Package
(Note 7)
2.0kV
200V
(Notes 2, 9)
Limits in standard typeface are for TJ = 25oC. Limits in boldface type apply over the full operating junction temperature range
(-30˚C ≤ TJ ≤ +105˚C) . Unless otherwise noted, specifications apply to the LM2770 Typical Application Circuit (pg. 1) with: VIN
= 3.6V; V(EN) = VSEL = 1.8V, V(SLEEP) = 0V, CIN = COUT = 10µF, C1 = C2 = 1.0µF. (Note 10)
Symbol
Parameter
Condition
Min
Typ
Max
Units
VIN = 3.5V, IOUT = 150mA,
VSEL = 1.8V
1.443
1.495
1.547
V
3.0V ≤ VIN ≤ 4.5V
IOUT = 150mA, VSEL = 1.8V
1.420
1.495
1.570
4.5V < VIN ≤ 5.5V,
IOUT = 150mA, VSEL = 1.8V
1.428
1.495
1.562
VIN = 3.5V, IOUT = 150mA,
VSEL = 0V
1.157
1.205
1.253
3.0V ≤ VIN ≤ 4.5V
IOUT - 150mA, VSEL =0V
1.140
1.205
1.270
4.5V < VIN ≤ 5.5V,
IOUT = 150mA, VSEL = 0V
1.135
1.205
1.275
VIN = 3.5V, IOUT = 150mA,
VSEL = 1.8V
1.528
1.575
1.622
3.1V ≤ VIN ≤ 4.5V
IOUT = 150mA, VSEL = 1.8V
1.500
1.575
1.650
4.5V < VIN ≤ 5.5V,
IOUT = 150mA, VSEL = 1.8V
1.504
1.575
1.646
VIN = 3.5V, IOUT = 150mA,
VSEL = 0V
1.162
1.210
1.258
3.0V ≤ VIN ≤ 4.5V
IOUT - 150mA, VSEL =0V
1.145
1.210
1.275
4.5V < VIN ≤ 5.5V,
IOUT = 150mA, VSEL = 0V
1.145
1.210
1.275
Output Voltage Specifications: Specific to Individual LM2770 Options
VOUT-1215
LM2770-1215:
1.5V Output Voltage Regulation
LM2770-1215:
1.2V Output Voltage Regulation
VOUT-12157
LM2770-12157:
1.575V Output Voltage
Regulation
LM2770-12157:
1.2V Output Voltage Regulation
VOUT/IOUT
Load Regulation
IOUT = 1mA to 250mA
3
0.18
V
mV/mA
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LM2770
Absolute Maximum Ratings (Notes 1, 2)
LM2770
Electrical Characteristics (Notes 2, 9)
(Continued)
Limits in standard typeface are for TJ = 25oC. Limits in boldface type apply over the full operating junction temperature range
(-30˚C ≤ TJ ≤ +105˚C) . Unless otherwise noted, specifications apply to the LM2770 Typical Application Circuit (pg. 1) with: VIN
= 3.6V; V(EN) = VSEL = 1.8V, V(SLEEP) = 0V, CIN = COUT = 10µF, C1 = C2 = 1.0µF. (Note 10)
Symbol
VLDO-1215
VLDO-12157
Min
Typ
Max
Units
LM2770-1215:
1.5V Output Voltage Regulation
- SLEEP Mode
Parameter
3.0V ≤ VIN ≤ 5.5V,
0mA ≤ IOUT ≤ 20mA,
VSEL= 0V, V(SLEEP) = 1.8V
Condition
1.435
1.495
1.555
V
LM2770-1215:
1.2V Output Voltage Regulation
- SLEEP Mode
3.0V ≤ VIN ≤ 5.5V,
0mA ≤ IOUT ≤ 20mA,
VSEL = 0V, V(SLEEP) = 1.8V
1.145
1.205
1.265
LM2770-12157:
1.575V Output Voltage
Regulation - SLEEP Mode
3.0V ≤ VIN ≤ 5.5V,
0mA ≤ IOUT ≤ 20mA,
VSEL= 0V, V(SLEEP) = 1.8V
1.520
1.575
1.630
LM2770-12157:
1.2V Output Voltage Regulation
- SLEEP Mode
3.0V ≤ VIN ≤ 5.5V,
0mA ≤ IOUT ≤ 20mA,
VSEL = 0V, V(SLEEP) = 1.8V
1.150
1.210
1.270
V
Specifications Below Apply to All LM2770 Options
E
Power Efficiency
VIN = 3.6V, IOUT = 150mA
VOUT =1.5V
82
%
EAVG
Average Eficiency over Li-Ion
Input Voltage Range (Note 11)
3.0V ≤ VIN ≤ 4.2V
IOUT = 200mA, VOUT = 1.5V
73
%
IQ
Quiescent Supply Current:
