INTERSIL ISL6324AIRZ

ISL6324A
Hybrid SVI/PVI with I2C
®
Data Sheet
April 29, 2010
Monolithic Dual PWM Hybrid Controller
Powering AMD SVI Split-Plane and PVI
Uniplane Processors
The ISL6324A dual PWM controller delivers high efficiency
and tight regulation from two synchronous buck DC/DC
converters. The ISL6324A supports hybrid power control of
AMD processors which operate from either a 6-bit parallel
VID interface (PVI) or a serial VID interface (SVI). The dual
output ISL6324A features a multi-phase controller to support
uniplane VDD core voltage and a single phase controller to
power the Northbridge (VDDNB) in SVI mode. Only the
multi-phase controller is active in PVI mode to support
uniplane VDD only processors.
FN6880.1
Features
Processor Core Voltage Regulator Features
• Configuration Flexibility
- 1- or 2-Phase Operation with Internal Drivers
- 3- or 4-Phase Operation with External PWM Drivers
• Parallel VID (6-bit) Interface Inputs for PVI Mode
• PSI_L Support via Phase Shedding
• Differential Remote Voltage Sensing
• Optimal Processor Core Voltage Transient Response
- Adaptive Phase Alignment (APA)
- Active Pulse Positioning Modulation
A precision uniplane core voltage regulation system is provided
by a 2-to-4-phase PWM voltage regulator (VR) controller. The
integration of two power MOSFET drivers, adding flexibility in
layout, reduce the number of external components in the multiphase section. A single phase PWM controller with integrated
driver provides a second precision voltage regulation system
for the North Bridge portion of the processor. This monolithic,
dual controller with integrated driver solution provides a cost
and space saving power management solution.
Processor Core Voltage Regulator and North Bridge
Voltage Regulator Shared Features
For applications which benefit from load line programming to
reduce bulk output capacitors, the ISL6324A features output
voltage droop. The multi-phase portion also includes
advanced control loop features for optimal transient response
to load application and removal. One of these features is
highly accurate, fully differential, continuous DCR current
sensing for load line programming and channel current
balance. Dual edge modulation is another unique feature,
allowing for quicker initial response to high di/dt load
transients.
• Fully Differential, Continuous DCR Current Sensing
The ISL6324A supports Power Savings Mode by dropping
phases when the PSI_L bit is set. The number of phases
that the ISL6324A will drop to is programmable through an
I2C interface. The number of PWM cycles between both
dropping phases when entering Power Savings Mode and
adding phases when exiting Power Savings Mode is also
programmable through the I2C interface.
• Pb-Free (RoHS Compliant)
The ISL6324A I2C interface also allows independent
programmable output voltage offset for both the Core and
North Bridge regulators. The I2C interface can also be used
to set the PGOOD and OVP trip levels for both regulators as
well.
1
• Precision Voltage Regulation: ±0.5% System Accuracy
Over-Temperature
• Two Wire, AMD Compliant Serial VID Interface Inputs for
SVI Mode
• I2C Interface
- Voltage Margining, OVP and PGOOD Trip Levels
- Enhanced PSI_L State Control
- Accurate Load Line Programming
- Precision Channel Current Balancing for Core
• Overcurrent Protection
• Multi-tiered Overvoltage Protection
• Variable Gate Drive Bias: 5V to 12V
• Simultaneous Digital Soft-Start of Both Outputs
• Selectable Switching Frequency up to 1MHz
Ordering Information
PART
NUMBER
(Note)
PART
MARKING
ISL6324ACRZ* ISL6324A CRZ
ISL6324AIRZ*
ISL6324A IRZ
TEMP.
RANGE
(°C)
0 to +70
PACKAGE
(Pb-free)
PKG.
DWG. #
48 Ld 7x7 QFN L48.7x7
-40 to +85 48 Ld 7x7 QFN L48.7x7
*Add “-T” suffix for tape and reel. Please refer to TB347 for details on
reel specifications.
NOTE: These Intersil Pb-free plastic packaged products employ
special Pb-free material sets, molding compounds/die attach materials,
and 100% matte tin plate plus anneal (e3 termination finish, which is
RoHS compliant and compatible with both SnPb and Pb-free soldering
operations). Intersil Pb-free products are MSL classified at Pb-free peak
reflow temperatures that meet or exceed the Pb-free requirements of
IPC/JEDEC J STD-020.
CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures.
1-888-INTERSIL or 1-888-468-3774 | Intersil (and design) is a registered trademark of Intersil Americas Inc.
Copyright Intersil Americas Inc. 2009, 2010. All Rights Reserved
All other trademarks mentioned are the property of their respective owners.
ISL6324A
Pinout
COMP_NB
ISEN_NB-
ISEN4+
ISEN4-
ISEN3+
ISEN3-
PVCC_NB
LGATE_NB
BOOT_NB
UGATE_NB
PHASE_NB
VDDPWRGD
ISL6324A HYBRID SVI AND PVI
(48 LD QFN)
TOP VIEW
48
47
46
45
44
43
42
41
40
39
38
37
FB_NB
1
36 PWM4
ISEN_NB+
2
35 PWM3
SDA
3
34 PWROK
VID0/VFIXEN
4
33 PHASE1
VID1/SEL
5
32 UGATE1
VID2/SVD
6
VID3/SVC
7
30 LGATE1
VID4
8
29 PVCCI_2
VID5
9
28 LGATE2
49
GND
31 BOOT1
VCC 10
FS
27 BOOT2
17
18
19
20
FB
COMP
APA
ISEN1+
21
22
23
24
EN
16
ISEN2-
15
ISEN2+
14
ISEN1-
13
RSET
25 PHASE2
RCOMP
RGND 12
SCL
26 UGATE2
VSEN
11
Integrated Driver Block Diagram
PVCC
BOOT
UGATE
PWM
20kΩ
SOFT-START
AND
FAULT LOGIC
GATE
CONTROL
LOGIC
SHOOTTHROUGH
PROTECTION
PHASE
10kΩ
LGATE
2
FN6880.1
April 29, 2010
ISL6324A
Controller Block Diagram
COMP_NB
FB_NB
SCL
NB_OVP
CORE_OVP
I2C
DAC_OFS
SDA
ISEN_NB+
CURRENT
SENSE
ISEN_NB-
LGATE_NB
E/A
UV
LOGIC
OV
LOGIC
MOSFET
DRIVER
NB_REF
RAMP
BOOT_NB
UGATE_NB
PHASE_NB
VDDPWRGD
EN_12V
PVCC_NB
APA
APA
NB
FAULT
LOGIC
COMP
ENABLE
LOGIC
EN
VCC
POWER-ON
RESET
VDDPWRGD_MOD
PVCC1_2
SOFT-START
AND
FB
FAULT LOGIC
E/A
DVC
2X
BOOT1
RGND
∑
DROOP
CONTROL
LOAD APPLY
TRANSIENT
ENHANCEMENT
PWROK
VID0/VFIXEN
VID1/SEL
VID2/SVD
VID3/SVC
VID4
LGATE1
SVI
SLAVE
BUS
AND
PVI
DAC
DAC_OFS
CLOCK AND
TRIANGLE WAVE
GENERATOR
FS
PWM1
∑
NB_REF
BOOT2
OV
LOGIC
CORE_OVP
VSEN
UV
LOGIC
ISEN1+
ISEN1ISEN2+
ISEN2ISEN3+
ISEN3-
ISEN4-
PWM2
∑
MOSFET
DRIVER
PWM3
RESISTOR
MATCHING
OC
CH1
CURRENT
SENSE
I_TRIP I_AVG
∑
∑
CHANNEL
CURRENT
BALANCE
EN_12V
I_AVG
ISEN3ISEN4-
1
N
PWM3
SIGNAL
LOGIC
CH3
CURRENT
SENSE
CH4
CURRENT
SENSE
PHASE2
PH3/PH4
POR
CHANNEL
DETECT
CH2
CURRENT
SENSE
UGATE2
LGATE2
PWM4
ISEN3ISEN4+
UGATE1
PHASE1
VID5
RSET
MOSFET
DRIVER
PWM3
∑
PWM4
SIGNAL
LOGIC
ISEN4-
PWM4
GND
3
FN6880.1
April 29, 2010
ISL6324A
Typical Application - SVI Mode
+12V
+12V
FB
COMP
ISEN3+
ISEN3PWM3
VSEN
BOOT1
BOOT1
UGATE1
UGATE1
PHASE1
PHASE1
APA
PWM1
PGND
ISEN1ISEN1+
DVC
+5V
LGATE1
LGATE1
ISL6614
+12V
PVCC1_2
VDD
+12V
VCC
BOOT2
+12V
VCC
PVCC
BOOT2
UGATE2
FS
PHASE2
CPU
LOAD
PHASE2
PWM2
LGATE2
LGATE2
RSET
NC
NC
UGATE2 GND
VFIXEN
ISEN2SEL
ISEN2+
SVD
SVC
RGND
VID4
VID5
PWROK
VDDPWRGD ISEN4+
GND
ISEN4-
SCL
SDA
PWM4
+12V
ISL6324A
+12V
PVCC_NB
OFF
EN
BOOT_NB
ON
UGATE_NB
PHASE_NB
VDDNB
LGATE_NB
COMP_NB ISEN_NB-
NB
LOAD
ISEN_NB+
FB_NB
4
FN6880.1
April 29, 2010
ISL6324A
Typical Application - PVI Mode
+12V
+12V
FB
COMP
ISEN3+
ISEN3PWM3
VSEN
BOOT1
BOOT1
UGATE1
UGATE1
PHASE1
PHASE1
LGATE1
+5V
APA
LGATE1
DVC
ISEN1ISEN1+
PWM1
PGND
ISL6614
+12V
PVCC1_2
VDD
+12V
VCC
+12V
VCC
BOOT2 PVCC
BOOT2
UGATE2 GND
UGATE2
FS
PHASE2
PWM2
LGATE2
LGATE2
RSET
NC
CPU
LOAD
PHASE2
VID0
ISEN2VID1/SEL
ISEN2+
VID2
VID3
RGND
VID4
VID5
PWROK
VDDPWRGD ISEN4+
GND
ISEN4-
SCL
SDA
PWM4
ISL6324A
+12V
+12V
NORTH BRIDGE REGULATOR
PVCC_NB
OFF
DISABLED IN PVI MODE
EN
BOOT_NB
ON
UGATE_NB
PHASE_NB
VDDNB
LGATE_NB
COMP_NB ISEN_NB-
NB
LOAD
ISEN_NB+
FB_NB
5
FN6880.1
April 29, 2010
ISL6324A
Absolute Maximum Ratings
Thermal Information
Supply Voltage (VCC) . . . . . . . . . . . . . . . . . . . . . . . . -0.3V to +6.2V
Supply Voltage (PVCC) . . . . . . . . . . . . . . . . . . . . . . . . -0.3V to +15V
Absolute Boot Voltage (VBOOT). . . . . . . . GND - 0.3V to GND + 36V
Phase Voltage (VPHASE) . . . . . . . . GND - 0.3V to 15V (PVCC = 12)
GND - 8V (<400ns, 20µJ) to 24V (<200ns, VBOOT-PHASE = 12V)
Upper Gate Voltage (VUGATE). . . . VPHASE - 0.3V to VBOOT + 0.3V
VPHASE - 3.5V (<100ns Pulse Width, 2µJ) to VBOOT + 0.3V
Lower Gate Voltage (VLGATE) . . . . . . . GND - 0.3V to PVCC + 0.3V
GND - 5V (<100ns Pulse Width, 2µJ) to PVCC+ 0.3V
Input, Output, or I/O Voltage . . . . . . . . . GND - 0.3V to VCC + 0.3V
Thermal Resistance
θJA (°C/W)
θJC (°C/W)
QFN Package (Notes 1, 2) . . . . . . . . . .
27
2
Maximum Junction Temperature . . . . . . . . . . . . . . . . . . . . . . +150°C
Maximum Storage Temperature Range . . . . . . . . . .-65°C to +150°C
Pb-free Reflow Profile . . . . . . . . . . . . . . . . . . . . . . . . .see link below
http://www.intersil.com/pbfree/Pb-FreeReflow.asp
Recommended Operating Conditions
VCC Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .+5V ±5%
PVCC Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . +5V to 12V ±5%
Ambient Temperature
ISL6324ACRZ . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0°C to +70°C
ISL6324AIRZ . . . . . . . . . . . . . . . . . . . . . . . . . . . . .-40°C to +85°C
CAUTION: Do not operate at or near the maximum ratings listed for extended periods of time. Exposure to such conditions may adversely impact product reliability and
result in failures not covered by warranty.
NOTES:
1. θJA is measured in free air with the component mounted on a high effective thermal conductivity test board with “direct attach” features. See
Tech Brief TB379.
2. For θJC, the “case temp” location is the center of the exposed metal pad on the package underside.
Electrical Specifications
Recommended Operating Conditions (0°C to +70°C), Unless Otherwise Specified.
PARAMETER
TEST CONDITIONS
MIN
(Note 4)
TYP
MAX
(Note 4)
UNITS
15
22
25
mA
BIAS SUPPLIES
Input Bias Supply Current
IVCC; EN = high
Gate Drive Bias Current - PVCC1_2 Pin
IPVCC1_2; EN = high
1
1.8
3
mA
Gate Drive Bias Current - PVCC_NB Pin
IPVCC_NB; EN = high
0.3
0.9
2
mA
VCC POR (Power-On Reset) Threshold
VCC Rising
4.20
4.35
4.50
V
PVCC POR (Power-On Reset) Threshold
VCC Falling
3.70
3.85
4.05
V
PVCC Rising
4.20
4.35
4.50
V
PVCC Falling
3.70
3.85
4.05
V
RT = 100kΩ (±0.1%) to Ground, (All Temps)
(Droop Enabled)
225
250
265
kHz
RT = 100kΩ (±0.1%) to VCC, TA = 0°C to +70°C
(Droop Disabled)
245
275
310
kHz
RT = 100kΩ (±0.1%) to VCC, TA = -40°C to +85°C
(Droop Disabled)
240
275
310
kHz
(Note 3)
0.08
1.0
MHz
PWM MODULATOR
Oscillator Frequency Accuracy, fSW
Typical Adjustment Range of Switching
Frequency
Oscillator Ramp Amplitude, VP-P
(Note 3)
1.50
V
Maximum Duty Cycle
(Note 3)
99.5
%
CONTROL THRESHOLDS
EN Rising Threshold
EN Hysteresis
0.80
0.88
0.92
V
70
130
190
mV
PWROK Input HIGH Threshold
1.1
V
PWROK Input LOW Threshold
0.95
V
VDDPWRGD Sink Current
Open drain, V_VDDPWRGD = 400mV
PWM Channel Disable Threshold
VISEN3-, VISEN4-, VISEN2-
4
4.4
mA
V
REFERENCE AND DAC
System Accuracy (VDAC > 1.000V)
6
-0.6
0.6
%
FN6880.1
April 29, 2010
ISL6324A
Electrical Specifications
Recommended Operating Conditions (0°C to +70°C), Unless Otherwise Specified.
PARAMETER
TEST CONDITIONS
MIN
(Note 4)
TYP
MAX
(Note 4)
UNITS
System Accuracy (0.600V < VDAC < 1.000V)
-1.0
1.0
%
System Accuracy (VDAC < 0.600V)
-2.0
2.0
%
DVC Voltage Gain
VDAC = 1V
APA Current Tolerance
VAPA = 1V
2.0
90
100
V
108
µA
ERROR AMPLIFIER
RL = 10k to ground, (Note 3)
96
dB
Gain-Bandwidth Product (Note 3)
CL = 100pF, RL = 10k to ground, (Note 3)
20
MHz
Slew Rate (Note 3)
CL = 100pF, Load = ±400µA, (Note 3)
8
V/µs
Maximum Output Voltage
Load = 1mA
Minimum Output Voltage
Load = -1mA
DC Gain
3.80
4.20
V
1.3
1.6
V
3.0
4.0
mV/µs
0.5
V
SOFT-START RAMP
Soft-Start Ramp Rate
2.2
PWM OUTPUTS
PWM Output Voltage LOW Threshold
ILOAD = ±500µA
PWM Output Voltage HIGH Threshold
ILOAD = ±500µA
4.5
VISENn- - VISENn+ = 23.2mV, RSET = 37.6kΩ,
4 Phases, TA = +25°C
68
88
µA
VISEN_NB- - VISEN_NB+ = 23.2mV,
RSET = 37.6kΩ, 4 Phases, TA = +25°C
68
89
µA
VISENn- - VISENn+ = 23.2mV, RSET = 37.6kΩ,
4 Phases, TA = +25°C
68
88
µA
Normal Operation, RSET = 28.2kΩ
87
120
µA
V
CURRENT SENSING - CORE CONTROLLER
Sensed Current Tolerance
CURRENT SENSING - NB CONTROLLER
Sensed Current Tolerance
DROOP CURRENT
Tolerance
OVERCURRENT PROTECTION
Overcurrent Trip Level - Average Channel
Overcurrent Limiting- Individual Channel
100
Dynamic VID Change (Note 3)
130
µA
Normal Operation, RSET = 28.2kΩ
142
µA
Dynamic VID Change (Note 3)
190
µA
POWER-GOOD
Core Overvoltage Threshold
VSEN Rising
Bit 6 of I2C data = 0
VDAC +
225mV
VDAC +
250mV
VDAC +
275mV
V
Undervoltage Threshold
VSEN Falling (Core)
Bit 6 of I2C data = 0
VDAC 325mV
VDAC 300mV
VDAC 270mV
mV
ISEN_NB+ Falling (North Bridge)
Bit 6 of I2C data = 0
VDAC 310mV
VDAC 275mV
VDAC 235mV
mV
Power Good Hysteresis
50
mV
OVERVOLTAGE PROTECTION
Bit 7 of I2C data = 0, VDAC ≤ 1.55V
OVP Trip Level
OVP Lower Gate Release Threshold
1.73
1.80
350
400
1.84
mV
V
SWITCHING TIME (Note 3) [See “Timing Diagram” on page 8]
UGATE Rise Time
tRUGATE; VPVCC = 12V, 3nF Load, 10% to 90%
26
ns
LGATE Rise Time
tRLGATE; VPVCC = 12V, 3nF Load, 10% to 90%
18
ns
UGATE Fall Time
tFUGATE; VPVCC = 12V, 3nF Load, 90% to 10%
18
ns
LGATE Fall Time
tFLGATE; VPVCC = 12V, 3nF Load, 90% to 10%
12
ns
7
FN6880.1
April 29, 2010
ISL6324A
Electrical Specifications
Recommended Operating Conditions (0°C to +70°C), Unless Otherwise Specified.
