1
®
FN9243.0
ISL6567
Multipurpose Two-Phase Buck PWM
Controller with Integrated MOSFET
Drivers
The ISL6567 two-phase synchronous buck PWM control IC
provides a precision voltage regulation system for point-of-
load and other high-current applications requiring an efficient
and compact implementation. Multi-phase power conversion
is a marked departure from single phase converter
configurations employed to satisfy the increasing current
demands of various electronic circuits. By distributing the
power and load current, implementation of multi-phase
converters utilize smaller and lower cost transistors with
fewer input and output capacitors. These reductions accrue
from the higher effective conversion frequency with higher
frequency ripple current resulting from the phase
interleaving inherent to this topology.
Outstanding features of this controller IC include an internal
0.6V reference with a system regulation accuracy of ±1%, an
optional external reference input, and user-adjustable
switching frequency. Precision regulation is further
enhanced by the available unity-gain differential amplifier
targeted at remote voltage sensing capability, while output
regulation is monitored and its quality is reported via a
PGOOD pin. Also included, an internal shunt regulator with
optional external connection capability extends the
operational input voltage range. For applications requiring
voltage tracking or sequencing, the ISL6567 offers a host of
possibilities, including coincidental, ratiometric, or offset
tracking, as well as sequential start-ups, user adjustable for
a wide range of applications.
Protection features of this controller IC include overvoltage
and overcurrent protection. Overvoltage results in the
converter turning the lower MOSFETs ON to clamp the rising
output voltage. The ISL6567 uses cost and space-saving
rDS(ON) sensing for channel current balance, dynamic
voltage positioning, and overcurrent protection. Channel
current balancing is automatic and accurate with the
integrated current-balance control system. Overcurrent
protection can be tailored to various application with no need
for additional parts.
Features
• Integrated Two-Phase Power Conversion
- Integrated 4A Drivers for High Efficiency
• Shunt Regulator for Wide Input Power Conversion
- 5V and Higher Bias
- Up to 20V Power Down-Conversion
• Precision Channel Current Sharing
- Loss-Less Current Sampling - Uses rDS(ON)
• Precision Output Voltage Regulation
-±1% System Accuracy Over Temperature (Commercial)
• 0.6V Internal Reference
• Full Spectrum Voltage Tracking
- Coincidental, Ratiometric, or Offset
• Sequential Start-up Control
• Adjustable Switching Frequency
- 150kHz - 1.5MHz
• Fast Transient Recovery Time
• Unity-Gain Differential Amplifier
- Increased Voltage Sensing Accuracy
• Overcurrent Protection
• Overvoltage Protection
• Start-up into Pre-Charged Output
• Small, QFN Package Footprint
• Pb-Free Plus Anneal Available (RoHS Compliant)
Data Sheet November 2, 2005
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. 2005. All Rights Reserved
All other trademarks mentioned are the property of their respective owners.
2
ISL6567
Pinout
ISL6567 (QFN)
TOP VIEW
Ordering Information
PART
NUMBER
(Note)
PART
MARKING
TEMP.
(°C)
PACKAGE
(Pb-Free)
PKG.
DWG. #
ISL6567CRZ 6567CRZ 0 to 70 24 Ld 4x4 QFN L24.4x4
ISL6567CRZ-T 6567CRZ 0 to 70 24 Ld 4x4 QFN L24.4x4
ISL6567IRZ 6567IRZ -40 to 85 24 Ld 4x4 QFN L24.4x4
ISL6567IRZ-T 6567IRZ -40 to 85 24 Ld 4x4 QFN L24.4x4
ISL6567EVAL1 Evaluation Platform
NOTE: Intersil Pb-free plus anneal products employ special Pb-free
material sets; molding compounds/die attach materials and 100%
matte tin plate termination finish, which are 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.
RGND
VDIFF
VSEN
MON
FB
COMP
VREG
VCC
EN
BOOT2
UGATE2
PHASE2
REFTRK
SS
FS
PGOOD
BOOT1
UGATE1
PVCC
LGATE2
PHASE1
ISEN1
LGATE1
ISEN2
1
2
3
4
5
6
18
17
16
15
14
13
24 23 22 21 20 19
789101112
25
GND
3
Block Diagram
SOFT-START
BOOT1
COMP
FB
REFERENCE
AND
FAULT LOGIC
Σ
Σ
CONTROL
LOGIC
GATE
CONTROL
GATE
CONTROL
CURRENT
CORRECTION
+
-
OC
EA
PWM1
PWM2
OVP
ISEN1
PVCC
VCC
EN
PGOOD
PHASE1
LGATE1
UGATE1
GND
PHASE2
LGATE2
UGATE2
BOOT2
ISEN2
FS
REFTRK
VDIFF
RGND
VSEN
X1
MON
VREG
OSCILLATOR
300mV +
-
VCC
SS
10µA
VCC
20µA
VCC
20µA/1mA
20µA
10µA
110%
90%
REGULATOR
SHUNT LINEAR
POWER-ON
RESET (POR)
120%
ISL6567ISL6567
4
Simplified Power System Diagram
Typical Application
CHANNEL1
VIN
VOUT
Q1
Q2
ISL6567
CHANNEL2
Q3
Q4
EN
PGOOD
ISL6567
VIN
Q1
Q2
Q3
Q4
COMP
FB
GND
VCC
BOOT1
BOOT2
UGATE1
UGATE2
LGATE1
LGATE2
LIN
LOUT1
CHFIN1 CBIN1
CHFIN2 CBIN2
CBOOT1
CBOOT2
LOUT2
CHFOUT CBOUT
RISEN1
R2
R1
C2
C1
CF1
PHASE1
PHASE2
VOUT
RGND
PVCC
CF2
PGOOD
EN
VREG
RSHUNT
ISEN1
RISEN2
ISEN2
VSEN
VDIFF
RS
MON
SS
REFTRK
FS
RFS
RP
CSS
RPG
R4
R5
ISL6567ISL6567
5
Absolute Maximum Ratings
Supply Voltage, VCC, PVCC . . . . . . . . . . . . . . . . . . . -0.3V to +6.5V
Shunt Regulator Voltage, VVREG . . . . . . . . . . . . . . . -0.3V to +6.5V
Boot Voltage, VBOOT . . . . . . . . . . . . . PGND - 0.3V to PGND + 27V
Phase Voltage, VPHASE . . . . . . . . . . VBOOT - 7V to VBOOT + 0.3V
Upper Gate Voltage, VUGATE . . . . VPHASE - 0.3V to VBOOT + 0.3V
Lower Gate Voltage, VLGATE. . . . . . . . PGND - 0.3V to VCC + 0.3V
Input, Output, or I/O Voltage . . . . . . . . . GND - 0.3V to VCC + 0.3V
ESD Classification . . . . . . . . . . . . . . . . . . HBM Class 1 JEDEC STD
Recommended Operating Conditions
Supply Voltage, VCC . . . . . . . . . . . . . . . . . . . . . . . . . +4.9V to +5.5V
Ambient Temperature. . . . . . . . . . . . . . . . . . . . . . . . . . . 0°C to 70°C
Thermal Information
Thermal Resistance θJA (°C/W) θJC (°C/W)
QFN Package (Notes 1, 2). . . . . . . . . . 43 7
Maximum Junction Temperature . . . . . . . . . . . . . . . . . . . . . . . 150°C
Maximum Storage Temperature Range . . . . . . . . . . . -65°C to 150°C
Maximum Lead Temperature (Soldering 10s) . . . . . . . . . . . . . 300°C
CAUTION: Stress above those listed in “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress only rating and operation of the
device at these or any other conditions above those indicated in the operational section of this specification is not implied.
