ISL6218_14 Datasheet, PDF(12/19 Page) Intersil Corporation – Precision Single-Phase Buck PWM Controller for Intel Mobile Voltage Positioning IMVP-IV and IMVP-IV+

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ISL6218_14 Datasheet, PDF (12/19 Pages) Intersil Corporation – Precision Single-Phase Buck PWM Controller for Intel Mobile Voltage Positioning IMVP-IV and IMVP-IV+

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ISL6218

shutting off the low side MOSFET. This âThree-Stateâ mode

will hold both upper and low side MOSFETs off during the

time that the Low Side MOSFET would normally be on.

This âDiode Emulationâ is initiated when the current, as

sensed through the low side MOSFET, is negative. This event

triggers the âThree-Stateâ mode until the next PWM cycle.

This Discontinuous operation improves efficiency by preventing

the reverse conduction of current through the low side

MOSFET. This eliminates conduction loss and output

discharge. Discontinuous operation is enabled in Deep and

Deeper Sleep modes and is based solely on current feedback.

Due to this ISL6218âs ability to sense zero current and

prevent discharging through the low side MOSFETs during

light loads, the ISL6218 meets the requirements for PSI

without requiring any external signals.

STV, DSV and DRSV

START-UP âBOOTâ VOLTAGE - STV

The Start-up, or âBoot,â voltage is programmed by an

external resistor divider network from the OCSET pin (refer

to Figure 8). Internally, a 1.75V reference voltage is output

on the OCSET pin. The start-up voltage is set through a

voltage divider from the 1.75V reference at the OCSET pin.

The voltage on the STV pin will be the controller regulating

voltage during the start-up sequence.

Once the PGOOD pin of the ISL6218 controller is externally

enabled high by the Vccp and Vcc_mch controllers, the

ISL6218 will then ramp, after a 10Âµs delay, to the voltage

commanded by the VID setting minus âDroopâ.

DEEP SLEEP VOLTAGE- DSV

The Deep Sleep voltage is programmed by an external

voltage divider network from the DACOUT pin (Refer to

Figure 8). The DACOUT pin is the output of the VID digital-

to-analog converter. By having the Deep Sleep voltage setup

from a resistor divider from DAC, the Deep Sleep voltage will

be a constant percentage of the VID. Through the voltage

divider network, Deep Sleep voltage is set to 98.8% of the

programmed VID voltage, as per the IMVP-IVâ¢ specification.

The IC enters the Deep Sleep mode when the DSEN is low

and the DRSEN pin is low as shown in Figure 6 and

Figure 5. Once in Deep Sleep Mode, the controller will

regulate to the voltage seen on the DSV pin minus âDroopâ.

DEEPER SLEEP VOLTAGE - DRSV

The Deeper Sleep voltage, DRSV, is programmed by an

external voltage divider network from the 1.75V reference on

the OCSET pin (Refer to Figure 8). In Deeper Sleep mode

the ISL6218 controller will regulate the output voltage to the

voltage present on the DRSV pin minus âDroopâ.

The IC enters Deeper Sleep mode when DRSEN is high and

DSEN is low, as shown in Figure 5.

BATTERY

V REF = 1.75V

I OCSET

ISL6218

OCSET

R1 36.5k

VBAT

1.200V STV

R2 30.1k

VID COMMAND

DACOUT

VOLTAGE

0.750V DRSV

1.21k

R3 49.9k

SOFT

GND

DSV

98.8%

DACOUT

0.012ÂµF

98.8k

FIGURE 8. CONFIGURATIONS FOR BATTERY INPUT,

OVERCURRENT SETTING AND START, DEEP

SLEEP AND DEEPER SLEEP VOLTAGE

OVERCURRENT SETTING - OCSET

The ISL6218 overcurrent protection essentially compares a

user-selectable overcurrent threshold to the scaled and

sampled output current. An overcurrent condition is defined

when the sampled current is equal to or greater than the

threshold current. A step by step process to the user-desired

overcurrent set point is detailed next.

Step 1: Setting the Overcurrent Threshold

The overcurrent threshold is represented by the DC current

flowing out of the OCSET pin (See Figure 8). Since the

OCSET pin is held at a constant 1.75V, the user need only

populate a resistor from this pin to ground to set the desired

overcurrent threshold, IOCSET. The user should pick a value

of IOCSET between 10ÂµA and 15ÂµA. Once this is done, use

Ohmâs Law to determine the necessary resistor to place from

OCSET to ground:

ROCSET

1.75V

IOCSET

= R1 + R2

+ R3

(EQ. 2)

For example, if the desired overcurrent threshold is 15ÂµA,

Step 2: Selecting ISEN Resistance for Desired

Overcurrent Level

After choosing the IOCSET level, the user must then decide

what level of total output current is desired for overcurrent.

Typically, this number is between 150% and 200% of the

maximum operating current of the application. For example,

if the max operating current is 27A, and the user chooses

150% overcurrent, the ISL6218 will shut down if the output

current exceeds 27A*1.5 or 40A. According to the âBlock

Diagramâ on page 7, Equation 3 should be used to

determine RISEN once the overcurrent level, IOC, is chosen.

FN9101.6

August 6, 2007

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