PARAMETER
MIN
(Note 4)
TEST CONDITIONS
TYP
MAX
(Note 4)
UNITS
UGATE Turn-On Non-overlap
tPDHUGATE; VPVCC = 12V, 3nF Load, Adaptive
10
ns
LGATE Turn-On Non-overlap
tPDHLGATE; VPVCC = 12V, 3nF Load, Adaptive
10
ns
GATE DRIVE RESISTANCE (Note 3)
Upper Drive Source Resistance
VPVCC = 12V, 15mA Source Current
2.0
Ω
Upper Drive Sink Resistance
VPVCC = 12V, 15mA Sink Current
1.65
Ω
Lower Drive Source Resistance
VPVCC = 12V, 15mA Source Current
1.25
Ω
Lower Drive Sink Resistance
VPVCC = 12V, 15mA Sink Current
0.80
Ω
MODE SELECTION
VID1/SEL Input Low
EN taken from HI to LO, VDDIO = 1.5V
VID1/SEL Input High
EN taken from LO to HI, VDDIO = 1.5V
0.6
1.00
V
V
PVI INTERFACE
VIDx Pull-down
VDDIO = 1.5V
VIDx Input Low
VDDIO = 1.5V
VIDx Input High
VDDIO = 1.5V
30
40
µA
0.6
V
1.00
V
SVI INTERFACE
SVC, SVD Input LOW (VIL)
SVC, SVD Input HIGH (VIH)
0.95
Schmitt Trigger Input Hysteresis
0.14
SVD Low Level Output Voltage
V
0.45
V
0.285
V
V
0.35
3mA Sink Current
Maximum SVC, SVD Leakage (Note 3)
0.4
±5
µA
I2C INTERFACE
SCL, SDA Input LOW (VIL)
SCL, SDA Input HIGH (VIH)
1.75
Schmitt Trigger Input Hysteresis
0.18
SDA Low Level Output Voltage
1.10
V
0.50
V
V
0.35
3mA Sink Current
0.2
Maximum SCL, SDA Leakage (Note 3)
±5
V
µA
NOTES:
3. Limits should be considered typical and are not production tested.
4. Parameters with MIN and/or MAX limits are 100% tested at +25°C, unless otherwise specified. Temperature limits established by characterization
and are not production tested.
Timing Diagram
tPDHUGATE
tRUGATE
tFUGATE
UGATE
LGATE
tFLGATE
tRLGATE
tPDHLGATE
8
FN6880.1
April 29, 2010
ISL6324A
Functional Pin Description
VID1/SEL
This pin selects SVI or PVI mode operation based on the state
of the pin prior to enabling the ISL6324A. If the pin is LO prior
to enable, the ISL6324A is in SVI mode and the dual purpose
pins [VID0/VFIXEN, VID2/SVC, VID3/SVD] use their SVI
mode related functions. If the pin held HI prior to enable, the
ISL6324A is in PVI mode and dual purpose pins use their
VIDx related functions to decode the correct DAC code.
VID0/VFIXEN
If VID1 is LO prior to enable [SVI Mode], the pin is functions
as the VFIXEN selection input from the AMD processor for
determining SVI mode versus VFIX mode of operation.
If VID1 is HI prior to enable [PVI Mode], the pin is used as
DAC input VID0. This pin has an internal 30µA pull-down
current applied to it at all times.
VID2/SVD
If VID1 is LO prior to enable [SVI Mode], this pin is the serial
VID data bi-directional signal to and from the master device on
AMD processor. If VID1 is HI prior to enable [PVI Mode], this
pin is used to decode the programmed DAC code for the
processor. In PVI mode, this pin has an internal 30µA pull-down
current applied to it. There is no pull-down current in SVI mode.
VID3/SVC
If VID1 is LO prior to enable [SVI Mode], this pin is the serial
VID clock input from the AMD processor. If VID1 is HI prior to
enable [PVI Mode], the ISL6324A is in PVI mode and this pin
is used to decode the programmed DAC code for the
processor. In PVI mode, this pin has an internal 30µA
pull-down current applied to it. There is no pull-down current in
SVI mode.
VID4
This pin is active only when the ISL6324A is in PVI mode.
When VID1 is HI prior to enable, the ISL6324A decodes the
programmed DAC voltage required by the AMD processor.
This pin has an internal 30µA pull-down current applied to it at
all times.
VID5
This pin is active only when the ISL6324A is in PVI mode.
When VID1 is HI prior to enable, the ISL6324A decodes the
programmed DAC voltage required by the AMD processor.
This pin has an internal 30µA pull-down current applied to it at
all times.
VCC
VCC is the bias supply for the ICs small-signal circuitry.
Connect this pin to a +5V supply and decouple using a
quality 0.1µF ceramic capacitor.
PVCC1_2
The power supply pin for the multi-phase internal MOSFET
drivers. Connect this pin to any voltage from +5V to +12V
9
depending on the desired MOSFET gate-drive level.
Decouple this pin with a quality 1.0µF ceramic capacitor.
PVCC_NB
The power supply pin for the internal MOSFET driver for the
Northbridge controller. Connect this pin to any voltage from
+5V to +12V depending on the desired MOSFET gate-drive
level. Decouple this pin with a quality 1.0µF ceramic capacitor.
GND
GND is the bias and reference ground for the IC. The GND
connection for the ISL6324A is through the thermal pad on
the bottom of the package.
EN
This pin is a threshold-sensitive (approximately 0.85V) system
enable input for the controller. Held low, this pin disables both
CORE and NB controller operation. Pulled high, the pin
enables both controllers for operation.
When the EN pin is pulled high, the ISL6324A will be placed
in either SVI or PVI mode. The mode is determined by the
latched value of VID1 on the rising edge of the EN signal.
A third function of this pin is to provide driver bias monitor for
external drivers. A resistor divider with the center tap
connected to this pin from the drive bias supply prevents
enabling the controller before insufficient bias is provided to
external driver. The resistors should be selected such that
when the POR-trip point of the external driver is reached, the
voltage at this pin meets the above mentioned threshold level.
FS
A resistor, placed from FS to Ground or from FS to VCC,
sets the switching frequency of both controllers. Refer to
Equation 1 for proper resistor calculation.
R T = 10
[ 10.61 – 1.035 log ( f s ) ]
(EQ. 1)
With the resistor tied from FS to Ground, Droop is enabled.
With the resistor tied from FS to VCC, Droop is disabled.
VSEN and RGND
VSEN and RGND are inputs to the core voltage regulator
(VR) controller precision differential remote-sense amplifier
and should be connected to the sense pins of the remote
processor core(s), VDDFB[H,L].
FB and COMP
These pins are the internal error amplifier inverting input and
output respectively of the core VR controller. FB, VSEN and
COMP are tied together through external R-C networks to
compensate the regulator.
APA
Adaptive Phase Alignment (APA) pin for setting trip level and
adjusting time constant. A 100µA current flows into the APA
pin and by tying a resistor from this pin to COMP the trip
level for the Adaptive Phase Alignment circuitry can be set.
FN6880.1
April 29, 2010
ISL6324A
ISEN1-, ISEN1+, ISEN2-, ISEN2+, ISEN3-, ISEN3+,
ISEN4-, and ISEN4+
These pins are used for differentially sensing the corresponding
channel output currents. The sensed currents are used for
channel balancing, protection, and core load line regulation.
Connect ISEN1-, ISEN2-, ISEN3-, and ISEN4- to the node
between the RC sense elements surrounding the inductor of
their respective channel. Tie the ISEN+ pins to the VCORE
side of their corresponding channel’s sense capacitor.
UGATE1 and UGATE2
DVC
The DVC pin is a buffered version of the reference to the error
amplifier. A series resistor and capacitor between the DVC pin
and FB pin smooth the voltage transition during VID-on-the-fly
operations.
FB_NB and COMP_NB
These pins are the internal error amplifier inverting input and
output respectively of the NB VR controller. FB_NB,
VDIFF_NB, and COMP_NB are tied together through
external R-C networks to compensate the regulator.
Connect these pins to the corresponding upper MOSFET
gates. These pins are used to control the upper MOSFETs
and are monitored for shoot-through prevention purposes.
Maximum individual channel duty cycle is limited to 93.3%.
ISEN_NB-, ISEN_NB+
BOOT1 and BOOT2
Connect ISEN_NB- to the node between the RC sense
element surrounding the inductor. Tie the ISEN_NB+ pin to
the VNB side of the sense capacitor.
These pins provide the bias voltage for the corresponding
upper MOSFET drives. Connect these pins to appropriately
chosen external bootstrap capacitors. Internal bootstrap
diodes connected to the PVCC1_2 pin provide the
necessary bootstrap charge.
PHASE1 and PHASE2
Connect these pins to the sources of the corresponding
upper MOSFETs. These pins are the return path for the
upper MOSFET drives.
LGATE1 and LGATE2
These pins are used to control the lower MOSFETs. Connect
these pins to the corresponding lower MOSFETs’ gates.
PWM3 and PWM4
Pulse-width modulation outputs. Connect these pins to the
PWM input pins of an Intersil driver IC if 3- or 4-phase
operation is desired. Connect the ISEN- pins of the channels
not desired to +5V to disable them and configure the core
VR controller for 2-phase or 3-phase operation.
These pins are used for differentially sensing the North
Bridge output current. The sensed current is used for
protection and load line regulation if droop is enabled.
UGATE_NB
Connect this pin to the corresponding upper MOSFET gate.
This pin provides the PWM-controlled gate drive for the
upper MOSFET and is monitored for shoot-through
prevention purposes.
BOOT_NB
This pin provides the bias voltage for the corresponding
upper MOSFET drive. Connect this pin to appropriately
chosen external bootstrap capacitor. The internal bootstrap
diode connected to the PVCC_NB pin provides the
necessary bootstrap charge.
PHASE_NB
Connect this pin to the source of the corresponding upper
MOSFET. This pin is the return path for the upper MOSFET
drive. This pin is used to monitor the voltage drop across the
upper MOSFET for overcurrent protection.
PWROK
LGATE_NB
System wide Power Good signal. If this pin is low, the two
SVI bits are decoded to determine the “metal VID”. When the
pin is high, the SVI is actively running its protocol.
Connect this pin to the corresponding MOSFET’s gate. This
pin provides the PWM-controlled gate drive for the lower
MOSFET. This pin is also monitored by the adaptive
shoot-through protection circuitry to determine when the
lower MOSFET has turned off.
RSET
Connect this pin to the VCC pin through a resistor (RSET) to
set the effective value of the internal RISEN current sense
resistors. The values of the RSET resistor should be no less
than 20kΩ and no more than 80kΩ. A 0.1µF capacitor
should be placed in parallel to the RSET resistor.
SCL
Connect this pin to the clock signal for the I2C bus, which is
a logic level input signal. The clock signal tells the controller
when data is available on the I2C bus.
SDA
VDDPWRGD
During normal operation this pin indicates whether both output
voltages are within specified overvoltage and undervoltage
limits. If either output voltage exceeds these limits or a reset
event occurs (such as an overcurrent event), the pin is pulled
low. This pin is always low prior to the end of soft-start.
10
Connect this pin to the bidirectional data line of the I2C bus,
which is a logic level input/output signal. All I2C data is sent
over this line, including the address of the device the bus is
trying to communicate with, and what functions the device
should perform.
FN6880.1
April 29, 2010
ISL6324A
Operation
The ISL6324A utilizes a multi-phase architecture to provide
a low cost, space saving power conversion solution for the
processor core voltage. The controller also implements a
simple single phase architecture to provide the Northbridge
voltage on the same chip.
Multi-phase Power Conversion
Microprocessor load current profiles have changed to the
point that the advantages of multi-phase power conversion
are impossible to ignore. The technical challenges
associated with producing a single-phase converter that is
both cost-effective and thermally viable have forced a
change to the cost-saving approach of multi-phase. The
ISL6324A controller helps simplify implementation by
integrating vital functions and requiring minimal external
components. The “Controller Block Diagram” on page 3
provides a top level view of the multi-phase power
conversion using the ISL6324A controller.
Interleaving
The switching of each channel in a multi-phase converter is
timed to be symmetrically out-of-phase with each of the other
channels. In a 3-phase converter, each channel switches 1/3
cycle after the previous channel and 1/3 cycle before the
following channel. As a result, the three-phase converter has a
combined ripple frequency three times greater than the ripple
frequency of any one phase. In addition, the peak-to-peak
amplitude of the combined inductor currents is reduced in
proportion to the number of phases (Equations 2 and 3).
Increased ripple frequency and lower ripple amplitude mean
that the designer can use less per-channel inductance and
lower total output capacitance for any performance
specification.
Figure 1 illustrates the multiplicative effect on output ripple
frequency. The three channel currents (IL1, IL2, and IL3)
combine to form the AC ripple current and the DC load
current. The ripple component has three times the ripple
frequency of each individual channel current. Each PWM
pulse is terminated 1/3 of a cycle after the PWM pulse of the
previous phase. The peak-to-peak current for each phase is
about 7A, and the DC components of the inductor currents
combine to feed the load.
The output capacitors conduct the ripple component of the
inductor current. In the case of multi-phase converters, the
capacitor current is the sum of the ripple currents from each
of the individual channels. Compare Equation 2 to the
expression for the peak-to-peak current after the summation
of N symmetrically phase-shifted inductor currents in
Equation 3. Peak-to-peak ripple current decreases by an
amount proportional to the number of channels. Output
voltage ripple is a function of capacitance, capacitor
equivalent series resistance (ESR), and inductor ripple
current. Reducing the inductor ripple current allows the
designer to use fewer or less costly output capacitors.
( V IN – N V OUT ) V OUT
I C ( P – P ) = ----------------------------------------------------------L fS V
Another benefit of interleaving is to reduce input ripple
current. Input capacitance is determined in part by the
maximum input ripple current. Multi-phase topologies can
improve overall system cost and size by lowering input ripple
current and allowing the designer to reduce the cost of input
capacitance. The example in Figure 2 illustrates input
currents from a three-phase converter combining to reduce
the total input ripple current.
The converter depicted in Figure 2 delivers 1.5V to a 36A load
from a 12V input. The RMS input capacitor current is 5.9A.
Compare this to a single-phase converter also stepping down
12V to 1.5V at 36A. The single-phase converter has
11.9ARMS input capacitor current. The single-phase converter
must use an input capacitor bank with twice the RMS current
capacity as the equivalent three-phase converter.
Figures 26, 27 and 28 in the section entitled “Input Capacitor
Selection” on page 35 can be used to determine the input
capacitor RMS current based on load current, duty cycle,
and the number of channels. They are provided as aids in
determining the optimal input capacitor solution.
IL1 + IL2 + IL3, 7A/DIV
IL3, 7A/DIV
PWM3, 5V/DIV
IL2, 7A/DIV
To understand the reduction of ripple current amplitude in the
multi-phase circuit, examine Equation 2, which represents
an individual channel peak-to-peak inductor current.
( V IN – V OUT ) V OUT
I P – P = ----------------------------------------------------L fS V
(EQ. 2)
IN
(EQ. 3)
IN
PWM2, 5V/DIV
IL1, 7A/DIV
PWM1, 5V/DIV
In Equation 2, VIN and VOUT are the input and output
voltages respectively, L is the single-channel inductor value,
and fS is the switching frequency.
11
1µs/DIV
FIGURE 1. PWM AND INDUCTOR-CURRENT WAVEFORMS
FOR 3-PHASE CONVERTER
FN6880.1
April 29, 2010
ISL6324A
CHANNEL 1
INPUT CURRENT
10A/DIV
1μs/DIV
FIGURE 2. CHANNEL INPUT CURRENTS AND INPUT
CAPACITOR RMS CURRENT FOR 3-PHASE
CONVERTER
Active Pulse Positioning Modulated PWM Operation
The PWM output state is driven by the position of the error
amplifier output signal, VCOMP, minus the current correction
signal relative to the proprietary modulator ramp waveform as
illustrated in Figure 3. At the beginning of each PWM time
interval, this modified VCOMP signal is compared to the
internal modulator waveform. As long as the modified VCOMP
voltage is lower then the modulator waveform voltage, the
PWM signal is commanded low. The internal MOSFET driver
detects the low state of the PWM signal and turns off the
upper MOSFET and turns on the lower synchronous
MOSFET. When the modified VCOMP voltage crosses the
modulator ramp, the PWM output transitions high, turning off
the synchronous MOSFET and turning on the upper
MOSFET. The PWM signal will remain high until the modified
VCOMP voltage crosses the modulator ramp again. When this
occurs the PWM signal will transition low again.
During each PWM time interval the PWM signal can only
transition high once. Once PWM transitions high it can not
transition high again until the beginning of the next PWM
time interval. This prevents the occurrence of double PWM
pulses occurring during a single period.
12
EXTERNAL CIRCUIT
ISL6324A INTERNAL CIRCUIT
APA
CAPA
RAPA
100µA
VAPA,TRIP
+
-
+
The ISL6324A uses a proprietary Active Pulse Positioning
(APP) modulation scheme to control the internal PWM signals
that command each channel’s driver to turn their upper and
lower MOSFETs on and off. The time interval in which a PWM
signal can occur is generated by an internal clock, whose cycle
time is the inverse of the switching frequency set by the resistor
between the FS pin and ground. The advantage of Intersil’s
proprietary Active Pulse Positioning (APP) modulator is that the
PWM signal has the ability to turn on at any point during this
PWM time interval, and turn off immediately after the PWM
signal has transitioned high. This is important because it allows
the controller to quickly respond to output voltage drops
associated with current load spikes, while avoiding the ring
back affects associated with other modulation schemes.