Full-power Mode
2.7V ≤ VIN ≤ 5.5V
IOUT = 0mA
V(SLEEP) = 0V
55
75
µA
ISLEEP
Quiescent Supply Current:
Sleep Mode
2.7V ≤ VIN ≤ 5.5V
IOUT = 0mA
V(SLEEP) = 1.8V
50
65
µA
ISD
Shutdown Current
2.7V ≤ VIN ≤ 5.5V
V(EN) = 0V
0.1
0.5
µA
ICL
Current Limit - Sleep Mode
0V ≤ VOUT ≤ 0.2V
V(SLEEP) = 1.8V
60
mA
tON
Turn-on Time
VIN = 3.6V, COUT = 10µF
200
µs
FSW
Switching Frequency
2.7V ≤ VIN ≤ 5.5V
475
700
925
kHz
0.4
V
Logic Pin Specifications: EN, ENA, ENB
VIL
Logic-low Input Voltage
2.7V ≤ VIN ≤ 5.5V
0
1.0
VIH
Logic-high Input Voltage
2.7V ≤ VIN ≤ 5.5V
IIH
Logic-high Input Current:
SLEEP and VSEL pins
Logic Input = 3.0V
IIH-EN
IIL
VIN
V
0.1
µA
Logic-high Input Current: EN pin V(EN) = 1.8V
(Note 12)
6
µA
Logic-low Input Current: All
Logic Pins
0
µA
Logic Input = 0V
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the component may occur. Operating Ratings are conditions under which operation of
the device is guaranteed. Operating Ratings do not imply guaranteed performance limits. For guaranteed performance limits and associated test conditions, see the
Electrical Characteristics tables.
Note 2: All voltages are with respect to the potential at the GND pin.
Note 3: Internal thermal shutdown circuitry protects the device from permanent damage. Thermal shutdown engages at TJ=150oC (typ.) and disengages at
TJ=140oC (typ.).
Note 4: Short circuit protection circuitry protects the part from immediate destructive failure when VOUT is shorted to GND. Applying a continuous GND short to the
output may shorten the lifetime of the device.
Note 5: For detailed information on soldering requirements and recommendations, please refer to National Semiconductor’s Application Note 1187 (AN-1187):
Leadless Leadframe Package (LLP).
Note 6: The Human body model is a 100pF capacitor discharged through a 1.5kΩ resistor into each pin. The machine model is a 200pF capacitor discharged
directly into each pin. MIL-STD-883 3015.7
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4
(Continued)
Note 7: Maximum ambient temperature (TA-MAX) is dependent on the maximum operating junction temperature (TJ-MAX-OP = 105oC), the maximum power
dissipation of the device in the application (PD-MAX), and the junction-to ambient thermal resistance of the part/package in the application (θJA), as given by the
following equation: TA-MAX = TJ-MAX-OP – (θJA x PD-MAX).
Note 8: Junction-to-ambient thermal resistance is highly application and board-layout dependent. In applications where high maximum power dissipation exists,
special care must be paid to thermal dissipation issues.
Note 9: Min and Max limits are guaranteed by design, test, or statistical analysis. Typical numbers are not guaranteed, but do represent the most likely norm.
Note 10: CIN, COUT, C1, and C2 : Low-ESR Surface-Mount Ceramic Capacitors (MLCCs) used in setting electrical characteristics.
