SA57255-20GW-G [NXP]

IC 0.3 A SWITCHING CONTROLLER, 115 kHz SWITCHING FREQ-MAX, PDSO5, 1.50 MM, PLASTIC, MO-178, SOT-25, SOT-23, SOP-5, Switching Regulator or Controller;


型号：	SA57255-20GW-G
厂家：	NXP
描述：	IC 0.3 A SWITCHING CONTROLLER, 115 kHz SWITCHING FREQ-MAX, PDSO5, 1.50 MM, PLASTIC, MO-178, SOT-25, SOT-23, SOP-5, Switching Regulator or Controller 开关光电二极管
文件：	总17页 (文件大小：238K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

INTEGRATED CIRCUITS

SA57255-XX

CMOS switching regulator

(PWM controlled)

Product data

2003 Nov 11

Supersedes data of 2001 Aug 01

Philips

Semiconductors

Philips Semiconductors

Product data

CMOS switching regulator (PWM controlled)

SA57255-XX

GENERAL DESCRIPTION

The SA57255-XX is a highly integrated DC/DC converter circuit.

Efficient, compact power conversion is achieved with a pulse width

modulation (PWM) controlled switching regulator circuit designed

using CMOS processing. Low ripple and high efficiency of typically

83% are achieved through PWM control. The regulator has a high

precision output with ±2.4% accuracy. Few external components are

required.

The SA57255-XX has a built-in, soft-start circuit to reduce current

inrush and voltage overshoot during start up. The PWM control

circuit is designed to drive an external low resistance NPN bipolar

junction transistor (BJT). The DRIVE output provides typically 7 mA

at 100 kHz typical switching frequency to drive the BJT.

FEATURES

• Operates from 0.7 to 9 V

APPLICATIONS

• Mobile and portable phones

• Ultra low operating supply current—typically 17 µA

• Uses external power BJT

• Instrumentation and industrial products

• Other portable, battery-operated equipment

• High efficiency—typically 83%

• High precision output—typically ±2.4%

• Operating temperature range of –40 to +85 °C

• Available output voltages: 2.0, 2.5, 2.8, 3.0, 3.3, 3.6, 5.0 V

• Available in a 5-lead small outline surface mount package

(SOP003)

SIMPLIFIED SYSTEM DIAGRAM

OUT

BATT

SA57255-XX

REF

DRIVE

PWM CONTROL

GND

SOFT START

SA57255-XX as a boost (step-up) converter.

SL01508

Figure 1. Simplified system diagram.

2003 Nov 11

Philips Semiconductors

Product data

CMOS switching regulator (PWM controlled)

SA57255-XX

ORDERING INFORMATION

PACKAGE

TEMPERATURE

RANGE

TYPE NUMBER

NAME

DESCRIPTION

VERSION

SOT23-5,

SOT25, SO5

SA57255-XXGW

Plastic small outline package; 5 leads; body width 1.6 mm

SOP003

–40 to +85 °C

NOTE:

Part number marking

The device has seven voltage output options, indicated by the XX

on the Type Number.

Each device is marked with a four letter code. The first three letters

designate the product. The fourth letter, represented by ‘x’, is a date

tracking code.

VOLTAGE (Typical)

Part number

Marking

A E T x

A E U x

A E V x

A E W x

A E X x

A E Y x

A E Z x

2.0 V

2.5 V

2.8 V

3.0 V

3.3 V

3.6 V

5.0 V

SA57255-20GW

SA57255-25GW

SA57255-28GW

SA57255-30GW

SA57255-33GW

SA57255-36GW

SA57255-50GW

PIN CONFIGURATION

PIN DESCRIPTION

PIN SYMBOL

DESCRIPTION

Feedback from the output voltage to the PWM

control.

DRIVE

Voltage input to regulator.

No connection.

N/C

GND

DRIVE

Ground.

N/C

GND

Output for external power transistor.

SL01509

Figure 2. Pin configuration.

MAXIMUM RATINGS

SYMBOL

PARAMETER

MIN.

–0.3

–

MAX.

