LM2854MHX-500/NOPB - NATIONAL SEMICONDUCTOR

LM2853

LM2853 3A 550 kHz Synchronous SIMPLE SWITCHER® Buck Regulator

Literature Number: SNVS459

LM2853

3A 550 kHz Synchronous SIMPLE SWITCHER®Buck

Regulator

General Description

The LM2853 synchronous SIMPLE SWITCHER®buck regu-

lator is a 550 kHz step-down switching voltage regulator

capable of driving up to a 3A load with excellent line and load

regulation. The LM2853 accepts an input voltage between

3.0V and 5.5V and delivers a customizable output voltage

that is factory programmable from 0.8V to 3.3V in 100mV

increments. Internal type-three compensation enables a low

component count solution and greatly simplifies external

component selection. The exposed-pad TSSOP-14 package

enhances the thermal performance of the LM2853.

Features

nInput voltage range of 3.0V to 5.5V

nFactory EEPROM set output voltages from 0.8V to 3.3V

in 100 mV increments

nMaximum load current of 3A

nVoltage Mode Control

nInternal type-three compensation

nSwitching frequency of 550 kHz

nLow standby current of 12 µA

nInternal 40 mΩMOSFET switches

nStandard voltage options

0.8/1.0/1.2/1.5/1.8/2.5/3.0/3.3 volts

nExposed pad TSSOP-14 package

Applications

nLow voltage point of load regulation

nLocal solution for FPGA/DSP/ASIC core power

nBroadband networking and communications

infrastructure

Typical Application Circuit

20201502

Efficiency vs Load Current (V

OUT

= 3.3V)

20201501

SIMPLE SWITCHER®is a Registered Trademark of National Semiconductor Corporation.

October 2006

LM2853 3A 550 kHz Synchronous SIMPLE SWITCHER

Buck Regulator

Connection Diagram

20201503

Ordering Information

Order Number

Voltage

Option

Package

Marking Package Type

Package

Drawing Supplied As

LM2853MH-0.8 0.8 LM2853-0.8

TSSOP-14 exposed

pad MXA14A

94 Units, Rail

LM2853MHX-0.8 2500 Units, Tape and Reel

LM2853MH-1.0 1.0 LM2853-1.0 94 Units, Rail

LM2853MHX-1.0 2500 Units, Tape and Reel

LM2853MH-1.2 1.2 LM2853-1.2 94 Units, Rail

LM2853MHX-1.2 2500 Units, Tape and Reel

LM2853MH-1.5 1.5 LM2853-1.5 94 Units, Rail

LM2853MHX-1.5 2500 Units, Tape and Reel

LM2853MH-1.8 1.8 LM2853-1.8 94 Units, Rail

LM2853MHX-1.8 2500 Units, Tape and Reel

LM2853MH-2.5 2.5 LM2853-2.5 94 Units, Rail

LM2853MHX-2.5 2500 Units, Tape and Reel

LM2853MH-3.0 3.0 LM2853-3.0 94 Units, Rail

LM2853MHX-3.0 2500 Units, Tape and Reel

LM2853MH-3.3 3.3 LM2853-3.3 94 Units, Rail

LM2853MHX-3.3 2500 Units, Tape and Reel

Note: Contact factory for other voltage options.

Pin Descriptions

Pin # Name Function

1 AVIN Input Voltage for Control Circuitry.

2 EN Enable.

3 SGND Low noise ground.

4 SS Soft-Start Pin.

5 NC No Connect. This pin must be tied to ground.

6,7 PVIN Input Voltage for Power Circuitry.

8,9 SW Switch Pin.

10,11 PGND Power Ground.

12,13 NC No-Connect. These pins must be tied to ground.

14 SNS Output Voltage Sense Pin.

Exposed Pad EP The exposed pad is internally connected to GND, but it cannot be

used as the primary GND connection. The exposed pad should be

soldered to an external GND plane.

LM2853

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Absolute Maximum Ratings (Note 1)

If Military/Aerospace specified devices are required,

please contact the National Semiconductor Sales Office/

Distributors for availability and specifications.

AVIN, PVIN, EN, SNS, SW, SS −0.3V to 6.0V

ESD Susceptibility (Note 2) 2kV

Power Dissipation Internally Limited

Storage Temperature Range −65˚C to +150˚C

Maximum Junction Temp. 150˚C

14-Pin Exposed Pad TSSOP Package

Infrared (15 sec) 220˚C

Vapor Phase (60 sec) 215˚C

Soldering (10 sec) 260˚C

Operating Ratings (Note 1)

PVIN to GND 1.5V to 5.5V

AVIN to GND 3.0V to 5.5V

Junction Temperature −40˚C to +125˚C

Electrical Characteristics Specifications with standard typeface are for T

= 25˚C, and those in bold face

type apply over the full Junction Temperature Range (−40˚C to 125˚C). Minimum and Maximum limits are guaranteed through

test, design or statistical correlation. Typical values represent the most likely parametric norm at T

= 25˚C and are provided

for reference purposes only. Unless otherwise specified AVIN = PVIN = 5V.