Note 11: Efficiency is measured versus VIN, with VIN being swept in small increments from 3.0V to 4.2V. The average is calculated from these measurement results.
Weighting to account for battery voltage discharge characteristics (VBAT vs. Time) is not done in computing the average.
Note 12: There is a 300kΩ pull-down resistor connected internally between the EN pin and GND.
5
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LM2770
Electrical Characteristics (Notes 2, 9)
LM2770
Block Diagram
20126003
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Output Voltage vs. Input Voltage: VOUT = 1.2V
Efficiency vs. Input Voltage: VOUT = 1.2V
20126006
20126007
Output Voltage vs. Input Voltage: VOUT = 1.5V
Efficiency vs. Input Voltage: VOUT = 1.5V
20126004
20126005
Output Voltage vs. Input Voltage: VOUT = 1.575V
Efficiency vs. Input Voltage: VOUT = 1.575V
20126019
20126018
7
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LM2770
Typical Performance Characteristics Unless otherwise specified: CIN = 10µF, C1 = 1.0µF, C2 =
1.0µF, COUT = 10µF, TA = 25oC. Capacitors are low-ESR multi-layer ceramic capacitors (MLCC’s).
LM2770
Typical Performance Characteristics Unless otherwise specified: CIN = 10µF, C1 = 1.0µF, C2 =
1.0µF, COUT = 10µF, TA = 25oC. Capacitors are low-ESR multi-layer ceramic capacitors (MLCC’s). (Continued)
Load Regulation: VOUT = 1.2V
Load Regulation: VOUT = 1.5V
20126009
20126008
Load Regulation: VOUT = 1.575V
Output Voltage Ripple
20126013
VIN = 3.6V, VOUT = 1.5V, IOUT = 200mA
CH1: CIN = COUT = 2x10µF; C1 = C2 = 1µF; Scale: 50mV/Div
CH2: CIN = COUT = 10µF; C1 = C2 = 1µF; Scale: 50mV/Div
Time scale: 4µs/Div
20126020
Input Voltage RIpple
Start-up Behavior
20126012
20126014
VIN = 3.6V, VOUT = 1.5V, Load = 7.5Ω (200mA)
CH1: EN pin; Scale: 1V/Div
VIN = 3.6V, VOUT = 1.5V, IOUT = 200mA
CH1: CIN = COUT = 2x10µF; C1 = C2 = 1µF; Scale: 50mV/Div
CH2: CIN = COUT = 10µF; C1 = C2 = 1µF; Scale: 50mV/Div
CH2: VOUT; Scale: 500mV/Div
Time scale: 4µs/Div
Time scale: 40µs/Div
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8
Load Step
Active-to-Sleep Mode Transitions
20126017
20126010
VIN = 3.6V, VOUT = 1.5V, Load = 10mA - 150mA step
VIN = 3.6V, VOUT = 1.5V, Load = 20mA
CH1 (top): Output Current; Scale: 100mA/Div
CH1: SLEEP pin; Scale: 2V/Div
CH2: VOUT; Scale: 100mV/Div
CH2: VOUT; Scale: 200mV/Div
Time scale: 40µs/Div
Time scale: 200µs/Div
Dynamic Output Voltage Switching: 1.5V to 1.2V
20126016
VIN = 3.6V, VOUT = 1.5V, Load = 10mA - 150mA step
CH1: VSEL pin; Scale: 2V/Div
CH2: VOUT; Scale: 500mV/Div
Time scale: 40µs/Div
9
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LM2770
Typical Performance Characteristics Unless otherwise specified: CIN = 10µF, C1 = 1.0µF, C2 =
1.0µF, COUT = 10µF, TA = 25oC. Capacitors are low-ESR multi-layer ceramic capacitors (MLCC’s). (Continued)
LM2770
pump at any given time is the one that yields the highest
efficiency based on the input and output conditions present.
