ISL6552_04 Datasheet, PDF(9/18 Page) Intersil Corporation – Microprocessor CORE Voltage Regulator Multi-Phase Buck PWM Controller

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ISL6552_04 Datasheet, PDF (9/18 Pages) Intersil Corporation – Microprocessor CORE Voltage Regulator Multi-Phase Buck PWM Controller

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ISL6552

comparator to compensate for the detected âabove averageâ

current in that channel.

Droop Compensation

In addition to control of each power channelâs output current,

the average channel current is also used to provide CORE

voltage âdroopâ compensation. Average full channel current

is defined as 50ÂµA. By selecting an input resistor, RIN, the

amount of voltage droop required at full load current can be

programmed. The average current driven into the FB pin

results in a voltage increase across resistor RIN that is in the

direction to make the error amplifier âseeâ a higher voltage at

the inverting input, resulting in the error amplifier adjusting

the output voltage lower. The voltage developed across RIN

is equal to the âdroopâ voltage. See the âCurrent Sensing

and Balancingâ section for more details.

Applications and Converter Start-Up

Each PWM power channelâs current is regulated. This

enables the PWM channels to accurately share the load

current for enhanced reliability. The HIP6601, HIP6602 or

HIP6603 MOSFET driver interfaces with the ISL6552. For

more information, see the HIP6601, HIP6602 or HIP6603

data sheets [1][2].

The ISL6552 is capable of controlling up to 4 PWM power

channels. Connecting unused PWM outputs to VCC

automatically sets the number of channels. The phase

relationship between the channels is 360o/number of active

PWM channels. For example, for three channel operation,

the PWM outputs are separated by 120o. Figure 2 shows the

PWM output signals for a four channel system.

PWM 1

PWM 2

PWM 3

PWM 4

FIGURE 2. FOUR PHASE PWM OUTPUT AT 500kHz

Power supply ripple frequency is determined by the channel

frequency, FSW, multiplied by the number of active channels.

For example, if the channel frequency is set to 250kHz and

there are three phases, the ripple frequency is 750kHz.

The IC monitors and precisely regulates the CORE voltage

of a microprocessor. After initial start-up, the controller also

provides protection for the load and the power supply. The

following section discusses these features.

Initialization

The ISL6552 usually operates from an ATX power supply.

Many functions are initiated by the rising supply voltage to

the VCC pin of the ISL6552. Oscillator, sawtooth generator,

soft-start and other functions are initialized during this

interval. These circuits are controlled by POR, Power-On

Reset. During this interval, the PWM outputs are driven to a

three state condition that makes these outputs essentially

open. This state results in no gate drive to the output

MOSFETs.

Once the VCC voltage reaches 4.375V (+125mV), a voltage

level to insure proper internal function, the PWM outputs are

enabled and the Soft-Start sequence is initiated. If for any

reason, the VCC voltage drops below 3.875V (+125mV). The

POR circuit shuts the converter down and again three states

the PWM outputs.

Soft-Start

After the POR function is completed with VCC reaching

4.375V, the Soft-Start sequence is initiated. Soft-Start, by its

slow rise in CORE voltage from zero, avoids an over-current

condition by slowly charging the discharged output

capacitors. This voltage rise is initiated by an internal DAC

that slowly raises the reference voltage to the error amplifier

input. The voltage rise is controlled by the oscillator

frequency and the DAC within the ISL6552, therefore, the

output voltage is effectively regulated as it rises to the final

programmed CORE voltage value.

For the first 32 PWM switching cycles, the DAC output

remains inhibited and the PWM outputs remain three stated.

From the 33rd cycle and for another, approximately 150

cycles the PWM output remains low, clamping the lower

output MOSFETs to ground, see Figure 3. The time

variability is due to the error amplifier, sawtooth generator

and comparators moving into their active regions. After this

short interval, the PWM outputs are enabled and increment

the PWM pulse width from zero duty cycle to operational

pulse width, thus allowing the output voltage to slowly reach

the CORE voltage. The CORE voltage will reach its

programmed value before the 2048 cycles, but the PGOOD

output will not be initiated until the 2048th PWM switching

cycle.

The Soft-Start time or delay time, DT = 2048/FSW. For an

oscillator frequency, FSW, of 200kHz, the first 32 cycles or

160Âµs, the PWM outputs are held in a three state level as

explained above. After this period and a short interval

described above, the PWM outputs are initiated and the

voltage rises in 10.08ms, for a total delay time DT of

10.24ms.

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