Symbol Parameter Conditions Min Typ Max Units

SYSTEM PARAMETERS

OUT

Voltage Tolerance (Note 3) V

OUT

= 0.8V option 0.782 0.8 0.818

OUT

= 1.0V option 0.9775 1.0 1.0225

OUT

= 1.2V option 1.1730 1.2 1.227

OUT

= 1.5V option 1.4663 1.5 1.5337

OUT

= 1.8V option 1.7595 1.8 1.8405

OUT

= 2.5V option 2.4437 2.5 2.5563

OUT

= 3.0V option 2.9325 3.0 3.0675

OUT

= 3.3V option 3.2257 3.3 3.3743

∆V

OUT

/∆AVIN Line Regulation (Note 3) V

OUT

= 0.8V, 1.0V, 1.2V, 1.5V,

1.8V or 2.5V

3.0V ≤AVIN ≤5.5V

0.2 1.1 %

OUT

= 3.0V or 3.3V

3.5V ≤AVIN ≤5.5V

0.2 1.1 %

∆V

OUT

/∆I

Load Regulation Normal operation 2 mV/A

UVLO Threshold (AVIN) Rising 2.47 3.0 V

Falling Hysteresis 50 155 260 mV

DS(ON)-P

PFET On Resistance Isw = 3A 40 120 mΩ

DS(ON)-N

NFET On Resistance Isw = 3A 32 100 mΩ

Soft-Start Resistance 450 kΩ

Peak Current Limit Threshold 3.6 5A

Operating Current Non-switching 0.85 2mA

Shutdown Quiescent Current EN = 0V 12 50 µA

SNS

Sense Pin Resistance 432 kΩ

PWM

osc

Switching Frequency . 325 550 725 kHz

range

Duty Cycle Range 0 100 %

ENABLE CONTROL (Note 4)

EN Pin Minimum High Input 75 %of

AVIN

EN Pin Maximum Low Input 25 %of

AVIN

EN Pin Pullup Current EN = 0V 1.5 µA

LM2853

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Electrical Characteristics Specifications with standard typeface are for T

= 25˚C, and those in bold face type

apply over the full Junction Temperature Range (−40˚C to 125˚C). Minimum and Maximum limits are guaranteed through test,

design or statistical correlation. Typical values represent the most likely parametric norm at T

= 25˚C and are provided for

reference purposes only. Unless otherwise specified AVIN = PVIN = 5V. (Continued)

Symbol Parameter Conditions Min Typ Max Units

THERMAL CONTROLS

Thermal Shutdown Threshold 165 ˚C

SD-HYS

Hysteresis for Thermal

Shutdown

10 ˚C

THERMAL RESISTANCE

Junction to Ambient MXA14A 38 ˚C/W

Note 1: Absolute maximum ratings indicate limits beyond which damage to the device may occur. Operating Range indicates conditions for which the device is

intended to be functional, but does not guarantee specific performance limits. For guaranteed specifications and test conditions, see the Electrical Characteristics.

Note 2: The human body model is a 100 pF capacitor discharged through a 1.5 kΩresistor into each pin. Test Method is per JESD22-AI14.

Note 3: VOUT measured in a non-switching, closed-loop configuration at the SNS pin.

Note 4: The enable pin is internally pulled up, so the LM2853 is automatically enabled unless an external enable voltage is applied.

LM2853

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Typical Performance Characteristics Unless otherwise specified, the following conditions apply: V

= AVIN = PVIN = 5V, T

= 25˚C.

Efficiency vs. I

LOAD

OUT

= 1.8V NFET R

DS(ON)

vs. Temperature

20201507 20201505

Efficiency vs. I

LOAD

OUT

= 2.5V PFET R

DS(ON)

vs. Temperature

20201509 20201504

Efficiency vs. I

LOAD

OUT

= 3.3V Switching Frequency vs. Temperature

20201508 20201506

LM2853

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Typical Performance Characteristics Unless otherwise specified, the following conditions apply: V

= AVIN = PVIN = 5V, T

= 25˚C. (Continued)

vs. V

and Temperature I

vs. V

and Temperature

20201510 20201511

LM2853

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Block Diagram

20201512

Applications Information

The LM2853 is a DC-DC buck regulator belonging to Na-

tional Semiconductor’s synchronous SIMPLE SWITCHER®

family. Integration of the PWM controller, power switches

and compensation network greatly reduces the component

count required to implement a switching power supply. A

typical application requires only four components: an input

capacitor, a soft-start capacitor, an output filter capacitor and

an output filter inductor.

