MAXIM MAX8707ETL

19-3360; Rev 0; 8/04
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
The MAX8707 is a multiphase (3-/4-phase), interleaved,
fixed-frequency, step-down controller for AMD Hammer
CPU core supplies. Interleaved multiphase operation
reduces the input ripple current and output voltage ripple
while easing component selection and layout placement.
The MAX8707 includes active voltage positioning with
adjustable gain and offset, reducing power dissipation
and bulk output-capacitance requirements.
The MAX8707 is intended for two different notebook
CPU core applications: stepping down the battery
directly or stepping down the +5V system supply to
create the core voltage. The single-stage conversion
method allows these devices to directly step down
high-voltage batteries for the highest possible efficiency. Alternatively, 2-stage conversion (stepping down
the +5V system supply instead of the battery) at higher
switching frequency provides the minimum possible
physical size.
The MAX8707 features dedicated differential currentsense inputs for each phase and includes a fifth pair of
current-sense inputs to provide an accurate voltagepositioning slope and average current-limit protection
using a single current-sense resistor. The MAX8707 also
has two dedicated inputs that provide differential remote
voltage sensing.
The MAX8707 provides an analog input for setting the
suspend voltage and a slew-rate controller for transitions between VID codes or the suspend voltage. The
controllers reduce the transition slew rate during startup
and shutdown, providing soft-start with minimal input
surge current and damped soft-shutdown without negative output undershoot. The MAX8707 includes output
fault protection—undervoltage, nonlatched overvoltage,
and thermal overload—and an independent voltageregulator power-OK (VROK) output.
The MAX8707 has a selectable switching frequency,
allowing 200kHz, 300kHz, or 600kHz per-phase operation. The MAX8707 is available in the low-profile, 40-pin,
6mm x 6mm thin QFN package. Refer to the MAX8702/
MAX8703 for compatible drivers.
Features
♦ 3-/4-Phase Interleaved Fixed-Frequency
Controller
♦ ±0.75% VOUT Accuracy Over Line, Load, and
Temperature
♦ 5-Bit On-Board Digital-to-Analog Converter
(DAC)—0.80V to 1.55V
♦ Adjustable Suspend Voltage Input
♦ Active Voltage Positioning with Adjustable Gain
and Offset
♦ Accurate Lossless Current Balance
♦ Accurate Droop and Current Limit
♦ Remote Output and Ground Sense
♦ Output Slew-Rate Control
♦ Power-Good Window Comparator
♦ Selectable 200kHz/300kHz/600kHz Switching
Frequency
♦ Output Overvoltage and Undervoltage Protection
♦ Thermal Fault Protection
♦ 2V ±0.7% Reference Output
♦ Soft-Startup and Shutdown
Ordering Information
PART
TEMP RANGE
PIN-PACKAGE
MAX8707ETL
-40°C to +85°C
40 Thin QFN 6mm x 6mm
Applications
AMD Hammer Desknote Computers
Multiphase CPU Core Supplies
Voltage-Positioned Step-Down Converters
Notebook/Desktop Computers
Servers
Pin Configuration appears at end of data sheet.
________________________________________________________________ Maxim Integrated Products
For pricing, delivery, and ordering information, please contact Maxim/Dallas Direct! at
1-888-629-4642, or visit Maxim’s website at www.maxim-ic.com.
1
MAX8707
General Description
MAX8707
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
ABSOLUTE MAXIMUM RATINGS
SHDN to GND (Note 1)...........................................-0.3V to +14V
REF Short-Circuit Duration .........................................Continuous
Continuous Power Dissipation (TA = +70°C)
40-Pin 6mm x 6mm Thin QFN
(derate 26.3mW/°C above +70°C) ................................2.105W
Operating Temperature Range ...........................-40°C to +85°C
Junction Temperature ......................................................+150°C
Storage Temperature Range .............................-65°C to +150°C
Lead Temperature (soldering, 10s) .................................+300°C
VCC to GND ..............................................................-0.3V to +6V
D0–D4 to GND..........................................................-0.3V to +6V
SKIP, SUS, VROK, ILIM(AVE) to GND......................-0.3V to +6V
SUSV, OFS, OSC to GND.........................................-0.3V to +6V
CSP_, CSN_, CRSP, CRSN to GND .........................-0.3V to +6V
VPS, FBS, CCV, REF to GND .....................-0.3V to (VCC + 0.3V)
ILIM(PK), TRC, TIME to GND .....................-0.3V to (VCC + 0.3V)
PWM_, DRSKP to PGND ............................-0.3V to (VCC + 0.3V)
PGND, GNDS to GND ...........................................-0.3V to +0.3V
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.
Note 1: SHDN can be forced to 12V for debugging prototype boards using the no-fault test mode, which disables fault protection.
ELECTRICAL CHARACTERISTICS
(Circuit of Figure 1. VCC = VSHDN = 5V, OSC = REF, VVPS = VFBS = VCRSN = VCRSP = VCSP_ = 1.20V, VSUSV = 0.8V, OFS = SUS =
GNDS = PGND = SKIP = GND, D0–D4 set for 1.20V (D0–D4 = 01110). TA = 0°C to +85°C, unless otherwise specified. Typical values
are at TA = +25°C.)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
4.5
5.5
V
DAC codes from
1.10V to 1.55V
-0.75
+0.75
DAC codes from
0.80V to 1.075V
-2.0
+2.0
SUS = VCC
-20
+20
mV
0.4
2.0
V
µA
PWM CONTROLLER
Input Voltage Range
VCC
DC Output Voltage Accuracy
VOUT
SUSV Input Range
VSUSV
SUSV Input-Bias Current
ISUSV
OFS Input Range
OFS GAIN
OFS Input-Bias Current
VOFS
AOFS
IOFS
GNDS Input Range
VGNDS
GNDS Gain
AGNDS
GNDS Input-Bias Current
IGNDS
FBS Input-Bias Current
Switching Frequency Accuracy
(Per Phase)
2
IFBS
fSW
Includes loadregulation error
(VPS = FBS)
%
VSUSV = 0.4V to 2V
-0.1
+0.1
Negative offsets
0
0.8
Positive offsets
1.2
2.0
∆VOUT / ∆VOFS, ∆VOFS = VOFS,
VOFS = 0 to 0.8V
-0.131
-0.125
-0.118
∆VOUT / ∆VOFS, ∆VOFS = VOFS-VREF,
VOFS = 1.2V to 2V
-0.131
-0.125
-0.118
VOFS = 0 to 2V
∆VOUT / ∆VGNDS,
-200mV ≤ VGNDS ≤ +200mV
V
V/V
-0.1
+0.1
µA
-200
+200
mV
1.05
V/V
+2
µA
+10
µA
0.95
1.00
-2
CRSP = CRSN, CSP_ = CSN_
-10
OSC = GND
180
200
220
OSC = REF
270
300
330
OSC = VCC
540
600
660
_______________________________________________________________________________________
kHz
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
(Circuit of Figure 1. VCC = VSHDN = 5V, OSC = REF, VVPS = VFBS = VCRSN = VCRSP = VCSP_ = 1.20V, VSUSV = 0.8V, OFS = SUS =
GNDS = PGND = SKIP = GND, D0–D4 set for 1.20V (D0–D4 = 01110). TA = 0°C to +85°C, unless otherwise specified. Typical values
are at TA = +25°C.)
PARAMETER
SYMBOL
TIME Slew-Rate Accuracy
CONDITIONS
MIN
TYP
MAX
RTIME = 143kΩ (6.25mV/µs)
-10
+10
RTIME = 47kΩ (19mV/µs) to 392kΩ
(2.28mV/µs)
-15
+15
Startup and shutdown, RTIME = 47kΩ
(4.75mV/µs) to 392kΩ (0.57mV/µs)
-20
+20
UNITS
%
BIAS AND REFERENCE
Quiescent Supply Current (VCC)
ICC
Shutdown Supply Current (VCC)
ICC(SHDN)
Reference Voltage
VREF
Reference Load Regulation
∆VREF
Measured at VCC, VPS and FBS forced
above the regulation points
7
Measured at VCC, SHDN = GND
VCC = 4.5V to 5.5V, IREF = 0
IREF = 0 to 500µA
1.986
-2
IREF = -100µA to 0
12
mA
0.05
10
µA
2.000
2.014
V
-0.2
0.21
6.2
mV
FAULT PROTECTION
Output Overvoltage-Protection
Threshold
VOVP
Measured at VPS
with respect to
unloaded output
voltage, rising edge,
8mV hysteresis
PWM (SKIP = GND)
or SKIP mode when
VOUT ≤ VTRIP
150
200
250
SKIP = VCC and
VOUT > VTRIP
1.70
1.75
1.80
Minimum OVP level
1.1
10
mV
V
Output Overvoltage Propagation
Delay
tOVP
VPS forced 25mV above trip threshold
Output Undervoltage-Protection
Threshold
VUVP
Measured at VPS with respect to 70% of the
unloaded nominal output voltage
Output Undervoltage
Propagation Delay
tUVP
VPS forced 25mV below trip threshold
10
µs
Measured from the time when VPS reaches
the target voltage, slew rate set by RTIME
(Note 2)
20
µs
VROK Transition Blanking Time
tBLANK
Undervoltage measured at VPS with
respect to 87.5% unloaded output voltage,
falling edge, 15mV hysteresis
-30
µs
+30
-30
mV
+30
VROK Threshold
mV
Overvoltage measured at VPS with respect
to 112.5% of the unloaded output voltage,
rising edge, 15mV hysteresis
VROK Delay
tVROK
VPS forced 25mV outside the VROK trip
thresholds
VROK Output Low Voltage
ISINK = 3mA
VROK Leakage Current
High state, VROK forced to 5.5V
-30
+30
10
µs
0.4
V
1
µA
_______________________________________________________________________________________
3
MAX8707
ELECTRICAL CHARACTERISTICS (continued)
MAX8707
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
ELECTRICAL CHARACTERISTICS (continued)
(Circuit of Figure 1. VCC = VSHDN = 5V, OSC = REF, VVPS = VFBS = VCRSN = VCRSP = VCSP_ = 1.20V, VSUSV = 0.8V, OFS = SUS =
GNDS = PGND = SKIP = GND, D0–D4 set for 1.20V (D0–D4 = 01110). TA = 0°C to +85°C, unless otherwise specified. Typical values
are at TA = +25°C.)
PARAMETER
VCC Undervoltage-Lockout
Threshold
Thermal-Shutdown Threshold
SYMBOL
VUVLO(VCC)
TSHDN
CONDITIONS
Rising edge, hysteresis = 20mV, PWM_
disabled below this level
MIN
TYP
MAX
UNITS
4.10
4.25
4.45
V
Rising edge hysteresis = 15°C
°C
+160
DROOP AND TRANSIENT RESPONSE
DC Droop Amplifier Offset
-1.5
+1.5
mV
DC Droop Amplifier
Transconductance
(CRS Sense Enabled)
Gm(VPS)
∆IVPS / (N x ∆VCRS), VVPS = VCRSN = 1.2V,
VCRSP - VCRSN = -60mV to +60mV,
N = number of phases enabled
194
200
206
µS
DC Droop Amplifier
Transconductance
(CRS Sense Disabled)
Gm(VPS)
∆IVPS / (Σ∆VCS), VCRSP = VCC,
VVPS = VCSN_ = 1.2V,
VCSP_ – VCSN_ = -60mV to +60mV
194
200
206
µS
Transient-Droop Transresistance
RTRANS
Current-sense gain (ACS = 10 typ) divided
by the voltage preamplifier
transconductance (Gm(TRC) = 2ms typ)
4.75
5.0
5.25
kΩ
Measured at VPS with respect to steadystate VPS regulation voltage; falling edge,
5.5mV hysteresis (typ)
-30
-25
-20
mV
CSP_ - CSN_
-2.0
+2.0
mV
VREF
- 1.0
VREF
- 0.2
V
mV
Transient Detection Threshold
CURRENT LIMIT AND BALANCE
Current-Sense Input Preamplifier
Offsets
ILIM(AVE) Input Range
(Adjustable Mode)
VILIM(AVE)
ILIM(AVE) Average Current-Limit
Threshold Voltage
(Positive, Default)
VAVELIMIT
CRSP - CRSN; ILIM(AVE) = VCC
ILIM(AVE) Average Current-Limit
Threshold Voltage
(Positive, Adjustable)
VAVELIMIT
CRSP - CRSN
ILIM(AVE) Average Current-Limit
Threshold Voltage (Negative)
ILIM(AVE) Input Current
22
25
28
VILIM(AVE) = VREF - 0.2V
7
10
13
VILIM(AVE) = VREF - 1.0V
46
50
54
-30
-25
-20
mV
mV
CRSP - CRSN; ILIM(AVE) = VCC
IILIM(AVE)
-0.1
+0.1
µA
3
VCC
- 1.0
VCC
- 0.4
V
VPKLIMIT = 30mV
24
30
36
VPKLIMIT = 50mV
40
50
60
-60
-50
-40
ILIM(AVE) Current-Limit Default
Switchover Threshold
ILIM(PK) Peak Current-Limit
Threshold Voltage (Positive)
ILIM(PK) Peak Current-Limit
Threshold Voltage (Negative)
4
VPKLIMIT
CSP_ - CSN_,
RILIM(PK) = RTRC x
8V / VLIM(PK)
mV
CSP_ - CSN_, RILIM(PK) = RTRC x 8V /
VPKLIMIT, VPKLIMIT = 50mV
_______________________________________________________________________________________
mV
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
(Circuit of Figure 1. VCC = VSHDN = 5V, OSC = REF, VVPS = VFBS = VCRSN = VCRSP = VCSP_ = 1.20V, VSUSV = 0.8V, OFS = SUS =
GNDS = PGND = SKIP = GND, D0–D4 set for 1.20V (D0–D4 = 01110). TA = 0°C to +85°C, unless otherwise specified. Typical values
are at TA = +25°C.)
