ISL6565ACBZ Intersil, ISL6565ACBZ Datasheet - Page 22

ISL6565ACBZ

Manufacturer Part Number

ISL6565ACBZ

Description

IC CTRLR PWM MULTIPHASE 28-SOIC

Manufacturer

Intersil

Datasheet

1.ISL6565ACBZ.pdf (28 pages)

Specifications of ISL6565ACBZ

Pwm Type

Voltage Mode

Number Of Outputs

Frequency - Max

1.5MHz

Duty Cycle

66.7%

Voltage - Supply

4.75 V ~ 5.25 V

Buck

Yes

Boost

Flyback

Inverting

Doubler

Divider

Cuk

Isolated

Operating Temperature

0°C ~ 105°C

Package / Case

28-SOIC (7.5mm Width)

Frequency-max

1.5MHz

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Current page: 22 of 28
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important to note that when using Equations 33 and 34 the

resistor divider ratio of the corresponding phase RC network

is being changed. In the phase being adjusted, this new ratio,

If this occurs, the current in the hot phase cannot be reduced

any more. Instead of decreasing the current in the hot phase,

the current must be increased in the colder phases. To

accomplish this, use Equations 33 and 34 to get the desired

temperature rise in the cold phases.

While a single adjustment, according to Equations 33 and 34,

is usually sufficient, it may occasionally be necessary to adjust

to achieve optimal thermal balance between all phases.

Load-Line Regulation Resistor

The load-line regulation resistor is labeled R

Its value depends on the desired full-load droop voltage

chosen, the load-line regulation resistor can be calculated

using Equation 36.

If one or more of the ISEN resistors is adjusted for thermal

balance, as in Equation 26, the load-line regulation resistor

should be selected according to Equation 37 where I

full-load operating current and R

connected to the n

Temperature Compensation Resistor

By combining Equations 17 and 18 found in the Temperature

Compensation section, the value of the TCOMP resistor can

be determined using Equation 38.

In Equation 38, K

between the ISL6565A and the closest lower MOSFET, or

the ISL6565B and the output inductor. It represents how

closely the controller temperature tracks the lower MOSFET

or inductor temperature. The value of K

75% and 100%. K

transconductance of the internal compensation circuit. Its

value is designed as 2µA/V/°C. The temperature coefficient

of MOSFET r

the ratio of the change in resistance to the change in

new

TCOMP

DROOP

and R

(described in Equation 35), can not exceed 1.0.

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

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

70 10

DROOP

∆T

----------

∆T

in Figure 7). Once the ISEN resistor has been

in the corresponding channels two or more times

DS ON

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

DS(ON)

–

(

)

is the temperature coupling coefficient

∑

ISEN pin.

or inductor DCR is given by α. This is

is the temperature dependant

ISEN n ( )

ISEN(n)

is the ISEN resistor

is typically between

in Figure 7.

ISL6565A, ISL6565B

(EQ. 35)

(EQ. 36)

(EQ. 37)

(EQ. 38)

is the

temperature. Resistance is normalized to the value at 25°C

and the value of

0.50%/°C.

According to Equation 38, a voltage regulator with 80%

thermal coupling coefficient between the controller and lower

MOSFET and 0.4%/°C temperature coefficient of MOSFET

If the exact value for K

can give an incorrect value for R

follow the steps below to obtain an accurate value for

voltage measurements. The first is made by using too much

temperature compensation, and the second with too little.

Each of the measurements produces an error and a linear

interpolation is used to find a TCOMP resistor value to

produce zero error. Make all measurements using a digital

multimeter accurate to 100µV or better.

Compensation

The two opposing goals of compensating the voltage

regulator are stability and speed.

The load-line regulated converter behaves in a similar

manner to a peak-current mode controller because the two

poles at the output-filter L-C resonant frequency split with

the introduction of current information into the control loop.

The final location of these poles is determined by the system

function, the gain of the current signal, and the value of the

compensation components, R

DS(ON)

1. Install a 5kΩ resistor (R

2. Start the regulator at room temperature and apply full

3. Allow the board to heat until the output voltage stabilizes

4. Install a 1kΩ resistor (R

5. Start the regulator at room temperature and apply full

6. Allow the board to heat until the output voltage stabilizes

7. Calculate the correct value for R

TCOMP

load current. Record the output voltage, V

after loading the regulator.

(usually several minutes). Record the output voltage, V

load current. Record the output voltage, V

after loading the regulator.

(usually several minutes). Record the output voltage, V

Equation 39.

requires a 2.5kΩ TCOMP resistor.

. This procedure works by making two output

–

(

is typically between 0.35%/°C and

–

and α are not known, Equation 38

)

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

(

) for R

–

(

and C

TCOMP

)

–

TCOMP

(

TCOMP

)

. If this is the case,

–

)

using

, immediately

December 1, 2005

(EQ. 39)

FN9135.4

ISL6565ACBZ Intersil, ISL6565ACBZ Datasheet - Page 22

ISL6565ACBZ

Specifications of ISL6565ACBZ

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