INPUT CAPACITOR (C

)

Fast switching of large currents in the buck converter places

a heavy demand on the voltage source supplying PVIN. The

input capacitor, C

, supplies extra charge when the switcher

needs to draw a burst of current from the supply. The RMS

current rating and the voltage rating of the C

capacitor are

therefore important in the selection of C

. The RMS current

specification can be approximated by:

where D is the duty cycle, V

OUT

also provides

filtering of the supply. Trace resistance and inductance de-

grade the benefits of the input capacitor, so C

should be

placed very close to PVIN in the layout. A 22 µF or 47 µF

ceramic capacitor is typically sufficient for C

. In parallel

with the large input capacitance a smaller capacitor should

be added such asa1µFceramic for higher frequency

filtering. Ceramic capacitors with high quality dielectrics such

as X5R or X7R should be used to provide a constant capaci-

tance across temperature and line variations. For improved

load regulation and transient performance, the use of a small

1 µF ceramic capacitor is also recommended as a local

bypass for the AVIN pin.

SOFT-START CAPACITOR (C

)

The DAC that sets the reference voltage of the error ampli-

fier sources a current through a resistor to set the reference

voltage. The reference voltage is one half of the output

voltage of the switcher due to the 200 kΩdivider connected

to the SNS pin. Upon start-up, the output voltage of the

switcher tracks the reference voltage with a two to one ratio

as the DAC current charges the capacitance connected to

the reference voltage node. Internal capacitance of 20 pF is

permanently attached to the reference voltage node which is

also connected to the soft start pin, SS. Adding a soft-start

capacitor externally increases the time it takes for the output

voltage to reach its final level. The charging time required for

the reference voltage can be estimated using the RC time

constant of the DAC resistor and the capacitance connected

to the SS pin. Three RC time constant periods are needed

for the reference voltage to reach 95% of its final value. The

actual start up time will vary with differences in the DAC

resistance and higher-order effects.

If little or no soft-start capacitance is connected, then the

start up time may be determined by the time required for the

current limit current to charge the output filter capacitance.

The capacitor charging equationI=C∆V/∆t can be used to

estimate the start-up time in this case. For example, a part

with a 3V output, a 100 µF output capacitance and a 5A

current limit threshold would require a time of 60 µs:

LM2853

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Applications Information (Continued)

Since it is undesirable for the power supply to start up in

current limit, a soft-start capacitor must be chosen to force

the LM2853 to start up in a more controlled fashion based on

the charging of the soft-start capacitance. In this example,

supposea3msstart time is desired. Three time constants

are required for charging the soft-start capacitor to 95% of

the final reference voltage. So in this case RC = 1 ms. The

DAC resistor, R, is 450 kΩso C can be calculated to be 2.2

nF. A 2.2 nF ceramic capacitor can be chosen to yield

approximatelya3msstart-up time.

SOFT-START CAPACITOR (C

) AND FAULT

CONDITIONS

Various fault conditions such as short circuit and UVLO of

the LM2853 activate internal circuitry designed to control the

voltage on the soft-start capacitor. For example, during a

short circuit current limit event, the output voltage typically

falls to a low voltage. During this time, the soft-start voltage

is forced to track the output so that once the short is re-

moved, the LM2853 can restart gracefully from whatever

voltage the output reached during the short circuit event. The

range of soft-start capacitors is therefore restricted to values

1nFto50nF.

COMPENSATION

The LM2853 provides a highly integrated solution to power

supply design. The compensation of the LM2853, which is

type-three, is included on-chip. The benefit of integrated

compensation is straight-forward, simple power supply de-

sign. Since the output filter capacitor and inductor values

impact the compensation of the control loop, the range of L

and C

ESR

values is restricted in order to ensure stability.

OUTPUT FILTER VALUES

Table 1 details the recommended inductor and capacitor

ranges for the LM2853 that are suggested for various typical

output voltages. Values slightly different than those recom-

mended may be used, however the phase margin of the

power supply may be degraded. For best performance when

output voltage ripple is a concern, ESR values near the

minimum of the recommended range should be paired with

capacitance values near the maximum. If a minimum output

voltage ripple solution from a 5V input voltage is desired, a

6.8 µH inductor can be paired with a 220 µF (50 mΩ)

capacitor without degraded phase margin.