PARAMETER
ILIM(PK) Idle Current-Limit
Threshold Voltage (Skip Mode)
SYMBOL
VIDLE
Current-Sense Input Current
CONDITIONS
CSP_ - CSN_, VSKIP ≥ 1.2V,
RILIM(PK) = RTRC x 8V / VPKLIMIT,
VPKLIMIT = 50mV
MIN
TYP
MAX
UNITS
2
5
8
mV
CSP_, CRSP
-0.2
+0.2
CSN_, CRSN
-1.0
+1.0
2
V
µA
Current-Sense Common-Mode
Input Range
CRSP, CRSN, CSP_, CSN_
0
Phase Disable Threshold
CSP4
3
VCC - 1
VCC 0.4
V
CRS Sense Input Disable
Threshold
CRSP
3
VCC - 1
VCC 0.4
V
LOGIC AND I/O
Logic Input High Voltage
VIH
SHDN, SUS
Logic Input Low Voltage
VIL
SHDN, SUS
SHDN No-Fault Threshold
2.4
0.8
To enable no-fault mode
11
D0–D4 Logic Input High Voltage
VOSC
Medium (REF)
VSKIP
1.8
Logic Output High Voltage
VOH
PWM_, DRSKP; ISOURCE = 3mA
Logic Output Low Voltage
VOL
PWM_, DRSKP; ISINK = 3mA
2.2
V
V
0.4
1.2
Low (GND)
SHDN, SKIP, SUS, OSC, D0–D4 = 0 to 5V
Logic Input Current
V
VCC 0.4
Low (GND)
High
V
V
0.4
High (VCC)
SKIP Input Logic Levels
13
0.8
D0–D4 Logic Input Low Voltage
OSC 3-Level Input Logic Levels
V
0.8
-1
+1
VCC 0.4
V
µA
V
0.4
V
_______________________________________________________________________________________
5
MAX8707
ELECTRICAL CHARACTERISTICS (continued)
MAX8707
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
ELECTRICAL CHARACTERISTICS
(Circuit of Figure 1. VCC = VSHDN = 5V, OSC = REF, VVPS = VFBS = VCRSN = VCRSP = VCSP_ = 1.20V, VSUSV = 0.8V, OFS = SUS =
GNDS = PGND = SKIP = GND, D0–D4 set for 1.20V (D0–D4 = 01110). TA = -40°C to +85°C, unless otherwise specified.) (Note 3)
PARAMETER
SYMBOL
CONDITIONS
MIN
MAX
UNITS
V
PWM CONTROLLER
Input Voltage Range
DC Output Voltage Accuracy
SUSV Input Range
OFS Input Range
OFS GAIN
VCC
VOUT
5.5
-1.0
+1.0
DAC codes from
0.80V to 1.075V
-3.0
+3.0
SUS = VCC
-25
+25
mV
V
%
VSUSV
VOFS
AOFS
GNDS Input Range
VGNDS
GNDS Gain
AGNDS
Switching Frequency Accuracy
(Per Phase)
Includes loadregulation error
(VPS = FBS)
4.5
DAC codes from
1.10V to 1.55V
fSW
TIME Slew-Rate Accuracy
0.4
2.0
Negative offsets
0
0.8
Positive offsets
1.2
2.0
∆VOUT / ∆VOFS; ∆VOFS = VOFS,
VOFS = 0 to 0.8V
-0.131
-0.118
∆VOUT / ∆VOFS; ∆VOFS = VOFS - VREF,
VOFS = 1.2V to 2V
-0.131
-0.118
-200
+200
mV
∆VOUT / ∆VGNDS,
-200mV ≤ VGNDS ≤ +200mV
0.95
1.05
V/V
OSC = GND
180
220
OSC = REF
270
330
OSC = VCC
540
660
RTIME = 143kΩ (6.25mV/µs)
-10
+10
RTIME = 47kΩ (19mV/µs) to 392kΩ
(2.28mV/µs)
-15
+15
Startup and shutdown, RTIME = 47kΩ
(4.75mV/µs) to 392kΩ (0.57mV/µs)
-20
+20
V
V/V
kHz
%
BIAS AND REFERENCE
Quiescent Supply Current (VCC)
ICC
Shutdown Supply Current (VCC)
ICC(SHDN)
Reference Voltage
Reference Load Regulation
VREF
∆VREF
Measured at VCC, VPS and FBS forced
above the regulation points
Measured at VCC, SHDN = GND
VCC = 4.5V to 5.5V, IREF = 0
IREF = 0 to 500µA
1.98
12
mA
10
µA
2.02
V
-2
IREF = -100µA to 0
mV
6.2
mV
FAULT PROTECTION
Output Overvoltage-Protection
Threshold
6
VOVP
Measured at VPS
with respect to
unloaded output
voltage, rising edge,
8mV hysteresis
PWM (SKIP = GND)
or SKIP mode when
VOUT ≤ VTRIP
150
250
mV
SKIP = VCC and
VOUT > VTRIP
1.70
1.80
V
_______________________________________________________________________________________
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
(Circuit of Figure 1. VCC = VSHDN = 5V, OSC = REF, VVPS = VFBS = VCRSN = VCRSP = VCSP_ = 1.20V, VSUSV = 0.8V, OFS = SUS =
GNDS = PGND = SKIP = GND, D0–D4 set for 1.20V (D0–D4 = 01110). TA = -40°C to +85°C, unless otherwise specified.) (Note 3)
PARAMETER
Output Undervoltage-Protection
Threshold
SYMBOL
CONDITIONS
MIN
MAX
UNITS
VUVP
Measured at VPS with respect to 70% of the
unloaded nominal output voltage
-40
+40
mV
Undervoltage, measured at VPS with
respect to 87.5% of the unloaded output
voltage, falling edge, 15mV hysteresis
-40
+40
VROK Threshold
mV
Overvoltage, measured at VPS with respect
to 112.5% of the unloaded output voltage,
rising edge, 15mV hysteresis
VROK Output Low Voltage
VCC Undervoltage-Lockout
Threshold
-40
ISINK = 3mA
Rising edge, hysteresis = 20mV, PWM_
VUVLO(VCC)
disabled below this level
+40
0.4
V
4.10
4.45
V
-2
+2
mV
DROOP AND TRANSIENT RESPONSE
DC Droop Amplifier Offset
DC Droop Amplifier
Transconductance
(CRS Sense Enabled)
Gm(VPS)
∆IVPS / (N x ∆VCRS); VVPS = VCRSN = 1.2V,
VCRSP - VCRSN = -60mV to +60mV,
N = number of phases enabled
190
210
µS
DC Droop Amplifier
Transconductance
(CRS Sense Disabled)
Gm(VPS)
∆IVPS / (Σ∆VCS), VCRSP = VCC,
VVPS = VCSN_ = 1.2V,
VCSP_ - VCSN_ = -60mV to +60mV
190
210
µS
Transient-Droop Transresistance
RTRANS
Current-sense gain (ACS = 10 typ) divided
by the voltage preamplifier
transconductance (Gm(TRC) = 2mS typ)
4.50
5.25
kΩ
CSP_ - CSN_
-2.5
+2.5
mV
VREF
- 1.0
VREF
- 0.2
V
20
30
mV
VILIM(AVE) = VREF - 0.2V
5
15
VILIM(AVE) = VREF - 1.0V
44
56
-31
-19
mV
3
VCC
- 0.4
V
CURRENT LIMIT AND BALANCE
Current-Sense Input Preamplifier
Offsets
ILIM(AVE) Input Range
(Adjustable Mode)
VILIM(AVE)
ILIM(AVE) Average Current-Limit
Threshold Voltage
(Positive, Default)
VAVELIMIT
CRSP - CRSN; ILIM(AVE) = VCC
ILIM(AVE) Average Current-Limit
Threshold Voltage
(Positive, Adjustable)
VAVELIMIT
CRSP - CRSN
ILIM(AVE) Average Current-Limit
Threshold Voltage (Negative)
ILIM(AVE) Current-Limit Default
Switchover Threshold
mV
CRSP - CRSN; ILIM(AVE) = VCC
_______________________________________________________________________________________
7
MAX8707
ELECTRICAL CHARACTERISTICS (continued)
MAX8707
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
ELECTRICAL CHARACTERISTICS (continued)
(Circuit of Figure 1. VCC = VSHDN = 5V, OSC = REF, VVPS = VFBS = VCRSN = VCRSP = VCSP_ = 1.20V, VSUSV = 0.8V, OFS = SUS =
GNDS = PGND = SKIP = GND, D0–D4 set for 1.20V (D0–D4 = 01110). TA = -40°C to +85°C, unless otherwise specified.) (Note 3)
PARAMETER
ILIM(PK) Peak Current-Limit
Threshold Voltage (Positive)
SYMBOL
VPKLIMIT
ILIM(PK) Peak Current-Limit
Threshold Voltage (Negative)
ILIM(PK) Idle Current-Limit
Threshold Voltage (Skip Mode)
VIDLE
Current-Sense Input Current
CONDITIONS
MIN
MAX
VPKLIMIT = 30mV
24
36
VPKLIMT = 50mV
40
60
CSP_ - CSN_,
RILIM(PK) = RTRC x 8V / VPKLIMIT,
VPKLIMIT = 50mV
-60
-40
mV
CSP_ - CSN_, VSKIP ≥ 1.2V,
RILIM(PK) = RTRC x 8V / VPKLIMIT,
VPKLIMIT = 50mV
2
8
mV
CSP_, CRSP
-0.2
+0.2
CSN_, CRSN
-1.0
+1.0
CSP_ - CSN_,
RILIM(PK) = RTRC x
8V / VLIM(PK)
UNITS
mV
µA
Current-Sense Common-Mode
Input Range
CRSP, CRSN, CSP_, CSN_
0
2
V
Phase Disable Threshold
CSP4
3
VCC
- 0.4
V
CRS Sense Input Disable
Threshold
CRSP
3
VCC
- 0.4
V
LOGIC AND I/O
Logic Input High Voltage
VIH
SHDN, SUS
Logic Input Low Voltage
VIL
SHDN, SUS
D0–D4 Logic Input High Voltage
2.4
0.8
D0–D4 Logic Input Low Voltage
VOSC
Medium (REF)
SKIP Input Logic Levels
VSKIP
Logic Output High Voltage
VOH
1.8
2.2
V
0.4
1.2
Low (GND)
PWM_, DRSKP; ISOURCE = 3mA
V
VCC
- 0.4
Low (GND)
High
V
V
0.4
High (VCC)
OSC 3-Level Input Logic Levels
V
0.8
0.8
VCC
- 0.4
V
V
Note 2: VROK is blanked during the transitions, when the internal target is being slewed. See the Output-Voltage Transition Timing
section. VROK is reenabled in tBLANK (20µs) after the transition is completed.
Note 3: Specifications to TA = -40°C are guaranteed by design and are not production tested.