To further improve the transient response, the ISL6324A
also implements Intersil’s proprietary Adaptive Phase
Alignment (APA) technique, which turns on all of the
channels together at the same time during large current step
transient events. As Figure 3 shows, the APA circuitry works
by monitoring the voltage on the APA pin and comparing it to
a filtered copy of the voltage on the COMP pin. The voltage
on the APA pin is a copy of the COMP pin voltage that has
been negatively offset. If the APA pin exceeds the filtered
COMP pin voltage an APA event occurs and all of the
channels are forced on.
LOW
PASS
FILTER
COMP
APA
TO APA
CIRCUITRY
ERROR
AMPLIFIER
+
CHANNEL 2
INPUT CURRENT
10A/DIV
Adaptive Phase Alignment (APA)
-
CHANNEL 3
INPUT CURRENT
10A/DIV
To further improve the transient response, ISL6324A also
implements Intersil’s proprietary Adaptive Phase Alignment
(APA) technique, which turns on all phases together under
transient events with large step current. With both APP and
APA control, ISL6324A can achieve excellent transient
performance and reduce the demand on the output capacitors.
-
INPUT-CAPACITOR CURRENT, 10A/DIV
FIGURE 3. ADAPTIVE PHASE ALIGNMENT DETECTION
The APA trip level is the amount of DC offset between the
COMP pin and the APA pin. This is the voltage excursion
that the APA and COMP pins must have during a transient
event to activate the Adaptive Phase Alignment circuitry.
This APA trip level is set through a resistor, RAPA, that
connects from the APA pin to the COMP pin. A 100µA
current flows across RAPA into the APA pin to set the APA
trip level as described in Equation 4. An APA trip level of
500mV is recommended for most applications. A 0.1µF
capacitor, CAPA, should also be placed across the RAPA
resistor to help with noise immunity.
V APA, TRIP = R APA ⋅ 100 × 10
–6
(EQ. 4)
PWM Operation
The timing of each core channel is set by the number of
active channels. Channel detection on the ISEN2-, ISEN3and ISEN4- pins selects 1-Channel to 4-Channel operation
for the ISL6323A. The switching cycle is defined as the time
between PWM pulse termination signals of each channel.
The cycle time of the pulse signal is the inverse of the
FN6880.1
April 29, 2010
ISL6324A
Connecting ISEN4- to VCC selects three channel operation
and the pulse times are spaced in 1/3 cycle increments. If
ISEN3- is also connected to VCC, 2-Channel operation is
selected and the PWM2 pulse happens 1/2 of a cycle after
PWM1 pulse. If ISEN2- is also connected to VCC, 1Channel operation is selected.
Continuous Current Sampling
n
A simple R-C network across the inductor (R1, R2 and C)
extracts the DCR voltage, as shown in Figure 6. The voltage
across the sense capacitor, VC, can be shown to be
proportional to the channel current ILn, shown in Equation 6.
s⋅L
⎛ ------------+ 1⎞
⎝ DCR
⎠
------------------------------------------------------- ⋅ K ⋅ DCR ⋅ I L
VC ( s ) =
n
(
⋅
R
)
R
⎛
⎞
1
2
⎜ s ⋅ ------------------------ ⋅ C + 1⎟
R1 + R2
⎝
⎠
(EQ. 6)
Where:
R2
K = --------------------R2 + R1
(EQ. 7)
IL
VIN
n
UGATE(n)
L
MOSFET
DRIVER
LGATE(n)
DCR
VOUT
INDUCTOR
VL(s)
+
+
In order to realize proper current-balance, the currents in
each channel are sampled continuously every switching
cycle. During this time, the current-sense amplifier uses the
ISEN inputs to reproduce a signal proportional to the
inductor current, IL. This sensed current, ISEN, is simply a
scaled version of the inductor current.
(EQ. 5)
V L ( s ) = I L ⋅ ( s ⋅ L + DCR )
VC(s)
R1
COUT
-
For 4-channel operation, the channel firing order is 1-2-3-4:
PWM3 pulse happens 1/4 of a cycle after PWM4, PWM2
output follows another 1/4 of a cycle after PWM3, and
PWM1 delays another 1/4 of a cycle after PWM2. For
3-channel operation, the channel firing order is 1-2-3.
Equation 5 shows the S-domain equivalent voltage, VL,
across the inductor.
-
switching frequency set by the resistor between the FS pin
and ground. The PWM signals command the MOSFET
driver to turn on/off the channel MOSFETs.
C
PWM
R2
ISL6323 INTERNAL CIRCUIT
SWITCHING PERIOD
In
IL
SAMPLE
+
+
-
VC(s)
RISEN
ISEN
TIME
Inductor windings have a characteristic distributed
resistance or DCR (Direct Current Resistance). For
simplicity, the inductor DCR is considered as a separate
lumped quantity, as shown in Figure 6. The channel current
ILn, flowing through the inductor, passes through the DCR.
ISENnISENn+
VCC
RSET
FIGURE 4. CONTINUOUS CURRENT SAMPLING
The ISL6324A supports Inductor DCR current sensing to
continuously sample each channel’s current for channel-current
balance. The internal circuitry, shown in Figure 6 represents
Channel N of an N-Channel converter. This circuitry is repeated
for each channel in the converter, but may not be active
depending on how many channels are operating.
-
ISEN
RSET
CSET
FIGURE 5. INDUCTOR DCR CURRENT SENSING
CONFIGURATION
If the R-C network components are selected such that the
RC time constant matches the inductor L/DCR time constant
(see Equation 8), then VC is equal to the voltage drop across
the DCR multiplied by the ratio of the resistor divider, K. If a
resistor divider is not being used, the value for K is 1.
R1 ⋅ R2
L
------------= --------------------- ⋅ C
R1 + R2
DCR
(EQ. 8)
The capacitor voltage VC, is then replicated across the
effective internal sense resistor, RISEN. This develops a
13
FN6880.1
April 29, 2010
ISL6324A
current through RISEN which is proportional to the inductor
current. This current, ISEN, is continuously sensed and is
then used by the controller for load-line regulation, channelcurrent balancing, and overcurrent detection and limiting.
Equation 9 shows that the proportion between the channel
current, IL, and the sensed current, ISEN, is driven by the
value of the effective sense resistance, RISEN, and the DCR
of the inductor.
DCR
I SEN = I L ⋅ -----------------R ISEN
IER toward zero. The same method for error signal
correction is applied to each active channel.
.
3
R ISEN = ---------- ⋅ R SET
400
(EQ. 10)
The North Bridge regulator samples the load current in the
same manner as the Core regulator does. The RSET resistor
will program all the effective internal RISEN resistors to the
same value.
Channel-Current Balance
One important benefit of multi-phase operation is the thermal
advantage gained by distributing the dissipated heat over
multiple devices and greater area. By doing this the designer
avoids the complexity of driving parallel MOSFETs and the
expense of using expensive heat sinks and exotic magnetic
materials.
In order to realize the thermal advantage, it is important that
each channel in a multi-phase converter be controlled to
carry about the same amount of current at any load level. To
achieve this, the currents through each channel must be
sampled every switching cycle. The sampled currents, In,
from each active channel are summed together and divided
by the number of active channels. The resulting cycle
average current, IAVG, provides a measure of the total load
current demand on the converter during each switching
cycle. Channel-current balance is achieved by comparing
the sampled current of each channel to the cycle average
current, and making the proper adjustment to each channel
pulse width based on the error. Intersil’s patented current
balance method is illustrated in Figure 6, with error
correction for Channel 1 represented. In the figure, the cycle
average current, IAVG, is compared with the Channel 1
sample, I1, to create an error signal IER.
The filtered error signal modifies the pulse width
commanded by VCOMP to correct any unbalance and force
14
+
MODULATOR
RAMP
WAVEFORM
-
PWM1
-
TO GATE
CONTROL
LOGIC
f(s)
FILTER
I4
IER
(EQ. 9)
The effective internal RISEN resistance is important to the
current sensing process because it sets the gain of the load
line regulation loop when droop is enabled as well as the
gain of the channel-current balance loop and the overcurrent
trip level. The effective internal RISEN resistance is user
programmable and is set through use of the RSET pin.
Placing a single resistor, RSET, from the RSET pin to the
VCC pin programs the effective internal RISEN resistance
according to Equation 10.
+
VCOMP
IAVG
-
+
Σ
÷N
I3
I2
I1
NOTE: Channel 3 and 4 are optional.
FIGURE 6. CHANNEL-1 PWM FUNCTION AND CURRENTBALANCE ADJUSTMENT
VID Interface
The ISL6324A supports hybrid power control of AMD
processors which operate from either a 6-bit parallel VID
interface (PVI) or a serial VID interface (SVI). The VID1/SEL
pin is used to command the ISL6324A into either the PVI
mode or the SVI mode. Whenever the EN pin is held LOW,
both the multi-phase Core and single-phase North Bridge
Regulators are disabled and the ISL6324A is continuously
sampling voltage on the VID1/SEL pin. When the EN pin is
toggled HIGH, the status of the VID1/SEL pin will latch the
ISL6324A into either PVI or SVI mode. This latching occurs
on the rising edge of the EN signal.If the VID1/SEL pin is
held LOW during the latch, the ISL6324A will be placed into
SVI mode. If the VID1/SEL pin is held HIGH during the latch,
the ISL6324A will be placed into PVI mode. For the
ISL6324A to properly enter into either mode, the level on the
VID1/SEL pin must be stable no less that 1µs prior to the EN
signal transitioning from low to high.
6-bit Parallel VID Interface (PVI)
With the ISL6324A in PVI mode, the single-phase North
Bridge regulator is disabled. Only the multi-phase controller
is active in PVI mode to support uniplane VDD only
processors. Table 1 shows the 6-bit parallel VID codes and
the corresponding reference voltage.
TABLE 1. 6-BIT PARALLEL VID CODES
VID5
VID4
VID3
VID2
VID1
VID0
VREF
0
0
0
0
0
0
1.5500
0
0
0
0
0
1
1.5250
0
0
0
0
1
0
1.5000
0
0
0
0
1
1
1.4750
0
0
0
1
0
0
1.4500
0
0
0
1
0
1
1.4250
0
0
0
1
1
0
1.4000
0
0
0
1
1
1
1.3750
FN6880.1
April 29, 2010
ISL6324A
TABLE 1. 6-BIT PARALLEL VID CODES (Continued)
TABLE 1. 6-BIT PARALLEL VID CODES (Continued)
VID5
VID4
VID3
VID2
VID1
VID0
VREF
VID5
VID4
VID3
VID2
VID1
VID0
VREF
0
0
1
0
0
0
1.3500
1
1
0
1
0
0
0.5125
0
0
1
0
0
1
1.3250
1
1
0
1
0
1
0.5000
0
0
1
0
1
0
1.3000
1
1
0
1
1
0
0.4875
0
0
1
0
1
1
1.2750
1
1
0
1
1
1
0.4750
0
0
1
1
0
0
1.2500
1
1
1
0
0
0
0.4625
0
0
1
1
0
1
1.2250
1
1
1
0
0
1
0.4500
0
0
1
1
1
0
1.2000
1
1
1
0
1
0
0.4375
0
0
1
1
1
1
1.1750
1
1
1
0
1
1
0.4250
0
1
0
0
0
0
1.1500
1
1
1
1
0
0
0.4125
0
1
0
0
0
1
1.1250
1
1
1
1
0
1
0.4000
0
1
0
0
1
0
1.1000
1
1
1
1
1
0
0.3875
0
1
0
0
1
1
1.0750
1
1
1
1
1
1
0.3750
0
1
0
1
0
0
1.0500
0
1
0
1
0
1
1.0250
0
1
0
1
1
0
1.0000
0
1
0
1
1
1
0.9750
0
1
1
0
0
0
0.9500
0
1
1
0
0
1
0.9250
0
1
1
0
1
0
0.9000
0
1
1
0
1
1
0.8750
0
1
1
1
0
0
0.8500
0
1
1
1
0
1
0.8250
0
1
1
1
1
0
0.8000
0
1
1
1
1
1
0.7750
1
0
0
0
0
0
0.7625
1
0
0
0
0
1
0.7500
1
0
0
0
1
0
0.7375
1
0
0
0
1
1
0.7250
1
0
0
1
0
0
0.7125
1
0
0
1
0
1
0.7000
1
0
0
1
1
0
0.6875
1
0
0
1
1
1
0.6750
1
0
1
0
0
0
0.6625
1
0
1
0
0
1
0.6500
1
0
1
0
1
0
0.6375
1
0
1
0
1
1
0.6250
1
0
1
1
0
0
0.6125
1
0
1
1
0
1
0.6000
1
0
1
1
1
0
0.5875
1
0
1
1
1
1
0.5750
1
1
0
0
0
0
0.5625
1
1
0
0
0
1
0.5500
1
1
0
0
1
0
0.5375
1
1
0
0
1
1
0.5250
15
Serial VID Interface (SVI)
The on-board Serial VID interface (SVI) circuitry allows the
processor to directly drive the core voltage and Northbridge
voltage reference level within the ISL6324A. The SVC and SVD
states are decoded with direction from the PWROK and
VFIXEN inputs as described in the following sections. The
ISL6324A uses a digital to analog converter (DAC) to generate
a reference voltage based on the decoded SVI value. See
Figure 7 for a simple SVI interface timing diagram.
FN6880.1
April 29, 2010
ISL6324A
1
2
3
4
5
6
7
8
9
10
11
12
VCC
SVC
SVD
ENABLE
PWROK
METAL_VID
VDD AND VDDNB
V_SVI
METAL_VID
V_SVI
VDDPWRGD
VFIXEN
FIGURE 7. SVI INTERFACE TIMING DIAGRAM: TYPICAL PRE-PWROK METAL VID START-UP
PRE-PWROK METAL VID
Typical motherboard start-up occurs with the VFIXEN input
low. The controller decodes the SVC and SVD inputs to
determine the Pre-PWROK metal VID setting. Once the
POR circuitry is satisfied, the ISL6324A begins decoding the
inputs per Table 2. Once the EN input exceeds the rising
enable threshold, the ISL6324A saves the Pre-PWROK
metal VID value in an on-board holding register and passes
this target to the internal DAC circuitry.
TABLE 2. PRE-PWROK METAL VID CODES
SVC
SVD
OUTPUT VOLTAGE (V)
0
0
1.1
0
1
1.0
1
0
0.9
1
1
0.8
The Pre-PWROK metal VID code is decoded and latched on
the rising edge of the enable signal. Once enabled, the
ISL6324A passes the Pre-PWROK metal VID code on to
internal DAC circuitry. The internal DAC circuitry begins to
ramp both the VDD and VDDNB planes to the decoded
Pre-PWROK metal VID output level. The digital soft-start
circuitry actually stair steps the internal reference to the
target gradually over a fix interval. The controlled ramp of
both output voltage planes reduces in-rush current during
the soft-start interval. At the end of the soft-start interval, the
VDDPWRGD output transitions high indicating both output
planes are within regulation limits.
If the EN input falls below the enable falling threshold, the
ISL6324A ramps the internal reference voltage down to near
zero. The VDDPWRGD de-asserts with the loss of enable.
16
The VDD and VDDNB planes will linearly decrease to near
zero.
VFIX MODE
In VFIX Mode, the SVC, SVD and VFIXEN inputs are fixed
external to the controller through jumpers to either GND or
VDDIO. These inputs are not expected to change, but the
ISL6324A is designed to support the potential change of
state of these inputs. If VFIXEN is high, the IC decodes the
SVC and SVD states per Table 3.
Once enabled, the ISL6324A begins to soft-start both VDD
and VDDNB planes to the programmed VFIX level. The
internal soft-start circuitry slowly stair steps the reference up
to the target value and this results in a controlled ramp of the
power planes. Once soft-start has ended and both output
planes are within regulation limits, the VDDPWRGD pin
transitions high. If the EN input falls below the enable falling
threshold, then the controller ramps both VDD and VDDNB
down to near zero.
TABLE 3. VFIXEN VID CODES
SVC
SVD
OUTPUT VOLTAGE (V)
0
0
1.4
0
1
1.2
1
0
1.0
1
1
0.8
SVI MODE
Once the controller has successfully soft-started and
VDDPWRGD transitions high, the Northbridge SVI interface
can assert PWROK to signal the ISL6324A to prepare for
SVI commands. The controller actively monitors the SVI
interface for set VID commands to move the plane voltages
FN6880.1
April 29, 2010
ISL6324A
to start-up VID values. Details of the SVI Bus protocol are
provided in the AMD Design Guide for Voltage Regulator
Controllers Accepting Serial VID Codes specification.
Once the set VID command is received, the ISL6324A
decodes the information to determine which plane and the
VID target required. See Table 4. The internal DAC circuitry
steps the required output plane voltage to the new VID level.
During this time one or both of the planes could be targeted.
In the event the core voltage plane, VDD, is commanded to
power off by serial VID commands, the VDDPWRGD signal
remains asserted. The Northbridge voltage plane must
remain active during this time.
If the PWROK input is de-asserted, then the controller steps
both VDD and VDDNB planes back to the stored
Pre-PWROK metal VID level in the holding register from
initial soft-start. No attempt is made to read the SVC and
SVD inputs during this time. If PWROK is reasserted, then
the on-board SVI interface waits for a set VID command.
If VDDPWRGD deasserts during normal operation, both
voltage planes are powered down in a controlled fashion.
The internal DAC circuitry stair steps both outputs down to
near zero.
