IR3473MTRPBF International Rectifier, IR3473MTRPBF Datasheet - Page 14

IR3473MTRPBF

Manufacturer Part Number

IR3473MTRPBF

Description

IC BUCK SYNC ADJ 6A PQFN

Manufacturer

International Rectifier

Series

SupIRBuck™r

Type

Step-Down (Buck), PWM - Current Moder

Datasheet

1.IR3473MTRPBF.pdf (21 pages)

Specifications of IR3473MTRPBF

Internal Switch(s)

Yes

Synchronous Rectifier

Yes

Number Of Outputs

Voltage - Output

0.5 V ~ 12 V

Current - Output

Frequency - Switching

Up to 750kHz

Voltage - Input

3 V ~ 27 V

Operating Temperature

-40°C ~ 125°C

Mounting Type

Package / Case

Primary Input Voltage

27V

No. Of Outputs

Output Voltage

12V

Output Current

No. Of Pins

Operating Temperature Range

-40Â°C To +125Â°C

Peak Reflow Compatible (260 C)

Yes

Rohs Compliant

Yes

Leaded Process Compatible

Yes

Part Status

Preferred

Package

PQFN / 4 x 5

Circuit

Single Output

Iout (a)

Switch Freq (khz)

0 - 750

Input Range (v)

3.0 - 27

Output Range (v)

0.5 - 12

Ocp Otp Uvlo Pre-bias Soft Start And

Constant On-Time + PGOOD + EN + Temp Comp OCP

Digital Home Media

Yes

Mobile Computing

Yes

Industrial 24v Input

Yes

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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GATE DRIVE LOGIC

The gate drive logic features adaptive dead time,

diode emulation, and a minimum lower gate interval.

An adaptive dead time prevents the simultaneous

conduction of the upper and lower MOSFETs. The lower

gate voltage must be below approximately 1V after PWM

goes HIGH before the upper MOSFET can be gated on.

Also, the differential voltage between the upper gate and

PHASE must be below approximately 1V after PWM goes

LOW before the lower MOSFET can be gated on.

The upper MOSFET is gated on after the adaptive delay

for PWM = HIGH and the lower MOSFET is gated on after

the adaptive delay for PWM = LOW. When FCCM = LOW,

the lower MOSFET is driven ‘off’ when the ZCROSS signal

indicates that the inductor current is about to reverse

direction. The ZCROSS comparator monitors the PHASE

voltage to determine when to turn off the lower MOSFET.

The lower MOSFET stays ‘off’ until the next PWM falling

edge. When the lower peak of the inductor current is

above zero, IR3473 operates in continuous conduction

mode. The continuous conduction mode can also be

selected for all load current levels by pulling FCCM to

HIGH.

Whenever the upper MOSFET is turned ‘off’, it stays

‘off’ for the Min Off Time denoted in the Electrical

Specifications. This minimum duration allows time to

recharge the bootstrap capacitor and allows the over

current monitor to sample the PHASE voltage.

COMPONENT SELECTION

Selection of components for the converter is an iterative

process which involves meeting the specifications and

tradeoffs between performance and cost. The following

sections will guide one through the process.

Inductor Selection

Inductor selection involves meeting the steady state

output ripple requirement, minimizing the switching loss

of the upper MOSFET, meeting transient response

specifications 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 the output

February 16, 2011 | ADVANCED DATASHEET | V1.9 | PD97601

6A Highly Integrated SupIRBuck

capacitor, the magnitude of the AC voltage ripple is

determined by the total inductor ripple current flowing

through the total equivalent series resistance (ESR) of the

output capacitor bank.

One can use equation 5 to find the required inductance.

ΔI is defined as shown in Figure 27. The main advantage

of small inductance is increased inductor current slew rate

during a load transient, which leads to a smaller output

capacitance requirement as discussed in the Output

Capacitor Selection section. The drawback of using smaller

inductances is increased switching power loss in the upper

MOSFET, which reduces the system efficiency and

increases the thermal dissipation.

Input Capacitor Selection

The main function of the input capacitor bank is to provide

the input ripple current and fast slew rate current during

the load current step up. The input capacitor bank must

have adequate ripple current carrying capability to handle

the total RMS current. Figure 27 shows a typical input

current. Equation 6 shows the RMS input current.

The RMS input current contains the DC load current and

the inductor ripple current. As shown in equation 5, the

inductor ripple current is unrelated to the load current.

The maximum RMS input current occurs at the maximum

output current. The maximum power dissipation in the

input capacitor equals the square of the maximum RMS

input current times the input capacitor’s total ESR.

The voltage rating of the input capacitor needs to be

greater than the maximum input voltage because of high

frequency ringing at the phase node. The typical

percentage is 25%.



IN_RMS

Figure 27: Typical Input Current Waveform

OUT

ΔI















 









OUT











ΔI

OUT

IR3473

(5)







(6)

IR3473MTRPBF International Rectifier, IR3473MTRPBF Datasheet - Page 14

IR3473MTRPBF

Specifications of IR3473MTRPBF

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