MAXIM MAX17582GTM+

19-4821; Rev 0; 7/09
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
LX2
DH2
PGND2
DL2
VRHOT
VDD
DL1
PGND1
IMVP-6.5 Core Supply
LX1
TOP VIEW
BST1
Applications
Pin Configuration
DH1
The MAX17582 is a 2-/1-phase-interleaved QuickPWM™ step-down VID power-supply controller for
notebook CPUs. True out-of-phase operation reduces
input-ripple-current requirements and output-voltage
ripple, while easing component selection and layout difficulties. The Quick-PWM control provides instantaneous response to fast load-current steps. Active
voltage positioning reduces power dissipation and bulk
output capacitance requirements and allows ideal positioning compensation for tantalum, polymer, or ceramic
bulk output capacitors.
A slew-rate controller allows controlled transitions among
VID codes, controlled soft-start and shutdown, and controlled exit from suspend. A thermistor-based temperature
sensor provides a programmable thermal-fault output
(VRHOT). A current-monitor output (IMON) provides an
analog current output proportional to the power consumed
by the CPU. The MAX17582 includes output undervoltage and thermal protection. When any of these protection features detect a fault, the controller shuts down. A
voltage-regulator power-OK (PWRGD) output indicates
the output is in regulation. Additionally, the MAX17582
features true differential current sense and a phase-good
(PHASEGD) output that indicates a phase imbalance
fault condition.
The MAX17582 implements the Intel IMVP-6.5 VID code
set. The MAX17582 is available in a 6mm x 6mm,
48-pin TQFN package.
Features
o Single-/Dual-Phase, Quick-PWM Controller
o ±8mV VOUT Accuracy Over Line, Load, and
Temperature
o 7-Bit 0 to 1.50V VID Control
o Dynamic Phase Selection Optimizes Active/Sleep
Efficiency
o Transient Phase Overlap Reduces Output
Capacitance
o Integrated Boost Switches
o Active Voltage Positioning with Adjustable Gain
o Programmable 200kHz to 800kHz Switching
Frequency
o Accurate Current Balance and Current Limit
o Adjustable Slew-Rate Control
o Power-Good, Clock Enable, and Thermal-Fault
Outputs
o Phase Current Imbalance Fault Output
o Drives Large Synchronous Rectifier MOSFETs
o 4V to 26V Battery Input-Voltage Range
o Undervoltage and Thermal-Fault Protection
o IMVP-6.5 Power Sequencing and Timing
Compliant
o Soft-Startup and Soft-Shutdown
36 35 34 33 32 31 30 29 28 27 26 25
Multiphase CPU Core Supply
Voltage-Positioned, Step-Down Converters
24 N.C.
N.C. 37
23 PHASEGD
SLOW 38
Notebook/Desktop Computers
D0 39
22 PWRGD
Blade Servers
D1 40
21 CLKEN
D2 41
20 V3P3
Ordering Information
D3 42
19 TON
MAX17582
D4 43
PART
MAX17582GTM+
TEMP RANGE
PIN-PACKAGE
D5 44
-40°C to +105°C
48 TQFN-EP*
D6 45
+Denotes a lead(Pb)-free/RoHS-compliant package.
*EP = Exposed pad.
18 PSI
17 DPRSLPVR
16 SHDN
CSP1 46
GND 47
15 CSP2
*EP
GND
+
14 GND
CSN1 48
10 11 12
N.C.
9
GNDS
8
FBAC
ILIM
7
FB
IMON
6
CCI
THRM
5
VCC
4
GND
3
TIME
2
PGDIN
13 CSN2
1
THIN QFN
(6mm x 6mm)
Quick-PWM is a trademark of Maxim Integrated Products, Inc.
*EXPOSED PAD. CONNECTED TO GND.
________________________________________________________________ Maxim Integrated Products
1
For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642,
or visit Maxim’s website at www.maxim-ic.com.
MAX17582
General Description
BST2
KIT
ATION
EVALU
LE
B
A
IL
A
AV
MAX17582
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
ABSOLUTE MAXIMUM RATINGS
VCC, VDD, V3P3 to GND ...........................................-0.3V to +6V
D0–D6 to GND..........................................................-0.3V to +6V
PGDIN, DPRSLPVR, PSI to GND..............................-0.3V to +6V
SLOW to GND ..........................................................-0.3V to +6V
CSP1, CSP2, CSN1, CSN2 to GND..........................-0.3V to +6V
THRM, ILIM, PHASEGD to GND...............................-0.3V to +6V
PWRGD, VRHOT to GND .........................................-0.3V to +6V
CLKEN to GND .........................................(-0.3V to V3P3) + 0.3V
FB, FBAC to GND.......................................(-0.3V to VCC) + 0.3V
TIME, IMON, CCI to GND ...........................(-0.3V to VCC) + 0.3V
PGND, GNDS to GND ...........................................-0.3V to +0.3V
SHDN to GND (Note 1)...........................................-0.3V to +16V
TON to GND ...........................................................-0.3V to +30V
DL1, DL2 to GND .......................................-0.3V to (VDD + 0.3V)
BST1, BST2 to GND ...............................................-0.3V to +36V
BST1, BST2 to VDD .................................................-0.3V to +30V
LX1 to BST1..............................................................-6V to +0.3V
LX2 to BST2..............................................................-6V to +0.3V
DH1 to LX1 ..............................................(-0.3V to VBST1) + 0.3V
DH2 to LX2 ..............................................(-0.3V to VBST2) + 0.3V
Continuous Power Dissipation
6mm x 6mm, 48-Pin TQFN Up to +70°C ...................2105mW
(derate above +70°C) ...........................................26.3mW/°C
Operating Temperature Range .........................-40°C to +105°C
Junction Temperature ......................................................+150°C
Storage Temperature Range .............................-65°C to +165°C
Lead Temperature (soldering, 10s) .................................+300°C
Note 1: SHDN might be forced to 12V for the purpose of debugging prototype boards using the no-fault test mode, which disables
fault protection and overlapping operation.
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
ELECTRICAL CHARACTERISTICS
(Circuit of Figure 1, VIN = 10V, VCC = VDD = VSHDN = VPGDIN = VPSI = VILIM = 5V, V3P3 = 3.3V, DPRSLPVR = GNDS = GND, VCSP1
= VCSN1 = VCSP2 = VCSN1 = 1.0000V, FB = FBAC, RFBAC = 3.57kΩ from FBAC to CSN1, D6–D0 = [0101000]; VSLOW = 5V; TA = 0°C
to +85°C, unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
PWM CONTROLLER
Input-Voltage Range
DC Output-Voltage
Accuracy
Boot Voltage
VOUT
VCC, VDD
4.5
5.5
V3P3
3.0
3.6
DAC codes from 0.8125V
to 1.5000V
-0.5
+0.5
DAC codes from 0.3750V
to 0.8000V
-7
+7
Measured at FB
with respect to
GNDS;
includes loadregulation error
(Note 2)
VBOOT
-20
1.094
VCC = 4.5V to 5.5V, VIN = 4.5V to 26V
FB Input Bias Current
TA = +25°C
+20
1.100
1.106
0.1
-0.1
A GNDS
VOUT/VGNDS
0.97
GNDS Input Bias Current
IGNDS
TA = +25°C
-0.5
TIME Regulation Voltage
VTIME
RTIME = 71.5k
1.985
1.00
2.000
_______________________________________________________________________________________
V
%
+0.1
-200
GNDS Gain
2
%
mV
DAC codes from 0 to
0.3625V
Line Regulation Error
GNDS Input Range
V
μA
+200
mV
1.03
V/V
+0.5
μA
2.015
V
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
(Circuit of Figure 1, VIN = 10V, VCC = VDD = VSHDN = VPGDIN = VPSI = VILIM = 5V, V3P3 = 3.3V, DPRSLPVR = GNDS = GND, VCSP1
= VCSN1 = VCSP2 = VCSN1 = 1.0000V, FB = FBAC, RFBAC = 3.57kΩ from FBAC to CSN1, D6–D0 = [0101000]; VSLOW = 5V; TA = 0°C
to +85°C, unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER
SYMBOL
TIME Slew-Rate Accuracy
On-Time
t ON
CONDITIONS
MIN
TYP
MAX
RTIME = 71.5k (12.5mV/μs nominal)
-10
+10
RTIME = 35.7k (25mV/μs nominal) to 178k
(5mV/μs nominal)
-15
+15
Soft-start and soft-shutdown:
RTIME = 35.7k (3.125mV/μs nominal) to 178k
(0.625mV/μs nominal)
-25
+25
%
Slow:
V SLOW = 0V,
1/2 of nominal slew rate, RTIME = 71.5k
(6.25mV/μs nominal)
-15
+15
Slow:
V SLOW = 0V, 1/2 of nominal slew rate, RTIME =
35.7k (12.5mV/μs nominal) to 178k (2.5mV/μs
nominal)
-15
+15
RTON = 96.75k (600kHz per phase),
167ns nominal
-15
+15
RTON = 200k (300kHz per phase),
333ns nominal
-10
+10
RTON = 303.25k (200kHz per phase),
500ns nominal
-15
+15
Measured
at DH_
(Note 3)
UNITS
%
Minimum Off-Time
t OFF(MIN)
Measured at DH_ (Note 3)
300
350
ns
TON Shutdown Input
Current
IRTON,SDN
SHDN = GND, VIN = 26V, VCC = VDD = 0V or 5V,
TA = +25°C
0.01
0.1
μA
BIAS CURRENTS
Quiescent Supply Current
(VCC)
ICC
Measured at VCC, VDPRSLPVR = 5V, FB forced
above the regulation point
2.5
5
mA
Quiescent Supply Current
(VDD)
IDD
Measured at VDD, VDPRSLPVR = 0V, FB forced
above the regulation point, TA = +25°C
0.02
1
μA
Quiescent Supply Current
(V3P3)
I3P3
Measured at V3P3, FB forced within the CLKEN
power-good window
2
4
μA
Shutdown Supply Current
(VCC)
ICC,SDN
Measured at VCC, SHDN = GND, TA = +25°C
0.01
1
μA
Shutdown Supply Current
(VDD)
IDD,SDN
Measured at VDD, SHDN = GND, TA = +25°C
0.01
1
μA
Shutdown Supply Current
(V3P3)
I3P3,SDN
Measured at V3P3, SHDN = GND, TA = +25°C
0.01
1
μA
_______________________________________________________________________________________
3
MAX17582
ELECTRICAL CHARACTERISTICS (continued)
MAX17582
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
ELECTRICAL CHARACTERISTICS (continued)
(Circuit of Figure 1, VIN = 10V, VCC = VDD = VSHDN = VPGDIN = VPSI = VILIM = 5V, V3P3 = 3.3V, DPRSLPVR = GNDS = GND, VCSP1
= VCSN1 = VCSP2 = VCSN1 = 1.0000V, FB = FBAC, RFBAC = 3.57kΩ from FBAC to CSN1, D6–D0 = [0101000]; VSLOW = 5V; TA = 0°C
to +85°C, unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
Output UndervoltageProtection Threshold
VUVP
Measured at FB with respect to the voltage target
set by the VID code; see Table 4
-450
-400
-350
mV
Output UndervoltagePropagation Delay
tUVP
FB forced 25mV below trip threshold
FAULT PROTECTION
CLKEN Startup Delay and
Boot Time Period
10
μs
Measured from the time when FB reaches the
boot target voltage (Note 2)
20
60
100
μs
PWRGD Startup Delay
Measured at startup from the time when CLKEN
goes low
3
6.5
10
ms
Lower threshold,
falling edge
(undervoltage)
-350
-300
-250
CLKEN and PWRGD
Threshold
Measured at FB with respect
to the voltage target set by
the VID code; see Table 4,
20mV hysteresis (typ)
Upper threshold,
rising edge
(overvoltage)
+150
tBOOT
mV
+200
+250
CLKEN and PWRGD Delay
FB forced 25mV outside the PWRGD trip
thresholds
10
μs
PHASEGD Delay
V(CCI,FB) forced 25mV outside trip thresholds
10
μs
Measured from the time when FB reaches the
target voltage (Note 2)
20
μs
PHASEGD Transition
Blanking Time (Phase 2
Enable Transitions)
Number of DH2 pulses for which PHASEGD is
blanked after phase 2 is enabled
32
Pulses
CLKEN Output Low Voltage
Low state, ISINK = 3mA
CLKEN, PWRGD, and
PHASEGD Transition
Blanking Time
(VID Transitions)
tBLANK
CLKEN Output High
Voltage
High state, I SOURCE = 3mA
PWRGD, PHASEGD Output
Low Voltage
Low state, I SINK = 3mA
PWRGD, PHASEGD
Leakage Current
High-impedance state, PWRGD, PHASEGD forced
to 5V, TA = +25°C
CSN1 Pulldown Resistance
in Shutdown
SHDN = 0, measured after soft-shutdown
completed (DL_ = low)
VCC Undervoltage Lockout
(UVLO) Threshold
4
VUVLO(VCC)
Rising edge, 65mV typical hysteresis,
controller disabled below this level
0.4
V3P3 0.4
V
0.4
V
1
μA
10
4.05
V
4.27
_______________________________________________________________________________________
4.48
V
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
(Circuit of Figure 1, VIN = 10V, VCC = VDD = VSHDN = VPGDIN = VPSI = VILIM = 5V, V3P3 = 3.3V, DPRSLPVR = GNDS = GND, VCSP1
= VCSN1 = VCSP2 = VCSN1 = 1.0000V, FB = FBAC, RFBAC = 3.57kΩ from FBAC to CSN1, D6–D0 = [0101000]; VSLOW = 5V; TA = 0°C
to +85°C, unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
29
30
31
%
THERMAL PROTECTION
Measured at THRM as a percentage of VCC,
falling edge, typical hysteresis = 75mV
VRHOT Trip Threshold
VRHOT Delay
t VRHOT
VRHOT Output
On-Resistance
THRM forced 25mV below the VRHOT trip
threshold, falling edge
10
R ON(VRHOT) Low state
2
High-impedance state, VRHOT forced to 5V,
TA = +25°C
VRHOT Leakage Current
THRM Input Leakage
ITHRM
Thermal-Shutdown Threshold
T SHDN
VTHRM = 0 to 5V, TA = +25°C
Typical hysteresis = 15°C
-0.1
μs
10
1
μA
+0.1
μA
160
°C
VALLEY CURRENT LIMIT, DROOP, AND CURRENT BALANCE
Current-Limit Threshold
Voltage (Positive)
VLIMIT
Current-Limit Threshold
Voltage (Negative)
Accuracy
VLIMIT(NEG)
Current-Limit Threshold
Voltage (Zero Crossing)
VZERO
VCSP_ - VCSN_
VTIME - VILIM = 100mV
7
10
13
VTIME - VILIM = 500mV
45
50
55
ILIM = VCC
20
22.5
25
VCSP_ - VCSN_, nominally -125% of VLIMIT
VGND - VLX_, DPRSLPVR = 5V
