LTC1504AIS8#TRPBF Datasheet LTC1504ACS8-3.3#PBF, LTC1504AIS8#PBF, LTC1504AIS8-3.3#PBF | P7-P9

LTC1504A

Ideally, the LTC1504A requires a low impedance bypass

right at the chip and a larger reservoir capacitor that can be

located somewhat farther away. This requirement usually

can be met with a ceramic capacitor right next to the

LTC1504A and an electrolytic capacitor (usually 10µF to

100µF, depending on expected load current) located some-

where nearby. In certain cases, the bulk capacitance

requirement can be met by the output bypass of the input

supply. Applications running at very high load currents or

at input supply voltages greater than 6V may require the

local ceramic capacitor to be 1µF or greater. In some

cases, both the low impedance and bulk capacitance

requirements can be met by a single capacitor, mounted

very close to the LTC1504A. Low ESR organic semicon-

ductor (OS-CON) electrolytic capacitors or surge tested

surface mount tantalum capacitors can have low enough

impedance to keep the LTC1504A happy in some circuits.

Often the RMS current capacity of the input bypass capaci-

tors is more important to capacitor selection than value.

Buck converters like the LTC1504A are hard on input

capacitors, since the current flow alternates between the

full load current and near zero during every clock cycle. In

the worst case (50% duty cycle or V

OUT

= 0.5V

) the RMS

current flow in the input capacitor is half of the total load

current plus half the ripple current in the inductor—

perhaps 300mA in a typical 500mA load current applica-

tion. This current flows through the ESR of the input

bypass capacitor, heating it up and shortening its life,

sometimes dramatically. Many ordinary electrolytic ca-

pacitors that look OK at first glance are not rated to

withstand such currents—check the RMS current rating

before you specify a device! If the RMS current rating isn’t

specified, it should not be used as an input bypass capaci-

tor. Again, low ESR electrolytic and surge tested tantalums

usually do well in LTC1504A applications and have high

RMS current ratings. The local ceramic bypass capacitor

usually has negligible ESR, allowing it to withstand large

RMS currents without trouble. Table 1 shows typical

surface mount capacitors that make acceptable input

bypass capacitors in LTC1504A applications.

Inductor

The LTC1504A requires an external inductor to be con-

nected from the switching node SW to the output node

APPLICATIONS INFORMATION

WUU

Table 1. Representative Surface Mount Input Bypass Capacitors

PART VALUE ESR MAX RMS TYPE HEIGHT

AVX

TPSC226M016R0375 22µF 0.38Ω 0.54A Tantalum 2.6mm

TPSD476M016R0150 47µF 0.15Ω 0.86A Tantalum 2.9mm

TPSE107M016R0125 100µF 0.13Ω 1.15A Tantalum 4.1mm

1206YC105M 1µF Low >1A X7R Ceramic 1.5mm

1210YG106Z 10µF Low >1A Y5V Ceramic 1.7mm

Sanyo

16SN33M 33µF 0.15Ω 1.24A OS-CON 7mm

16SN68M 68µF 0.1Ω 1.65A OS-CON 7mm

16CV100GX 100µF 0.44Ω 0.23A* Electrolytic 6mm

16CV220GX 220µF 0.34Ω 0.28A* Electrolytic 7.7mm

Sprague

593D476X0016D2W 47µF 0.17Ω 0.93A Tantalum 2.8mm

593D107X0016E2W 100µ 0.15Ω 1.05A Tantalum 4mm

*Note: Use multiple devices in parallel or limit output current to prevent capacitor overload.

where the load is connected. Inductor requirements are

fairly straightforward; it must be rated to handle continu-

ous DC current equal to the maximum load current plus

half the ripple current and its value should be chosen

based on the desired ripple current and/or the output

current transient requirements. Large value inductors

lower ripple current and decrease the required output

capacitance, but limit the speed that the LTC1504A can

change the output current, limiting output transient re-

sponse. Small value inductors result in higher ripple

currents and increase the demands on the output capaci-

tor, but allow faster output current slew rates and are often

smaller and cheaper for the same DC current rating. A

typical inductor used in an LTC1504A application might

have a maximum current rating between 500mA and 1A

and an inductance between 33µH and 220µH.

