MIC2207_10 Datasheet, PDF(10/18 Page) Micrel Semiconductor – 3mm x 3mm 2MHz 3A PWM Buck Regulator

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MIC2207_10 Datasheet, PDF (10/18 Pages) Micrel Semiconductor – 3mm x 3mm 2MHz 3A PWM Buck Regulator

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Micrel, Inc.

â (VOUT + VD )

The total off time can be calculated as;

TOFF

1â D

2MHz

Figure 4. Off-Time

Discontinuous Operation

Discontinuous operation is when the inductor current

discharges to zero during the off cycle. Figure 5.

demonstrates the switch voltage and inductor currents

during discontinuous operation.

Figure 5. Discontinuous Operation

When the inductor current (IL) has completely

discharged, the voltage on the switch node rings at the

frequency determined by the parasitic capacitance and

the inductor value. In figure 5, it is drawn as a DC

voltage, but to see actual operation (with ringing) refer to

the functional characteristics.

Discontinuous mode of operation has the advantage

over full PWM in that at light loads, the MIC2207 will skip

April 2010

MIC2207

pulses as necessary, reducing gate drive losses,

drastically improving light load efficiency.

Efficiency Considerations

Calculating the efficiency is as simple as measuring

power out and dividing it by the power in;

Efficiency = POUT Ã 100

Where input power (PIN) is;

PIN = VIN Ã IIN

and output power (POUT) is calculated as;

POUT = VOUT Ã IOUT

The Efficiency of the MIC2207 is determined by several

factors.

â¢ Rdson (Internal P-channel Resistance)

â¢ Diode conduction losses

â¢ Inductor Conduction losses

â¢ Switching losses

Rdson losses are caused by the current flowing through

the high side P-channel MOSFET. The amount of power

loss can be approximated by;

PSW = RDSON Ã IOUT 2 Ã D

Where D is the duty cycle.

Since the MIC2207 uses an internal P-channel

MOSFET, Rdson losses are inversely proportional to

supply voltage. Higher supply voltage yields a higher

gate to source voltage, reducing the Rdson, reducing the

MOSFET conduction losses. A graph showing typical

Rdson vs input supply voltage can be found in the typical

characteristics section of this datasheet.

Diode conduction losses occur due to the forward

voltage drop (VF) and the output current. Diode power

losses can be approximated as follows;

PD = VF Ã IOUT Ã (1 â D)

For this reason, the schottky diode is the rectifier of

choice. Using the lowest forward voltage drop will help

reduce diode conduction losses, and improve efficiency.

Duty cycle, or the ratio of output voltage to input voltage,

determines whether the dominant factor in conduction

losses will be the internal MOSFET or the schottky

diode. Higher duty cycles place the power losses on the

high side switch, and lower duty cycles place the power

losses on the schottky diode.

Inductor conduction losses (PL) can be calculated by

multiplying the DC resistance (DCR) times the square of

the output current;

PL = DCR Ã IOUT 2

M9999-041910

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