UNIT

FB pin voltage

Power supply voltage

DRIVE pin voltage

DRIVE pin current

Operating temperature

Storage temperature

Power dissipation

DD(max)

DRIVE

300

+85

+125

150

°C

DRIVE

–40

–

oper

stg

°C

2003 Nov 11

Philips Semiconductors

Product data

CMOS switching regulator (PWM controlled)

SA57255-XX

ELECTRICAL CHARACTERISTICS

amb

= 25 °C, unless otherwise specified.

SYMBOL

PARAMETER

input voltage

CONDITIONS

Part #

–

MIN.

–

TYP.

–

MAX.

9.0

UNIT

operating start voltage

oscillator start voltage

operation hold voltage

consumption current 1

= 1.0 mA

–

0.9

ST1

ST2

HLD

OUT

–

0.7

–

0.8

–

OUT

-20

-25

-28

-30

-33

-36

-50

-20

-25

-28

-30

-33

-36

-50

-20

-25

-28

-30

-33

-36

-50

-20

-25

-28

-30

-33

-36

-50

–

14.5

17.8

20.0

21.4

23.7

28.8

54.0

3.8

24.1

29.7

33.3

35.7

39.5

48.0

89.9

7.6

µA

= output voltage × 0.95

SS1

OUT

–

µA

–

µA

–

µA

–

µA

–

µA

–

µA

–

µA

consumption current 2

OUT

= output voltage + 0.5 V

SS2

–

3.9

7.7

µA

–

3.9

7.8

µA

–

3.9

7.8

µA

–

4.0

7.9

µA

–

4.0

7.9

µA

–

4.2

8.3

µA

–

–1.9

–2.7

–3.5

–5.3

3.8

–2.9

–4.0

–5.3

–8.0

5.7

ppm/°C

DRIVE pin output current

(HIGH)

= V

– 0.4 V

OUT

DRIVEH

DRIVE

–

DRIVE pin output current

(LOW)

= 0.4 V

DRIVEL

DRIVE

–

5.3

8.0

–

5.3

8.0

–

7.0

10.5

–

7.0

–

7.0

–

10.7

∆V

load ripple voltage

= 10 mA ≈ I (following) × 1.25

OUT

–

OUT2

OUT

/∆T

output voltage temperature

coefficient

–40 °C ≤ T ≤ +85 °C

amb

–

±50

–

OUT

amb

oscillator frequency

maximum duty ratio

soft start time

= output voltage × 0.95

–

3.0

–

100

6.0

115

–

kHz

OSC

OUT

MaxDuty

–

OUT

= 1.0 mA

–

OUT

-20

-25

-28

-30

-33

-36

-50

efficiency

FFI

–

2003 Nov 11

Philips Semiconductors

Product data

CMOS switching regulator (PWM controlled)

SA57255-XX

TYPICAL PERFORMANCE CURVES

= OUTPUT VOLTAGE × 0.95

= OUTPUT VOLTAGE = 0.5 V

OUT

SS2

SS1

(

–40

–20

100

–40

–20

100

T , TEMPERATURE °C)

amb

T , TEMPERATURE °C)

amb

SL01489

SL01490

Figure 3. Supply current 1 versus temperature.

Figure 4. Supply current 2 versus temperature.

140

= OUTPUT VOLTAGE × 0.95

amb

= 25 °C

OUT

130

120

110

100

OSC

(kHz)

SS1, 2

(µA)

–40

–20

100

T , TEMPERATURE °C)

amb

(V)

OUT

SL01491

SL01459

Figure 5. Oscillator frequency versus temperature.

Figure 6. Supply current 1, 2 versus V

OUT

–16

= V

OUT

– 0.4 V

DRIVE

–14

–12

–10

–8

DRIVEH

(mA)

–6

–4

–2

–40

–20

100

T , TEMPERATURE °C)

amb

SL01492

Figure 7. DRIVE pin output current HIGH versus temperature.

