INTERSIL ISL6265C_10

ISL6265C
Features
The ISL6265C is a multi-output controller with embedded
gate drivers. A single-phase controller powers the
Northbridge (VDDNB) portion of the CPU. The two
remaining controller channels can be configured for
two-phase or individual single-phase outputs. For
uniplane CPU applications, the ISL6265C is configured as
a two-phase buck converter. This allows the controller to
interleave channels to effectively double the output
voltage ripple frequency, and thereby reduce output
voltage ripple amplitude with fewer components, lower
component cost, reduced power dissipation, and smaller
area. For dual-plane processors, the ISL6265C can be
configured as independent single-phase controllers
powering VDD0 and VDD1.
• Core Configuration Flexibility
- Dual Plane, Single-Phase Controllers
- Uniplane, Two-Phase Controller
The heart of the ISL6265C is the patented R3
Technology™, Intersil’s Robust Ripple Regulator
modulator. Compared with the traditional buck regulator,
the R3 Technology™ has a faster transient response. This
is due to the R3 modulator commanding variable
switching frequency during a load transient.
The Serial VID Interface (SVI) allows dynamic
adjustment of the Core and Northbridge output voltages
independently and in combination from 0.500V to 1.55V.
Core and Northbridge output voltages achieve a 0.5%
system accuracy over-temperature.
A unity-gain differential amplifier is provided for remote
CPU die sensing. This allows the voltage on the CPU die
to be accurately regulated per AMD mobile CPU
specifications. Core output current sensing is realized
using lossless inductor DCR sensing. All outputs feature
overcurrent, overvoltage and undervoltage protection.
• Precision Voltage Regulators
- 0.5% System Accuracy Over-temperature
• Voltage Positioning with Adjustable Load Line and Offset
• Internal Gate Drivers with 2A Driving Capability
• Differential Remote CPU Die Voltage Sensing
• Core Differential Current Sensing: DCR or Resistor
• Northbridge Lossless rDS(ON) Current Sensing
• Serial VID Interface
- Two Wire Clock and Data Bus
- Supports High-Speed I2C
- 0.500V to 1.55V in 12.5mV Steps
- Supports PSI_L Power-Saving Mode
• Core Outputs Feature Phase Shedding with PSI_L
• Adjustable Output-Voltage Offset
• Digital Soft-Start of all Outputs
• User Programmable Switching Frequency
• Static and Dynamic Current Sharing (Uniplane Core)
• Overvoltage, Undervoltage, and Overcurrent Protection
• Pb-Free (RoHS compliant)
Applications*(see page 26)
• AMD Griffin Platform CPU
• Notebook Core/GPU Voltage Regulators
Related Literature*(see page 26)
• See FN6884 for “Multi-Output Controller with Integrated
MOSFET Drivers for AMD SVI Capable Mobile CPUs”
POWER
STAGE
ISL6265C
POWER
STAGE
CORE_0
CORE_1
NORTHBRIDGE
Simplified System Diagram
POWER
STAGE
July 28, 2010
FN6976.1
1
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. 2010. All Rights Reserved
All other trademarks mentioned are the property of their respective owners.
ISL6265C
Multi-Output Controller with Integrated MOSFET
Drivers for AMD SVI Capable Mobile CPUs
ISL6265C
Functional Block Diagram
RTN_NB
COMP_NB FSET_NB
FB_NB
VSEN_NB
PVCC
IFSET_NB
VNB
1.5kΩ
SVC
PWROK
NO DROOP
PSI_L
I_OFS
VREF_NB
VREF0
SVI
INTERFACE
AND DAC
SVD
1.5kW
1
BOOT_NB
3.0kΩ
FLT
MODULATOR
NB
E/A
VREF_NB
MOSFET
DRIVER
PHASE_NB
SHOOT-THRU
PROTECTION
LGATE_NB
DE MODE
PGND_NB
VIN
VREF1
OFS/FIXEN
UGATE_NB
PSI_L
PVCC
VCC
OCSET_NB
FLT
VNB
RTN1
V0
V1
ISEN0
ISEN1
FAULT
PROTECTION
OCSET
RBIAS
VW0
POWER-ON
RESET AND
SOFT-START
LOGIC
ENABLE
PGOOD
GND
MODE
PVCC
IVW0
COMP0
BOOT0
FB0
FLT
E/A
I_OFS
VDIFF0
VSEN0
VREF0
ISN0
VIN
V0
1
RTN0
ISP0
℘
NO
DROOP
ISEN0
ISN1
VSEN1
MODULATOR
CORE
CURRENT
SENSE
CURRENT
SENSE
ISEN1
CURRENT
BALANCE
PHASE0
SHOOT-THRU
PROTECTION
LGATE0
DE MODE
PGND0
PVCC
UGATE1
MODE
℘
PSI_L
BOOT1
VREF1
RTN1
VDIFF1
MOSFET
DRIVER
FLT
NO
DROOP
V1
1
UGATE0
MODE
MODE
ISP1
VIN
MOSFET
DRIVER
PHASE1
SHOOT-THRU
PROTECTION
LGATE1
DE MODE
PGND1
E/A
I_OFS
PSI_L
IVW1
FB1
COMP1
VW1
FIGURE 1. SIMPLIFIED FUNCTIONAL BLOCK DIAGRAM OF ISL6265C
2
FN6976.1
July 28, 2010
ISL6265C
Ordering Information
PART
MARKING
PART NUMBER (Note)
TEMP RANGE
(°C)
PACKAGE
(Pb-Free)
PKG. DWG. #
ISL6265CHRTZ
6265C HRTZ
-10 to +100
48 Ld 6x6 TQFN
L48.6x6
ISL6265CHRTZ-T
6265C HRTZ
-10 to +100
48 Ld 6x6 TQFN
Tape and Reel
L48.6x6
1. Please refer to TB347 for details on reel specifications.
2. 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.
3. For Moisture Sensitivity Level (MSL), please see device information page for ISL6265C. For more information on MSL please
see techbrief TB363.
Pin Configuration
UGATE_NB
PHASE_NB
LGATE_NB
PGND_NB
OCSET_NB
RTN_NB
VSEN_NB
FSET_NB
COMP_NB
FB_NB
VCC
VIN
ISL6265C
(48 LD TQFN)
TOP VIEW
48 47 46 45 44 43 42 41 40 39 38 37
36 BOOT_NB
35 BOOT0
OFS/VFIXEN 1
PGOOD 2
34 UGATE0
33 PHASE0
PWROK 3
SVD 4
SVC 5
32 PGND0
31 LGATE0
49
GND
[BOTTOM]
ENABLE 6
RBIAS 7
30 PVCC
29 LGATE1
OCSET 8
28 PGND1
27 PHASE1
VDIFF0 9
FB0 10
26 UGATE1
25 BOOT1
COMP0 11
VW0 12
ISN1
VW1
ISP1
COMP1
VDIFF1
FB1
RTN1
VSEN1
RTN0
VSEN0
ISP0
3
ISN0
13 14 15 16 17 18 19 20 21 22 23 24
FN6976.1
July 28, 2010
ISL6265C
Pin Descriptions
PIN(s)
SYMBOL(s)
DESCRIPTION
1
OFS/VFIXEN
A resistor from this pin to GND programs a DC current source, which generates a positive
offset voltage across the resistor between FB and VDIFF pins. In this case, the OFS pin
voltage is +1.2V and VFIX mode is not enabled. If OFS is pulled up to +3.3V, VFIX mode
is enabled, the DAC decodes the SVC and SVD inputs to determine the programmed
voltage, and the OFS function is disabled. If OFS is pulled up to +5V, the OFS function
and VFIX mode are disabled.
2
PGOOD
Controller power-good open-drain output. This pin is typically pulled up externally by a
2.0kΩ resistor to +3.3V. During normal operation, this pin indicates whether all output
voltages are within specified overvoltage and undervoltage limits and no overcurrent
condition is present. If any output voltage exceeds these limits or a reset event occurs,
the pin is pulled low. This pin is always low prior to the end of soft-start.
3
PWROK
System power good input. When this pin is high, the SVI interface is active and I2C
protocol is running. While this pin is low, the SVC, SVD, and VFIXEN input states
determine the pre-PWROK metal VID or VFIX mode voltage. This pin must be low prior
to the ISL6265C PGOOD output going high per the AMD SVI Controller Guidelines.
4
SVD
This pin is the serial VID data bidirectional signal to and from the master device on the
AMD processor.
5
SVC
This pin is the serial VID clock input from the AMD processor.
6
ENABLE
7
RBIAS
A 117kΩ resistor from RBIAS to GND sets internal reference currents. The addition of
capacitance to this pin must be avoided and can create instabilities in operation.
8
OCSET
CORE_0 and CORE_1 common overcurrent protection selection input. The voltage on this
pin sets the (ISPx - ISNx) voltage limit for OC trip.
9, 19
VDIFF0, VDIFF1
10, 20
FB0, FB1
11, 21
COMP0, COMP1
The output of the CORE_0 and CORE_1 controller error amplifiers respectively. FBx,
VDIFFx, and COMPx pins are tied together through external R-C networks to compensate
the regulator
12, 22
VW0, VW1
A resistor from this pin to corresponding COMPx pin programs the switching frequency
(for example, 6.81k ~ 300kHz).
13, 14, 23, 24
ISP0, ISN0, ISP1,
ISN1
These pins are used for differentially sensing the corresponding channel output current.
The sensed current is used for channel balancing, protection, and core load line
regulation.
Connect ISN0 and ISN1 to the node between the RC sense elements surrounding the
inductor of their respective channel. Tie the ISP0 and ISP1 pins to the VCORE side of
their corresponding channel’s sense capacitor. These pins can also be used for discrete
resistor sensing.
15, 16
VSEN0, RTN0
Inputs to the CORE_0 VR controller precision differential remote sense amplifier. Connect
to the sense pins of the VDD0_FB[H,L] portion of the processor.
18, 17
VSEN1, RTN1
Inputs to the CORE_1 VR controller precision differential remote sense amplifier. Connect
to the sense pins of the VDD1_FB[H,L] portion of the processor. The RTN1 pin is also
used for detection of the VDD_PLANE_STRAP signal prior to enable.