TABLE 1. Recommended L

and C

Values

OUT

(V) VIN (V)

(µH) C

(µF) C

ESR

(mΩ)

Min Max Min Max Min Max

0.8 5 4.7 6.8 120 220 70 100

0.8 3.3 4.7 4.7 150 220 50 100

1 5 4.7 6.8 120 220 70 100

1 3.3 4.7 4.7 150 220 50 100

1.2 5 4.7 6.8 120 220 70 100

1.2 3.3 4.7 4.7 120 220 60 100

1.5 5 4.7 6.8 120 220 70 100

1.5 3.3 4.7 4.7 120 220 60 100

1.8 5 4.7 6.8 120 220 70 120

1.8 3.3 4.7 4.7 100 220 70 120

2.5 5 4.7 6.8 120 220 70 150

2.5 3.3 4.7 4.7 100 220 80 150

3.0 5 4.7 6.8 120 220 70 150

3.0 3.3 4.7 4.7 100 220 80 150

3.3 5 4.7 6.8 120 220 70 150

LM2853

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Applications Information (Continued)

CHOOSING AN INDUCTANCE VALUE

The current ripple present in the output filter inductor is

determined by the input voltage, output voltage, switching

frequency and inductance according to the following equa-

tion:

where ∆I

is the peak to peak current ripple, D is the duty

cycle V

OUT

is the input voltage applied to the output

stage, V

OUT

is the output voltage of the switcher, f is the

switching frequency and L

is the inductance of the output

filter inductor. Knowing the current ripple is important for

inductor selection since the peak current through the induc-

tor is the load current plus one half the ripple current. Care

must be taken to ensure the peak inductor current does not

reach a level high enough to trip the current limit circuitry of

the LM2853. As an example, consider a 5V to 1.2V conver-

sion and a 550 kHz switching frequency. According to Table

1, a 4.7 µH inductor may be used. Calculating the expected

peak-to-peak ripple,

The maximum inductor current for a 3A load would therefore

be 3A plus 177 mA, 3.177A. As shown in the ripple equation,

the current ripple is inversely proportional to inductance.

OUTPUT FILTER INDUCTORS

Once the inductance value is chosen, the key parameter for

selecting the output filter inductor is its saturation current

SAT

) specification. Typically I

SAT

is given by the manufac-

turer as the current at which the inductance of the coil falls to

a certain percentage of the nominal inductance. The I

SAT

an inductor used in an application should be greater than the

maximum expected inductor current to avoid saturation. Be-

low is a table of inductors that are suitable in LM2853

applications.

TABLE 2. Recommended Inductors

Inductance Part Number Vendor

4.7 µF DO3308P-472ML Coilcraft

4.7 µF DO3316P-472ML Coilcraft

4.7 µF MSS1260-472ML Coilcraft

5.2 µF MSS1038-522NL Coilcraft

5.6 µF MSS1260-562ML Coilcraft

6.8 µF DO3316P-682ML Coilcraft

6.8 µF MSS1260-682ML Coilcraft

OUTPUT FILTER CAPACITORS

The recommended capacitors that may be used in the output

filter with the LM2853 are limited in value and ESR range

according to Table 1.

Below are some examples of capacitors that can typically be

used in an LM2853 application.

TABLE 3. Recommended Capacitors

Capacitance (µF) Part Number Chemistry Vendor

100 594D107X_010C2T Tantalum Vishay-Sprague

100 593D107X_010D2_E3 Tantalum Vishay-Sprague

100 TPSC107M006#0075 Tantalum AVX

100 NOSD107M006#0080 Niobium Oxide AVX

100 NOSC107M004#0070 Niobium Oxide AVX

120 594D127X_6R3C2T Tantalum Vishay-Sprague

150 594D157X_010C2T Tantalum Vishay-Sprague

150 595D157X_010D2T Tantalum Vishay-Sprague

150 591D157X_6R3C2_20H Tantalum Vishay-Sprague

150 TPSD157M006#0050 Tantalum AVX

150 TPSC157M004#0070 Tantalum AVX

150 NOSD157M006#0070 Niobium Oxide AVX

220 594D227X_6R3D2T Tantalum Vishay-Sprague

220 591D227X_6R3D2_20H Tantalum Vishay-Sprague

220 591D227X_010D2_20H Tantalum Vishay-Sprague

220 593D227X_6R3D2_E3 Tantalum Vishay-Sprague

LM2853

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Applications Information (Continued)

TABLE 3. Recommended Capacitors (Continued)

Capacitance (µF) Part Number Chemistry Vendor

220 TPSD227M006#0050 Tantalum AVX

220 NOSD227M0040060 Niobium Oxide AVX

SPLIT-RAIL OPERATION

The LM2853 can be powered using two separate voltages

for AVIN and PVIN. AVIN is the supply for the control logic;

PVIN is the supply for the power FETs. The output filter

components need to be chosen based on the value of PVIN.