0
Phase 2 Disable Threshold
ILIM Input Current
Droop Amplifier Offset
Gm(FBAC)
Current-Balance Amplifier
Offset
Current-Balance Amplifier
Transconductance
Gm(CCI)
mV
V
VCC 0.4
V
-0.2
+0.2
μA
-0.1
+0.1
μA
TA = +25oC
-0.5
+0.5
TA = 0oC to +85oC
-0.75
+0.75
3
ICSP_, ICSN_ TA = +25°C
TA = +25°C
(1/N) x (VCSP_ - VCSN_) at
IFBAC = 0;
indicates summation over
all phases from 1 to N, N = 2
mV
2
Measured at CSP2
I ILIM
Droop Amplifier
Transconductance
+4
1
CSP_, CSN_ CommonMode Input Range
CSP_, CSN_ Input Current
-4
mV
IFBAC/[ (VCSP_ - VCSN_)];
indicates summation over all phases from 1 to
N, N = 2, VFBAC = VCSN- = 0.45V to 2V
590
(VCSP1 - VCSN1) - (VCSP2 - VCSN2) at ICCI = 0V
-1.0
ICCI/[(VCSP1 - VCSN1) - (VCSP2 - VCSN2)]
VCC 1
600
200
mV/
phase
608
μS
+1.0
mV
μS
_______________________________________________________________________________________
5
MAX17582
ELECTRICAL CHARACTERISTICS (continued)
MAX17582
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
ELECTRICAL CHARACTERISTICS (continued)
(Circuit of Figure 1, VIN = 10V, VCC = VDD = VSHDN = VPGDIN = VPSI = VILIM = 5V, V3P3 = 3.3V, DPRSLPVR = GNDS = GND, VCSP1
= VCSN1 = VCSP2 = VCSN1 = 1.0000V, FB = FBAC, RFBAC = 3.57kΩ from FBAC to CSN1, D6–D0 = [0101000]; VSLOW = 5V; TA = 0°C
to +85°C, unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
93.12
96
98.88
μA
2.2
2.4
2.6
mS
1.05
1.10
1.15
V
CURRENT MONITOR
Current-Monitor Output
Current at Full Load
Condition
Current-Monitor
Transconductance
IMON Clamp Voltage
I IMON
Gm(IMON)
VIMON,MAX
VCSP1 - VCSN1 = VCSP2 - VCSN2 = 20mV,
VCSN_ = 0.45V to 2.0V
I IMON/[ (VCSP_ - VCSN_)];
indicates summation over all phases from 1 to
N, N = 2, CSN_ = 0.45V to 2V
I SINK = 10mA
SHDN = 0, measured after soft-shutdown
completed (DL_ = low)
IMON Pulldown Resistance
in Shutdown
10
GATE DRIVERS
DH_ Gate Driver
On-Resistance
R ON(DH_)
DL_ Gate Driver
On-Resistance
R ON(DL_)
DH_ Gate Driver Source
Current
DH_ Gate Driver Sink
Current
DL_ Gate Driver Source
Current
BST_ - LX_ forced to 5V
High state (pullup)
0.9
2.5
Low state (pulldown)
0.7
2.0
High state (pullup)
0.7
2.0
Low state (pulldown)
0.25
0.7
IDH_(SOURCE) DH_ forced to 2.5V, BST_ - LX_ forced to 5V
IDH_(SINK)
DH_ forced to 2.5V, BST_ - LX_ forced to 5V
IDL_(SOURCE) DL_ forced to 2.5V
DL_ Gate Driver Sink
Current
IDL_(SINK)
Internal BST_ Switch
On-Resistance
R ON(BST_)
DL_ forced to 2.5V
2.2
A
2.7
A
2.7
A
8
A
10
20
1.0
V
13
V
LOGIC AND I/O
Logic Input High Voltage
VIH
SHDN, PGDIN
Logic Input Low Voltage
VIL
SHDN, PGDIN
SHDN No-Fault Level
To enable no-fault mode
Low-Voltage Logic Input
High Voltage
VIHLV
PSI, D0–D6; DPRSLPVR, SLOW
Low-Voltage Logic Input
Low Voltage
VILLV
PSI, D0–D6; DPRSLPVR, SLOW
Logic Input Current
6
TA = +25°C, SHDN, DPRSLPVR, PGDIN, PSI,
SLOW, D0–D6 = 0 or 5V
2.3
11
V
0.67
-1
_______________________________________________________________________________________
V
0.33
V
+1
μA
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
(Circuit of Figure 1, VIN = 10V, VCC = VDD = VSHDN = VPGDIN = VPSI = VILIM = 5V, V3P3 = 3.3V, DPRSLPVR = GNDS = GND, VCSP1
= VCSN1 = VCSP2 = VCSN2 = 1.0000V, FB = FBAC, RFBAC = 3.57kΩ from FBAC to CSN1, D6–D0 = [0101000]; VSLOW = 5V; TA =
-40°C to +105°C, unless otherwise noted.) (Note 4)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
PWM CONTROLLER
Input-Voltage Range
VCC, VDD
4.5
5.5
V3P3
3.0
3.6
-0.75
+0.75
-10
+10
DAC codes from
0.8125V to 1.5000V
DC Output-Voltage
Accuracy
VOUT
Boot Voltage
Measured at FB with
respect to GNDS;
DAC codes from
includes load0.3750V to 0.8000V
regulation error (Note 2)
DAC codes from 0 to
0.3625V
VBOOT
A GNDS
TIME Regulation Voltage
VTIME
TIME Slew-Rate Accuracy
t ON
Minimum Off-Time
t OFF(MIN)
mV
-25
+25
1.09
1.11
V
+200
mV
VOUT/VGNDS
0.97
1.03
V/V
RTIME = 71.5k
V
1.985
2.015
RTIME = 71.5k (12.5mV/μs nominal)
-10
+10
RTIME = 35.7k (25mV/μs nominal) to 178k
(5mV/μs nominal)
-15
+15
Soft-start and soft-shutdown:
RTIME = 35.7k (3.125mV/μs nominal) to 178k
(0.625mV/μs nominal)
-25
+25
Slow:
V SLOW = 0V,
1/2 of nominal slew rate, RTIME = 71.5k
(6.25mV/μs nominal)
-15
+15
Slow:
V SLOW = 0V,
1/2 of nominal slew rate, RTIME = 35.7k
(12.5mV/μs nominal) to 178k (2.5mV/μs nominal)
-17
+17
-15
+15
-15
+15
-15
+15
RTON = 96.75k (600kHz per phase),
167ns nominal
On-Time
%
-200
GNDS Input Range
GNDS Gain
V
Measured
RTON = 200k (300kHz per phase),
at DH_
333ns nominal
(Note 3)
RTON = 303.25k (200kHz per phase),
500ns nominal
Measured at DH_ (Note 3)
%
%
350
ns
BIAS CURRENTS
Quiescent Supply Current
(VCC)
ICC
Measured at VCC, VDPRSLPVR = 5V, FB forced
above the regulation point
5
mA
Quiescent Supply Current
(V3P3)
I3P3
Measured at V3P3, FB forced within the CLKEN
power-good window
4
μA
_______________________________________________________________________________________
7
MAX17582
ELECTRICAL CHARACTERISTICS
MAX17582
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
ELECTRICAL CHARACTERISTICS (continued)
(Circuit of Figure 1, VIN = 10V, VCC = VDD = VSHDN = VPGDIN = VPSI = VILIM = 5V, V3P3 = 3.3V, DPRSLPVR = GNDS = GND, VCSP1
= VCSN1 = VCSP2 = VCSN2 = 1.0000V, FB = FBAC, RFBAC = 3.57kΩ from FBAC to CSN1, D6–D0 = [0101000]; VSLOW = 5V; TA =
-40°C to +105°C, unless otherwise noted.) (Note 4)
PARAMETER
SYMBOL
CONDITIONS
MIN
Output UndervoltageProtection Threshold
VUVP
Measured at FB with respect to the voltage target
set by the VID code; see Table 4
CLKEN Startup Delay and
Boot Time Period
tBOOT
TYP
MAX
UNITS
-450
-350
mV
Measured from the time when FB reaches the
boot target voltage (Note 3)
20
100
μs
PWRGD Startup Delay
Measured at startup from the time when CLKEN
goes low
3
10
ms
CLKEN and PWRGD
Threshold
Measured at FB with
respect to the voltage
target set by the VID
code; see Table 4,
20mV hysteresis (typ)
-350
-250
FAULT PROTECTION
Lower threshold, falling
edge (undervoltage)
mV
Upper threshold, rising
edge (overvoltage)
CLKEN Output Low Voltage
Low state, ISINK = 3mA
CLKEN Output High
Voltage
High state, I SOURCE = 3mA
PWRGD, PHASEGD Output
Low Voltage
Low state, I SINK = 3mA
VCC Undervoltage-Lockout
Threshold (UVLO)
VUVLO(VCC)
+150
+250
0.4
V3P3 0.4
V
V
0.4
V
Rising edge, 65mV typical hysteresis, controller
disabled below this level
4.0
4.5
V
Measured at THRM as a percentage of VCC,
falling edge, typical hysteresis = 75mV
28
32
%
10
THERMAL PROTECTION
VRHOT Trip Threshold
VRHOT Output
On-Resistance
R ON(VRHOT) Low state
VALLEY CURRENT LIMIT, DROOP, AND CURRENT BALANCE
Current-Limit Threshold
Voltage (Positive)
VLIMIT
VTIME - VILIM = 100mV
7
13
VTIME - VILIM = 500mV
40
60
ILIM = VCC
19
26
0
2
V
IFBAC/[(VCSP_ - VCSN_)],
indicates summation over all phases from 1 to
N, N = 2, VFBAC = VCSN- = 0.45V to 2V
585
610
μS
(VCSP1 - VCSN1) - (VCSP2 - VCSN2) at ICCI = 0V
-1.25
+1.25
mV
VCSP_ - VCSN_
CSP_, CSN_ Common-Mode
Input Range
Droop Amplifier
Transconductance
Current-Balance Amplifier
Offset
8
Gm(FBAC)
_______________________________________________________________________________________
mV
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
(Circuit of Figure 1, VIN = 10V, VCC = VDD = VSHDN = VPGDIN = VPSI = VILIM = 5V, V3P3 = 3.3V, DPRSLPVR = GNDS = GND, VCSP1
= VCSN1 = VCSP2 = VCSN2 = 1.0000V, FB = FBAC, RFBAC = 3.57kΩ from FBAC to CSN1, D6–D0 = [0101000]; VSLOW = 5V; TA =
-40°C to +105°C, unless otherwise noted.) (Note 4)
PARAMETER
SYMBOL
CONDITIONS
MIN
Gm(IMON)
I IMON/[(VCSP_ - VCSN_)],
indicates summation over all phases from 1 to
N, N = 2, VCSN_ = 0.45V to 2V
I SINK = 10mA
TYP
MAX
UNITS
2.2
2.6
mS
1.05
1.15
V
CURRENT MONITOR
Current-Monitor
Transconductance
IMON Clamp Voltage
VIMON,MAX
GATE DRIVERS
DH_ Gate Driver
On-Resistance
R ON(DH_)
DL_ Gate Driver
On-Resistance
R ON(DL_)
BST_ - LX_ forced to 5V
High state (pullup)
2.5
Low state (pulldown)
2.0
High state (pullup)
2.0
Low state (pulldown)
0.7
LOGIC AND I/O
Logic Input High Voltage
VIH
SHDN, PGDIN
Logic Input Low Voltage
VIL
SHDN, PGDIN
Low-Voltage Logic Input
High Voltage
VIHLV
PSI, D0–D6: DPRSLPVR, SLOW
Low-Voltage Logic Input
Low Voltage
VILLV
PSI, D0–D6: DPRSLPVR, SLOW
2.3
V
1.0
0.67
V
V
0.33
V
Note 2: When pulse skipping, the output rises by approximately 1.5% when transitioning from continuous conduction to no load.
Note 3: On-time and minimum off-time specifications are measured from 50% to 50% at the DH_ and DL_ pins, with LX_ forced to
GND, BST_ forced to 5V, and a 500pF capacitor from DH_ to LX_ to simulate external MOSFET gate capacitance. Actual incircuit times might be different due to MOSFET switching speeds.
Note 4: Specifications to TA = -40°C and +105°C are guaranteed by design and are not production tested.
_______________________________________________________________________________________
9
MAX17582
ELECTRICAL CHARACTERISTICS (continued)
Typical Operating Characteristics
(Circuit of Figure 1. VIN = 12V, VCC = VDD = 5V, SHDN = VCC, D0–D6 set for 1.075V, TA = +25°C, unless otherwise specified.)
7V
1.05
1.00
12V
80
0.89
OUTPUT VOLTAGE (V)
90
1.10
0.90
MAX17582 toc02
MAX17582 toc01
100
EFFICIENCY (%)
OUTPUT VOLTAGE (V)
1.15
OUTPUT VOLTAGE vs. LOAD CURRENT
(VOUT(LFM) = 0.875V)
EFFICIENCY vs. LOAD CURRENT
(VOUT(HFM) = 1.075V)
20V
70
MAX17582 toc03
OUTPUT VOLTAGE vs. LOAD CURRENT
(VOUT(HFM) = 1.075V)
SKIP MODE
0.88
0.87
0.86
PWM MODE
0.85
60
0.84
10
0
20
30
40
0.1
50
1.0
10.0
0
100.0
5
10
15
20
LOAD CURRENT (A)
LOAD CURRENT (A)
LOAD CURRENT (A)
EFFICIENCY vs. LOAD CURRENT
(VOUT(LFM) = 0.875V)
OUTPUT VOLTAGE vs. LOAD CURRENT
(VOUT(C4) = 0.4V)
EFFICIENCY vs. LOAD CURRENT
(VOUT(C4) = 0.4V)
OUTPUT VOLTAGE (V)
80
12V
70
20V
0.40
MAX17582 toc06
90
7V
80
EFFICIENCY (%)
7V
MAX17582 toc05
0.41
MAX17582 toc04
90
EFFICIENCY (%)
0.83
50
0.95
70
12V
60
50
20V
60
40
SKIP MODE
PWM MODE
50
1.0
10.0
100.0
3
4
0.01
5
0.10
1.00
10.00
LOAD CURRENT (A)
SWITCHING FREQUENCY
vs. LOAD CURRENT
NO-LOAD SUPPLY CURRENT vs. INPUT VOLTAGE
(VOUT(HFM) = 1.075V)
NO-LOAD SUPPLY CURRENT vs. INPUT VOLTAGE
AT SKIP MODE (VOUT(HFM) = 1.075V)
250
200
150
100
DPRSLPVR = VCC
DPRSLPVR = GND
0
10
20
30
LOAD CURRENT (A)
40
50
IIN
50
ICC + IDD
25
DPRSLPVR = GND
0
6
9
12
15
18
INPUT VOLTAGE (V)
21
24
MAX17582 toc09
MAX17582 toc08
75
10.0
NO-LOAD SUPPLY CURRENT (mA)
VOUT(HFM) = 1.075V
100
NO-LOAD SUPPLY CURRENT (mA)
MAX17582 toc07
VOUT(LFM) = 0.875V
50
10
2
LOAD CURRENT (A)
300
0
1
0
LOAD CURRENT (A)
400
350
DPRSLPVR = VCC
30
0.39
0.1
SWITCHING FREQUENCY (kHz)
MAX17582
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
ICC + IDD
1.0
IIN
0.1
DPRSLPVR = VCC
0
6
9
12
15
18
21
INPUT VOLTAGE AT SKIP MODE (V)
______________________________________________________________________________________
24
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
20
MAX17582 toc11
40
30
20
0.5
40
0.4
30
0.3
20
0.2
0.1
610
608
606
604
602
600
598
596
594
592
590
0.8175
0.8165
0.8155
0.8145
0
0.8135
0
0.8125
0
0.8115
10
0.8105
10
0.8095
0.6
50
10
0.8085
MAX17582 toc12
VOUT = 1.075V
0
0
5
10 15 20 25 30 35 40 45 50
LOAD CURRENT (A)
TRANSCONDUCTANCE (µS)
OUTPUT VOLTAGE (V)
SOFT-START WAVEFORM (UP TO CLKEN)
5V
0
5V
0
1.075V
SHUTDOWN WAVEFORM
SOFT-START WAVEFORM (UP TO PWRGD)
MAX17582 toc13
MAX17582 toc15
MAX17582 toc14
A
B
C
0
D
0
5V
0
5V
0
5V
0
5V
0
1.075V
A
B
C
D
E
D
0
0
F
G
0
0
A. SHDN, 10V/div
B. CLKEN, 10V/div
C. VOUT, 500mV/div
B
C
E
F
E
200µs/div
A
0
0
0
5V
0
5V
0
5V
0
5V
0
1.075V
G
100µs/div
1ms/div
D. ILX1, 10A/div
E. ILX2, 10A/div
IOUT = 15A
A. SHDN, 10V/div
B. PWRGD, 10V/div
C. PHASEGD, 10V/div
D. CLKEN, 10V/div
E. VOUT, 1V/div
F. ILX1, 10A/div
G. ILX2, 10A/div
IOUT = 15A
A. SHDN, 10V/div
B. CLKEN, 10V/div
C. PWRGD, 10V/div
D. DL_, 10V/div
E. VOUT, 500mV/div
F. ILX1, 10A/div
G. ILX2, 10A/div
______________________________________________________________________________________
11
VCSPN1 - VCSPN2 (mV)
30
SAMPLE SIZE = 100
+85°C
+25°C
60
VCSP_ - VCSN_ (mV)
40
50
SAMPLE PERCENTAGE (%)
MAX17582 toc10
50
0.8075
SAMPLE PERCENTAGE (%)
60
SAMPLE SIZE = 100
+85°C
+25°C
CURRENT BALANCE vs. LOAD CURRENT
Gm(FB) TRANSCONDUCTANCE DISTRIBUTION
60
MAX17582
0.8125V OUTPUT-VOLTAGE DISTRIBUTION
70
Typical Operating Characteristics (continued)
(Circuit of Figure 1. VIN = 12V, VCC = VDD = 5V, SHDN = VCC, D0–D6 set for 1.075V, TA = +25°C, unless otherwise specified.)