TABLE 4. SERIAL VID CODES
SVID[6:0]
VOLTAGE (V)
SVID[6:0]
VOLTAGE (V)
SVID[6:0]
VOLTAGE (V)
SVID[6:0]
VOLTAGE (V)
000_0000b
1.5500
010_0000b
1.1500
100_0000b
0.7500
110_0000b
0.3500*
000_0001b
1.5375
010_0001b
1.1375
100_0001b
0.7375
110_0001b
0.3375*
000_0010b
1.5250
010_0010b
1.1250
100_0010b
0.7250
110_0010b
0.3250*
000_0011b
1.5125
010_0011b
1.1125
100_0011b
0.7125
110_0011b
0.3125*
000_0100b
1.5000
010_0100b
1.1000
100_0100b
0.7000
110_0100b
0.3000*
000_0101b
1.4875
010_0101b
1.0875
100_0101b
0.6875
110_0101b
0.2875*
000_0110b
1.4750
010_0110b
1.0750
100_0110b
0.6750
110_0110b
0.2750*
000_0111b
1.4625
010_0111b
1.0625
100_0111b
0.6625
110_0111b
0.2625*
000_1000b
1.4500
010_1000b
1.0500
100_1000b
0.6500
110_1000b
0.2500*
000_1001b
1.4375
010_1001b
1.0375
100_1001b
0.6375
110_1001b
0.2375*
000_1010b
1.4250
010_1010b
1.0250
100_1010b
0.6250
110_1010b
0.2250*
000_1011b
1.4125
010_1011b
1.0125
100_1011b
0.6125
110_1011b
0.2125*
000_1100b
1.4000
010_1100b
1.0000
100_1100b
0.6000
110_1100b
0.2000*
000_1101b
1.3875
010_1101b
0.9875
100_1101b
0.5875
110_1101b
0.1875*
000_1110b
1.3750
010_1110b
0.9750
100_1110b
0.5750
110_1110b
0.1750*
000_1111b
1.3625
010_1111b
0.9625
100_1111b
0.5625
110_1111b
0.1625*
001_0000b
1.3500
011_0000b
0.9500
101_0000b
0.5500
111_0000b
0.1500*
001_0001b
1.3375
011_0001b
0.9375
101_0001b
0.5375
111_0001b
0.1375*
001_0010b
1.3250
011_0010b
0.9250
101_0010b
0.5250
111_0010b
0.1250*
001_0011b
1.3125
011_0011b
0.9125
101_0011b
0.5125
111_0011b
0.1125*
001_0100b
1.3000
011_0100b
0.9000
101_0100b
0.5000
111_0100b
0.1000*
001_0101b
1.2875
011_0101b
0.8875
101_0101b
0.4875*
111_0101b
0.0875*
001_0110b
1.2750
011_0110b
0.8750
101_0110b
0.4750*
111_0110b
0.0750*
001_0111b
1.2625
011_0111b
0.8625
101_0111b
0.4625*
111_0111b
0.0625*
001_1000b
1.2500
011_1000b
0.8500
101_1000b
0.4500*
111_1000b
0.0500*
001_1001b
1.2375
011_1001b
0.8375
101_1001b
0.4375*
111_1001b
0.0375*
001_1010b
1.2250
011_1010b
0.8250
101_1010b
0.4250*
111_1010b
0.0250*
001_1011b
1.2125
011_1011b
0.8125
101_1011b
0.4125*
111_1011b
0.0125*
001_1100b
1.2000
011_1100b
0.8000
101_1100b
0.4000*
111_1100b
OFF
001_1101b
1.1875
011_1101b
0.7875
101_1101b
0.3875*
111_1101b
OFF
001_1110b
1.1750
011_1110b
0.7750
101_1110b
0.3750*
111_1110b
OFF
001_1111b
1.1625
011_1111b
0.7625
101_1111b
0.3625*
111_1111b
OFF
NOTE: * Indicates a VID not required for AMD Family 10h processors.
17
FN6880.1
April 29, 2010
ISL6324A
POWER SAVINGS MODE: PSI_L
Voltage Regulation
Bit 7 of the Serial VID code transmitted as part of the 8-bit
data phase over the SVI bus is allocated for the PSI_L. If
Bit 7 is 0, then the processor is at an optimal load for the
regulator to enter power savings mode. If Bit 7 is 1, then the
regulator should not be in power savings mode.
The integrating compensation network shown in Figure 8
insures that the steady-state error in the output voltage is
limited only to the error in the reference voltage,
remote-sense and error amplifiers. Intersil specifies the
guaranteed tolerance of the ISL6324A to include the
combined tolerances of each of these elements.
With the ISL6324A, Power Savings mode is realized through
phase shedding. Once a Serial VID command with Bit 7 set
to 0 is received, the ISL6324A will shed phases in a
sequential manner. The default number of phases that the
ISL6324A will run on in Power Savings Mode is two. This
number is programmable through the I2C interface and can
be set to three phases or to one phase (See “I2C Bus
Interface” on page 23). Phases are shed decrementally,
starting with Channel 4. When a phase is shed, that phase
will not go into a tri-state mode until that phase would have
had its PWM go HIGH.
After a phase is shed, the ISL6324A will wait, by default,
1 full PWM cycle before shedding the next phase. This delay
can be changed to 0, 2 or 4 PWM cycle delays through the
I2C interface (See “I2C Bus Interface” on page 23). It should
be noted that with a 0 cycle delay, all phases that are to be
shed will be turned off at the same time. While the option to
shed all phases at once is available, it is not recommended
as the Core voltage could be subjected to large output
deviations during the transition.
When leaving Power Savings Mode, through the reception of
a Serial VID command with Bit 7 set to 1, the ISL6324A will
sequentially turn on phases starting with the lowest
numbered phase that has been shed. When a phase is
being reactivated, it will not leave a tri-state until the PWM of
that phase goes HIGH.
After a phase is reactivated, the ISL6324A will wait, by
default, 1 full PWM cycle before reactivating the next phase.
This delay can be changed to 0, 2 or 4 PWM cycle delays
through the I2C interface (See “I2C Bus Interface” on
page 23). It should be noted that with a 0 cycle delay, all
phases that have been shed will be turned on at the same
time. While the option to reactivate all phases at once is
available, it is not recommended as the Core voltage could
be subjected to large output deviations during the transition.
If, while in Power Savings Mode, a Serial VID command is
received that forces a VID level change while maintaining
Bit 7 at 0, the ISL632A will first exit the Power Savings Mode
state as previously described. The output voltage will then
be stepped up or down to the appropriate VID level. Finally,
the ISL6324A will then re-enter Power Savings Mode.
If the Core regulator has had an offset voltage added to the
DAC through the I2C interface, this offset will, by default,
remain while in Power Savings Mode. Through the I2C
interface, the offset can be disabled while in Power Savings
Mode (See “I2C Bus Interface” on page 23).
18
The output of the error amplifier, VCOMP, is used by the
modulator to generate the PWM signals. The PWM signals
control the timing of the Internal MOSFET drivers and
regulate the converter output so that the voltage at FB is equal
to the voltage at REF. This will regulate the output voltage to
be equal to Equation 11. The internal and external circuitry
that controls voltage regulation is illustrated in Figure 8.
(EQ. 11)
V OUT = V REF – V DROOP
The ISL6324A incorporates differential remote-sense
amplification in the feedback path. The differential sensing
removes the voltage error encountered when measuring the
output voltage relative to the controller ground reference point
resulting in a more accurate means of sensing output voltage.
EXTERNAL CIRCUIT
ISL6324A INTERNAL CIRCUIT
FS
RFS
DROOP
CONTROL
TO
OSCILLATOR
COMP
CC
IAVG
RC
FB
+
RFB
ERROR
AMPLIFIER
+
VDROOP
-
VSEN
+
VOUT
-
VCOMP
∑
+
VID
DAC
+
RGND
FIGURE 8. OUTPUT VOLTAGE AND LOAD-LINE
REGULATION
Load-Line (Droop) Regulation
By adding a well controlled output impedance, the output
voltage can effectively be level shifted in a direction which
works to achieve a cost-effective solution can help to reduce
the output-voltage spike that results from fast load-current
demand changes.
FN6880.1
April 29, 2010
ISL6324A
The magnitude of the spike is dictated by the ESR and ESL
of the output capacitors selected. By positioning the no-load
voltage level near the upper specification limit, a larger
negative spike can be sustained without crossing the lower
limit. By adding a well controlled output impedance, the
output voltage under load can effectively be level shifted
down so that a larger positive spike can be sustained without
crossing the upper specification limit.
As shown in Figure 8, with the FS resistor tied to ground, the
average current of all active channels, IAVG, flows from FB
through a load-line regulation resistor RFB. The resulting
voltage drop across RFB is proportional to the output current,
effectively creating an output voltage droop with a
steady-state value defined as in Equation 12:
V DROOP = I AVG ⋅ R FB
(EQ. 12)
The regulated output voltage is reduced by the droop voltage
VDROOP. The output voltage as a function of load current is
shown in Equation 13.
RFB
VSEN
IDVC = IC
IC
IDVC
CC
CDVC
DVC
RC
RDVC
COMP
FB
+
VDAC+RGND
ERROR
AMPLIFIER
ISL6324A INTERNAL CIRCUIT
FIGURE 9. DYNAMIC VID COMPENSATION NETWORK
during a VID change, a VID-on-the-fly compensation
network is required. This network is composed of a resistor
and capacitor in series, RDVC and CDVC, between the DVC
and the FB pin.
Dynamic VID
This VID-on-the-fly compensation network works by
sourcing AC current into the FB node to offset the effects of
the AC current flowing from the FB to the COMP pin during a
VID transition. To create this compensation current the
ISL6324A sets the voltage on the DVC pin to be 2x the
voltage on the REF pin. Since the error amplifier forces the
voltage on the FB pin and the REF pin to be equal, the
resulting voltage across the series RC between DVC and FB
is equal to the REF pin voltage. The RC compensation
components, RDVC and CDVC, can then be selected to
create the desired amount of compensation current.
The AMD processor does not step the output voltage
commands up or down to the target voltage, but instead
passes only the target voltage to the ISL6324A through
either the PVI or SVI interface. The ISL6324A manages the
resulting VID-on-the-Fly transition in a controlled manner,
supervising a safe output voltage transition without
discontinuity or disruption. The ISL6324A begins slewing the
DAC at 3.25mV/µs until the DAC and target voltage are
equal. Thus, the total time required for a dynamic VID
transition is dependent only on the size of the DAC change.
The amount of compensation current required is dependant
on the modulator gain of the system, K1, and the error
amplifier RC components, RC and CC, that are in series
between the FB and COMP pins. Use Equations 14, 15 and
16 to calculate the RC component values, RDVC and CDVC,
for the VID-on-the-fly compensation network. For these
equations: VIN is the input voltage for the power train; VP-P
is the oscillator ramp amplitude (1.5V); and RC and CC are
the error amplifier RC components between the FB and
COMP pins.
⎛ I OUT
⎞
400
1
V OUT = V REF – ⎜ ------------- ⋅ DCR ⋅ ⎛ ---------- ⋅ ---------------⎞ ⋅ K ⋅ R FB⎟
⎝ 3 R
⎠
⎝ N
⎠
SET
(EQ. 13)
In Equation 13, VREF is the reference voltage, IOUT is the
total output current of the converter, K is the DC gain of the
RC filter across the inductor (K is defined in Equation 7), N is
the number of active channels, and DCR is the Inductor
DCR value.
To further improve dynamic VID performance, ISL6324A
also implements a proprietary DAC smoothing feature. The
external series RC components connected between DVC
and FB limit any stair-stepping of the output voltage during a
VID-on-the-Fly transition.
Compensating Dynamic VID Transitions
During a VID transition, the resulting change in voltage on
the FB pin and the COMP pin causes an AC current to flow
through the error amplifier compensation components from
the FB to the COMP pin. This current then flows through the
feedback resistor, RFB, and can cause the output voltage to
overshoot or undershoot at the end of the VID transition. In
order to ensure the smooth transition of the output voltage
19
K1
A = ----------------K1 – 1
(EQ. 14)
V IN
K1 = ---------------VP – P
R RCOMP = A × R C
(EQ. 15)
CC
C RCOMP = -------A
(EQ. 16)
Advanced Adaptive Zero Shoot-Through Deadtime
Control (Patent Pending)
The integrated drivers incorporate a unique adaptive deadtime
control technique to minimize deadtime, resulting in high
FN6880.1
April 29, 2010
ISL6324A
efficiency from the reduced freewheeling time of the lower
MOSFET body-diode conduction, and to prevent the upper and
lower MOSFETs from conducting simultaneously. This is
accomplished by ensuring either rising gate turns on its
MOSFET with minimum and sufficient delay after the other has
turned off.
During turn-off of the lower MOSFET, the PHASE voltage is
monitored until it reaches a -0.3V/+0.8V (forward/reverse
inductor current). At this time the UGATE is released to rise. An
auto-zero comparator is used to correct the rDS(ON) drop in the
phase voltage preventing false detection of the -0.3V phase
level during rDS(ON) conduction period. In the case of zero
current, the UGATE is released after 35ns delay of the LGATE
dropping below 0.5V. When LGATE first begins to transition
low, this quick transition can disturb the PHASE node and
cause a false trip, so there is 20ns of blanking time once
LGATE falls until PHASE is monitored.
Once the PHASE is high, the advanced adaptive
shoot-through circuitry monitors the PHASE and UGATE
voltages during a PWM falling edge and the subsequent
UGATE turn-off. If either the UGATE falls to less than 1.75V
above the PHASE or the PHASE falls to less than +0.8V, the
LGATE is released to turn-on.
Initialization
Prior to initialization, proper conditions must exist on the EN,
VCC, PVCC1_2, PVCC_NB, ISEN3-, and ISEN4- pins. When
the conditions are met, the controller begins soft-start. Once
the output voltage is within the proper window of operation,
the controller asserts VDDPWRGD.
ISL6324A INTERNAL CIRCUIT
EXTERNAL CIRCUIT
VCC
PVCC1_2
PVCC_NB
+12V
POR
CIRCUIT
ENABLE
COMPARATOR
10.7kΩ
EN
+
-
1.00kΩ
0.86V
ISEN3SOFT-START
AND
FAULT LOGIC
CHANNEL
DETECT
ISEN4-
FIGURE 10. POWER SEQUENCING USING THRESHOLDSENSITIVE ENABLE (EN) FUNCTION
20
Power-On Reset
The ISL6324A requires VCC, PVCC1_2, and PVCC_NB
inputs to exceed their rising POR thresholds before the
ISL6324A has sufficient bias to guarantee proper operation.
The bias voltage applied to VCC must reach the internal
power-on reset (POR) rising threshold. Once this threshold
is reached, the ISL6324A has enough bias to begin checking
the driver POR inputs, EN, and channel detect portions of
the initialization cycle. Hysteresis between the rising and
falling thresholds assure the ISL6324A will not advertently
turn off unless the bias voltage drops substantially (see
“Electrical Specifications” on page 6).
The bias voltage applied to the PVCC1_2 and PVCC_NB
pins power the internal MOSFET drivers of each output
channel. In order for the ISL6324A to begin operation, both
PVCC inputs must exceed their POR rising threshold to
guarantee proper operation of the internal drivers.
Hysteresis between the rising and falling thresholds assure
that once enabled, the ISL6324A will not inadvertently turn
off unless the PVCC bias voltage drops substantially (see
“Electrical Specifications” on page 6). Depending on the
number of active CORE channels determined by the Phase
Detect block, the external driver POR checking is supported
by the Enable Comparator.
Enable Comparator
The ISL6324A features a dual function enable input (EN) for
enabling the controller and power sequencing between the
controller and external drivers or another voltage rail. The
enable comparator holds the ISL6324A in shutdown until the
voltage at EN rises above 0.86V. The enable comparator has
about 110mV of hysteresis to prevent bounce. It is important
that the driver ICs reach their rising POR level before the
ISL6324A becomes enabled. The schematic in Figure 10
demonstrates sequencing the ISL6324A with the ISL66xx
family of Intersil MOSFET drivers, which require 12V bias.
When selecting the value of the resistor divider the driver
maximum rising POR threshold should be used for
calculating the proper resistor values. This will prevent
improper sequencing events from creating false trips during
soft-start.
If the controller is configured for 2-phase CORE operation,
then the resistor divider can be used for sequencing the
controller with another voltage rail. The resistor divider to EN
should be selected using a similar approach as the previous
driver discussion.
The EN pin is also used to force the ISL6324A into either
PVI or SVI mode. The mode is set upon the rising edge of
the EN signal. When the voltage on the EN pin rises above
0.86V, the mode will be set depending upon the status of the
VID1/SEL pin.
FN6880.1
April 29, 2010
ISL6324A
Phase Detection
.
The ISEN3- and ISEN4- pins are monitored prior to soft-start
to determine the number of active CORE channel phases.
If ISEN4- is tied to VCC, the controller will configure the
channel firing order and timing for 3-phase operation. If
ISEN3- and ISEN4- are tied to VCC, the controller will set
the channel firing order and timing for 2-phase operation
(see “PWM Operation” on page 12 for details). If Channel 4
and/or Channel 3 are disabled, then the corresponding
PWMn and ISENn+ pins may be left unconnected
VNB
400mV/DIV
TDA
TDB
EN
5V/DIV
VDDPWRGD
5V/DIV
Soft-Start Output Voltage Targets
Once the POR and Phase Detect blocks and enable
comparator are satisfied, the controller will begin the
soft-start sequence and will ramp the CORE and NB output
voltages up to the SVI interface designated target level if the
controller is set SVI mode. If set to PVI mode, the North
Bridge regulator is disabled and the core is soft started to the
level designated by the parallel VID code.
SVI MODE
Prior to soft-starting both CORE and NB outputs, the
ISL6324A must check the state of the SVI interface inputs to
determine the correct target voltages for both outputs. When
the controller is enabled, the state of the VFIXEN, SVD and
SVC inputs are checked and the target output voltages set
for both CORE and NB outputs are set by the DAC (see
“Serial VID Interface (SVI)” on page 15). These targets will
only change if the EN signal is pulled low or after a POR
reset of VCC.
Soft-Start
The soft-start sequence is composed of three periods, as
shown in Figure 11. At the beginning of soft-start, the DAC
immediately obtains the output voltage targets for both
outputs by decoding the state of the SVI or PVI inputs. A
100µs fixed delay time, TDA, proceeds the output voltage
rise. After this delay period the ISL6324A will begin ramping
both CORE and NB output voltages to the programmed DAC
level at a fixed rate of 3.25mV/µs. The amount of time
required to ramp the output voltage to the final DAC voltage
is referred to as TDB, and can be calculated as shown in
Equation 17.
