lt3431efe-trpbf Linear Technology Corporation, lt3431efe-trpbf Datasheet - Page 20

lt3431efe-trpbf

Manufacturer Part Number

lt3431efe-trpbf

Description

High Voltage, 3a, 500khz Step-down Switching Regulator

Manufacturer

Linear Technology Corporation

Datasheet

1.LT3431EFE-TRPBF.pdf (28 pages)

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LT3431

APPLICATIO S I FOR ATIO

Note: Some of the internal power dissipation in the IC, due

to BOOST pin voltage, can be transferred outside of the IC

to reduce junction temperature, by increasing the voltage

drop in the path of the boost diode D2. (see Figure 9). This

reduction of junction temperature inside the IC will allow

higher ambient temperature operation for a given set of

conditions. BOOST pin circuitry dissipates power given

by:

Typically V

equals V

considered almost equal, where:

Hence the equation used for boost circuitry power dissipa-

tion given in the previous Thermal Calculations section is

stated as:

Here it can be seen that Boost power dissipation increases

as the square of Vout. It is possible, however, to reduce

the voltage drop in the path of D2. Care should be taken

that V

voltage required for full saturation of the internal power

switch. For output voltages of 5V, V

During switch turn on, V

C2 is dicharged by the boost pin. In a previous BOOST Pin

section, the value of C2 was designed for a 0.7V droop in

would still allow the minimum 3.3V for the boost function

using the C2 capacitor calculated. If a target output voltage

of 12V is required, however, an excess of 8V is placed

across the boost capacitor which is not required for the

boost function, but still dissipates additional power. What

is required is a voltage drop in the path of D2 to achieve

minimal power dissipation while still maintaining mini-

mum boost voltage across C2. A zener, D4, placed in

series with D2 (see Figure 9), drops voltage to C2.

below Vout to save power dissipation by increasing

DISS BOOST

= V

DROOP

(

OUT

does not fall below the minimum 3.3V Boost

OUT

. This is because diodes D1 and D2 can be

(the boost voltage across the capacitor C2)

– V

. Hence, an output voltage as low as 4V

)

FD2

OUT

– (–V

• (

FD1

will fall as the boost capacitor

) = V

OUT

) •

is approximately 5V.

OUT

Example : The BOOST pin power dissipation for a 20V input

to 12V output conversion at 2A is given by :

If a 7V zener D4 is placed in series with D2, then power

dissipation becomes :

For an FE package with thermal resistance of 45 C/W,

ambient temperature savings would be, T

ings = 0.233W • 45 C/W = 11 C. The 7V zener should be

sized for excess of 0.233W operaton. The tolerances of the

zener should be considered to ensure minimum V

ceeds 3.3V + V

Input Voltage vs Operating Frequency Considerations

The absolute maximum input supply voltage for the LT3431

is specified at 60V. This is based on internal semiconduc-

tor junction breakdown effects. The practical maximum

input supply voltage for the LT3431 may be less than 60V

due to internal power dissipation or switch minimum on

time considerations.

For the extreme case of an output short-circuit fault to

ground, see the section Short-Circuit Considerations.

BOOST

Figure 9. BOOST Pin, Diode Selection

12 2 36 12

12 2 36 5

SHDN

SYNC

GND

DROOP

• ( /

LT3431

BOOST

BIAS

) •

0 167

0 4

D2 D4

(AMBIENT)

sn3431 3431fs

3431 F09

sav-

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lt3431efe-trpbf Linear Technology Corporation, lt3431efe-trpbf Datasheet - Page 20

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