30
PVCC
The power supply pin for the internal MOSFET gate drivers of the ISL6265C. Connect this
pin to a +5V power supply. Decouple this pin with a quality 1.0µF ceramic capacitor.
31, 29
LGATE0, LGATE1
Connect these pins to the corresponding lower MOSFET gate(s).
32, 28
PGND0, PGND1
The return path of the lower gate driver for CORE_0 and CORE_1 respectively. Connect
these pins to the corresponding sources of the lower MOSFETs.
33, 27
PHASE0, PHASE1
Switch node of the CORE_0 and CORE_1 controllers. Connect these pins to the sources
of the corresponding upper MOSFET(s). These pins are the return path for the upper
MOSFET drives.
4
Digital input enable. A high level logic signal on this pin enables the ISL6265C.
Output of the CORE_0 and CORE_1 differential amplifiers.
These pins are the output voltage feedback to the inverting input of the CORE_0 and
CORE_1 error amplifiers.
FN6976.1
July 28, 2010
ISL6265C
Pin Descriptions (Continued)
PIN(s)
SYMBOL(s)
DESCRIPTION
34, 26
UGATE0, UGATE1
Connect these pins to the corresponding upper MOSFET gate(s). These pins control the
upper MOSFET gate(s) and are monitored for shoot-through prevention.
35, 25
BOOT0, BOOT1
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 PVCC pin provide the necessary bootstrap charge.
36
BOOT_NB
This pin is the upper gate drive supply voltage for the Northbridge controller. Connect an
appropriately sized ceramic bootstrap capacitor between the BOOT_NB and PHASE_NB
pins. An internal bootstrap diode connected to the PVCC pin provides the necessary
bootstrap charge.
37
UGATE_NB
Upper MOSFET gate signal from Northbridge controller.
38
PHASE_NB
Switch node of the Northbridge controller. This pin should connect to the source of the
Northbridge channel upper MOSFET(s).
39
LGATE_NB
Lower MOSFET gate signal from Northbridge controller.
40
PGND_NB
The return path of the Northbridge controller lower gate driver. Connect this pin to the
source of the lower MOSFET(s).
41
OCSET_NB
Overcurrent protection selection input for the Northbridge controller. A resistor from this
pin to PHASE_NB sets the OC trip point.
43, 42
VSEN_NB, RTN_NB
Remote Northbridge voltage sense input and return. Connect isolated traces from these
pins to the Northbridge sense points of the processor.
44
FSET_NB
A resistor from this pin to GND programs the switching frequency of the Northbridge
controller (for example, 22.1k ~ 260kHz).
45
COMP_NB
This pin is the output of the Northbridge controller error amplifier.
46
FB_NB
47
VCC
The bias supply for the IC’s control circuitry. Connect this pin to a +5V supply and
decouple using a quality 0.1µF ceramic capacitor.
48
VIN
Battery supply voltage. It is used for input voltage feed-forward to improve the input line
transient performance.
-
GND
The bias and reference ground for the IC. The GND connection for the ISL6265C is
through the thermal pad on the bottom of the package.
5
This pin is the output voltage feedback to the inverting input of the Northbridge controller
error amplifier.
FN6976.1
July 28, 2010
ISL6265C
Simplified Application Circuit for Dual Plane and Northbridge Support
VIN
+5V
VCC PVCC
SVI DATA
SVD
SVI CLOCK
SVC
VIN
GND
+VIN
CIN
UGATE0
ENABLE
EN
PWROK
PWROK
BOOT0
VDDPWRGD
PGOOD
PHASE0
VSEN0
LGATE0
REMOTE
SENSE
RTN0
REMOTE
SENSE
LOUT
CORE
LOAD
PGND0
VSEN1
ISP0
RTN1
ISN0
VDD0
VDD_PLANE_STRAP
RBIAS
OFS/VFIXEN
OCSET
VDIFF0
+VIN
CIN
FB0
COMP0
UGATE1
ISL6265C
BOOT1
LOUT
VDD1
PHASE1
VW0
LGATE1
CORE
LOAD
PGND1
VDIFF1
ISP1
ISN1
+VIN
FB1
CIN
COMP1
UGATE_NB
BOOT_NB
VW1
FSET_NB
LOUT
VDDNB
PHASE_NB
LGATE_NB
PGND_NB
COMP_NB
NB
LOAD
OCSET_NB
VSEN_NB
FB_NB
RTN_NB
FIGURE 2. ISL6265C BASED DUAL-PLANE AND NORTHBRIDGE CONVERTERS WITH INDUCTOR DCR CURRENT
SENSING
6
FN6976.1
July 28, 2010
ISL6265C
Simplified Application Circuit for Uniplane Core and Northbridge Support
VIN
+5V
VCC PVCC
SVI DATA
SVD
SVI CLOCK
SVC
ENABLE
EN
PWROK
PWROK
VDDPWRGD
PGOOD
+VIN
CIN
UGATE0
BOOT0
LOUT
PHASE0
LGATE0
CORE
LOAD
PGND0
VSEN0
REMOTE
SENSE
GND
ISP0
RTN0
ISN0
REMOTE
SENSE
VSEN1
VDD_PLANE_STRAP
RTN1
RBIAS
OCSET
OFS/VFIXEN
VDD0
+VIN
VDIFF0
CIN
UGATE1
FB0
COMP0
BOOT1
ISL6265C
LOUT
PHASE1
LGATE1
VW0
CORE
LOAD
PGND1
ISP1
OPEN
VDIFF1
OPEN
FB1
OPEN
COMP1
OPEN
VW1
ISN1
+VIN
CIN
UGATE_NB
BOOT_NB
LOUT
VDDNB
PHASE_NB
FSET_NB
LGATE_NB
PGND_NB
COMP_NB
NB
LOAD
OCSET_NB
VSEN_NB
RTN_NB
FB_NB
FIGURE 3. ISL6265C BASED UNIPLANE AND NORTHBRIDGE CONVERTERS WITH INDUCTOR DCR CURRENT
SENSING
7
FN6976.1
July 28, 2010
ISL6265C
Simplified Application Circuit for Dual Layout
VIN
+5V
VCC PVCC
SVI DATA
SVD
SVI CLOCK
SVC
ENABLE
EN
PWROK
PWROK
VDDPWRGD
PGOOD
UGATE0
BOOT0
LOUT
PHASE0
VDD0
LGATE0
CORE
LOAD
PGND0
ISP0
RTN0
VDD_PLANE_STRAP
+1.8V
REMOTE
SENSE
CIN
VSEN0
REMOTE
SENSE
+VIN
GND
ISN0
RTN1
DNP UNIPLANE
VSEN1
RBIAS
UNIPLANE
VDD0
OCSET
OFS/VFIXEN
DNP
DUAL
PLANE
+VIN
VDIFF0
CIN
UGATE1
FB0
COMP0
BOOT1
ISL6265C
LOUT
PHASE1
LGATE1
VW0
VDD1
CORE
LOAD
PGND1
ISP1
POPULATION OPTIONAL IN UNIPLANE
VDIFF1
ISN1
+VIN
FB1
COMP1
CIN
UGATE_NB
BOOT_NB
VW1
FSET_NB
VDDNB
PHASE_NB
LGATE_NB
PGND_NB
COMP_NB
LOUT
NB
LOAD
OCSET_NB
VSEN_NB
RTN_NB
FB_NB
FIGURE 4. ISL6265C BASED UNIPLANE OR DUAL PLANE CORE CONVERTER WITH INDUCTOR DCR CURRENT
SENSING
8
FN6976.1
July 28, 2010
ISL6265C
Table of Contents
Simplified System Diagram................................ 1
Operation ........................................................ 18
Functional Block Diagram .................................. 2
Switching Frequency ......................................
Current Sense ...............................................
Selecting RBIAS For Core Outputs....................
Offset Resistor Selection.................................
Ordering Information ....................................... 3
Pin Configuration............................................... 3
Pin Descriptions ................................................ 4
18
18
19
19
Internal Driver Operation................................ 20
MOSFET Gate-Drive Outputs ........................... 20
Diode Emulation ............................................ 20
Simplified Application Circuit for Dual Plane and
Northbridge Support.......................................... 6
Power-Savings Mode ....................................... 20
Simplified Application Circuit for Uniplane Core
and Northbridge Support ................................... 7
Northbridge And Dual Plane Core ..................... 20
Uniplane Core ............................................... 20
Simplified Application Circuit for Dual Layout ... 8
Fault Monitoring and Protection ...................... 21
Absolute Maximum Ratings ............................ 10
Thermal Information ...................................... 10
Recommended Operating Conditions .............. 10
Electrical Specifications . ................................ 10
ISL6265C Gate Driver Timing Diagram ............ 13
Theory of Operation......................................... 13
Modulator ..................................................... 13
Initialization.................................................... 14
Power-On Reset ............................................. 14
Core Configuration ......................................... 14
Mode Selection .............................................. 14
Serial VID Interface......................................... 14
Pre-PWROK Metal VID.....................................
VFIX MODE ...................................................
SVI MODE .....................................................
VID-On-the-Fly Transition ...............................
SVI WIRE Protocol..........................................
SVI Bus Protocol ............................................
9
14
15
16
16
16
17
Power-Good Signal ........................................
Overcurrent Protection ...................................
Overvoltage Protection ...................................
Undervoltage Protection .................................
21
21
22
22
General Application Design Guide ................... 22
Selecting the LC Output Filter..........................
Selection of the Input Capacitor.......................
MOSFET Selection and Considerations ..............
Selecting The Bootstrap Capacitor....................
22
23
23
24
PCB Layout Considerations.............................. 24
Power and Signal Layers Placement on the PCB .
Component Placement ...................................
Signal Ground and Power Ground ....................
Routing and Connection Details .......................
Copper Size for the Phase Node.......................