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 Operating Conditions: VCC = 5V, TJ = -40°C to 85°C, Unless Otherwise Specified
PARAMETER TEST CONDITIONS MIN TYP MAX UNITS
BIAS SUPPLY AND INTERNAL OSCILLATOR
Input Bias Supply Current IVCC; EN > 0.7V; LGATE, UGATE open - 7.6 9 mA
Rising VCC POR (Power-On Reset) Threshold 4.30 4.40 4.50 V
VCC POR Hysteresis 0.46 0.51 0.58 V
Rising PVCC POR Threshold 3.60 3.67 3.75 V
Shunt Regulation VVCC; IVREG = 0 to 120mA 4.90 5.10 5.35 V
Maximum Shunt Current IVREG_MAX 120 - - mA
Switching Frequency (per channel; Note 4) FSW 200 - 2000 kHz
Frequency Tolerance FSW -10 - 10 %
Oscillator Peak-to-Peak Ramp Amplitude VOSC -1.4-V
Maximum Duty Cycle dMAX -66-%
CONTROL THRESHOLDS
EN Threshold -0.65-V
EN Hysteresis Current -20-µA
MON Power-Good Enable Threshold VMON_TH 290 305 320 mV
MON Hysteresis Current -10-µA
SOFT-START
SS Current ISS -22-µA
SS Ramp Amplitude 0.55 - 3.60 V
SS Threshold for Output Gates Turn-Off 0.40 - - V
REFERENCE AND DAC
System Accuracy (Commercial Temp. Range) -0.6 - 0.6 %
System Accuracy (Industrial Temp. Range) -0.8 - 0.8 %
Internal Reference VREF -0.6-V
External Reference DC Amplitude Range VREFTRK (DC) 0.1 - 2.3 V
External Reference DC Offset Range VREFTRK (DC) offset -4.5 - 4.5 mV
ISL6567ISL6567
6
Timing Diagram
ERROR AMPLIFIER AND REMOTE SENSING
DC Gain (Note 3) RL = 10K to ground - 80 - dB
Gain-Bandwidth Product (Note 3) CL = 10pF - 95 - MHz
Slew Rate (Note 3) CL = 10pF - 30 - V/µs
Maximum Output Voltage no load 4.0 - - V
Minimum Output Voltage no load - - 0.7 V
VSEN, RGND Input Resistance 140 225 - kΩ
POWER GOOD
PGOOD Rising Lower Threshold -92-%
PGOOD Rising Upper Threshold - 112 - %
PGOOD Threshold Hysteresis -2.5-%
PROTECTION
Overcurrent Trip Level 80 103 120 µA
Overvoltage Threshold VDIFF Rising - 122 - %
Overvoltage Hysteresis VDIFF Falling - 5.5 - %
SWITCHING TIME
UGATE Rise Time (Note 3) tRUGATE; VVCC = 5V, 3nF Load - 8 - ns
LGATE Rise Time (Note 3) tRLGATE; VVCC = 5V, 3nF Load - 8 - ns
UGATE Fall Time (Note 3) tFUGATE; VVCC = 5V, 3nF Load - 8 - ns
LGATE Fall Time (Note 3) tFLGATE; VVCC = 5V, 3nF Load - 4 - ns
UGATE Turn-On Non-overlap (Note 3) tPDHUGATE; VVCC = 5V, 3nF Load - 8 - ns
LGATE Turn-On Non-overlap (Note 3) tPDHLGATE; VVCC = 5V, 3nF Load - 8 - ns
OUTPUT
Upper Drive Source Resistance 100mA Source Current - 1.0 2.5 Ω
Upper Drive Sink Resistance 100mA Sink Current - 1.0 2.5 Ω
Lower Drive Source Resistance 100mA Source Current - 1.0 2.5 Ω
Lower Drive Sink Resistance 100mA Sink Current - 0.4 1.0 Ω
NOTES:
3. Parameter magnitude guaranteed by design.
4. Not a tested parameter; range provided for reference only.
Electrical Specifications Operating Conditions: VCC = 5V, TJ = -40°C to 85°C, Unless Otherwise Specified (Continued)
PARAMETER TEST CONDITIONS MIN TYP MAX UNITS
UGATE
LGATE
tFLGATE
tPDHUGATE
tRUGATE tFUGATE
tPDHLGATE
tRLGATE
ISL6567ISL6567
7
Functional Pin Description
VCC (Pin 8)
Bias supply for the IC’s small-signal circuitry. Connect this
pin to a 5V supply and locally decouple using a quality 0.1µF
ceramic capacitor. This pin is monitored for POR purposes.
VCC bias may be applied in the absence of PVCC bias.
PVCC (Pin 15)
Power supply pin for the MOSFET drives. Connect this pin to
a 5V supply and locally decouple using a quality 1µF
ceramic capacitor. This pin is monitored for POR purposes.
PVCC bias should not be applied in the absence of VCC
bias.
VREG (Pin 7)
This pin is the output of the internal shunt regulator. The
internal shunt regulator monitors and regulates the voltage
at the VCC pin. In applications where the chip bias, including
that necessary to drive the external MOSFETs, is below the
current rating of this pin, connect it to VCC and PVCC, then
connect this node to the input supply via a properly sized
resistor. Should the input voltage vary over a wide range
and/or the bias current required exceed the intrinsic
capability of the on-board regulator, use this pin in
conjunction with an external NPN transistor and a couple of
resistors to create a more flexible bias supply for the
ISL6567. In any configuration, pay particular attention to the
chip’s limitations in terms of both current sinking capability of
the shunt regulator, as well as the internal power dissipation.
For more information, refer to the Bias Supply
Considerations paragraph.
GND (Pin 25)
Connect this pad to the circuit ground using the shortest
possible path (one to four vias to the internal ground plane,
placed on the soldering pad are recommended). All internal
small-signal circuitry, as well as the lower gates’ return paths
are referenced to this pin.
REFTRK (Pin 24)
This pin represents an optional reference input, as well as a
clamp voltage for the internal reference. If utilizing the
ISL6567’s internal 0.6V reference, and desire no special
tracking features enabled, electrically connect this pin to the
VCC pin, or leave it open. Internal or external reference
operation mode is dictated by the MON pin.
While operating in internal reference mode, this pin
represents an internal reference clamp that can be used for
implementation of various tracking features. In this operating
mode, a small internal current is sourced on this pin, pulling it
high if left open.
If utilizing the ISL6567 in conjunction with an external
reference, connect the desired stimulus to this pin; the sensed
output of the ISL6567 converter follows this input.
While operating with an external reference, the power-good
and overvoltage protection functions are disabled while the
MON pin voltage is below its threshold (typically 300mV).
MON (Pin 3)
The status of this pin is checked every time the chip is
enabled or POR is released; should its potential be lower than
3.5V (typical), the REFTRK potential is assumed to be an
externally-provided reference and the ISL6567 proceeds to
regulate the sensed output voltage to this external reference.
When operating using the internal reference voltage, connect
this pin to VCC (to bypass the mechanism described above).
While operating with an externally-provided reference,
connect this pin to a properly-sized resistor divider off the
voltage to be monitored. PGOOD and OVP functions are
enabled when this pin exceeds its monitored threshold
(typically 300mV).
This pin is normally floating (high impedance input) until it
exceeds its detect threshold. Once the threshold is
exceeded, a small current is sourced on this pin; this current,
along with a properly sized resistor network, allows the user
to adjust the threshold hysteresis.
For more information, refer to the External Reference
Operation paragraph.
EN (Pin 9)
This pin is a precision-threshold (approximately 0.6V) enable
pin. Pulled above the threshold, the pin enables the controller
for operation, initiating a soft-start. Normally a high impedance
input, once it is pulled above its threshold, a small current is
sourced on this pin; this current, along with a properly sized
resistor network, allows the user to adjust the threshold
hysteresis. Pulled below the falling threshold, this pin disables
controller operation, by ramping down the SS voltage and
discharging the output.
VSEN, RGND, and VDIFF (Pins 2, 1, and 4)
The inputs and output of the on-board unity-gain operational
amplifier intended for differential output sensing. Connect
RGND and VSEN to the output load’s local GND and VOUT,
respectively; VDIFF will reflect the load voltage referenced to
the chip’s local ground. Connect the feedback network to the
voltage thus reflected at the VDIFF pin. Should the circuit not
allow implementation of remote sensing, connect the VSEN
and RGND pins to the physical place where voltage is to be
regulated.
Connect the resistor divider setting the output voltage at the
input of the differential amplifier. To minimize the error
introduced by the resistance of differential amplifier’s inputs,
select resistor divider values smaller than 1kΩ. VDIFF is
monitored for overvoltage events and for PGOOD reporting
purposes.
ISL6567ISL6567
8
FB and COMP (Pins 6 and 5)
The internal error amplifier’s inverting input and output
respectively. These pins are connected to the external
network used to compensate the regulator’s feedback loop.
ISEN1, ISEN2 (Pins 17, 13)
These pins are used to close the current feedback loop and
set the overcurrent protection threshold. A resistor
connected between each of these pins and their
corresponding PHASE pins determine a certain current flow
magnitude during the lower MOSFET’s conduction interval.
The resulting currents established through these resistors
are used for channel current balancing and overcurrent
protection.
Use the following equation to select the proper RISEN
resistor:
where:
rDS(ON) = lower MOSFET drain-source ON resistance (Ω)
IOUT = channel maximum output current (A)
Read ‘Current Loop’, ‘Current Sensing’, ‘Channel-Current
Balance’, and ‘Overcurrent Protection’ paragraphs for more
information.
UGATE1, UGATE2 (Pins 19, 11)
Connect these pins to the upper MOSFETs’ gates. These
pins are used to control the upper MOSFETs and are
monitored for shoot-through prevention purposes. Minimize
the impedance of these connections. Maximum individual
channel duty cycle is limited to 66%.
