LT3431_15 Datasheet, PDF(23/28 Page) Linear Technology – High Voltage, 3A, 500kHz Step-Down Switching Regulator

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LT3431_15 Datasheet, PDF (23/28 Pages) Linear Technology – High Voltage, 3A, 500kHz Step-Down Switching Regulator

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LT3431

APPLICATIO S I FOR ATIO

BUCK CONVERTER WITH ADJUSTABLE SOFT-START

Large capacitive loads or high input voltages can cause

high input currents at start-up. Figure 13 shows a circuit

that limits the dv/dt of the output at start-up, controlling

the capacitor charge rate. The buck converter is a typical

configuration with the addition of R3, R4, CSS and Q1.

As the output starts to rise, Q1 turns on, regulating switch

current via the VC pin to maintain a constant dv/dt at the

output. Output rise time is controlled by the current

through CSS defined by R4 and Q1âs VBE. Once the output

is in regulation, Q1 turns off and the circuit operates

normally. R3 is transient protection for the base of Q1.

(R4)(CSS)(VOUT )

Rise Time =

VBE

Using the values shown in Figure 10,

( )( )( ) 47 â¢103 15â¢10â9 5

Rise Time =

= 5ms

0.7

The ramp is linear and rise times in the order of 100ms are

possible. Since the circuit is voltage controlled, the ramp

rate is unaffected by load characteristics and maximum

output current is unchanged. Variants of this circuit can be

used for sequencing multiple regulator outputs.

INPUT

12V

MMSD914TI

4.7ÂµF

25V

CER

BOOST BIAS

VIN

LT3431

0.22ÂµF

15ÂµH

C1 +

30BQ060 100ÂµF

OR B250A 10V

15.4k

SHDN

SYNC GND

3.3k

0.022ÂµF

220pF Q1

CSS

15nF

4.99k

3431 F13

47k

L1: CDRH104R-220M

OUTPUT

Figure 13. Buck Converter with Adjustable Soft-Start

Dual Polarity Output Converter

The circuit in Figure 14a generates both positive and

negative 5V outputs with all components under 3mm

height. The topology for the 5V output is a standard buck

converter. The â5V output uses a second inductor L2,

diode D3, and output capacitor C6. The capacitor C4

couples energy to L2 and ensures equal voltages across

L2 and L1 during steady state. Instead of using a trans-

former for L1 and L2, uncoupled inductors were used

because they require less height than a single transformer,

can be placed separately in the circuit layout for optimized

space savings and reduce overall cost. This is true even

when the uncoupled inductors are sized (twice the value of

inductance of the transformer) in order to keep ripple

current comparable to the transformer solution. If a single

transformer becomes available to provide a better height

/cost solution, refer to the Dual Output SEPIC circuit

description in Design Note 100 for correct transformer

connection.

During switch on-time, in steady state, the voltage across

both L1 and L2 is positive and equal ; with energy (and

current) ramping up in each inductor. The current in L2 is

provided by the coupling capacitor C4. During switch off-

time, current ramps downward in each inductor. The

current in L2 and C4 flows via the catch diode D3, charging

the negative output capacitor C6. If the negative output is

not loaded enough it can go severely unregulated (become

more negative). Figure 14b shows the maximum allow-

able â5V output load current (vs load current on the 5V

output) that will maintain the â5V output within 3%

tolerance. Figure 14c shows the â5V output voltage regu-

lation versus its own load current when plotted for three

separate load currents on the 5V output. The efficiency of

the dual polarity output converter circuit shown in Figure

14a is given in Figure 14d.

sn3431 3431fs

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