Operation Description
OVERVIEW
MULTI-GAIN EFFICIENCY PERFORMANCE
The LM2770 is a switched capacitor converter that produces
a regulated low voltage output. The core of the part is a
highly efficient charge pump that utilizes multiple fractional
gains and pulse-frequency-modulated (PFM) switching to
minimize power losses over wide input voltage and output
current ranges. A description of the principal operational
characteristics of the LM2770 is broken up into the following
sections: PFM Regulation, Fractional Multi-Gain Charge
Pump, and Multi-Gain Efficiency Performance. Each of
these sections refers to the Block Diagram.
The ability to switch gains based on input and output conditions results in optimal efficiency throughout the operating
ranges of the LM2770. Charge-pump efficiency is derived in
the following two ideal equations (supply current and other
losses are neglected for simplicity):
IIN = G x IOUT
E = (VOUT x IOUT) ÷ (VIN x IIN) = VOUT ÷ (G X VIN)
In the equations, G represents the charge pump gain. Efficiency is at its highest as GxVIN approaches VOUT. Refer to
the efficiency graphs in the Typical Perfromance Characteristics section for detailed efficiency data. The gain regions are clearly distinguished by the sharp discontinuities in
the efficiency curves and are identified at the bottom of each
graph (G = 2⁄3, G = 1⁄2, and G = 1⁄3).
PFM REGULATION
The LM2770 achieves tightly regulated output voltages with
pulse-frequency-modulated (PFM) regulation. PFM simply
means the part only pumps when charge needs to be delivered to the output in order to keep the output voltage in
regulation. When the output voltage is above the target
regulation voltage, the part idles and consumes minimal
supply-current. In this state, the load current is supplied
solely by the charge stored on the output capacitor. As this
capacitor discharges and the output voltage falls below the
target regulation voltage, the charge pump activates, and
charge is delivered to the output. This charge supplies the
load current and boosts the voltage on the output capacitor.
DYNAMIC OUTPUT VOLTAGE SELECTION
The output voltage of the LM2770 can be dynamically adjusted for the purpose of improving system efficiency. Each
LM2770 version contains two built-in output voltage options:
a high level and a low level (1.5V and 1.2V, for example).
With the simple VSEL logic input pin, the output voltage can
be switched between these two voltages.
Dynamic voltage selection can be used to improve overall
system efficiency. When comparing system efficiency between two different output voltages, evaluating power consumption often lends more insight than actually comparing
converter efficiencies. An application powered with a Li-Ion
battery is a good example to illustrate this. Referring to the
LM2770 efficiency curves (see Typical Performance Charactersitics), all LM2770 output voltage options operate with
G = 1⁄2 over the core Li-Ion battery voltage range (3.5V 3.9V). Thus, the LM2770 circuit will draw an input current
that is approximately half the output current in the core Li-Ion
voltage range, regardless of the output voltage (IIN = G x
IOUT) .
While varying the LM2770 output voltage does not directly
improve system efficiency, it can have a secondary effect.
Different output voltages often will result in different LM2770
load currents. This is where system efficiency can benefit
from dynamic output voltage selection: the LM2770 load
circuit can run at lower currents. This reduces LM2770 input
current and improves overall system efficiency.
The primary benefit of PFM regulation is when output currents are light and the part is predominantly in the lowsupply-current idle state. Net supply current is minimal because the part only occasionally needs to recharge the
output capacitor by activating the charge pump. With PFM
regulation, input and output ripple frequencies vary significantly, and are dependent on output current, input voltage,
and, to a lesser degree, other factors such as temperature
and internal switch characteristics.
FRACTIONAL MULTI-GAIN CHARGE PUMP
The core of the LM2770 is a two-phase charge pump controlled by an internally generated non-overlapping clock. The
charge pump operates by using the external flying capacitors, C1 and C2, to transfer charge from the input to the
output.
The two phases of the switching cycle will be referred to as
the "charge phase" and the "hold/rest phase". During the
charge phase, the flying capacitors are charged by the input
supply. After charging the flying capacitors for half of a
switching cycle [ t = 1/(2xFSW) ], the LM2770 switches to the
hold/rest phase. In this configuration, the charge that was
stored on the flying capacitors in the charge phase is transferred to the output. If the voltage on the output is below the
target regulation voltage at completion of the switching
cycle, the charge pump will switch back to the charge phase.
