ISL6377 Datasheet, PDF(25/36 Page) Intersil Corporation – Multiphase PWM Regulator for AMD Fusion™ Desktop CPUs Using SVI 2.0

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ISL6377 Datasheet, PDF (25/36 Pages) Intersil Corporation – Multiphase PWM Regulator for AMD Fusion™ Desktop CPUs Using SVI 2.0

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ISL6377

Dynamic Load Line Slope Trim

The ISL6377 supports the SVI2 ability for the processor to

manipulate the load line slope of the Core and Northbridge VRs

independently using the serial VID interface. The slope

manipulation applies to the initial load line slope. A load line

slope trim will typically coincide with a VOTF change. See

Table 10 for more information about the load line slope trim

feature of the ISL6377. The Disable LL selection is not

recommended unless operation without a LL is required and

considered during the compensation of the VR.

TABLE 10. LOAD LINE SLOPE TRIM DEFINITION

LOAD LINE SLOPE TRIM [2:0]

DESCRIPTION

000

Disable LL

001

-40% mâ¦ Change

010

-20% mâ¦ Change

011

No Change

100

+20% mâ¦ Change

101

+40% mâ¦ Change

110

+60% mâ¦ Change

111

+80% mâ¦ Change

Dynamic Offset Trim

The ISL6377 supports the SVI2 ability for the processor to

manipulate the output voltage offset of the Core and Northbridge

VRs. This offset is in addition to any output voltage offset set via

the COMP resistor reader. The dynamic offset trim can disable

the COMP resistor programmed offset of either output when

Disable All Offsetâ is selected.

TABLE 11. OFFSET TRIM DEFINITION

OFFSET TRIM [1:0]

DESCRIPTION

Disable All Offset

-25mV Change

0mV Change

+25mV Change

Telemetry

The ISL6377 can provide voltage and current information to the

AMD CPU through the telemetry system outlined by the AMD

SVI2 specification. The telemetry data is transmitted through the

SVC and SVT lines of the SVI2 interface.

Current telemetry is based on a voltage generated across a

133kâ¦ resistor placed from the IMON pin to GND. The current

flowing out of the IMON pin is proportional to the load current in

the VR. The Isum current defined in âVoltage Regulation and Load

Line Implementationâ on page 15, provides the base conversion

from the load current to the internal amplifier created Isum

current. The Isum current is then divided down by a factor of 4 to

create the IMON current which flows out of the IMON pin. The

Isum current will measure 36ÂµA when the load current is at full

load based on a droop current designed for 45ÂµA at the same

load current. The difference between the Isum current and the

droop current is provided in Equation 2. The IMON current will

measure 11.25ÂµA at full load current for the VR and the IMON

voltage will be 1.2V. The load percentage which is reported by the

IC is based on the this voltage. When the load is 25% of the full

load, the voltage on the IMON pin will be 25% of 1.2V or 0.3V.

The SVI interface allows the selection of no telemetry, voltage

only, or voltage and current telemetry on either or both of the VR

outputs. The TFN bit along with the Core and Northbridge domain

selector bits are used by the processor to change the

functionality of telemetry, see Table 12 for more information.

TFN, Core, NB

BITS [21,6,7]

1,0,1

TABLE 12. TFN TRUTH TABLE

DESCRIPTION

Telemetry is in voltage and current mode. Therefore,

voltage and current are sent for VDD and VDDNB

domains by the controller.

1,0,0

1,1,0

Telemetry is in voltage mode only. Only the voltage of

VDD and VDDNB domains is sent by the controller.

Telemetry is disabled.

1,1,1

Reserved

Protection Features

Core VR and Northbridge VR both provide overcurrent,

current-balance, undervoltage, and overvoltage fault protections.

The controller also provides over-temperature protection. The

following discussion is based on Core VR and also applies to the

Northbridge VR.

Overcurrent

The IMON voltage provides a means of determining the load

current at any moment in time. The overcurrent protection (OCP)

circuitry monitors the IMON voltage to determine when a fault

occurs. Based on the previous description in âVoltage Regulation

and Load Line Implementationâ on page 15, the current which

flows out of the IMON pin is proportional to the Isum current. The

Isum current is created from the sensed voltage across Cn which is

a measure of the load current based upon the sensing element

selected. The IMON current is generated internally and is 1/4 of

the Isum current. The EDC or IDDspike current value for the AMD

CPU load is used to set the maximum current level for droop and

the IMON voltage of 1.2V which indicates 100% loading for

telemetry. The Isum current level at maximum load, or IDDspike, is

36ÂµA and this translates to an IMON current level of 9ÂµA. The

IMON resistor is 133kâ¦ and the 9ÂµA flowing through the IMON

resistor results in a 1.2V level at maximum loading of the VR.

The overcurrent threshold is 1.5V on the IMON pin. Based on a

1.2V IMON voltage equating to 100% loading, the additional 0.3V

provided above this level equates to a 25% increase in load current

before an OCP fault is detected. The EDC or IDDspike current is

used to set the 1.2V on IMON for full load current. So the OCP level

is 1.25 times the EDC or IDDspike current level. This additional

margin above the EDC or IDDspike current allows the AMD CPU to

enter and exit the IDDspike performance mode without issue

unless the load current is out of line with the IDDspike expectation,

thus the need for overcurrent protection.

FN8336.0

August 6, 2012

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