LOAD-TRANSIENT RESPONSE (HFM MODE)
50A
10A
VID CODE CHANGE (SLOW = GND)
LOAD-TRANSIENT RESPONSE (LFM MODE)
MAX17582 toc18
MAX17582 toc17
MAX17582 toc16
5V
20A
A
A
1.075V
5A
A
0
1.075V
B
B
1V
0.875V
B
25A
0.975V
C
20A
5A
0
C
0
D
C
D
5A
5A
20μs/div
20µs/div
20µs/div
A. IOUT = 5A TO 20A
B. VOUT, 50mV/div
C. ILX1, 10A/div
D. ILX2, 10A/div
A. IOUT = 10A TO 50A
B. VOUT, 50mV/div
OUTPUT UNDERVOLTAGE FAULT
MAX17582 toc20
MAX17582 toc19
5V
C. ILX1, 10A/div
D. ILX2, 10A/div
A. VID3, 5V/div
B. VOUT, 50mV/div
C. INDUCTOR CURRENT,
10A/div
DYNAMIC VID CODE CHANGE
(D0 = 12.5mV)
VID CODE CHANGE (SLOW = VDD)
A
MAX17582 toc21
1.075V
5V
0
A
0
1.075V
B
0.975V
B
1.075V
1.0625V
0
C
5A
0
D
5A
A
0
5V
0
B
5V
0
C
C
30A
D
D
0
20µs/div
20µs/div
A. D0, 5V/div
B. VOUT, 20mV/div
IOUT = 10A
C. ILX1, 10A/div
D. ILX2, 10A/div
A. VID3, 5V/div
B. VOUT, 50mV/div
100μs/div
C. ILX1, 10A/div
D. ILX2, 10A/div
MAX17582 toc22
VOUT = 1.075V
140
5V
A
0.875V
120
B
100
0
5V
80
C
0
5V
0
60
40
DPRSLPVR = VCC
DPRSLPVR = GND
20
0
0
10
20
30
40
50
VCSPN1 + VCSPN2 (mV)
12
C. DL_, 10V/div
D. ILX1, 15A/div
MAX17582 toc23
180
160
A. VOUT, 500mV/div
B. PWRGD, 10V/div
BIAS SUPPLY REMOVAL
(UVLO RESPONSE)
VIMON vs. LOAD CURRENT
VIMON (μA)
MAX17582
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
60
70
80
D
10A
E
0
40μs/div
A. 5V BIAS SUPPLY, 5V/div
B. VOUT, 500mV/div
C. PWRGD, 5V/div
D. DL_, 5V/div
E. ILX1, 10A/div
IOUT = 10A
______________________________________________________________________________________
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
PIN
NAME
FUNCTION
1
PGDIN
System Power-Good Logic Input. PGDIN indicates the power status of other system rails and is used for
power-supply sequencing. After power-up to the boot voltage, the output voltage remains at VBOOT, CLKEN
remains high, and PWRGD remains low as long as PGDIN stays low. When PGDIN is pulled high, the
output transitions to the selected VID voltage, and CLKEN is pulled low. If the system pulls PGDIN low
during normal operation, the MAX17582 immediately drives CLKEN high, pulls PWRGD low, and slews the
output to the boot voltage (using two-phase pulse-skipping mode). The controller remains at the boot
voltage until PGDIN goes high again, SHDN is toggled, or the VCC input power supply is cycled.
2
THRM
3
IMON
Input of Internal Comparator. Connect the output of a resistor- and thermistor-divider (between VCC and
GND) to THRM. Select the components such that the voltage at THRM falls below 1.5V (30% of VCC) at
the desired high temperature.
Current-Monitor Output. The MAX17582 IMON output sources a current that is directly proportional to the
current-sense voltage as defined by:
I IMON = Gm(IMON) x (VCSP_ - VCSN_)
where Gm(IMON) = 5mS (typ).
The IMON current is unidirectional (sources current out of IMON only) for positive current-sense values.
For negative current-sense voltages, the IMON current is zero.
Connect an external resistor between IMON and GNDS to create the desired IMON gain based on the
following equation:
RIMON = 0.9V/(IMAX x R SENSE(MIN) x Gm(IMON_MIN))
where IMAX is defined in the Current Monitor section of the Intel IMVP-6.5 specification and based on
discrete increments (20A, 30A, 40A, etc.), RSENSE(MIN) is the minimum effective value of the currentsense element (sense resistor or inductor DCR) that is used to provide the current-sense voltage, and
Gm(IMON_MIN) is the minimum transconductance amplifier gain as defined in the Electrical
Characteristics table.
The IMON voltage is internally clamped to a maximum of 1.1V (typ).
The transconductance amplifier and voltage clamp are internally compensated, so IMON cannot directly
drive large capacitance values. To filter the IMON signal, use an RC filter as shown in Figure 1.
IMON is pulled to ground when the MAX17582 is in shutdown.
ILIM
Valley Current-Limit Adjustment Input. The valley current-limit threshold voltage at CSP_ to CSN_
equals precisely 1/10 of the differential TIME to ILIM voltage over a 0.1V to 0.5V range (10mV to 50mV
current-sense range). The negative current-limit threshold is nominally -125% of the corresponding
valley current-limit threshold. Connect ILIM directly to VCC to set the default current-limit threshold
setting of 22.5mV (typ) nominal.
5
TIME
Slew-Rate Adjustment. TIME regulates to 2.0V and the load current determines the slew rate of the internal
error-amplifier target. The sum of the resistance between TIME and GND (RTIME) determines the nominal
slew-rate:
SLEW RATE = (12.5mV/μs) x (71.5k/RTIME)
The guaranteed RTIME range is between 35.7k and 178k. This “nominal” slew rate applies to VID
transitions and to the transition from boot mode to VID. If the VID DAC inputs are clocked, the slew rate for
all other VID transitions is set by the rate at which they are clocked, up to a maximum slew rate equal to
the nominal slew rate defined above.
The startup and shutdown slew rates are always 1/8 of nominal slew rate in order to minimize surge
currents.
If SLOW is low, then the slew rate is reduced to 1/2 of nominal.
6, 14, 47
GND
Analog Ground
7
VCC
Controller Analog Bias Supply Voltage. Connect to a 4.5V to 5.5V source. Bypass to GND with 1μF minimum.
8
CCI
Current-Balance Compensation. Connect a 470pF capacitor between CCI and the positive side of the
feedback remote sense. CCI is internally forced low in shutdown.
4
______________________________________________________________________________________
13
MAX17582
Pin Description
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
MAX17582
Pin Description (continued)
PIN
NAME
9
FB
10
FBAC
11
GNDS
12, 24,
37
N.C.
13
CSN2
15
CSP2
16
SHDN
17
DPRSLPVR
14
FUNCTION
Remote Feedback-Sense Input. Normally shorted to FBAC and connected to the VCC_SENSE pin of the
CPU socket through the load-line gain resistor (see the FBAC pin description). FB internally connects
to the error amplifier and integrator.
Voltage-Positioning Transconductance Amplifier Output. Connect a resistor RFB between FBAC and the
positive side of the feedback remote sense to set the DC steady-state droop based on the voltagepositioning gain requirement:
RFB = RDROOP/(RSENSE x Gm(FBAC))
where RDROOP is the desired voltage-positioning slope and Gm(FBAC) = 600μS (typ). RSENSE is the
value of the current-sense resistors that are used to provide the (CSP_, CSN_) current-sense voltages. If
lossless sensing is used, R SENSE = RL. In this case, consider making RFB a resistor network that
includes an NTC thermistor to minimize the temperature dependence of the voltage-positioning slope.
FBAC is high impedance in shutdown.
Remote Ground-Sense Input. Normally connected to the VSS_SENSE pin of the CPU socket. GNDS
internally connects to a transconductance amplifier that fine tunes the output voltage—compensating
for voltage drops from the regulator ground to the load ground.
Internally Not Connected
Negative Current-Sense Input for Phase 2. Connect CSN2 to the negative terminal of the inductor
current-sensing resistor or directly to the negative terminal of the inductor if the lossless DCR sensing
method is used (see Figure 3).
Positive Current-Sense Input for Phase 2. Connect CSP2 to the positive terminal of the inductor currentsensing resistor or directly to the positive terminal of the filtering capacitor used when the lossless
DCR sensing method is used (see Figure 3). Short CSP2 to VCC for dedicated 1-phase operation.
Shutdown Control Input. This input cannot withstand the battery voltage. Connect to VCC for normal
operation. Connect to ground to put the IC into its 1μA max shutdown state. During startup, the output
voltage is ramped up to the boot voltage slowly at a slew rate that is 1/8 the slew rate set by the TIME
resistor. During the transition from normal operation to shutdown, the output voltage is ramped down at
the same slow slew rate. Forcing SHDN to 11V~13V disables undervoltage protection, clears the fault
latch, disables transient phase overlap, and disables the BST_ charging switches. Do not connect
SHDN to > 13V.
Pulse-Skipping Control Input. This 1.0V logic input signal indicates power usage and sets the operating
mode of the MAX17582. When DPRSLPVR is forced high, the controller immediately enters the automatic
pulse-skipping mode. The controller returns to forced-PWM mode when DPRSLPVR is forced low and the
output is in regulation. The PWRGD upper threshold is blanked during any downward output-voltage
transition that occurs when the controller is in pulse-skipping mode, and stays blanked until the transitionrelated PWRGD blanking period is complete and the output reaches regulation.
The MAX17582 is in 2-phase pulse-skipping mode during startup and while in boot mode, but is in
forced-PWM mode during the transition from boot mode to VID mode plus 20μs, and during softshutdown, irrespective of the DRPSLPVR logic level.
DPRSLPVR and PSI together determine the operating mode and the number of active phases as shown
in the following truth table:
DPRSLPVR
PSI
MODE AND PHASES
1
0
Very low current (1-phase pulse skipping)
1
1
Low current (approximately 3A) (1-phase pulse skipping)
0
0
Intermediate power potential (1-phase PWM)
0
1
Max power potential (2- or 1-phase PWM as configured at CSP2)
______________________________________________________________________________________
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
PIN
NAME
FUNCTION
18
PSI
Power-State Indicator Input. DPRSLPVR and PSI together determine the operating mode and the number
of active phases as shown in the truth table included under the PSI pin description.
19
TON
20
V3P3
21
CLKEN
22
PWRGD
23
PHASEGD
25
BST2
26
LX2
27
DH2
28
PGND2
29
DL2
30
VRHOT
31
VDD
Switching Frequency Setting Input. An external resistor between the input power source and TON sets
the switching period (T SW = 1/f SW) per phase according to the following equation:
T SW = 16.3pF x (RTON + 6.5k)
TON becomes high impedance in shutdown to reduce the input quiescent current. If the TON current is
less than 10μA, the MAX17582 disables the controller, sets the TON open fault latch, and pulls DL_
and DH_ low.
3.3V CLKEN Input Supply. V3P3 input supplies the CLKEN CMOS push-pull logic output. Connect to
the system’s standard 3.3V supply voltage before SHDN is pulled high for proper IMVP-6.5 operation.
Clock Enable Push-Pull Logic Output. This inverted logic output indicates when the output voltage
sensed at FB is in regulation. During soft-start, shutdown, and when the FB is out of regulation, the
MAX17582 pulls CLKEN up to V3P3. During VID transitions, the controller forces CLKEN low. Except
during the power-up sequence, CLKEN is the inverse of PWRGD. See the Startup Timing Diagram (Figure
9). When in pulse-skipping mode (DPRSLPVR high), the upper CLKEN threshold is disabled.
Open-Drain Power-Good Output. After output-voltage transitions, except during power-up and powerdown; if FB is in regulation then PWRGD is high impedance.
During startup, PWRGD is held low and continues to be low while the part is in boot mode and until
5ms (typ) after CLKEN goes low.
PWRGD is forced low in shutdown.
PWRGD is forced high impedance whenever the slew-rate controller is active (output-voltage transitions).
When in pulse-skipping mode (DPRSLPVR high), the upper PWRGD threshold comparator is blanked
during downward transitions.
A pullup resistor on PWRGD causes additional finite shutdown current.
Phase-Good Current-Balance Open-Drain Output. Used to signal the system that one of the two
phases either has a fault condition or is not matched with the other. Detection is done by identifying
the need for a large on-time difference between phases in order to achieve or move towards current
balance. PHASEGD is low in shutdown.
PHASEGD is forced high impedance whenever the slew-rate controller is active (output-voltage
transitions).
PHASEGD is forced high impedance while in 1-phase operation (DPRSLPVR = high or PSI = low).
Boost Flying-Capacitor Connection for Phase 2. BST2 provides the upper supply rail for the DH2 highside gate driver. An internal switch between VDD and BST2 charges the flying capacitor while the lowside MOSFET is on (DL2 pulled high and LX2 pulled to ground).
Inductor Connection for Phase 2. LX2 is the internal lower supply rail for the DH2 high-side gate driver.
Also used as an input to the controller’s zero-crossing comparator for phase 2.
High-Side Gate-Driver Output for Phase 2. DH2 swings from LX2 to BST2. The controller pulls DH2 low
in shutdown.
Power Ground
Low-Side Gate-Driver Output for Phase 2. DL2 swings from GND to VDD. DL2 is forced low in skip mode
after detecting an inductor current zero crossing. DL2 is forced low during 1-phase operation (PSI =
GND or CSP2 = VCC).
Open-Drain Output of Internal Comparator. VRHOT is pulled low when the voltage at THRM goes below
1.5V (30% of VCC). VRHOT is high impedance in shutdown.
Driver Supply Voltage Input. VDD is the supply voltage used to internally power the low-side gate
drivers and refresh the BST_ flying capacitors during the off-times. Connect VDD to the 4.5V to 5.5V
system supply voltage. Bypass VDD to the system power ground with a 1μF each or greater ceramic
capacitor.
______________________________________________________________________________________
15
MAX17582
Pin Description (continued)
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
MAX17582
Pin Description (continued)
PIN
NAME
FUNCTION
32
DL1
33
PGND1
34
DH1
High-Side Gate-Driver Output for Phase 1. DH1 swings from LX1 to BST1. The controller pulls DH1 low
in shutdown.
35
LX1
Inductor Connection for Phase 1. LX1 is the internal lower supply rail for the DH1 high-side gate driver.
Also used as an input to the controller’s zero-crossing comparator for phase 1.
36
BST1
Boost Flying-Capacitor Connection for Phase 1. BST1 provides the upper supply rail for the DH1 highside gate driver. An internal switch between VDD and BST1 charges the flying capacitor while the lowside MOSFET is on (DL1 is pulled high and LX1 is pulled to ground).
38
SLOW
IMVP-6.5 Slew-Rate Select Input. This 1.0V logic input signal selects between the nominal and “slow”
(half of nominal rate) slew rates. When SLOW is forced high, the selected nominal slew rate is set by
the TIME resistance as defined above. When SLOW is forced low, the slew rate is reduced to half the
nominal slew rate.
39–45
D0–D6
Low-Voltage VID DAC Code Input. The D0–D6 inputs do not have internal pullups. These 1.0V logic
inputs are designed to interface directly with the CPU. The output voltage is set by the VID code
indicated by the logic-level voltages on D0–D6 (see Table 4).
46
CSP1
Positive Current-Sense Input for Phase 1. Connect CSP1 to the positive terminal of the inductor currentsensing resistor or directly to the positive terminal of the filtering capacitor used when the lossless
DCR sensing method is used (see Figure 3).
48
CSN1
Negative Current-Sense Input for Phase 1. Connect CSN1 to the negative terminal of the inductor
current-sensing resistor or directly to the negative terminal of the inductor if the lossless DCR sensing
method is used (see Figure 3).
Under VCC UVLO conditions and after soft-shutdown is completed, CSN1 is internally pulled to GND
through a 10 FET to discharge the output.
—
EP
Low-Side Gate-Driver Output for Phase 1. DL1 swings from GND to VDD. DL1 is forced low after softshutdown or in skip mode after detecting an inductor current zero crossing.
Power Ground
Exposed Pad. Internally connected to GND. Connect to the ground plane through a thermally
enhanced via.
Detailed Description
Table 1 lists the component selection for standard
applications. Table 2 lists component suppliers for the
MAX17582.
Free-Running, Constant-On-Time PWM
Controller with Input Feed-Forward
The Quick-PWM control architecture is a pseudo-fixedfrequency, constant-on-time, current-mode regulator
with voltage feed-forward (Figure 2). This architecture
relies on the output filter capacitor’s ESR to act as the
current-sense resistor, so the output ripple voltage provides the PWM ramp signal. The control algorithm is
16
simple: the high-side switch on-time is determined solely by a one-shot whose period is inversely proportional
to input voltage and directly proportional to output voltage, or the difference between the main and secondary
inductor currents (see the On-Time One-Shot section).