But if the output voltage is above the target regulation voltage at the end of the switching cycle, the charge pump will
remain in the hold/rest state. It will idle in this mode until the
output voltage drops below the target regulation voltage.
When this finally occurs, the LM2770 will switch back to the
charge phase.
Input, output, and intermediary connections of the flying
capacitors are made with internal MOS switches. The
LM2770 utilizes two flying capacitors and a versatile switch
network to achieve three distinct fractional voltage gains: 1⁄3,
1⁄2, and 2⁄3. With this gain-switching ability, it is as if the
LM2770 is three-charge-pumps-in-one. The "active" charge
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SLEEP MODE BYPASS LDO
The LM2770 offers a bypass low-dropout linear regulator
(LDO) for low-noise performance under light loads. Capable
of delivering up to 20mA of output current, this LDO has low
ground pin current and is ideal for stand-by operation. The
LDO is activated with the SLEEP logic input pin. When
SLEEP is active, the charge pump is disabled and the LDO
supplies all load current.
SHUTDOWN
The LM2770 is in shutdown mode when the voltage on the
enable pin (EN) is logic-low. In shutdown, the LM2770 draws
virtually no supply current. When in shutdown, the output of
the LM2770 is completely disconnected from the input. The
internal feedback resistors will pull the output voltage down
to 0V (unless the output is driven by an outside source).
In some applications, it may be desired to disable the
LM2770 and drive the output pin with another voltage
10
Net capacitance of a ceramic capacitor decreases with increased DC bias. This degradation can result in lower capacitance than expected on the input and/or output, resulting
in higher ripple voltages and currents. Using capacitors at
DC bias voltages significantly below the capacitor voltage
rating will usually minimize DC bias effects. Consult capacitor manufacturers for information on capacitor DC bias characteristics.
(Continued)
source. This can be done, but the voltage on the output pin
of the LM2770 must not be brought above the input voltage.
The output pin will draw a small amount of current when
driven externally due the internal feedback resistor divider
connected between VOUT and GND.
SOFT START
The LM2770 employs soft start circuitry to prevent excessive
input inrush currents during startup. At startup, the output
voltage gradually rises from 0V to the nominal output voltage. This occurs in 200µs (typ.). Soft-start is engaged when
the part is enabled, including situations where voltage is
established simultaneously on the VIN and EN pins.
Capacitance characteristics can vary quite dramatically with
different application conditions, capacitor types, and capacitor manufacturers. It is strongly recommended that the
LM2770 circuit be thoroughly evaluated early in the
design-in process with the mass-production capacitors of
choice. This will help to ensure that any such variability in
capacitance does not negatively impact circuit performance.
THERMAL SHUTDOWN
The table below lists some leading ceramic capacitor manufacturers.
Protection from overheating-related damage is achieved
with a thermal shutdown feature. When the junction temperature rises to 150oC (typ.), the part switches into shutdown mode. The LM2770 disengages thermal shutdown
when the junction temperature of the part is reduced to
140oC (typ.). Due to the high efficiency of the LM2770,
thermal shutdown and/or thermal cycling should not be encountered when the part is operated within specified input
voltage, output current, and ambient temperature operating
ratings. If thermal cycling is seen under these conditions, the
most likely cause is an inadequate PCB layout that does not
allow heat to be sufficiently dissipated out of the LLP package.
Manufacturer
Contact Information
AVX
www.avx.com
Murata
www.murata.com
Taiyo-Yuden
www.t-yuden.com
TDK
www.component.tdk.com
Vishay-Vitramon
www.vishay.com
OUTPUT CAPACITOR AND OUTPUT VOTAGE RIPPLE
The output capacitor in the LM2770 circuit (COUT) directly
impacts the magnitude of output voltage ripple. Other prominent factors also affecting output voltage ripple include input
voltage, output current and flying capacitance. Due to the
complexity of multi-gain and PFM switching, providing equations or models to approximate the magnitude of the ripple
can not be easily accomplished. But one important generalization can be made: increasing (decreasing) the output capacitance will result in a proportional decrease (increase) in
output voltage ripple. This can be observed in the output
voltage ripple waveforms in the Typical Performance Characteristics section.