24
24
25
25
25
Revision History .............................................. 26
Products.......................................................... 26
Package Outline Drawing ............................... 27
FN6976.1
July 28, 2010
ISL6265C
P
Absolute Maximum Ratings
Thermal Information
Supply Voltage, VCC, PVCC . . . . . . . . . . . . . . . . -0.3 - +7V
Battery Voltage, VIN . . . . . . . . . . . . . . . . . . . . . . . . . +28V
Boot Voltage (BOOT) . . . . . . . . . . . . . . . . . -0.3V to +33V
Boot to Phase Voltage (BOOT-PHASE) . . . . -0.3V to +7V(DC)
. . . . . . . . . . . . . . . . . . . . . . . . . . -0.3V to +9V (<10ns)
Phase Voltage (PHASE) . . . . -7V (<20ns Pulse Width, 10µJ)
UGATE Voltage (UGATE) . . . . . . PHASE -0.3V (DC) to BOOT
LGATE Voltage (LGATE) . . . . . . . -0.3V (DC) to VCC + 0.3V
ALL Other Pins . . . . . . . . . . . . . . . . . -0.3V to (VCC + 0.3V)
Open Drain Outputs, PGOOD . . . . . . . . . . . . . . -0.3 - +7V
Thermal Resistance (Typical, Notes 4, 5)θJA (°C/W)θJC (°C/W)
TQFN Package . . . . . . . . . . . . . . .
28
3.5
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
Supply Voltage, VCC, PVCC
Battery Voltage, VIN . . . . .
Ambient Temperature . . . .
Junction Temperature . . . .
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
. . . . . +5V ±5%
. . . . +6V to 24V
-10°C to +100°C
-10°C to +125°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:
4. 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.
5. For θJC, the “case temp” location is the center of the exposed metal pad on the package underside.
Electrical Specifications
PARAMETER
VCC = PVCC = 5V, VIN = 12V, TA = -10°C to +100°C, Unless Otherwise Specified. Boldface
limits apply over the operating temperature range, -10°C to +100°C.
MIN
(Note 6)
TYP
MAX
(Note 6)
UNITS
EN = 3.3V
-
7.8
10
mA
EN = 0V
-
-
1
µA
VCC PORr
VCC Rising
-
4.35
4.5
V
VCC PORf
VCC Falling
3.9
4.1
-
V
-
-
1
µA
-0.5
-
0.5
%
-5
-
+5
mV
1.15
1.17
1.19
V
SYMBOL
TEST CONDITIONS
INPUT POWER SUPPLY
+5V Supply Current
IVCC
POR (Power-On Reset)
Threshold
Battery Supply Current (VIN)
IVIN
EN = 0V, VIN = 24V
SYSTEM AND REFERENCES
System Accuracy
(Vcore0, Vcore1, Vcore_NB)
%Error
(VCORE)
No load, closed loop, active mode
VID = 0.75V to 1.55V
VID = 0.50V to 0.7375V
RBIAS Voltage
RRBIAS
RRBIAS = 117kΩ
Maximum Output Voltage
VCOREx
(max)
SVID = [000_0000b]
-
1.55
-
V
Minimum Output Voltage
VCOREx
(min)
SVID = [101_0100b]
-
0.500
-
V
VIN = 15.5V, VDAC = 1.55V,
VFB0 = 1.60V, force Vcomp_0 = 2V,
RVW = 6.81kΩ, 2-Phase Operation
285
300
315
kHz
RFSET_NB = 22.1kΩ, CFSET_NB = 1nF,
VDAC = 0.5V, Vsen_nb = 0.51V
285
300
315
kHz
Core Frequency Adjustment
Range
200
-
500
kHz
NB Frequency Adjustment
Range
200
-
500
kHz
-
90
-
dB
CHANNEL FREQUENCY
Nominal CORE Switching
Frequency
fSW_core0
Nominal NB Switching
Frequency
fSW_core_NB
AMPLIFIERS
Error Amp DC Gain (Note 7)
10
AV0
FN6976.1
July 28, 2010
ISL6265C
Electrical Specifications
PARAMETER
VCC = PVCC = 5V, VIN = 12V, TA = -10°C to +100°C, Unless Otherwise Specified. Boldface
limits apply over the operating temperature range, -10°C to +100°C. (Continued)
SYMBOL
Error Amp Gain-Bandwidth
Product (Note 7)
TEST CONDITIONS
MIN
(Note 6)
TYP
MAX
(Note 6)
UNITS
GBW
CL = 20pF
-
18
-
MHz
SR
CL = 20pF
-
5.0
-
V/µs
Di
-
4
-
mV
Input Bias Current
-
20
-
nA
RTN1 Threshold
-
0.8
-
V
1.25
1.875
2.50
mV/µs
5
7.5
10
mV/µs
Error Amp Slew Rate (Note 7)
CORE CURRENT SENSE
Current Imbalance Threshold
SOFT START/VID-ON-THE-FLY
Soft-Start Voltage Transition
VSS
VID on the Fly Transition
GATE DRIVER DRIVING CAPABILITY [CORE AND NB]
UGATE Source Resistance
(Note 8)
RSRC(UGATE) 500mA Source Current
-
1
1.5
Ω
UGATE Source Current (Note 8)
ISRC(UGATE)
VUGATE_PHASE = 2.5V
-
2
-
A
UGATE Sink Resistance (Note 8)
RSNK(UGATE) 500mA Sink Current
-
1
1.5
Ω
UGATE Sink Current (Note 8)
ISNK(UGATE)
-
2
-
A
LGATE Source Resistance
(Note 8)
RSRC(LGATE) 500mA Source Current
-
1
1.5
Ω
LGATE Source Current (Note 8)
ISRC(LGATE)
-
2
-
A
LGATE Sink Resistance (Note 8)
RSNK(LGATE) 500mA Sink Current
-
0.5
0.9
Ω
LGATE Sink Current (Note 8)
ISNK(LGATE)
-
4
-
A
UGATE to PHASE Resistance
Rp(UGATE)
-
1
-
kΩ
VUGATE_PHASE = 2.5V
VLGATE = 2.5V
VLGATE = 2.5V
GATE DRIVER SWITCHING TIMING (Refer to “ISL6265C Gate Driver Timing Diagram” on page 13)
UGATE Rise Time (Note 7)
tRU
PVCC = 5V, 3nF Load
-
8.0
-
ns
LGATE Rise Time (Note 7)
tRL
PVCC = 5V, 3nF Load
-
8.0
-
ns
UGATE Fall Time (Note 7)
tFU
PVCC = 5V, 3nF Load
-
8.0
-
ns
LGATE Fall Time (Note 7)
tFL
PVCC = 5V, 3nF Load
-
4.0
-
ns
UGATE Turn-on Propagation
Delay
tPDHU
PVCC = 5V, Outputs Unloaded
-
36
-
ns
LGATE Turn-on Propagation
Delay
tPDHL
PVCC = 5V, Outputs Unloaded
-
20
-
ns
0.43
0.58
0.67
V
-
-
5
µA
-
0.2
0.5
V
-1
-
1
µA
BOOTSTRAP DIODE
Forward Voltage
VDDP = 5V, Forward Bias
Current = 2mA
Leakage
VR = 16V
POWER-GOOD AND PROTECTION MONITOR
PGOOD Low Voltage
VOL
IPGOOD = 4mA
PGOOD Leakage Current
IOH
PGOOD = 5V
PGOOD High After Soft-Start
Enable to PGOOD High, VCOREx = 1.1V
570
700
1010
µs
PGOOD Low After Fault
Fault to PGOOD Low
160
208
250
µs
VCOREx falls below set-point for 208µs
240
295
350
mV
Undervoltage Threshold
UVH
11
FN6976.1
July 28, 2010
ISL6265C
Electrical Specifications
PARAMETER
VCC = PVCC = 5V, VIN = 12V, TA = -10°C to +100°C, Unless Otherwise Specified. Boldface
limits apply over the operating temperature range, -10°C to +100°C. (Continued)
SYMBOL
Overvoltage Threshold
OVHS
TEST CONDITIONS
VO rising above threshold > 0.5µs
MIN
(Note 6)
TYP
MAX
(Note 6)
UNITS
1.770
1.800
1.825
V
5
6.0
7
mV
9.2
10
10.8
µA
1.18
1.2
1.22
V
9.0
9.9
10.8
µA
OVERCURRENT PROTECTION VDD0 AND VDD1
OCSET Reference Voltage
(VISPx - VISNx)
VOCSET = 180mV; VIN = 15.5V
OVERCURRENT PROTECTION VDD_NB
OCSET_NB OCP Current
RBIAS pin to GND = 117kΩ; Trips after
8 PWM cycles
OFFSET FUNCTION
OFS Pin Voltage For Droop
Enabling
VOFS
FB Pin Source Current
IFB
ROFS = 240kΩ (OFS pin to GND)
IOFS = =10µA
OFS Pin Voltage Threshold for
VFIX Mode and No Droop
Operation
VOFS
-
1.8
-
V
OFS Pin Voltage Threshold for
SVI Mode and No Droop
Operation
VOFS
-
4.0
-
V
OFS Bias
IOFS
-
4.0
-
µA
1.8V < OFS < VCC
LOGIC INPUTS
ENABLE Low Threshold
VIL(3.3V)
-
1.35
0.9
V
ENABLE High Threshold
VIH(3.3V)
2.0
1.6
-
V
-1
0
-
µA
-
0
1
µA
PWROK Input Low Threshold
-
0.65
0.8
V
PWROK Input High Threshold
-
0.9
-
V
SVC, SVD Input HIGH (VIH)
1.05
0.87
-
V
SVC, SVD Input LOW (VIL)
-
0.68
0.45
V
Schmitt Trigger Input
Hysteresis
-
0.19
-
V
ENABLE Leakage Current
Logic input is low
Logic input is high at 3.3V
SVI INTERFACE
SVD Low Level Output Voltage
3mA Sink Current
-
0.1
0.285
V
SVC, SVD Leakage
EN = 0V, SVC, SVD = 0V
-
< -100
-
nA
EN = 5V, SVC, SVD = 1.8V
-
< -100
-
nA
-2
-
2
mV
DIFF AMP
Accuracy
VSEN = 0.5V to 1.55V; RTN = 0 ±0.1V
NOTES:
6. 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
7. Limits should be considered typical and are not production tested.
8. Limits established by characterization and are not production tested.
12
FN6976.1
July 28, 2010
ISL6265C
ISL6265C Gate Driver Timing Diagram
PWM
tPDHU
tFU
tRU
1V
UGATE
LGATE
1V
tFL
tRL
tPDHL
Theory of Operation
Modulator
The ISL6265C is a flexible multi-output controller
supporting Northbridge and single or dual power planes
required by Class M AMD Mobile CPUs. In single plane
applications, both core voltage regulators operate
single-phase. In uniplane core applications, the core
voltage regulators are configured to operate as a
two-phase regulator. All three regulator outputs include
integrated gate drivers for reduced system cost and
small board area. The regulators provide optimum
steady-state and transient performance for
microprocessor applications. System efficiency is
enhanced by idling a phase in uniplane configurations at
low-current and implementing automatic DCM-mode
operation when PSI_L is asserted to logic low.
