MIC2199_10 Datasheet, PDF(12/14 Page) Micrel Semiconductor – 300kHz 4mm × 4mm Synchronous Buck Converter

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MIC2199_10 Datasheet, PDF (12/14 Pages) Micrel Semiconductor – 300kHz 4mm × 4mm Synchronous Buck Converter

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Micrel, Inc.

Voltage Setting Components

The MIC2199 requires two resistors to set the output voltage

as shown in Figureâ¯6.

Error

Amp

MIC2199

VREF

0.8V

Figureâ¯6.â Voltage-Divider Configuration

The output voltage is determined by the equation:

VREF

ï£«

Ã ï£¬1+

ï£

R1ï£¶

ï£·

R2 ï£¸

Where: VREF for the MIC2199 is typically 0.8V.

A typical value of R1 can be between 3k and 10k. If R1 is

too large it may allow noise to be introduced into the volt-

age feedback loop. If R1 is too small in value it will decrease

the efficiency of the power supply, especially at low output

loads.

Once R1 is selected, R2 can be calculated using:

R2 = VREF Ã R1

VO â VREF

Voltage Divider Power Dissipation

The reference voltage and R2 set the current through the

voltage divider.

IDIVIDER

VREF

The power dissipated by the divider resistors is:

PDIVIDER = (R1+ R2) Ã IDIVIDER2

Efficiency Calculation and Considerations

Efficiency is the ratio of output power to input power. The

difference is dissipated as heat in the buck converter. Under

light output load, the significant contributors are:

â¢ Supply current to the MIC2199

â¢ MOSFET gate-charge power (included in the IC

supply current)

â¢ Core losses in the output inductor

MIC2199

To maximize efficiency at light loads:

â¢ Use a low gate-charge MOSFET or use the small-

est MOSFET, which is still adequate for maximum

output current.

â¢ Use a ferrite material for the inductor core, which

has less core loss than an MPP or iron power

core.

Under heavy output loads the significant contributors to power

loss are (in approximate order of magnitude):

â¢ Resistive on-time losses in the MOSFETs

â¢ Switching transition losses in the MOSFETs

â¢ Inductor resistive losses

â¢ Current-sense resistor losses

â¢ Input capacitor resistive losses (due to the capaci-

tors ESR)

To minimize power loss under heavy loads:

â¢ Use logic-level, low on-resistance MOSFETs.

Multiplying the gate charge by the on-resistance

gives a figure of merit, providing a good balance

between low and high load efficiency.

â¢ Slow transition times and oscillations on the voltage

and current waveforms dissipate more power during

turn-on and turnoff of the MOSFETs. A clean layout

will minimize parasitic inductance and capacitance

in the gate drive and high current paths. This will

allow the fastest transition times and waveforms

without oscillations. Low gate-charge MOSFETs

will transition faster than those with higher gate-

charge requirements.

â¢ For the same size inductor, a lower value will

have fewer turns and therefore, lower winding re-

sistance. However, using too small of a value will

require more output capacitors to filter the output

ripple, which will force a smaller bandwidth, slower

transient response and possible instability under

certain conditions.

â¢ Lowering the current-sense resistor value will

decrease the power dissipated in the resistor.

However, it will also increase the overcurrent

limit and will require larger MOSFETs and inductor

components.

â¢ Use low-ESR input capacitors to minimize the

power dissipated in the capacitors ESR.

January 2010

M9999-011310

▷