MIC28511 Datasheet, PDF(20/34 Page) Microchip Technology – 60VIN, 3A Synchronous Buck Regulator

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MIC28511 Datasheet, PDF (20/34 Pages) Microchip Technology – 60VIN, 3A Synchronous Buck Regulator

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MIC28511

IL CROSSES 0 AND VFB > 0.8.

DISCONTINUOUS MODE STARTS

VFB < 0.8. WAKEUP FROM

DISCONTINUOUS MODE.

VFB

VREF

VHSD

VLSD

ESTIMATED ON-TIME

FIGURE 4-4:

MIC28511-1 Control Loop

Timing (Discontinuous Mode).

During discontinuous mode, the bias current of most

circuits are reduced. As a result, the total power supply

current during discontinuous mode is only about

450 Î¼A, allowing the MIC28511-1 to achieve high

efficiency in light load applications.

4.3 VDD Regulator

The MIC28511 provides a 5V regulated VDD to bias

internal circuitry for VIN ranging from 5.5V to 60V.

When VIN is less than 5.5V, VDD should be tied to VIN

pins to bypass the internal linear regulator.

4.4 Soft-Start

Soft-start reduces the power supply inrush current at

startup by controlling the output voltage rise time while

the output capacitor charges.

The MIC28511 implements an internal digital soft-start

by ramping up the 0.8V reference voltage (VREF) from

0 to 100% in about 5 ms with 9.7 mV steps. This

controls the output voltage rate of rise at turn on,

minimizing inrush current and eliminating output

voltage overshoot. Once the soft-start cycle ends, the

related circuitry is disabled to reduce current

consumption.

4.5 Current Limit

The MIC28511 uses the RDS(ON) of the internal

low-side power MOSFET to sense overcurrent

conditions. In each switching cycle, the inductor current

is sensed by monitoring the low-side MOSFET during

its ON period. The sensed voltage, V(ILIM), is compared

with the power ground (PGND) after a blanking time of

150 ns.

The voltage drop of the resistor RILIM is compared with

the low-side MOSFET voltage drop to set the

overcurrent trip level. The small capacitor connected

from the ILIM pin to PGND can be added to filter the

switching node ringing, allowing a better short limit

measurement. The time constant created by RILIM and

the filter capacitor should be much less than the

minimum off time.

The overcurrent limit can be programmed by using

Equation 4-3:

EQUATION 4-3:

RILIM

ï¨---I--C----L---I-M------â----0---.--5----ï´-----ï----I--L---ï¨--P---P---ï©--ï©----ï´-----R----D---S---ï¨--O----N---ï©---+-----V----C---L-

ICL

Where:

ICLIM

âIL(PP)

RDS(ON)

VCL

ICL

Desired Current Limit

Inductor Current Peak-to-Peak

Use Equation 4-4 to calculate the

inductor ripple current

On-Resistance of Low-Side Power

MOSFET (40 mâ¦ typical)

Current-limit threshold.

14 mV (typical absolute value).

See the Electrical Characteristics table.

Current-limit source current.

70 ÂµA (typical). See the Electrical Char-

acteristics table.

The peak-to-peak inductor current ripple is calculated

with Equation 4-4.

EQUATION 4-4:

ïI L ï¨ P P ï©

The MOSFET RDS(ON) varies 30% to 40% with

temperature; therefore, it is recommended to use the

RDS(ON) at maximum junction temperature with a 20%

margin to calculate RILIM in Equation 4-3.

In case of hard short, the current-limit threshold is

folded down to allow an indefinite hard short on the

output without any destructive effect. It is mandatory to

make sure that the inductor current used to charge the

output capacitor during soft-start is under the folded

DS20005520A-page 20

ï£ 2016 Microchip Technology Inc.

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