ISL8101IRZ Intersil, ISL8101IRZ Datasheet - Page 15

ISL8101IRZ

Manufacturer Part Number

ISL8101IRZ

Description

IC PWM CTRLR BUCK 2PHASE 24-QFN

Manufacturer

Intersil

Datasheet

1.ISL8101CRZ-T.pdf (20 pages)

Specifications of ISL8101IRZ

Applications

Controller, Intel VRM9, VRM10, and AMD Hammer Applications

Voltage - Input

4.6 ~ 12 V

Number Of Outputs

Voltage - Output

0.6 ~ 2.3 V

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

24-VQFN Exposed Pad, 24-HVQFN, 24-SQFN, 24-DHVQFN

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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dissipated in the lower MOSFET can be found in

Equation 15.

where: I

is the peak-to-peak inductor current, and D is the duty cycle

(approximately V

An additional term can be added to the lower-MOSFET loss

equation to account for additional loss accrued during the

dead time when inductor current is flowing through the

lower-MOSFET body diode. This term is dependent on the

diode forward voltage at I

frequency, f

the beginning and the end of the lower-MOSFET conduction

interval, respectively.

Equation 16 assumes the current through the lower

MOSFET is always positive; if so, the total power dissipated

in each lower MOSFET is approximated by the summation of

UPPER MOSFET POWER CALCULATION

In addition to r

MOSFET losses are switching losses, due to currents

conducted through the device while the input voltage is

present as V

separate components, separating the upper MOSFET

switching losses, the lower MOSFET body diode reverse

recovery charge loss, and the upper MOSFET r

conduction loss.

In most typical circuits, when the upper MOSFET turns off, it

continues to conduct the inductor current until the voltage at

the phase node falls below ground. Once the lower

MOSFET begins conducting (via its body diode or

enhancement channel), the current in the upper MOSFET

falls to zero. In the following equation, the required time for

this commutation is t

Similarly, the upper MOSFET begins conducting as soon as

it begins turning on. Assuming the inductor current is in the

positive domain, the upper MOSFET sees approximately the

input voltage applied across its drain and source terminals,

while it turns on and starts conducting the inductor current.

LMOS1

UMOS,1

LMOS1

LMOS 2

UMOS 1 ,

and P

≈

is the maximum continuous output current, I

DS ON

; and the length of dead times, t

D ON

(

DS(ON)

⎛

⎜

⎝

(

LMOS2

. Upper MOSFET losses can be divided into

-------------

OUT

)

⎛

⎜

⎝

------------ -

OUT

⎛

⎜

⎝

losses, a large portion of the upper

and the associated power loss is

---------------

------------ -

L P-P

OUT

⎞

⎟

⎠

, V

(

⎞ t

⎟

⎠

1 D

⎛

⎜

⎝

D(ON)

---------- -

–

----

P-P

⎞

⎟

⎠

)

⎞

⎟

⎠

; the switching

----------------------------------

L P-P

⎛

⎜

⎝

(

------------ -

OUT

1 D

–

)

and t

DS(ON)

---------- -

P-P

(EQ. 15)

(EQ. 16)

⎞

⎟

⎠

(EQ. 17)

L,P-P

, at

ISL8101

This transition occurs over a time t

the power loss is P

A third component involves the lower MOSFET’s

reverse-recovery charge, Q

body diode conducts the full inductor current before it has

fully switched to the upper MOSFET, the upper MOSFET

has to provide the charge required to turn off the lower

MOSFET’s body diode. This charge is conducted through

the upper MOSFET across VIN, the power dissipated as a

result, P

Equation 19.

Lastly, the conduction loss part of the upper MOSFET’s

power dissipation, P

Equation 20.

In this case, of course, r

upper MOSFET.

The total power dissipated by the upper MOSFET at full load

can be approximated as the summation of these results.

Since the power equations depend on MOSFET parameters,

choosing the correct MOSFETs can be an iterative process

that involves repetitively solving the loss equations for

different MOSFETs and different switching frequencies until

converging upon the best solution.

OUTPUT FILTER DESIGN

The output inductors and the output capacitor bank together

form a low-pass filter responsible for smoothing the square

wave voltage at the phase nodes. Additionally, the output

capacitors must also provide the energy required by a fast

transient load during the short interval of time required by the

controller and power train to respond. Because it has a low

bandwidth compared to the switching frequency, the output

filter limits the system transient response leaving the output

capacitor bank to supply the load current or sink the inductor

currents, all while the current in the output inductors

increases or decreases to meet the load demand.

In high-speed converters, the output capacitor bank is

amongst the costlier (and often the physically largest) parts

of the circuit. Output filter design begins with consideration

of the critical load parameters: maximum size of the load

step, ΔI, the load-current slew rate, di/dt, and the maximum

allowable output voltage deviation under transient loading,

ΔV

capacitance, ESR, and ESL (equivalent series inductance).

UMOS 2 ,

UMOS 3 ,

UMOS 4 ,

MAX

. Capacitors are characterized according to their

UMOS,3

≈

DS ON

⎛

⎜

⎝

(

-------------

OUT

can be approximated as shown in

UMOS,2

)

UMOS,4,

⋅

–

---------------

⋅

L P-P

DS(ON)

⎛

⎜

⎝

------------ -

OUT

⎞ t

⎟

⎠

⎛

⎜

⎝

can be calculated using

----

⎞

⎟

⎠

. Since the lower MOSFET’s

is the ON-resistance of the

⎞

⎟

⎠

---------- -

P-P

, and the approximate

July 28, 2008

(EQ. 18)

(EQ. 20)

(EQ. 19)

FN9223.1

ISL8101IRZ Intersil, ISL8101IRZ Datasheet - Page 15

ISL8101IRZ

Specifications of ISL8101IRZ

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