ISL6267HRZ Intersil, ISL6267HRZ Datasheet - Page 23

ISL6267HRZ

Manufacturer Part Number

ISL6267HRZ

Description

IC PWM CTRLR MULTIPHASE 48TQFN

Manufacturer

Intersil

Datasheet

1.ISL6267HRZ-T.pdf (33 pages)

Specifications of ISL6267HRZ

Applications

Converter, AMD Fusion™ CPU GPU

Voltage - Input

4.75 V ~ 5.25 V

Number Of Outputs

Voltage - Output

0.0125 V ~ 1.55 V

Operating Temperature

-10°C ~ 100°C

Mounting Type

Package / Case

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Meier Automation Equipment Co., Limited

Part Number:

ISL6267HRZ

Manufacturer:

INTERSIL

Quantity:

20 000

Current page: 23 of 33
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Dynamic Operation

Core VR and Northbridge VR behave the same during dynamic

operation. The controller responds to VID-on-the-fly changes by

slewing to the new voltage at the fixed 7.5mV/µs slew rate.

During negative VID transitions, the output voltage decays to the

lower VID value at the slew rate determined by the load.

SVI_L low command prompts the controller to enter DE mode.

Overvoltage protection is blanked during VID down transition in

DE mode until the output voltage is within 60mV of the VID value.

During load insertion response, the Fast Clock function increases

the PWM pulse response speed. The controller monitors the

VSEN pin voltage and compares it to 100ns-filtered version.

When the unfiltered version is 20mV below the filtered version,

the controller knows there is a fast voltage dip due to load

insertion, and it issues an additional master clock signal to

deliver a PWM pulse immediately.

The R

output voltage is insensitive to a fast slew rate input voltage

change.

Protections

Core VR and Northbridge VR both provide overcurrent,

current-balance and overvoltage fault protections. The controller

also provides over-temperature protection. The following

discussion is based on Core VR and also applies to Northbridge VR.

The controller determines overcurrent protection (OCP) by

comparing the average value of the droop current (I

internal current source threshold as Table 6 shows. It declares OCP

when I

For overcurrent conditions above 1.5x the OCP level, the PWM

outputs immediately shuts off and PGOOD goes low to maximize

protection. This protection is also referred to as way-overcurrent

protection or fast overcurrent protection for short-circuit

protections.

The controller monitors the ISEN pin voltages to determine

current-balance protection. If the ISEN pin voltage difference is

greater than 9mV for 1ms, the controller will declare a fault and

latch off.

The controller takes the same actions for all of the previously

describe fault protections: de-assertion of PGOOD and turn-off of

the high-side and low-side power MOSFETs. Any residual inductor

current decays through the MOSFET body diodes.

The controller declares an overvoltage fault and de-asserts PGOOD if

the output voltage exceeds the VID set value by +250mV. The

ISL6267 immediately declares an OV fault, de-asserts PGOOD,

and turn on the low-side power MOSFETs. The low-side power

MOSFETs remain on until the output voltage is pulled down below

the VID set value when all power MOSFETs are turned off. If the

output voltage rises above the VID set value +250mV again, the

protection process is repeated. This behavior provides the

maximum amount of protection against shorted high-side power

MOSFETs while preventing output ringing below ground.

All of the previously described fault conditions can be reset by

bringing ENABLE low or by bringing V

droop

™ modulator intrinsically has voltage feed-forward. The

is above the threshold for 120µs.

below the POR

droop

) with an

ISL6267

threshold. When ENABLE and V

levels, a soft-start occurs.

Table 8 summarizes the fault protections.

FB2 Function

The FB2 function is only available for Core VR or Northbridge VR

in 2-phase configuration.

Figure 19 shows the FB2 function. A switch (called FB2 switch)

turns on to short the FB and the FB2 pins when the controller is in

2-phase mode. Capacitors C3.1 and C3.2 are in parallel, serving

as part of the compensator. When the controller enters 1-phase

mode, the FB2 switch turns off, removing C3.2 and leaving only

C3.1 in the compensator. The compensator gain increases with

the removal of C3.2. By properly sizing C3.1 and C3.2, the

compensator can be optimal for both 2-phase mode and 1-phase

mode.

When the FB2 switch is off, C3.2 is disconnected from the FB pin.

However, the controller still actively drives the FB2 pin voltage to

follow the FB pin voltage such that C3.2 voltage always follows

C3.1 voltage. When the controller turns on the FB2 switch, C3.2

is reconnected to the compensator smoothly.

The FB2 function ensures excellent transient response in both

2-phase and 1-phase mode. If the FB2 function is not used,

populate C3.1 only.

Adaptive Body Diode Conduction Time

Reduction

In DCM, the controller turns off the low-side MOSFET when the

inductor current approaches zero. During on-time of the low-side

MOSFET, phase voltage is negative, and the amount is the

Overcurrent

Phase Current

Unbalance

Way-Overcurrent

(1.5xOC)

Overvoltage +200mV

Over-Temperature

VSEN

2-PHASE MODE

CONTROLLER

FAULT TYPE

TABLE 8. FAULT PROTECTION SUMMARY

VREF

FB2

FIGURE 19. FB2 FUNCTION

C3.1

C3.2

FAULT DURATION

E/A

PROTECTION

Immediately

BEFORE

120µs

1ms

COMP

VSEN

1-PHASE MODE

CONTROLLER

return to their high operating

PGOOD latched

PWM tri-state,

PGOOD latched

low

low. Actively pulls

the output

voltage to below

VID value, then

tri-state.

400µs

PROTECTION

ACTION

VREF

FB2

January 31, 2011

C3.1

C3.2

E/A

ENABLE

toggle or

VDD toggle

RESET

FAULT

FN7801.0

N/A

COMP

ISL6267HRZ Intersil, ISL6267HRZ Datasheet - Page 23

ISL6267HRZ

Specifications of ISL6267HRZ

Available stocks

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