IRDC3710-DF【PDF 13/20 页】BOARD EVAL SYNC BUCK CONTROLLER

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Sheet目录17360

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IR3710MTRPBF

switching power loss because the output current flow

through the lower MOSFET’s body diode during the

dead time stores some minority charges. When the

upper MOSFETs turn on, it has to carry this extra

current to remove the minority charges. The reverse

recovery power loss can be found in equation 8.

P Qrr = Q rr ? V IN ? F S (8)

By combining the P SW and P Qrr , the total switching

power loss of the upper MOSFETs is much greater

than its conduction loss. International Rectifier

MOSFET datasheets has separated the gate charge

Inductor selection involves meeting the steady state

output ripple requirement, minimizing the switching

loss of upper MOSFETs, transient response and

minimizing the output capacitance. The output

voltage includes a DC voltage and a small AC ripple

component due to the low pass filter which has

incomplete attenuation of the switching harmonics.

Neglecting the inductance in series with output

capacitor, the magnitude of the AC voltage ripple is

determined by the total inductor ripple current flow

through the total equivalent series resistance (ESR)

of the output capacitor bank.

of Q GS1 and Q GS2 so that the designer can calculate

the switching power loss. Therefore, selection of the

upper MOSFETs should consider those factors.

Δ I =

V OUT

? ( 1 ? D ) ? Ts =

V OUT ? ( V IN ? V OUT )

V IN ? L ? F s

(12)

Otherwise, the converter losses degrade the system

efficiency and may exceed the thermal constraints.

The main power loss of lower MOSFETs is the

conduction loss because its on-time is in the range of

90% of the switching period. The switching power

loss of lower MOSFETs can be negligible because

their body diode voltage drops are in the range of 1V.

Equation 9 shows the conduction power loss

calculation. T S is inversely proportional to fs, and T OFF

is the on-time of the lower MOSFETs. R DS(on)

increases approximately 30% with temperature.

One can use equation 12 to find the inductance. The

main advantage of small inductance is increased

inductor current slew rate during a load transient,

which leads to small output capacitance requirement

as discussed in the Output Capacitor Selection

section. The draw back of using smaller inductances

is increased switching power loss in upper

MOSFETs, which reduces the system efficiency and

increases the thermal dissipation as discussed in the

Power Loss section.

P COND = I RMS_COND 2 ? R DSON ?

T OFF

(9)

Input Capacitor Selection

The main function of the input capacitor bank is to

? ?

1 ? Δ I ?

Where : I RMS_COND = I OUT ? 1 - D ? 1 +

3 ? I OUT ?

provide the input ripple current and fast slew rate

current during the load current step up. The input

capacitor bank must have adequate to handle the

The driver power loss is a small factor when heavily

loaded but it can be significant contributor of

degradation to the converter efficiency in light load.

Equation 10 shows the driver power loss relating to

the total gate charge of upper and lower MOSFETs

and switching frequency.

total RMS current. Figure 21 shows a typical input

current. Equation 13 shows the RMS input current.

The RMS input current contains the DC load current

and the inductor ripple current. As shown in equation

12, inductor ripple current is unrelated to the load

current. The maximum RMS input current occurs at

the maximum output current. The maximum power

P COND =

∫ V DR ? I GDr ? dt = V DR ? Q GTotal ? F S (10)

dissipate in the input capacitor equals the square of

the maximum RMS input current times the input

capacitor’s total ESR.

The low frequency and core losses are main factors

of the total power loss of an inductor. Low frequency

loss of an inductor is caused by the resistance of

copper winding. The copper loss of the winding is

shown in equation 11. The core loss of an inductor

depends on the B-H loop characteristic, volume and

frequency. This data can be obtained from the

inductor manufactures.

P DCR = I RMS 2 ? DCR (11)

Figure 21. Typical Input Current Waveform.

Where : I RMS = I OUT ? 1 + ? ? ?

∫

1 ? Δ I ?

Inductor Selection

1 Δ I ?

3 ? I OUT ?

I IN_RMS =

f 2 ( t ) ? dt = I OUT ? D ? 1 +

? ? ? (13)

3 ? I OUT ?

Page 13 of 20

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IR Confidential

4/26/10

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