For PVIN levels lower than 3.3V, use output filter component

values recommended for 3.3V. PVIN must always be equal

to or less than AVIN.

20201513

SWITCH NODE PROTECTION

The LM2853 includes protection circuitry that monitors the

voltage on the switch pin. Under certain fault conditions,

switching is disabled in order to protect the switching de-

vices. One side effect of the protection circuitry may be

observed when power to the LM2853 is applied with no or

light load on the output. The output will regulate to the rated

voltage, but no switching may be observed. As soon as the

output is loaded, the LM2853 will begin normal switching

operation.

LAYOUT GUIDELINES

These are several guidelines to follow while designing the

PCB layout for an LM2853 application.

1. The input bulk capacitor, C

, should be placed very

close to the PVIN pin to keep the resistance as low as

possible between the capacitor and the pin. High current

levels will be present in this connection.

2. All ground connections must be tied together. Use a

broad ground plane, for example a completely filled back

plane, to establish the lowest resistance possible be-

tween all ground connections.

3. The sense pin connection should be made as close to

the load as possible so that the voltage at the load is the

expected regulated value. The sense line should not run

too close to nodes with high dV/dt or dl/dt (such as the

switch node) to minimize interference.

4. The switch node connections should be low resistance

to reduce power losses. Low resistance means the trace

between the switch pin and the inductor should be wide.

However, the area of the switch node should not be too

large since EMI increases with greater area. So connect

the inductor to the switch pin with a short, but wide trace.

Other high current connections in the application such

as PVIN and V

OUT

assume the same trade off between

low resistance and EMI.

5. Allow area under the chip to solder the entire exposed

die attach pad to ground for improved thermal perfor-

mance. Lab measurements also show improved regula-

tion performance when the exposed pad is well

grounded.

LM2853 Example Circuit Schematic

20201514

FIGURE 1.

LM2853

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LM2853 Example Circuit Schematic (Continued)

Bill of Materials for 5V to 3.3V Conversion

ID Part Number Type Size Parameters Qty Vendor

LM2853MH-3.3 3A Buck ETSSOP-14 3.3V 1 NSC

GRM31CR60J476ME19 Capacitor 1206 47 µF 1 Murata

BYP

GRM21BR71C105KA01 Capacitor 0805 1 µF 1 Murata

VJ0805Y222KXXA Capacitor 0603 2.2 nF 1 Vishay-Vitramon

DO3316P-682 Inductor DO3316P 6.8 µH 1 Coilcraft

594D127X06R3C2T Capacitor C Case 120µF

(85mΩ)

1 Vishay-Sprague

Bill of Materials for 3.3V to 1.2V Conversion

ID Part Number Type Size Parameters Qty Vendor

LM2853MH-1.2 3A Buck ETSSOP-14 1.2V 1 NSC

GRM31CR60J476ME19 Capacitor 1206 47 µF 1 Murata

BYP

GRM21BR71C105KA01 Capacitor 0805 1 µF 1 Murata

CSS VJ0805Y222KXXA Capacitor 0603 2.2 nF 1 Vishay-Vitramon

DO3316P-472 Inductor DO3316P 4.7 µH 1 Coilcraft

NOSD157M006R0070 Capacitor D Case 150 µF

(70 mΩ)

1AVX

LM2853

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Physical Dimensions inches (millimeters) unless otherwise noted

14-Lead ETSSOP Package

NS Package Number MXA14A

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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NATIONAL’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS

WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT AND GENERAL COUNSEL OF NATIONAL SEMICONDUCTOR

CORPORATION. As used herein:

1. Life support devices or systems are devices or systems

which, (a) are intended for surgical implant into the body, or

(b) support or sustain life, and whose failure to perform when

properly used in accordance with instructions for use

provided in the labeling, can be reasonably expected to result

in a significant injury to the user.

2. A critical component is any component of a life support

device or system whose failure to perform can be reasonably

expected to cause the failure of the life support device or

system, or to affect its safety or effectiveness.

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National Semiconductor follows the provisions of the Product Stewardship Guide for Customers (CSP-9-111C2) and Banned Substances

and Materials of Interest Specification (CSP-9-111S2) for regulatory environmental compliance. Details may be found at:

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LM2853 3A 550 kHz Synchronous SIMPLE SWITCHER

Buck Regulator

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