V DAC
TDB = -----------------------------–3
3.25 × 10
(EQ. 17)
After the DAC voltage reaches the final VID setting,
VDDPWRGD will be set to high.
VCORE
400mV/DIV
100µs/DIV
FIGURE 11. SOFT-START WAVEFORMS
Pre-Biased Soft-Start
The ISL6324A also has the ability to start up into a
pre-charged output, without causing any unnecessary
disturbance. The FB pin is monitored during soft-start, and
should it be higher than the equivalent internal ramping
reference voltage, the output drives hold both MOSFETs off.
Once the internal ramping reference exceeds the FB pin
potential, the output drives are enabled, allowing the output to
ramp from the pre-charged level to the final level dictated by
the DAC setting. Should the output be pre-charged to a level
exceeding the DAC setting, the output drives are enabled at
the end of the soft-start period, leading to an abrupt correction
in the output voltage down to the DAC-set level.
Both CORE and NB output support start up into a
pre-charged output.
OUTPUT PRECHARGED
ABOVE DAC LEVEL
OUTPUT PRECHARGED
BELOW DAC LEVEL
VCORE
400mV/DIV
EN
5V/DIV
100µs/DIV
FIGURE 12. SOFT-START WAVEFORMS FOR
ISL6324A-BASED MULTI-PHASE CONVERTER
21
FN6880.1
April 29, 2010
ISL6324A
Overvoltage Protection
-
17.5µA
OCL
+
12.5µA
REPEAT FOR EACH
CORE CHANNEL
-
OCP
INB
I1
+
-
12.5µA
+
IAVG
OCP
CORE ONLY
NB ONLY
SOFT-START, FAULT
AND CONTROL LOGIC
DUPLICATED FOR
NB AND CORE
1.8V
+
OVP
-
DAC + 250mV
+
-
VSEN
DAC - 300mV
UV
VDDPWRGD
ISL6324A INTERNAL CIRCUITRY
FIGURE 13. POWER-GOOD AND PROTECTION CIRCUITRY
Fault Monitoring and Protection
The ISL6324A actively monitors both CORE and NB output
voltages and currents to detect fault conditions. Fault
monitors trigger protective measures to prevent damage to
either load. One common power-good indicator is provided
for linking to external system monitors. The schematic in
Figure 13 outlines the interaction between the fault monitors
and the power good signal.
Power-Good Signal
The power good pin (VDDPWRGD) is an open-drain logic
output that signals whether or not the ISL6324A is regulating
both NB and CORE output voltages within the proper levels,
and whether any fault conditions exist. This pin should be
tied to a +5V source through a resistor.
During shutdown and soft-start, VDDPWRGD pulls low and
releases high after a successful soft-start and both output
voltages are operating between the undervoltage and
overvoltage limits. VDDPWRGD transitions low when an
undervoltage, overvoltage, or overcurrent condition is
detected on either regulator output or when the controller is
disabled by a POR reset or EN. In the event of an
overvoltage or overcurrent condition, the controller latches
off and VDDPWRGD will not return high. Pending a POR
reset of the ISL6324A and successful soft-start, the
VDDPWRGD will return high.
22
At the inception of an overvoltage event, both on-board
lower gate pins are commanded low as are the active PWM
outputs to the external drivers, the VDDPWRGD signal is
driven low, and the ISL6324A latches off normal PWM
action. This turns on the all of the lower MOSFETs and pulls
the output voltage below a level that might cause damage to
the load. The lower MOSFETs remain driven ON until VDIFF
falls below 400mV. The ISL6324A will continue to protect the
load in this fashion as long as the overvoltage condition
recurs. Once an overvoltage condition ends the ISL6324A
latches off, and must be reset by toggling POR, before a
soft-start can be re-initiated.
Pre-POR Overvoltage Protection
OV
+
The ISL6324A constantly monitors the sensed output voltage
on the VSEN pin to detect if an overvoltage event occurs.
When the output voltage rises above the OVP trip level and
exceeds the VDDPWRGD OV limit actions are taken by the
ISL6324A to protect the microprocessor load.
Prior to PVCC and VCC exceeding their POR levels, the
ISL6324A is designed to protect either load from any
overvoltage events that may occur. This is accomplished by
means of an internal 10kΩ resistor tied from PHASE to
LGATE, which turns on the lower MOSFET to control the
output voltage until the overvoltage event ceases or the input
power supply cuts off. For complete protection, the low side
MOSFET should have a gate threshold well below the
maximum voltage rating of the load/microprocessor.
In the event that during normal operation the PVCC or VCC
voltage falls back below the POR threshold, the pre-POR
overvoltage protection circuitry reactivates to protect from
any more pre-POR overvoltage events.
Undervoltage Detection
The undervoltage threshold is set at VDAC - 300mV typical.
When the output voltage (VSEN-RGND) is below the
undervoltage threshold, VDDPWRGD gets pulled low. No
other action is taken by the controller. VDDPWRGD will
return high if the output voltage rises above VDAC - 250mV
typical.
Open Sense Line Protection
In the case that either of the remote sense lines, VSEN or
GND, become open, the ISL6324A is designed to detect this
and shut down the controller. This event is detected by
monitoring small currents that are fed out the VSEN and
RGND pins. In the event of an open sense line fault, the
controller will continue to remain off until the fault goes away,
at which point the controller will re-initiate a soft-start
sequence.
Overcurrent Protection
The ISL6324A takes advantage of the proportionality
between the load current and the average current, IAVG, to
detect an overcurrent condition. See “Continuous Current
FN6880.1
April 29, 2010
ISL6324A
Sampling” on page 13 and “Channel-Current Balance” on
page 14 for more detail on how the average current is
measured. Once the average current exceeds 100µA, a
comparator triggers the converter to begin overcurrent
protection procedures. The Core regulator and the North
Bridge regulator have the same type of overcurrent
protection.
zero. Once the regulator has completed soft-start, the
overcurrent trip point will return to it’s nominal setting and an
overcurrent shutdown will be initiated. This will result in a
continuous hiccup mode.
Note that the energy delivered during trip-retry cycling is
much less than during full-load operation, so there is no
thermal hazard.
The overcurrent trip threshold is dictated by the DCR of the
inductors, the number of active channels, the DC gain of the
inductor RC filter and the RSET resistor. The overcurrent trip
threshold is shown in Equation 18.
OUTPUT CURRENT, 50A/DIV
V IN – N ⋅ V OUT V OUT
N
1
3
I OCP = 100μA ⋅ ------------- ⋅ ---- ⋅ ⎛ ---------- ⋅ R SET⎞ – ---------------------------------------- ⋅ ---------------⎠
2 ⋅ L ⋅ fS
V IN
DCR K ⎝ 400
(EQ. 18)
0A
Where:
R2
K = -------------------R1 + R2
See “Continuous Current Sampling” on
page 13.
OUTPUT VOLTAGE,
500mV/DIV
fS = Switching Frequency
0V
Equation 18 is valid for both the Core regulator and the
North Bridge regulator. This equation includes the DC load
current as well as the total ripple current contributed by all
the phases. For the North Bridge regulator, N is 1.
During soft-start, the overcurrent trip point is boosted by a
factor of 1.4. Instead of comparing the average measured
current to 100µA, the average current is compared to 140µA.
Immediately after soft-start is over, the comparison level
changes to 100µA. This is done to allow for start-up into an
active load while still supplying output capacitor in-rush
current.
CORE REGULATOR OVERCURRENT
At the beginning of overcurrent shutdown, the controller sets
all of the UGATE and LGATE signals low, puts PWM3 and
PWM4 (if active) in a high-impedance state, and forces
VDDPWRGD low. This turns off all of the upper and lower
MOSFETs. The system remains in this state for fixed period of
12ms. If the controller is still enabled at the end of this wait
period, it will attempt a soft-start, as shown in Figure 14. If the
fault remains, the trip-retry cycles will continue until either the
fault is cleared or for a total of seven attempts. If the fault is
not cleared on the final attempt, the controller disables
UGATE and LGATE signals for both Core and North Bridge
and latches off requiring a POR of VCC to reset the
ISL6324A.
It is important to note that during soft start, the overcurrent
trip point is increased by a factor of 1.4. If the fault draws
enough current to trip overcurrent during normal run mode, it
may not draw enough current during the soft-start ramp
period to trip overcurrent while the output is ramping up. If a
fault of this type is affecting the output, then the regulator will
complete soft-start and the trip-retry counter will be reset to
23
3ms/DIV
FIGURE 14. OVERCURRENT BEHAVIOR IN HICCUP MODE
NORTH BRIDGE REGULATOR OVERCURRENT
The overcurrent shutdown sequence for the North Bridge
regulator is identical to the Core regulator with the exception
that it is a single phase regulator and will only disable the
MOSFET drivers for the North Bridge. Once 7 retry attempts
have been executed unsuccessfully, the controller will disable
UGATE and LGATE signals for both Core and North Bridge
and will latch off requiring a POR of VCC to reset the
ISL6324A.
Note that the energy delivered during trip-retry cycling is
much less than during full-load operation, so there is no
thermal hazard.
Individual Channel Overcurrent Limiting
The ISL6324A has the ability to limit the current in each
individual channel of the Core regulator without shutting
down the entire regulator. This is accomplished by
continuously comparing the sensed currents of each channel
with a constant 140µA OCL reference current. If a channel’s
individual sensed current exceeds this OCL limit, the UGATE
signal of that channel is immediately forced low, and the
LGATE signal is forced high. This turns off the upper
MOSFET(s), turns on the lower MOSFET(s), and stops the
rise of current in that channel, forcing the current in the
channel to decrease. That channel’s UGATE signal will not
be able to return high until the sensed channel current falls
back below the 140µA reference.
I2C Bus Interface
The ISL6324A includes an I2C bus interface which allows for
user programmability of three of the controller’s operating
FN6880.1
April 29, 2010
ISL6324A
parameters and programmability of the Power Savings Mode
feature. The parameters that can be adjusted through the
I2C are:
1. Voltage Margining Offset: The DAC voltage can be
offset in 25mV increments.
SDA
SCL
2. VDDPWRGD Trip Level: The PGOOD trip level for either
the Core regulator or the North Bridge regulator can be
increased.
3. Overvoltage Trip Level: The OVP trip level of either the
Core or North Bridge regulator can be increased.
4. Power Savings Mode Options:
a. The number of phases to drop to in Power Savings
Mode can be programmed
b. The number of PWM cycles between dropping phases
while entering Power Savings Mode can be
programmed.
c. The number of PWM cycles between adding phases
when exiting Power Savings Mode can be
programmed.
d. Core Voltage Margining Offset can be Enabled or
Disabled while in Power Savings Mode.
To adjust these parameters, data transmission from the main
microprocessor to the ISL6324A and vice versa must take
place through the two wire I2C bus interface. The two wires of
the I2C bus consist of the SDA line, over which all data is sent,
and the SCL line, which is a clock signal used to synchronize
sending/receiving of the data.
Both SDA and SCL are bidirectional lines, externally connected
to a positive supply voltage via a pull-up resistor. Pull-up
resistor values should be chosen to limit the input current to
less then 3mA. When the bus is free, both lines are HIGH. The
output stages of ISL6324A have an open drain/open collector in
order to perform the wired-AND function. Data on the I2C bus
can be transferred up to 100Kbps in the standard-mode or up to
400Kbps in the fast-mode. The level of logic “0” and logic “1” is
dependent on associated value of VDD as per electrical
specification table. One clock pulse is generated for each data
bit transferred. The ISL6324A is a “SLAVE only” device, so the
SCL line must always be controlled by an external master.
It is important to note that the I2C interface of the ISL6324A
only works once the voltage on the VCC pin has risen above
the POR rising threshold. The I2C will continue to remain
active until the voltage on the VCC pin falls back below the
falling POR threshold level.
Data Validity
DATA LINE CHANGE
STABLE
OF DATA
DATA VALID ALLOWED
FIGURE 15. DATA VALIDITY
START and STOP Conditions
Figure 16 shows a START (S) condition is a HIGH to LOW
transition of the SDA line while SCL is HIGH.
The STOP (P) condition is a LOW to HIGH transition on the
SDA line while SCL is HIGH. A STOP condition must be sent
before each START condition..
SDA
SCL
S
P
START
CONDITION
STOP
CONDITION
FIGURE 16. START AND STOP WAVEFORMS
Byte Format
Every byte put on the SDA line must be eight bits long. The
number of bytes that can be transmitted per transfer is
unrestricted. Each byte has to be followed by an
acknowledge bit. Data is transferred with the most significant
bit first (MSB) and the least significant bit last (LSB).
Acknowledge
Each address and data transmission uses 9-clock pulses.
The ninth pulse is the acknowledge bit (A). After the start
condition, the master sends 7 slave address bits and a R/W
bit during the next 8-clock pulses. During the ninth clock
pulse, the device that recognizes its own address holds the
data line low to acknowledge. The acknowledge bit is also
used by both the master and the slave to acknowledge
receipt of register addresses and data as described in
Figure 17.
SCL
1
2
8
9
SDA
The data on the SDA line must be stable during the HIGH
period of the SCL, unless generating a START or STOP
condition. The HIGH or LOW state of the data line can only
change when the clock signal on the SCL line is LOW. Refer
to Figure 15.
24
MSB
START
ACKNOWLEDGE
FROM SLAVE
FIGURE 17. ACKNOWLEDGE ON THE I2C BUS
FN6880.1
April 29, 2010
ISL6324A
ISL6324A I2C Slave Address
All devices on the I2C bus must have a 7-Bit I2C address in
order to be recognized. The address for the ISL6324A is
1000_110.
Communicating Over the I2C Bus
Two transactions are supported on the I2C interface:
1. Write register
2. Read register from current address.
All transactions start with a control byte sent from the I2C
master device. The control byte begins with a Start condition,
followed by 7-Bits of slave address. The last bit sent by the
master is the R/W bit and is 0 for a write or 1 for a read. If
any slaves on the I2C bus recognize their address, they will
Acknowledge by pulling the serial data line low for the last
clock cycle in the control byte. If no slaves exist at that
address or are not ready to communicate, the data line will
be 1, indicating a Not Acknowledge condition.
Once the control byte is sent, and the ISL6324A
acknowledges it, the 2nd byte sent by the master must be a
register address byte. This register address byte tells the
ISL6324A which one of the internal registers it wants to write
to or read from. The address of the first internal register,
RGS1, is 0000_0000. This register sets the North Bridge
Offset, Overvoltage trip point and Power-good trip level. The
address of the second internal register, RGS2, is 0000_0001.
This register sets the Core Offset, Overvoltage trip point and
Power-good trip level. The address of the third register,
RGS3, is 0000_0010. The third register is for programming of
the Power Savings Mode features. Once the ISL6324A
receives a correct register address byte, it responds with an
acknowledge.
TABLE 5. I2C REGISTER FUNCTIONS
REGISTER ADDRESS
FUNCTION
RGS1
0000_0000 North Bridge DAC Offset, OVP, PGOOD
RGS2
0000_0001 Core DAC Offset, OVP, PGOOD
RGS3
0000_0010 Power Savings Mode Functionality
Writing to the Internal Registers
In order to change any of the three operating parameters via
the I2C bus, the internal registers must be written to. The two
registers inside the ISL6324A can be written individually with
two separate write transactions or sequentially with one write
transaction by sending two data bytes. See “Reading from
the Internal Registers” on page 25.
To write to a single register in the ISL6324A, the master
sends a control byte with the R/W bit set to 0, indicating a
write. If it receives an Acknowledge from the ISL6324A, it
sends a register address byte representing the internal
register it wants to write to (0000_0000 for RGS1,
0000_0001 for RGS2 or 0000_0010 for RGS3). The
ISL6324A will respond with an Acknowledge. The master
25
then sends a byte representing the data byte to be written
into the desired register. The ISL6324A will respond with an
Acknowledge. The master then issues a Stop condition,
indicating to the ISL6324A that the current transaction is
complete. Once this transaction completes, the ISL6324A
will immediately update and change the operating
parameters on-the-fly.
It is also possible to write to the all the registers sequentially.
To do this the master must write to register RGS1first. This
transaction begins with the master sending a control byte
with the R/W bit set to 0. If it receives an Acknowledge from
the ISL6324A, it sends the register address byte 0000_0000,
representing the internal register RGS1. The ISL6324A will
respond with an Acknowledge. After sending the data byte to
RGS1 and receiving an Acknowledge from the ISL6324A,
instead of sending a Stop condition, the master sends the
data byte to be stored in register RGS2. After the ISL6324A
responds with another Acknowledge, the master can either
send a Stop condition to indicate that the current transaction
is complete, or it can send the data byte to be stored in
register RGS3. If register RGS3 is written to, the ISL6324A
will respond with an Acknowledge and the master would
send a Stop condition, completing the transaction. Once this
transaction completes the ISL6324A will immediately update
and change the operating parameters on-the-fly.
Reading from the Internal Registers
The ISL6324A has the ability to read from both registers
separately or read from them consecutively. Prior to reading
from an internal register, the master must first select the
desired register by writing to it and sending the register’s
address byte. This process begins by the master sending a
control byte with the R/W bit set to 0, indicating a write. Once
it receives an Acknowledge from the ISL6324A, it sends a
register address byte representing the internal register it
wants to read from (0000_0000 for RGS1, 0000_0001 for
RGS2 or 0000_0010 for RGS3). The ISL6324A will respond
with an Acknowledge. The master must then respond with a
Stop condition. After the Stop condition, the master follows
with a new Start condition, and then sends a new control
byte with the R/W bit set to 1, indicating a read. The
ISL6324A will then respond by sending the master an
Acknowledge, followed by the data byte stored in that
register. The master must then send a Not Acknowledge
followed by a Stop command, which will complete the read
transaction.
It is also possible for all registers to be read consecutively.