8
_______________________________________________________________________________________
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
(Circuit of Figure 1. VIN = 12V, VCC = 5V, SUS = SKIP = GND, SHDN = VCC, VSUSV = 0.80V, TA = +25°C, unless otherwise specified.)
VIN = 20V
60
MAX8707 toc02
VIN = 20V
100
10
VIN = 12V
70
60
50
1
100
10
1
100
10
LOAD CURRENT (A)
LOAD CURRENT (A)
LOAD CURRENT (A)
OUTPUT VOLTAGE DEVIATION
vs. LOAD CURRENT
SINGLE-PHASE
EFFICIENCY vs. LOAD CURRENT
(VOUT = 0.800V)
NO-LOAD SUPPLY CURRENT
vs. INPUT VOLTAGE
(4-PHASE FORCED-PWM MODE)
VIN = 8V
90
VIN = 12V
VOUT = 1.00V
-40
-60
VOUT = 1.30V
80
VIN = 20V
70
IBIAS
SUPPLY CURRENT (mA)
EFFICIENCY (%)
-20
200
-80
-120
20
40
80
60
100
IIN
SKIP = VCC
SKIP = SUS = VCC
50
0
150
50
60
-100
MAX8707 toc06
0
100
MAX8707 toc05
VIN = 12V
MAX8707 toc04
20
0.1
1
10
0
100
0
5
10
15
20
LOAD CURRENT (A)
LOAD CURRENT (A)
INPUT VOLTAGE (V)
NO-LOAD SUPPLY CURRENT
vs. INPUT VOLTAGE
(1-PHASE PULSE SKIPPING)
OUTPUT OFFSET VOLTAGE
vs. OFS VOLTAGE
REFERENCE VOLTAGE
DISTRIBUTION
8
IBIAS
6
4
2
150
100
50
0
-50
UNDEFINED
REGION
-150
0
5
10
15
INPUT VOLTAGE (V)
20
25
SAMPLE SIZE = 100
40
30
20
10
-100
IIN = 15µA
25
50
SAMPLE PERCENTAGE (%)
SKIP = GND
OUTPUT OFFSET VOLTAGE (mV)
MAX8707 toc07
10
0
80
VIN = 20V
50
1
OUTPUT VOLTAGE (mV)
70
60
50
SUPPLY CURRENT (mA)
VIN = 12V
MAX8707 toc09
70
80
VIN = 8V
90
EFFICIENCY (%)
VIN = 12V
100
MAX8707 toc08
EFFICIENCY (%)
80
VIN = 8V
90
EFFICIENCY (%)
VIN = 8V
90
EFFICIENCY vs. LOAD CURRENT
(VOUT = 1.000V)
100
MAX8707 toc01
100
EFFICIENCY vs. LOAD CURRENT
(VOUT = 1.300V)
MAX8707 toc03
EFFICIENCY vs. LOAD CURRENT
(VOUT = 1.525V)
0
0.5
1.0
OFS VOLTAGE (V)
1.5
2.0
0
1.990
1.995
2.000
2.005
2.010
REFERENCE VOLTAGE (V)
_______________________________________________________________________________________
9
MAX8707
Typical Operating Characteristics
Typical Operating Characteristics
(Circuit of Figure 1. VIN = 12V, VCC = 5V, SUS = SKIP = GND, SHDN = VCC, VSUSV = 0.80V, TA = +25°C, unless otherwise specified.)
VPS TRANSCONDUCTANCE
DISTRIBUTION
60
30
20
10
50
40
30
20
10
-5
-3
-1
1
3
0.3
0.2
0.1
0
197
199
201
203
205
0
5
10
15
20
OUTPUT OFFSET VOLTAGE (mV)
TRANSCONDUCTANCE (µS)
LOAD CURRENT (A)
STARTUP WAVEFORM
(NO LOAD)
STARTUP WAVEFORM
(20A LOAD)
SHUTDOWN WAVEFORM
(NO LOAD)
A
C
3.3V
0
5V
0
2V
0
1V
D
0
1V
0
E
0
B
A
3.3V
0
C
5V
0
1.3V
D
0
B
A
B
C
D
E
F
F
G
G
200µs/div
A. SHDN, 5V/div
B. DRSKP, 10V/div
C. REF, 2V/div
D. OUT, 1V/div
E
0
200µs/div
200µs/div
E. VROK, 10V/div
F. DL1, 10V/div
G. INDUCTOR CURRENT
(IL1), 10A/div
A. SHDN, 5V/div
B. DRSKP, 10V/div
C. REF, 2V/div
D. OUT, 1V/div
25
MAX8707 toc15
MAX8707 toc14
MAX8707 toc13
3.3V
0
5V
0
2V
10
0.4
-0.2
195
5
0.5
-0.1
0
0
0.6
MAX8707 toc12
SAMPLE SIZE = 100
SAMPLE PERCENTAGE (%)
40
70
MAX8707 toc11
SAMPLE SIZE = 100
0.800V
1.550V
MAX8707 toc10
50
CURRENT-SENSE VOLTAGE DIFFERENCE
vs. LOAD CURRENT
CURRENT-SENSE DIFFERENCE (mV)
OUTPUT OFFSET VOLTAGE
DISTRIBUTION
SAMPLE PERCENTAGE (%)
MAX8707
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
E. VROK, 10V/div
F. DL1, 10V/div
G. INDUCTOR CURRENT
(IL1), 10A/div
A. SHDN, 5V/div
B VROK, 10V/div
C. OUT, 1V/div
______________________________________________________________________________________
D. DL1, 10V/div
E. INDUCTOR CURRENT
(IL1), 10A/div
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
(Circuit of Figure 1. VIN = 12V, VCC = 5V, SUS = SKIP = GND, SHDN = VCC, VSUSV = 0.80V, TA = +25°C, unless otherwise specified.)
LOAD TRANSIENT
(VOUT = 1.30V)
LOAD TRANSIENT
(VOUT = 1.00V)
MAX8707 toc16
65A
TRANSIENT PHASE REPEAT
MAX8707 toc18
MAX8707 toc17
70A
30A
A
0A
1.30V
1.00V
1.30V
B
12V
12V
20V
D
10A
C
C
0
20A
0
20A
B
B
C
0
A
A
0
10A
10A
D
D
10A
0
0
VIN = 20V
0
20µs/div
A. IOUT = 10A TO 65A,
50A/div
B. VOUT, 100mV/div
2µs/div
20µs/div
C. LX1, 10V/div
D. INDUCTOR CURRENT
(IL1), 10A/div
A. IOUT = 0 TO 30A,
50A/div
B. VOUT, 50mV/div
DEEP-SLEEP TRANSITION
MAX8707 toc20
A
3.3V
0
MAX8707 toc21
A
1.30V
0.2V
B
0
C
1.300V
3.3V
0
A
1.30V
B
B
0.80V
5V
0.80V
C
0
1.275V
C. LX1, 10V/div
D. INDUCTOR CURRENT
(IL1), 10A/div
SUSPEND TRANSITION
(SKIP = SUS)
SUSPEND EXIT TRANSITION
MAX8707 toc19
3.3V
0
A. IOUT = 0 TO 70A,
100A/div
B. VOUT, 100mV/div
C. LX1, 10V/div
D. INDUCTOR CURRENT
(IL1), 10A/div
C
5V
0
D
5A
D
D
E
5A
E
E
IOUT = 20A
20µs/div
A. DPSLP, 5V/div
B. OFS, 200mV/div
C. VOUT, 25mV/div
20µs/div
D. INDUCTOR CURRENT
(IL1), 10A/div
E. INDUCTOR CURRENT
(IL3), 10A/div
A. SUS, 5V/div
B. VOUT, 500mV/div
C. DRSKP, 5V/div
200µs/div
D. INDUCTOR CURRENT
(IL1), 10A/div
E. INDUCTOR CURRENT
(IL3), 10A/div
A. SUS, 5V/div
B. VOUT, 500mV/div
C. DRSKP, 5V/div
D. INDUCTOR CURRENT
(IL1), 10A/div
E. INDUCTOR CURRENT
(IL3), 10A/div
______________________________________________________________________________________
11
MAX8707
Typical Operating Characteristics (continued)
MAX8707
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
Typical Operating Characteristics (continued)
(Circuit of Figure 1. VIN = 12V, VCC = 5V, SUS = SKIP = GND, SHDN = VCC, VSUSV = 0.80V, TA = +25°C, unless otherwise specified.)
SUSPEND TRANSITION
(SKIP = SUS)
SUSPEND TRANSITION
(SKIP = GND)
MAX8707 toc22
3.3V
0
D1 (25mV) VID TRANSITION
MAX8707 toc23
A
1.30V
3.3V
0
3.3V
1.30V
0.80V
B
0.80V
5V
5V
0
C
0
MAX8707 toc24
A
0
A
1.30V
B
B
C
1.275V
0
C
0
D
D
D
E
E
100µs/div
A. SUS, 5V/div
B. VOUT, 500mV/div
C. DRSKP, 5V/div
40µs/div
D. INDUCTOR CURRENT
(IL1), 10A/div
E. INDUCTOR CURRENT
(IL3), 10A/div
20µs/div
D. INDUCTOR CURRENT
(IL1), 10A/div
E. INDUCTOR CURRENT
(IL3), 10A/div
A. SUS, 5V/div
B. VOUT, 500mV/div
C. DRSKP, 5V/div
A. D1, 5V/div
B. VOUT, 25mV/div
D3 (200mV) VID TRANSITION
MAX8707 toc25
3.3V
0
A
1.30V
B
1.10V
0
C
0
D
20µs/div
A. D3, 5V/div
B. VOUT, 200mV/div
12
C. INDUCTOR CURRENT
(IL1), 10A/div
D. INDUCTOR CURRENT
(IL3), 10A/div
______________________________________________________________________________________
C. INDUCTOR CURRENT
(IL1), 10A/div
D. INDUCTOR CURRENT
(IL3), 10A/div
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
PIN
NAME
FUNCTION
1
D2
Low-Voltage VID DAC Code Input. The D0–D4 inputs do not have internal pullups. These 1.0V logic inputs
are designed to interface directly with the CPU. In normal mode (Table 4, SUS = GND), the output voltage
is set by the VID code indicated by the logic-level voltages on D0–D4. In suspend mode (SUS = high), the
output voltage tracks the voltage at SUSV.
2
D3
Low-Voltage VID DAC Code Input
3
D4
Low-Voltage VID DAC Code Input (MSB)
4
N.C.
No Connect. Leave open. Pin internally connected.
SKIP
Pulse-Skipping Indicator Input. When pulse skipping, the controller blanks the VROK upper threshold.
3.3V or VCC (high) = 1-phase pulse-skipping operation (phases 2, 3, and 4 disabled)
GND = multiphase forced-PWM operation
The controller automatically enters forced-PWM mode during startup, shutdown, and the no-CPU VID
mode.
5
SHDN
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 50nA (typ) shutdown state. During the startup and
shutdown transitions, the output voltage is ramped at 1/4th the output-voltage slew rate programmed by
RTIME. After completing soft-shutdown, the drivers are disabled—DRSKP and PWM_ are pulled low.
Forcing SHDN to 11V~13V disables both overvoltage-protection and undervoltage-protection circuits, and
clears the fault latch. Do not connect SHDN to >13V.
7
SUS
Suspend Control Input. When the controller detects a transition on SUS, the controller slews the output
voltage to the new voltage level determined by SUSV (SUS = high) or D0–D4 (SUS = low). The controller
blanks VROK during the transition and another 20µs after the new target voltage is reached. When SUS is
high, the offset (OFS) is automatically disabled.
8
SUSV
Suspend-Mode Voltage Input. Connect to the output of a resistive voltage-divider from REF to GND to
provide an analog voltage between 0.4V to 2V. The output voltage is set by the voltage at SUSV when SUS
is high.
6
9
10
Average Current-Limit Threshold Adjustment. The controller uses the accurate CRSP-to-CRSN currentsense voltage to limit the average current per phase. When the average current-limit threshold is
exceeded, the controller internally reduces the peak inductor current-limit threshold (ILIM(PK)) at 2% of
IPKLIMIT per µs until the average current remains within the programmed limits. When the accurate current
sensing is disabled (CRSP = VCC), the average current-limit circuit is disabled and ILIM(AVE) should be
ILIM(AVE)
connected to VCC.