Another one-shot sets a minimum off-time. The on-time
one-shot triggers when the error comparator goes low,
the inductor current of the selected phase is below the
valley current-limit threshold, and the minimum off-time
one-shot times out. The controller maintains 180° out-ofphase operation by alternately triggering the main and
secondary phases after the error comparator drops
below the output-voltage set point.
______________________________________________________________________________________
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
DESIGN PARAMETERS
IMVP-6.5 AUBURNDALE SV CORE
IMVP-6.5 AUBURNDALE LV CORE
CIRCUIT
FIGURE 1
FIGURE 1
Input-Voltage Range
7V to 20V
7V to 20V
Maximum Load Current
(TDC Current)
50A
(37A)
28A
(19A)
Transient Load Current
35A
(10A/μs)
23A
(10A/μs)
Load Line
-1.9mV/A
-3mV/A
MAX17582
Table 1. Component Selection for Standard Applications
COMPONENTS
TON Resistance (RTON)
Inductance (L)
200k (f SW = 300kHz)
200k (f SW = 300kHz)
NEC/TOKIN MPC1055LR36 0.36μH,
32A, 0.8m
NEC/TOKIN MPC1055LR36 0.36μH,
32A, 0.8m
Siliconix 1x Si4386DY
7.8m/9.5m (typ/max)
Siliconix 1x Si4386DY
7.8m/9.5m (typ/max)
Siliconix 2x Si4642DY
3.9m/4.7m (typ/max)
4x 330μF, 6m, 2.5V Panasonic
EEFSX0D0D331XR
28x 10μF, 6V ceramic (0805)
4x 10μF, 25V ceramic (1210)
Siliconix 2x Si4642DY
3.9m/4.7m (typ/max)
3x 330μF, 6m, 2.5V Panasonic
EEFSX0D0D331XR
28x 10μF, 6V ceramic (0805)
4x 10μF, 25V ceramic (1210)
10k
10k
High-Side MOSFET (NH)
Low-Side MOSFET (NL)
Output Capacitors (COUT)
Input Capacitors (CIN)
TIME-ILIM Resistance (R1)
ILIM-GND Resistance (R2)
59k
59k
FB Resistance (RFB)
4.02k
6.34k
IMON Resistance
9.09k
18.2k
LX_-CSP_ Resistance (R5)
1.21k
1.21k
CSP_-CSN_ Series Resistance (R6)
1.50k
1.50k
Parallel NTC Resistance
20k
20k
DCR Sense NTC (NTC1)
10k NTC B = 3380
TDK NTCG163JH103F
10k NTC B = 3380
TDK NTCG163JH103F
2x 0.22μF, 6V ceramic (0805)
2x 0.22μF, 6V ceramic (0805)
DCR Sense Capacitance (CSENSE)
Table 2. Component Suppliers
SUPPLIER
WEBSITE
SUPPLIER
WEBSITE
AVX Corp.
www.avxcorp.com
Pulse Engineering
BI Technologies
www.bitechnologies.com
Renesas Technology Corp. www.renesas.com
www.pulseeng.com
Central Semiconductor Corp. www.centralsemi.com
SANYO Electric Co, Ltd.
www.sanyodevice.com
Fairchild Semiconductor
www.fairchildsemi.com
Siliconix (Vishay)
www.vishay.com
International Rectifier
www.irf.com
Sumida Corp.
www.sumida.com
KEMET Corp
www.kemet.com
Taiyo Yuden
www.t-yuden.com
NEC/TOKIN America, Inc.
www.nec-tokin.com
TDK Corp.
www.component.tdk.com
Panasonic Corp.
www.panasonic.com
TOKO America, Inc.
www.tokoam.com
______________________________________________________________________________________
17
MAX17582
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
16
ON OFF (VRON)
17
38
AGND
18
1
39
40
41
42
VID INPUTS
43
44
45
SHDN
VCC
SLOW
VDD
R1
12.1kΩ
D0
TON
D1
D2
D3
BST1
D4
DH1
D5
D6
MAX17582 LX1
PGND1
5
CSP1
ILIM
CSN1
TIME
AGND
CCI
20
3.3V
CSN2
V3P3
1.1V
R3
56Ω
R4
1.9kΩ
CSP2
R5
10kΩ
23
22
30
21
R6
13kΩ
2
VCC
PWRGD
BST2
VRHOT
DH2
CLKEN
LX2
THRM
DL2
PGND2
36
32
C15
0.1μF
C10
1000pF
C11
0.22μF
R13
0Ω
27
C8
26 0.22μF
29
28
L1
R10
1.21kΩ
R11
1.50kΩ
D1
R12
20kΩ
COUT
PWR
NLO
NTC1
10kΩ
B = 3380
C7
0.22μF
C5
0.22μF
8
25
PWR
PWR
48
15
NHI
C6
OPEN
AGND
DCR THERMAL
COMPENSATION
C9
0.22μF
C12
OPEN
AGND
NHI
CORE
OUTPUT
NTC2
10kΩ
B = 3380
R15
1.50kΩ
COUT
R16
20kΩ
R14
1.21kΩ
PWR
L2
D1
PWR
LOAD-LINE ADJUSTMENT:
RFB = RDROOP/(RSENSE x 600μs)
IMON
FBAC
FB
R8
9.09kΩ
GND
GNDS
VSS_SENSE
6, 14, 47
NLO
46
13
INPUT
7V TO 24V
CIN
C4
35 0.22μF
33
SWITCHING FREQUENCY (fSW = 1/TSW):
TSW = 16.3pF x (RTON + 6.5kΩ)
R9
0Ω
34
AGND
3
C2
1.0μF
RTON
200kΩ
19
PHASEGD
NTC3
100kΩ
B = 4250
R7
1kΩ
AGND
PWR
DL1
4
31
5V BIAS
INPUT
PGDIN
VALLEY CURRENT LIMIT SET TO ILIM
VLIMIT = 0.2V x R1/(R1 + R2)
SLEW RATE SET BY TIME BIAS CURRENT
dV/dt = 12.5mV/μs x 71.5kΩ/(R1 + R2)
R2
59.0kΩ
C1
1.0μF
DPRSLPVR
PSI
R19
10Ω
7
10
9
RFB
4.02kΩ
1%
11
GND (EP)
R20
10Ω
C13
1000pF
AGND
R22
25Ω
VCC_SENSE
REMOTE-SENSE
INPUTS
R21
10Ω
VSS_SENSE
C14
1000pF
AGND
REMOTE-SENSE FILTERS
R23
25Ω
PWR
CATCH RESISTORS
REQUIRED WHEN CPU NOT
POPULATED
Figure 1. Standard 2-Phase IMVP-6.5 (Calpella) Application Circuit
18
______________________________________________________________________________________
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
MAX17582
BST2
THRM
DH2
VRHOT
EN2
MAX17582
LX2
SECONDARY
PHASE DRIVERS
DL2
GND
0.3 x VCC
BLANK
CSP2
PHASEGD
10x
CSN2
Q
CSP1
TRIG
ONE-SHOT
ILIM
Q
TIME
CCI
PHASE 2
ON-TIME
10x
CSN1
5ms
STARTUP
DELAY
CURRENTBALANCE
FAULT
MINIMUM
OFF-TIME
TRIG
200kΩ
CSN2
ONE-SHOT
Gm(CCI)
PHASE 1
ON-TIME
VCC
CSP1
FB
ONE-SHOT
REF
(2.0V)
Q
CSP2
TRIG
Gm(CCI)
CSN1
TON
GND
SLEW
D0–D6
DAC
PGDIN
Q
DH1
S
SHDN
TARGET
Q
Q
GND
LX1
1mV
T
LX1
S
Q
R
VDD
SKIP
FAULT
BST1
MAIN PHASE
DRIVERS
R
R-TO-I
CONVERTER
DL1
GND
TARGET
- 300mV
PWRGD
5ms
STARTUP
DELAY
FB
CSN_
(SLOW)
Gm(FB)
PSI
CSP_
DPRSLPVR
x2
PGDIN
MODE/PHASE/
SLEW-RATE
CONTROL
V3P3
60μs
STARTUP
DELAY
SKIP
EN2
SLEW
GNDS
FBAC
TARGET
+ 200mV
CLKEN
BLANK
MAX17582
CSP_
x2
CSN_
Gm(IMON)
IMON
Figure 2. Functional Diagram
______________________________________________________________________________________
19
MAX17582
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
Dual 180° Out-of-Phase Operation
Switching Frequency (TON)
The two phases in the MAX17582 operate 180° out-ofphase to minimize input and output filtering requirements,
reduce electromagnetic interference (EMI), and improve
efficiency. This effectively lowers component count—
reducing cost, board space, and component power
requirements—making the MAX17582 ideal for highpower, cost-sensitive applications.
Connect a resistor (RTON) between TON and VIN to set
the switching period TSW = 1/fSW, per phase:
TSW = 16.3pF x (RTON + 6.5kΩ)
A 96.75kΩ to 303.25kΩ corresponds to switching periods of 167ns (600kHz) to 500ns (200kHz), respectively.
High-frequency (600kHz) operation optimizes the application for the smallest component size, trading off efficiency due to higher switching losses. This might be
acceptable in ultra-portable devices where the load
currents are lower and the controller is powered from a
lower voltage supply. Low-frequency (200kHz) operation offers the best overall efficiency at the expense of
component size and board space.
Typically, switching regulators provide power using
only one phase instead of dividing the power among
several phases. In these applications, the input capacitors must support high instantaneous current requirements. The high RMS ripple current can lower
efficiency due to I2R power loss associated with the
input capacitor’s effective series resistance (ESR).
Therefore, the system typically requires several lowESR input capacitors in parallel to minimize input-voltage ripple, to reduce ESR-related power losses, and to
meet the necessary RMS ripple current rating.
With the MAX17582, the controller shares the current
between two phases that operate 180° out-of-phase, so
the high-side MOSFETs never turn on simultaneously
during normal operation. The instantaneous input current of either phase is effectively halved, resulting in
reduced input-voltage ripple, ESR power loss, and RMS
ripple current (see the Input Capacitor Selection section). Therefore, the same performance can be
achieved with fewer or less-expensive input capacitors.
+5V Bias Supply (VCC and VDD)
The Quick-PWM controller requires an external +5V
bias supply in addition to the battery. Typically, this
+5V bias supply is the notebook’s 95% efficient +5V
system supply. Keeping the bias supply external to the
IC improves efficiency and eliminates the cost associated with the +5V linear regulator that would otherwise be
needed to supply the PWM circuit and gate drivers. If
stand-alone capability is needed, the +5V bias supply
can be generated with an external linear regulator.
The +5V bias supply must provide V CC (PWM controller) and VDD (gate-drive power), so the maximum
current drawn is:
IBIAS = ICC + fSW (QG(LOW) + QG(HIGH))
where ICC is provided in the Electrical Characteristics
table, fSW is the switching frequency, and QG(LOW) and
Q G(HIGH) are the MOSFET data sheet’s total gatecharge specification limits at VGS = 5V.
VIN and VDD can be connected together if the input power
source is a fixed +4.5V to +5.5V supply. If the +5V bias
supply is powered up prior to the battery supply, the enable
signal (SHDN going from low to high) must be delayed until
the battery voltage is present to ensure startup.
20
TON Open-Circuit Protection
The TON input includes open-circuit protection to avoid
long, uncontrolled on-times that could result in an overvoltage condition on the output. The MAX17582 detects
an open-circuit fault if the TON current drops below
10μA for any reason—the TON resistor (R TON ) is
unpopulated, a high resistance value is used, the input
voltage is low, etc. Under these conditions, the
MAX17582 stops switching (DH_ and DL_ pulled low)
and immediately sets the fault latch. Toggle SHDN or
cycle the VCC power supply below 0.5V to clear the
fault latch and reactivate the controller.
On-Time One-Shot
The core of each phase contains a fast, low-jitter,
adjustable one-shot that sets the high-side MOSFETs
on-time. The one-shot for the main phase varies the ontime in response to the input and feedback voltages.
The main high-side switch on-time is inversely proportional to the input voltage as measured by the TON
input, and proportional to the feedback voltage (VFB):
tON(MAIN) =
TSW ( VFB + 0.075V )
VIN
where the switching period (TSW = 1/fSW) is set by the
resistor at the TON pin, and 0.075V is an approximation
to accommodate the expected drop across the lowside MOSFET switch.
The one-shot for the secondary phase varies the ontime in response to the input voltage and the difference
between the main and secondary inductor currents.
Two identical transconductance amplifiers integrate the
difference between the master and slave current-sense
signals. The summed output is internally connected to
CCI, allowing adjustment of the integration time constant with a compensation network connected between
______________________________________________________________________________________
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
where ZCCI is the impedance at the CCI output. The
secondary on-time one-shot uses this integrated signal
(VCCI) to set the secondary high-side MOSFETs ontime. When the main and secondary current-sense signals (VCM = VCSP1 - VCSN1 and VCS = VCSP2 - VCSN2)
become unbalanced, the transconductance amplifiers
adjust the secondary on-time, which increases or
decreases the secondary inductor current until the current-sense signals are properly balanced:
⎛V
+ 0.075V ⎞
tON(SEC) = TSW ⎜ CCI
⎟⎠
VIN
⎝
⎛ V + 0.07
⎛ ICCIZCCI ⎞
75V ⎞
= TSW ⎜ FB
⎟⎠ + TSW ⎜⎝ V
⎟
VIN
⎝
IN ⎠
= (Main On-ttime) + ( Secondary Current Balance Correction)
This algorithm results in a nearly constant switching frequency and balanced inductor currents despite the
lack of a fixed-frequency clock generator. The benefits
of a constant switching frequency are twofold: first, the
frequency can be selected to avoid noise-sensitive
regions such as the 455kHz IF band; second, the
inductor ripple-current operating point remains relatively constant, resulting in easy design methodology and
predictable output-voltage ripple. The on-time oneshots have good accuracy at the operating points
specified in the Electrical Characteristics table. Ontimes at operating points far removed from the conditions specified in the Electrical Characteristics table
can vary over a wider range.
On-times translate only roughly to switching frequencies. The on-times guaranteed in the Electrical
Characteristics table are influenced by switching
delays in the external high-side MOSFET. Resistive
losses, including the inductor, both MOSFETs, output
capacitor ESR, and PCB copper losses in the output
and ground tend to raise the switching frequency at
higher output currents. Also, the dead-time effect
increases the effective on-time, reducing the switching
frequency. It occurs only during forced-PWM operation
and dynamic output-voltage transitions when the inductor current reverses at light- or negative-load currents.
With reversed inductor current, the inductor’s EMF
causes LX_ to go high earlier than normal, extending
the on-time by a period equal to the DH_-rising dead
time. For loads above the critical conduction point,
where the dead-time effect is no longer a factor, the
actual switching frequency (per phase) is:
fSW =
( VOUT + VDROP1)
tON ( VIN + VDROP1 - VDROP2 )
where VDROP1 is the sum of the parasitic voltage drops in
the inductor discharge path, including synchronous rectifier, inductor, and PCB resistances; VDROP2 is the sum of
the parasitic voltage drops in the inductor charge path,
including high-side switch, inductor, and PCB resistances; and tON is the on-time as determined above.
Current Sense
The output current of each phase is sensed. Low-offset
amplifiers are used for current balance, voltage-positioning gain, and current limit. Sensing the current at
the output of each phase offers advantages, including
less noise sensitivity, more accurate current sharing
between phases, and the flexibility of using either a current-sense resistor or the DC resistance of the output
inductor.
Using the DC resistance (RDCR) of the output inductor
allows higher efficiency. In this configuration, the initial
tolerance and temperature coefficient of the inductor’s
DCR must be accounted for in the output-voltage
droop-error budget and power monitor. This currentsense method uses an RC filtering network to extract
the current information from the output inductor (see
Figure 3). The resistive divider used should provide a
current-sense resistance (RCS) low enough to meet the
current-limit requirements, and the time constant of the
RC network should match the inductor’s time constant
(L/RCS):
⎛ R2 ⎞
RCS = ⎜
R
⎝ R1 + R2 ⎟⎠ DCR
and:
RCS =
L ⎡1
1 ⎤
+
⎢
CEQ ⎣ R1 R2 ⎥⎦
where RCS is the required current-sense resistance and
RDCR is the inductor’s series DC resistance.