To do this the master must read from register RGS1 first.
This transaction begins with the master sending a control
byte with the R/W bit set to 0. If it receives an Acknowledge
from the ISL6324A, it sends the register address byte
0000_0000, representing the internal register RGS1. The
ISL6324A will respond with an Acknowledge. The master
must then respond with a Stop condition. After the Stop
condition the master follows with a new Start condition, and
FN6880.1
April 29, 2010
ISL6324A
POR rising threshold level, these registers can be changed
at any time via the I2C interface. If the voltage on the VCC
pin falls below the POR falling threshold, the internal
registers are automatically reset to their initial states.
then sends a new control byte with the R/W bit set to 1,
indicating a read. The ISL6324A will then respond by
sending the master an Acknowledge, followed by the data
byte stored in register RGS1. The master must then send an
Acknowledge, and after doing so, the ISL6324A will respond
by sending the data byte stored in register RGS2. The
master must then send another Acknowledge, which the
ISL6324A will respond to by sending the data byte stored in
register RGS3. The master must then send a Not
Acknowledge followed by a Stop command, which will
complete the read transaction.
TABLE 6. I2C REGISTER INITIAL STATES
Resetting the Internal Registers
REGISTER
ADDRESS
INITIAL STATE
RGS1
0000_0000
0000_0000
RGS2
0000_0001
0000_0000
RGS3
0000_0010
0000_0001
It is possible to reset the internal registers without powering
down the controller and without requiring the controller to
stop regulating and soft-start again. Simply write the initial
states to the internal registers over the I2C interface.
The ISL6324A’s internal I2C registers always initialize to the
states shown in Table 6 when the controller first receives
power. Once the voltage on the VCC pin rises above the
I2C Read and Write Protocol
WRITE TO A SINGLE REGISTER
S
1000_1100
A
0000_0000
A
RGS1_DATA
A
P
A
RGS1_DATA
A
RGS1_DATA
WRITE TO ALL REGISTERS
S
1000_1100
A
0000_0000
A
RGS1_DATA
A
P
READ FROM SINGLE REGISTER
S
1000_1100
A REG_ADDR A
P
S
1000_1101
A
RGS1_DATA
N
P
P
S
1000_1101
A
RGS1_DATA
A
RGS2_DATA
READ FROM ALL REGISTERS
S
1000_1100
A
0000_0000
A
A
DRIVEN BY MASTER
S = START CONDITION
A = ACKNOWLEDGE
DRIVEN BY ISL6324A
P = STOP CONDITION
N = NO ACKNOWLEDGE
26
RGS3_DATA
N
P
FN6880.1
April 29, 2010
ISL6324A
Register Bit Definitions
The bits for RGS1 and RGS2 are utilized in the same
manner by the ISL6324A (see Table 5). Bit-7 enables the
overvoltage protection trip point to be increased. Bit-6
enables the Power-good trip point to be increased. These
bits will be interpreted by the ISL6324A according to Table 7.
Bits 5 through 0 determine the amount of offset for the
particular regulator. See Table 8 for the bit codes and the
corresponding offset voltages from the nominal DAC.
TABLE 7. BIT [7] AND [6] of REGISTER RGS1 AND RGS2
BIT 7
OVP TRIP LEVEL
TABLE 8. BITS [5:0] REGISTER RGS1 and RGS2
(VOLTAGE MARGINING OFFSET) (Continued)
BIT5
BIT4
BIT3
BIT2
BIT1
BIT0
VO5
VO4
VO3
VO2
VO1
VO0
VOFFSET
(mV)
1
1
0
1
1
0
-250
1
1
0
1
1
1
-225
1
1
1
0
0
0
-200
1
1
1
0
0
1
-175
1
1
1
0
1
0
-150
1
1
1
0
1
1
-125
0
1.8V or VDAC + 250mV, whichever is greater
1
1
1
1
0
0
-100
1
1.8V or VDAC + 500mV, whichever is greater
1
1
1
1
0
1
-75
1
1
1
1
1
0
-50
1
1
1
1
1
1
-25
0
0
0
0
0
0
0
0
0
0
0
0
1
25
0
0
0
0
1
0
50
0
0
0
0
1
1
75
0
0
0
1
0
0
100
0
0
0
1
0
1
125
0
0
0
1
1
0
150
BIT 6
PGOOD TRIP LEVEL
0
VDACCORE +250mV/-300mV
VDACNB - 300mV
1
VDACCORE +300mV/-350mV
VDACNB - 350mV
NOTE: All Pgood trip points have 50mV hysteresis
TABLE 8. BITS [5:0] REGISTER RGS1 and RGS2
(VOLTAGE MARGINING OFFSET)
BIT5
BIT4
BIT3
BIT2
BIT1
BIT0
VO5
VO4
VO3
VO2
VO1
VO0
VOFFSET
(mV)
1
0
0
0
0
0
-800
0
0
0
1
1
1
175
1
0
0
0
0
1
-775
0
0
1
0
0
0
200
1
0
0
0
1
0
-750
0
0
1
0
0
1
225
0
1
0
1
0
250
1
0
0
0
1
1
-725
0
1
0
0
1
0
0
-700
0
0
1
0
1
1
275
1
0
0
1
0
1
-675
0
0
1
1
0
0
300
1
0
0
1
1
0
-650
0
0
1
1
0
1
325
1
0
0
1
1
1
-625
0
0
1
1
1
0
350
1
0
1
0
0
0
-600
0
0
1
1
1
1
375
1
0
1
0
0
1
-575
0
1
0
0
0
0
400
1
0
1
0
1
0
-550
0
1
0
0
0
1
425
1
0
0
1
0
450
1
0
1
0
1
1
-525
0
1
0
1
1
0
0
-500
0
1
0
0
1
1
475
1
0
1
1
0
1
-475
0
1
0
1
0
0
500
1
0
1
1
1
0
-450
0
1
0
1
0
1
525
1
0
1
1
1
1
-425
0
1
0
1
1
0
550
1
1
0
0
0
0
-400
0
1
0
1
1
1
575
1
1
0
0
0
1
-375
0
1
1
0
0
0
600
1
1
0
0
1
0
-350
0
1
1
0
0
1
625
1
1
0
1
0
650
1
1
0
0
1
1
-325
0
1
1
0
1
0
0
-300
0
1
1
0
1
1
675
1
1
0
1
0
1
-275
0
1
1
1
0
0
700
0
1
1
1
0
1
725
27
FN6880.1
April 29, 2010
ISL6324A
TABLE 8. BITS [5:0] REGISTER RGS1 and RGS2
(VOLTAGE MARGINING OFFSET) (Continued)
BIT5
BIT4
BIT3
BIT2
BIT1
BIT0
VO5
VO4
VO3
VO2
VO1
VO0
VOFFSET
(mV)
0
1
1
1
1
0
750
0
1
1
1
1
1
775
The bits for Register RGS3 control some of the functionality
of the ISL6324A for Power Savings Mode. Bits 0 and 1
control the number of phases that the ISL6324A will drop to
when in Power Savings Mode. Bits 2 and 3 control the
number of PWM cycles between adding of phases when
exiting Power Savings Mode. Bits 4 and 5 control the
number of PWM cycles between dropping of phases when
entering Power Savings Mode. Bit 6 will disable/enable the
Core DAC offset when in Power Savings Mode. Bit 7 is
reserved. See Table 9 for a complete description of register
RGS3 bits and their functionality.
TABLE 9. BITS [7:0] REGISTER RGS3
Bit 7
Reserved
Bit 6
Core DAC Offset
0
ENABLED
1
DISABLED
Bits [5:4] Number of PWM Cycles Between Dropping Phases
00
1 PWM Cycle (default)
01
2 PWM Cycles
10
4 PWM Cycles
11
0 PWM Cycles (All Phases Drop at Once)
Bits [3:2]
Number of PWM Cycles Between Adding Phases
00
1 PWM Cycle (Default)
01
2 PWM Cycles
10
4 PWM Cycles
11
0 PWM Cycles (All Phases Added at Once)
Bits [1:0]
Number of Phases Active in Power Savings Mode
00
1 Phase
01
2 Phases (Default)
1X
3 Phases
General Design Guide
This design guide is intended to provide a high-level
explanation of the steps necessary to create a multi-phase
power converter. It is assumed that the reader is familiar with
many of the basic skills and techniques referenced in the
following sections. In addition to this guide, Intersil provides
complete reference designs that include schematics, bills of
materials, and example board layouts for all common
microprocessor applications.
28
Power Stages
The first step in designing a multi-phase converter is to
determine the number of phases. This determination depends
heavily on the cost analysis which in turn depends on system
constraints that differ from one design to the next. Principally,
the designer will be concerned with whether components can
be mounted on both sides of the circuit board, whether
through-hole components are permitted, the total board space
available for power-supply circuitry, and the maximum amount
of load current. Generally speaking, the most economical
solutions are those in which each phase handles between
25A and 30A. All surface-mount designs will tend toward the
lower end of this current range. If through-hole MOSFETs and
inductors can be used, higher per-phase currents are
possible. In cases where board space is the limiting
constraint, current can be pushed as high as 40A per phase,
but these designs require heat sinks and forced air to cool the
MOSFETs, inductors and heat dissipating surfaces.
MOSFETS
The choice of MOSFETs depends on the current each
MOSFET will be required to conduct, the switching frequency,
the capability of the MOSFETs to dissipate heat, and the
availability and nature of heat sinking and air flow.
LOWER MOSFET POWER CALCULATION
The calculation for power loss in the lower MOSFET is
simple, since virtually all of the loss in the lower MOSFET is
due to current conducted through the channel resistance
(rDS(ON)). In Equation 19, IM is the maximum continuous
output current, IP-P is the peak-to-peak inductor current (see
Equation 20), and d is the duty cycle (VOUT/VIN).
2
I L ( P – P ) ⋅ ( 1 – d ) (EQ. 19)
⎛ I M⎞ 2
P LOW, 1 = r DS ( ON ) ⋅ ⎜ -----⎟ ⋅ ( 1 – d ) + ---------------------------------------------12
⎝ N⎠
An additional term can be added to the lower-MOSFET loss
equation to account for additional loss accrued during the
dead time when inductor current is flowing through the
lower-MOSFET body diode. This term is dependent on the
diode forward voltage at IM, VD(ON), the switching
frequency, fS, and the length of dead times, td1 and td2, at
the beginning and the end of the lower-MOSFET conduction
interval respectively.
⎛I
⎞
⎛I
⎞
⎟
M I P – P⎟ ⋅ t
M I--------------P LOW, 2 = V D ( ON ) ⋅ f S ⋅ ⎜ -----+ ⎜ -----+ --------------– P + P-⎟ ⋅ t d2
d1
⎜
2 ⎠
⎝N
2 ⎠
⎝N
(EQ. 20)
The total maximum power dissipated in each lower MOSFET
is approximated by the summation of PLOW,1 and PLOW,2.
UPPER MOSFET POWER CALCULATION
In addition to rDS(ON) losses, a large portion of the upper
MOSFET losses are due to currents conducted across the
input voltage (VIN) during switching. Since a substantially
higher portion of the upper-MOSFET losses are dependent on
switching frequency, the power calculation is more complex.
FN6880.1
April 29, 2010
ISL6324A
Upper MOSFET losses can be divided into separate
components involving the upper-MOSFET switching times,
the lower-MOSFET body-diode reverse recovery charge, Qrr,
and the upper MOSFET rDS(ON) conduction loss.
When the upper MOSFET turns off, the lower MOSFET does
not conduct any portion of the inductor current until the
voltage at the phase node falls below ground. Once the
lower MOSFET begins conducting, the current in the upper
MOSFET falls to zero as the current in the lower MOSFET
ramps up to assume the full inductor current. In Equation 21,
the required time for this commutation is t1 and the
approximated associated power loss is PUP(1).
⎛ I M I P – P⎞ ⎛ t 2 ⎞
P UP( 2 ) ≈ V IN ⋅ ⎜ ----- – --------------⎟ ⋅ ⎜ ---- ⎟ ⋅ f S
2 ⎠ ⎝ 2⎠
⎝N
(EQ. 22)
Finally, the resistive part of the upper MOSFET is given in
Equation 24 as PUP(4).
2
(EQ. 24)
The total power dissipated by the upper MOSFET at full load
can now be approximated as the summation of the results
from Equations 21, 22, 23 and 24. Since the power
equations depend on MOSFET parameters, choosing the
correct MOSFETs can be an iterative process involving
repetitive solutions to the loss equations for different
MOSFETs and different switching frequencies.
Internal Bootstrap Device
All three integrated drivers feature an internal bootstrap
Schottky diode. Simply adding an external capacitor across
the BOOT and PHASE pins completes the bootstrap circuit.
The bootstrap function is also designed to prevent the
bootstrap capacitor from overcharging due to the large
negative swing at the PHASE node. This reduces voltage
stress on the boot to phase pins.
The bootstrap capacitor must have a maximum voltage
rating above PVCC + 4V and its capacitance value can be
chosen from Equation 25:
29
1.4
1.2
1.0
0.8
0.6
QGATE = 100nC
0.4
50nC
(EQ. 23)
I P – P2
⎛ I M⎞
P UP( 4 ) ≈ r DS ( ON ) ⋅ ⎜ -----⎟ ⋅ d + -------------12
⎝ N⎠
1.6
0.2
A third component involves the lower MOSFET
reverse-recovery charge, Qrr. Since the inductor current has
fully commutated to the upper MOSFET before the
lower-MOSFET body diode can recover all of Qrr, it is
conducted through the upper MOSFET across VIN. The
power dissipated as a result is PUP(3) as shown in
Equation 23.
P UP( 3 ) = V IN ⋅ Q rr ⋅ f S
where QG1 is the amount of gate charge per upper MOSFET
at VGS1 gate-source voltage and NQ1 is the number of
control MOSFETs. The ΔVBOOT_CAP term is defined as the
allowable droop in the rail of the upper gate drive.
(EQ. 21)
At turn-on, the upper MOSFET begins to conduct and this
transition occurs over a time t2. In Equation 22, the
approximate power loss is PUP(2).
(EQ. 25)
Q G1 • PVCC
Q GATE = ------------------------------------ • N Q1
V GS1
CBOOT_CAP (µF)
I M I P – P⎞ ⎛ t 1 ⎞
P UP( 1 ) ≈ V IN ⋅ ⎛ ----- ⋅ ⎜ ---- ⎟ ⋅ f
⎝ N- + ------------2 ⎠ ⎝ 2⎠ S
Q GATE
C BOOT_CAP ≥ -------------------------------------ΔV BOOT_CAP
20nC
0.0
0.0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
ΔVBOOT_CAP (V)
FIGURE 18. BOOTSTRAP CAPACITANCE vs BOOT RIPPLE
VOLTAGE
Gate Drive Voltage Versatility
The ISL6324A provides the user flexibility in choosing the
gate drive voltage for efficiency optimization. The controller
ties the upper and lower drive rails together. Simply applying
a voltage from 5V up to 12V on PVCC sets both gate drive
rail voltages simultaneously.
Package Power Dissipation
When choosing MOSFETs it is important to consider the
amount of power being dissipated in the integrated drivers
located in the controller. Since there are a total of three
drivers in the controller package, the total power dissipated
by all three drivers must be less than the maximum
allowable power dissipation for the QFN package.
Calculating the power dissipation in the drivers for a desired
application is critical to ensure safe operation. Exceeding the
maximum allowable power dissipation level will push the IC
beyond the maximum recommended operating junction
temperature of +125°C. The maximum allowable IC power
dissipation for the 7x7 QFN package is approximately 3.5W
at room temperature. See “Layout Considerations” on
page 36 for thermal transfer improvement suggestions.
When designing the ISL6324A into an application, it is
recommended that the following calculations is used to
ensure safe operation at the desired frequency for the
selected MOSFETs. The total gate drive power losses,
PQg_TOT, due to the gate charge of MOSFETs and the
FN6880.1
April 29, 2010
ISL6324A
integrated driver’s internal circuitry and their corresponding
average driver current can be estimated with Equations 26
and 27, respectively.
P Qg_TOT = P Qg_Q1 + P Qg_Q2 + I Q ⋅ VCC
(EQ. 26)
3
P Qg_Q1 = --- ⋅ Q G1 ⋅ PVCC ⋅ f SW ⋅ N Q1 ⋅ N PHASE
2
P Qg_Q2 = Q G2 ⋅ PVCC ⋅ f SW ⋅ N Q2 ⋅ N PHASE
3
+ Q G2 ⋅ N Q2⎞ ⋅ N PHASE ⋅ f SW + I Q (EQ. 27)
I DR = ⎛ --- ⋅ Q G1 ⋅ N
⎝2
⎠
Q1
In Equations 26 and 27, PQg_Q1 is the total upper gate drive
power loss and PQg_Q2 is the total lower gate drive power
loss; the gate charge (QG1 and QG2) is defined at the
particular gate to source drive voltage PVCC in the
corresponding MOSFET data sheet; IQ is the driver total
quiescent current with no load at both drive outputs; NQ1 and
NQ2 are the number of upper and lower MOSFETs per phase,
respectively; NPHASE is the number of active phases. The
IQ*VCC product is the quiescent power of the controller
without capacitive load and is typically 75mW at 300kHz.