The average current-limit threshold defaults to 25mV if ILIM(AVE) is connected to VCC. In adjustable mode,
the average current-limit threshold voltage is precisely 1/20th the voltage difference between ILIM(AVE)
and the reference: (VREF - VILIM(AVE)) / 20 for a range of 1.0V (VREF - 1V) to 1.8V (VREF - 0.2V). The logic
threshold for switchover to the 25mV default value is approximately VCC - 1V.
OFS
Adjustable Offset Voltage Input. For 0 < VOFS < 0.8V, 1/8th the voltage at OFS is subtracted from the
output. For 1.2V < VOFS < 2.0V, 1/8th the difference between REF and OFS is added to the output.
Voltages in the range of 0.8V < VOFS < 1.2V are undefined. The controller disables the offset amplifier
during suspend mode (SUS = high).
______________________________________________________________________________________
13
MAX8707
Pin Description
MAX8707
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
Pin Description (continued)
PIN
NAME
11
OSC
12
GNDS
FUNCTION
Oscillator Select Input. OSC is a 3-level logic input for selecting the per-phase switching frequency.
Connect to GND for 200kHz, connect to REF for 300kHz, or connect to VCC for 600kHz per phase.
Ground Remote-Sense Input. Connect GNDS directly to the CPU ground-sense pin. GNDS internally
connects to an amplifier that adjusts the output voltage, compensating for voltage drops from the regulator
ground to the load ground.
Slew-Rate Adjustment Pin. Connect a resistor from TIME to GND to set the internal slew rate. A 47kΩ to
392kΩ corresponds to slew rates of 19mV/µs to 2.28mV/µs, respectively, for all suspend voltage
transitions.
13
TIME
t TRAN(SUS) =
| VNEW − VOLD |
dVTARGET / dt
where dVTARGET / dt = 6.25mV/µs × 143kΩ / RTIME is the slew rate. For soft-start and shutdown, the
controller automatically reduces the slew rate by 1/4th. For all dynamic VID transitions, the rate at which
the VID inputs (D0–D4) are clocked sets the slew rate, as long as it is less than the dv/dt set by RTIME.
Peak Inductor Current-Limit Threshold Adjustment (Cycle-by-Cycle Current Limit). If the voltage across the
current-sense inputs (CSP to CSN) exceeds the peak current-limit threshold, the controller immediately
terminates the respective phase’s on-time. Connect a resistor RILIM(PK) from ILIM(PK) to GND to set the
cycle-by-cycle peak current-limit threshold:
14
ILIM(PK)
RILIM (PK ) =
8V × R TRC
IPKLIMIT RCS
where RCS is the resistance value of the current-sense element (inductors’ DCR or current-sense resistor),
RTRC is the resistance between TRC and REF, and IPKLIMIT is the desired peak current limit (per phase).
15
CCV
Voltage Integrator Capacitor Connection. Connect a 470pF x (4 / ηPH) or greater capacitor from CCV to
analog ground (GND) to set the integration time constant.
Transient-Voltage Preamplifier Output. Connect a resistor (RTRC) between TRC and REF to set the
transient droop based on the voltage-positioning requirements. TRC does not affect the DC steady-state
droop. Choose RTRC based on the equation:
16
TRC
 R

TRANSRCS
R TRC = ACS 

 ηPHRDROOP(AC) 
as defined in the Design Procedure (page 33). If voltage positioning is not required, RTRC is determined
by the stability requirements. TRC is high impedance in shutdown.
14
______________________________________________________________________________________
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
PIN
NAME
17
REF
FUNCTION
2.0V Reference Output. Bypass to GND with a 0.22µF to 1µF (max) ceramic capacitor. The reference can
source 500µA for external loads. Loading REF degrades output-voltage accuracy according to the REF
load-regulation error.
18
VROK
Open-Drain Power-Good Output. After power-up, VROK remains high impedance as long as the output
voltage remains in regulation. The controller blanks VROK (high impedance) whenever the slew-rate
control is active (output-voltage transitions). VROK is forced low during startup and shutdown. In pulseskipping mode (SKIP = high), the upper VROK threshold is disabled.
19
GND
Analog Ground. Connect the MAX8707’s exposed pad to analog ground.
20
PGND
Power Ground. Ground connection for the driver control outputs (PWM_) and driver skip output (DRSKP).
21
VCC
Analog Supply-Voltage Input. Connect VCC to the system supply voltage (4.5V to 5.5V) with a series 10Ω
resistor. Bypass to analog GND with a 1µF or greater ceramic capacitor, as close to the IC as possible.
22
PWM1
PWM Driver Control Output for Phase 1. Logic low in shutdown.
23
PWM2
PWM Driver Control Output for Phase 2. Logic low in shutdown.
24
PWM3
PWM Driver Control Output for Phase 3. Logic low in shutdown.
25
PWM4
PWM Driver Control Output for Phase 4. Logic low when disabled (CSP4 = VCC) and in shutdown.
26
DRSKP
Driver Skip Control Output. Push/pull logic output that controls the operating mode of the skip-mode driver ICs.
DRSKP swings from VCC to PGND. When DRSKP is high, the driver ICs operate in forced-PWM mode. When
DRSKP is low, the driver ICs enable their zero-crossing comparators and operate in pulse-skipping mode.
FBS
Remote Feedback Sense Input. Connect FBS to the CPU output sense point. To minimize output-voltage
errors due to any resistance in series with the FBS input, the controller generates an FBS input bias
current equal in magnitude and opposite in polarity to the VPS output current. FBS is high impedance
in shutdown.
28
VPS
Voltage-Positioning Transconductance-Amplifier Output. Connect a resistor RVPS between VPS and FBS to
set the DC steady-state droop (load line) based on the required voltage-positioning slope (see the
Voltage-Positioning Amplifier section).
RVPS = RDROOP / (RSENSE x GM(VPS))
where RDROOP is the desired DC voltage-positioning slope, RSENSE is the current-sense resistor, and
GM(VPS) = 200µS. RSENSE is the accurate sense resistor used to generate current-sense voltage (CRSP,
CRSN). When CRSP is connected to VCC, the input to the transconductance amplifier is the sum of the
current-sense voltage (CSP_, CSN_) inputs. When the inductors’ DC resistances (RDCR) are used as the
current-sense elements (for lossless sensing), RVPS should include an NTC thermistor to minimize the
temperature dependence of the voltage-positioning slope. To disable voltage positioning, short VPS to
FBS. VPS is high impedance in shutdown.
29
CRSN
27
Negative Current-Sense Resistor Input. CRSN is the negative differential input used for accurate sensing
of the phase 1 inductor current. Connect a current-sense resistor between CRSP and CRSN for accurate
voltage positioning and current limit. Float CRSN when not used (CRSP pulled up to VCC).
______________________________________________________________________________________
15
MAX8707
Pin Description (continued)
MAX8707
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
Pin Description (continued)
PIN
NAME
FUNCTION
30
CRSP
Positive Current-Sense Resistor Input. CRSP is the positive differential input used for accurate sensing of
the phase 1 inductor current. Connect a current-sense resistor between CRSP and CRSN. If current-sense
resistors are used on all phases (CSP_, CSN_), this additional current-sense (CRSP, CRSN) feature can be
disabled by connecting CRSP to VCC and floating CRSN.
31
CSP1
Positive Current-Sense Input for Phase 1. This input should be connected to the positive terminal of the
current-sense resistor or of the DCR sensing filtering capacitor, depending on the current-sense method
implemented.
32
CSN1
Negative Current-Sense Input for Phase 1
33
CSN2
Negative Current-Sense Input for Phase 2
34
CSP2
Positive Current-Sense Input for Phase 2. This input should be connected to the positive terminal of the
current-sense resistor or of the DCR sensing filtering capacitor, depending on the current-sense method
implemented.
35
CSP3
Positive Current-Sense Input for Phase 3. This input should be connected to the positive terminal of the
current-sense resistor or of the DCR sensing filtering capacitor, depending on the current-sense method
implemented.
36
CSN3
Negative Current-Sense Input for Phase 3
37
CSN4
Negative Current-Sense Input for Phase 4
38
CSP4
Positive Current-Sense Input for Phase 4. This input should be connected to the positive terminal of the
current-sense resistor or of the DCR sensing filtering capacitor, depending on the current-sense method
implemented. Connect CSP4 to VCC for fixed 3-phase operation.
39
D0
Low-Voltage VID-DAC Code Inputs. The D0–D4 inputs do not have internal pullups. These 1.0V logic
inputs are designed to interface directly with the CPU. In normal mode (Table 4, SUS = low), the output
voltage is set by the D0–D4 VID-DAC inputs. In suspend mode (SUS = high), the output voltage tracks the
voltage at SUSV.
40
D1
Low-Voltage VID-DAC Code Inputs
Detailed Description
+5V Bias Supply (VCC)
The MAX8707 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 controller
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.
16
The +5V bias supply must provide VCC (PWM controller) and VDRV (FET gate-drive power), so the maximum current drawn is:
IBIAS = ICC + IDRIVE
where ICC is provided in the Electrical Characteristics
table and IDRIVE is the driver’s supply current dominated by fSW x QG (per phase) as defined in the driver’s
data sheet. 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.
______________________________________________________________________________________
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
Interleaved Multiphase Operation
The MAX8707 interleaves all the active phases—resulting in out-of-phase operation that minimizes the input
and output filtering requirements, reduces electromagnetic interference (EMI), and improves efficiency. The
multiphase controller shares the current between multiple
phases that operate 90° out-of-phase (4-phase operation) or 120° out-of-phase (3-phase operation). The highside MOSFETs do not turn on simultaneously during
normal operation. The instantaneous input current is
effectively reduced by the number of active phases,
resulting in reduced input voltage ripple, ESR power loss,
and RMS ripple current (see the Input-Capacitor
Selection section). Therefore, the controller achieves high
performance while minimizing the component count—
which reduces cost, saves board space, and lowers
component power requirements—making the MAX8707
ideal for high-power, cost-sensitive applications.
Transient Phase Repeat
When a transient occurs, the response time of the controller depends on its ability to quickly respond to the
output-voltage deviation and slew the inductor current
to the new current level. Multiphase, fixed-frequency
controllers typically respond only to the clock edge,
resulting in a delayed response from the actual transient event. To eliminate this delay time, the MAX8707
includes transient phase repeat, which allows the controller to immediately respond when heavy load transients are detected. If the controller detects that the
output voltage has dropped by 25mV, the transient
detection comparator immediately retriggers the phase
that completed its on-time last. The controller triggers
the subsequent phases as normal—on the appropriate
oscillator edges. This effectively triggers a phase a full
cycle early, increasing the total inductor-current slew
rate and providing an immediate transient response.
Feedback-Adjustment Amplifiers
Voltage-Positioning Amplifier (Steady-State Droop)
The multiphase controllers include a transconductance
amplifier for adding gain to the voltage-positioning
sense path. The current-sense inputs differentially
sense the voltage across either a single current-sense
resistor (CRS sensing enabled) or the inductor’s DCR
(CRS sensing disabled). The VPS amplifier’s input is
generated by sensing either a single phase (CRS sensing) and multiplying by the number of active phases, or
by summing the current-sense (CS_) inputs of all active
phases (CRSP = VCC). The transconductance amplifier’s output connects to the regulator’s voltage-positioned feedback input (VPS), so the resistance between
VPS and the output voltage-sense point (FBS) determines the voltage-positioning gain:
VOUT = VTARGET - RVPS IVPS
where the target voltage (VTARGET) is defined in the
Nominal Output-Voltage Selection section, and the
transconductance amplifier’s output current (IVPS) is
determined by the current-sense voltage and the number of active phases (ηPH):
IVPS = ηPH (VCRSP - VCRSN) GM(VPS)
when CRS sensing is enabled, or:
IVPS = ∑ (VCSP_ - VCSN_) GM(VPS)
when CRS sensing is disabled (CRSP = VCC).
where G M(VPS) is typically 200µS as defined in the
Electrical Characteristics table. To avoid output-voltage
errors caused by the VPS current flowing through parasitic trace resistance or feedback fliter resistance, a
second transconductance amplifier generates an equal
and opposite current on the FBS input.
Disable voltage positioning by shorting VPS directly to FBS.
______________________________________________________________________________________
17
MAX8707
Switching Frequency (OSC)
OSC is a 3-level logic input used to set the per-phase
switching frequency. Connect OSC directly to GND,
REF, or VCC for 200kHz, 300kHz, and 600kHz operation, respectively. High-frequency (600kHz, OSC =
VCC) operation optimizes the application for the smallest component size, trading off efficiency due to higher
switching losses. This may be acceptable in ultraportable devices where the load currents are lower.