The ISL6265C modulator features Intersil’s R3
technology, a hybrid of fixed frequency PWM control and
variable frequency hysteretic control (see Figure 5).
Intersil’s R3 technology can simultaneously affect the
PWM switching frequency and PWM duty cycle in
response to input voltage and output load transients. The
R3 modulator synthesizes an AC signal VR, which is an
analog representation of the output inductor ripple
current. The duty-cycle of VR is the result of charge and
discharge current through a ripple capacitor CR. The
current through CR is provided by a transconductance
amplifier gm that measures the VIN and VO voltages. The
positive slope of VR can be written as determined by
Equation 1:
The heart of the ISL6265C is the R3 Technology™,
Intersil's Robust Ripple Regulator modulator. The R3
modulator combines the best features of fixed frequency
PWM and hysteretic PWM while eliminating many of their
shortcomings. The ISL6265C modulator internally
synthesizes an analog of the inductor ripple current and
uses hysteretic comparators on those signals to establish
PWM pulse widths. Operating on these large-amplitude,
noise-free synthesized signals allows the ISL6265C to
achieve lower output ripple and lower phase jitter than
either conventional hysteretic or fixed frequency PWM
controllers. Unlike conventional hysteretic converters,
the ISL6265C has an error amplifier that allows the
controller to maintain a 0.5% voltage regulation accuracy
throughout the VID range from 0.75V to 1.55V. Voltage
regulation accuracy is slightly wider, ±5mV, over the VID
range from 0.7375V to 0.5V.
V RPOS = ( g m ) ⋅ ( V IN – V OUT )
The hysteresis window voltage is relative to the error
amplifier output such that load current transients result
in increased switching frequency, which gives the R3
regulator a faster response than conventional fixed
frequency PWM controllers. In uniplane configurations,
transient load current is inherently shared between
active phases due to the use of a common hysteretic
window voltage. Individual average phase currents are
monitored and controlled to equally share current among
the active phases.
13
(EQ. 1)
The negative slope of VR can be written as determined by
Equation 2:
V RNEG = g m ⋅ V OUT
(EQ. 2)
Where gm is the gain of the transconductance amplifier.
A window voltage VW is referenced with respect to the
error amplifier output voltage VCOMP, creating an
envelope into which the ripple voltage VR is compared.
The amplitude of VW is set by a resistor connected across
the FSET and GND pins. The VR, VCOMP, and VW signals
feed into a window comparator in which VCOMP is the
lower threshold voltage and VW is the higher threshold
voltage. Figure 6 shows PWM pulses being generated as
VR traverses the VW and VCOMP thresholds. The PWM
switching frequency is proportional to the slew rates of
the positive and negative slopes of VR; it is inversely
proportional to the voltage between VW and VCOMP.
FN6976.1
July 28, 2010
ISL6265C
Core Configuration
.
VIN
PWM FREQUENCY
CONTROL
VO
+
gmVO
VR
+
-
+
R
PWM Q
S
-
+
VW
-
-
+
gmVIN
FSET
VCOMP
+
CR TO
PWM
CONTROL
ISL6265C
-
FIGURE 5. MODULATOR CIRCUITRY
The ISL6265C determines the core channel requirements
of the CPU based on the state of the RTN1 pin prior to
ENABLE. If RTN1 is low prior to ENABLE, both VDD0 and
VDD1 core planes are required. The core controllers
operate as independent single-phase regulators. RTN1 is
connected to the CPU Core1 negative sense point. For
single core CPU designs (uniplane), RTN1 is tied to a
+1.8V or greater supply. Prior to ENABLE, RTN1 is
detected as HIGH and the ISL6265C drives the core
controllers as a two-phase multi-phase regulator. Dual
purpose motherboard designs should include resistor
options to open the CPU Core1 negative sense and
connect the RTN1 pin to a pull-up resistor.
Mode Selection
RIPPLE CAPACITOR VOLTAGE CR
WINDOW VOLTAGE VW
ERROR AMPLIFIER VOLTAGE VCOMP
The OFS/VFIXEN pin selects between the AMD defined
VFIX and SVI modes of operation and enables droop if
desired in SVI mode only. If OFS/VFIXEN is tied to VCC,
then SVI mode with no droop on the core output(s) is
selected. Connected to +3.3V, VFIX mode is active with
no droop on the core output(s). SVI mode with droop is
enabled when OFS/VFIXEN is tied to ground through a
resistor sized to set the core voltage positive offset.
Further information is provided in “Offset Resistor
Selection” on page 19.
Serial VID Interface
PWM
FIGURE 6. MODULATOR WAVEFORMS DURING LOAD
TRANSIENT
Initialization
Once sufficient bias is applied to the VCC pin, internal
logic checks the status of critical pins to determine the
controller operation profile prior to ENABLE. These pins
include RTN1 which determines single vs two-phase
operation and OFS/VFIXEN for enabling/disabling the SVI
interface and core voltage droop. Depending on the
configuration set by these pins, the controller then
checks the state of the SVC and SVD pins to determine
the soft-start target output voltage level.
Power-On Reset
The ISL6265C requires a +5V input supply tied to VCC
and PVCC to exceed a rising power-on reset (POR)
threshold before the controller has sufficient bias to
guarantee proper operation. Once this threshold is
reached or exceeded, the ISL6265C has enough bias to
begin checking RTN1, OFS/VFIXEN, ENABLE, and SVI
inputs. Hysteresis between the rising the falling
thresholds assure the ISL6265C will not inadvertently
turn-off unless the bias voltage drops substantially (see
“Electrical Specifications” on page 12).
14
The on-board Serial VID Interface (SVI) circuitry allows
the processor to directly control the Core and
Northbridge voltage reference levels within the
ISL6265C. The SVC and SVD states are decoded
according to the PWROK and VFIXEN inputs as described
in the following sections. The ISL6265C 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.
Pre-PWROK Metal VID
Assuming the OFS/VFIXEN pin is not tied to +3.3V during
controller configuration, typical motherboard start-up
begins with the controller decoding the SVC and SVD
inputs to determine the pre-PWROK metal VID setting
(see Table 1). Once the enable input (EN) exceeds the
rising enable threshold, the ISL6265C decodes and locks
the decoded value in an on-board hold register.
The internal DAC circuitry begins to ramp Core and
Northbridge planes to the decoded pre-PWROK metal
VID output level. The digital soft-start circuitry ramps the
internal reference to the target gradually at a fixed rate
of approximately 2mV/µs. The controlled ramp of all
output voltage planes reduces in-rush current during the
soft-start interval. At the end of the soft-start interval,
the PGOOD output transitions high indicating all output
planes are within regulation limits.
FN6976.1
July 28, 2010
ISL6265C
VFIX MODE
TABLE 1. PRE-PWROK METAL VID CODES
SVC
SVD
OUTPUT VOLTAGE (V)
0
0
1.1
0
1
1.0
In VFIX Mode, the SVC and SVD levels fixed external to
the controller through jumpers to either GND or VDDIO.
These inputs are not expected to change. In VFIX mode,
the IC decodes the SVC and SVD states per Table 2.
1
0
0.9
TABLE 2. VFIXEN VID CODES
1
1
0.8
If the EN input falls below the enable falling threshold,
the ISL6265C tri-states all outputs. PGOOD is pulled low
with the loss of EN. The Core and Northbridge planes will
decay based on output capacitance and load leakage
resistance. If bias to VCC falls below the POR level, the
ISL6265C responds in the same manner previously
described. Once VCC and EN rise above their respective
rising thresholds, the internal DAC circuitry re-acquires a
pre-PWROK metal VID code and the controller
soft-starts.
1
2
3
4
5
SVC
SVD
OUTPUT VOLTAGE (V)
0
0
1.4
0
1
1.2
1
0
1.0
1
1
0.8
Once enabled, the ISL6265C begins to soft-start both
Core and Northbridge planes to the programmed VFIX
level. The internal soft-start circuitry slowly ramps the
reference up to the target value. The same fixed internal
rate of approximately 2mV/µs results in a controlled
ramp of the power planes. Once soft-start has ended and
all output planes are within regulation limits, the PGOOD
pin transitions high.
6
7
8
9
10
11
12
VCC
SVC
SVD
ENABLE
PWROK
METAL_VID
DD AND VDDNB
V_SVI
METAL_VID
V_SVI
VDDPWRGD
(PGOOD)
FIXEN
Interval 1 to 2: ISL6265C waits to POR.
Interval 2 to 3: SVC and SVD are externally set to pre-Metal VID code.
Interval 3 to 4: EN locks core output configuration and pre-Metal VID code. All outputs soft-start to this level.
Interval 4 to 5: PGOOD signal goes HIGH indicating proper operation.
Interval 5 to 6: CPU detects VDDPWRGD high and drives PWROK high to allow ISL6265C to prepare for SVI code.
Interval 6 to 7: SVC and SVD data lines communicate change in VID code.
Interval 7 to 8: ISL6265C responds to VID-ON-THE-FLY code change.
Interval 8 to 9: PWROK is driven low and ISL6265C returns all outputs to pre-PWROK Metal VID level.
Interval 9 to 10: PWROK driven high once again by CPU and ISL6265C prepares for SVI code.
Interval 10 to 11: SVC and SVD data lines communicate new VID code.