In typical high-current applications, a 10µF low-ESR ceramic
output capacitor is recommended. Different output capacitance values can be used to reduce ripple, shrink the solution size, and/or cut the cost of the solution. But changing the
output capacitor may also require changing the flying capacitors and/or input capacitor to maintain good overall circuit
performance. Performance of the LM2770 with different capacitor setups in discussed in the section Recommended
Capacitor Configurations.
High ESR in the output capacitor increases output voltage
ripple. If a ceramic capacitor is used at the output, this is
usually not a concern because the ESR of a ceramic capacitor is typically vey low and has only a minimal impact on
ripple magnitudes. If a different capacitor type with higher
ESR is used (tantalum, for example), the ESR could result in
high ripple. To eliminate this effect, the net output ESR can
be significantly reduced by placing a low-ESR ceramic capacitor in parallel with the primary output capacitor. The low
ESR of the ceramic capacitor will be in parallel with the
higher ESR, resulting in a low net ESR based on the principles of parallel resistance reduction.
Due to the PFM nature of the LM2770, output voltage ripple
is highest at light loads. To eliminate this ripple, consider
running the LM2770 in sleep mode when load currents are
20mA or less. Sleep mode disables the charge pump and
enables the internal low-noise bypass linear regulator (LDO).
SHORT-CIRCUIT AND CURRENT LIMIT PROTECTION
The LM2770 charge pump contains circuitry that protects the
device from destructive failure in the event of a direct short to
ground on the output. This short-circuit protection circuit
limits the output current to 400mA (typ.) when the output
voltage is below 165mV (typ.). The sleep-mode LDO contains a 60mA (typ.) current limit circuit.
Application Information
RECOMMENDED CAPACITOR TYPES
The LM2770 requires 4 external capacitors for proper operation. Surface-mount multi-layer ceramic capacitors are recommended. These capacitors are small, inexpensive and
have very low equivalent series resistance (ESR, ≤ 15mΩ
typ.). Tantalum capacitors, OS-CON capacitors, and aluminum electrolytic capacitors generally are not recommended
for use with the LM2770 due to their high ESR, as compared
to ceramic capacitors.
For most applications, ceramic capacitors with an X7R or
X5R temperature characteristic are preferred for use with the
LM2770. These capacitors have tight capacitance tolerance
(as good as ± 10%) and hold their value over temperature
(X7R: ± 15% over -55oC to 125oC; X5R: ± 15% over -55oC to
85oC).
Capacitors with a Y5V or Z5U temperature characteristic are
generally not recommended for use with the LM2770. These
types of capacitors typically have wide capacitance tolerance (+80%, -20%) and vary significantly over temperature
(Y5V: +22%, -82% over -30oC to +85oC range; Z5U: +22%,
-56% over +10oC to +85oC range). Under some conditions, a
1µF-rated Y5V or Z5U capacitor could have a capacitance
as low as 0.1µF. Such detrimental deviation is likely to cause
Y5V and Z5U capacitors to fail to meet the minimum capacitance requirements of the LM2770.
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LM2770
Operation Description
LM2770
Application Information
capacitance is too small, the LM2770 may not be able to
regulate the output voltage when load currents are high. On
the other hand, if the flying capacitance is too large, the
flying capacitors might overwhelm the input and output capacitors, resulting in increased input and output ripple.
(Continued)
INPUT CAPACITOR AND INPUT VOTLAGE RIPPLE
The input capacitor (CIN) is a reservoir of charge that aids a
quick transfer of charge from the supply to the flying capacitors during the charge phase of operation. The input capacitor helps to keep the input voltage from drooping at the start
of the charge phase when the flying capacitor is connected
to the input. It also filters noise on the input pin, keeping this
noise out of sensitive internal analog circuitry that is biased
off the input line.
Much like the relationship between the output capacitance
and output voltage ripple, input capacitance has a dominant
and first-order effect on input ripple magnitude. Increasing
(decreasing) the input capacitance will result in a proportional decrease (increase) in input voltage ripple. This can be
observed in the input voltage ripple waveforms in the Typical Performance Characteristics section. Input voltage,
output current, and flying capacitance also will affect input
ripple levels to some degree.