BOOT1, BOOT2 (Pins 20, 10)
These pins provide the bias voltage for the upper MOSFETs’
drives. Connect these pins to appropriately-chosen external
bootstrap capacitors. Internal bootstrap diodes connected to
the PVCC pins provide the necessary bootstrap charge.
Minimize the impedance of these connections.
PHASE1, PHASE2 (Pins 18, 12)
Connect these pins to the sources of the upper MOSFETs.
These pins are the return path for the upper MOSFETs’
drives. Minimize the impedance of these connections.
LGATE1, LGATE2 (Pins 16, 14)
These pins are used to control the lower MOSFETs and are
monitored for shoot-through prevention purposes. Connect
these pins to the lower MOSFETs’ gates. Minimize the
impedance of these connections.
SS (Pin 23)
This pin allows adjustment of the output voltage soft-start
ramp rate, as well as the hiccup interval following an
overcurrent event. The potential at this pin is used as a clamp
voltage for the internal error amplifier’s non-inverting input,
regulating its rate of rise during start-up. Connect this pin to a
capacitor referenced to ground. Small internal current sources
linearly charge and discharge this capacitor, leading to similar
variation in the ramp up/down of the output voltage. While
below 0.3V, all output drives are turned off. As this pin ramps
up, the drives are not enabled but only after the first UGATE
pulse emerges (avoid draining the output, if pre-charged). If
no UGATE pulse are generated until the SS exceeds the top
of the oscillator ramp, at that time all gate operation is
enabled, allowing immediate draining of the output, as
necessary.
SS voltage has a ~0.7V offset above the reference clamp,
meaning the reference clamp rises from 0V with unity gain
correspondence as the SS pin exceeds 0.7V. For more
information, please refer to the Soft-Start paragraph.
FS (Pin 22)
This pin is used to set the switching frequency. Connect a
resistor, RFS, from this pin to ground and size it according to
the graph in Figure 1 or the following equation:
PGOOD (Pin 21)
This pin represents the output of the on-board power-good
monitor. Thus, the FB pin is monitored and compared against
a window centered around the available reference; an FB
voltage within the window disables the open-collector output,
allowing the external resistor to pull-up PGOOD high.
Approximate pull-down device impedance is 65Ω.
While operating with an external reference, the power-good
function is enabled once the MON pin amplitude exceeds its
monitored threshold (typically 300mV).
RISEN
rDS ON()
IOUT
×
50µA
------------------------------------------=
RFS 10
10.61 1.035 FSW
()log⋅()–()
=
FIGURE 1. SWITCHING FREQUENCY VS. RFS VALUE
100k 200k 500k 1M 2M
Switching Frequency (Hz)
RFS Value (Ω)
10k
20k
50k
100k
200k
ISL6567ISL6567
9
Operation
Figure 2 shows a simplified diagram of the voltage regulation
and current loops. The voltage loop is used to precisely
regulate the output voltage, while the current feedback is
used to balance the output currents, IL1 and IL2, of the two
power channels.
VOLTAGE LOOP
Feedback from the output voltage is fed via the on-board
differential amplifier and applied via resistor R1 to the
inverting input of the Error Amplifier. The signal generated by
the error amplifier is summed up with the current correction
error signal and applied to the positive inputs of the PWM
circuit comparators. Out-of-phase sawtooth signals are
applied to the two PWM comparators inverting inputs.
Increasing error amplifier voltage results in increased duty
cycle. This increased duty cycle signal is passed to the
output drivers with no phase reversal to drive the external
MOSFETs. Increased duty cycle, translating to increased
ON-time for the upper MOSFET transistor, results in
increased output voltage, compensating for the low output
voltage which lead to the increase in the error signal in the
first place.
CURRENT LOOP
The current control loop is only used to finely adjust the
individual channel duty cycle, in order to balance the current
carried by each phase. The information used for this control
is the voltage that is developed across rDS(ON) of each lower
MOSFET, while they are conducting. A resistor converts and
scales the voltage across each MOSFET to a current that is
applied to the current sensing circuits within the ISL6567.
Output from these sensing circuits is averaged and used to
compute a current error signal. Each PWM channel receives
a current signal proportional to the difference between the
average sensed current and the individual channel current.
When a PWM channel’s current is greater than the average
current, the signal applied via the summing correction circuit
to the PWM comparator reduces the output pulse width (duty
cycle) of the comparator to compensate for the detected
above average current in the respective channel.
MULTI-PHASE POWER CONVERSION
Multi-phase power conversion provides a cost-effective
power solution when load currents are no longer easily
supported by single-phase converters. Although its greater
complexity presents additional technical challenges, the
multi-phase approach offers advantages with improved
response time, superior ripple cancellation, and thermal
distribution.
FIGURE 2. SIMPLIFIED BLOCK DIAGRAM OF THE ISL6567 VOLTAGE AND CURRENT CONTROL LOOPS
AVERAGE
Σ
Σ
Σ
REFERENCE
PWM
CIRCUIT
PWM
CIRCUIT
HALF-BRIDGE
DRIVE
HALF-BRIDGE
DRIVE
Σ
OSCILLATOR
COMP
FB
L1
L2
COUT
VOUT
VIN
VIN
RISEN2
UGATE1
UGATE2
LGATE1
LGATE2
ISEN1
ISEN2
CURRENT
SENSE
R1
R2
C1
PHASE1
CURRENT
SENSE
PHASE2
RISEN1
ISL6567
VDIFF
VSEN RGND
ISL6567ISL6567
10
INTERLEAVING
The switching of each channel in a ISL6567-based converter
is timed to be symmetrically out of phase with the other
channel. As a result, the two-phase converter has a
combined ripple frequency twice the frequency of one of its
phases. In addition, the peak-to-peak amplitude of the
combined inductor currents is proportionately reduced.
Increased ripple frequency and lower ripple amplitude
generally translate to lower per-channel inductance and/or
lower total output capacitance for any given set of
performance specification.
Figure 3 illustrates the additive effect on output ripple
frequency. The two channel currents (IL1 and IL2), combine
to form the AC ripple current and the DC load current. The
ripple component has two times the ripple frequency of each
individual channel current.
To understand the reduction of ripple current amplitude in the
multi-phase circuit, examine the equation representing an
individual channel’s peak-to-peak inductor current.
VIN and VOUT are the input and output voltages,
respectively, L is the single-channel inductor value, and fS is
the switching frequency.
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. 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
(should output high-frequency ripple be an important design
parameter).
Another benefit of interleaving is the reduction of input ripple
current. Input capacitance is determined in a large 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 4 illustrates input
currents from a two-phase converter combining to reduce
the total input ripple current.
Figure 28, part of the section entitled Input Capacitor
Selection, can be used to determine the input-capacitor
RMS current based on load current and duty cycle. The
figure is provided as an aid in determining the optimal input
capacitor solution.
PWM OPERATION
One switching cycle for the ISL6567 is defined as the time
between consecutive PWM pulse terminations (turn-off of
the upper MOSFET on a channel). Each cycle begins when
a switching clock signal commands the upper MOSFET to
go off. The other channel’s upper MOSFET conduction is
terminated 1/2 of a cycle later.
Once a channel’s upper MOSFET is turned off, the lower
MOSFET remains on for a minimum of 1/3 cycle. This forced
off time is required to assure an accurate current sample.
Following the 1/3-cycle forced off time, the controller enables
the upper MOSFET output. Once enabled, the upper
MOSFET output transitions high when the sawtooth signal
crosses the adjusted error-amplifier output signal, as
illustrated in Figure 2. Just prior to the upper drive turning
FIGURE 3. PWM AND INDUCTOR-CURRENT WAVEFORMS
FOR 2-PHASE CONVERTER
PWM2
PWM1
IL2
IL1
IL1 + IL2
ILPP,
VIN VOUT
–()VOUT
⋅
Lf
SV⋅IN
⋅
----------------------------------------------------------=
IPP
VIN NV
OUT
⋅–()VOUT
⋅
Lf
SV⋅IN
⋅
--------------------------------------------------------------------=
FIGURE 4. INPUT CAPACITOR CURRENT AND INDIVIDUAL
CHANNEL CURRENTS IN A 2-PHASE
CONVERTER
Q1 D-S CURRENT
Q3 D-S CURRENT
CIN CURRENT
ISL6567ISL6567
11
the MOSFET on, the lower MOSFET drive turns the
freewheeling element off. The upper MOSFET is kept on
until the clock signals the beginning of the next switching
cycle and the PWM pulse is terminated.
CURRENT SENSING
ISL6567 senses current by sampling the voltage across the
lower MOSFET during its conduction interval. MOSFET
rDS(ON) sensing is a no-added-cost method to sense current
for load line regulation, channel current balance, module
current sharing, and overcurrent protection.
The ISEN pins are used as current inputs for each channel.