Interval 11 to 12: ISL6265C drives outputs to new VID code level.
Post 12 : Enable falls and all internal drivers are tri-stated and PGOOD is driven low.
FIGURE 7. SVI INTERFACE TIMING DIAGRAM: TYPICAL PRE-PWROK METAL VID STARTUP
15
FN6976.1
July 28, 2010
ISL6265C
In the same manner described in “Pre-PWROK Metal
VID” on page 14, the POR circuitry impacts the internal
driver operation and PGOOD status.
SVI MODE
Once the controller has successfully soft-started and
PGOOD transitions high, the processor can assert
PWROK to signal the ISL6265C to prepare for SVI
commands. The controller actively monitors the SVI
interface for set VID commands to move the plane
voltages 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 a set VID command is received, the ISL6265C
decodes the information to determine which output plane
is affected and the VID target required (see Table 3).The
internal DAC circuitry steps the required output plane
voltage to the new VID level. During this time, one or
more of the planes could be targeted. In the event either
core voltage plane, VDD0 or VDD1, is commanded to
power-off by serial VID commands, the PGOOD 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 Core and Northbridge 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 EN goes low during normal operation, all internal
drivers are tri-stated and PGOOD is pulled low. This
event clears the pre-PWROK metal VID code and forces
the controller to check SVC and SVD upon restart.
VID-On-the-Fly Transition
Once PWROK is high, the ISL6265C detects this flag and
begins monitoring the SVC and SVD pins for SVI
instructions. The microprocessor will follow the protocol
outlined in the following sections to send instructions for
VID-on-the-Fly transitions. The ISL6265C decodes the
instruction and acknowledges the new VID code. For VID
codes higher than the current VID level, the ISL6265C
begins stepping the required regulator output(s) to the
new VID target with a typical slew rate of 7.5mV/µs,
which meets the AMD requirements.
When the VID codes are lower than the current VID
level, the ISL6265C begins stepping the regulator output
to the new VID target with a typical slew rate of
-7.5mV/µs. Both Core and NB regulators are always in
CCM during a down VID transition. The AMD
requirements under these conditions do not require the
regulator to meet the minimum slew rate specification of
-5mV/µs. In either case, the slew rate is not allowed to
exceed 10mV/µs. The ISL6265C does not change the
state of PGOOD (VDDPWRGD in AMD specifications)
when a VID-on-the-fly transition occurs.
SVI WIRE Protocol
The SVI wire protocol is based on the I2C bus concept.
Two wires (serial clock (SVC) and serial data (SVD)),
carry information between the AMD processor (master)
and VR controller (slave) on the bus. The master initiates
and terminates SVI transactions and drives the clock,
SVC, during a transaction. The AMD processor is always
the master and the voltage regulators are the slaves. The
slave receives the SVI transactions and acts accordingly.
Mobile SVI wire protocol timing is based on high-speed
mode I2C. See AMD Griffin (Family 11h) processor
publications for additional details.
A POR event on VCC during normal operation will
shutdown all regulators and PGOOD is pulled low. The
pre-PWROK metal VID code is not retained.
TABLE 3. 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*
16
FN6976.1
July 28, 2010
ISL6265C
TABLE 3. SERIAL VID CODES (Continued)
SVID[6:0]
VOLTAGE (V)
SVID[6:0]
VOLTAGE (V)
SVID[6:0]
VOLTAGE (V)
SVID[6:0]
VOLTAGE (V)
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
PSI_L
NOTE: *Indicates a VID not required for AMD Family 10h processors.
6
5
4
3
2
1
7
0
(See Table 3)
SVID
6
5
4
3
2
1
0
SVC
STOP
ACK
DATA PHASE
ACK
SLAVE ADDRESS PHASE
WRITE
START
SVD
FIGURE 8. SEND BYTE EXAMPLE
SVI Bus Protocol
The AMD processor bus protocol is compliant with SMBus
send byte protocol for VID transactions (see Figure 8).
During a send byte transaction, the processor sends the
start sequence followed by the slave address of the VR
for which the VID command applies. The address byte
must be configured according to Table 4. The processor
then sends the write bit. After the write bit, if the
ISL6265C receives a valid address byte, it sends the
acknowledge bit. The processor then sends the PSI-L bit
and VID bits during the data phase. The Serial VID 8-bit
17
data field encoding is outlined in Table 5. If ISL6265C
receives a valid 8-bit code during the data phase, it
sends the acknowledge bit. Finally, the processor sends
the stop sequence. After the ISL6265C has detected the
stop, it can then proceed with the VID-on-the-fly
transition.
TABLE 4. SVI SEND BYTE ADDRESS DESCRIPTION
BITS
6:4
3
DESCRIPTION
Always 110b
Reserved by AMD for future use
FN6976.1
July 28, 2010
ISL6265C
DESCRIPTION
2
VDD1, if set then the following data byte contains the
VID for VDD1
1
VDD0, if set then the following data byte contains the
VID for VID0
0
VDDNB, if set then the following data byte contains the
VID for VIDNB
TABLE 5. SERIAL VID 8-BIT DATA FIELD ENCODING
6:0
PSI_L:
=0 means the processor is at an optimal load for the
regulator(s) to enter power-savings mode
=1 means the processor is not at an optimal load for
the regulator(s) to enter power-saving mode
SVID[6:0] as defined in Table 3.
Operation
After the start-up sequence, the ISL6265C begins
regulating the core and Northbridge output voltages to
the pre-PWROK metal VID programmed. The controller
monitors SVI commands to determine when to enter
power-savings mode, implement dynamic VID changes,
and shutdown individual outputs.
The ISL6265C controls the no-load output voltage of core
and Northbridge output to an accuracy of ±0.5% overthe-range of 0.75V to 1.5V. A fully differential amplifier
implements core voltage sensing for precise voltage
control at the microprocessor die.
Switching Frequency
The R3 modulator scheme is a variable frequency PWM
architecture. The switching frequency increases during
the application of a load to improve transient
performance. It also varies slightly due to changes in
input and output voltage and output current. This
variation is normally less than 10% in continuous
conduction mode.
Estimating the value of RFSET_NB is written as shown in
Equation 5:
1
R FSET = --------------------K ⋅ F SW
A resistor connected between the VW and COMP pins of
the Core segment of the ISL6265C adjusts the switching
window and therefore adjusts the switching frequency.
The RFSET resistor that sets up the switching frequency of
the converter operating in CCM can be determined using
Equation 3, where RFSET is in kΩ and the switching period
is in ms. Designs for 300kHz switching frequency would
result in a RFSET value of 6.81kΩ.
(EQ. 5)
Where FSW is the PWM switching frequency, RFSET_NB is
the programming resistor and K = 1.5 x 10-10.
It is recommended that whenever the control loop
compensation network is modified, the switching
frequency should be checked and adjusted by changing
RFSET_NB if necessary.
Current Sense
Core and Northbridge regulators feature two different
types of current sense circuits.
CORE CONTINUOUS CURRENT SENSE
The ISL6265C provides for load current to be measured
using either resistors in series with the individual output
inductors or using the intrinsic series resistance of the
inductors as shown in the applications circuits in
Figures 2 and 3. The load current in a particular output is
sampled continuously every switching cycle. During this
time, the current-sense amplifier uses the current sense
inputs to reproduce a signal proportional to the inductor
current. This sensed current is a scaled version of the
inductor current.
IL
VIN
UGATE
L
MOSFET
DRIVER
CORE FREQUENCY SELECTION
(EQ. 4)
LGATE
(EQ. 3)
In discontinuous conduction mode (DCM) the ISL6265C
runs in period stretching mode.
18
VL(s)
VC(s)
R1
ISL6265C INTERNAL CIRCUIT
CURRENT
SENSE
VOUT
COUT
C1
R2
RNTC
ISP
R FSET ( kΩ ) = ( Period ( μs ) – 0.4 ) × 2.33
DCR
INDUCTOR
+
7
DESCRIPTION
1
F SW = ----------------------------------K ⋅ R FSETNB
+
BITS
The Northbridge switching frequency to programmed by
a resistor connected from the FSET_NB pin to the GND
pin. The approximate PWM switching frequency is written
as shown in Equation 4:
-
BITS
NORTHBRIDGE FREQUENCY SELECTION
-
TABLE 4. SVI SEND BYTE ADDRESS DESCRIPTION
R3
OPTIONAL
NTC
NETWORK
ISN
FIGURE 9. DCR SENSING COMPONENTS
FN6976.1
July 28, 2010
ISL6265C
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 9. The inductor
current, IL, flowing through the inductor, passes through
the DCR. Equation 6 shows the s-domain equivalent
voltage, VL, across the inductor.
V L ( s ) = I L ⋅ ( s ⋅ L + DCR )
(EQ. 6)
A simple R-C network across the inductor (R1, R2 and C)
extracts the DCR voltage, as shown in Equation 7. The
voltage across the sense capacitor, VC, can be shown to
be proportional to the output current IL, shown in
Equation 7.
s⋅L
⎛ ------------+ 1⎞
⎝ DCR
⎠
V C ( s ) = ----------------------------------------------------------- ⋅ K ⋅ DCR ⋅ I L
⎛ ( R1 ⋅ R2 )
⎞
⎜ s ⋅ ------------------------ ⋅ C 1 + 1⎟
R
+
R
⎝
⎠
1
2
(EQ. 7)
Where:
load line can be set to any level, giving the converter the
correct amount of droop at all load currents.
Equation 10 shows the relation between droop voltage,
maximum output current (IMAX), OC trip level and
current sense capacitor voltage at the OC current level,
VC(OC).
I MAX
V DROOP = -------------- ⋅ 5 ⋅ V C, OC
I OC
(EQ. 10)
AMD specifications do not require droop and provide no
load line guidelines. Tight static output voltage tolerance
limits push acceptable level of droop below a useful level
for Griffin applications. Care must be taken in
applications which implement droop to balance time
constant mismatch, sense capacitor resistor ratio, OC trip
and droop equations. Temperature shifts related to DCR
must also be addressed, as outlined in the previous
section.