2003 Nov 11

Philips Semiconductors

Product data

CMOS switching regulator (PWM controlled)

SA57255-XX

= 1.8 V

OUT

OUTPUT VOLTAGE

(20 mV/div)

OUTPUT VOLTAGE

(20 mV/div)

SW VOLTAGE

(1 V/div)

SW VOLTAGE

(1 V/div)

t (10 µs/div)

SL01472

= 1.8 V

SL01473

= 60 mA

Figure 8. Ripple voltage with light load.

Figure 9. Ripple voltage with medium load.

OUT

OUTPUT VOLTAGE

(20 mV/div)

INPUT VOLTAGE

(1 V/div)

OUT

SW VOLTAGE

(1 V/div)

OUTPUT VOLTAGE

(1 V/div)

t (10 µs/div)

t (1 ms/div)

SL01474

SL01475

Figure 10. Ripple voltage with heavy load.

Figure 11. Start-up characteristic V : 0 V → 1.8 V.

I : 100 µA → 50 mA; V = 1.8 V

OUT IN

= 60 mA; V = 1.8 V

OUT

LOAD CURRENT

(20 mA/div)

ON/OFF

INPUT VOLTAGE

(1 V/div)

OUT

OUTPUT VOLTAGE

(50 mV/div)

OUT

OUTPUT VOLTAGE

(1 V/div)

t (1 ms/div)

t (200 µs/div)

SL01476

SL01477

Figure 12. Start-up characteristic V

: 0 V → 3.0 V.

ON/OFF

Figure 13. Output load regulation, increasing current.

2003 Nov 11

Philips Semiconductors

Product data

CMOS switching regulator (PWM controlled)

SA57255-XX

: 50 mA → 100 µA; V = 1.8 V

: 1.8 V → 2.4 V; I

= 50 mA

OUT

LOAD CURRENT

(20 mA/div)

INPUT VOLTAGE

(500 mV/div)

OUT

OUTPUT VOLTAGE

(50 mV/div)

OUTPUT VOLTAGE

(50 mV/div)

t (5 ms/div)

t (100 µs/div)

SL01478

SL01479

Figure 14. Output load regulation, decreasing current.

Figure 15. Input line regulation, increasing voltage.

1.0

0.9

0.8

0.7

0.6

0.5

0.4

0.3

: 2.4 V → 1.8 V; I

= 50 mA

OUT

INPUT VOLTAGE

(500 mV/div)

OUT

ST1

0.2

0.1

0.0

OUTPUT VOLTAGE

(50 mV/div)

t (200 µs/div)

I , OUTPUT CURRENT (mA)

OUT

SL01480

SL01481

Figure 16. Input line regulation, decreasing voltage.

Figure 17. Output current versus starting voltage.

2003 Nov 11

Philips Semiconductors

Product data

CMOS switching regulator (PWM controlled)

SA57255-XX

TECHNICAL DISCUSSION

The SA57255-XX requires an external NPN bipolar transistor to

provide the switching power waveform. Its internal block diagram is

shown in Figure 18.

General discussion

The SA57255-XX is a fixed frequency, boost-mode switching power

supply controller. Each device is set to provide a fixed output voltage

by having a fully compensated internal voltage feedback loop. The

SA57255-XX operates at a fixed frequency of 100 kHz and can

operate from a single alkaline cell (0.9 V) or up to 9 V.

SA57255-XX

REF

DRIVE

PWM CONTROL

GND

SOFT START

SL01510

Figure 18. Functional diagram.

2003 Nov 11

Philips Semiconductors

Product data

CMOS switching regulator (PWM controlled)

SA57255-XX

APPLICATION INFORMATION

The SA57255-XX can be used for a simple boost (step-up)

converter or the less commonly used flyback converter (isolated

boost). The major operating restriction of the simple boost converter

PASSIVE SNUBBER

(OPTIONAL)

is that its output voltage must always be above the highest

expected value of the input voltage. The flyback converter circuit

requires more parts, but the output voltage is not restricted by the

input voltage.

OUT

Boost converter fundamentals

SA57255-XX

The boost or step-up converter is a non-dielectrically isolated

switching power supply topology (arrangement of power parts).

That is, the input power source is directly connected to the output

load (ground and signals). A typical boost converter, with an optional

passive snubber, can be seen in Figure 19.

