EVALPM6680 STMicroelectronics, EVALPM6680 Datasheet - Page 32

EVALPM6680

Manufacturer Part Number

EVALPM6680

Description

BOARD EVALUATION FOR PM6680

Manufacturer

STMicroelectronics

Datasheet

1.PM6680TR.pdf (49 pages)

Specifications of EVALPM6680

Mfg Application Notes

PM6680 Eval Kit, AN2566 App Note

Main Purpose

DC/DC, Step Down with LDO

Outputs And Type

3, Non-Isolated

Power - Output

13.25W

Voltage - Output

1.05V, 1.5V, 5V

Current - Output

5A, 5A, 100mA

Voltage - Input

6 ~ 28V

Regulator Topology

Buck

Frequency - Switching

200kHz, 300kHz

Board Type

Fully Populated

Utilized Ic / Part

PM6680

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Other names

497-6241

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

BOSTOCK HK LIMITED

Part Number:

EVALPM6680

Manufacturer:

Company:

BOSTOCK HK LIMITED

Part Number:

EVALPM6680A

Manufacturer:

Current page: 32 of 49
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Device description

7.13

7.13.1

7.13.2

32/49

Design guidelines

The design of a switching section starts from two parameters:

●

Switching frequency

It's possible to set 3 different working frequency ranges for the two sections with F

(

Switching frequency mainly influences two parameters:

●

Inductor selection

Once that switching frequency is defined, inductor selection depends on the desired

inductor ripple current and load transient performance.

Low inductance means great ripple current and could generate great output noise. On the

other hand, low inductor values involve fast load transient response.

A good compromise between the transient response time, the efficiency, the cost and the

size is to choose the inductor value in order to maintain the inductor ripple current ∆I

between 20 % and 50 % of the maximum output current I

occurs at the maximum input voltage. With this considerations, the inductor value can be

calculated with the following relationship:

Equation 12

where f

∆I

In order to prevent overtemperature working conditions, inductor must be able to provide an

RMS current greater than the maximum RMS inductor current I

Equation 13

Where ∆I

Table 7 on page 30

is the selected inductor ripple current.

Input voltage range: in notebook applications it varies from the minimum battery

voltage, V

Maximum load current: it is the maximum required output current, I

Inductor size: for a given saturation current and RMS current, greater frequency allows

to use lower inductor values, which means smaller size.

Efficiency: switching losses are proportional to frequency. High frequency generally

involves low efficiency.

(max) is the maximum ripple current:

is the switching frequency, V

INmin

to the AC adapter voltage, V

LRMS

I (

LOAD

is the input voltage, V

(max))

−

∆

OUT

INmax.

(

OUT

∆

(max))

LOAD

(max). The maximum ∆I

OUT

LRMS

is the output voltage and

LOAD(max)

SEL

PM6680

EVALPM6680 STMicroelectronics, EVALPM6680 Datasheet - Page 32

EVALPM6680

Specifications of EVALPM6680

Available stocks

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