NORTHBRIDGE CURRENT SENSE
R2
K = --------------------R2 + R1
(EQ. 8)
Sensing the time varying inductor current accurately
requires that the parallel R-C network time constant
match the inductor L/DCR time constant. If the R-C
network components are selected, such that the R-C
time constant matches the inductor L/DCR time constant
(see Equation 9), then VC is equal to the voltage drop
across the DCR multiplied by the ratio of the resistor
divider, K.
R1 ⋅ R2
L
- ⋅ C1
------------- = -------------------R1 + R2
DCR
(EQ. 9)
During the off-time following a PHASE transition low, the
Northbridge controller samples the voltage across the
lower MOSFET rDS(ON). A ground-referenced amplifier is
connected to the PHASE node through a resistor,
ROCSET_NB. The voltage across ROCSET_NB is equal to the
voltage drop across the rDS(ON) of the lower MOSFET
while it is conducting. The resulting current into the
OCSET_NB pin is proportional to the inductor current.
The sensed inductor current is used for overcurrent
protection and described in the “Fault Monitoring and
Protection” on page 21. The Northbridge controller does
not support output voltage droop.
Selecting RBIAS For Core Outputs
The inductor current sense information is used for
current balance in dual plane applications, overcurrent
detection in core outputs and output voltage droop
depending on controller configuration.
CORE DCR TEMPERATURE COMPENSATION
It may also be necessary to compensate for changes in
inductor DCR due to temperature. DCR shifts due to
temperature cause time constant mismatch, skewing
inductor current accuracy. Potential problems include
output voltage droop and OC trip point, both shifting
significantly from expected levels. The addition of a
negative temperature coefficient (NTC) resistor to the
R-C network compensates for the rise in DCR due to
temperature. Typical NTC values are in the 10kΩ range. A
second resistor, R3, in series with the NTC allows for
more accurate time-constant and resistor-ratio matching
as the pair of resistors are placed in parallel with R2
(Figure 9). The NTC resistor must be placed next to the
inductor for good heat transfer, while R1, R2, R3, and C1
are placed close to the controller for interference
immunity.
To properly bias the ISL6265C, a reference current is
established by placing a 117kΩ, 1% tolerance resistor
from the RBIAS pin to ground. This will provide a highly
accurate, 10µA current source from which OC reference
current is derived.
Care must be taken in layout to place the resistor very
close to the RBIAS pin. A good quality signal ground
should be connected to the opposite end of the RBIAS
resistor. Do not connect any other components to this pin
as this would negatively impact performance.
Capacitance on this pin could create instabilities and is to
be avoided.
A resistor divider off this pin is used to set the Core side
OC trip level. Additional direction on how to size is
provided in “Fault Monitoring and Protection” on page 21
on how to size the resistor divider.
Offset Resistor Selection
CORE DCR COMPONENT SELECTION FOR DROOP
If the OFS pin is connected to ground through a resistor,
the ISL6265C operates in SVI mode with droop active.
The resistor between the OFS pin and ground sets the
positive Core voltage offset per Equation 11.
By adjusting the ratio between inductor DCR drop and
the voltage measured across the sense capacitor, the
1.2V ⋅ R FB
R OFS = ---------------------------V OFS
19
(EQ. 11)
FN6976.1
July 28, 2010
ISL6265C
Where VOFS is the user defined output voltage offset.
Typically, VOFS is determined by taking half the total
output voltage droop. The resulting value centers the
overall output voltage waveform around the programmed
SVID level. For example, RFB of 1kΩ and a total output
droop of 24mV would result in an offset voltage of 12mV
and a ROFS of 100kΩ.
Internal Driver Operation
The ISL6265C features three internal gate-drivers to
support the Core and Northbridge regulators and to
reduce solution size. The drivers include a diode
emulation mode, which helps to improve light-load
efficiency.
MOSFET Gate-Drive Outputs
The ISL6265C has internal gate-drivers for the high-side
and low-side N-Channel MOSFETs. The low-side gatedrivers are optimized for low duty-cycle applications
where the low-side MOSFET conduction losses are
dominant, requiring a low r DS(ON) MOSFET. The LGATE
pull-down resistance is low in order to strongly clamp the
gate of the MOSFET below the VGS(th) at turn-off. The
current transient through the gate at turn-off can be
considerable because the gate charge of a low r DS(ON)
MOSFET can be large. Adaptive shoot-through protection
prevents a gate-driver output from turning on until the
opposite gate-driver output has fallen below
approximately 1V.
monitors the phase voltage when the low-side MOSFET is
conducting inductor current to determine the direction of
the inductor current.
When the output load current is less than half the
inductor ripple current, the inductor current goes
negative. Sinking the negative inductor through the lowside MOSFET lowers efficiency by preventing DCM period
stretching and allowing unnecessary conduction losses.
In DE, the ISL6265C Core regulators automatically enter
DCM after the PHASE pin has detected positive voltage
and LGATE was allowed to go high. The NB regulator
enters DCM after the PHASE pin has detected positive
voltage and LGATE was allowed to go high for eight
consecutive PWM switching cycles. The ISL6265C turns
off the low-side MOSFET once the phase voltage turns
positive, indicating negative inductor current. The
ISL6265C returns to CCM on the following cycle after the
PHASE pin detects negative voltage, indicating that the
body diode of the low-side MOSFET is conducting positive
inductor current.
Efficiency can be further improved with a reduction of
unnecessary switching losses by reducing the PWM
frequency. It is characteristic of the R3 architecture for
the PWM frequency to decrease while in diode emulation.
The extent of the frequency reduction is proportional to
the reduction of load current. Upon entering DCM, the
PWM frequency makes an initial step-reduction because
of a 33% step-increase of the window voltage V W.
The high-side gate-driver output voltage is measured
across the UGATE and PHASE pins while the low-side
gate-driver output voltage is measured across the LGATE
and PGND pins. The power for the LGATE gate driver is
sourced directly from the PVCC pin. The power for the
UGATE gate-driver is sourced from a “boot” capacitor
connected across the BOOT and PHASE pins. The boot
capacitor is charged from a 5V bias supply through a
“boot diode” each time the low-side MOSFET turns on,
pulling the PHASE pin low. The ISL6265C has an
integrated boot diode connected from the PVCC pin to
the BOOT pin.
Power-Savings Mode
Diode Emulation
While PSI_L is high, the controller operates all three
regulators in forced CCM. If PSI_L is asserted low by the
SVI interface, the ISL6265C initiates DE in all three
regulators. This transition allows the controller to achieve
the highest possible efficiency over the entire load range
for each output. A smooth transition is facilitated by the
R3 technology™, which correctly maintains the internally
synthesized ripple current throughout mode transitions
of each regulator.
The ISL6265C implements forced
continuous-conduction-mode (CCM) at heavy load and
diode-emulation-mode (DE) at light load, to optimize
efficiency in the entire load range. The transition is
automatically achieved by detecting the inductor current
when PSI_L is low. If PSI_L is high, the controller
disables DE and forces CCM on both Core and NB
regulators.
Positive-going inductor current flows either from the
source of the high-side MOSFET, or into the drain of the
low-side MOSFET. Negative-going inductor current flows
into the drain of the low-side MOSFET. When the low-side
MOSFET conducts positive inductor current, the phase
voltage is negative with respect to the GND and PGND
pins. Conversely, when the low-side MOSFET conducts
negative inductor current, the phase voltage is positive
with respect to the GND and PGND pins. The ISL6265C
20
The ISL6265C has two operating modes to optimize
efficiency based on the state of the PSI_L input from the
AMD SVI control signal. When this input is low, the
controller expects to deliver low power and enters a
power-savings mode to improve efficiency in this low
power state. The controller’s operational modes are
designed to work in conjunction with the AMD SVI control
signal to maintain the optimal system configuration for
all conditions.
Northbridge And Dual Plane Core
Uniplane Core
In uniplane mode, the ISL6265C Core regulator is in
2-phase multiphase mode. The controller operates with
both phases fully active, responding rapidly to transients
and delivering the maximum power to the load. When
the processor asserts PSI_L low under reduced load
levels, the ISL6265C sheds one phase to eliminate
switching losses associated with the idle channel. Even
FN6976.1
July 28, 2010
ISL6265C
with the regulator operating in single-phase mode,
transient response capability is maintained.
While operating in single-phase DE with PSI_L low, the
lower MOSFET driver switches the lower MOSFET off at
the point of zero inductor current to prevent discharge
current from flowing from the output capacitor bank
through the inductor. In DCM, switching frequency is
proportionately reduced, thus greatly reducing both
conduction and switching loss. In DCM, the switching
frequency is defined by Equation 12.
2
2 ⋅ L ⋅ IO
F CCM
F DCM = ------------------- ⋅ ------------------------------------2
VO ⎞
⎛
1.33
V O ⋅ ⎜ 1 – ---------⎟
V IN⎠
⎝
(EQ. 12)
programmed trip level, the comparator signals an OC fault.
Figure 10 shows the basic OC functions within the IC.
CURRENT
SENSE
ISP
5x
OC
The power-good pin (PGOOD) is an open-drain logic
output that signals if the ISL6265C is not regulating Core
and Northbridge output voltages within the proper levels
or output current in one or more outputs has exceeded
the maximum current setpoint.
This pin must be tied to a +3.3V or +5V source through a
resistor. During shutdown and soft-start, PGOOD is
pulled low and is released high only after a successful
soft-start has raised Core and Northbridge output
voltages within operating limits. PGOOD is pulled low
when an overvoltage, undervoltage, or overcurrent (OC)
condition is detected on any output or when the
controller is disabled by a POR or forcing enable (EN)
low. Once a fault condition is triggered, the controller
acts to protect the processor. The controller latches off
and PGOOD is pulled low. Toggling EN or VCC initiates a
soft-start of all outputs. In the event of an OV, the
controller will not initiate a soft-start by toggling EN, but
requires VCC be lowered below the falling POR threshold
to reset.
Overcurrent Protection
Core and Northbridge outputs feature two different
methods of current sensing. Core output current sensing
is achieved via inductor DCR or discrete resistor sensing.
The Northbridge controller uses lower MOSFET rDS(ON)
sensing to detect output current.