Low-frequency (200kHz, OSC = GND) operation offers
the best overall efficiency at the expense of component
size and board space.
18
Figure 1. Standard MAX8707 AMD Hammer Application Circuit
______________________________________________________________________________________
CREF
0.22µF
RVROK
100kΩ
ROFS2
20kΩ
RFBS
10Ω
RVPS
6.49kΩ
RSUSV2
81kΩ
RILIM(PK)
200kΩ
RSUSV1
120kΩ
CGNDS
1000pF
CFBS
1000pF
RTRC
2.0kΩ
ROFS1
182kΩ
RILIMAVE1
RILIMAVE2 49.9kΩ
150kΩ
(VRON)
3-LEVEL PIN
DPRSLPVR
REF
PWM
OFF
RGNDS
10Ω
5V
SKIP
ON
VID INPUTS
MAX8707
PGND
CSP4
CSN4
CSP3
CSN3
TIME
CCV
PWM2
PWM1
DRSKP
PWM3
PWM4
CSP2
CSN2
CRSN
CRSP
CSN1
CSP1
GND
VCC
CCSN4
4700pF
CCSN3
4700pF
RTIME
143kΩ
CCCV
1000pF
CCSN2
4700pF
CCRS
1000pF
CCSN1
4700pF
CVCC
1.0µF
CPU REMOTE-SENSE CONNECTIONS
VPS
FBS
GNDS
VROK
OSC
SUS
SUSV
ILIM(PK)
OFS
ILIM(AVE)
REF
TRC
SHDN
SKIP
D0
D1
D2
D3
D4
RVCC
10Ω
CCS4
0.22µF
CCS3
0.22µF
CCS2
0.22µF
RCRSN
100Ω
RCRSP
100Ω
CCS1
0.22µF
RCSP1
1.5kΩ
NL1
CIN
RCSP4
1.5kΩ
L4
RCSP3
1.5kΩ
L3
8V TO 20V
PWR INPUT
CIN
RCSP3
1.5kΩ
L2
RCRSENSE
1.0mΩ
L1
5V BIAS
NH4
NH2
AGND
TSET
VCC
VDD
SKIP
PWM1
PWM2
DRHOT
SHDN
AGND
TSET
VDD
VCC
DRHOT
SHDN
SKIP
PWM1
PWM2
MAX8702
PGND
DL2
LX2
DH2
DL1
LX1
DH1
BST1
BST2
PGND
DL2
LX2
DH2
DL1 MAX8702
LX1
DH1
OUTPUT
(CPU CORE SUPPLY)
NL4
NL3
NH3
NL2
NH1
BST1
BST2
8V TO 20V
PWR INPUT
RTSET2
RVCC2
10Ω
RTSET1
RVCC1
10Ω
VRON
CVCC2
1.0µF
VRON
RDRHOT
100kΩ
CVCC1
1.0µF
CVDD1
4.7µF
CVDD2
4.7µF
5V BIAS
MAX8707
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
If voltage positioning is not required, R DROOP is
defined by the maximum output-voltage sag with the
worst-case transient load (∆VOUT / ∆IOUT) and is subject to stability requirements. TRC is high impedance in
shutdown.
Differential Remote Sense
The multiphase controllers include differential, remotesense inputs to eliminate the effects of voltage drops
down the PC board traces and through the processor’s
power pins.
The MAX8707 GNDS amplifier adds an offset directly to
the target voltage, adjusting the output voltage to counteract the voltage drop in the ground path. Connect the
feedback sense (FBS), voltage-positioning resistor
(RVPS), and ground-sense (GNDS) inputs directly to the
processor’s core supply remote- sense outputs.
Integrator Amplifier
An integrator amplifier forces the DC average of the
VPS 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 has the ability to shift the output voltage by
±100mV (typ). The differential input voltage range is at
least ±60mV total, including DC offset and AC ripple.
The integration time constant can be set easily with an
external compensation capacitor at the CCV pin. Use a
470pF x (4 / ηPH) or greater ceramic capacitor.
The MAX8707 disables the integrator by connecting the
amplifier inputs together at the beginning of all transitions done in pulse-skipping mode (SKIP = 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).
MAX8707
Transient-Droop Amplifier
The MAX8707 controller includes a transient-droop
transconductance amplifier to handle the instantaneous
load transients typical of CPU applications. The transient-droop amplifier sets the correct voltage-positioning
slope during a load transient, complimenting the slower
steady-state voltage-positioning amplifier. The currentsense inputs differentially sense the voltage across the
CSP_ and CSN_ current-sense element (inductor’s DCR
or current-sense resistor). The transconductance amplifier’s output connects to the regulator’s transient-response
input (TRC), so the resistance between TRC and the reference voltage (REF) determines the transient voltagepositioning gain as defined in the Multiphase,
Fixed-Frequency Design Procedure section.
Table 1. Component Selection for
Standard Multiphase Applications
MAX8707
AMD HAMMER
COMPONENTS
DESIGNATION
Circuit of Figure 1
Input Voltage Range
7V to 24V
VID Output Voltage (D4–D0)
1.50V (D4–D0 = 00010)
SUSV Suspend Voltage
(SUS = High)
0.80V
Maximum Load Current
80A
Number of Phases (ηTOTAL)
4 phases
(1) MAX8705 + (2) MAX8702
Inductor (Per Phase)
0.56µH, 1.6mΩ
Panasonic ETQP4LR56WFC
Switching Frequency
(Per Phase)
300kHz (OSC = REF)
High-Side MOSFET
(NH, Per Phase)
Siliconix (1) Si7892DP
Low-Side MOSFET
(NL, Per Phase)
Siliconix (2) Si7356DP
Total Input Capacitance (CIN)
(8) 10µF, 25V
TDK C3225X7R1E106M
Taiyo Yuden
TMK325BJ106MN
Total Output Capacitance
(COUT)
(6) 330µF, 2.5V, 9mΩ
Sanyo 2R5TPE330M9
Current-Sense Resistor
(RSENSE)
1.0mΩ
Panasonic ERJM1WTJ1M0U
When voltage positioning is disabled (VPS = FBS), the
transient droop must be less than the ±80mV minimum
adjustment range of the integrator amplifier to guarantee proper DC output-voltage accuracy.
Offset Amplifier
The multiphase controllers include a fifth amplifier used
to add small offsets to the voltage-positioned load line.
The offset amplifier sums directly with the target voltage, making the offset gain independent of the DAC
code. This amplifier has the ability to offset the output
by ±100mV. The offset is adjusted using resistive voltage-dividers at the OFS input. For inputs from 0 to 0.8V,
the offset amplifier adds a negative offset to the output
that is equal to 1/8th the voltage appearing at the OFS
input (VOFFSET = -0.125 x VOFS). For inputs from 1.2V
______________________________________________________________________________________
19
MAX8707
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
VCC
REF
(2.0V)
REF
UVLO
MAX8707
RUN
GND
REFOK
DECODER
D4
D3
D2
D1
D0
CHANGE
SUS
WINDOW
COMPARATOR
DAC
OFS
GM
SUSV
GNDS
TARGET
SUS
GM
SHDN
FAULT
CSLEW
ERROR
AMP
R-TO-I
CONVERTER
REF
x4
TIME
CSP_
x4
FBS
A = 10
CSN_
TARGET
TRC
GM(TRC)
SKIP
ILIM(PK)
REF
PHASE ENABLE
DETECT
TRC
CLAMP
OSCILLATOR
SKIP
OSC
R-TO-I
CONVERTER
EA[4:1]
ILIM(AVE)
CURRENTLIMIT
COMPARATOR
4-PHASE
FIXED-FREQ
CURRENT-MODE
PWM LOGIC
SUS
25mV
PWM_
DRSKP
RUN
CRSP
DROOP
CRSN
500kΩ
TRAN
GM(VPS)
PGND
LOAD-TRANSIENT
DETECT COMPARATOR
VPS
VPS
160µS
TARGET
PGOOD AND
FAULT DETECT
CCV
CHANGE
INTEGRATOR
AMP
FAULT
(UVP + THERMAL)
Figure 2. MAX8707 Functional Diagram
20
______________________________________________________________________________________
VROK
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
MAX8707
Table 2. Component Suppliers
MANUFACTURER
WEBSITE
BI Technologies
www.bitechnologies.com
Central Semiconductor
www.centralsemi.com
Coilcraft
www.coilcraft.com
Coiltronics
www.coiltronics.com
Fairchild Semiconductor
www.fairchildsemi.com
International Rectifier
www.irf.com
Kemet
www.kemet.com
Panasonic
www.panasonic.com
Sanyo
www.secc.co.jp
Siliconix (Vishay)
www.vishay.com
Sumida
www.sumida.com
Taiyo Yuden
www.t-yuden.com
TDK
www.component.tdk.com
TOKO
www.tokoam.com
Table 3. Operating-Mode Truth Table
SHDN
SUS
SKIP
OFS
OUTPUT
VOLTAGE
GND
X
X
X
GND
Low-Power Shutdown Mode. PWM_ outputs are forced low,
and the controller is disabled. The supply current drops to
10µA (max).
VCC
GND
GND
GND or REF
D0–D4
(no offset)
Normal Operation. The no-load output voltage is determined
by the selected VID DAC code (D0–D4, Table 4).
Pulse-Skipping Operation. When SKIP is pulled high, the
MAX8707 immediately enters pulse-skipping operation
allowing automatic PWM/PFM switchover under light loads.
The VROK upper threshold is blanked.
OPERATING MODE
VCC
GND
VCC
GND or REF
D0–D4
(no offset)
VCC
GND
X
0 to 0.8V
or
1.2V to 2.0V
D0–D4
(plus offset)
Deep-Sleep Mode. The no-load output voltage is determined
by the selected VID-DAC code (D0–D4, Table 4) plus the
offset voltage set by OFS.
VCC
VCC
X
X
SUSV
(no offset)
Suspend Mode/One Phase Skip. The no-load output voltage
is determined by the suspend voltage present on SUSV,
overriding all other active modes of operation.
VCC
X
X
X
GND
Fault Mode. The fault latch has been set by either UVP or
thermal shutdown. The controller remains in FAULT mode
until VCC power is cycled or SHDN toggled.
X = Don’t Care
______________________________________________________________________________________
21
to 2V, the offset amplifier adds a positive offset to the
output that is equal to 1/8th the difference between the
reference voltage and the voltage appearing at the
OFS input (VOFFSET = 0.125 x (VREF - VOFS)). With this
scheme, the controller supports both positive and negative offsets with a single input. The piecewise lineartransfer function is shown in Figure 3. The regions of
the transfer function below zero, above 2.0V, and
between 0.8V and 1.2V are undefined. OFS inputs are
disallowed in these regions, and the respective effects
on the output are not specified.
The controller disables the offset amplifier during suspend mode (SUS = high).
OUTPUT OFFSET VOLTAGE
vs. OFS INPUT VOLTAGE
200mV
UNDEFINED
REGION
OUTPUT OFFSET VOLTAGE
MAX8707
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
100mV
0
-100mV
Nominal Output-Voltage Selection
The nominal no-load output voltage (VTARGET) is defined
by the selected voltage reference (VID DAC or SUSV)
plus the offset voltage and remote ground-sense adjustment (VGNDS) as defined in the following equation:
VTARGET = VDAC + VOFFSET + VGNDS
when SUS = GND
where VDAC is the selected VID voltage during normal
operation (SUS = low, Table 4), and VOFFSET is the offset
voltage defined by the OFS pin (Figure 3). In suspend
mode (SUS = high), the offset voltage amplifier is disabled
and the target voltage tracks the SUSV input voltage:
VTARGET = VSUSV + VGNDS
when SUS = VCC
The MAX8707 uses a multiplexer that selects from one of
three different inputs (Figure 2)—the output of the VID
DAC, the SUSV suspend voltage, or ground (controller
disabled). On startup, the MAX8707 slews the target voltage from ground to either the decoded D0–D4 (SUS =
low) voltage or the SUSV voltage (SUS = high).
DAC Inputs (D0–D4)
During normal forced-PWM operation (SUS = low), the
DAC programs the output voltage using the D0–D4
inputs. D0–D4 are low-voltage (1.0V) logic inputs,
designed to interface directly with the CPU. Do not leave
D0–D4 unconnected. D0–D4 can be changed while the
MAX8707 is active, initiating a transition to a new outputvoltage level. Change D0–D4 together, avoiding greater
than 50ns skew between bits. Otherwise, incorrect DAC
readings may 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
22
0.8V
-200mV
0
0.5V
1.2V
1.0V
1.5V
2.0V
OFS VOLTAGE (VOFS)
Figure 3. Output Offset Voltage vs. OFS Input Voltage
are compatible with the AMD Hammer (Table 4) specifications.
