ISL62883HRTZ Intersil, ISL62883HRTZ Datasheet - Page 12

ISL62883HRTZ

Manufacturer Part Number

ISL62883HRTZ

Description

IC REG PWM 3PHASE BUCK 40TQFN

Manufacturer

Intersil

Datasheet

1.ISL62883EVAL2Z.pdf (39 pages)

Specifications of ISL62883HRTZ

Applications

Controller, Intel IMVP-6.5™

Voltage - Input

5 V ~ 21 V

Number Of Outputs

Voltage - Output

0.0125 V ~ 1.5 V

Operating Temperature

-10°C ~ 100°C

Mounting Type

Package / Case

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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Current page: 12 of 39
Download datasheet (2Mb)

Each slave circuit has its own ripple capacitor C

voltage mimics the inductor ripple current. A g

amplifier converts the inductor voltage into a current

source to charge and discharge C

turns on its PWM pulse upon receiving the clock signal,

and the current source charges C

and the current source discharges C

Since the ISL62883 works with V

amplitude and noise-free synthesized signals, the

ISL62883 achieves lower phase jitter than conventional

hysteretic mode and fixed PWM mode controllers. Unlike

conventional hysteretic mode converters, the ISL62883

has an error amplifier that allows the controller to

maintain a 0.5% output voltage accuracy.

Figure 5 shows the operation principles during load

insertion response. The COMP voltage rises during load

insertion, generating the master clock signal more

quickly, so the PWM pulses turn on earlier, increasing the

effective switching frequency, which allows for higher

control loop bandwidth than conventional fixed frequency

PWM controllers. The VW voltage rises as the COMP

voltage rises, making the PWM pulses wider. During load

release response, the COMP voltage falls. It takes the

master clock circuit longer to generate the next master

clock signal so the PWM pulse is held off until needed.

The VW voltage falls as the VW voltage falls, reducing the

current PWM pulse width. This kind of behavior gives the

ISL62883 excellent response speed.

The fact that all the phases share the same VW window

voltage also ensures excellent dynamic current balance

among phases.

Diode Emulation and Period Stretching

ISL62883 can operate in diode emulation (DE) mode to

improve light load efficiency. In DE mode, the low-side

MOSFET conducts when the current is flowing from

source to drain and doesn’t not allow reverse current,

emulating a diode. As Figure 6 shows, when LGATE is

on, the low-side MOSFET carries current, creating

negative voltage on the phase node due to the voltage

drop across the ON-resistance. The ISL62883 monitors

the current through monitoring the phase node voltage.

It turns off LGATE when the phase node voltage reaches

U G A T E

L G A T E

Crs

P h a s e

hits VW, the slave circuit turns off the PWM pulse,

FIGURE 6. DIODE EMULATION

crs

. When C

. The slave circuit

, which are large-

ISL62883, ISL62883B

voltage

, whose

zero to prevent the inductor current from reversing the

direction and creating unnecessary power loss.

If the load current is light enough, as Figure 6 shows, the

inductor current will reach and stay at zero before the

next phase node pulse, and the regulator is in

discontinuous conduction mode (DCM). If the load

current is heavy enough, the inductor current will never

reach 0A, and the regulator is in CCM although the

controller is in DE mode.

Figure 7 shows the operation principle in diode

emulation mode at light load. The load gets

incrementally lighter in the three cases from top to

bottom. The PWM on-time is determined by the VW

window size, therefore is the same, making the inductor

current triangle the same in the three cases. The

ISL62883 clamps the ripple capacitor voltage V

mode to make it mimic the inductor current. It takes

the COMP voltage longer to hit V

the switching period. The inductor current triangles

move further apart from each other such that the

inductor current average value is equal to the load

current. The reduced switching frequency helps increase

light load efficiency.

Start-up Timing

With the controller's V

threshold, the start-up sequence begins when VR_ON

exceeds the 3.3V logic high threshold. The ISL62883

uses digital soft start to ramp up DAC to the boot voltage

of 1.1V at about 2.5mV/µs. Once the output voltage is

within 10% of the boot voltage for 13 PWM cycles (43µs

for frequency = 300kHz), CLK_EN# is pulled low and

DAC slews at 5mV/µs to the voltage set by the VID pins.

PGOOD is asserted high in approximately 7ms. Figure 8

shows the typical start-up timing. Similar results occur if

Vcrs

FIGURE 7. PERIOD STRETCHING

CCM/DCM BOUNDARY

LIGHT DCM

DEEP DCM

voltage above the POR

crs

, naturally stretching

crs

FN6891.3

in DE

ISL62883HRTZ Intersil, ISL62883HRTZ Datasheet - Page 12

ISL62883HRTZ

Specifications of ISL62883HRTZ

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