LTC3816_15 Datasheet, PDF(21/44 Page) Linear Technology – Single-Phase Wide VIN Range DC/DC Controller for Intel IMVP-6/IMVP-6.5 CPUs

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LTC3816_15 Datasheet, PDF (21/44 Pages) Linear Technology – Single-Phase Wide VIN Range DC/DC Controller for Intel IMVP-6/IMVP-6.5 CPUs

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LTC3816

APPLICATIONS INFORMATION

to lower the regulator output voltage. This current limit

condition persists until the fault condition disappears or

the controller detects a low output voltage fault and forces

the switcher output to latch off. Once the output voltage

is lower than the power good threshold, the controller

limits the maximum load to 1Ã to reduce the short-circuit

current.

Active Voltage PositioNing (AVP)

In a conventional buck converter, the feedback control

regulates the output voltage to the same level for the

entire load range as shown in Figure 7a. The peak-to-peak

output voltage spikes resulting from the load step must

be smaller than the voltage tolerance window.

To reduce the regulator output voltage peak-to-peak

perturbation resulting from a load transient, the LTC3816

modulates the output voltage based on the output loading

current. The built-in AVP circuit lowers the output voltage

proportional to the load current as shown in Figure 7b.

Figure 7c shows the transient response with the AVP

function. The AVP voltage droop reduces the peak-to-peak

output voltage perturbation. As a result, the AVP topology

requires fewer capacitors at the regulator output to achieve

the same voltage tolerance window.

The AVP circuit obtains the load current information from

the sense resistor or the inductor DCR as shown in Figure 8.

The voltage drop across the sense resistor is extracted

1.03

1.00

0.97

PROGRAMMABLE

AVP SLOPE

â3

0.94

â6

0.91

â9

0.88

â12

5 10 15 20 25 30

ILOAD (A)

3816 F07b

Figure 7b. AVP DC Transfer Curve

VOUT

50mV/DIV

ILOAD

10A/DIV

VSW

20V/DIV

VIN = 12V

VOUT = 1V

ILOAD = 0A TO 20A

20Âµs/DIV

3816 F07c

Figure 7c. Transient Waveform with AVP Slope = â3mV/A, Using

The Same Inductor and Output Capacitor as Figure 7a. The

Transient Peak-to-Peak Perturbation is Reduced to About 85mV

VOUT

50mV/DIV

ILOAD

10A/DIV

VSW

20V/DIV

VIN = 12V

VOUT = 1V

ILOAD = 0A TO 20A

20Âµs/DIV

3816 F07a

Figure 7a. Transient Waveform Without AVP. The Transient

Peak-to-Peak Spike â 130mV. The AITC Amplifier is

Configured as a Unity-Gain Amplifier

by the AITC amplifier and summed with the differential

amplifier output voltage. The resulting output is servoed

to the VID DAC voltage. At higher load current, the volt-

age drop across the sense resistor increases, resulting

in a lower switcher output voltage. Typically, the system

requirement defines the amount of AVP gain ensuring

that the output voltage remains within the regulator sup-

ply tolerance band over the full range of load conditions.

Figure 8 includes the components required to compensate

for the sense resistor parasitic inductance. The AVP DC

transfer function is:

VOUT = VDAC â AAVP(SR) â¢ IL = VDAC â AG(SR) â¢ IL â¢ RSEN

3816f

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