Suspend Mode
When the processor enters low-power suspend mode,
the processor sets the regulator to a lower output voltage
to reduce power consumption. The MAX8707 includes a
buffered suspend-voltage input (SUSV) and a digital
SUS control input. The suspend voltage is adjusted with
an external resistive voltage-divider from REF to SUSV to
analog ground. The suspend-voltage adjustment range
is from 0.4V to 2.0V (VREF).
When the CPU suspends operation (SUS = high), the
controller disables the offset amplifier, overrides the 5-bit
VID-DAC code set by D0–D4, and slews the output voltage to the target voltage set by the SUSV voltage. During
the transition, the MAX8707 blanks both VROK thresholds until 20µs after the slew-rate controller reaches the
suspend-mode voltage. Once the 20µs timer expires, the
MAX8707 (SKIP pulled low) automatically switches to the
1-phase, pulse-skipping control scheme, forces DRSKP
low, and blanks the upper VROK threshold.
Output-Voltage Transition Timing
The MAX8707 performs mode transitions in a controlled
manner, automatically minimizing input surge currents.
This feature allows the circuit designer to achieve nearly
______________________________________________________________________________________
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
D4
D3
D2
D1
D0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
OUTPUT VOLTAGE
(V)
1.550
1.525
1.500
1.475
1.450
1.425
1.400
1.375
1.350
1.325
1.300
1.275
1.250
1.225
1.200
1.175
D4
D3
D2
D1
D0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
OUTPUT VOLTAGE
(V)
1.150
1.125
1.100
1.075
1.050
1.025
1.000
0.975
0.950
0.925
0.900
0.875
0.850
0.825
0.800
No CPU*
*No-CPU Mode: The controller enters the no-CPU mode by ramping down the output voltage to 0V with the shutdown slew rate.
When exiting the no-CPU mode, the controller ramps the output up to the new VID output voltage using the startup slew rate. In noCPU mode, the controller remains in standby so VID transitions may be detected.
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
MAX8707 blanks both VROK thresholds, preventing the
VROK open-drain output from changing states during
the transition. The controller enables the lower VROK
threshold approximately 20µs after the slew-rate controller reaches the target output voltage, but the upper
VROK threshold is enabled only if the controller remains
in forced-PWM operation. If the controller enters pulseskipping operation, the upper VROK threshold remains
blanked. 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.
When transitions occur in pulse-skipping mode, the
MAX8707 sets OVP to 1.75V and disables the integrator
at the beginning of all transitions. OVP remains at 1.75V
and the integrator remains disabled until 20µs after the
transition is completed (internal target settles) and the
output is in regulation (an error-comparator edge is
detected).
The MAX8707 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 set by ILIM(AVE) and ILIM(PK). For
voltage transitions into and out of suspend mode, the
transition time (tTRAN) is given by:
t TRAN(SUS) =
| VNEW - VOLD |
dVTARGET / dt
where dVTARGET / dt = 6.25mV/µs × 143kΩ / 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 tSLEW limits. For soft-start and shutdown, the controller automatically reduces the slew rate by 1/4th:
______________________________________________________________________________________
23
MAX8707
Table 4. AMD Hammer Output-Voltage VID DAC Codes (SUS = GND)
MAX8707
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
t TRAN(START) = t TRAN(SHDN) =
4 VTARGET
dVTARGET / dt
For all dynamic VID transitions, the rate at which the
VID inputs (D0–D4) are clocked sets the slew rate, with
a maximum slew-rate limit set by the RTIME value. The
practical range of RTIME is 47kΩ to 392kΩ corresponding to slew rates of 19mV/µs to 2.28mV/µs, respectively.
The output voltage tracks the slewed target voltage,
making the transitions relatively smooth.
The average inductor current per phase required to
make an output-voltage transition is:
IL ≅
COUT
× (dVTARGET / dt)
ηPH
where dVTARGET / dt is the required slew rate, COUT is
the total output capacitance, and ηPH is the number of
active phases.
Suspend Transition
(Forced-PWM Operation Selected)
When the MAX8707 enters suspend mode while configured for forced-PWM operation (SKIP pulled low), the
controller ramps the output voltage down to the programmed SUSV voltage at the slew rate determined by
RTIME. The controller blanks VROK (forced high impedance) until 20µs after the transition is completed—internal
target voltage equals the SUSV voltage. After this blanking time expires, the controller automatically shuts down
phases 2, 3, and 4 (DRSKP pulled low), and enters single-phase, pulse-skipping operation. VROK monitors only
the lower threshold in skip mode.
When exiting suspend mode (SUS pulled low), the
MAX8707 immediately activates all enabled phases
(DRSKP driven high) so the output voltage may be
ramped up at the slew rate set by RTIME. The controller
blanks VROK (forced high impedance) until 20µs after
the transition is completed—internal target voltage
equals the selected VID-DAC voltage.
Suspend Transition
(Pulse-Skipping Operation Selected)
If the MAX8707 is configured for pulse-skipping operation (SKIP = high) when SUS goes high, the MAX8707
immediately disables phases 2, 3, and 4 (DRSKP pulled
low) and enters pulse-skipping operation (Figure 5). The
output drops at a rate determined by the load and the
output capacitance. The internal target still ramps as
before, and VROK remains high impedance until the
new target is reached plus an extra 20µs. After this time
expires, VROK monitors only the lower threshold.
24
When exiting deeper sleep (SUS pulled low), the
MAX8707 starts to slew the internal target up towards
the new target. The controller remains in skip mode
while the output voltage is higher than the internal target. As the internal target approaches the output voltage, the MAX8707 activates all enabled phases
(DRSKP driven high) so the output voltage may be
ramped up at the slew rate set by RTIME. The controller
blanks VROK (forced high impedance) until 20µs after
the transition is completed.
Forced-PWM Operation (Normal Mode)
During soft-start, soft-shutdown, and normal operation—
when the CPU is actively running (SKIP = low, Table 5)—
the MAX8707 operates with a low-noise, forced-PWM control scheme. Forced-PWM operation forces DRSKP high,
instructing the drivers to disable their zero-crossing comparators and force 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 200mA
per phase, depending on the external MOSFETs and
switching frequency. To maintain high efficiency under
light-load conditions, the controller switches to a lowpower pulse-skipping control scheme after entering suspend mode.
Light-Load Pulse-Skipping Operation
The MAX8707 includes a light-load operating-mode control input (SKIP) used to disable extra phases and
enable/disable the driver’s zero-crossing comparator.
When the driver’s zero-crossing comparators are enabled
(DRSKP pulled low), the controller forces PWM_ low for
the disabled phases so the driver pulls DL_ low when its
current-sense inputs detect zero inductor current. This
keeps the inductor from discharging the output capacitors and forces the controller to skip pulses under lightload conditions to avoid overcharging the output. When
the zero-crossing comparators are disabled, each controller maintains PWM operation under light-load conditions (forced PWM).
After the MAX8707 enters suspend mode while configured for forced-PWM operation (SKIP pulled low), the
controller automatically switches to the pulse-skipping
control scheme 20µs after the target voltage reaches
the programmed SUSV voltage.
When pulse-skipping operation is enabled, the controller terminates the on-time when the output voltage
exceeds the feedback threshold and when the current-
______________________________________________________________________________________
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
MAX8707
VID
CPU CORE
VOLTAGE
SUSV
SUS
INTERNAL
PWM CONTROL
FORCED-PWM
AUTO 1-PHASE SKIP
HIGH-Z
LOW THRESHOLD ONLY
FORCED-PWM
PWM1
PWM2
PWM3
PWM4
DRSKP
VROK
HIGH-Z
tBLANK
20µs typ
tBLANK
20µs typ
NOTE: OVP CONSTANTLY TRACKS THE INTERNAL TARGET, AND THE INTEGRATOR (CCV) IS CONSTANTLY ENABLED.
Figure 4. Suspend Transition in Forced-PWM Mode (SKIP = low)
VID
ACTUAL VOUT
CPU CORE
VOLTAGE
TARGET
SUSV
SKIP = SUS
INTERNAL
PWM CONTROL
1-PHASE SKIP
FORCED PWM
PWM1
PWM2
PWM3
PWM4
DRSKP
VROK
HIGH-Z
LOW VROK THRESHOLD ONLY
OVP/CCV
OVP = 1.8V INTEGRATOR DISABLED
tBLANK
20µs
HIGH-Z
OVP TRACKS INTERNAL TARGET
INTEGRATOR ENABLED
tBLANK
20µs
Figure 5. Suspend Transition in Pulse-Skipping Operation (SKIP = SUS)
______________________________________________________________________________________
25
MAX8707
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
Table 5. SKIP Settings
SKIP
(INPUT)
SUS
(INPUT)
Low
(GND)
MODE
Multiphase
Forced-PWM
DRSKP
(OUTPUT)
OPERATION
High
(VDD)
The controller operates with a constant switching
frequency, providing low-noise forced-PWM operation. The
controller disables the zero-crossing comparators, forcing
the low-side gate-drive waveform to constantly be the
complement of the high-side gate-drive waveform.
Low
(GND)
High
(>1.2V)
High
(3.3V or VCC)
1-Phase Pulse
Skipping
Low
(PGND)
The controller automatically switches to pulse-skipping
operation 20µs after the target voltage reaches the SUSV
voltage. Pulse-skipping operation forces the controller into
PFM operation under light loads. Phase 1 remains active
while the other three phases are disabled—PWM2, PWM3,
and PWM4 pulled low.
Don’t Care
1-Phase Pulse
Skipping
Low
(PGND)
Pulse-skipping operation forces the controller into PFM
operation under light loads. Phase 1 remains active while
the other three phases are disabled—PWM2, PWM3, and
PWM4 pulled low.
sense voltage exceeds the Idle Mode current-sense
threshold (VIDLE = 0.1 x VPKLIMIT). Under heavy-load
conditions, the continuous inductor current remains
above the Idle-Mode current-sense threshold, so the
on-time depends only on the feedback-voltage threshold. Under light-load conditions, the controller remains
above the feedback-voltage threshold, so the on-time
duration depends solely on the Idle-Mode currentsense threshold, which is approximately 10% of the fullload current-limit threshold set by ILIM(PK).
When the controller enters suspend mode while SKIP is
pulled high, the multiphase controller immediately disables three phases, and only the main phase (PWM1)
remains active. When pulse skipping, the controller
blanks the upper VROK threshold and the OVP threshold
tracks the selected VID DAC code. The MAX8707 automatically uses forced-PWM operation during soft-start
and soft-shutdown, regardless of the SKIP configuration.
Idle-Mode Current Sense Threshold
The Idle-Mode current-sense threshold forces a lightly
loaded regulator to source a minimum amount of energy with each on-time since the controller cannot terminate the on-time until the current-sense voltage
exceeds the Idle-Mode current-sense threshold (VIDLE
= 0.1 x VPKLIMIT). Since the zero-crossing comparator
prevents the switching regulator from sinking current,
the controller must skip pulses to avoid overcharging
the output. When the clock edge occurs, if the output
voltage still exceeds the feedback threshold, the con-
troller does not initiate another on-time. This forces the
controller to actually regulate the valley of the output
voltage ripple under light-load conditions.
Automatic Pulse-Skipping Crossover
In skip mode, the MAX8707 disables three phases and
forces DRSKP low to instruct the skip-mode drivers to
activate their zero-crossing comparators. Therefore, an
inherent automatic switchover to PFM takes place at light
loads (Figure 6), resulting in a highly efficient operating
mode. This switchover is affected by a comparator that
truncates the low-side switch on-time at the inductor current’s zero crossing. The driver’s zero-crossing comparator senses the inductor current across the low-side
MOSFET (refer to the skip-mode driver data sheet).
Once V LX - V PGND drops below the zero-crossing
threshold, the driver 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 inductor-current operation (also known as the critical conduction
point). The load-current level at which the PFM/PWM
crossover occurs, ILOAD(SKIP), is given by:
ILOAD(SKIP) =
VOUT ( VIN − VOUT )
2VINfSW L
The switching waveforms may appear noisy and asynchronous when light loading causes pulse-skipping
operation, but this is a normal operating condition that
Idle Mode is a trademark of Maxim Integrated Products, Inc.