DRIVE

GND

To understand the boost converter’s operation, examine its three

periods of operation. These periods are: the power switch on-time

(period 1); the inductor discharge period (period 2); and the inductor

empty state (period 3). These periods and their associated currents

can be seen in Figure 20.

SL01511

Figure 19. Boost converter.

SPIKE

ENERGY BEING TRANSFERRED TO OUTPUT

OUT

ENERGY BEING

STORED IN INDUCTOR

CORE EMPTY,

PARASITIC CIRCULATING ENERGY

PERIOD 2

PERIOD 1

PERIOD 3

× R

DS(ON)

peak

(V – V

)

OUT

SL01464

Figure 20. Boost converter waveforms (discontinuous mode).

2003 Nov 11

Philips Semiconductors

Product data

CMOS switching regulator (PWM controlled)

SA57255-XX

Period 1: power switch on-time

Period 3: inductor empty state

During this period, a simple circuit loop is formed when the power

switch is on. The input voltage source is connected directly across

DISCONTINUOUS MODE—This period as displayed in Figure 20 occurs

in the discontinuous–mode of operation of a boost converter. It is

identified by a period of “ringing” following the output period

(period 2). The inductor has been completely emptied of its stored

energy and the switched node returns to the level of the input

voltage. Ringing is seen at this node because a resonant circuit is

the boost inductor (L ). A current ramp is exhibited whose slope is

described by:

V_IN

Eqn. (1)

IL_(on)

L₀

formed by the inductance of L and any parasitic inductances and

Energy is then stored within the core material of the inductor and is

described by:

capacitances connected to that node. This ringing has very little

energy and can easily be eliminated by a small passive snubber.

CONTINUOUS MODE—If the inductor is not completely emptied of its

stored energy before the power switch turns on again, the converter

is operating in the continuous mode. A small amount of residual flux

(energy) remains in the inductor core and the current waveform

jumps to an initial value when the power switch is again turned-on.

This mode offers some advantages over the discontinuous-mode,

because the peak current seen by the power switch is lower. In low

voltage applications, the inductor can store more energy with lower

peak currents.

Eqn. (2)

E_sto+ 0.5L₀ I_peak

This current ramp continues until the controller turns off the power

switch.

Period 2: inductor discharge period

The instant the power switch turns off, the current flowing through

the inductor forces the voltage at its output node (switched node) to

rise quickly above the input voltage (spike). This voltage is then

clamped when it exceeds the device’s output voltage and the output

rectifier becomes forward biased. The inductor empties its stored

energy in the form of a linearly decreasing current ramp whose

slope is dictated by:

The continuous mode waveforms can be seen in Figure 21.

V_IN* V_OUT

Eqn. (3)

I_L(off)

[

L₀

The stored energy is transferred to the output capacitor. This output

current continues until the magnetic core is completely emptied of its

stored energy or the power switch turns back on.

SPIKE

OUT

ENERGY BEING

STORED IN

INDUCTOR

ENERGY BEING

TRANSFERRED

TO OUTPUT

peak

(V – V

)

OUT

RESIDUAL FLUX

SL01465

Figure 21. Continuous mode waveforms.

2003 Nov 11

Philips Semiconductors

Product data

CMOS switching regulator (PWM controlled)

SA57255-XX

Selecting the external NPN transistor

A ceramic capacitor would typically be used in this application if the

required value is less than 1 – 10 µF, or a tantalum capacitor for

required values of 10 µF and above. Lower cost aluminum electrolytic

capacitors can be used, but you should confirm that the higher ESRs

typically exhibited by these capacitors does not cause a problem.

The SA57255-XX requires an external NPN bipolar transistor to

provide the PWM switching waveform to the boost power circuit.

The type of bipolar transistor for this power range includes higher

current “small signal” transistors or “medium power” transistors.

Minimum transistor parameters are:

The minimum value of the output capacitor can be estimated by

Equation (7).