______________________________________________________________________________________
21
MAX17582
CCI and FB. The resulting compensation current and
voltage are determined by the following equations:
ICCI = Gm(VCSP1 - VCSN1) - Gm(VCSP2 - VCSN2)
VCCI = VFB + ICCIZCCI
MAX17582
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
Use the worst-case inductance and RDCR values provided by the inductor manufacturer, adding some margin for the inductance drop over temperature and load.
To minimize the current-sense error due to the currentsense inputs’ bias current (ICSP_ and ICSN_), choose
R1||R2 to be less than 2kΩ and use the previous equation to determine the sense capacitance (CEQ). Choose
capacitors with 5% tolerance and resistors with 1% tolerance specifications. Temperature compensation is
recommended for this current-sense method. See the
Voltage Positioning and Loop Compensation section for
detailed information.
resistor (see Figure 3). The ESL induced-voltage step
does not affect the average current-sense voltage, but
results in a significant peak current-sense voltage error
that results in unwanted offsets in the regulation voltage
and results in early current-limit detection. Similar to the
inductor DCR sensing method above, the RC filter’s time
constant should match the L/R time constant formed by
the current-sense resistor’s parasitic inductance:
When using a current-sense resistor for accurate outputvoltage positioning, the circuit requires a differential RC
filter to eliminate the AC voltage step caused by the
equivalent series inductance (LESL) of the current-sense
where LESL is the equivalent series inductance of the
current-sense resistor, RSENSE is current-sense resistance value, and CEQ and R1 are the time-constant
matching components.
LESL
= CEQR1
RSENSE
INPUT (VIN)
CIN
DH_
NH
SENSE RESISTOR
LX_
MAX17582
DL_
LESL
L
NL
RSENSE
COUT
DL
PGND
R1
CEQR1 =
LSENSE
RSENSE
CEQ
CSP_
CSN_
A) OUTPUT SERIES RESISTOR SENSING
INPUT (VIN)
CIN
DH_
NH
INDUCTOR
LX_
MAX17582
L
RDCR
RCS =
DL_
NL
DL
COUT
R1
PGND
B) LOSSLESS INDUCTOR SENSING
R2
R1 + R2
)
RDCR
R2
RDCR =
CSP_
CSN_
(
[
L
1 1
+
CEQ R1 R2
]
CEQ
FOR THERMAL COMPENSATION:
R2 SHOULD CONSIST OF AN NTC RESISTOR IN
SERIES WITH A STANDARD THIN-FILM RESISTOR.
Figure 3. Current-Sense Methods
22
______________________________________________________________________________________
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
VOS(IBAL)
IOS(IBAL) = ILMAIN - ILSEC =
RSENSE
where RSENSE is the effective sense resistance seen at
the current-sense pins and VOS(IBAL) is the current-balance offset specification in the Electrical Characteristics table.
The worst-case current mismatch occurs immediately
after a load transient due to inductor value mismatches
resulting in different di/dt for the two phases. The time it
takes the current-balance loop to correct the transient
imbalance depends on the mismatch between the
inductor values and switching frequency.
Current Limit
The current-limit circuit employs a unique “valley” current-sensing algorithm that uses current-sense resistors
between the current-sense inputs (CSP_ to CSN_) as
the current-sensing elements. If the current-sense signal of the selected phase is above the current-limit
threshold, the PWM controller does not initiate a new
cycle until the inductor current of the selected phase
drops below the valley current-limit threshold. When
either phase trips the current limit, both phases are
effectively current limited since the interleaved controller does not initiate a cycle with either phase.
Since only the valley current is actively limited, the actual peak current is greater than the current-limit threshold by an amount equal to the inductor ripple current.
Therefore, the exact current-limit characteristic and
maximum load capability are a function of the currentsense resistance, inductor value, and battery voltage.
When combined with the undervoltage-protection circuit, this current-limit method is effective in almost
every circumstance.
The positive valley current-limit threshold voltage at
CSP_ to CSN_ equals precisely 1/10 of the differential
TIME to ILIM voltage over a 0.1V to 0.5V range (10mV
to 50mV current-sense range). Connect ILIM directly to
VCC to set the default current-limit threshold setting of
22.5mV (typ).
The negative current-limit threshold (forced-PWM mode
only) is nominally -125% of the corresponding valley
current-limit threshold. When the inductor current drops
below the negative current limit, the controller immediately activates an on-time pulse—DL_ turns off and
DH_ turns on—allowing the inductor current to remain
above the negative-current threshold.
Carefully observe the PCB layout guidelines to ensure
that noise and DC errors do not corrupt the current-sense
signals seen by the current-sense inputs (CSP_, CSN_).
Feedback Adjustment Amplifiers
Voltage-Positioning Amplifier (Steady-State Droop)
The MAX17582 includes a transconductance amplifier
for adding gain to the voltage-positioning sense path.
The amplifier’s input is generated by summing the current-sense inputs, which differentially sense the voltage
across either current-sense resistors or the inductor’s
DCR. The amplifier’s output connects directly to the regulator’s voltage-positioned feedback input (FB), so the
resistance between FB and the output-voltage sense
point determines the voltage-positioning gain:
VOUT = VTARGET - RFB|FB
where the target voltage (VTARGET) is defined in the
Nominal Output-Voltage Selection section, and the FB
amplifier’s output current (IFB) is determined by the
sum of the current-sense voltages:
ηPH
IFB = Gm(FB) ∑ VCSX
X =1
where VCS = VCSP_ - VCSN_ is the differential currentsense voltage, and G m(FB) is typically 600μS as
defined in the Electrical Characteristics table.
______________________________________________________________________________________
23
MAX17582
Current Balance
The MAX17582 integrates the difference between the
current-sense voltages and adjusts the on-time of the
secondary phase to maintain current balance. The current balance now relies on the accuracy of the currentsense resistors instead of the inaccurate, thermally
sensitive on-resistance of the low-side MOSFETs. With
active current balancing, the current mismatch is determined by the current-sense resistor values and the offset
voltage of the transconductance amplifiers:
MAX17582
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
Differential Remote Sense
The MAX17582 includes differential, remote-sense
inputs to eliminate the effects of voltage drops along the
PCB traces and through the processor’s power pins. The
feedback-sense node connects to the voltage-positioning resistor (RFB). The ground-sense (GNDS) input connects to an amplifier that adds an offset directly to the
target voltage, effectively adjusting the output voltage to
counteract the voltage drop in the ground path. Connect
the voltage-positioning resistor (RFB) and ground-sense
(GNDS) input directly to the processor’s remote-sense
outputs, as shown in Figure 1.
turns on both high-side MOSFETs during the next ontime cycle. This maximizes the total inductor current
slew rate. The phases remain overlapped until the output voltage exceeds the regulation voltage after the
minimum off-time expires.
Integrator Amplifier
An integrator amplifier forces the DC average of the FB
voltage to equal the target voltage. This transconductance amplifier integrates the feedback voltage and provides a fine adjustment to the regulation voltage (Figure
2), allowing accurate DC output-voltage regulation
regardless of the output ripple voltage. The integrator
amplifier can shift the output voltage by ±100mV (typ).
The differential input-voltage range is at least ±60mV
total, including DC offset and AC ripple.
The MAX17582 disables the integrator by connecting
the amplifier inputs together at the beginning of all VID
transitions done in pulse-skipping mode (DPRSLPVR =
high). The integrator remains disabled until 20μs after
the transition is completed (the internal target settles)
and the output is in regulation (edge detected on the
error comparator).
The nominal no-load output voltage (V TARGET ) is
defined by the selected voltage reference (VID DAC)
plus the remote ground-sense adjustment (VGNDS) as
defined in the following equation:
VTARGET = VFB = VDAC + VGNDS
Transient-Overlap Operation
When a transient occurs, the response time of the controller depends on how quickly it can slew the inductor
current. Multiphase controllers that remain 180° out-ofphase when a transient occurs actually respond slower
than an equivalent single-phase controller. To provide
fast-transient response, the MAX17582 supports a
phase-overlap mode, which allows the dual regulators
to operate in-phase when heavy load transients are
detected, effectively reducing the response time. After
either high-side MOSFET turns off, if the output voltage
does not exceed the regulation voltage when the minimum off-time expires, the controller simultaneously
24
After the phase-overlap mode ends, the controller automatically begins with the opposite phase. For example, if the
secondary phase provided the last on-time pulse before
overlap operation began, the controller starts switching
with the main phase when overlap operation ends. Table 3
is the operating mode truth table.
Nominal Output-Voltage Selection
where VDAC is the selected VID voltage. On startup, the
MAX17582 slews the target voltage from ground to the
preset boot voltage.
DAC Inputs (D0–D6)
The digital-to-analog converter (DAC) programs the output voltage using the D0–D6 inputs. D0–D6 are lowvoltage (1.0V) logic inputs, designed to interface directly
with the CPU. Do not leave D0–D6 unconnected.
Changing D0–D6 initiates a transition to a new outputvoltage level. Change D0–D6 together, avoiding greater
than 20ns skew between bits. Otherwise, incorrect DAC
readings might cause a partial transition to the wrong voltage level followed by the intended transition to the correct
voltage level, lengthening the overall transition time. The
available DAC codes and resulting output voltages are
compatible with the IMVP-6.5 (Table 4) specifications.
______________________________________________________________________________________
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
INPUTS
SHDN
SLOW
DPRSLPVR
PSI
PHASE
OPERATION*
GND
X
X
X
Disabled
Rising
X
X
X
High
High
Low
High
High
High
High
High
High
Low
Low
High
High
Multiphase
pulse-skipping
1/8 RTIME slew
rate
Multiphase
forced-PWM
nominal RTIME
slew rate
OPERATING MODE
Low-Power Shutdown Mode. DL1 and DL2 forced low, and the
controller is disabled. The supply current drops to 1μA (max).
Startup/Boot. When SHDN is pulled high, the MAX17582 begins
the startup sequence. The controller enables the PWM regulator
and ramps the output voltage up to the boot voltage. See Figure 9.
Full Power. The no-load output voltage is determined by the
selected VID DAC code (D0–D6, Table 4).
1-phase forcedPWM
nominal RTIME
slew rate
Intermediate Power. The no-load output voltage is determined by
the selected VID DAC code (D0–D6, Table 4). When PSI is pulled
low, the MAX17582 immediately disables phase 2. DH2 and DL2
are pulled low.
1-phase pulseskipping
nominal RTIME
slew rate
Deeper Sleep Mode. The no-load output voltage is determined
by the selected VID DAC code (D0–D6, Table 4). When
DPRSLPVR is pulled high, the MAX17582 immediately enters
1-phase pulse-skipping operation, allowing automatic PWM/
PFM switchover under light loads. The PWRGD and CLKEN
upper thresholds are blanked during downward transitions. DH2
and DL2 are pulled low.
X
1-phase pulseskipping
Deeper Sleep Slow Exit Mode. The no-load output voltage is
determined by the selected VID DAC code (D0–D6, Table 4).
When SLOW is pulled low, the MAX17582 reduces its slew rate
to 1/2 of normal. The PWRGD and CLKEN upper thresholds are
blanked. DH2 and DL2 are pulled low.
Shutdown. When SHDN is pulled low, the MAX17582 immediately
pulls PWRGD and PHASEGD low, CLKEN becomes high, all
enabled phases are activated, and the output voltage is ramped
down to ground. Once the output reaches 0V, the controller enters
the low-power shutdown state. See Figure 9.
Low
X
Falling
X
X
X
Multiphase
forced-PWM
1/8 RTIME slew
rate
High
X
X
X
Disabled
Fault Mode. The fault latch has been set by the MAX17582 UVP or
thermal-shutdown protection. The controller remains in fault mode
until VCC power is cycled or SHDN toggled.
*Multiphase operation—all enabled phases active.
______________________________________________________________________________________
25
MAX17582
Table 3. Operating Mode Truth Table
MAX17582
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
Table 4. IMVP-6.5 Output-Voltage VID DAC Codes
D6
D5
D4
D3
D2
D1
D0
OUTPUT
VOLTAGE
(V)
D6
D5
D4
D3
D2
D1
D0
OUTPUT
VOLTAGE
(V)
0
0
0
0
0
0
0
1.5000
1
0
0
0
0
0
0
0.7000
0
0
0
0
0
0
1
1.4875
1
0
0
0
0
0
1
0.6875
0
0
0
0
0
1
0
1.4750
1
0
0
0
0
1
0
0.6750
0
0
0
0
0
1
1
1.4625
1
0
0
0
0
1
1
0.6625
0
0
0
0
1
0
0
1.4500
1
0
0
0
1
0
0
0.6500
0
0
0
0
1
0
1
1.4375
1
0
0
0
1
0
1
0.6375
0
0
0
0
1
1
0
1.4250
1
0
0
0
1
1
0
0.6250
0
0
0
0
1
1
1
1.4125
1
0
0
0
1
1
1
0.6125
0
0
0
1
0
0
0
1.4000
1
0
0
1
0
0
0
0.6000
0
0
0
1
0
0
1
1.3875
1
0
0
1
0
0
1
0.5875
0
0
0
1
0
1
0
1.3750
1
0
0
1
0
1
0
0.5750
0
0
0
1
0
1
1
1.3625
1
0
0
1
0
1
1
0.5625
0
0
0
1
1
0
0
1.3500
1
0
0
1
1
0
0
0.5500
0
0
0
1
1
0
1
1.3375
1
0
0
1
1
0
1
0.5375
0
0
0
1
1
1
0
1.3250
1
0
0
1
1
1
0
0.5250
0
0
0
1
1
1
1
1.3125
1
0
0
1
1
1
1
0.5125
0
0
1
0
0
0
0
1.3000
1
0
1
0
0
0
0
0.5000
0
0
1
0
0
0
1
1.2875
1
0
1
0
0
0
1
0.4875
0
0
1
0
0
1
0
1.2750
1
0
1
0
0
1
0
0.4750
0
0
1
0
0
1
1
1.2625
1
0
1
0
0
1
1
0.4625
0
0
1
0
1
0
0
1.2500
1
0
1
0
1
0
0
0.4500
0
0
1
0
1
0
1
1.2375
1
0
1
0
1
0
1
0.4375
0
0
1
0
1
1
0
1.2250
1
0
1
0
1
1
0
0.4250
0
0
1
0
1
1
1
1.2125
1
0
1
0
1
1
1
0.4125
0
0
1
1
0
0
0
1.2000
1
0
1
1
0
0
0
0.4000
0
0
1
1
0
0
1
1.1875
1
0
1
1
0
0
1
0.3875
0
0
1
1
0
1
0
1.1750
1
0
1
1
0
1
0
0.3750
0
0
1
1
0
1
1
1.1625
1
0
1
1
0
1
1
0.3625
0
0
1
1
1
0
0
1.1500
1
0
1
1
1
0
0
0.3500
0
0
1
1
1
0
1
1.1375
1
0
1
1
1
0
1
0.3375
0
0
1
1
1
1
0
1.1250
1
0
1
1
1
1
0
0.3250
0
0
1
1
1
1
1
1.1125
1
0
1
1
1
1
1
0.3125
0
0
1
1
1
1
1
1.1125
1
0
1
1
1
1
1
0.3125
Note: The MAX17582 enters the shutdown sequence if the OFF code is set, forcing PWRGD and PHASEGD low and forcing CLKEN
high. Exit from the OFF code follows the startup sequence. If the OFF code is present when SHDN is pulled high, the MAX17582
remains off.