Internally, a virtual ground is created at the ISEN pins. The
RISEN resistors are used to size the current flow through the
ISEN pins, proportional to the lower MOSFETs’ rDS(ON)
voltage, during their conduction periods. The current thus
developed through the ISEN pins is internally averaged, then
the current error signals resulting from comparing the
average to the individual current signals are used for
channel current balancing.
Select the value for the RISEN resistors based on the room
temperature rDS(ON) of the lower MOSFETs and the full-load
total converter output current, IFL. As this current sense path
is also used for OC detection, ensure that at maximum
power train temperature rise and maximum output current
loading the OC protection is not inadvertently tripped. OC
protection current level through the ISEN pins is listed in the
Electrical Specifications table.
CHANNEL-CURRENT BALANCE
Another 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 multiple parallel
MOSFETs and the expense of using expensive heat sinks
and exotic magnetic materials.
All things being equal, in order to fully realize the thermal
advantage, it is important that each channel in a multi-phase
converter be controlled to deliver about the same current at
any load level. Intersil’s ISL6567 ensure current balance by
comparing each channel’s current to the average current
delivered by both channels and making appropriate
adjustments to each channel’s pulse width based on the
resultant error. The error signal modifies the pulse width to
correct any unbalance and force the error toward zero.
Conversely, should a channel-to-channel imbalance be
desired, such imbalance can be created by adjusting the
individual channel’s RISEN resistor. Asymmetrical layouts,
where one phase of the converter is naturally carrying more
current than the other, or where one of the two phases is
subject to a more stringent thermal environment limiting its
current-carrying capability, are instances where this
adjustment is particularly useful, helping to cancel out the
design-intrinsic thermal or current imbalances.
SOFT-START
The soft-start function allows the converter to bring up the
output voltage in a controlled fashion, resulting in a linear
ramp-up. As soon as the controller is fully enabled for
operation, the SS pin starts to output a small current which
charges the external capacitor, CSS, connected to this pin.
An internal reference clamp controlled by the potential at the
SS pin releases the reference to the input of the error
amplifier with a 1:1 correspondence for SS potential
exceeding 0.7V (typically). Figure 5 details a normal soft-
start start-up. The following equation helps determine the
approximate time period during which the controlled output
voltage is ramped from 0V to the desired DC-set level.
Whenever the ISL6567’s power-on reset falling threshold is
tripped, or it is disabled via the EN pin, the SS capacitor is
quickly discharged via an internal pull-down device
(represented as the 1mA, typical, current source).
As the SS pin’s positive excursion is internally clamped to
about 3.5V, insure that any external pull-up device does not
force more than 3mA into this pin.
Should OC protection be tripped while the ISL6567 is
operating in internal-reference mode and the SS pin not be
allowed to fully discharge the SS capacitor, the ISL6567
cannot continue the normal SS cycling.
RISEN
rDS ON()
50 10 6
–
×
----------------------- IFL
2
--------
⋅=
tSS
CSS VREF
⋅
ISS
--------------------------------=
GND>
FIGURE 5. NORMAL SOFT-START WAVEFORMS FOR
ISL6567-BASED MULTI-PHASE CONVERTER
EN (5V/DIV)
VSS (1V/DIV)
GND>GND>
GND>
VintREF (0.5V/DIV)
VOUT (0.5V/DIV)
ISL6567ISL6567
12
OVERCURRENT PROTECTION
The individual channel currents, as sensed via the PHASE
pins and scaled via the ISEN resistors, as well as their
combined average are continuously monitored and
compared with an internal overcurrent (OC) reference. If the
combined channel current average exceeds the reference
current, the overcurrent comparator triggers an overcurrent
event. Similarly, an OC event is also triggered if either
channel’s current exceeds the OC reference for 7
consecutive switching cycles.
As a result of an OC event, output drives turn off both upper
and lower MOSFETs, and the SS capacitor is discharged via
a 20µA current source. The behavior following this standard
response varies depending whether the controller is
operating in internal (using internal reference; MON > 3.5V)
or external reference mode (using external reference; MON
< 3.5V). As shown in Figure 6, the soft-start capacitor
discharge prompted by the OC event is followed by two SS
cycles, during which the ISL6567 stays off. Following the
dormant SS cycles, the controller attempts to re-establish
the output. Should the OC condition been removed, the
output voltage is ramped up and operation resumes as
normal. Should the OC condition still be present and result in
another OC event, the entire behavior repeats until the OC
condition is removed or the IC is disabled. Figure 7 details
the OC behavior while in external reference mode. Following
the OC event, the output drives are turned off, the ISL6567
latches off, and the SS capacitor is discharged to ground.
Resetting the OC latch involves removal of bias power or
cycling of the EN pin (pictured in Figure 7). Should the OC
event been removed, the controller initiates a new SS cycle
and restores the output voltage.
SETTING THE OUTPUT VOLTAGE
The ISL6567 uses a precision internal reference voltage to
set the output voltage. Based on this internal reference, the
output voltage can thus be set from 0.6V up to a level deter-
mined by the input voltage, the maximum duty cycle, and the
conversion efficiency of the circuit; the following equation
estimates this maximum amplitude the output voltage can be
regulated to. Obviously, insure that the input voltage and all
the voltages sampled by the ISL6567 do not exceed the con-
troller’s absolute maximum limits, or any other limits specified
in this document.
OUTPUT CURRENT
FIGURE 6. OVERCURRENT BEHAVIOR WHILE IN INTERNAL
REFERENCE MODE
OUTPUT VOLTAGE
SS
EN
GND>
GND>
GND>
GND>
OUTPUT CURRENT
FIGURE 7. OVERCURRENT BEHAVIOR WHILE IN EXTERNAL
REFERENCE MODE
OUTPUT VOLTAGE
SS
EN
GND>
GND>
GND>
GND>
VOUTMAX dMAX VIN Efficiency⋅⋅=
FIGURE 8. SETTING THE OUTPUT VOLTAGE AT THE INPUT
OF THE DIFFERENTIAL AMPLIFIER
-
+
EXTERNAL CIRCUIT
ISL6567
VSEN
RGND
VDIFF
RS
RP
DIFFERENTIAL
AMPLIFIER
X1
FB
-
+
To VOUT
+
-
VREF
ERROR
AMPLIFIER R1
ISL6567ISL6567
13
The output voltage can be set via a simple resistor divider, as
shown in Figure 8. It is recommended this resistor divider is
connected at the input of the differential amplifier (as this
amplifier is powered from the IC’s 5V bias and has limited
input range). To avoid degradation of DC regulation tolerance
due to the differential amplifier’s input resistance, a size
requirement is placed on the combined value of RP and RS.
Consider R to be the parallel combination of these two resis-
tors, and use a value of 2kΩ or less for R; use the following
equations to determine the value of RP and RS, based on the
desired output voltage, the reference voltage, and the chosen
value of R.
The differential amplifier can be used even if remote output
sensing is not desired or not feasible, simply connect RGND
to the local ground and connect VSEN to the output voltage
being monitored. Should one desire to bypass the differential
amplifier, the circuit in Figure 9 is recommended as the
proper implementation. Since its output is monitored for OVP
and PGOOD purposes, the differential amplifier needs to be
connected to the feedback circuit at all times, hence its input
connections to FB and local ground. However, its output,
VDIFF, can be left open. The resistor divider setting the out-
put voltage is calculated in a manner identical to that already
revealed.
DIFFERENTIAL AMPLIFIER’S UNITY GAIN NETWORK
The differential amplifier on the ISL6567 utilizes a typical
resistive network along with active compensating circuitry to
set its unity gain. This resistive network can affect the DC
regulation setpoint in proportion to its relative magnitude
compared to the external output voltage setting resistor
divider. Figure 10 details the internal resistive network. For
minimal impact on the output voltage setting, follow the
guidelines presented in the Setting the Output Voltage
paragraph.
EXTERNAL REFERENCE OPERATION
The ISL6567 is capable of accepting an external voltage and
using it as a reference for its output regulation. To enable this
mode of operation, the MON pin potential has to be below
3.5V and the reference voltage has to be connected to the
REFTRK pin. The internal or external reference mode of
operation is latched in every time the POR is released or the
ISL6567 is enabled. The highest magnitude external
reference fed to the REFTRK pin that the ISL6567 can follow
is limited to 2.3V. The ISL6567 utilizes a small initial negative
offset (typically about 50mV) in the voltage loop at the
beginning of it soft-start, to counteract any positive offsets
that may have undesirable effects. As this initial offset is
phased out as the reference is ramped up to around 200mV,
in order to avoid an error in the output regulation level, it is
recommended the external reference has an amplitude
(final, DC level) exceeding 300mV.
