ISL6265AHRTZ Intersil, ISL6265AHRTZ Datasheet - Page 16

ISL6265AHRTZ

Manufacturer Part Number

ISL6265AHRTZ

Description

IC CTRLR MULTI-OUTPUT 48-TQFN

Manufacturer

Intersil

Datasheet

1.ISL6265AHRTZ.pdf (23 pages)

Specifications of ISL6265AHRTZ

Applications

Controller, AMD SVI Capable Mobile

Voltage - Input

5 ~ 24 V

Number Of Outputs

Voltage - Output

0.5 ~ 1.55 V

Operating Temperature

-10°C ~ 100°C

Mounting Type

Surface Mount

Package / Case

48-TQFN

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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Current page: 16 of 23
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It is recommended that whenever the control loop

compensation network is modified, the switching frequency

should be checked and adjusted by changing R

necessary.

Current Sense

Core and Northbridge regulators feature two different types

of current sense circuits.

CORE CONTINUOUS CURRENT SENSE

The ISL6265A provides for load current to be measured

using either resistors in series with the individual output

inductors or using the intrinsic series resistance of the

inductors as shown in the applications circuits in Figures 2

and 3. The load current in a particular output is sampled

continuously every switching cycle. During this time, the

current-sense amplifier uses the current sense inputs to

reproduce a signal proportional to the inductor current. This

sensed current is a scaled version of the inductor current.

Inductor windings have a characteristic distributed

resistance or DCR (Direct Current Resistance). For

simplicity, the inductor DCR is considered as a separate

lumped quantity, as shown in Figure 9. The inductor current,

Equation 6 shows the s-domain equivalent voltage, V

across the inductor.

A simple R-C network across the inductor (R

extracts the DCR voltage, as shown in Equation 7. The

voltage across the sense capacitor, V

proportional to the output current I

, flowing through the inductor, passes through the DCR.

s ( )

MOSFET

DRIVER

ISL6265A INTERNAL CIRCUIT

---------------------------------------------------------- - K DCR I

⎛

⎜

⎝

FIGURE 9. DCR SENSING COMPONENTS

⋅

(

s L

(

----------------------- - C

⎛

⎝

⋅

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

DCR

s L

⋅

UGATE

LGATE

⋅

CURRENT

DCR

SENSE

)

⋅

⎞

⎠

)

⎞

⎟

⎠

⋅

ISN

ISP

, shown in Equation 7.

INDUCTOR

⋅

, can be shown to be

I L

(s)

DCR

(s)

NTC

, R

FSET_NB

OPTIONAL

NTC

NETWORK

and C)

OUT

(EQ. 6)

(EQ. 7)

OUT

ISL6265A

Where:

Sensing the time varying inductor current accurately

requires that the parallel R-C network time constant match

the inductor L/DCR time constant. If the R-C network

components are selected, such that the R-C time constant

matches the inductor L/DCR time constant (see Equation 9),

then V

multiplied by the ratio of the resistor divider, K.

The inductor current sense information is used for current

balance in dual plane applications, overcurrent detection in

core outputs and output voltage droop depending on

controller configuration.

CORE DCR TEMPERATURE COMPENSATION

It may also be necessary to compensate for changes in

inductor DCR due to temperature. DCR shifts due to

temperature cause time constant mismatch, skewing inductor

current accuracy. Potential problems include output voltage

droop and OC trip point, both shifting significantly from

expected levels. The addition of a negative temperature

coefficient (NTC) resistor to the R-C network compensates for

the rise in DCR due to temperature. Typical NTC values are in

the 10kΩ range. A second resistor, R

allows for more accurate time-constant and resistor-ratio

matching as the pair of resistors are placed in parallel with R

(Figure 9). The NTC resistor must be placed next to the

inductor for good heat transfer, while R

placed close to the controller for interference immunity.

CORE DCR COMPONENT SELECTION FOR DROOP

By adjusting the ratio between inductor DCR drop and the

voltage measured across the sense capacitor, the load line

can be set to any level, giving the converter the correct

amount of droop at all load currents.

Equation 10 shows the relation between droop voltage,

maximum output current (I

sense capacitor voltage at the OC current level, V

AMD specifications do not require droop and provide no load

line guidelines. Tight static output voltage tolerance limits

push acceptable level of droop below a useful level for Griffin

applications. Care must be taken in applications which

implement droop to balance time constant mismatch, sense

capacitor resistor ratio, OC trip and droop equations.

Temperature shifts related to DCR must also be addressed,

as outlined in the previous section.

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

DCR

DROOP

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

-------------------- - C

is equal to the voltage drop across the DCR

⋅

------------- - 5 V

MAX

⋅

C OC

MAX

), OC trip level and current

, in series with the NTC

, R

, and C

C(OC)

May 11, 2009

(EQ. 10)

(EQ. 8)

FN6884.0

(EQ. 9)

are

ISL6265AHRTZ Intersil, ISL6265AHRTZ Datasheet - Page 16

ISL6265AHRTZ

Specifications of ISL6265AHRTZ

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