Case: minimum P

800 mW (such as SOT223)

D(max)

HFE

100

20 V

500 mA minimum

(min)

(I_OUT(max)) (T_off

)

VCEO

Eqn. (7)

C_OUT

Where:

V_ripple(p*p)

(max)

A good choice for 0.5 watts and below is the PZT2222A, which

exceeds these specifications.

is the average value of the output load current (A).

OUT

is the nominal off–time of the power switch (sec) [ 10 µs].

off

Determining the value of the boost inductor

is the desired amount of ripple voltage (V ).

p–p

ripple

The precise value of the boost inductor is not critical to the operation

of the SA57255-XX. The value of the boost inductor should be

calculated to provide continuous-mode operation over most of its

operating range. The converter may enter the discontinuous-mode

when the output load current falls to less than about 20 percent of

the full-load current.

Finding the value of the input capacitor is done by Equation (8).

(I_peak) (T_on

V_drop

)

Eqn. (8)

C_IN

Where:

At low input voltages, the time required to store the needed energy

lengthens, but the time needed to empty the inductor’s core of its

energy shrinks. Conversely, at high input voltages, the time needed

to store the energy shrinks while the time needed to empty the core

increases. See Equations (1) and (3). At the extremes of these

conditions, the converter will fall out of regulation, that is the output

voltage will begin to fall, because the time needed for either storing

or emptying the stored inductor energy is too short to support the

output load current.

is the expected maximum peak current of the switch (A).

is the on-time of the switch (sec) [ 10 µs].

is the desired amount of voltage drop across the capacitor

peak

drop

(V ).

p–p

These calculations should produce a good estimate of the needed

values of the input and output capacitors to yield the desired ripple

voltages.

Selecting the output rectifier

Equation (4) determines the nominal value of the inductance.

The output rectifier (D) is critical to the efficiency and low-noise

operation of the boost converter. The majority of the loss within the

supply will be caused by the output rectifier. Three parameters are

important in the rectifier’s operation within a boost-mode supply.

These are defined below.

V_IN(min) T_on

Eqn. (4)

L0 ^

I_peak

Where:

is the lowest expected input operating voltage (V).

is about 5 µs or one-half the switching period (s).

IN(min)

Forward voltage drop (V )—This is the voltage across the rectifier

when a forward current is flowing through the rectifier. A P-N

ultra-fast diode exhibits a 0.7 – 1.4 volt drop, and this drop is

relatively fixed over the range of forward currents. A Schottky diode

exhibits a 0.3 – 0.6 volt drop and appears more resistive during the

forward conduction periods. That is, its forward voltage drop

increases with increasing currents. You can gain an advantage by

purposely over-rating the current rating of a Schottky rectifier.

is the maximum peak current for the NPN transistor.

peak

This is an estimated inductor value and you can select an

inductance value slightly higher or lower with little effect on the

converter’s operation. If the design falls out of regulation within the

desired operating range, reduce the inductance value, but by no

more than 30 percent.

Determining the minimum value of the capacitors

Reverse recovery time (T )—This is an issue when the boost

The input and output capacitors experience the current waveforms

seen in Figures 20 and 21. The peak currents can be typically

between 3 to 6 times the average currents flowing into the input and

from the output. This makes the choice of capacitor an issue of how

much ripple voltage can be tolerated on the capacitor’s terminals

and how much heating the capacitor can tolerate. At the power

levels produced by the SA57255-XX heating is not a major issue.

supply is operating in the continuous-mode. T is the amount of time

required for the rectifier to assume an open circuit when a forward

current is flowing and a reverse voltage is then placed across its

terminals. P-N ultra-fast rectifiers typically have a 25–40 ns reverse

recovery time. Schottky rectifiers have a very short or no reverse

recovery time.

Forward recovery time (T )—This is the amount of time before a

The Equivalent Series Resistance (ESR) of the capacitor, the

resistance that appears between its terminals, and the actual

capacitance causes heat to be generated within the case whenever

there is current entering or exiting the capacitor. ESR also adds to

the apparent voltage drop across the capacitor. The heat that is

generated can be approximated by Equation (5).

rectifier begins conducting forward current after a forward voltage is

placed across its terminals. This parameter is not always well

specified by the rectifier manufacturers. It causes a spike to appear

when the power switch turns off. This particular point in its operation

causes the most radiated noise. Several rectifiers may have to be

evaluated for the prototype. After the final output rectifier selection is

made, if the spike is still causing a problem a small passive snubber

can be placed across the rectifier.