RPR
VOUT
VOUT VREF
–
-------------------------------------
⋅=RSR
VOUT
VREF
----------------
⋅=
FIGURE 9. SETTING THE OUTPUT VOLTAGE AT THE FB PIN
-
+
EXTERNAL CIRCUIT
ISL6567
VSEN
RGND
RP
DIFFERENTIAL
AMPLIFIER
X1
FB
-
+
To VOUT
+
VREF
ERROR
AMPLIFIER
RS(R1)
VDIFF
FIGURE 10. SETTING THE OUTPUT VOLTAGE AT THE INPUT
OF THE DIFFERENTIAL AMPLIFIER
EXTERNALISL6567
VSEN
RGND
VDIFF
DIFFERENTIAL
AMPLIFIER
-
+
ZIN
CIRCUIT
~2µA
ZIN > 240kΩ
over process, temperature, and
0 < VSEN-RGND < 2.5V
ISL6567ISL6567
14
While in external reference (ER) mode, the threshold
sensitive MON pin can be used to control when the ISL6567
starts to monitor the output for PGOOD and OVP protection
purposes. As shown in Figure 11, connect the MON pin to
the voltage to be monitored via a resistor divider. An internal
current source helps set a user-adjustable monitor threshold
hysteresis. Choose resistor values according to desired
hysteresis voltage, VH, and desired rising threshold, VT
.
Make note that, in these equations, VREF refers to the
reference of the MON comparator (300mV).
Intersil recommends the MON threshold is set to be tripped
when the external reference voltage reaches at least 90% of
the final DC value. Since PGOOD and OVP monitoring are
relative to the external reference magnitude, it is important to
understand that the PGOOD and OVP thresholds will move
in proportion to the moving reference (externally soft-started
reference). Thus, the absolute thresholds of PGOOD and
OVP
ISL6567 POWER-GOOD OPERATION
The open-collector PGOOD output reports on the quality of
the regulated output voltage. Once the ISL6567 is enabled
and the MON pin is above its threshold, PGOOD goes open
circuit when the output enters the power-good window (see
Electrical Specifications), and stays open for as long as the
output remains within the specified window. The PGOOD is
immediately pulled low if the ISL6567 is disabled by removal
of bias, toggling of the EN pin, or upon encountering of an
overcurrent event; PGOOD is allowed to report the status of
the output as soon as operation is resumed following any of
these events.
The MON pin is used in external-reference configurations,
where the reference is controlled by a circuit external to the
ISL6567. As such, the ISL6567 has no way of ‘knowing’
when the external reference has stabilized to its full value, or
is within a certain percentage of its final value. Thus, the
MON pin’s functionality can be used to indicate when a
desired threshold has been reached (either by monitoring
the reference itself, or the output voltage controlled by the
ISL6567). By default, when operating in external-reference
mode and desiring PGOOD monitoring as shown in this
datasheet, it is recommended the MON is set to trip its
threshold when the output voltage (or reference) reaches
92% of the final set value, choosing the resistor divider as to
achieve a 2% hysteresis.
When operating in internal-reference mode, the value of the
reference is known to the ISL6567, so the MON pin function
can be bypassed by tying it to VCC potential.
VOLTAGE TRACKING AND SEQUENCING
By making creative use of the reference clamps at the SS
and REFTRK pins, and/or the available external reference
input, as well as the functionality of the EN pin, the ISL6567
can accommodate the full spectrum of tracking and
sequencing options. The following figures offer some
implementation suggestions for a few typical situations.
FIGURE 11. SETTING THE MONITORING THRESHOLD AND
HYSTERESIS
EXTERNAL CIRCUIT
ISL6567
RP
MON
MON
COMPARATOR
RS
(300mV)
(10µA)
VCC
-
+
+
-
IH
VREF
VDIFF
RS
VH
IH
--------= RP
RSVREF
⋅
VTVREF
–
----------------------------=
VTARGET
VOUT
EXT CIRCUITISL6567
VSEN
RGND
VDIFF
RS
RP
X1
FB
-
+
To VOUT
+
-
VREF
E/A
R1
-
+
REFTRK
To VTARGET
+
VOUT
VTARGET
--------------------------- RP
RPRS
+
----------------------=
FIGURE 12. RATIOMETRIC VOLTAGE TRACKING
ISL6567ISL6567
15
Simple ratiometric external voltage tracking, such as that
required by the termination voltage regulator for double data
rate (DDR) memory can be implemented by feeding a
reference voltage equal to 0.5 of the memory core voltage
(VDDQ) to the reference input of the ISL6567, as shown in
Figure 12. The resistor divider at the REFTRK pin sets the
VOUT level. Select a suitable SS capacitor, such that the SS
clamp does not interfere with the desired ramp-up time or
slope of VOUT
.
Coincidental tracking using the internal reference results in a
behavior similar to that presented in Figure 13. The resistor
divider at the input of the differential amplifier sets the output
voltage, VOUT
, to the desired regulation level. The same
resistor divider used at the REFTRK pin divides down the
voltage to be tracked, effectively scaling it to the magnitude
of the internal reference. As a result, the output voltage
ramps up at the same rate as the target voltage, its ramp-up
leveling off at the programmed regulation level established
by the RS/RP resistor divider.
Offset tracking can be accomplished via a circuit similar to
that used for coincidental tracking (see Figure 14). The
desired offset can be implemented via a voltage source
inserted in line with the resistor divider present at the
REFTRK pin. Since most offset tracking requirements are
subject to fairly broad tolerances, simple voltage drop
sources can be used. Figure 14 exemplifies the use of
various counts of forward-biased diodes or that of a schottky,
although other options are available.
Sequential start-up control is easily implemented via the EN
pin, using either a logic control signal or the ISL6567’s own
EN threshold as a power-good detector for the tracked, or
sequence-triggering, voltage. See Figure 15 for details of
control using the EN pin.
OVERVOLTAGE PROTECTION
Although the normal feedback loop operation naturally
counters overvoltage (OV) events the ISL6567 benefits from
a secondary, fixed threshold overvoltage protection. Should
the output voltage exceed 120% of the reference, the lower
MOSFETs are turned on. Once turned on, the lower
MOSFETs are only turned off when the sensed output
voltage drops below the 110% falling threshold of the OC
comparator. The OVP behavior repeats for as long as the
ISL6567 is biased, should the sensed output voltage rise
back above the designated threshold. The occurrence of an
OVP event does not latch the controller; should the
VTARGET
VOUT
EXT CIRCUITISL6567
VSEN
RGND
VDIFF
RS
RP
X1
FB
-
+
To VOUT
+
-
VREF
E/A
R1
-
+
REFTRK
To VTARGET
+
VREF
VOUT
----------------RP
RPRS
+
----------------------=
FIGURE 13. COINCIDENTAL VOLTAGE TRACKING
RS
RP
VTARGET
VOUT
EXT CIRCUITISL6567
VSEN
RGND
VDIFF
RS
RP
X1
FB
-
+
To VOUT
+
-
VREF
E/A
R1
-
+
REFTRK
To VTARGET
+
VREF
VOUT
----------------RP
RPRS
+
----------------------=
FIGURE 14. OFFSET VOLTAGE TRACKING
RS
RP
VOFS
+
-
VOFS
VOFS
+-
+-
+-
ISL6567ISL6567
16
phenomenon be transitory, the controller resumes normal
operation following such an event.
When operating in external-reference mode, the OVP
monitoring is enabled when the MON pin exceeds its rising
threshold. For as long as the ISL6567 is biased, OVP has
the highest priority, bypassing all other control mechanisms
and acting directly onto the lower MOSFETs, as described.
Disabling the IC via the EN pin does not turn off OVP
protection.
START-UP INTO A PRE-CHARGED OUTPUT
The ISL6567 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 circuit setting.
As shown in Figure 15, while operating in internal reference
mode, should the output be pre-charged to a level exceeding
the circuit’s output voltage setting, the output drives are
enabled at the conclusion of the internal reference ramp,
leading to an abrupt correction in the output voltage down to
the set level.
When operating in external reference mode, should the
output voltage be pre-charged above the regulation level
driven by the external reference, the output drives are fully
enabled when the SS pin levels out at the top of its range.
CONTROL OF ISL6567 OPERATION
The internal power-on reset circuit (POR) prevents the
ISL6567 from starting before the bias voltage at VCC and
PVCC reach the rising POR thresholds, as defined in
Electrical Specifications. The POR levels are sufficiently high
to guarantee that all parts of the ISL6567 can perform their
functions properly once bias is applied to the part. While bias
is below the rising POR thresholds, the controlled MOSFETs
are kept in an off state.
A secondary disablement feature is available via the
threshold-sensitive enable input, the EN. This optional
feature prevents the ISL6567 from operating until a certain
chosen voltage rail is available and above some selectable
threshold. One example would be the input voltage: it may
be desirable the ISL6567-based converter does not start up
until the input voltage is sufficiently high. The schematic in
Figure 16 demonstrates coordination of the ISL6567 start-up
with such a rail. The internal current source, IH, provides the
means to a user-adjustable hysteresis. The resistor value
selection process follows the same equations as those
presented in External Reference Operation section.