26
______________________________________________________________________________________
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
The output current of each phase is sensed differentially. Each phase of the MAX8707 has an independent
return path for fully differential current-sense. A low offset voltage and high-gain (10V/V) differential current
amplifier at each phase allow low-resistance currentsense resistors to be used to minimize power dissipation. 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. This current-sense method uses an
RC filtering network to extract the current information
from the output inductor (Figure 7). The time constant
of the RC network should match the inductor’s time
constant (L/RDCR):
L
= REQ CSENSE
RDCR
where CSENSE is the sense capacitor and REQ is the
equivalent sense resistance. To minimize the currentsense error due to the current-sense inputs’ bias current (ICSP_ and ICSN_), choose REQ less than 2kΩ and
use the above equation to determine the sense capacitance (CSENSE). Choose capacitors with 5% tolerance
and resistors with 1% tolerance specifications.
Temperature compensation is recommended for this
current-sense method.
When using a current-sense resistor for accurate output-voltage positioning (CRSP to CRSN for the
MAX8707), differential RC-filter circuits should be used
to cancel the equivalent series inductance of the current-sense resistor (Figure 7). Similar to inductor DCRsensing methods, the RC filter’s time constant should
match the L/R time constant formed by the currentsense resistor’s parasitic inductance:
VOUT
VINfSW
IIDLE
INDUCTOR CURRENT
Current Sense
tON(SKIP) =
MAX8707
results in high light-load efficiency. Trade-offs in PFM
noise vs. 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).
ILOAD ≈ ILOAD(SKIP)
2
0
ON-TIME
TIME
Figure 6. Pulse-Skipping/Discontinuous Crossover Point
LESL
= REQ CSENSE
RSENSE
where LESL is the equivalent series inductance of the
current-sense resistor, R SENSE is the current-sense
resistance value, CSENSE is the compensation capacitor, and REQ is the equivalent compensation resistance.
Current Balance
The fixed-frequency, multiphase, current-mode architecture automatically forces the individual phases to
remain current balanced. After the oscillator triggers an
on-time, the controller does not terminate the on-time
until the amplified differential current-sense voltage
reaches the integrated threshold voltage (VREF - VTRC).
This control scheme regulates the peak inductor current of each phase, forcing them to remain properly
balanced. Therefore, the average inductor-current variation depends mainly on the variation in the currentsense element and inductance value.
Peak/Average Current Limit
The MAX8707 current-limit circuit employs a fast peak
inductor current-sensing algorithm. Once the currentsense signal (CSP to CSN) of the active phase exceeds
the peak current-limit threshold, the PWM controller terminates the on-time. The MAX8707 also includes a
slower average current sense that uses a current-sense
resistor between CRSP and CRSN to accurately limit
the inductor current. When this average current-sense
threshold is exceeded, the current-limit circuit lowers
the peak current-limit threshold, effectively lowering the
average inductor current. See the Current Limit section
in the Design Procedure section.
______________________________________________________________________________________
27
MAX8707
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
INPUT (VIN)
INPUT (VIN)
CIN
CIN
DRIVER
DRIVER
DH
NH
DH
L
PWM
PWM_
INDUCTOR
RSENSE
L
LX
DL
NH
RDCR
LX
COUT
NL
DL
DL
PGND
PWM
PWM_
CSP_
CSN_
COUT
NL
DL
REQ
PGND
CSENSE
CSP_
CSN_
CONTROLLER
CONTROLLER
A) OUTPUT SERIES RESISTOR SENSING
B) LOSSLESS INDUCTOR SENSING
Figure 7. Current-Sense Methods
Power-Up Sequence (POR, UVLO)
Power-on reset (POR) occurs when VCC rises above
approximately 2V, resetting the fault latch and preparing the controller for operation. The VCC undervoltagelockout (UVLO) circuitry inhibits switching—forces
DRSKP high and pulls the PWM_ outputs low—until
VCC rises above 4.25V. The controller powers up the
reference once the system enables the controller—VCC
above 4.25V and SHDN pulled high. With the reference
in regulation, the controller begins to slew the output
voltage to the target voltage—either the output of the
VID DAC (SUS = low) or the SUSV suspend voltage
(SUS = high)—at 1/4th the slew rate set by RTIME:
t TRAN(START) =
4 VTARGET
dVTARGET / dt
where dVTARGET / dt = 6.25mV/µs × 143kΩ / RTIME is the
slew rate. The soft-start circuitry does not use a variable
current limit, so full output current is available immediately. VROK becomes high impedance approximately 20µs
after the MAX8707 reaches the target voltage.
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
28
down until the fault latch is cleared by toggling SHDN
or cycling the VCC power supply below 1V.
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—
forces DRSKP high and pulls the PWM_ outputs low.
Shutdown
When SHDN goes low, the MAX8707 enters low-power
shutdown mode. VROK is pulled low immediately, and
the output voltage ramps down at 1/4th the slew rate
set by RTIME:
t TRAN(SHDN) =
4 VOUT
dVTARGET / dt
where dVTARGET / dt = 6.25mV/µs × 143kΩ / 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
______________________________________________________________________________________
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
MAX8707
VCC
SHDN
VID (D0-D4)
INVALID
CODE
INVALID
CODE
SOFT-START
1/4TH SLEW RATE SET BY RTIME
SOFT-SHUTDOWN
1/4TH SLEW RATE SET BY RTIME
VCORE
INTERNAL
PWM CONTROL
FORCED-PWM
FORCED-PWM
DRSKP
VROK
tBLANK
20s typ
tBLANK
20s typ
Figure 8. Power-Up and Shutdown Sequence Timing Diagram
the negative output-voltage excursion. When the controller reaches the 0V target, the drivers are disabled
(DRSKP driven low and PWM_ outputs pulled low), the
reference turns off, and the supply current drops to
about 10µA (max). 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 1V.
Fault Protection
Output Overvoltage Protection (Unlatched)
The overvoltage-protection (OVP) circuit is designed to
protect the CPU against a shorted high-side MOSFET
by drawing high current and blowing the battery fuse.
The MAX8707 continuously monitors the output for an
overvoltage fault. The controller detects an OVP fault if
the output voltage exceeds the set target voltage by
more than 200mV. After entering pulse-skipping operation (SKIP rising edge), the OVP threshold is set to
1.75V until the output voltage drops below the target
voltage for the first time. Once the MAX8707 detects
the output is being regulated (VOUT ≈ VTARGET), the
OVP threshold begins tracking the target voltage again.
When the OVP circuit detects an overvoltage fault, it
immediately enters forced-PWM operation—pulling
DRSKP high so the drivers force the low-side gate dri-
vers high (DL = VDD) and pull the high-side gate drivers low (DH = LX). The controller does not initiate an
on-time pulse until the output voltage drops below the
OVP threshold. This action turns on the synchronousrectifier MOSFET with 100% duty and, in turn, rapidly
discharges the output filter capacitor and forces the
output low. If the condition that caused the overvoltage
(such as a shorted high-side MOSFET) persists, the
battery fuse blows.
Overvoltage protection can be disabled through the nofault test mode (see the No-Fault Test Mode section).
Output Undervoltage Protection (Latched)
The output undervoltage-protection (UVP) function is
similar to foldback current limiting, but employs a timer
rather than a variable current limit. If the MAX8707 output voltage is under 70% of the nominal value, the controller activates the shutdown sequence and sets the
fault latch. Once the controller ramps down to the 0V
setting, it forces the PWM_ driver outputs low. Toggle
SHDN or cycle the VCC power supply below 1V 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).
Thermal Fault Protection (Latched)
The MAX8707 features a thermal fault-protection circuit.
When the junction temperature rises above +160°C, a
______________________________________________________________________________________
29
MAX8707
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
thermal sensor sets the fault latch and activates the
soft-shutdown sequence. Once the controller ramps
down to the 0V setting, it forces the PWM_ driver outputs low. Toggle SHDN or cycle the VCC power supply
below 1V 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).
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—overvoltage 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.
Multiphase, Fixed-Frequency
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
ηPH
30
where ηPH is the total number of active phases.
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 tradeoffs 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 sizereduction 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:

 V
VIN − VOUT
OUT 
L = ηPH 


 fSW ILOAD(MAX) LIR   VIN 
where ηPH is the total number of phases, and fSW is the
switching frequency per phase.
Find a low-loss inductor with the lowest possible DC
resistance that fits in the allotted dimensions. If using a
swinging inductor (where the no-load inductance
decreases linearly with increasing current), evaluate
the LIR with properly scaled inductance values. For the
selected inductance value, the actual peak-to-peak
inductor ripple current (∆IINDUCTOR) is defined by:
V
(V − V
)
∆IINDUCTOR = OUT IN OUT
VIN fSW L
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)   ∆IINDUCTOR 
IPEAK = 

 + 

ηPH
2


______________________________________________________________________________________
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
RILIM(PK) =
8V × RTRC
IPKLIMIT RSENSE
where RSENSE is the resistance value of the currentsense element (inductors’ DCR or current-sense resistor), RTRC is the resistance between TRC and REF, and
IPKLIMIT is the desired peak current limit (per phase).
The peak current-limit-threshold voltage adjustment
range is from 20mV to 80mV.
The peak current-limit circuit also prevents excessive
reverse inductor currents when VOUT is sinking current.
The negative current-limit threshold is equivalent to the
positive current limit, and tracks the positive current limit
when RILIM(PK) or RTRC are adjusted. When a phase
drops below the negative current limit, the controller activates an on-time pulse at the next clock edge, regardless of the error-amplifier state, until the inductor current
rises above the negative current-limit threshold.
Average Inductor Current-Limit
(ILIM(AVE))
The MAX8707 also uses the accurate CRSP to CRSN current-sense voltage to limit the average current per phase.
When the average current-limit threshold is exceeded,
the controller internally reduces the peak inductor current-limit threshold (ILIM(PK)) until the average current
remains within the programmed limits. When the accurate
current sensing is disabled (CRSP = VCC), the average
current-limit circuit is disabled.
The average current-limit threshold defaults to 25mV if
ILIM(AVE) is connected to VCC. In adjustable mode, the
average current-limit threshold voltage is precisely
1/20th the voltage difference between ILIM(AVE) and
the reference:
VLAVE =
VREF − VILIM( AVE)
20
The logic threshold for switchover to the 25mV default
value is approximately VCC - 1V. The average currentlimit circuit also prevents against excessive reverse
inductor current when VOUT is sinking current. The negative current-limit threshold is equivalent to the positive
current limit, and tracks the positive current limit when
VLAVE is adjusted.
Output-Capacitor Selection
The output filter capacitor must have low enough effective series resistance (ESR) to meet output ripple and
load-transient 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
∆ILOAD(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
(VRIPPLE) by reducing the total inductor ripple current.
For nonoverlapping, multiphase operation (VIN ≥ ηPH
x VOUT), the maximum ESR to meet the output-ripplevoltage requirement is:
VIN fSW L


RESR ≤ 
VRIPPLE
(
V
−
η
V
)
V
 IN
PH OUT OUT 
where ηPH 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 selection is
usually limited by ESR and voltage rating rather than by
capacitance value (this is true of polymer types).
______________________________________________________________________________________
31
MAX8707
Current Limit
Peak Inductor Current Limit (ILIM(PK))
The MAX8707 overcurrent protection employs a peak
current-sensing algorithm that uses either currentsense resistors or the inductor’s DCR as the currentsense element (see the Current Sense section). Since
the controller limits the peak inductor current, the maximum average load current is less than the peak current-limit threshold by an amount equal to half the
inductor ripple current. Therefore, the maximum load
capability is a function of the current-sense resistance,
inductor value, switching frequency, and input voltage.
When combined with the undervoltage-protection circuit, this current-limit method is highly effective.
The peak current-limit threshold is set with a single external resistor between ILIM(PK) and analog ground, where
the resistor is determined by the following equation:
MAX8707
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
The capacitance value required is determined primarily
by the output transient-response requirements. Low
inductor values allow the inductor current to slew faster,
replenishing the charge removed from or added to the
output filter capacitors by a sudden load step.
Therefore, the amount of output soar when the load is
removed is a function of the output voltage and inductor value. The minimum output capacitance required to
prevent overshoot (VSOAR) due to stored inductor energy can be calculated as:
COUT ≥
(∆ILOAD(MAX) )2 L
2ηPH VOUT VSOAR
where ηPH is the total number of active phases. When
using low-capacity ceramic filter capacitors, capacitor
size is usually determined by the capacity needed to
prevent 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.