CORE OC DETECTION
Core outputs feature an OC monitor which compares a
voltage set at the OCSET pin to the voltage measured
across the current sense capacitor, VC. When the voltage
across the current sense capacitor exceeds the
21
BIAS
CKT
RBIAS
+
Vc
_
1.17V
10µA
+
VOCSET
6
6
OCSET
RBIAS
VOCSET
ROCSET
ISL6265C
Fault Monitoring and Protection
Power-Good Signal
ISN
5 x VC(OC) @
OC TRIP CURRENT
Where FCCM is equivalent to the Core frequency set by
Equation 3.
The ISL6265C actively monitors Core and Northbridge
output voltages and currents to detect fault conditions.
These fault monitors trigger protective measures to
prevent damage to the processor. One common power
good indicator is provided for linking to external system
monitors.
SEE FIGURE 9 FOR
ADDITIONAL DETAIL
FIGURE 10. OC TRIP CIRCUITRY
The sense capacitor voltage, VC, will increase as inductor
current rises per Equation 7. When the inductor current
rises to the OC trip level, the voltage across the sense
capacitor will reach a maximum based on the resistor
ratio K. This maximum value, VC(OC), is gained up by a
factor of 5 and compared to the static OC trip level set by
the OCSET pin.
The recommended voltage range for VC,OC is 6mV to
25mV, which sets the resistor divider ratio K, where IOC is
the user-defined OC trip level (see Equation 13). Typical
inductor DCR values are on the order of 1mΩ which
result in more than enough voltage drop to support this
VC,OC range.
V C ( OC )
K = ---------------------------I OC ⋅ DCR
(EQ. 13)
The resistor divider components also impact timeconstant matching, these components need to meet the
parallel combination requirements of Equation 9.
Based on the selected VC(OC) level, the required OC
monitor trip level is set. The recommended VC(OC) level
range will result in an OC monitor trip level range of
30mV to 125mV based on the internal gain of 5.
This OC monitor trip level sets the voltage level required
at the OCSET pin to create an OC fault at the userdefined OC trip level. A resistor divider from the RBIAS
pin to ground with the mid-point connected to OCSET
sets the voltage at the pin (see Figure 10). This voltage is
internally divided by 6 and compared with VC(OC).
Working backwards, the voltage required at the OCSET
pin to achieve this OC trip level ranges from 180mV to
0.750mV as defined in Equation 14.
V OCSET = V C ( OC ) ⋅ 30
(EQ. 14)
The resistor divider ratio used to determine the RBIAS and
ROCSET values is shown in Equation 15.
FN6976.1
July 28, 2010
ISL6265C
V OCSET
R OCSET
----------------------------------------------- = ----------------------R OCSET + R BIAS
1.17V
(EQ. 15)
The resistor values must also meet the RBIAS
requirement that the total series resistance to ground
equal 117kΩ. An OC condition must be sustained for
100µs before action is taken by the controller in response
to the OC fault.
A short-circuit OC loop is also active based on the same
sense elements outlined above with a threshold set to
2.25x the OCSET threshold set. The controller takes
immediate action when this fast OC fault is detected.
NORTHBRIDGE OC DETECTION
Northbridge OC sensing is achieved via rDS(ON) sensing
across the lower MOSFET. An internal 10µA current
source develops a voltage across ROCSET_NB, which is
compared with the voltage developed across the low-side
MOSFET as measured at the PHASE pin. When the
voltage drop across the MOSFET exceeds the voltage
drop across the resistor, an OC event occurs. The
OCSET_NB resistor is selected based on the relationship
in Equation 16.
I OC ⋅ r DS ( ON )
R OCSETNB = ------------------------------------10μA
(EQ. 16)
Where IOC is the OC trip level selected for the
Northbridge application and rDS(ON) is the drain-source
ON-resistance of the lower MOSFET.
OC FAULT RESPONSE
When an OC fault occurs on any combination of outputs,
both Core and Northbridge regulators shutdown and the
driver outputs are tri-stated. The PGOOD signal
transitions low indicating a fault condition. The controller
will not attempt to restart the regulators and the user
must toggle either EN or VCC to clear the fault condition.
Overvoltage Protection
The ISL6265C monitors the individual Core and
Northbridge output voltages using differential remote
sense amplifiers. The ISL6265C features a severe
overvoltage (OV) threshold of 1.8V. If any of the outputs
exceed this voltage, an OV fault is immediately triggered.
PGOOD is latched low and the low-side MOSFETs of the
offending output(s) are turned on. The low-side MOSFETs
will remain on until the output voltage is pulled below
0.85V at which time all MOSFETs are turned off. If the
output again rises above 1.8V, the protection process
repeats. This offers protection against a shorted
high-side MOSFET while preventing output voltage from
ringing below ground. The OV is reset by toggling EN low.
OV detection is active at all times that the controller is
enabled including after one of the other faults occurs so
that the processor is protected against high-side MOSFET
leakage while the MOSFETs are commanded off.
Undervoltage Protection
Undervoltage protection is independent of the OC limit. A
fault latches if any of the sensed output voltages are less
22
than the VID set value by a nominal 295mV for 205µs.
The PWM outputs turn off both Core and Northbridge
internal drivers and PGOOD goes low.
General Application Design
Guide
This design guide is intended to provide a high-level
explanation of the steps necessary to design a
single-phase power converter. It is assumed that the
reader is familiar with many of the basic skills and
techniques referenced in the following section. In
addition to this guide, Intersil provides complete
reference designs that include schematics, bills of
materials, and example board layouts.
Selecting the LC Output Filter
The output inductor and output capacitor bank form a
low-pass filter responsible for smoothing the pulsating
voltage at the phase node. The output filter also must
support the transient energy required by the load until
the controller 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.
The duty cycle of an ideal buck converter is a function of
the input and the output voltage. This relationship is
written as Equation 17:
VO
D = --------V IN
(EQ. 17)
The output inductor peak-to-peak ripple current is
written as Equation 18:
VO • ( 1 – D )
I P-P = -----------------------------f SW • L
(EQ. 18)
For this type of application, a typical step-down DC/DC
converter has an IP-P of 20% to 40% of the maximum
DC output load current. The value of IP-P is selected
based upon several criteria such as MOSFET switching
loss, inductor core loss, and the resistive loss of the
inductor winding. The DC copper loss of the inductor can
be estimated by Equation 19:
P COPPER = I LOAD
2
•
DCR
(EQ. 19)
Where ILOAD is the converter output DC current.
The copper loss can be significant so attention must be
given to the DCR selection. Another factor to consider
when choosing the inductor is its saturation
characteristics at elevated temperature. A saturated
inductor could cause destruction of circuit components as
well as nuisance OCP faults.
A DC/DC buck regulator must have output capacitance
CO into which ripple current IP-P can flow. Current IP-P
develops a corresponding ripple voltage VP-P across CO,
which is the sum of the voltage drop across the capacitor
FN6976.1
July 28, 2010
ISL6265C
ESR and of the voltage change stemming from charge
moved in and out of the capacitor. These two voltages
are written as shown in Equation 20:
The normalized RMS current calculation is written as
Equation 22:
ΔV ESR = I PP • E SR
I IN_RMS, N =
(EQ. 20)
2
D
D ⋅ ( 1 – D ) + ⎛ ------⎞ ⋅ I PP ,N
⎝ 12⎠
(EQ. 22)
and Equation 21:
(EQ. 21)
SW
If the output of the converter has to support a load with
high pulsating current, several capacitors will need to be
paralleled to reduce the total ESR until the required VP-P
is achieved. The inductance of the capacitor can cause a
brief voltage dip if the load transient has an extremely
high slew rate. Capacitor ESL can significantly impact
output voltage ripple. Low inductance capacitors should
be considered. A capacitor dissipates heat as a function
of RMS current and frequency. Be sure that IP-P is
shared by a sufficient quantity of paralleled capacitors
so that they operate below the maximum rated RMS
current at FSW. Take into account that the rated value of
a capacitor can degrade as much as 50% as the DC
voltage across it increases.
Selection of the Input Capacitor
The input capacitors are responsible for sourcing the AC
component of the input current flowing into the upper
MOSFETs. Their RMS current capability 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.
The important parameters for the bulk input capacitance
are the voltage rating and the RMS current rating. For
reliable operation, select bulk capacitors with voltage and
current ratings above the maximum input voltage and
capable of supplying the RMS current required by the
switching circuit. Their voltage rating should be at least
1.25x greater than the maximum input voltage, while a
voltage rating of 1.5x is a preferred rating. Figure 11 is a
graph of the input RMS ripple current, normalized
relative to output load current, as a function of duty
cycle for a single-phase regulator that is adjusted for
converter efficiency.
0.60
NORMALIZED INPUT RMS
RIPPLE CURRENT (IRMS/IO)
0.55
0.45
0.40
0.35
IP-P,N = 0
0.30
IP-P,N = 0.25
0.25
0.20
0.15
0.10
0.05
0
0
0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9
1.0
DUTY CYCLE (VIN/VO)
FIGURE 11. NORMALIZED RMS INPUT CURRENT FOR
SINGLE PHASE CONVERTER
23
VO
D = -----------------V IN ⋅ η
(EQ. 23)
- where η is converter efficiency
Figure 12 provides the same input RMS current
information for two-phase designs.
0.3
0.2
IP-P,N = 0.5
IP-P,N = 0.75
0.1
IP-P,N = 0
0
0
0.2
0.4
0.6
0.8
1.0
DUTY CYCLE (VIN/VO)
FIGURE 12. NORMALIZED RMS INPUT CURRENT FOR
2-PHASE CONVERTER
In addition to the bulk capacitance, some low ESL
ceramic capacitance is recommended to decouple
between the drain of the high-side MOSFET and the
source of the low-side MOSFET.
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.
IP-P,N = 0.75
0.50
- IMAX is the maximum continuous ILOAD of the
converter
- IPP,N is the ratio of inductor peak-to-peak ripple
current to IMAX
- D is the duty cycle that is adjusted to take into
account the efficiency of the converter which is
written as:
MOSFET Selection and Considerations
IP-P,N = 0.50
IP-P,N = 1
Where:
NORMALIZED INPUT RMS
RIPPLE CURRENT (IRMS/IO)
I PP
ΔV C = ----------------------------8 • CO • f
Typically, a MOSFET cannot tolerate even brief excursions
beyond their maximum drain to source voltage rating.