Additionally, an open-drain or open-collector device (Q1) can
be used to wire-AND a second (or multiple) control signal. To
defeat the threshold-sensitive enable, connect EN to VCC
directly or via a pull-up resistor.
In summary, for the ISL6567 to operate, VCC and PVCC
must be greater than their respective POR thresholds and
the voltage at EN must be greater than the comparator’s
reference (see typical threshold in Electrical Specifications).
Once these conditions are met, the controller immediately
initiates a soft-start sequence.
FIGURE 15. SOFT-START WAVEFORMS INTO A PRE-
CHARGED OUTPUT CAPACITOR BANK
EN (5V/DIV)
VOUT (1.0V/DIV)
GND>
GND>
OUTPUT PRE-CHARGED:
ABOVE INTERNAL REFERENCE
BELOW REFERENCE
ABOVE EXTERNAL REFERENCE
OUTPUT INITIALLY
DISCHARGED
SS (1V/DIV)
FIGURE 16. START-UP COORDINATION USING THE EN PIN
-
+
(0.61V)
EXTERNAL CIRCUITISL6567
EN
VCC
+5V
EN
COMP
OFF
ON
POR
CIRCUIT
(20µA)
VCC
RS
RP
VIN
Q1
IH
VREF
ISL6567
17
General Application 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 below. In
addition to this guide, Intersil provides complete reference
designs that include schematics, bills of materials, and
example board layouts for typical applications.
BIAS SUPPLY CONSIDERATIONS
The ISL6567 features an on-board shunt regulator capable of
sinking up to 100mA (minimally). This integrated regulator can
be used to produce the necessary bias voltage for the
controller and the MOSFETs. The integrated regulator can be
utilized directly, via a properly sized resistor, as shown in
Figure 17, or via an external NPN transistor and additional
resistors when either the current needed or the power being
dissipated becomes too large to be handled inside the
ISL6567 in the given operating environment.
A first step in determining the feasibility and selecting the
proper bias regulator configuration consists in determining
the maximum bias current required by the circuit. While the
bias current required by the ISL6567 is listed in the Electrical
Specifications table, the bias current required by the
controlled MOSFETs needs be calculated. The following
equation helps determine this bias current function of the
sum of the gate charge of all the controlled MOSFETs at 5V
VGS, QGTOTAL, and the switching frequency, FSW:
Total required bias current, IBIAS, sums up the ISL6567’s
bias current, IVCC, to that required by the MOSFETs, IB.
The maximum bias current, IBIAS, that can be obtained via
the internal shunt regulator and a simple external resistor is
characterized in Figure 18 and can also be determined using
the following equation:
To exemplify the use, for an input voltage ranging from 10V
to 14V, find the intersection of the ∆VIN = 4V curve with the
VINmin = 10V mark and project the result on the Y axis to
find the maximum bias current obtainable (approximately
56% of the maximum current obtainable via the integrated
shunt regulator, IVREG_MAX).
Once the maximum obtainable bias current, IBIAS_MAX, is
determined, and providing it is greater than the bias current,
IBIAS, required by the circuit, RSHUNT can be determined
based on the lowest input voltage, VINMIN:
Figure 19 helps with a quick resistor selection based on the
previous guidelines presented. Divide the value thus
obtained by the maximum desired bias current, IBIAS, to
obtain the actual resistor value to be used.
FIGURE 17. INTERNAL SHUNT REGULATOR USE WITH
EXTERNAL RESISTOR (PASSIVE
CONFIGURATION)
-
+
EXTERNAL CIRCUITISL6567
SHUNT REG
E/A
POR
CIRCUIT
VREG
RBIAS
VIN
VREF
VCC
PVCC
IBQGTOTAL FSW
⋅≅
IBIAS IVCC IB
+=
FIGURE 18. NORMALIZED MAXIMUM BIAS CURRENT
OBTAINABLE IN PASSIVE CONFIGURATION vs
INPUT VOLTAGE RANGE CHARACTERISTIC;
VVCC = 5V
∆VIN = 1V
∆VIN = 2V
∆VIN = 3V
∆VIN = 4V
∆VIN = 5V
∆VIN = 6V
∆VIN = 7V
∆VIN = 8V
78910 11
VINmin (V)
0%
20%
40%
60%
80%
90%
IBIAS_MAX (% of IVREG_MAX)
70%
50%
30%
10%
6
IBIASMAX IVREGMAX
VINMIN VVCC
–
VINMAX VVCC
–
--------------------------------------------
⋅=
RBIAS
VINMIN VVCC
–
IBIAS
------------------------------------------=
ISL6567
18
Figure 20 details the normalized maximum power dissipation
RBIAS will be subject to in the given application. To use the
graph provided, find the power dissipation level
corresponding to the minimum input voltage and the input
voltage range and multiply it by the maximum desired bias
current to obtain the maximum power RBIAS will dissipate.
Alternately, the maximum power dissipation inside RBIAS
can be calculated using the following equation:
Maximum power dissipation in the bias resistor will take
place at the upper end of the input voltage range. Select a
resistor with a power dissipation rating above the calculated
value and pay attention to design aspects related to the
power dissipation level of this component. Although Figures
18 through 20 assume a VCC voltage of 5V, the design aid
curves can be translated to a different VCC voltage by
translating them in the amount of the voltage differential, to
the left for a lower VCC voltage, or to the right for a higher
VCC voltage,
Should the simple series bias resistor configuration fall short
of providing the necessary bias current, the internal shunt
regulator can be used in conjunction with an external BJT
transistor to increase the shunt regulator current. Figure 21
details such an implementation utilizing a PNP transistor.
Selection of R1 can be based on the graphs provided for the
passive regulator configuration. Maximum power dissipation
inside Q1 will take place when maximum voltage is applied
to the circuit and the ISL6567 is disabled; determine
IVREGMAX by reverse-use of the graph in Figure 18 and use
the obtained number to calculate Q1 power dissipation.
An NPN transistor can also be used to increase the
maximum available bias current, as shown in Figure 22.
Used as a series pass element, Q1 will dissipate the most
power when the circuit is enabled and operational, and the
input voltage, VIN, is at its highest level.
With the series pass element configuration shown in
Figure 22, the difference between the input and the
regulation level at the VCC pin has to be higher than the
lowest acceptable VCE of Q1 (may choose to run Q1 into
saturation, but must consider the reduced gain). Thus, R2
has to be chosen such that it will provide appropriate base
current at lowest VCE of Q1. Next, ensure the ISL6567’s
IVREGMAX is not exceeded when the input voltage swings to
its highest extreme (assume base current goes to 0 when
the IC is disabled). R1 is an optional circuit element: it can
FIGURE 19. NORMALIZED RESISTOR VALUE IN PASSIVE
CONFIGURATION; VVCC = 5V
678910 11
VINmin (V)
RBIASmin (kΩ•mA)
7
6
5
4
3
2
1
0
FIGURE 20. NORMALIZED RESISTOR POWER DISSIPATION
(AS SELECTED IN FIGURE 17) vs MINIMUM
INPUT VOLTAGE; VVCC = 5V
∆VIN = 1V
∆VIN = 2V
∆VIN = 3V
∆VIN = 4V
∆VIN = 5V
∆VIN = 6V
∆VIN = 7V
∆VIN = 8V
678910 11
VINmin (V)
150
135
120
105
90
75
60
45
30
15
0
PMAX_RBIAS (mW/mA)
PMAXRBIAS
VINMAX VVCC
–()
VINMIN VVCC
–
-------------------------------------------------IBIAS
⋅=
-
+
EXTERNAL CIRCUITISL6567
SHUNT REGULATOR
E/A
POR
CIRCUIT
VREG
R1
VIN
VREF
VCC
PVCC
Q1
FIGURE 21. INTERNAL SHUNT REGULATOR USE WITH
EXTERNAL PNP TRANSISTOR (ACTIVE
CONFIGURATION)
R2
(optional)
ISL6567
19
be added to offset some of the power dissipation in Q1, but it
also reduces the available VCE for Q1. If utilizing such a
series resistor, check that it does not impede on the proper
operation at the lowest input voltage and choose a power
rating corresponding to the highest bias current that the
ISL6567 may require to drive the switching MOSFETs.
FREQUENCY COMPENSATION
The ISL6567 multi-phase converter behaves in a similar
manner to a voltage-mode controller. This section highlights
the design consideration for a voltage-mode controller requiring
external compensation. To address a broad range of
applications, a type-3 feedback network is recommended
(see Figure 23).