The flying capacitors should be identical. As a general guideline, the capacitance value of each flying capacitor should be
1/10th that of the output capacitor, up to a maximum of 1µF.
This is a recommendation, not a requirement. Polarized
capacitors (tantalum, aluminum electrolytic, etc.) must not be
used for the flying capacitors, however, as they could become reverse-biased during LM2770 operation.
RECOMMENDED CAPACITOR CONFIGURATIONS
The data in Table 1 can be used to assist in the selection of
a capacitor configuration that best balances solution size
and cost with the electrical requirements of the application
(ripple voltages, output current capability, etc.).
As previously discussed, input and output ripple voltages
and frequencies will vary considerably with output current
and input voltage. The numbers provided show expected
ripple voltage when VIN = 3.6V and load currents are between 100mA and 250mA. The table offers first look at
approximate ripple levels and provides a comparison for the
different capacitor configurations presented, but is not intended to be a guarantee of performance.
The columns that provide minimum input voltage recommendations illustrate the effect that smaller flying capacitors have
on charge pump output current capability. Using smaller
flying capacitors increases the output resistance of the
charge pump. As a result, the minimunm input voltage of an
application using small flying capacitance may need to be
set slightly higher to prevent the output from falling out of
regulation when loaded.
In typical high-current applications, a 10µF low-ESR ceramic
capacitor is recommended on the input. Different input capacitance values can be used to reduce ripple, shrink the
solution size, and/or cut the cost of the solution. But changing the input capacitor may also require changing the flying
capacitors and/or output capacitor to maintain good overall
circuit performance. Performance of the LM2770 with different capacitor setups is discussed below in Recommended
Capacitor Configurations.
FLYING CAPACITORS
The flying capacitors (C1 and C2) transfer charge from the
input to the output. Flying capacitance can impact both
output current capability and ripple magnitudes. If flying
TABLE 1. LM2770 Performance with Different Capacitor Configurations (Note 13)
TYPICAL
OUTUT
RIPPLE
(VIN = 3.6V)
TYPICAL
INPUT
RIPPLE
(VIN = 3.6V)
CIN = COUT = 2x10µF,
C1 = C2 = 1µF
25mV
CIN = COUT = 10µF,
C1 = C2 = 1µF
CAPACITOR
CONFIGURATION
Recommended Minimum VIN for Different Output Currents
IOUT = 50mA
IOUT = 150mA
IOUT = 250mA
35mV
3.0V
3.0V
3.1V
50mV
70mV
3.0V
3.0V
3.1V
CIN = COUT = 4.7µF,
C1 = C2 = 0.47µF
130mV
150mV
3.0V
3.1V
3.2V
CIN = COUT = 2.2µF,
C1 = C2 = 0.22µF
200mV
260mV
3.0V
3.1V
3.2V
Note 13: Refer to the text in the Recommended Capacitor Configurations section for detailed information on the data in this table
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12
LM2770
Layout Guidelines
Proper board layout will help to ensure optimal performance
of the LM2770 circuit. The following guidelines are recommended:
• Place capacitors as close to the LM2770 as possible, and
preferably on the same side of the board as the IC.
• Use short, wide traces to connect the external capacitors
to the LM2770 to minimize trace resistance and inductance.
• Use a low resistance connection between ground and the
GND pin of the LM2770. Using wide traces and/or multiple vias to connect GND to a ground plane on the board
is most advantageous.
20126015
FIGURE 1. Recommended Board Layout of a LM2770 Circuit
Unlabelled vias connect to an internal ground plane.
13
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LM2770 High Efficiency Switched Capacitor Step-Down DC/DC Regulator with Sleep Mode
Physical Dimensions
inches (millimeters) unless otherwise noted
SDA10A: 10-Pin Non-Pullback Leadless Leadframe Package
3.0mm x 3.0mm x 0.8mm
National does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and National reserves
the right at any time without notice to change said circuitry and specifications.
For the most current product information visit us at www.national.com.
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