PVCC
D
G
RLO1
RG1
CDS
RGI1
CGS
Q1
S
PHASE
FIGURE 19. TYPICAL UPPER-GATE DRIVE TURN-ON PATH
PVCC
D
CGD
RHI2
RLO2
G
LGATE
RG2
CDS
RGI2
CGS
P Qg_Q1
P BOOT = --------------------3
(EQ. 28)
R LO1
R HI1
⎛
⎞ P Qg_Q1
P DR_UP = ⎜ -------------------------------------- + ----------------------------------------⎟ ⋅ --------------------R
+
R
R
+
R
3
⎝ HI1
EXT1
LO1
EXT1⎠
R LO2
R HI2
⎛
⎞ P Qg_Q2
P DR_LOW = ⎜ -------------------------------------- + ----------------------------------------⎟ ⋅ --------------------R
+
R
R
+
R
2
⎝ HI2
EXT2
LO2
EXT2⎠
Q1
CGD
UGATE
P DR = P DR_UP + P DR_LOW + P BOOT + ( I Q ⋅ VCC )
R GI1
R EXT1 = R G1 + ------------N
BOOT
RHI1
The total gate drive power losses are dissipated among the
resistive components along the transition path and in the
bootstrap diode. The portion of the total power dissipated in
the controller itself is the power dissipated in the upper drive
path resistance (PDR_UP) the lower drive path resistance
(PDR_UP) and in the boot strap diode (PBOOT). The rest of
the power will be dissipated by the external gate resistors
(RG1 and RG2) and the internal gate resistors (RGI1 and
RGI2) of the MOSFETs. Figures 19 and 20 show the typical
upper and lower gate drives turn-on transition path. The total
power dissipation in the controller itself, PDR, can be roughly
estimated as Equation 28:
Q2
S
FIGURE 20. TYPICAL LOWER-GATE DRIVE TURN-ON PATH
R GI2
R EXT2 = R G2 + ------------N
Q2
Inductor DCR Current Sensing Component
Selection and RSET Value Calculation
With the single RSET resistor setting the value of the
effective internal sense resistors for both the North Bridge
and Core regulators, it is important to set the RSET value
and the inductor RC filter gain, K, properly. See “Continuous
Current Sampling” on page 13 and “Channel-Current
Balance” on page 14 for more details on the application of
the RSET resistor and the RC filter gain.
There are 3 separate cases to consider when calculating
these component values. If the system under design will
never utilize the North Bridge regulator and the ISL6323 will
always be in parallel mode, then follow the instructions for
Case 3 and only calculate values for Core regulator
components.
For all three cases, use the expected VID voltage that would
be used at TDC for Core and North Bridge for the VCORE
and VNB variables, respectively.
CASE 1
I NB
I Core
MAX
⋅ DCR NB < -------------------------- ⋅ DCR Core
N
MAX
(EQ. 29)
In Case 1, the DC voltage across the North Bridge inductor
at full load is less than the DC voltage across a single phase
of the Core regulator while at full load. Here, the DC voltage
across the Core inductors must be scaled down to match the
DC voltage across the North Bridge inductor, which will be
impressed across the ISEN_NB pins without any gain. Thus,
30
FN6880.1
April 29, 2010
ISL6324A
the R2 resistor for the North Bridge inductor RC filter is left
unpopulated and K = 1.
3. Calculate the value for the RSET resistor using
Equation 37:(Derived from Equation 18).
3. Choose a capacitor value for the North Bridge RC filter. A
0.1µF capacitor is a recommended starting point.
V IN – V CORE V CORE⎞
400 DCR CORE ⋅ K ⎛
R SET = ---------- ⋅ --------------------------------------- ⋅ ⎜ I OCP
+ ------------------------------------- ⋅ --------------------⎟
⋅ L CORE ⋅ f S
V IN ⎠
100μA ⋅ N
2
3
CORE
⎝
4. Calculate the value for resistor R1 using Equation 30:
Where: K = 1
L NB
R1
= -------------------------------------DCR NB ⋅ C NB
NB
(EQ. 30)
V IN – V NB V NB⎞
400 DCR NB ⋅ K ⎛
R SET = ---------- ⋅ ------------------------------ ⋅ ⎜ I OCP
+ ----------------------------- ⋅ -----------⎟
100μA
2
⋅ L NB ⋅ f S V IN ⎠
3
NB
⎝
(EQ. 38)
(EQ. 31)
6. Using Equation 32 (also derived from Equation 18),
calculate the value of K for the Core regulator.
100μA
N
3
K = ---------- ⋅ R SET ⋅ ------------------------------ ⋅ ----------------------------------------------------------------------------------------------------------V IN – N ⋅ V CORE V CORE
DCR CORE
400
I OCP
+ --------------------------------------------- ⋅ -------------------2 ⋅ L CORE ⋅ f S
V IN
CORE
(EQ. 32)
7. Choose a capacitor value for the Core RC filters. A 0.1µF
capacitor is a recommended starting point.
8. Calculate the values for R1 and R2 for Core.
Equations 33 and 34 will allow for their computation.
R2
Core
K = ---------------------------------------------R1
+ R2
(EQ. 33)
R1
⋅ R2
L Core
Core
Core
------------------------- = ---------------------------------------------⋅ C Core
DCR Core
+ R2
R1
Core
Core
(EQ. 34)
Core
Core
CASE 2
I NB
I Core
MAX
⋅ DCR NB > -------------------------- ⋅ DCR Core
N
MAX
(EQ. 35)
In Case 2, the DC voltage across the North Bridge inductor
at full load is greater than the DC voltage across a single
phase of the Core regulator while at full load. Here, the DC
voltage across the North Bridge inductor must be scaled
down to match the DC voltage across the Core inductors,
which will be impressed across the ISEN pins without any
gain. So, the R2 resistor for the Core inductor RC filters is
left unpopulated and K = 1.
1. Choose a capacitor value for the Core RC filter. A 0.1µF
capacitor is a recommended starting point.
2. Calculate the value for resistor R1:
R1
L Core
= -----------------------------------------------DCR
Core
Core ⋅ C Core
4. Using Equation 38 (also derived from Equation 18),
calculate the value of K for the North bridge regulator.
100μA
1
3
K = ---------- ⋅ R SET ⋅ --------------------- ⋅ -------------------------------------------------------------------------V IN – V NB V NB
DCR NB
400
I OCP
+ ----------------------------- ⋅ ----------NB 2 ⋅ L NB ⋅ f S V IN
5. Calculate the value for the RSET resistor using
Equation 31: (Derived from Equation 18).
Where: K = 1
(EQ. 36)
5. Choose a capacitor value for the North Bridge RC filter. A
0.1µF capacitor is a recommended starting point.
6. Calculate the values for R1 and R2 for North Bridge.
Equations 39 and 40 will allow for their computation.
R2
NB
K = ------------------------------------R1
+ R2
(EQ. 39)
R1
⋅ R2
L NB
NB
NB
--------------------= ------------------------------------- ⋅ C NB
DCR NB
+ R2
R1
NB
NB
(EQ. 40)
NB
NB
CASE 3
I NB
I Core
MAX
⋅ DCR NB = -------------------------- ⋅ DCR Core
N
MAX
(EQ. 41)
In Case 3, the DC voltage across the North Bridge inductor
at full load is equal to the DC voltage across a single phase
of the Core regulator while at full load. Here, the full scale
DC inductor voltages for both North Bridge and Core will be
impressed across the ISEN pins without any gain. So, the R2
resistors for the Core and North Bridge inductor RC filters
are left unpopulated and K = 1 for both regulators.
For this Case, it is recommended that the overcurrent trip
point for the North Bridge regulator be equal to the
overcurrent trip point for the Core regulator divided by the
number of core phases.
1. Choose a capacitor value for the North Bridge RC filter. A
0.1µF capacitor is a recommended starting point.
2. Calculate the value for the North Bridge resistor R1:
R1
NB
L NB
= -------------------------------------DCR NB ⋅ C NB
(EQ. 42)
3. Choose a capacitor value for the Core RC filter. A 0.1µF
capacitor is a recommended starting point.
4. Calculate the value for the Core resistor R1:
R1
31
(EQ. 37)
L Core
= -----------------------------------------------DCR
Core
Core ⋅ C Core
(EQ. 43)
FN6880.1
April 29, 2010
ISL6324A
5. Calculate the value for the RSET resistor using Equation 44:
V IN – V CORE V CORE⎞
400 DCR CORE ⋅ K ⎛
R SET = ---------- ⋅ --------------------------------------- ⋅ ⎜ I OCP
+ ------------------------------------- ⋅ --------------------⎟
⋅ L CORE ⋅ f S
V IN ⎠
100μA ⋅ N
2
3
CORE
⎝
(EQ. 44)
Where: K = 1
6. Calculate the OCP trip point for the North Bridge
regulator using Equation 45. If the OCP trip point is higher
than desired, then the component values must be
recalculated utilizing Case 1. If the OCP trip point is lower
than desired, then the component values must be
recalculated utilizing Case 2.
I OCP
V IN – V NB V NB
3
1
= 100μA ⋅ --------------------- ⋅ ⎛ ---------- ⋅ R SET⎞ + ----------------------------- ⋅ ----------⎝
⎠
2 ⋅ L NB ⋅ f S V IN
DCR NB 400
NB
(EQ. 45)
NOTE: The values of RSET must be greater than 20kΩ and
less than 80kΩ. For all of the 3 cases, if the calculated value
of RSET is less than 20kΩ, then either the OCP trip point
needs to be increased or the inductor must be changed to an
inductor with higher DCR. If the RSET resistor is greater than
80kΩ, then a value of RSET that is less than 80kΩ must be
chosen and a resistor divider across both North Bridge and
Core inductors must be set up with proper gain. This gain
will represent the variable “K” in all equations. It is also very
important that the RSET resistor be tied between the RSET
pin and the VCC pin of the ISL6323.
Inductor DCR Current Sensing Component Fine
Tuning
I
VIN
Due to errors in the inductance and/or DCR it may be
necessary to adjust the value of R1 and R2 to match the time
constants correctly. The effects of time constant mismatch
can be seen in the form of droop overshoot or undershoot
during the initial load transient spike, as shown in Figure 22.
Follow the steps below to ensure the RC and inductor
L/DCR time constants are matched accurately.
1. If the regulator is not utilizing droop, modify the circuit by
placing the frequency set resistor between FS and
Ground for the duration of this procedure.
2. Capture a transient event with the oscilloscope set to
about L/DCR/2 (sec/div). For example, with L = 1µH and
DCR = 1mΩ, set the oscilloscope to 500µs/div.
3. Record ΔV1 and ΔV2 as shown in Figure 22. Select new
values, R1(NEW) and R2(NEW) for the time constant
resistors based on the original values, R1(OLD) and
R2(OLD) using Equations 46 and 47.
ΔV 1
R 1 ( NEW ) = R 1 ( OLD ) ⋅ ---------ΔV 2
(EQ. 46)
ΔV 1
R 2 ( 1 ) ( NEW ) = R 2 ( OLD ) ⋅ ---------ΔV 2
(EQ. 47)
4. Replace R1 and R2 with the new values and check to see
that the error is corrected. Repeat the procedure if
necessary.
Ln
UGATE(n)
LGATE(n)
DCR
VOUT
+
VL(s)
VC(s)
R1
VOUT
COUT
-
+
INDUCTOR
ΔV1
-
DRIVER
ΔV2
L
MOSFET
ITRAN
C
ΔI
R2
ISL6323 INTERNAL CIRCUIT
In
FIGURE 22. TIME CONSTANT MISMATCH BEHAVIOR
Loadline Regulation Resistor
SAMPLE
-
VC(s)
RISEN
-
+
+
The loadline regulation resistor, labeled RFB in Figure 8,
sets the desired loadline required for the application.
Equation 48 can be used to calculate RFB.
ISENnISENn+
VCC
ISEN
RSET
RSET
V DROOP
MAX
R FB = --------------------------------------------------------------------I OUT
400
MAX DCR
---------- ⋅ -------------------------- ⋅ --------------- ⋅ K
N
R SET
3
(EQ. 48)
Where K is defined in Equation 7.
CSET
FIGURE 21. DCR SENSING CONFIGURATION
32
If no loadline regulation is required, FS resistor should be
tied between the FS pin and VCC. To choose the value for
FN6880.1
April 29, 2010
ISL6324A
RFB in this situation, please refer to “Compensation Without
Loadline Regulation” on page 33.
Compensation With Loadline Regulation
The load-line regulated converter behaves in a similar
manner to a peak current mode controller because the two
poles at the output filter L-C resonant frequency split with the
introduction of current information into the control loop. The
final location of these poles is determined by the system
function, the gain of the current signal, and the value of the
compensation components, RC and CC.
C2 (OPTIONAL)
RC
value of RC while observing the transient performance on an
oscilloscope until no further improvement is noted. Normally,
CC will not need adjustment. Keep the value of CC from
Equation 49 unless some performance issue is noted.
The optional capacitor C2, is sometimes needed to bypass
noise away from the PWM comparator (see Figure 23). Keep
a position available for C2, and be prepared to install a high
frequency capacitor of between 22pF and 150pF in case any
leading edge jitter problem is noted.
.
Case 1:
1
-------------------------------- > f 0
2⋅π⋅ L⋅C
2 ⋅ π ⋅ f 0 ⋅ V P-P ⋅ L ⋅ C
R C = R FB ⋅ ---------------------------------------------------------0.66 ⋅ V
CC
IN
COMP
0.66 ⋅ V IN
C C = ----------------------------------------------------2 ⋅ π ⋅ V P-P ⋅ R FB ⋅ f 0
FB
ISL6324A
RFB
Case 2:
V PP ⋅ ( 2 ⋅ π ) 2 ⋅ f 02 ⋅ L ⋅ C
R C = R FB ⋅ ----------------------------------------------------------------0.66 ⋅ V IN
VSEN
Select a target bandwidth for the compensated system, f0.
The target bandwidth must be large enough to assure
adequate transient performance, but smaller than 1/3 of the
per-channel switching frequency. The values of the
compensation components depend on the relationships of f0
to the L-C pole frequency and the ESR zero frequency. For
each of the following three, there is a separate set of
equations for the compensation components.
In Equation 49, L is the per-channel filter inductance divided
by the number of active channels; C is the sum total of all
output capacitors; ESR is the equivalent series resistance of
the bulk output filter capacitance; and VP-P is the
peak-to-peak sawtooth signal amplitude as described in the
“Electrical Specifications” table on page 6.
(EQ. 49)
0.66 ⋅ V IN
C C = -------------------------------------------------------------------------------------( 2 ⋅ π ) 2 ⋅ f 02 ⋅ V P-P ⋅ R FB ⋅ L ⋅ C
FIGURE 23. COMPENSATION CONFIGURATION FOR
LOAD-LINE REGULATED ISL6324A CIRCUIT
Since the system poles and zero are affected by the values
of the components that are meant to compensate them, the
solution to the system equation becomes fairly complicated.
Fortunately, there is a simple approximation that comes very
close to an optimal solution. Treating the system as though it
were a voltage-mode regulator, by compensating the L-C
poles and the ESR zero of the voltage mode approximation,
yields a solution that is always stable with very close to ideal
transient performance.
1
1
-------------------------------- ≤ f 0 < -----------------------------------2 ⋅ π ⋅ C ⋅ ESR
2⋅π⋅ L⋅C
Case 3:
1
f 0 > ------------------------------------2 ⋅ π ⋅ C ⋅ ESR
2 ⋅ π ⋅ f 0 ⋅ V P-P ⋅ L
R C = R FB ⋅ ---------------------------------------------0.66 ⋅ V IN ⋅ ESR
0.66 ⋅ V IN ⋅ ESR ⋅ C
C C = ----------------------------------------------------------------2 ⋅ π ⋅ V P-P ⋅ R FB ⋅ f 0 ⋅ L
Compensation Without Loadline Regulation
The non load-line regulated converter is accurately modeled
as a voltage-mode regulator with two poles at the L-C
resonant frequency and a zero at the ESR frequency. A
type-III controller, as shown in Figure 24, provides the
necessary compensation.
The first step is to choose the desired bandwidth, f0, of the
compensated system. Choose a frequency high enough to
assure adequate transient performance but not higher than 1/3
of the switching frequency. The type-III compensator has an
extra high-frequency pole, fHF. This pole can be used for added
noise rejection or to assure adequate attenuation at the error
amplifier high-order pole and zero frequencies. A good general
rule is to choose fHF = 10f0, but it can be higher if desired.
Choosing fHF to be lower than 10f0 can cause problems with
too much phase shift below the system bandwidth as shown in
Equation 50.
Once selected, the compensation values in Equation 49
assure a stable converter with reasonable transient
performance. In most cases, transient performance can be
improved by making adjustments to RC. Slowly increase the
33
FN6880.1
April 29, 2010
ISL6324A
C2
Case 2:
RC
1
1
-------------------------------- ≤ f 0 < -----------------------------------2 ⋅ π ⋅ C ⋅ ESR
2⋅π⋅ L⋅C
2
CC
2
V P-P ⋅ ( 2 ⋅ π ) ⋅ f 0 ⋅ L ⋅ C
R C = R FB ⋅ -----------------------------------------------------------------0.66 ⋅ V
COMP
(EQ. 51)
IN
0.66 ⋅ V IN
C C = -------------------------------------------------------------------------------------2
2
( 2 ⋅ π ) ⋅ f 0 ⋅ V P-P ⋅ R FB ⋅ L ⋅ C
FB
C1
ISL6324A
RFB
R1
Case 3:
VSEN
2 ⋅ π ⋅ f 0 ⋅ V P-P ⋅ L
R C = R FB ⋅ ---------------------------------------------0.66 ⋅ V IN ⋅ ESR
FIGURE 24. COMPENSATION CIRCUIT WITHOUT LOAD-LINE
REGULATION
.
C ⋅ ESR
R 1 = R FB ⋅ -------------------------------------------L ⋅ C – C ⋅ ESR
(EQ. 50)
L ⋅ C – C ⋅ ESR
C 1 = -------------------------------------------R FB
0.75 ⋅ V IN
C 2 = -------------------------------------------------------------------------------------------------------2
( 2 ⋅ π ) ⋅ f 0 ⋅ f HF ⋅ ( L ⋅ C ) ⋅ R FB ⋅ V P – P
2
V PP ⋅ ⎛ 2π⎞ ⋅ f 0 ⋅ f HF ⋅ L ⋅ C ⋅ R FB
⎝ ⎠
R C = ---------------------------------------------------------------------------------------0.75 ⋅ V ⋅ ( 2 ⋅ π ⋅ f HF ⋅ L ⋅ C – 1 )
IN
0.75 ⋅ V IN ⋅ ( 2 ⋅ π ⋅ f HF ⋅ L ⋅ C – 1 )
C C = -------------------------------------------------------------------------------------------------------( 2 ⋅ π ) 2 ⋅ f 0 ⋅ f HF ⋅ ( L ⋅ C ) ⋅ R FB ⋅ V P – P
In the solutions to the compensation equations, there is a
single degree of freedom. For the solutions presented in
Equation 51, RFB is selected arbitrarily. The remaining
compensation components are then selected according to
Equation 51.