Figure 24 highlights the voltage-mode control loop for a
synchronous-rectified buck converter, applicable, with a small
number of adjustments, to the multi-phase ISL6567 circuit. The
output voltage (VOUT) is regulated to the reference voltage,
VREF, level. The error amplifier output (COMP pin voltage) is
compared with the oscillator (OSC) modified saw-tooth wave to
provide a pulse-width modulated wave with an amplitude of VIN
at the PHASE node. The PWM wave is smoothed by the output
filter (L and C). The output filter capacitor bank’s equivalent
series resistance is represented by the series resistor E.
The modulator transfer function is the small-signal transfer
function of VOUT/VCOMP
. This function is dominated by a DC
gain, given by dMAXVIN/VOSC, and shaped by the output
filter, with a double pole break frequency at FLC and a zero at
FCE. For the purpose of this analysis, L and D represent the
individual channel inductance and its DCR divided by 2
(equivalent parallel value of the two output inductors), while C
and E represents the total output capacitance and its
equivalent series resistance.
The compensation network consists of the error amplifier
(internal to the ISL6567) and the external R1-R3, C1-C3
components. The goal of the compensation network is to
provide a closed loop transfer function with high 0dB crossing
frequency (F0; typically 0.1 to 0.3 of FSW) and adequate phase
margin (better than 45 degrees). Phase margin is the difference
between the closed loop phase at F0dB and 180o. The
equations that follow relate the compensation network’s poles,
FIGURE 22. INTERNAL SHUNT REGULATOR USE WITH
EXTERNAL NPN TRANSISTOR (ACTIVE
CONFIGURATION)
-
+
EXTERNAL CIRCUITISL6567
E/A
POR
CIRCUIT
VREG
R1
VIN
VREF
VCC
PVCC
R2
Q1
(optional)
SHUNT REGULATOR
FIGURE 23. COMPENSATION CONFIGURATION FOR ISL6567
CIRCUIT
ISL6567
COMP
C1
R2
R1
FB
VDIFF (VOUT)
C2
R3
C3
FIGURE 24. VOLTAGE-MODE BUCK CONVERTER
COMPENSATION DESIGN
-
+
E/A
VREF
COMP C1
R2
R1
FB
C2
R3 C3
L
C
VIN
PWM
CIRCUIT
HALF-BRIDGE
DRIVE
OSCILLATOR
E
EXTERNAL CIRCUIT
ISL6567
VOUT
VOSC
D
UGATE
PHASE
LGATE
-
+
VDIFF
VSEN
RGND
Ro
FLC
1
2πLC⋅⋅
---------------------------=FCE
1
2πCE⋅⋅
------------------------=
ISL6567
20
zeros and gain to the components (R1, R2, R3, C1, C2, and
C3) in Figure 23. Use the following guidelines for locating the
poles and zeros of the compensation network:
1. Select a value for R1 (1kΩ to 5kΩ, typically). Calculate
value for R2 for desired converter bandwidth (F0). If
setting the output voltage via an offset resistor connected
to the FB pin, Ro in Figure 24, the design procedure can
be followed as presented. However, when setting the
output voltage via a resistor divider placed at the input of
the differential amplifier, in order to compensate for the
attenuation introduced by the resistor divider, the
obtained R2 value needs be multiplied by a factor of
(RP+RS)/RP
. The remainder of the calculations remain
unchanged, as long as the compensated R2 value is
used.
2. Calculate C1 such that FZ1 is placed at a fraction of the FLC,
at 0.1 to 0.75 of FLC (to adjust, change the 0.5 factor to
desired number). The higher the quality factor of the output
filter and/or the higher the ratio FCE/FLC, the lower the FZ1
frequency (to maximize phase boost at FLC).
3. Calculate C2 such that FP1 is placed at FCE.
4. Calculate R3 such that FZ2 is placed at FLC. Calculate C3
such that FP2 is placed below FSW (typically, 0.5 to 1.0
times FSW). FSW represents the per-channel switching
frequency. Change the numerical factor to reflect desired
placement of this pole. Placement of FP2 lower in
frequency helps reduce the gain of the compensation
network at high frequency, in turn reducing the HF ripple
component at the COMP pin and minimizing resultant
duty cycle jitter.
It is recommended a mathematical model is used to plot the
loop response. Check the loop gain against the error
amplifier’s open-loop gain. Verify phase margin results and
adjust as necessary. The following equations describe the
frequency response of the modulator (GMOD), feedback
compensation (GFB) and closed-loop response (GCL):
COMPENSATION BREAK FREQUENCY EQUATIONS
Figure 25 shows an asymptotic plot of the DC/DC converter’s
gain vs frequency. The actual Modulator Gain has a high gain
peak dependent on the quality factor (Q) of the output filter,
which is not shown. Using the above guidelines should yield a
compensation gain similar to the curve plotted. The open loop
error amplifier gain bounds the compensation gain. Check the
compensation gain at FP2 against the capabilities of the error
amplifier. The closed loop gain, GCL, is constructed on the
log-log graph of Figure 25 by adding the modulator gain,
GMOD (in dB), to the feedback compensation gain, GFB (in
dB). This is equivalent to multiplying the modulator transfer
function and the compensation transfer function and then
plotting the resulting gain.
A stable control loop has a gain crossing with close to a
-20dB/decade slope and a phase margin greater than 45
degrees. Include worst case component variations when
determining phase margin. The mathematical model presented
R2 VOSC R1 F0
⋅⋅
dMAX VIN FLC
⋅⋅
---------------------------------------------=
C1 1
2πR2 0.5 FLC
⋅⋅⋅
------------------------------------------------=
C2 C1
2πR2 C1 FCE 1–⋅⋅⋅
---------------------------------------------------------=
R3 R1
FSW
FLC
------------ 1–
----------------------= C3 1
2πR3 0.7 FSW
⋅⋅⋅
-------------------------------------------------=
GMOD f() dMAX VIN
⋅
VOSC
------------------------------1sf() EC⋅⋅+
1sf() ED+()C⋅⋅s2f() LC⋅⋅++
----------------------------------------------------------------------------------------
⋅=
GFB f() 1sf() R2 C1⋅⋅+
sf() R1 C1 C2+()⋅⋅
------------------------------------------------------ ⋅=
1sf() R1 R3+()C3⋅⋅+
1sf() R3 C3⋅⋅+()1sf() R2 C1 C2⋅
C1 C2+
----------------------
⋅⋅+
⋅
-----------------------------------------------------------------------------------------------------------------------------
⋅
GCL f() GMOD f() GFB f()⋅=where s f(),2πfj⋅⋅=
FZ1
1
2πR2 C1⋅⋅
--------------------------------=
FZ2
1
2πR1 R3+()C3⋅⋅
---------------------------------------------------=
FP1
1
2πR2 C1 C2⋅
C1 C2+
----------------------
⋅⋅
-----------------------------------------------=
FP2
1
2πR3 C3⋅⋅
--------------------------------=
0
FP1
FZ2
OPEN LOOP E/A GAIN
FZ1 FP2
FLC FCE
COMPENSATION GAIN
GAIN
FREQUENCY
MODULATOR GAIN
FIGURE 25. ASYMPTOTIC BODE PLOT OF CONVERTER GAIN
CLOSED LOOP GAIN
20
dMAX V
⋅IN
VOSC
---------------------------------log
20 R2
R1
--------
log
LOG
LOG
F0
GMOD
GFB
GCL
ISL6567
21
makes a number of approximations and is generally not
accurate at frequencies approaching or exceeding half the
switching frequency. When designing compensation networks,
select target crossover frequencies in the range of 10% to 30%
of the per-channel switching frequency, FSW.
OUTPUT FILTER DESIGN
The output inductors and the output capacitor bank together
form a low-pass filter responsible for smoothing the square
wave voltage at the phase nodes. Additionally, the output
capacitors must also provide the energy required by a fast
transient load during the short interval of time required by the
controller and power train to respond. Because it has a low
bandwidth compared to the switching frequency, the output
filter limits the system transient response leaving the output
capacitor bank to supply the load current or sink the inductor
currents, all while the current in the output inductors
increases or decreases to meet the load demand.
In high-speed converters, the output capacitor bank is
amongst the costlier (and often the physically largest) parts
of the circuit. Output filter design begins with consideration
of the critical load parameters: maximum size of the load
step, ∆I, the load-current slew rate, di/dt, and the maximum
allowable output voltage deviation under transient loading,
∆VMAX. 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 according to
the following equation:
The filter capacitor must have sufficiently low ESL and ESR
so that ∆V < ∆VMAX.
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
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.
The ESR of the bulk capacitors is also responsible for the
majority of the output-voltage ripple. As the bulk capacitors
sink and source the inductor AC ripple current, a voltage
develops across the bulk-capacitor ESR equal to IPP
. Thus,
once the output capacitors are selected and a maximum
allowable ripple voltage, VPP(MAX), is determined from an
analysis of the available output voltage budget, the following
equation can be used to determine a lower limit on the
output inductance.