26
______________________________________________________________________________________
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
D6
D5
D4
D3
D2
D1
D0
OUTPUT
VOLTAGE
(V)
D6
D5
D4
D3
D2
D1
D0
OUTPUT
VOLTAGE
(V)
0
1
0
0
0
0
0
1.1000
1
1
0
0
0
0
0
0.3000
0
1
0
0
0
0
1
1.0875
1
1
0
0
0
0
1
0.2875
0
1
0
0
0
1
0
1.0750
1
1
0
0
0
1
0
0.2750
0
1
0
0
0
1
1
1.0625
1
1
0
0
0
1
1
0.2625
0
1
0
0
1
0
0
1.0500
1
1
0
0
1
0
0
0.2500
0
1
0
0
1
0
1
1.0375
1
1
0
0
1
0
1
0.2375
0
1
0
0
1
1
0
1.0250
1
1
0
0
1
1
0
0.2250
0
1
0
0
1
1
1
1.0125
1
1
0
0
1
1
1
0.2125
0
1
0
1
0
0
0
1.0000
1
1
0
1
0
0
0
0.2000
0
1
0
1
0
0
1
0.9875
1
1
0
1
0
0
1
0.1875
0
1
0
1
0
1
0
0.9750
1
1
0
1
0
1
0
0.1750
0
1
0
1
0
1
1
0.9625
1
1
0
1
0
1
1
0.1625
0
1
0
1
1
0
0
0.9500
1
1
0
1
1
0
0
0.1500
0
1
0
1
1
0
1
0.9375
1
1
0
1
1
0
1
0.1375
0
1
0
1
1
1
0
0.9250
1
1
0
1
1
1
0
0.1250
0
1
0
1
1
1
1
0.9125
1
1
0
1
1
1
1
0.1125
0
1
1
0
0
0
0
0.9000
1
1
1
0
0
0
0
0.1000
0
1
1
0
0
0
1
0.8875
1
1
1
0
0
0
1
0.0875
0
1
1
0
0
1
0
0.8750
1
1
1
0
0
1
0
0.0750
0
1
1
0
0
1
1
0.8625
1
1
1
0
0
1
1
0.0625
0
1
1
0
1
0
0
0.8500
1
1
1
0
1
0
0
0.0500
0
1
1
0
1
0
1
0.8375
1
1
1
0
1
0
1
0.0375
0
1
1
0
1
1
0
0.8250
1
1
1
0
1
1
0
0.0250
0
1
1
0
1
1
1
0.8125
1
1
1
0
1
1
1
0.0125
0
1
1
1
0
0
0
0.8000
1
1
1
1
0
0
0
0
0
1
1
1
0
0
1
0.7875
1
1
1
1
0
0
1
0
0
1
1
1
0
1
0
0.7750
1
1
1
1
0
1
0
0
0
1
1
1
0
1
1
0.7625
1
1
1
1
0
1
1
0
0
1
1
1
1
0
0
0.7500
1
1
1
1
1
0
0
0
0
1
1
1
1
0
1
0.7375
1
1
1
1
1
0
1
0
0
1
1
1
1
1
0
0.7250
1
1
1
1
1
1
0
0
0
1
1
1
1
1
1
0.7125
1
1
1
1
1
1
1
OFF
Note: The MAX17582 enters the shutdown sequence if the OFF code is set, forcing PWRGD and PHASEGD low and forcing CLKEN
high. Exit from the OFF code follows the startup sequence. If the OFF code is present when SHDN is pulled high, the MAX17582
remains off.
______________________________________________________________________________________
27
MAX17582
Table 4. IMVP-6.5 Output-Voltage VID DAC Codes (continued)
MAX17582
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
Suspend Mode
When the processor enters low-power deeper sleep
mode, the CPU sets the VID DAC code to a lower output voltage and drives DPRSLPVR high. The MAX17582
responds by slewing the internal target voltage to the
new DAC code, switching to single-phase operation,
and letting the output voltage gradually drift down to
the deeper sleep voltage. During the transition, the
MAX17582 blanks both the upper and lower PWRGD
and CLKEN thresholds until 20μs after the internal target reaches the deeper sleep voltage. Once the 20μs
timer expires, the MAX17582 reenables the lower
PWRGD and CLKEN threshold, but keeps the upper
threshold blanked until the output voltage reaches the
regulation level. PHASEGD remains blanked high
impedance while DPRSLPVR is high.
t TRAN =
where dVTARGET/dt = 12.5mV/μs x 71.5kΩ/RTIME is the
slew rate, VOLD is the original output voltage, and VNEW
is the new target voltage. See TIME Slew Rate
Accuracy in the Electrical Characteristics for slew-rate
limits. For soft-start and shutdown, the controller automatically reduces the slew rate to 1/8.
The output voltage tracks the slewed target voltage,
making the transitions relatively smooth. The average
inductor current per phase required to make an outputvoltage transition is:
IL ≅
Output-Voltage-Transition Timing
The MAX17582 performs mode transitions in a controlled manner, automatically minimizing input surge currents. This feature allows the circuit designer to achieve
nearly ideal transitions, guaranteeing just-in-time arrival
at the new output-voltage level with the lowest possible
peak currents for a given output capacitance.
At the beginning of an output-voltage transition, the
MAX17582 blanks both PWRGD thresholds, preventing
the PWRGD open-drain output from changing states
during the transition. The controller enables the lower
PWRGD threshold approximately 20μs after the slewrate controller reaches the target output voltage, but the
upper PWRGD threshold remains blanked until the output voltage reaches the regulation level if the controller
enters pulse-skipping operation. The slew rate (set by
resistor RTIME) must be set fast enough to ensure that
the transition can be completed within the maximum
allotted time.
The MAX17582 automatically controls the current to the
minimum level required to complete the transition in the
calculated time. The slew-rate controller uses an internal capacitor and current source programmed by
RTIME to transition the output voltage. The total transition time depends on RTIME, the voltage difference, and
the accuracy of the slew-rate controller (CSLEW accuracy). The slew rate is not dependent on the total output
capacitance, as long as the surge current is less than
the current limit. For all dynamic VID transitions, the
transition time (tTRAN) is given by:
28
VNEW - VOLD
(dVTARGET dt)
COUT
× (dVTARGET dt )
ηTOTAL
where dVTARGET/dt is the required slew rate, COUT is
the total output capacitance, and ηTOTAL is the number
of active phases.
Deeper Sleep Transitions
When DPRSLPVR goes high, the MAX17582 immediately
disables phase 2 (DH2 and DL2 forced low), blanks
PHASEGD high impedance, and enters pulse-skipping
operation (see Figures 4 and 5). If the VIDs are set to a
lower voltage setting, the output drops at a rate determined by the load and the output capacitance. The internal target still ramps as before, and PWRGD remains
blanked high impedance until 20μs after the output voltage reaches the internal target.
•
Fast C4E Deeper Sleep Exit: When exiting deeper
sleep (DPRSLPVR pulled low) while the output voltage still exceeds the deeper sleep voltage, the
MAX17582 quickly slews (50mV/μs min regardless
of RTIME setting) the internal target voltage to the
DAC code provided by the processor as long as the
output voltage is above the new target. The controller remains in skip mode until the output voltage
equals the internal target. Once the internal target
reaches the output voltage, phase 2 is enabled. The
controller blanks PWRGD, PHASEGD, and CLKEN
until 20μs after the transition is completed. See
Figure 4.
______________________________________________________________________________________
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
MAX17582
ACTUAL VOUT
CPU CORE
VOLTAGE
INTERNAL TARGET
VID (D0–D6)
DEEPER SLEEP VID
DPRSLPVR
DO NOT CARE (DPRSLPVR DOMINATES STATE)
PSI
INTERNAL
PWM CONTROL
FORCED-PWM
1-PHASE SKIP (DH1 ACTIVE, DH2 = DL2 = FORCED LOW)
NO PULSES: VOUT > VTARGET
DH1
DH2
PWRGD
CLKEN
BLANK HIGH IMPEDANCE
BLANK LOW
PHASEGD
BLANK HIGH THRESHOLD ONLY
BLANK HIGH IMPEDANCE
BLANK HIGH THRESHOLD ONLY
BLANK LOW
BLANK HIGH IMPEDANCE (1-PHASE OPERATION)
tBLANK
20μs TYP
tBLANK
20μs TYP
Figure 4. C4E (C4 Early Exit) Transition
______________________________________________________________________________________
29
MAX17582
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
•
Standard C4 Deeper Sleep Exit: When exiting
deeper sleep (DPRSLPVR pulled low) while the output voltage is regulating to the deeper sleep
voltage, the MAX17582 immediately activates all
enabled phases and ramps the output voltage to the
LFM DAC code provided by the processor at the
slew rate set by R TIME . The controller blanks
PWRGD, PHASEGD, and CLKEN until 20μs after the
transition is completed. See Figure 5.
ACTIVE VID
CPU CORE
VOLTAGE
ACTUAL VOUT
INTERNAL
TARGET
VID (D0–D6)
DEEPER SLEEP VID
LFM VID
DPRSLP VID
LFM VID
DPRSLPVR
DO NOT CARE (DPRSLPVR DOMINATES STATE)
PSI
INTERNAL
PWM CONTROL
1-PHASE SKIP (DH1 ACTIVE, DH2 = DL2 = FORCED LOW)
1-PHASE FORCED-PWM
NO PULSES: VOUT > VTARGET
DH1
DH2
PWRGD
CLKEN
BLANK HIGH IMPEDANCE
BLANK LOW
BLANK HIGH THRESHOLD ONLY
BLANK HIGH IMPEDANCE
BLANK HIGH THRESHOLD ONLY
BLANK LOW
BLANK HIGH IMPEDANCE (1-PHASE OPERATION)
PHASEGD
tBLANK
20μs TYP
tBLANK
20μs TYP
Figure 5. Standard C4 Transition
30
______________________________________________________________________________________
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
high impedance for 32 switching cycles on DH2, allowing sufficient time/cycles for phases 1 and 2 to achieve
current balance. In a typical IMVP-6.5 application, the
VID is reduced by 1 LSB (12.5mV) when PSI is pulled
low, and is increased by 1 LSB when PSI is pulled high.
CPU FREQ
CPU LOAD
VID (D0–D6)
CPU CORE
VOLTAGE
PSI
INTERNAL
PWM CONTROL
2-PHASE PWM
1-PHASE PWM
2-PHASE PWM
PWRGD
BLANK HIGH IMPEDANCE
BLANK HIGH IMPEDANCE
CLKEN
BLANK LOW
BLANK LOW
BLANK HIGH IMPEDANCE
PHASEGD
tBLANK
20μs typ
tBLANK
20μs typ
32 SWITCHING CYCLES ON DH2
Figure 6. PSI Transition
______________________________________________________________________________________
31
MAX17582
PSI Transitions
When PSI is pulled low, the MAX17582 immediately disables phase 2 (DH2 and DL2 forced low), blanks
PHASEGD high impedance, and enters single-phase
PWM operation (see Figure 6). When PSI is pulled high,
the MAX17582 enables phase 2. PHASEGD is blanked
Forced-PWM Operation (Normal Mode)
During soft-shutdown and normal operation—when the
CPU is actively running (DPRSLPVR = low)—the
MAX17582 operates with the low-noise, forced-PWM
control scheme. Forced-PWM operation disables the
zero-crossing comparators of all active phases, forcing
the low-side gate-drive waveforms to constantly be the
complement of the high-side gate-drive waveforms.
This keeps the switching frequency constant and allows
the inductor current to reverse under light loads, providing fast, accurate negative output-voltage transitions
by quickly discharging the output capacitors.
Forced-PWM operation comes at a cost: the no-load 5V
bias supply current remains between 10mA to 50mA
per phase, depending on the external MOSFETs and
switching frequency. To maintain high efficiency under
light-load conditions, the processor can switch the controller to a low-power pulse-skipping control scheme
after entering suspend mode.
PSI determines how many phases are active when
operating in forced-PWM mode (DPRSLPVR = low).
When PSI is pulled low, the main phase remains active
but the secondary phase is disabled (DH2 and DL2
forced low).
Light-Load Pulse-Skipping Operation
(Deeper Sleep)
inductor-current operation. The PFM/PWM crossover
occurs when the load current of each phase is equal to
1/2 the peak-to-peak ripple current, which is a function
of the inductor value (Figure 7). For a battery input
range of 7V to 20V, this threshold is relatively constant,
with only a minor dependence on the input voltage due
to the typically low duty cycles. The total load current at
the PFM/PWM crossover threshold (I LOAD(SKIP) ) is
approximately:
⎞
⎛T V
⎞⎛V -V
ILOAD(SKIP) = ηTOTAL ⎜ SW OUT ⎟ ⎜ IN OUT ⎟
⎝
⎠⎝
L
VIN
⎠
where ηTOTAL is the number of active phases.
The switching waveforms might appear noisy and asynchronous when light loading activates pulse-skipping
operation, but this is a normal operating condition that
results in high light-load efficiency. Trade-offs between
PFM noise and light-load efficiency are made by varying the inductor value. Generally, low inductor values
produce a broader efficiency vs. load curve, while higher
values result in higher full-load efficiency (assuming that
the coil resistance remains fixed) and less output-voltage
ripple. Penalties for using higher inductor values include
larger physical size and degraded load-transient
response, especially at low input-voltage levels.
When DPRSLPVR is pulled high, the MAX17582 operates
with a single-phase pulse-skipping mode. The pulseskipping mode enables the driver’s zero-crossing comparator, so the controller pulls DL1 low when it detects
zero inductor current. This keeps the inductor from discharging the output capacitors and forces the controller
to skip pulses under light-load conditions to avoid overcharging the output.
The MAX17582 automatically uses forced-PWM operation
during soft-shutdown, regardless of the DPRSLPVR and
PSI configuration.
Automatic Pulse-Skipping Switchover
In skip mode (DPRSLPVR = high), an inherent automatic
switchover to PFM takes place at light loads (Figure 7).
This switchover is affected by a comparator that truncates the low-side switch on-time at the inductor current’s zero crossing. The zero-crossing comparator
senses the inductor current across the low-side
MOSFETs. Once VLX drops below the zero-crossing
comparator threshold (see the Electrical Characteristics
table), the comparator forces DL_ low. This mechanism
causes the threshold between pulse-skipping PFM and
nonskipping PWM operation to coincide with the
boundary between continuous and discontinuous
32
Δi
Δt
INDUCTOR CURRENT
MAX17582
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
VBATT - VOUT
L
IPEAK
ILOAD = IPEAK/2
0
ON-TIME
TIME
Figure 7. Pulse-Skipping/Discontinuous Crossover Point
______________________________________________________________________________________
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
t TRAN(START) =
8VBOOT
dV
( TARGET dt)
where dVTARGET/dt = 12.5mV/μs x 71.5kΩ/RTIME is the
slew rate. The soft-start circuitry does not use a variable
current limit, so full output current is available immediately. CLKEN is pulled low approximately 60μs after the
MAX17582 reaches the boot voltage if PGDIN is high.
At the same time, the MAX17582 slews the output to the
voltage set at the VID inputs at the programmed slew
rate. PWRGD and PHASEGD become high impedance
approximately 5ms after CLKEN is pulled low. The
MAX17582 automatically uses forced-PWM operation
during soft-start and soft-shutdown, regardless of the
DPRSLPVR and PSI configuration.
For automatic startup, the battery voltage should be
present before VCC. If the controller attempts to bring
the output into regulation without the battery voltage
present, the fault latch trips. The controller remains shut
down until the fault latch is cleared by toggling SHDN
or cycling the VCC power supply below 0.5V.
If the VCC voltage drops below 4.25V, the controller
assumes that there is not enough supply voltage to
make valid decisions. To protect the output from overvoltage faults, the controller shuts down immediately
and forces a high-impedance output.
VCC
SHDN
INVALID
CODE
VID (D0–D6)
INVALID
CODE
SOFT-START =
1/8 SLEW RATE SET
BY RTIME
SOFT-SHUTDOWN =
1/8 SLEW RATE SET
BY RTIME
VBOOT
VCORE
INTERNAL
PWM CONTROL
SKIP
FORCED-PWM
FORCED-PWM
PHASEGD
CLKEN
PWRGD
tBLANK
5ms TYP
tBLANK
60μs TYP
tBLANK
20μs TYP
tBLANK
60μs TYP
Figure 8. Power-Up and Shutdown Sequence Timing Diagram
______________________________________________________________________________________
33
MAX17582
Power-Up Sequence (POR, UVLO)
The MAX17582 is enabled when SHDN is driven high
(Figure 8). The internal reference powers up first. Once
the reference exceeds its UVLO threshold, the internal
analog blocks are turned on and masked by a 50μs
one-shot delay. The PWM controller is then enabled.
Power-on reset (POR) occurs when VCC rises above
approximately 2V, resetting the fault latch and preparing the controller for operation. The VCC UVLO circuitry
inhibits switching until VCC rises above 4.25V. The controller powers up the reference once the system
enables the controller, VCC is above 4.25V, and SHDN
is driven high. With the reference in regulation, the controller ramps the output voltage to the boot voltage at
1/8 the slew rate set by RTIME:
MAX17582
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
Shutdown
When SHDN goes low, the MAX17582 enters low-power
shutdown mode. PWRGD is pulled low immediately,
and the output voltage ramps down at 1/8 the slew rate
set by RTIME:
t TRAN(SHDN) =
8VOUT
dV
( TARGET dt)
where dVTARGET/dt = 12.5mV/μs x 71.5kΩ/RTIME is the
slew rate. Slowly discharging the output capacitors by
slewing the output over a long period of time keeps the
average negative inductor current low (damped
response), thereby eliminating the negative output-voltage excursion that occurs when the controller discharges the output quickly by permanently turning on
the low-side MOSFET (underdamped response). This
eliminates the need for the Schottky diode normally connected between the output and ground to clamp the
negative output-voltage excursion. After the controller
reaches the zero target, the MAX17582 shuts down
completely—the drivers are disabled (DL1 and DL2 driven low) and the supply current drops below 1μA.