In Equation 51, L is the per-channel filter inductance divided
by the number of active channels; C is the sum total of all
output capacitors; ESR is the equivalent-series resistance of
the bulk output-filter capacitance; and VP-P is the peak-topeak sawtooth signal amplitude as described in “Electrical
Specifications” on page 6.
Output Filter Design
Case 1:
1
-------------------------------- > f 0
2⋅π⋅ L⋅C
2 ⋅ π ⋅ f 0 ⋅ V P-P ⋅ L ⋅ C
R C = R FB ⋅ ---------------------------------------------------------0.66 ⋅ V IN
0.66 ⋅ V IN
C C = ----------------------------------------------------2 ⋅ π ⋅ V P-P ⋅ R FB ⋅ f 0
34
1
f 0 > ------------------------------------2 ⋅ π ⋅ C ⋅ ESR
0.66 ⋅ V IN ⋅ ESR ⋅ C
C C = ----------------------------------------------------------------2 ⋅ π ⋅ V P-P ⋅ R FB ⋅ f 0 ⋅ L
The output inductors and the output capacitor bank together
to form a low-pass filter responsible for smoothing the
pulsating voltage at the phase nodes. The output filter also
must provide the transient energy until the regulator can
respond. Because it has a low bandwidth compared to the
switching frequency, the output filter limits the system
transient response. The output capacitors must supply or
sink load current while the current in the output inductors
increases or decreases to meet the demand.
In high-speed converters, the output capacitor bank is usually
the most costly (and often the largest) part of the circuit.
Output filter design begins with minimizing the cost of this part
of the circuit. The critical load parameters in choosing the
output capacitors are the maximum size of the load step, ΔI,
the load-current slew rate, di/dt, and the maximum allowable
output-voltage deviation under transient loading, ΔVMAX.
Capacitors are characterized according to their capacitance,
ESR, and ESL (equivalent series inductance).
At the beginning of the load transient, the output capacitors
supply all of the transient current. The output voltage will
initially deviate by an amount approximated by the voltage
drop across the ESL. As the load current increases, the
voltage drop across the ESR increases linearly until the load
current reaches its final value. The capacitors selected must
have sufficiently low ESL and ESR so that the total output
voltage deviation is less than the allowable maximum.
Neglecting the contribution of inductor current and regulator
response, the output voltage initially deviates by an amount
as shown in Equation 52:
di
ΔV ≈ ESL ⋅ ----- + ESR ⋅ ΔI
dt
(EQ. 52)
The filter capacitor must have sufficiently low ESL and ESR
so that ΔV < ΔVMAX.
Most capacitor solutions rely on a mixture of high frequency
capacitors with relatively low capacitance in combination
with bulk capacitors having high capacitance but limited
high-frequency performance. Minimizing the ESL of the
FN6880.1
April 29, 2010
ISL6324A
high-frequency capacitors allows them to support the output
voltage as the current increases. Minimizing the ESR of the
bulk capacitors allows them to supply the increased current
with less output voltage deviation.
R T = 10
RT (kΩ)
100
(EQ. 53)
10
10k
Equation 54 gives the upper limit on L for the cases when
the trailing edge of the current transient causes a greater
output-voltage deviation than the leading edge. Equation 55
addresses the leading edge. Normally, the trailing edge
dictates the selection of L because duty cycles are usually
less than 50%. Nevertheless, both inequalities should be
evaluated, and L should be selected based on the lower of
the two results. In each equation, L is the per-channel
inductance, C is the total output capacitance, and N is the
number of active channels.
2 ⋅ N ⋅ C ⋅ VO
L ≤ --------------------------------- ⋅ ΔV MAX – ( ΔI ⋅ ESR )
( ΔI ) 2
(EQ. 54)
1.25 ⋅ N ⋅ C- ⋅ ΔV
⎛
⎞
L ≤ ---------------------------MAX – ( ΔI ⋅ ESR ) ⋅ ⎝ V IN – V O⎠
( ΔI ) 2
(EQ. 55)
Switching Frequency
There are a number of variables to consider when choosing the
switching frequency, as there are considerable effects on the
upper MOSFET loss calculation. These effects are outlined in
“MOSFETs” on page 28, and they establish the upper limit for
the switching frequency. The lower limit is established by the
requirement for fast transient response and small outputvoltage ripple as outlined in “Output Filter Design” on page 34.
Choose the lowest switching frequency that allows the
regulator to meet the transient-response requirements.
Switching frequency is determined by the selection of the
frequency-setting resistor, RT. Figure 25 and Equation 56
are provided to assist in selecting the correct value for RT.
100k
1M
10M
SWITCHING FREQUENCY (Hz)
FIGURE 25. RT vs SWITCHING FREQUENCY
Input Capacitor Selection
The input capacitors are responsible for sourcing the AC
component of the input current flowing into the upper
MOSFETs. Their RMS current capacity must be sufficient to
handle the AC component of the current drawn by the upper
MOSFETs which is related to duty cycle and the number of
active phases.
0.3
INPUT-CAPACITOR CURRENT (IRMS/IO)
Since the capacitors are supplying a decreasing portion of
the load current while the regulator recovers from the
transient, the capacitor voltage becomes slightly depleted.
The output inductors must be capable of assuming the entire
load current before the output voltage decreases more than
ΔVMAX. This places an upper limit on inductance.
35
(EQ. 56)
1k
The ESR of the bulk capacitors also creates the majority of
the output-voltage ripple. As the bulk capacitors sink and
source the inductor AC ripple current (see “Interleaving” on
page 11 and Equation 3), a voltage develops across the bulk
capacitor ESR equal to IC(P-P ) (ESR). Thus, once the output
capacitors are selected, the maximum allowable ripple
voltage, VP-P(MAX), determines the lower limit on the
inductance.
⎛V – N ⋅ V
⎞
OUT⎠ ⋅ V OUT
⎝ IN
L ≥ ESR ⋅ -------------------------------------------------------------------f S ⋅ V IN ⋅ V P – P( MAX )
[10.61 – ( 1.035 ⋅ log ( f S ) ) ]
IL(P-P) = 0
IL(P-P) = 0.25 IO
IL(P-P) = 0.5 IO
IL(P-P) = 0.75 IO
0.2
0.1
0
0
0.2
0.4
0.6
0.8
1.0
DUTY CYCLE (VO/VIN)
FIGURE 26. NORMALIZED INPUT-CAPACITOR RMS CURRENT
vs DUTY CYCLE FOR 4-PHASE CONVERTER
For a 4-phase design, use Figure 26 to determine the
input-capacitor RMS current requirement set by the duty
cycle, maximum sustained output current (IO), and the ratio
of the peak-to-peak inductor current (IL(P-P)) to IO. Select a
bulk capacitor with a ripple current rating which will minimize
the total number of input capacitors required to support the
RMS current calculated.
The voltage rating of the capacitors should also be at least
1.25x greater than the maximum input voltage. Figures 27
and 28 provide the same input RMS current information for
FN6880.1
April 29, 2010
ISL6324A
3-phase and two-phase designs respectively. Use the same
approach for selecting the bulk capacitor type and number.
Layout Considerations
MOSFETs switch very fast and efficiently. The speed with which
the current transitions from one device to another causes
voltage spikes across the interconnecting impedances and
parasitic circuit elements. These voltage spikes can degrade
efficiency, radiate noise into the circuit and lead to device
overvoltage stress. Careful component selection, layout, and
placement minimizes these voltage spikes. Consider, as an
example, the turnoff transition of the upper PWM MOSFET.
Prior to turnoff, the upper MOSFET was carrying channel
current. During the turn-off, current stops flowing in the upper
MOSFET and is picked up by the lower MOSFET. Any
inductance in the switched current path generates a large
voltage spike during the switching interval. Careful component
selection, tight layout of the critical components, and short, wide
circuit traces minimize the magnitude of voltage spikes.
INPUT-CAPACITOR CURRENT (IRMS/IO)
0.3
IL(P-P) = 0
IL(P-P) = 0.5 IO
IL(P-P) = 0.25 IO
IL(P-P)= 0.75 IO
0.2
0.1
0
0
0.2
0.4
0.6
0.8
DUTY CYCLE (VIN/VO)
FIGURE 27. NORMALIZED INPUT-CAPACITOR RMS
CURRENT FOR 3-PHASE CONVERTER
36
1.0
INPUT-CAPACITOR CURRENT (IRMS/IO)
Low capacitance, high-frequency ceramic capacitors are
needed in addition to the input bulk capacitors to suppress
leading and falling edge voltage spikes. The spikes result from
the high current slew rate produced by the upper MOSFET
turn on and off. Select low ESL ceramic capacitors and place
one as close as possible to each upper MOSFET drain to
minimize board parasitics and maximize suppression.
0.3
0.2
0.1
IL(P-P) = 0
IL(P-P) = 0.5 IO
IL(P-P) = 0.75 IO
0
0
0.2
0.4
0.6
0.8
1.0
DUTY CYCLE (VIN/VO)
FIGURE 28. NORMALIZED INPUT-CAPACITOR RMS
CURRENT FOR 2-PHASE CONVERTER
There are two sets of critical components in a DC/DC converter
using a ISL6324A controller. The power components are the
most critical because they switch large amounts of energy. Next
are small signal components that connect to sensitive nodes or
supply critical bypassing current and signal coupling.
The power components should be placed first, which include
the MOSFETs, input and output capacitors, and the inductors. It
is important to have a symmetrical layout for each power train,
preferably with the controller located equidistant from each.
Symmetrical layout allows heat to be dissipated equally
across all power trains. Equidistant placement of the controller
to the CORE and NB power trains it controls through the
integrated drivers helps keep the gate drive traces equally
short, resulting in equal trace impedances and similar drive
capability of all sets of MOSFETs.
When placing the MOSFETs try to keep the source of the upper
FETs and the drain of the lower FETs as close as thermally
possible. Input high-frequency capacitors, CHF, should be
placed close to the drain of the upper FETs and the source of
the lower FETs. Input bulk capacitors, CBULK, case size
typically limits following the same rule as the high-frequency
input capacitors. Place the input bulk capacitors as close to the
drain of the upper FETs as possible and minimize the distance
to the source of the lower FETs.
Locate the output inductors and output capacitors between the
MOSFETs and the load. The high-frequency output decoupling
capacitors (ceramic) should be placed as close as practicable
to the decoupling target, making use of the shortest connection
paths to any internal planes, such as vias to GND next or on the
capacitor solder pad.
FN6880.1
April 29, 2010
ISL6324A
The critical small components include the bypass capacitors
(CFILTER) for VCC and PVCC, and many of the components
surrounding the controller including the feedback network and
current sense components. Locate the VCC/PVCC bypass
capacitors as close to the ISL6324A as possible. It is especially
important to locate the components associated with the
feedback circuit close to their respective controller pins, since
they belong to a high-impedance circuit loop, sensitive to EMI
pick-up.
A multi-layer printed circuit board is recommended. Figure 28
shows the connections of the critical components for the
converter. Note that capacitors CIN and COUT could each
represent numerous physical capacitors. Dedicate one solid
layer, usually the one underneath the component side of the
board, for a ground plane and make all critical component
ground connections with vias to this layer. Dedicate another
solid layer as a power plane and break this plane into smaller
islands of common voltage levels. Keep the metal runs from the
PHASE terminal to output inductors short. The power plane
should support the input power and output power nodes. Use
copper filled polygons on the top and bottom circuit layers for
the phase nodes. Use the remaining printed circuit layers for
small signal wiring.
Routing UGATE, LGATE, and PHASE Traces
Great attention should be paid to routing the UGATE, LGATE,
and PHASE traces since they drive the power train MOSFETs
using short, high current pulses. It is important to size them as
large and as short as possible to reduce their overall
impedance and inductance. They should be sized to carry at
least one ampere of current (0.02” to 0.05”). Going between
layers with vias should also be avoided, but if so, use two vias
for interconnection when possible.
Extra care should be given to the LGATE traces in particular
since keeping their impedance and inductance low helps to
significantly reduce the possibility of shoot-through. It is also
important to route each channels UGATE and PHASE traces
in as close proximity as possible to reduce their inductances.
Current Sense Component Placement and Trace
Routing
One of the most critical aspects of the ISL6324A regulator
layout is the placement of the inductor DCR current sense
components and traces. The R-C current sense components
must be placed as close to their respective ISEN+ and
ISEN- pins on the ISL6324A as possible.
The sense traces that connect the R-C sense components to
each side of the output inductors should be routed on the
bottom of the board, away from the noisy switching
components located on the top of the board. These traces
should be routed side by side, and they should be very thin
traces. It’s important to route these traces as far away from
any other noisy traces or planes as possible. These traces
should pick up as little noise as possible.
Thermal Management
For maximum thermal performance in high current, high
switching frequency applications, connecting the thermal GND
pad of the ISL6324A to the ground plane with multiple vias is
recommended. This heat spreading allows the part to achieve
its full thermal potential. It is also recommended that the
controller be placed in a direct path of airflow if possible to help
thermally manage the part.
All Intersil U.S. products are manufactured, assembled and tested utilizing ISO9000 quality systems.
Intersil Corporation’s quality certifications can be viewed at www.intersil.com/design/quality
Intersil products are sold by description only. Intersil Corporation reserves the right to make changes in circuit design, software and/or specifications at any time without
notice. Accordingly, the reader is cautioned to verify that data sheets are current before placing orders. Information furnished by Intersil is believed to be accurate and
reliable. However, no responsibility is assumed by Intersil or its subsidiaries for its use; nor for any infringements of patents or other rights of third parties which may result
from its use. No license is granted by implication or otherwise under any patent or patent rights of Intersil or its subsidiaries.
For information regarding Intersil Corporation and its products, see www.intersil.com
37
FN6880.1
April 29, 2010
ISL6324A
RFB
C2
+12V
+12V
CC
RC
FB
VSEN
COMP
CIN
R3_2
CBOOT
C3
BOOT1
ISEN3+
ISEN3-
CBOOT
CIN
BOOT1
R3_1
UGATE1
UGATE1
PWM3
PHASE1
PHASE1
RAPA
R1_1
CAPA
C1
LGATE1
LGATE1
APA
PGND
ISEN1ISEN1+
DVC
ISL6614
+12V
V_CORE
+5V
PVCC1_2
CFILTER
PWM1
R1_2
VCC
+12V
CIN
CFILTER
CIN
CBOOT
CBULK
CFILTER
CHF
UGATE2
UGATE2
RFS
VCC
PVCC
CBOOT
BOOT2
FS
BOOT2
+12V
GND
PHASE2
CPU
LOAD
PHASE2
RSET
C2
C4
R2_2
R4_2
R2_1
VFIXEN
SEL
SVD
ISEN2ISEN2+
SVC
VID4
VID5
PWROK
RGND
VDDPWRGD
ISEN4+
GND
ISEN4-
SCL
SDA
+12V
PWM4
ISL6324A
REN1
OFF
+12V
KEY
HEAVY TRACE ON CIRCUIT PLANE LAYER
PVCC_NB
CIN
CFILTER
EN
ISLAND ON POWER PLANE LAYER
ISLAND ON CIRCUIT PLANE LAYER
CBOOT_NB
ON
LGATE2
LGATE2
RSET
NC
NC
PWM2
R4_1
BOOT_NB
REN2
VIA CONNECTION TO GROUND PLANE
UGATE_NB
V_NB
PHASE_NB
R1_NB
LGATE_NB
ISEN_NBCOMP_NB
ISEN_NB+
FB_NB
C2_NB
RC_NB
CC_NB
C1_NB
CBULK
CHF
R2_NB
RED COMPONENTS:
LOCATE CLOSE TO IC TO
MINIMIZE CONNECTION PATH
NB
LOAD
BLUE COMPONENTS:
LOCATE NEAR LOAD
(MINIMIZE CONNECTION PATH)
MAGENTA COMPONENTS:
LOCATE CLOSE TO SWITCHING TRANSISTORS
(MINIMIZE CONNECTION PATH)
RFB_NB
FIGURE 29. PRINTED CIRCUIT BOARD POWER PLANES AND ISLANDS
38
FN6880.1
April 29, 2010
ISL6324A
Package Outline Drawing
L48.7x7
48 LEAD QUAD FLAT NO-LEAD PLASTIC PACKAGE
Rev 4, 10/06
4X 5.5
7.00
A
44X 0.50
B
37
6
PIN 1
INDEX AREA
6
PIN #1 INDEX AREA
48
1
7.00
36
4. 30 ± 0 . 15
12
25
(4X)
0.15
13
24
0.10 M C A B
48X 0 . 40± 0 . 1
TOP VIEW
4 0.23 +0.07 / -0.05
BOTTOM VIEW
SEE DETAIL "X"
( 6 . 80 TYP )
(
0.10 C
BASE PLANE
0 . 90 ± 0 . 1
4 . 30 )
C
SEATING PLANE
0.08 C
SIDE VIEW
( 44X 0 . 5 )
C
0 . 2 REF
5
( 48X 0 . 23 )
( 48X 0 . 60 )
0 . 00 MIN.
0 . 05 MAX.
TYPICAL RECOMMENDED LAND PATTERN
DETAIL "X"
NOTES:
1. Dimensions are in millimeters.
Dimensions in ( ) for Reference Only.
2. Dimensioning and tolerancing conform to AMSE Y14.5m-1994.
3. Unless otherwise specified, tolerance : Decimal ± 0.05
4. Dimension b applies to the metallized terminal and is measured
between 0.15mm and 0.30mm from the terminal tip.
5. Tiebar shown (if present) is a non-functional feature.
6. The configuration of the pin #1 identifier is optional, but must be
located within the zone indicated. The pin #1 indentifier may be
either a mold or mark feature.
39
FN6880.1
April 29, 2010