Different core materials and shapes will change the size/

current and price/current relationship of an inductor.

Toroid or shielded pot cores in ferrite or permalloy mate-

rials are small and don’t radiate much energy, but gener-

ally cost more than powdered iron rod core inductors with

similar electrical characteristics. The choice of which style

inductor to use often depends more on the price vs size

requirements and any radiated field/EMI requirements

than on what the LTC1504A requires to operate. Table 2

shows some typical surface mount inductors that work

well in LTC1504A applications.

LTC1504A

APPLICATIONS INFORMATION

WUU

Table 2. Representative Surface Mount Inductors

CORE CORE

PART VALUE MAX DC TYPE MATERIAL HEIGHT

CoilCraft

DT3316-473 47µH 1A Shielded Ferrite 5.1mm

DT3316-104 100µH 0.8A Shielded Ferrite 5.1mm

DO1608-473 47µH 0.5A Open Ferrite 3.2mm

DO3316-224 220µH 0.8A Open Ferrite 5.5mm

Coiltronics

CTX50-1 50µH 0.65A Toroid KoolMµ

4.2mm

CTX100-2 100µH 0.63A Toroid KoolMµ 6mm

CTX50-1P 50µH 0.66A Toroid Type 52 4.2mm

CTX100-2P 100µH 0.55A Toroid Type 52 6mm

TP3-470 47µH 0.55A Toroid Ferrite 2.2mm

TP3-470 47µH 0.72A Toroid Ferrite 3mm

Sumida

CDRH62-470 47µH 0.54A Shielded Ferrite 3mm

CDRH73-101 100µH 0.50A Shielded Ferrite 3.4mm

CD43-470 47µH 0.54A Open Ferrite 3.2mm

CD54-101 100µH 0.52A Open Ferrite 4.5mm

Output Capacitor

The output capacitor affects the performance of the

LTC1504A in a couple of ways: it provides the first line of

defense during a transient load step and it has a large effect

on the compensation required to keep the LTC1504A

feedback loop stable. Transient load response of an

LTC1504A circuit is controlled almost entirely by the

output capacitor and the inductor. In steady load opera-

tion, the average current in the inductor will match the load

current. When the load current changes suddenly, the

inductor is suddenly carrying the wrong current and

requires a finite amount of time to correct itself—at least

several switch cycles with typical LTC1504A inductor

values. Even if the LTC1504A had psychic abilities and

could instantly assume the correct duty cycle, the rate of

change of current in the inductor is still related to its value

and cannot change instantaneously.

Until the inductor current adjusts to match the load cur-

rent, the output capacitor has to make up the difference.

Applications that require exceptional transient response

(2% or better for instantaneous full-load steps) will re-

quire relatively large value, low ESR output capacitors.

Applications with more moderate transient load require-

ments can often get away with traditional standard ESR

electrolytic capacitors at the output and can use larger

valued inductors to minimize the required output capaci-

tor value. Note that the RMS current in the output capacitor

is slightly more than half of the inductor ripple current—

much smaller than the RMS current in the input bypass

capacitor. Output capacitor lifetime is usually not a factor

in typical LTC1504A applications.

Large value ceramic capacitors used as output bypass

capacitors provide excellent ESR characteristics but can

cause loop compensation difficulties. See the Loop Com-

pensation section.

Loop Compensation

Loop compensation is strongly affected by the output

capacitor. From a loop stability point of view, the output

inductor and capacitor form a series RLC resonant circuit,

with the L set by the inductor value, the C by the value of

the output capacitor and the R dominated by the output

capacitor’s ESR. The amplitude response and phase shift

due to these components is compensated by a network of

Rs and Cs at the COMP pin to (hopefully) close the

feedback loop in a stable manner. Qualitatively, the L and

C of the output stage form a 2nd order roll-off with 180°

of phase shift; the R due to ESR forms a single zero at a

somewhat higher frequency that reduces the roll-off to

first order and reduces the phase shift to 90°.