When a fault condition—output UVLO or thermal shutdown—activates the shutdown sequence, the protection
circuitry sets the fault latch to prevent the controller from
restarting. To clear the fault latch and reactivate the controller, toggle SHDN or cycle VCC power below 0.5V.
Current Monitor (IMON)
The MAX17582 includes a unidirectional transconductance amplifier that sources current proportional to the
positive current-sense voltage. The IMON output current is defined by:
IIMON = Gm(IMON) x Σ (VCSP_ - VCSN_)
where Gm(IMON) = 2.4mS (typ) and the IMON current is
unidirectional (sources current out of IMON only) for
positive current-sense values. For negative currentsense voltages, the IMON current is zero.
The current monitor allows the processor to accurately
monitor the CPU load and quickly calculate the power
dissipation to determine if the system is about to overheat before the significantly slower temperature sensor
signals an over-temperature alert.
Connect an external resistor between IMON and GNDS
to create the desired IMON gain based on the following
equation:
RIMON = 0.9V/(IMAX x RSENSE(MIN) x Gm(IMON_MIN))
where IMAX is defined in the Current Monitor section of
the Intel IMVP-6.5 specification and based on discrete
34
increments (10A, 20A, 30A, 40A, etc.), RSENSE(MIN) is
the minimum effective value of the current-sense element (sense resistor or inductor DCR) that is used to
provide the current-sense voltage, and Gm(IMON_MIN)
is the minimum transconductance amplifier gain as
defined in the Electrical Characteristics table.
The IMON voltage is internally clamped to a maximum
of 1.1V (typ), preventing the IMON output from exceeding the IMON voltage rating even under overload or
short-circuit conditions. When the controller is disabled,
IMON is pulled to ground.
To filter the IMON signal, use an RC filter as shown in
Figure 1.
Phase Fault (PHASEGD)
The MAX17582 includes a phase-fault output that signals
the system that one of the two phases either has a fault
condition or is not matched with the other. Detection is
done by identifying the need for a large on-time difference between phases in order to achieve or move
towards current balance.
PHASEGD is high impedance when the controller operates in 1-phase mode (DPRSLPVR high or PSI low and
DPRSLPVR low). On exit to 2-phase mode, PHASEGD is
forced high impedance for 32 switching cycles on DH2.
PHASEGD is low in shutdown. PHASEGD is forced high
impedance whenever the slew-rate controller is active
(output-voltage transitions).
Temperature Comparator (VRHOT)
The MAX17582 also features an independent comparator with an accurate threshold (VHOT) that tracks the
analog supply voltage (VHOT = 0.3VCC). This makes the
thermal trip threshold independent of the VCC supply
voltage tolerance. Use a resistor- and thermistor-divider
between VCC and GND to generate a voltage-regulator
over-temperature monitor. Place the thermistor as close
to the MOSFETs and inductors as possible.
Output Undervoltage Protection (UVP)
The output UVP function is similar to foldback current limiting, but employs a timer rather than a variable current
limit. If the MAX17582 output voltage is 400mV below the
target voltage, the controller activates the shutdown
sequence and sets the fault latch. Once the controller
ramps down to zero, it forces DL1 and DL2 high and
pulls DH1 and DH2 low. Toggle SHDN or cycle the VCC
power supply below 0.5V to clear the fault latch and
reactivate the controller.
UVP can be disabled through the no-fault test mode
(see the No-Fault Test Mode section).
______________________________________________________________________________________
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
No-Fault Test Mode
The latched fault-protection features can complicate the
process of debugging prototype breadboards since
there are (at most) a few milliseconds in which to determine what went wrong. Therefore, a no-fault test mode is
provided to disable the fault protection—undervoltage
protection and thermal shutdown. Additionally, the test
mode clears the fault latch if it has been set. The no-fault
test mode is entered by forcing 11V to 13V on SHDN.
MOSFET Gate Drivers
The DH_ and DL_ drivers are optimized for driving
moderate-sized high-side and larger low-side power
MOSFETs. This is consistent with the low duty factor
seen in notebook applications, where a large V IN V OUT differential exists. The high-side gate drivers
(DH_) source and sink 2.2A, and the low-side gate drivers (DL_) source 2.7A and sink 8A. This ensures
robust gate drive for high-current applications. The DH_
floating high-side MOSFET drivers are powered by
internal boost switch charge pumps at BST_, while the
DL_ synchronous-rectifier drivers are powered directly
by the 5V bias supply (VDD).
Adaptive dead-time circuits monitor the DL_ and DH_
drivers and prevent either FET from turning on until the
other is fully off. The adaptive driver dead time allows
operation without shoot-through with a wide range of
MOSFETs, minimizing delays and maintaining efficiency.
There must be a low-resistance, low-inductance path
from the DL_ and DH_ drivers to the MOSFET gates for
the adaptive dead-time circuits to work properly; otherwise, the sense circuitry in the MAX17582 interprets the
MOSFET gates as off while charge actually remains.
Use very short, wide traces (50 mils to 100 mils wide if
the MOSFET is 1in from the driver).
The internal pulldown transistor that drives DL_ low is
robust, with a 0.25Ω (typ) on-resistance. This helps
prevent DL_ from being pulled up due to capacitive
coupling from the drain to the gate of the low-side
MOSFETs when the inductor node (LX_) quickly
switches from ground to VIN. Applications with high
input voltages and long inductive driver traces might
require that rising LX_ edges do not pull up the lowside MOSFETs’ gate, causing shoot-through currents.
The capacitive coupling between LX_ and DL_ created
by the MOSFET’s gate-to-drain capacitance (CRSS),
gate-to-source capacitance (CISS - CRSS), and additional board parasitics should not exceed the following
minimum threshold:
⎛C
⎞
VGS(TH) > VIN ⎜ RSS ⎟
C
⎝ ISS ⎠
Typically, adding a 4700pF capacitor between DL_ and
power ground (CNL in Figure 9), close to the low-side
MOSFETs, greatly reduces coupling. Do not exceed
22nF of total gate capacitance to prevent excessive
turn-off delays.
BST_
(RBST_)*
INPUT (VIN)
DH_
CBST_
NH
L
LX_
CBYP
VDD
DL_
NL
(CNL)*
PGND
(RBST_)* OPTIONAL—THE RESISTOR LOWERS EMI BY DECREASING THE
SWITCHING NODE RISE TIME.
(CNL)* OPTIONAL—THE CAPACITOR REDUCES LX_ TO DL_ CAPACITIVE
COUPLING THAT CAN CAUSE SHOOT-THROUGH CURRENTS.
Figure 9. Gate Drive Circuit
______________________________________________________________________________________
35
MAX17582
Thermal-Fault Protection
The MAX17582 features a thermal-fault-protection circuit. When the junction temperature rises above
+160°C, a thermal sensor sets the fault latch and activates the soft-shutdown sequence. Once the controller
ramps down to zero, it forces DL1 and DL2 high and
pulls DH1 and DH2 low. Toggle SHDN or cycle the VCC
power supply below 0.5V to clear the fault latch and
reactivate the controller after the junction temperature
cools by 15°C.
Thermal shutdown can be disabled through the no-fault
test mode (see the No-Fault Test Mode section).
MAX17582
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
Alternatively, shoot-through currents can be caused by
a combination of fast high-side MOSFETs and slow lowside MOSFETs. If the turn-off delay time of the low-side
MOSFETs is too long, the high-side MOSFETs can turn
on before the low-side MOSFETs have actually turned
off. Adding a resistor less than 5Ω in series with BST_
slows down the high-side MOSFET turn-on time, eliminating the shoot-through currents without degrading the
turn-off time (R BST_ in Figure 9). Slowing down the
high-side MOSFET also reduces the LX_ node rise time,
thereby reducing EMI and high-frequency coupling
responsible for switching noise.
Multiphase Quick-PWM
Design Procedure
Firmly establish the input-voltage range and maximum
load current before choosing a switching frequency
and inductor operating point (ripple-current ratio). The
primary design trade-off lies in choosing a good switching frequency and inductor operating point, and the following four factors dictate the rest of the design:
• Input-voltage range: The maximum value
(VIN(MAX)) must accommodate the worst-case high
AC adapter voltage. The minimum value (VIN(MIN))
must account for the lowest input voltage after drops
due to connectors, fuses, and battery selector
switches. If there is a choice at all, lower input voltages result in better efficiency.
• Maximum load current: There are two values to
consider. The peak load current (ILOAD(MAX)) determines the instantaneous component stresses and filtering requirements, and thus drives output
capacitor selection, inductor saturation rating, and
the design of the current-limit circuit. The continuous
load current (ILOAD) determines the thermal stresses and thus drives the selection of input capacitors,
MOSFETs, and other critical heat-contributing components. Modern notebook CPUs generally exhibit
ILOAD = ILOAD(MAX) x 80%.
•
For multiphase systems, each phase supports a
fraction of the load, depending on the current balancing. When properly balanced, the load current is
evenly distributed among each phase:
I
ILOAD(PHASE) = LOAD
ηTOTAL
where ηTOTAL is the total number of active phases.
36
•
•
Switching frequency: This choice determines the
basic trade-off between size and efficiency. The
optimal frequency is largely a function of maximum
input voltage, due to MOSFET switching losses that
are proportional to frequency and VIN2. The optimum frequency is also a moving target due to rapid
improvements in MOSFET technology that are making higher frequencies more practical.
Inductor operating point: This choice provides
trade-offs between size vs. efficiency and transient
response vs. output noise. Low inductor values provide better transient response and smaller physical
size, but also result in lower efficiency and higher
output noise due to increased ripple current. The
minimum practical inductor value is one that causes
the circuit to operate at the edge of critical conduction (where the inductor current just touches zero
with every cycle at maximum load). Inductor values
lower than this grant no further size-reduction benefit. The optimum operating point is usually found
between 20% and 50% ripple current.
Inductor Selection
The switching frequency and operating point (% ripple
current or LIR) determine the inductor value as follows:
⎛
⎞ ⎛ VOUT ⎞
VIN - VOUT
L = ηTOTAL ⎜
⎟⎜
⎟
f
I
LIR
⎝ SW LOAD(MAX)
⎠ ⎝ VIN ⎠
where ηTOTAL is the total number of phases.
Find a low-loss inductor having the lowest possible DC
resistance that fits in the allotted dimensions. Ferrite
cores are often the best choice, although powdered
iron is inexpensive and can work well at 200kHz. The
core must be large enough not to saturate at the peak
inductor current (IPEAK):
⎛ ILOAD(MAX) ⎞ ⎛ LIR ⎞
IPEAK = ⎜
⎟ ⎜ 1 + 2 ⎟⎠
⎝ ηTOTAL ⎠ ⎝
Transient Response
The inductor ripple current impacts transient-response
performance, especially at low VIN - VOUT differentials.
Low inductor values allow the inductor current to slew
faster, replenishing charge removed from the output filter capacitors by a sudden load step. The amount of
output sag is also a function of the maximum duty factor, which can be calculated from the on-time and minimum off-time. For a dual-phase controller, the
worst-case output sag voltage can be determined by:
______________________________________________________________________________________
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
)
where t OFF(MIN) is the minimum off-time (see the
Electrical Characteristics table). The amount of overshoot
due to stored inductor energy can be calculated as:
VSOAR ≈
( ΔILOAD(MAX) )2 L
2ηTOTAL COUT VOUT
where ηTOTAL is the total number of active phases.
Setting the Current Limit
The minimum current-limit threshold must be high
enough to support the maximum load current when the
current limit is at the minimum tolerance value. The valley of the inductor current occurs at ILOAD(MAX) minus
half the ripple current, therefore:
⎛ ILOAD(MAX) ⎞ ⎛ LIR ⎞
ILIMIT(LOW) > ⎜
⎟ ⎜ 1 - 2 ⎟⎠
⎝ ηTOTAL ⎠ ⎝
where ηTOTAL is the total number of active phases, and
ILIMIT(LOW) equals the minimum current-limit threshold
voltage divided by the current-sense resistor (RSENSE).
Output Capacitor Selection
The output filter capacitor must have low-enough ESR
to meet output ripple and load-transient requirements,
yet have high enough ESR to satisfy stability requirements.
In CPU VCORE converters and other applications where
the output is subject to large-load transients, the output
capacitor’s size typically depends on how much ESR is
needed to prevent the output from dipping too low
under a load transient. Ignoring the sag due to finite
capacitance:
(RESR + RPCB ) ≤
VSTEP
ΔILOAD(MAX)
In non-CPU applications, the output capacitor’s size
often depends on how much ESR is needed to maintain
an acceptable level of output ripple voltage. The output
ripple voltage of a step-down controller equals the total
inductor ripple current multiplied by the output capacitor’s ESR. When operating multiphase systems out-ofphase, the peak inductor currents of each phase are
staggered, resulting in lower output ripple voltage by
reducing the total inductor ripple current. For multiphase operation, the maximum ESR to meet ripple
requirements is:
⎤
⎡
VINfSWL
RESR ≤ ⎢
⎥ VRIPPLE
⎢⎣ ( VIN - ηTOTAL VOUT ) VOUT ⎥⎦
where ηTOTAL is the total number of active phases, and
fSW is the switching frequency per phase. The actual
capacitance value required relates to the physical size
needed to achieve low ESR, as well as to the chemistry
of the capacitor technology. Thus, the capacitor is usually selected by ESR and voltage rating rather than by
capacitance value (this is true of polymer types).
When using low-capacity ceramic filter capacitors,
capacitor size is usually determined by the capacity
needed to prevent V SAG and V SOAR from causing
problems during load transients. Generally, once
enough capacitance is added to meet the overshoot
requirement, undershoot at the rising load edge is no
longer a problem (see the VSAG and VSOAR equations
in the Transient Response section).
Output Capacitor Stability Considerations
For Quick-PWM controllers, stability is determined by
the value of the ESR zero relative to the switching frequency. The boundary of instability is given by the following equation:
f
fESR ≤ SW
π
where:
fESR =
1
2πREFF COUT
and:
REFF = RESR + RDROOP + RPCB
where COUT is the total output capacitance, RESR is the
total equivalent series resistance, RDROOP is the voltage-positioning gain, and RPCB is the parasitic board
resistance between the output capacitors and sense
resistors.
______________________________________________________________________________________
37
MAX17582
⎤
L ΔILOAD(MAX)
⎢⎜
MIN) ⎥
⎟⎠ + tOFF(M
V
⎝
IN
⎣
⎦ +
VSAG =
⎡⎛ ( VIN - 2VOUT ) TSW ⎞
⎤
2COUT VOUT ⎢⎜
⎟ - 2tOFF(MIN) ⎥
V
⎝
⎠
⎢⎣
⎥⎦
IN
ΔILOAD(MAX) ⎡⎛ VOUT TSW ⎞
⎤
⎢⎜
⎟⎠ + tOFF(MIN) ⎥
2COUT
VIN
⎢⎣⎝
⎥⎦
(
2 ⎡⎛ VOUT TSW ⎞
MAX17582
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
For a standard 300kHz application, the ESR zero frequency must be well below 95kHz, preferably below
50kHz. Tantalum, Sanyo POSCAP, and Panasonic SP
capacitors in widespread use at the time of publication
have typical ESR zero frequencies below 50kHz. In the
standard application circuit, the ESR needed to support
a 30mVP-P ripple is 30mV/(40A x 0.3) = 2.5mΩ. Four
330μF/2.5V Panasonic SP (type SX) capacitors in parallel provide 1.5mΩ (max) ESR. With a 2mΩ droop and
0.5mΩ PCB resistance, the typical combined ESR
results in a zero at 30kHz.
Ceramic capacitors have a high-ESR zero frequency,
but applications with significant voltage positioning can
take advantage of their size and low ESR. Do not put
high-value ceramic capacitors directly across the output without verifying that the circuit contains enough
voltage positioning and series PCB resistance to
ensure stability. When only using ceramic output
capacitors, output overshoot (VSOAR) typically determines the minimum output capacitance requirement.
Their relatively low capacitance value can cause output
overshoot when stepping from full-load to no-load conditions, unless a small inductor value is used (high
switching frequency) to minimize the energy transferred
from inductor to capacitor during load-step recovery.
Unstable operation manifests itself in two related but
distinctly different ways: double pulsing and feedbackloop instability. Double pulsing occurs due to noise on
the output or because the ESR is so low that there is not
enough voltage ramp in the output-voltage signal. This
“fools” the error comparator into triggering a new cycle
immediately after the minimum off-time period has
expired. Double pulsing is more annoying than harmful,
resulting in nothing worse than increased output ripple.
