ADP3050-EVAL Analog Devices Inc, ADP3050-EVAL Datasheet - Page 11

ADP3050-EVAL

Manufacturer Part Number

ADP3050-EVAL

Description

BOARD EVAL FOR ADP3050

Manufacturer

Analog Devices Inc

Datasheet

1.ADP3050ARZ-R7.pdf (24 pages)

Specifications of ADP3050-EVAL

Main Purpose

DC/DC, Step Down

Voltage - Input

3.6 ~ 30V

Regulator Topology

Buck

Board Type

Fully Populated

Utilized Ic / Part

ADP3050

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Current - Output

Voltage - Output

Power - Output

Frequency - Switching

Outputs And Type

Lead Free Status / RoHS Status

Not Compliant, Contains lead / RoHS non-compliant

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APPLICATIONS INFORMATION

The complete process for designing a step-down switching

regulator using the ADP3050 is provided in the following

sections. Each section includes a list of recommended devices.

These lists do not include every available device or manufacturer.

They contain only surface-mount devices. Equivalent through-

hole devices can be substituted if needed. In choosing components,

keep in mind what is most important to the design, for example,

efficiency, cost, and size. These ultimately determine which compo-

nents are used. It is also important to ensure that the design

specifications are clearly defined and reflect the worst-case

conditions. Key specifications include the minimum and

maximum input voltage, the output voltage and ripple, and the

minimum and maximum load current.

INDUCTOR SELECTION

The inductor value determines the mode of operation for the

regulator: continuous mode, where the inductor current flows

continuously; or discontinuous mode, where the inductor current

reduces to zero during every switch cycle. Continuous mode is

the best choice for many applications. It provides higher output

power, lower peak currents in the switch, inductor, and diode,

and a lower inductor ripple current, which means lower output

ripple voltage. Discontinuous mode allows the use of smaller

magnetics, but at a price: lower available load current and

higher peak and ripple currents. Designs with a high input

voltage or a low load current often operate in discontinuous

mode to minimize inductor value and size. The ADP3050 is

designed to work well in both modes of operation.

Continuous Mode

The inductor current in a continuous mode system is a triangular

waveform (equal to the ripple current) centered around a dc

value (equal to the load current). The amount of ripple current

is determined by the inductor value, and is usually between 20%

and 40% of the maximum load current. To reduce the inductor

size, ripple currents between 40% and 80% are often used in

continuous mode designs with a high input voltage or a low

output current. The inductor value is calculated using the

following equation:

Where V

regulated output voltage, and f

(200 kHz). The initial choice for the amount of ripple current

may seem arbitrary, but it serves as a good starting point for

finding a standard off-the-shelf inductor value, such as

10 μH, 15 μH, 22 μH, 33 μH, and 47 μH. If a specific inductance

value is to be used, simply rearrange Equation 2 to find the

ripple current. For an 800 mA, 12 V to 5 V system, and a

IN(MAX)

(

MAX

RIPPLE

is the maximum input voltage, V

)

−

OUT

is the switching frequency

OUT

(

MAX

)

OUT

is the

Rev. B | Page 11 of 24

(2)

ripple current of 320 mA (40% of 800 mA) is chosen, the

inductance is

A 47 μH inductor is the closest standard value that gives a ripple

current of about 310 mA. The peak switch current is equal to

the load current plus one-half the ripple current (this is also the

peak current for the inductor and the catch diode).

Pick an inductor with a dc (or saturation) current rating about 20%

larger than I

the edge of saturation. For this example, 1.20 × 0.95 A = 1.14 A, use

an inductor with a dc current rating of at least 1.2 A. The maxi-

mum switch current is internally limited to 1.5 A, and this limit,

along with the ripple current, determines the maximum load

current the system can provide.

If the load current decreases to below one-half the ripple

current, the regulator operates in discontinuous mode.

Discontinuous Mode

For load currents less than approximately 0.5 A, discontinuous

mode operation can be used. This allows the use of a smaller

inductor, but the ripple current is much higher (which means a

higher output ripple voltage). If a larger output capacitor must

be used to reduce the output ripple voltage, the overall system

may take up more board area than if a larger inductor is used.

The operation and equations for the two modes are quite different,

but the boundary between these two modes occurs when the ripple

current is equal to twice the load current (when I

From this, Equation 2 is used to find the minimum inductor

value needed to keep the system in continuous mode operation

(solve for the inductor value with I

Using an inductor below this value causes the system to operate

in discontinuous mode. For a 400 mA, 24 V to 5 V system

If the chosen inductor value is too small, the internal current

limit trips each cycle and the regulator has trouble providing the

necessary load current.

DIS

(

0.32

≤

−

)

SW(PK)

−

(

OUT

MAX

4 .

200

to ensure that the inductor is not running near

(

)

MAX

OUT

−

200

)

OUT

RIPPLE

45.5

RIPPLE

≤

μH

8 .

= 2 × I

OUT

(

7 .

MAX

μH

. 0

)

155

OUT

RIPPLE

ADP3050

. 0

= 2 × I

OUT

(3)

(4)

ADP3050-EVAL Analog Devices Inc, ADP3050-EVAL Datasheet - Page 11

ADP3050-EVAL

Specifications of ADP3050-EVAL

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