The MOSFETs used in the power stage of the converter
should have a maximum VDS rating that exceeds the
sum of the upper voltage tolerance of the input power
source and the voltage spike that occurs when the
MOSFETs switch.
There are several power MOSFETs readily available that
are optimized for DC/DC converter applications. The
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July 28, 2010
ISL6265C
preferred high-side MOSFET emphasizes low gate charge
so that the device spends the least amount of time
dissipating power in the linear region. The preferred
low-side MOSFET emphasizes low r DS(ON) when fully
saturated to minimize conduction loss.
For the low-side (LS) MOSFET, the power loss can be
assumed to be conductive only and is written as
Equation 24:
2
P CON_LS ≈ I LOAD ⋅ r DS ( ON )_LS • ( 1 – D )
(EQ. 24)
For the high-side (HS) MOSFET, the its conduction loss is
written as Equation 25:
P CON_HS = I LOAD
2
•
r DS ( ON )_HS • D
(EQ. 25)
For the high-side MOSFET, the switching loss is written as
Equation 26:
V IN • I PEAK • t OFF • f
V IN • I VALLEY • t ON • f
SW
SW
P SW_HS = ----------------------------------------------------------------- + ------------------------------------------------------------2
2
(EQ. 26)
Where:
- IVALLEY is the difference of the DC component of
the inductor current minus 1/2 of the inductor
ripple current
- IPEAK is the sum of the DC component of the
inductor current plus 1/2 of the inductor ripple
current
- tON is the time required to drive the device into
saturation
- tOFF is the time required to drive the device into
cut-off
Selecting The Bootstrap Capacitor
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 and PHASE pins.
The bootstrap capacitor must have a maximum voltage
rating above PVCC + 4V and its capacitance value is
selected per Equation 27:
Qg
C BOOT ≥ -----------------------ΔV BOOT
(EQ. 27)
Where:
- Qg is the total gate charge required to turn on the
high-side MOSFET
- ΔVBOOT, is the maximum allowed voltage decay
across the boot capacitor each time the high-side
MOSFET is switched on
As an example, suppose the high-side MOSFET has a
total gate charge Qg, of 25nC at VGS = 5V, and a ΔVBOOT
of 200mV. The calculated bootstrap capacitance is
0.125µF; for a comfortable margin, select a capacitor
24
that is double the calculated capacitance. In this
example, 0.22µF will suffice. Use a low
temperature-coefficient ceramic capacitor.
PCB Layout Considerations
Power and Signal Layers Placement on the
PCB
As a general rule, power layers should be close together,
either on the top or bottom of the board, with the weak
analog or logic signal layers on the opposite side of the
board. The ground-plane layer should be adjacent to the
signal layer to provide shielding. The ground plane layer
should have an island located under the IC, the
compensation components, and the FSET components.
The island should be connected to the rest of the ground
plane layer at one point.
Component Placement
There are two sets of critical components in a DC/DC
converter; the power components and the small signal
components. The power components are the most critical
because they switch large amount of energy. The small
signal components connect to sensitive nodes or supply
critical bypassing current and signal coupling.
The power components should be placed first and these
include MOSFETs, input and output capacitors, and the
inductor. It is important to have a symmetrical layout for
each power train, preferably with the controller located
equidistant from each power train. Symmetrical layout
allows heat to be dissipated equally across all power
trains. Keeping the distance between the power train and
the control IC short helps keep the gate drive traces
short. These drive signals include the LGATE, UGATE,
PGND, PHASE and BOOT.
VIAS TO
GROUND
PLANE
GND
VOUT
INDUCTOR
PHASE
NODE
HIGH-SIDE
MOSFETS
VIN
OUTPUT
CAPACITORS
SCHOTTKY
DIODE
LOW-SIDE
MOSFETS
INPUT
CAPACITORS
FIGURE 13. TYPICAL POWER COMPONENT PLACEMENT
When placing MOSFETs, try to keep the source of the
upper MOSFETs and the drain of the lower MOSFETs as
close as thermally possible (see Figure 13). Input
high-frequency capacitors should be placed close to the
drain of the upper MOSFETs and the source of the lower
MOSFETs. Place the output inductor and output
capacitors between the MOSFETs and the load.
High-frequency output decoupling capacitors (ceramic)
should be placed as close as possible to the decoupling
target (microprocessor), making use of the shortest
connection paths to any internal planes. Place the
components in such a way that the area under the IC has
FN6976.1
July 28, 2010
ISL6265C
less noise traces with high dV/dt and di/dt, such as gate
signals and phase node signals.
Signal Ground and Power Ground
The bottom of the ISL6265C QFN package is the signal
ground (GND) terminal for analog and logic signals of the
IC. Connect the GND pad of the ISL6265C to the island
of ground plane under the top layer using several vias,
for a robust thermal and electrical conduction path.
Connect the input capacitors, the output capacitors, and
the source of the lower MOSFETs to the power ground
plane.
Routing and Connection Details
Specific pins (and the trace routing from them), require
extra attention during the layout process. The following
sub-sections outline concerns by pin name.
ENABLE AND PGOOD PINS
These are logic signals that are referenced to the GND
pin. Treat as a typical logic signal.
FB PINS
The input impedance of the FB pin is high, so place the
voltage programming and loop compensation
components close to the COMP, FB, and GND pins
keeping the high impedance trace short.
FSET_NB PIN
This pin requires a quiet environment. The resistor RFSET
should be placed directly adjacent to this pin. Keep fast
moving nodes away from this pin.
LGATE ROUTING
This is the return path for the pull-down of the LGATE
low-side MOSFET gate driver. Ideally, PGND should be
connected to the source of the low-side MOSFET with a
low-resistance, low-inductance path.
The LGATE trace has a signal going through it that is both
high dV/dt and di/dt, with high peak charging and
discharging current. Route this trace in parallel with the
trace from the PGND pin. These two traces should be
short, wide, and away from other traces. There should be
no other weak signal traces in proximity with these
traces on any layer.
VIN PIN
BOOT AND PHASE ROUTING
The VIN pin should be connected close to the drain of the
high-side MOSFET, using a low- resistance and
low-inductance path.
The signals going through these traces are both high
dv/dt and high di/dt, with high peak charging and
discharging current. Route the UGATE and PHASE pins in
parallel with short and wide traces. There should be no
other weak signal traces in proximity with these traces
on any layer.
PGND PINS
VCC PIN
For best performance, place the decoupling capacitor
very close to the VCC and GND pins.
PVCC PIN
For best performance, place the decoupling capacitor
very close to the PVCC and respective PGND pins,
preferably on the same side of the PCB as the ISL6265C
IC.
25
Copper Size for the Phase Node
The parasitic capacitance and parasitic inductance of the
phase node should be kept very low to minimize ringing.
It is best to limit the size of the PHASE node copper in
strict accordance with the current and thermal
management of the application. An MLCC should be
connected directly across the drain of the upper MOSFET
and the source of the lower MOSFET to suppress the
turn-off voltage.
FN6976.1
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ISL6265C
Revision History
The revision history provided is for informational purposes only and is believed to be accurate, but not warranted. Please go to
web to make sure you have the latest Rev.
DATE
REVISION
7/23/10
FN6976.1
CHANGE
Added “Related Literature*(see page 26)” on page 1.
On page 3; corrected part marking in “Ordering Information” from ISL6265C HRTZ to 6265C
HRTZ
In “Thermal Information” on page 10, corrected Theta JC from 32 to 28
In “Electrical Specifications” table, corrected standard over temp note in common conditions
of Spec table from "Boldface limits apply over the operating temperature range, -40°C to
+85°C." to "Boldface limits apply over the operating temperature range, -10°C to +100°C."
On “Overvoltage Threshold” on page 12; changed typical from 1.795V to 1.800V and
maximum from 1.820V to 1.825V.
3/10/10
FN6976.0
Initial Release.
Products
Intersil Corporation is a leader in the design and manufacture of high-performance analog semiconductors. The
Company's products address some of the industry's fastest growing markets, such as, flat panel displays, cell phones,
handheld products, and notebooks. Intersil's product families address power management and analog signal
processing functions. Go to www.intersil.com/products for a complete list of Intersil product families.
*For a complete listing of Applications, Related Documentation and Related Parts, please see the respective device
information page on intersil.com: ISL6265C
To report errors or suggestions for this datasheet, please go to www.intersil.com/askourstaff
FITs are available from our website at http://rel.intersil.com/reports/search.php
For additional products, see www.intersil.com/product_tree
Intersil products are manufactured, assembled and tested utilizing ISO9000 quality systems as noted
in the quality certifications found 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
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patent or patent rights of Intersil or its subsidiaries.
For information regarding Intersil Corporation and its products, see www.intersil.com
26
FN6976.1
July 28, 2010
ISL6265C
Package Outline Drawing
L48.6x6
48 LEAD THIN QUAD FLAT NO-LEAD PLASTIC PACKAGE
Rev 1, 4/07
4X 4.4
6.00
44X 0.40
A
B
6
PIN 1
INDEX AREA
6
PIN #1 INDEX AREA
48
37
1
6.00
36
4 .40 ± 0.15
25
12
0.15
(4X)
13
24
0.10 M C A B
0.05 M C
TOP VIEW
48X 0.45 ± 0.10
4 48X 0.20
BOTTOM VIEW
SEE DETAIL "X"
0.10 C
BASE PLANE
MAX 0.80
(
SEATING PLANE
0.08 C
( 44 X 0 . 40 )
( 5. 75 TYP )
C
SIDE VIEW
4. 40 )
C
0 . 2 REF
5
( 48X 0 . 20 )
( 48X 0 . 65 )
0 . 00 MIN.
0 . 05 MAX.
DETAIL "X"
TYPICAL RECOMMENDED LAND PATTERN
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 identifier may be
either a mold or mark feature.
27
FN6976.1
July 28, 2010