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ISL6267 Datasheet, PDF (20/33 Pages) Intersil Corporation – Multiphase PWM Regulator for AMD Fusion Mobile CPUs
ISL6267
Rdroop
+Vdroop-
FB
COMP
+
E/A
-
Idroop
Σ
DAC
VDAC
+
INTERNAL TO IC
+
X1
-
VCCSENSE
VR LOCAL VO
“CATCH” RESISTOR
VIDs
VID<0:7>
RTN
VSSSENSE
VSS
“CATCH” RESISTOR
FIGURE 15. DIFFERENTIAL SENSING AND LOAD LINE
IMPLEMENTATION
As the load current increases from zero, the output voltage
droops from the VID table value by an amount proportional to the
load current, to achieve the load line. The ISL6267 can sense the
inductor current through the intrinsic DC Resistance (DCR) of the
inductors, as shown in Figures 15 and 16, or through resistors in
series with the inductors as shown in Figure 17. In both methods,
capacitor Cn voltage represents the inductor total currents. A
droop amplifier converts Cn voltage into an internal current
source with the gain set by resistor Ri. The current source is used
for load line implementation, current monitoring and overcurrent
protection.
Figure 15 shows the load-line implementation. The ISL6267
drives a current source (Idroop) out of the FB pin, as described by
Equation 1.
Idroop
=
2----x----V---C----n-
Ri
(EQ. 1)
When using inductor DCR current sensing, a single NTC element
is used to compensate the positive temperature coefficient of the
copper winding, thus sustaining the load-line accuracy with
reduced cost.
Idroop flows through resistor Rdroop and creates a voltage drop as
shown in Equation 2.
Vdroop = Rdroop × Idroop
(EQ. 2)
Vdroop is the droop voltage required to implement load line.
Changing Rdroop or scaling Idroop can change the load line slope.
Since Idroop also sets the overcurrent protection level, it is
recommended to first scale Idroop based on OCP requirement,
then select an appropriate Rdroop value to obtain the desired
load line slope.
Differential Sensing
Figure 15 also shows the differential voltage sensing scheme.
VCCSENSE and VSSSENSE are the remote voltage sensing signals
from the processor die. A unity gain differential amplifier senses
the VSSSENSE voltage and adds it to the DAC output. The error
amplifier regulates the inverting and non-inverting input voltages
to be equal as shown in Equation 3:
V
CCSE
NSE
+
V
dr
o
o
p
=
VDAC + VSSSENSE
(EQ. 3)
Rewriting Equation 3 and substituting Equation 2 gives
Equation 4 is the exact equation required for load-line
implementation.
VCCSENSE – VSSSENSE = VDAC – Rdroop × Idroop
(EQ. 4)
The VCCSENSE and VSSSENSE signals come from the processor die.
The feedback is, open circuit in the absence of the processor. As
Figure 15 shows, it is recommended to add a “catch” resistor to feed
the VR local output voltage back to the compensator, and to add
another “catch” resistor to connect the VR local output ground to the
RTN pin. These resistors, typically 10Ω~100Ω, provide voltage
feedback if the system is powered up without a processor installed.
Phase Current Balancing
ISEN3
INTERNAL
INTERNAL
TO IC
ISEN2
PHASE3
Risen
Cisen
PHASE2
Risen
Cisen
ISEN1
PHASE1
Risen
Cisen
L3
Rdcr3 Rpcb3
IL3
L2
Rdcr2 Rpcb2
VO
IL2
L1
Rdcr1 Rpcb1
IL1
FIGURE 16. CURRENT BALANCING CIRCUIT
The ISL6267 monitors individual phase average current by
monitoring the ISEN1, ISEN2, and ISEN3 voltages. Figure 16
shows the current balancing circuit recommended for ISL6267.
Each phase node voltage is averaged by a low-pass filter
consisting of Risen and Cisen, and is presented to the
corresponding ISEN pin. Risen should be routed to the inductor
phase-node pad in order to eliminate the effect of phase node
parasitic PCB DCR. Equations 5 through 7 give the ISEN pin
voltages:
VISEN1 = (Rdcr1 + Rpcb1) × IL1
(EQ. 5)
VISEN2 = (Rdcr2 + Rpcb2) × IL2
(EQ. 6)
VISEN3 = (Rdcr3 + Rpcb3) × IL3
(EQ. 7)
where Rdcr1, Rdcr2 and Rdcr3 are inductor DCR; Rpcb1, Rpcb2
and Rpcb3 are parasitic PCB DCR between the inductor output
side pad and the output voltage rail; and IL1, IL2 and IL3 are
inductor average currents.
20
January 31, 2011
FN7801.0