Eqn. (5)

P_D(in watts) ^ (1.8I_av

)

(R_ESR

)

ESR’s effect on the capacitor voltage is given by Equation (6).

For this boost application, the best choice of output rectifier is a low

forward drop, 0.5 – 1 ampere, 20 volt Schottky rectifier such as the

Philips part number BAT120A.

Eqn. (6)

DV_C^ I_peak(R_ESR

)

(expressed as V

)

p–p

2003 Nov 11

Philips Semiconductors

Product data

CMOS switching regulator (PWM controlled)

SA57255-XX

Flyback converter

The SA57255-XX can also be used to create a flyback converter,

COILTRONICS

CTX100-1P

OUT

also known as an isolated boost converter. The advantage of a

flyback converter is that the input voltage can go higher or lower

than the output voltage without affecting the operation of the

converter. The only restrictions are the breakdown voltage of the

OUT

NPN transistor and the feedback (V ) pins.

One transformer can accommodate a variety of output voltages in

different applications, because the circuit will change the on and

off–times to provide the desired output voltage.

DRIVE

SA57255-XX

The output voltage of the flyback can be changed by using a

SA57255-XX with the desired output voltage, with no other changes

to the circuit.

GND

Selecting the components

It is best to operate the transformer in the continuous-mode where

the highest expected peak primary current is below the maximum

current rating of the NPN transistor.

SL01512

Figure 22. Flyback converter circuit.

Begin with a peak current equal to or less than the maximum current

rating of the NPN transistor. A reasonable value of the primary

inductance can be found in Equation (9).

T_on

I_peak

Eqn. (9)

+ V

OUT

L_prit 5V_IN(min)

(1:1 TRANSFORMER)

Where:

is the current rating of the NPN transistor.

peak

is the maximum expected on-time of the switch (≈10 µs).

is the lowest expected input voltage (V).

IN(min)

Then select an off-the-shelf transformer such as the Coiltronics

CTX100–1P, a 1:1 turns ratio transformer that has a primary

inductance of 100 µH. It does not reach saturation until the primary

current reaches 440 mA, which is above the expected peak current

of the flyback converter. The 1:1 turns ratio should work for output

voltages from 0.8 to 2 times the highest input voltage, and produce

the output voltage set by the SA57255-XX. The only other restriction

is that the input voltage plus the output voltage must be less than

the breakdown voltage of the NPN transistor.

OUT

GROUND (0 V)

Use Equation (8) to determine the minimum value for the input

capacitor. A 0.1 V drop is desired across this capacitor.

–V

(0.3A) (10ms)

C_IN

+ 30mF

0.1V

A 47 µF at 6 V tantalum capacitor would be suitable.

For the design example, the output voltage will be +3.3 V with a

maximum output current of 50 mA. The input voltage can vary

between +1.8 V and 4.0 V. The design can be seen in Figure 22,

and the expected waveforms can be seen in Figure 23.

SW(peak)

= I

diode

peak

diode(peak)

(1:1 TRANSFORMER)

SL01468

Figure 23. Flyback converter waveforms.

2003 Nov 11

Philips Semiconductors

Product data

CMOS switching regulator (PWM controlled)

SA57255-XX

Designing a passive snubber

If the switching power supply is generating too much radio

PASSIVE SNUBBER

OUT

frequency interference (RFI) a passive snubber can be added.

A passive snubber is a series resistor and capacitor placed across

any component that exhibits a resonant “ringing”. This series R-L-C

loop creates a lossy or damped tank circuit that dissipates the

ringing energy. The design is critical, because it introduces another

loss within the converter.

OUT

Designing a snubber is an empirical process, mainly because it

involves undefined parasitic capacitances and inductances

contributed by the PCB layout, leakage inductance, and device

capacitances. The snubber should be placed across the major

source of the spike or ringing which is the output rectifier.

