ADP1864-BL-EVALZ Analog Devices Inc, ADP1864-BL-EVALZ Datasheet - Page 10

ADP1864-BL-EVALZ

Manufacturer Part Number

ADP1864-BL-EVALZ

Description

Blank Boards

Manufacturer

Analog Devices Inc

Datasheets

1.ADP1864AUJZ-R7.pdf (16 pages)

2.ADP1864-BL-EVALZ.pdf (16 pages)

Specifications of ADP1864-BL-EVALZ

Main Purpose

DC/DC, Step Down

Regulator Topology

Buck

Board Type

Partially Populated - Main IC Only

Utilized Ic / Part

ADP1864

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Current - Output

Voltage - Output

Voltage - Input

Power - Output

Frequency - Switching

Outputs And Type

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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ADP1864

APPLICATIONS INFORMATION

DUTY CYCLE

To determine the worst-case inductor ripple current, output

voltage ripple, and slope compensation factor, establish the

system maximum and minimum duty cycle. The duty cycle is

calculated by the equation

where V

A typical Schottky diode has a forward voltage drop of 0.5 V.

RIPPLE CURRENT

Choose the peak-to-peak inductor ripple current between 20%

and 40% of the maximum load current at the system’s highest

input voltage. A good starting point for a design is to pick the

peak-to-peak ripple current at 30% of the load current.

SENSE RESISTOR

Choose the sense resistor value to provide the desired current

limit. The internal current comparator measures the peak

current (sum of load current and positive inductor ripple

current) and compares it against the current limit threshold.

The current sense resistor value is calculated by the equation

where PCSV is the peak current sense voltage, typically 0.125 V.

To ensure the design provides the required output load current

over all system conditions, consider the variation in PCSV over

temperature (see the Specifications section) as well as increases

in ripple current due to inductor tolerance.

If the system is being operated with >40% duty cycle, incor-

porate the slope compensation factor into the calculation.

where SF is the slope factor correction ratio, taken from

Figure 13, at the system maximum duty cycle (minimum

input voltage).

ΔI

Duty

SENSE

(PEAK)

is the diode forward drop.

Cycle

(

MIN

= 0.3 × I

)

(

LOAD

LOAD(MAX)

)

(

MAX

OUT

PCSV

)

PCSV

(

PEAK

)

Rev. B | Page 10 of 16

(1)

(2)

(3)

(4)

INDUCTOR VALUE

The inductor value choice is important because it dictates the

inductor ripple and, therefore, the voltage ripple at the output.

When operating the part at >40% duty cycle, keep the inductor

value low enough for the slope compensation to remain

effective.

The inductor ripple current is inversely related to the

inductor value.

where f is the oscillator frequency.

Smaller inductor values are usually less expensive, but increase

the ripple current and the output voltage ripple. Too large an

inductor value results in added expenses and can impede effective

load transient responses at >40% duty cycle because it reduces

the effect of slope compensation.

Start with the highest input voltage, and assuming the ripple

current is 30% of the maximum load current,

From this starting point, modify the inductance to obtain

the right balance of size, cost, and output voltage ripple, while

maintaining the inductor ripple current between 20% and 40%

of the maximum load current.

1.05

0.95

0.85

0.75

0.65

0.55

0.45

0.35

(

PEAK

3 .

)

(

0.1

Figure 13. Slope Factor (SF) vs. Duty Cycle

LOAD

(

−

0.2

(

MAX

−

OUT

0.3

)

OUT

)

0.4

DUTY CYCLE

⎛

⎜

⎝

⎛

⎜

⎝

0.5

OUT

0.6

0.7

⎞

⎟

⎠

⎞

⎟

⎠

0.8

0.9

(5)

(6)

ADP1864-BL-EVALZ Analog Devices Inc, ADP1864-BL-EVALZ Datasheet - Page 10

ADP1864-BL-EVALZ

Specifications of ADP1864-BL-EVALZ

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