If the output capacitor has a relatively high ESR, the zero

comes in well before the initial phase shift gets all the way

to 180° and the loop only requires a single small capacitor

from COMP to GND to remain stable (Figure 4a). If, on the

other hand, the output capacitor is a low ESR type to

maximize transient response, the ESR zero can increase in

frequency by a decade or more and the output stage phase

shift can get awfully close to 180° before it turns around

and comes back to 90°. Large value ceramic, OS-CON

electrolytic and low impedance tantalum capacitors fall

into this category. These loops require an additional zero

to be inserted at the COMP pin; a series RC in parallel with

a smaller C to ground will usually ensure stability. Figure 4b

shows a typical compensation network which will opti-

mize transient response with most output capacitors.

Adjustable output parts can add a feedforward capacitor

across the feedback resistor divider to further improve

Kool Mµ is a registered trademark of Magnetics, Inc..

LTC1504A

APPLICATIONS INFORMATION

WUU

phase margin. The typical applications in this data sheet

show compensation values that work with several combi-

nations of external components—use them as a starting

point. For complex cases or stubborn oscillations, contact

the LTC Applications Department.

External Schottky Diode

An external Schottky diode can be included across the

internal N-channel switch (Q2) to improve efficiency at

heavy loads. The diode carries the inductor current during

the nonoverlap time while the LTC1504A turns Q1 off and

Q2 on and prevents current from flowing in the intrinsic

body diode in parallel with Q2. This diode will improve

efficiency by a percentage point or two as output current

approaches 500mA and can help minimize erratic behav-

ior at very high peak current levels caused by excessive

parasitic current flow through Q2. A Motorola MBRS0530L

is usually adequate, with the cathode connected to SW and

the anode connected to GND. Note that this diode is not

required for normal operation and has a negligible effect

on efficiency at low (<250mA) output currents.

COMP

*ADJUSTABLE PARTS ONLY

1504A • F04a

LTC1504A

FB2

FB1

OUT

COMP

*ADJUSTABLE PARTS ONLY

1504A • F04b

LTC1504A

FB2

FB1

OUT

Figure 4a. Minimum Compensation Network

Figure 4b. Optimum Compensation Network

Soft Start and Current Limit

Soft start and current limit are linked in the LTC1504A. Soft

start works in a straightforward manner. An internal 12µA

current source connected to the SS pin will pull up an

external capacitor connected from SS to GND at a rate

determined by the capacitor value. COMP is clamped to a

voltage one diode drop above SS; as SS rises, COMP will

rise at the same rate. When COMP reaches roughly 2V

below V

, the duty cycle will slowly begin to increase until

the output comes into regulation. As SS continues to rise,

the feedback amplifier takes over at COMP, the clamp

releases and SS rises to V

Current limit operates by pulling down on the soft start pin

when it senses an overload condition at the output. The

current limit amplifier (I

LIM

) compares the voltage drop

across the internal P-channel switch (Q1) during its on

time to the voltage at the I

MAX

pin. I

MAX

includes an internal

12µA pull-down, allowing the voltage to be set by a single

resistor between V

and I

MAX

. When the IR drop across

Q1 exceeds the drop across the I

MAX

resistor, I

LIM

pulls

current out of the external soft start capacitor, reducing

the voltage at SS. A soft start capacitor should always be

used if current limit is enabled. SS, in turn, pulls down on

COMP, limiting the output duty cycle and controlling the

output current. When the current overload is removed, the

LIM

amplifier lets go of SS and allows it to rise again as if

it were completing a soft start cycle. The size of the

external soft start capacitor controls both how fast the

current limit responds once an overload is detected and

how fast the output recovers once the overload is re-

moved. The soft start capacitor also compensates the

feedback loop created by the I

LIM

amplifier. Because the

LIM

loop is a current feedback loop, the additional phase

shift due to the output inductor and capacitor do not come

into play and the loop can be adequately compensated

with a single capacitor. Usually a 0.1µF ceramic capacitor

from SS to GND provides adequate soft start behavior and

acceptable current limit response.

This type of current limit circuit works well with mild

current overloads and eliminates the need for an external

current sensing resistor, making it attractive for LTC1504A

applications. These same features also handicap the cur-

rent limit circuit under severe short circuits when the

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Switching Voltage Regulators 500mA L V Buck Sync Sw Reg

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