However, it can indicate the possible presence of loop
instability due to insufficient ESR. Loop instability can
result in oscillations at the output after line or load
steps. Such perturbations are usually damped, but can
cause the output voltage to rise above or fall below the
tolerance limits.
The easiest method for checking stability is to apply a
very fast zero-to-max load transient and carefully
observe the output-voltage-ripple envelope for overshoot and ringing. It can help to simultaneously monitor
the inductor current with an AC current probe. Do not
allow more than one cycle of ringing after the initial
step-response under/overshoot.
38
Input Capacitor Selection
The input capacitor must meet the ripple current
requirement (IRMS) imposed by the switching currents.
The multiphase Quick-PWM controllers operate out-ofphase while the Quick-PWM slave controllers provide
selectable out-of-phase or in-phase on-time triggering.
Out-of-phase operation reduces the RMS input current
by dividing the input current between several staggered stages. For duty cycles less than 100%/ηOUTPH
per phase, the IRMS requirements can be determined
by the following equation:
⎛ I
⎞
IRMS = ⎜ LOAD ⎟ ηTOTAL VOUT ( VIN - ηTOTAL VOUT )
⎝ ηTOTAL VIN ⎠
where η TOTAL is the total number of out-of-phase
switching regulators. The worst-case RMS current
requirement occurs when operating with V IN =
2ηTOTALVOUT. At this point, the above equation simplifies to IRMS = 0.5 x ILOAD/ηTOTAL.
For most applications, nontantalum chemistries (ceramic, aluminum, or OS-CON) are preferred due to their
resistance to inrush surge currents typical of systems
with a mechanical switch or connector in series with the
input. If the Quick-PWM controller is operated as the
second stage of a two-stage power-conversion system,
tantalum input capacitors are acceptable. In either configuration, choose an input capacitor that exhibits less
than +10°C temperature rise at the RMS input current
for optimal circuit longevity.
Power-MOSFET Selection
Most of the following MOSFET guidelines focus on the
challenge of obtaining high load-current capability
when using high-voltage (> 20V) AC adapters. Lowcurrent applications usually require less attention.
The high-side MOSFET (NH) must be able to dissipate
the resistive losses plus the switching losses at both
V IN(MIN) and V IN(MAX) . Calculate both these sums.
Ideally, the losses at VIN(MIN) should be approximately
equal to losses at V IN(MAX) , with lower losses in
between. If the losses at VIN(MIN) are significantly higher than the losses at VIN(MAX), consider increasing the
size of NH (reducing RDS(ON) but with higher CGATE).
Conversely, if the losses at VIN(MAX) are significantly
higher than the losses at VIN(MIN), consider reducing
the size of NH (increasing RDS(ON) to lower CGATE). If
V IN does not vary over a wide range, the minimum
power dissipation occurs where the resistive losses
equal the switching losses.
______________________________________________________________________________________
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
MOSFET Power Dissipation
Worst-case conduction losses occur at the duty factor
extremes. For the high-side MOSFET (NH), the worstcase power dissipation due to resistance occurs at the
minimum input voltage:
2
⎞
⎛V
⎞⎛ I
PD (NH Re sistive) = ⎜ OUT ⎟ ⎜ LOAD ⎟ RDS(ON)
⎝ VIN ⎠ ⎝ ηTOTAL ⎠
where ηTOTAL is the total number of phases.
Generally, a small high-side MOSFET is desired to
reduce switching losses at high input voltages.
However, the RDS(ON) required to stay within package
power dissipation often limits how small the MOSFET
can be. Again, the optimum occurs when the switching
losses equal the conduction (RDS(ON)) losses. Highside switching losses do not usually become an issue
until the input is greater than approximately 15V.
Calculating the power dissipation in high-side MOSFET
(NH) due to switching losses is difficult since it must
allow for difficult quantifying factors that influence the
turn-on and turn-off times. These factors include the
internal gate resistance, gate charge, threshold voltage, source inductance, and PCB layout characteristics. The following switching-loss calculation provides
only a very rough estimate and is no substitute for
breadboard evaluation, preferably including verification
using a thermocouple mounted on NH:
⎛ VIN(MAX)ILOAD fSW ⎞ ⎛ QG(SW) ⎞
PD (NH Switching) = ⎜
⎟⎜ I
⎟
ηTOTAL
⎝
⎠ ⎝ GATE ⎠
C
V 2f
+ OSS IN SW
2
where COSS is the NH MOSFET’s output capacitance,
Q G(SW) is the charge needed to turn on the N H
MOSFET, and IGATE is the peak gate-drive source/sink
current (2.2A typ).
Switching losses in the high-side MOSFET can become
an insidious heat problem when maximum AC adapter
voltages are applied due to the squared term in the C x
VIN2 x ƒSW switching-loss equation. If the high-side
MOSFET chosen for adequate RDS(ON) at low-battery
voltages becomes extraordinarily hot when biased from
V IN(MAX) , consider choosing another MOSFET with
lower parasitic capacitance.
For the low-side MOSFET (NL), the worst-case power
dissipation always occurs at maximum input voltage:
⎡ ⎛ V
⎞ ⎤ ⎛ ILOAD ⎞ 2
OUT
PD (NL Re sistive) = ⎢1- ⎜
⎟ ⎥⎜
⎟ RDS(ON)
⎢⎣ ⎝ VIN(MAX) ⎠ ⎥⎦ ⎝ ηTOTAL ⎠
The worst case for MOSFET power dissipation occurs
under heavy overloads that are greater than
ILOAD(MAX), but are not quite high enough to exceed
the current limit and cause the fault latch to trip. To protect against this possibility, you can over design the circuit to tolerate:
ΔI
⎛
⎞
ILOAD = ηTOTAL ⎜ IVALLEY(MAX) + INDUCTOR ⎟
⎝
⎠
2
⎛ ILOAD(MAX)LIR ⎞
= ηTOTALIVALLEY(MAX) + ⎜
⎟
2
⎝
⎠
where I VALLEY(MAX) is the maximum valley current
allowed by the current-limit circuit, including threshold
tolerance and on-resistance variation. The MOSFETs
must have a good-size heatsink to handle the overload
power dissipation.
Choose a Schottky diode (DL) with a forward voltage
low enough to prevent the low-side MOSFET body
diode from turning on during the dead time. Select a
diode that can handle the load current per phase during the dead times. This diode is optional and can be
removed if efficiency is not critical.
Boost Capacitors
The boost capacitors (CBST_) must be selected large
enough to handle the gate-charging requirements of
the high-side MOSFETs. Typically, 0.1μF ceramic
capacitors work well for low-power applications driving
medium-sized MOSFETs. However, high-current applications driving large, high-side MOSFETs require boost
capacitors larger than 0.1μF. For these applications,
select the boost capacitors to avoid discharging the
capacitor more than 200mV while charging the highside MOSFETs’ gates:
CBST _ =
N × QGATE
200mV
where N is the number of high-side MOSFETs used for
one regulator, and QGATE is the gate charge specified
in the MOSFET’s data sheet. For example, assume (2)
IRF7811W n-channel MOSFETs are used on the high
______________________________________________________________________________________
39
MAX17582
Choose a low-side MOSFET that has the lowest possible
on-resistance (RDS(ON)), comes in a moderate-sized
package (i.e., one or two 8-pin SOs, DPAK, or D2PAK),
and is reasonably priced. Make sure that the DL_ gate
driver can supply sufficient current to support the gate
charge and the current injected into the parasitic gateto-drain capacitor caused by the high-side MOSFET
turning on; otherwise, cross-conduction problems might
occur (see the MOSFET Gate Drivers section).
MAX17582
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
side. According to the manufacturer’s data sheet, a single IRF7811W has a maximum gate charge of 24nC
(VGS = 5V). Using the above equation, the required
boost capacitance would be:
CBST_ =
2 × 24nC
= 0.24μF
200mV
Selecting the closest standard value, this example
requires a 0.22μF ceramic capacitor.
Current-Balance Compensation (CCI)
The current-balance compensation capacitor (CCCI)
integrates the difference between the main and secondary current-sense voltages. The internal compensation resistor (R CCI = 200kΩ) improves transient
response by increasing the phase margin. This allows
the dynamics of the current-balance loop to be optimized. Excessively large capacitor values increase the
integration time constant, resulting in larger current differences between the phases during transients.
Excessively small capacitor values allow the current
loop to respond cycle-by-cycle, but can result in small
DC current variations between the phases. For most
applications, a 470pF capacitor from CCI to the switching regulator’s output works well.
Connecting the compensation network to the output
(VOUT) allows the controller to feed-forward the outputvoltage signal, especially during transients.
Voltage Positioning and
Loop Compensation
Voltage positioning dynamically lowers the output voltage in response to the load current, reducing the output capacitance and processor’s power-dissipation
requirements. The controller uses a transconductance
amplifier to set the transient and DC output-voltage
droop (Figure 2) as a function of the load. This adjustability allows flexibility in the selected current-sense
resistor value or inductor DCR, and allows smaller current-sense resistance to be used, reducing the overall
power dissipated.
Steady-State Voltage Positioning
Connect a resistor (RFB) between FB and VOUT to set
the DC steady-state droop (load line) based on the
required voltage-positioning slope (RDROOP):
RFB =
RDROOP
RSENSEGm(FB)
where the effective current-sense resistance (RSENSE)
depends on the current-sense method (see the Current
Sense section), and the voltage-positioning amplifier’s
40
transconductance (G m(FB) ) is typically 600μS as
defined in the Electrical Characteristics table. The controller sums together the input signals of the currentsense inputs (CSP_, CSN_).
When the inductors’ DCR is used as the current-sense
element (RSENSE = RDCR), each current-sense input
should include an NTC thermistor to minimize the temperature dependence of the voltage-positioning slope.
Minimum Input-Voltage Requirements
and Dropout Performance
The output-voltage-adjustable range for continuousconduction operation is restricted by the nonadjustable
minimum off-time one-shot and the number of phases.
For best dropout performance, use the slower (200kHz)
on-time settings. When working with low input voltages,
the duty-factor limit must be calculated using worstcase values for on- and off-times. Manufacturing tolerances and internal propagation delays introduce an
error to the on-times. This error is greater at higher frequencies. Also, keep in mind that transient-response
performance of buck regulators operated too close to
dropout is poor, and bulk output capacitance must
often be added (see the V SAG equation in the
Multiphase Quick-PWM Design Procedure section).
The absolute point of dropout is when the inductor current ramps down during the minimum off-time (ΔIDOWN)
as much as it ramps up during the on-time (ΔIUP). The
ratio h = ΔIUP/ΔIDOWN is an indicator of the ability to
slew the inductor current higher in response to
increased load, and must always be greater than 1. As
h approaches 1, the absolute minimum dropout point,
the inductor current cannot increase as much during
each switching cycle and V SAG greatly increases
unless additional output capacitance is used.
A reasonable minimum value for h is 1.5, but adjusting
this up or down allows trade-offs between VSAG, output
capacitance, and minimum operating voltage. For a
given value of h, the minimum operating voltage can be
calculated as:
⎡ V -V
+ VDROP1 ⎤
VIN(MIN) = ηTOTAL ⎢ FB DROOP
⎥+
⎢⎣1 - ηTOTALh × tOFF(MIN)fSW ⎥⎦
VDROP2 - VDROP1 + VDROOP
where η TOTAL is the total number of out-of-phase
switching regulators, V FB is the voltage-positioning
droop, VDROP1 and VDROP2 are the parasitic voltage
drops in the discharge and charge paths (see the OnTime One-Shot section), and t OFF(MIN) is from the
Electrical Characteristics table. The absolute minimum
input voltage is calculated with h = 1.
______________________________________________________________________________________
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
Dropout design example:
VFB = 1.4V
fSW = 300kHz
tOFF(MIN) = 400ns
VDROOP = 3mV/A x 30A = 90mV
VDROP1 = VDROP2 = 150mV (30A Load)
•
•
h = 1.5 and ηTOTAL = 2:
⎡ 1.4V - 90mV + 150mV
⎤
VIN(MIN) = 2 × ⎢
⎥+
3
00
kHz
)
(
.
.
μs
×
×
×
1
2
0
4
1
5
⎣
⎦
150mV - 150mV + 90mV = 4.96V
•
Calculating again with h = 1 gives the absolute limit of
dropout:
⎡ 1.4V - 90mV + 150mV
⎤
VIN(MIN) = 2 × ⎢
⎥+
3
00
kHz
)
(
.
.
μs
×
×
×
1
2
0
4
1
0
⎣
⎦
150mV - 150mV + 90mV = 4.07V
Therefore, VIN must be greater than 4.1V, even with very
large output capacitance, and a practical input voltage
with reasonable output capacitance would be 5.0V.
Applications Information
PCB Layout Guidelines
Careful PCB layout is critical to achieve low switching
losses and clean, stable operation. The switching
power stage requires particular attention. If possible,
mount all the power components on the top side of the
board with their ground terminals flush against one
another. Refer to the MAX17582 evaluation kit specification for a layout example and follow these guidelines
for good PCB layout:
•
Keep the high-current paths short, especially at the
ground terminals. This is essential for stable, jitterfree operation.
•
Connect all analog grounds to a separate solid copper plane, which connects to the GND pin of the
Quick-PWM controller. This includes the VCC, FB,
and GNDS bypass capacitors.
Keep the power traces and load connections short.
This is essential for high efficiency. The use of thick
•
•
copper PCBs (2oz vs. 1oz) can enhance full-load
efficiency by 1% or more. Correctly routing PCB
traces is a difficult task that must be approached in
terms of fractions of centimeters, where a single mΩ
of excess trace resistance causes a measurable
efficiency penalty.
Keep the high-current, gate-driver traces (DL_,
DH_, LX_, and BST_) short and wide to minimize
trace resistance and inductance. This is essential
for high-power MOSFETs that require low-impedance gate drivers to avoid shoot-through currents.
CSP_ and CSN_ connections for current limiting
and voltage positioning must be made using Kelvinsense connections to guarantee the current-sense
accuracy.
When trade-offs in trace lengths must be made, it is
preferable to allow the inductor charging path to be
made longer than the discharge path. For example,
it is better to allow some extra distance between the
input capacitors and the high-side MOSFET than to
allow distance between the inductor and the lowside MOSFET or between the inductor and the output filter capacitor.
Route high-speed switching nodes away from sensitive analog areas (CCI, FB, CSP_, CSN_, etc.).
Layout Procedure
1) Place the power components first, with ground terminals adjacent (low-side MOSFET source, C IN,
COUT, and D1 anode). If possible, make all these
connections on the top layer with wide, copperfilled areas.
2) Mount the controller IC adjacent to the low-side
MOSFET. The DL_ gate traces must be short and
wide (50 mils to 100 mils wide if the MOSFET is 1in
from the controller IC).
3) Group the gate-drive components (BST_ diodes
and capacitors, VDD bypass capacitor) together
near the controller IC.
4) Make the DC-DC controller ground connections as
shown in Figure 1. This diagram can be viewed as
having four separate ground planes: input/output
ground, where all the high-power components go;
the power ground plane, where the GND pin and
V DD bypass capacitor go; the master’s analog
ground plane, where sensitive analog components
go, and the master’s GND pin and V CC bypass
capacitor go; and the slave’s analog ground plane,
where the slave’s GND pin and VCC bypass capacitor go. The master’s GND plane must meet the GND
plane only at a single point directly beneath the IC.
______________________________________________________________________________________
41
MAX17582
If the calculated VIN(MIN) is greater than the required
minimum input voltage, then reduce the operating frequency or add output capacitance to obtain an acceptable VSAG. If operation near dropout is anticipated,
calculate V SAG to be sure of adequate transient
response.
MAX17582
Dual-Phase, Quick-PWM Controller for
IMVP-6.5 CPU Core Power Supplies
Similarly, the slave’s GND plane must meet the
GND plane only at a single point directly beneath
the IC. The respective master and slave ground
planes should connect to the high-power output
ground with a short metal trace from GND to the
source of the low-side MOSFET (the middle of the
star ground). This point must also be very close to
the output capacitor ground terminal.
5) Connect the output power planes (VCORE and system ground planes) directly to the output filter
capacitor positive and negative terminals with multiple vias. Place the entire DC-DC converter circuit as
close to the CPU as is practical.
Package Information
Chip Information
PROCESS: BiCMOS
For the latest package outline information and land patterns, go
to www.maxim-ic.com/packages.
PACKAGE TYPE
PACKAGE CODE
DOCUMENT NO.
48 TQFN-EP
T4866+2
21-0141
Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are
implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.
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