Input Capacitor Selection
The input capacitor must meet the ripple-current
requirement (IRMS) imposed by the switching currents.
The multiphase controllers operate out-of-phase, which
reduces the RMS input current by dividing the input current between several staggered stages. For duty cycles
less than 100%/ηPH per phase, the IRMS requirements
can be determined by the following equation:
 I

IRMS =  LOAD  ηPHVOUT (VIN − ηPHVOUT )
 ηPHVIN 
where ηPH is the total number of out-of-phase switching
regulators. The worst-case RMS current requirement
occurs when operating with VIN = 2ηPH VOUT. At this
point, the above equation simplifies to I RMS = 0.5 x
ILOAD / ηPH.
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 MAX8707 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.
32
Setting Voltage Positioning
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 two transconductance amplifiers to set the transient and DC output voltage droop (Figure 2). The transient-compensation
(TRC) amplifier determines how quickly the MAX8707
responds to the load transient. The slower voltage-positioning (VPS) amplifier adjusts the steady-state regulation voltage as a function of the load. This adjustability
allows flexibility in the selected current-sense resistor
value or inductor DCR, and allows smaller currentsense resistance to be used, reducing the overall
power dissipated.
Steady-State Voltage Positioning
Connect a resistor (RVPS) between VPS and FBS to set
the DC steady-state droop (load line) based on the
required DC voltage-positioning slope (RDROOP):
RVPS =
RDROOP
RSENSE GM(VPS)
where the current-sense resistance (RSENSE) depends
on the current-sense method, and the voltage-positioning amplifier’s transconductance (GM(VPS)) is typically
200µS as defined in the Electrical Characteristics table.
When the MAX8707 CRS sensing is enabled, RSENSE is
defined as the accurate CRS current-sense resistance:
RSENSE = RCRS
when CRS sensing is enabled.
When the MAX8707 CRS sensing is disabled, the controller sums together the input signals of the currentsense inputs (CSP_, CSN_). These inputs typically use
the inductors’ DC resistance (RDCR) to sense the current, so RSENSE is defined as the average of the effective CS current-sense resistances (see the Current
Sense section):
RSENSE = RDCR
when CRS sensing is disabled.
When the inductors’ DCR (RDCR) is used as the current-sense elements (for lossless sensing), RVPS should
include an NTC thermistor to minimize the temperature
dependence of the voltage-positioning slope.
To avoid output-voltage errors caused by the voltagepositioning current, a second transconductance amplifier generates an equivalent current on the FBS input.
Accurate MAX8707 CRS sensing is disabled by connecting CRSP to VCC.
______________________________________________________________________________________
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
Transient Droop
Connect a resistor (RTRC) between TRC and REF to set
the transient droop (RDROOP(AC)) based on the voltagepositioning requirements. TRC allows the controller to
quickly respond to load transients, but it does not affect
the DC steady-state droop. Choose RTRC based on the
equation:
RTRC =
RTRANSRCS
ηPHRDROOP( AC)
where RCS is the current-sense element connected from
CSP_ to CSN_ (which is typically the inductor’s effective
DCR: RCS = L / REQCSENSE), RTRANS is the currentsense amplifier gain divided by the transient amplifier’s
transconductance as defined in the Electrical Characteristics table, and RDROOP(AC) is typically 80% of the DC
voltage-positioning slope to minimize the transient
sag voltage.
The TRC resistance also sets the small-signal loop gain,
so a maximum RTRC value is required for stability, even
if voltage positioning is not used (VPS = FBS).
VRIPPLE RTRC < (RTRANS RSENSE ∆IL) / 3
TRC is high impedance in shutdown.
Applications Information
Duty-Cycle Limits
Minimum Input Voltage
The minimum input operating voltage (dropout voltage)
is restricted by stability requirements, not the minimum
off-time (tOFF(MIN)). The MAX8707 does not include
slope compensation, so the controller becomes unstable with duty cycles greater than 50% per phase:
VIN(MIN) ≥ 2VOUT(MAX)
However, the controller may briefly operate with duty
cycles over 50% during heavy load transients.
Maximum Input Voltage
The MAX8707 controller and driver has a minimum ontime, which determines the maximum input operating
voltage that maintains the selected switching frequency. With higher input voltages, each pulse delivers
more energy than the output is sourcing to the load. At
the beginning of each cycle, if the output voltage is still
above the feedback threshold voltage, the controller
does not trigger an on-time pulse resulting in pulseskipping operation regardless of the operating mode
selected by SKIP. This allows the controller to maintain
regulation above the maximum input voltage, but forces
the controller to effectively operate with a lower switching frequency. This results in an input threshold voltage
at which the controller begins to skip pulses (VIN(SKIP)):


1
VIN(SKIP) = VOUT 

 fSW t ON(MIN) 
where fSW is the switching frequency per phase selected by OSC, and tON(MIN) is 110ns plus the driver’s
turn-off delay (PWM low to LX low) minus the driver’s
turn-on delay (PWM high to LX high). For the best highvoltage performance, use the slowest switching-frequency setting (200kHz per phase, OSC = GND).
PC Board Layout Guidelines
Careful PC board layout is critical to achieve low
switching losses and clean, stable operation. The
switching power stage requires particular attention
(Figure 9). If possible, mount all of the power components on the top side of the board with their ground terminals flush against one another. Follow these
guidelines for good PC board layout:
1) Keep the high-current paths short, especially at the
ground terminals. This is essential for stable, jitterfree operation.
2) Connect all analog grounds to a separate solid copper plane, which connects to the GND pin of the
controller. This includes the VCC bypass capacitor,
REF and GNDS bypass capacitors, compensation
(CCV, TRC) components, and the resistive dividers
connected to ILIM(AVE), SUSV, and OFS.
3) Keep the power traces and load connections short.
This is essential for high efficiency. The use of thick
copper PC boards (2oz vs. 1oz) can enhance fullload efficiency by 1% or more. Correctly routing PC
board 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.
4) Connections for current limiting (CSP_, CSN_) and
voltage positioning (CRSP, CRSN) must be made
using Kelvin-sense connections to guarantee the
current-sense accuracy.
5) Route high-speed switching nodes and driver traces
away from sensitive analog areas (REF, CCV, TRC,
VPS, etc.). Make all pin-strap control input connections (SHDN, SKIP, SUS, OSC) to analog ground or
VCC rather than power ground or VDD.
6) Keep the drivers close to the MOSFET, with the
gate-drive traces (DL, DH, LX, and BST) short and
wide to minimize trace resistance and inductance.
______________________________________________________________________________________
33
MAX8707
Disable voltage positioning by shorting VPS directly to FBS.
MAX8707
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
KELVIN SENSE VIAS UNDER
THE SENSE RESISTOR
(REFER TO THE EVALUATION KIT)
CPU
RSENSE
INDUCTOR
COUT
INDUCTOR
CIN
POWER
GROUND
CIN
CIN
CIN
CIN
CIN
COUT
INDUCTOR
POWER
GROUND
INDUCTOR
COUT
COUT
COUT
COUT
OUTPUT
INPUT
PLACE CONTROLLER ON
BACKSIDE WHEN POSSIBLE,
USING THE GROUND PLANE
TO SHIELD THE IC FROM EMI
ANALOG GROUND
(INNER LAYER)
CONNECT THE
EXPOSED PAD TO
ANALOG GND
POWER GROUND
(INNER LAYER)
CONNECT GND AND PGND TO THE
CONTROLLER AT ONE POINT
ONLY AS SHOWN
Figure 9. PC Board Layout Example
34
______________________________________________________________________________________
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
Layout Procedure
1) Place the power components first, with ground terminals adjacent (low-side MOSFET source, CIN, COUT,
and D1 anode). If possible, make all these connections on the top layer with wide, copper-filled areas.
2) Mount the driver IC adjacent to the low-side
MOSFETs. The DL gate traces must be short and
wide (50mils to 100mils wide if the MOSFET is 1in
from the driver IC).
ground planes: input/output ground, where all the
high-power components go; the power ground
plane, where the PGND pin, VDD bypass capacitor,
and driver IC ground connection go; and the controller’s analog ground plane, where sensitive analog components, the master’s GND pin, and the VCC
bypass capacitor go. The controller’s analog ground
plane (GND) must meet the power ground plane
(PGND) only at a single point directly beneath the
IC. The power ground plane should connect to the
high-power output ground with a short, thick metal
trace from PGND to the source of the low-side
MOSFETs (the middle of the star ground).
5) Connect the output power planes (VCORE and system ground planes) directly to the output-filtercapacitor positive and negative terminals with
multiple vias. Place the entire DC-DC converter circuit as close to the CPU as is practical.
3) Group the gate-drive components (BST diodes and
capacitors, VDD bypass capacitor) together near the
driver IC.
4) Make the DC-DC controller ground connections as
shown in the Standard Application Circuits. This diagram can be viewed as having three separate
______________________________________________________________________________________
35
MAX8707
This is essential for high-power MOSFETs that
require low-impedance gate drivers to avoid shootthrough currents.
7) When trade-offs in trace lengths must be made, it’s
preferable to allow the inductor charging path to be
made longer than the discharge path. For example,
it’s 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.
MAX8707
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
Chip Information
Pin Configuration
TRANSISTOR COUNT: 9011
PROCESS: BiCMOS
CSP1
CSN1
CSP2
CSN2
CSN3
CSP3
CSP4
CSN4
D1
D0
TOP VIEW
40 39 38 37 36 35 34 33 32 31
D2
1
30 CRSP
D3
2
29 CRSN
D4
3
28 VPS
N.C.
4
27 FBS
SKIP
5
SHDN
6
SUS
7
24 PWM3
SUSV
8
23 PWM2
ILIM(AVE)
9
22 PWM1
26 DRSKP
MAX8707
25 PWM4
OFS 10
21 VCC
PGND
GND
REF
VROK
TRC
CCV
TIME
ILIM(PK)
OSC
GNDS
11 12 13 14 15 16 17 18 19 20
THIN QFN
6mm x 6mm
36
______________________________________________________________________________________
Multiphase, Fixed-Frequency Controller for
AMD Hammer CPU Core Power Supplies
QFN THIN 6x6x0.8.EPS
D2
D
CL
D/2
b
D2/2
k
E/2
E2/2
(NE-1) X e
E
CL
E2
k
e
L
(ND-1) X e
e
L
CL
CL
L1
L
L
e
A1
A2
e
A
PACKAGE OUTLINE
36, 40, 48L THIN QFN, 6x6x0.8mm
21-0141
E
1
2
NOTES:
1. DIMENSIONING & TOLERANCING CONFORM TO ASME Y14.5M-1994.
2. ALL DIMENSIONS ARE IN MILLIMETERS. ANGLES ARE IN DEGREES.
3. N IS THE TOTAL NUMBER OF TERMINALS.
4. THE TERMINAL #1 IDENTIFIER AND TERMINAL NUMBERING CONVENTION SHALL CONFORM TO JESD 95-1
SPP-012. DETAILS OF TERMINAL #1 IDENTIFIER ARE OPTIONAL, BUT MUST BE LOCATED WITHIN THE
ZONE INDICATED. THE TERMINAL #1 IDENTIFIER MAY BE EITHER A MOLD OR MARKED FEATURE.
5. DIMENSION b APPLIES TO METALLIZED TERMINAL AND IS MEASURED BETWEEN 0.25 mm AND 0.30 mm
FROM TERMINAL TIP.
6. ND AND NE REFER TO THE NUMBER OF TERMINALS ON EACH D AND E SIDE RESPECTIVELY.
7. DEPOPULATION IS POSSIBLE IN A SYMMETRICAL FASHION.
8. COPLANARITY APPLIES TO THE EXPOSED HEAT SINK SLUG AS WELL AS THE TERMINALS.
9. DRAWING CONFORMS TO JEDEC MO220, EXCEPT FOR 0.4mm LEAD PITCH PACKAGE T4866-1.
10. WARPAGE SHALL NOT EXCEED 0.10 mm.
PACKAGE OUTLINE
36, 40, 48L THIN QFN, 6x6x0.8mm
21-0141
E
2
2
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.
Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 ____________________ 37
© 2004 Maxim Integrated Products
Printed USA
is a registered trademark of Maxim Integrated Products.
MAX8707
Package Information
(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,
go to www.maxim-ic.com/packages.)