LTC1430CS#TR (Linear) PDF资料下载 Datasheet(8/16 页)

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参数资料

型号：	LTC1430CS#TR
厂商：	Linear Technology
文件页数：	8/16页
文件大小：	0K
描述：	IC SW REG CNTRLR STEP-DWN 16SOIC
标准包装：	2,500
应用：	控制器，Intel Pentium?
输入电压：	4 V ~ 8 V
输出数：	1
输出电压：	3.3V，可调
工作温度：	0°C ~ 70°C
安装类型：	表面贴装
封装/外壳：	16-SOIC（0.154"，3.90mm 宽）
供应商设备封装：	16-SOIC
包装：	带卷 (TR)

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LTC1430

APPLICATIO S I FOR ATIO

Once the threshold voltage has been selected, R ON should

be chosen based on input and output voltage, allowable

power dissipation and maximum required output current.

In a typical LTC1430 buck converter circuit operating in

continuous mode, the average inductor current is equal to

the output load current. This current is always flowing

through either M1 or M2 with the power dissipation split

up according to the duty cycle:

Note that the required R ON for M2 is roughly twice that of

M1 in this example. This application might specify a single

0.03 ? device for M2 and parallel two more of the same

devices to form M1. Note also that while the required R ON

values suggest large MOSFETs, the dissipation numbers

are only 1.1W per device or less—large TO-220 packages

and heat sinks are not necessarily required in high effi-

ciency applications. Siliconix Si4410DY (in SO-8) and

DC ( M 1 ) =

V OUT

V IN

Motorola MTD20N03HL (in DPAK) are two small, surface

mount devices with R ON values of 0.03 ? or below with 5V

of gate drive; both work well in LTC1430 circuits with up

DC ( M 2 ) = 1 ? OUT

( V IN ? V OUT )

V

V IN

=

V IN

The R ON required for a given conduction loss can now be

calculated by rearranging the relation P = I 2 R:

to 10A output current. A higher P MAX value will generally

decrease MOSFET cost and circuit efficiency and increase

MOSFET heat sink requirements.

Inductor

The inductor is often the largest component in an LTC1430

design and should be chosen carefully. Inductor value and

type should be chosen based on output slew rate require-

R ON ( M 1 ) =

=

P MAX ( M 1 )

)

DC ( M 1 ) ? I MAX 2

V IN ? P MAX ( M 1

V OUT ? I MAX 2

ments and expected peak current. Inductor value is prima-

rily controlled by the required current slew rate. The

maximum rate of rise of the current in the inductor is set

by its value, the input-to-output voltage differential and the

maximum duty cycle of the LTC1430. In a typical 5V to

3.3V application, the maximum rise time will be:

R ON ( M 2 ) =

V IN ? P MAX ( M 2 )

( V IN ? V OUT ) ? I MAX 2

( V IN ? V OUT ) AMPS 1 . 53 A I

μ s L

P MAX ( M 2 )

DC ( M 2 ) ? I MAX 2

=

P MAX should be calculated based primarily on required

efficiency. A typical high efficiency circuit designed for 5V

in, 3.3V at 10A out might require no more than 3%

efficiency loss at full load for each MOSFET. Assuming

roughly 90% efficiency at this current level, this gives a

P MAX value of (3.3V ? 10A/0.9) ? 0.03 = 1.1W per FET and

a required R ON of:

90 % ? =

L SECOND

where L is the inductor value in μ H. A 2 μ H inductor would

have a 0.76A/ μ s rise time in this application, resulting in a

6.5 μ s delay in responding to a 5A load current step. During

this 6.5 μ s, the difference between the inductor current and

the output current must be made up by the output capaci-

tor, causing a temporary droop at the output. To minimize

this effect, the inductor value should usually be in the 1 μ H

to 5 μ H range for most typical 5V to 3.xV LTC1430 circuits.

Different combinations of input and output voltages and

expected loads may require different values.

= 0 . 017 ?

= 0 . 032 ?

R ON ( M 1 ) =

R ON ( M 2 ) =

8

5 V ? 1 . 1 W

3 . 3 V ? 10 A 2

5 V ? 1 . 1 W

( 5 V ? 3 . 3 V ) ? 10 A 2

Once the required value is known, the inductor core type

can be chosen based on peak current and efficiency

requirements. Peak current in the inductor will be equal to

the maximum output load current added to half the peak-

to- peak inductor ripple current. Ripple current is set by the

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