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ISL6312A_15 Datasheet, PDF (25/36 Pages) Intersil Corporation – Four-Phase Buck PWM Controller with Integrated MOSFET Drivers for Intel VR10,VR11, and AMD Applications
ISL6312A
Fault Monitoring and Protection
The ISL6312A actively monitors output voltage and current
to detect fault conditions. Fault monitors trigger protective
measures to prevent damage to a microprocessor load. One
common power-good indicator is provided for linking to
external system monitors. The schematic in Figure 14
outlines the interaction between the fault monitors and the
power-good signal.
125µA
IAVG
-
OCP
+
VRSEL
OVPSEL
VDAC
+175mV,
+250mV,
+350mV
VOVP
-
OCL
+
170µA
I1
REPEAT FOR
EACH CHANNEL
+
OCP
-
IOUT
VOCP
SOFT-START, FAULT
AND CONTROL LOGIC
VSEN
+
x1
-
RGND
-
OV
+
-
UV
+
PGOOD
VDIFF
0.60 x DAC ISL6312A INTERNAL CIRCUITRY
FIGURE 14. POWER-GOOD AND PROTECTION CIRCUITRY
Power-Good Signal
The power-good pin (PGOOD) is an open-drain logic output
that signals whether or not the ISL6312A is regulating the
output voltage within the proper levels, and whether any fault
conditions exist.This pin should be tied to a +5V source
through a resistor.
During shutdown and soft-start PGOOD pulls low and
releases high after a successful soft-start and the output
voltage is operating between the undervoltage and
overvoltage limits. PGOOD transitions low when an
undervoltage, overvoltage, or overcurrent condition is
detected or when the controller is disabled by a reset from
EN, EN_PH4, POR, or one of the no-CPU VID codes. In the
event of an overvoltage or overcurrent condition, the
controller latches off and PGOOD will not return high until
after a successful soft-start. In the case of an undervoltage
event, PGOOD will return high when the output voltage
returns to within the undervoltage.
Overvoltage Protection
The ISL6312A constantly monitors the sensed output voltage
on the VDIFF pin to detect if an overvoltage event occurs.
When the output voltage rises above the OVP trip level actions
are taken by the ISL6312A to protect the microprocessor load.
The overvoltage protection trip level changes depending on
what mode of operation the controller is in and what state the
OVPSEL and VRSEL pins are in. Tables 6 and 7 list what the
OVP trip levels are under all conditions.
At the inception of an overvoltage event, LGATE1, LGATE2
and LGATE3 are commanded high, PWM4 is commanded
low, and the PGOOD signal is driven low. This turns on the
all of the lower MOSFETs and pulls the output voltage below
a level that might cause damage to the load. The LGATE
outputs remain high and PWM4 remains low until VDIFF falls
100mV below the OVP threshold that tripped the overvoltage
protection circuitry. The ISL6312A will continue to protect the
load in this fashion as long as the overvoltage condition
recurs. Once an overvoltage condition ends the ISL6312A
latches off, and must be reset by toggling EN, or through
POR, before a soft-start can be reinitiated.
TABLE 6. INTEL VR10 AND VR11 OVP THRESHOLDS
MODE OF
OPERATION
OVPSEL PIN OPEN OVPSEL PIN TIED
OR TIED TO GND
TO VCC
Soft-Start
(TD1 and TD2)
1.280V and
VDAC + 175mV
(higher of the two)
1.280V and
VDAC + 350mV
(higher of the two)
Soft-Start
(TD3 and TD4)
VDAC + 175mV
VDAC + 350mV
Normal Operation
VDAC + 175mV
VDAC + 350mV
TABLE 7. AMD OVP THRESHOLDS
MODE OF
OPERATION
OVPSEL PIN OPEN OVPSEL PIN TIED
OR TIED TO GND
TO VCC
Soft-Start
2.200V and
VDAC + 250mV
(higher of the two)
2.200V and
VDAC + 350mV
(higher of the two)
Normal Operation
VDAC + 250mV
VDAC + 350mV
One exception that overrides the overvoltage protection
circuitry is a dynamic VID transition in AMD modes of operation.
If a new VID code is detected during normal operation, the OVP
protection circuitry is disabled from the beginning of the
dynamic VID transition, until 50µs after the internal DAC
reaches the final VID setting. This is the only time during
operation of the ISL6312A that the OVP circuitry is not active.
Pre-POR Overvoltage Protection
Prior to PVCC and VCC exceeding their POR levels, the
ISL6312A is designed to protect the load from any
overvoltage events that may occur. This is accomplished by
means of an internal 10k resistor tied from PHASE to
LGATE, which turns on the lower MOSFET to control the
output voltage until the overvoltage event ceases or the input
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FN9290.6
January 22, 2015