SA57255-XX

DRIVE

GND

The usual design process is:

1. Measure the period of the undesired ringing (T ).

SL01513

2. Place a very small ceramic capacitor (about 10 pF) across the

output rectifier or primary winding.

Figure 24. Flyback converter with passive snubber.

3. Re-measure the period of the undesired ringing. The new period

should be about 3 times that of T . If it is less than this, place a

slightly larger value of capacitor across the output rectifier or

primary winding.

4. Once the desired increase in the ringing period is achieved with

a capacitance (C ), place a resistor in series with the capacitor

whose value is approximately:

T₀

Eqn. (10)

R_snubber

2pC₀

This should produce a snubber that does not load the circuit and

introduces a very small loss.

2003 Nov 11

Philips Semiconductors

Product data

CMOS switching regulator (PWM controlled)

SA57255-XX

Designing the PCB for effective heat dissipation

Laying out the printed circuit board

The maximum junction temperature is +125 °C which should not be

exceeded under any operating conditions. Designing a PCB that

includes a heatsink system under the device is the key to cooler

operation of the circuit, and the long–term reliable operation of the

converter.

The design of the printed circuit board (PCB) is critical to the proper

operation of all switching power supplies. Its design affects the

supply stability, radio frequency interference behavior and the

reliability of the converter.

Never use the autoroute feature of any PCB design program

because this will always produce traces that are too long and too

thin.

The major sources of heat within the converter are the power switch

(NPN BJT), the resistive losses within the inductor, and losses

associated with the output rectifier. These losses can be estimated

by the following equations:

The input and output capacitors are the only source or sink of the

high frequency currents found in a switching power supply. All

connections to the switching power supply from the outside circuits

should be made to the input or output capacitor terminals (+ and –).

Internally, the layout should adhere to a “one-point” grounding

system, as shown in Figure 25.

Power switch:

f_sw T_on I_peak V_sat

Eqn. (11)

P_D(sw)

Inductor:

Eqn. (12)

P_D(L0)^ 2I_pk 2R_winding

Output rectifier:

OUT

Eqn. (13)

P_D(rect)^ I_OUT(Vfwd)

The thermal resistance (R

) of the SA57255-XX is approximately

th(j-a)

220 °C/W, assuming the device is soldered to a 2 oz. copper FR4

fiberglass circuit board, and that the minimum footprint was used

(copper just under the leads). A rule of thumb in PCB design is that

the thermal resistance can be reduced by 30% for each doubling of

the copper area close to the device. This effect diminishes for areas

greater than five times the minimum PCB footprint. If you take

advantage of this rule, thermal resistance can be reduced by using

wide copper lands when connecting to the leads of the major

power-producing parts. These PCB traces should almost fill the

areas surrounding the converter parts to conduct heat away from

the device. For demanding applications, additional heat dissipation

area can be created by placing a copper island on the opposite side

of the PCB from each wide trace and connecting it to the trace with

vias (plated thru holes).

OUT

EXT

SA57251-XX

INPUT

OUTPUT

GROUND

TO ONE

POINT

GROUND

TO ONE

POINT

GND

SL01514

Figure 25. Grounding trace for converter.

The traces between the input and output capacitors and the

inductor, power switch and rectifier(s) should be as short and wide

as possible. This reduces the series resistance and inductance that

can be introduced by traces.

The junction temperature can be estimated by Equation (14).

Eqn. (14)

T_j^ (P_D R_th(j-a)Ȁ) ) T_amb(max)

Where:

The guidelines for a PCB layout can be summarized as:

is the power dissipation (W).

′ is the effective thermal resistance with the additional

copper (°C/W).

is the highest local expected ambient temperature (°C).

• The traces between the input and output capacitor to the inductor,

power switch and the rectifier should be made as short and as

wide as possible.

th(j-a)

amb

• Strictly adhere to the one-point wiring practices shown in

Figure 25.

• On a 2-sided board, do not run sensitive signals traces under the

AC voltage node.

• The IC (control) ground is terminated at the output capacitor’s

negative terminal.

