APW7176QBI-TRG 查看數據表（PDF） - Anpec Electronics

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APW7176QBI-TRG

Dual 1.5MHz, 1A Synchronous Step-Down Converter

Anpec Electronics 

APW7176

Application Information (Cont.)

Output Capacitor Selection

The output voltage ripple is a significant parameter to

estimate the performance of a convertor. There are two

discrete components that affect the output voltage ripple

to be bigger or smaller. It is recommended to use the

criterion mentioned in the "Inductor Selection" to choose

a suitable inductor. Then, based on this known inductor

current ripple, the value and equivalent-series-resistance

(ESR) of output capacitor will affect the output voltage ripple

to be smaller or larger. The output voltage ripple consists

of two portions, one is the product of ESR and inductor

current ripple, the other portion is the function of the in-

ductor current ripple and the output capacitance. Figure-3

illustrates the waveform of the ripple voltage which is

generated when the inductor ripple current charges or

discharges the pure capacitor without the ESR.

0A

∆IL

I(COUT)

0.5TS

∆VOUT1

VOUT

Figure-3

Evaluate the ∆VOUT1 by the ideal of energy equalization.

According to the definition of Q,

Q

=

1

2





1

2

∆IL

⋅

1

2

TS





=

COUT

⋅ ∆VOUT1

....(6)

where TS is the inverse of switching frequency and the ∆IL

is the inductor current ripple. Move the C to the left side

OUT

to estimate the value of ∆VOUT1 as equation (7).

∆VOUT1

=

∆IL ⋅ TS

8 ⋅ COUT

................................(7)

As mentioned above, one part of output voltage ripple is

the product of the inductor current ripple and ESR of out-

put capacitor. The equation (8) explains the output volt-

age ripple estimation.

∆VOUT

=

∆IL

⋅ ESR +

TS

8 ⋅ COUT

.................(8)

Thermal Consideration

APW7176 is a high efficiency switching converter, it means

less power loss transferred into heat. Due to the on re-

sistance difference between internal power PMOSFET

and NMOSFET, the power dissipation at high duty cycle is

greater than the low duty cycle. The worst case in the

dropout operation is the conduction loss dissipate mainly

on the internal power PMOSFET. The power dissipation

is nearly defined as:

[ ] ( ) ( ) PD = IOUT 2 RDS−P ⋅D + RDS−N ⋅ 1− D .......(9)

The APW7176 provides internal over-temperature

protection. When the junction temperature reaches 150

degrees centigrade, the APW7176 will turn off both inter-

nal power PMOSFET and NMOSFET. The estimation of

the junction temperature, T , is defined as:

J

TJ = PD ⋅ θJA............................................(10)

where the θJA is the thermal resistance of the package

utilized by the APW7176.

Output Voltage Setting

Then APW7176 has the adjustable version for output volt-

age setting by the users. A suggestion of maximum value

of R2 is 300kΩ to keep the minimum current that provides

enough noise rejection ability through the resistor divider.

The output voltage is programmed by the equation as

below:

VOUT

=

0.6 ⋅ 1+

R1

R2

...............................(11)

VOUT

APW7176

R1

FB

R2

Copyright © ANPEC Electronics Corp.

10

Rev. A.1 - Mar., 2011

www.anpec.com.tw

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