2003 Nov 11

Philips Semiconductors

Product data

CMOS switching regulator (PWM controlled)

SA57255-XX

PACKING METHOD

The SA57255-XX is packed in reels, as shown in Figure 26.

GUARD

BAND

TAPE

TAPE DETAIL

REEL

ASSEMBLY

COVER TAPE

CARRIER TAPE

BARCODE

LABEL

BOX

SL01305

Figure 26. Tape and reel packing method.

2003 Nov 11

Philips Semiconductors

Product data

CMOS switching regulator (PWM controlled)

SA57255-XX

Plastic small outline package; 5 leads; body width 1.6 mm

SOP003

2003 Nov 11

Philips Semiconductors

Product data

CMOS switching regulator (PWM controlled)

SA57255-XX

REVISION HISTORY

Rev

Date

Description

20031111

Product data (9397 750 12318). ECN 853-2273 30332 of 09 September 2003.

Supersedes data of 2001 Aug 01 (9397 750 08904).

Modifications:

• Change package outline version to SOP003 in Ordering information table and Package outline sections.

20010801

Product data (9397 750 08904). ECN 853-2273 26807 of 01 August 2001.

Data sheet status

Product

status

Definitions

[1]

Level

Data sheet status

[2] [3]

Objective data

Development

This data sheet contains data from the objective specification for product development.

Philips Semiconductors reserves the right to change the specification in any manner without notice.

Preliminary data

Qualification

Production

This data sheet contains data from the preliminary specification. Supplementary data will be published

at a later date. Philips Semiconductors reserves the right to change the specification without notice, in

order to improve the design and supply the best possible product.

III

Product data

This data sheet contains data from the product specification. Philips Semiconductors reserves the

right to make changes at any time in order to improve the design, manufacturing and supply. Relevant

changes will be communicated via a Customer Product/Process Change Notification (CPCN).

[1] Please consult the most recently issued data sheet before initiating or completing a design.

[2] The product status of the device(s) described in this data sheet may have changed since this data sheet was published. The latest information is available on the Internet at URL

http://www.semiconductors.philips.com.

[3] For data sheets describing multiple type numbers, the highest-level product status determines the data sheet status.

Definitions

Short-form specification — The data in a short-form specification is extracted from a full data sheet with the same type number and title. For detailed information see

the relevant data sheet or data handbook.

Limitingvaluesdefinition— Limiting values given are in accordance with the Absolute Maximum Rating System (IEC 60134). Stress above one or more of the limiting

values may cause permanent damage to the device. These are stress ratings only and operation of the device at these or at any other conditions above those given

in the Characteristics sections of the specification is not implied. Exposure to limiting values for extended periods may affect device reliability.

Application information — Applications that are described herein for any of these products are for illustrative purposes only. Philips Semiconductors make no

representation or warranty that such applications will be suitable for the specified use without further testing or modification.

Disclaimers

Life support — These products are not designed for use in life support appliances, devices, or systems where malfunction of these products can reasonably be

expected to result in personal injury. Philips Semiconductors customers using or selling these products for use in such applications do so at their own risk and agree

to fully indemnify Philips Semiconductors for any damages resulting from such application.

Right to make changes — Philips Semiconductors reserves the right to make changes in the products—including circuits, standard cells, and/or software—described

or contained herein in order to improve design and/or performance. When the product is in full production (status ‘Production’), relevant changes will be communicated

viaaCustomerProduct/ProcessChangeNotification(CPCN).PhilipsSemiconductorsassumesnoresponsibilityorliabilityfortheuseofanyoftheseproducts,conveys

nolicenseortitleunderanypatent, copyright, ormaskworkrighttotheseproducts, andmakesnorepresentationsorwarrantiesthattheseproductsarefreefrompatent,

Koninklijke Philips Electronics N.V. 2003

Contact information

For additional information please visit

http://www.semiconductors.philips.com.

Fax: +31 40 27 24825

Date of release: 11-03

9397 750 12318

For sales offices addresses send e-mail to:

sales.addresses@www.semiconductors.philips.com.

Document order number:

Philips

Semiconductors

2003 Nov 11

SA57255-20GW-G [NXP]

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