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
∆VMAX. This places an upper limit on inductance.
While the previous equation addresses the leading edge, the
following equation gives the upper limit on L for cases where
the trailing edge of the current transient causes a greater
output voltage deviation than the leading edge.
Normally, the trailing edge dictates the selection of L, if the
duty cycle is less than 50%. Nevertheless, both inequalities
should be evaluated, and L should be selected based on the
lower of the two results. In all equations in this paragraph, L
is the per-channel inductance and C is the total output bulk
capacitance.
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
layout and printed circuit design minimizes the voltage
spikes in the converter. Consider, as an example, the turnoff
transition of the upper PWM MOSFET. Prior to turnoff, the
upper MOSFET was carrying channel current. During the
turnoff, 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.
There are two sets of critical components in a DC/DC
converter using a ISL6567 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.
∆V ESL()
di
dt
-----ESR()∆I+≈
L ESR
VIN 2V
OUT
⋅–()VOUT
⋅
fSVIN VPP MAX()
⋅⋅
-----------------------------------------------------------------
⋅≥
L
4CV
OUT
⋅⋅
∆I()
2
-------------------------------- ∆VMAX ∆I ESR⋅–()⋅≤
L2.5 C⋅
∆I()
2
-----------------∆VMAX ∆IESR⋅–()VIN VO
–()⋅⋅≤
ISL6567
22
Although the ISL6567 allows for external adjustment of the
channel-to-channel current balancing (via the RISEN
resistors), it is desirable to have a symmetrical layout,
preferably with the controller equidistantly located from the
two power trains it controls. Equally important are the gate
drive lines (UGATE, LGATE, PHASE): since they drive the
power train MOSFETs using short, high current pulses, it is
important to size them accordingly and reduce their overall
impedance. Equidistant placement of the controller to the
two power trains also helps keeping these traces equally
long (equal impedances, resulting in similar driving of both
sets of MOSFETs).
The power components should be placed first. Locate the
input capacitors close to the power switches. Minimize the
length of the connections between the input capacitors, CIN,
and the power switches. Locate the output inductors and
output capacitors between the MOSFETs and the load.
Locate all the high-frequency decoupling capacitors
(ceramic) as close as practicable to their decoupling target,
making use of the shortest connection paths to any internal
planes, such as vias to GND immediately next, or even onto
the capacitor’s grounded solder pad.
The critical small components include the bypass capacitors
for VCC and PVCC. Locate the bypass capacitors, CBP,
close to the device. 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. It is
important to place the RISEN resistors close to the
respective terminals of the ISL6567.
A multi-layer printed circuit board is recommended. Figure 26
shows the connections of the critical components for one
VIA CONNECTION TO GROUND PLANE
ISLAND ON POWER PLANE LAYER
ISLAND ON CIRCUIT PLANE LAYER
KEY
LOCATE CLOSE TO IC
FIGURE 26. PRINTED CIRCUIT BOARD POWER PLANES AND ISLANDS
LOCATE NEAR LOAD
(MINIMIZE CONNECTION PATH)
ISL6567
+12VIN
Q1
Q2
Q3
Q4
COMP
FB
GND
VCC
BOOT1
BOOT2
UGATE1
UGATE2
REFTRK
LGATE1
LGATE2
LIN
LOUT1
(CHFIN1)
CBIN1
(CHFIN2)
CBIN2
CBOOT1
CBOOT2
LOUT2
(CHFOUT)
CBOUT
RPG
R2
R1
C1
C2
(CF1)
PHASE1
PHASE2
VOUT
PGND
PVCC
(CF2)
+5VIN
MON
EN
RFS
PGOOD
REN
R2
HEAVY TRACE ON CIRCUIT PLANE LAYER
LOCATE NEAR SWITCHING TRANSISTORS
(MINIMIZE CONNECTION PATH)
(MINIMIZE CONNECTION PATH)
RISEN1
ISEN1
RISEN2
ISEN2
RGND
VSEN
VDIFF
CSS
SS
FS
RS
RP
ISL6567
23
output channel of the converter. Note that capacitors CxxIN
and CxxOUT 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 inductor LOUT 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.
Size the trace interconnects commensurate with the signals
they are carrying. Use narrow (0.005” to 0.008”) and short
traces for the high-impedance, small-signal connections, such
as the feedback, compensation, soft-start, frequency set,
enable, reference track, etc. The wiring traces from the IC to
the MOSFETs’ gates and sources should be wide (0.02” to
0.05”) and short, encircling the smallest area possible.
Component Selection Guidelines
MOSFETS
The selection of MOSFETs revolves closely around the
current each MOSFET is required to conduct, the switching
characteristics, the capability of the devices to dissipate heat,
as well as the characteristics of available heat sinking. Since
the ISL6567 drives the MOSFETs with a 5V signal, the
selection of appropriate MOSFETs should be done by
comparing and evaluating their characteristics at this specific
VGS bias voltage. The following paragraphs addressing
MOSFET power dissipation ignore the driving losses
associated with the gate resistance.
The aggressive design of the shoot-through protection
circuits, part of the ISL6567 output drivers, is geared toward
reducing the deadtime between the conduction of the upper
and the lower MOSFET/s. The short deadtimes, coupled with
strong pull-up and pull-down output devices driving the
UGATE and LGATE pins make the ISL6567 best suited to
driving low gate resistance (RG), late-generation MOSFETs. If
employing MOSFETs with a nominal gate resistance in
excess of 1-2Ω, check for the circuit’s proper operation. A few
examples (non exclusive list) of suitable MOSFETs to be used
in ISL6567 applications include the D8 (and later) generation
from Renesas and the OptiMOS®2 line from Infineon. Along
the same line, the use of gate resistors is discouraged, as
they may interfere with the circuits just mentioned.
LOWER MOSFET POWER CALCULATION
Since virtually all of the heat loss in the lower MOSFET is
conduction loss (due to current conducted through the
channel resistance, rDS(ON)), a quick approximation for heat
dissipated in the lower MOSFET can be found in the
following equation:
where: IM is the maximum continuous output current, IL,PP is
the peak-to-peak inductor current, and D is the duty cycle
(approximately VOUT/VIN).
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.
The above equation assumes the current through the lower
MOSFET is always positive; if so, the total power dissipated
in each lower MOSFET is approximated by the summation of
PLMOS1 and PLMOS2.
UPPER MOSFET POWER CALCULATION
In addition to rDS(ON) losses, a large portion of the upper-
MOSFET losses are switching losses, due to currents
conducted through the device while the input voltage is
present as VDS. Upper MOSFET losses can be divided into
separate components, separating the upper-MOSFET
switching losses, the lower-MOSFET body diode reverse
recovery charge loss, and the upper MOSFET rDS(ON)
conduction loss.
In most typical circuits, when the upper MOSFET turns off, it
continues to conduct a decreasing fraction of the output
inductor current as the voltage at the phase node falls below
ground. Once the lower MOSFET begins conducting (via its
body diode or enhancement channel), the current in the
upper MOSFET decreases to zero. In the following equation,
the required time for this commutation is t1and the
associated power loss is PUMOS,1.
Similarly, the upper MOSFET begins conducting as soon as
it begins turning on. Assuming the inductor current is in the
positive domain, the upper MOSFET sees approximately the
input voltage applied across its drain and source terminals,
while it turns on and starts conducting the inductor current.
PLMOS1 rDS ON()
IOUT
2
-------------
2
1D–()
ILPP,
21D–()
12
--------------------------------+=
PLMOS2 VDON()
fS
IOUT
2
------------- IPP
2
---------+
td1
IOUT
2
------------- IPP
2
---------–
td2
+
=
PUMOS 1,VIN
IOUT
N
------------- ILPP,
2
-------------+
t1
2
----
fS
≈
ISL6567
24
This transition occurs over a time t2, and the approximate
the power loss is PUMOS,2.
A third component involves the lower MOSFET’s reverse-
recovery charge, QRR. Since the lower MOSFET’s body
diode conducts the full inductor current before it has fully
switched to the upper MOSFET, the upper MOSFET has to
provide the charge required to turn off the lower MOSFET’s
body diode. This charge is conducted through the upper
MOSFET across VIN, the power dissipated as a result,
PUMOS,3 can be approximated as:
Lastly, the conduction loss part of the upper MOSFET’s
power dissipation, PUMOS,4, can be calculated using the
following equation:
In this case, of course, rDS(ON) is the ON resistance of the
upper MOSFET.
The total power dissipated by the upper MOSFET at full load
can be approximated as the summation of these results.
Since the power equations depend on MOSFET parameters,
choosing the correct MOSFETs can be an iterative process
that involves repetitively solving the loss equations for
different MOSFETs and different switching frequencies until
converging upon the best solution.
OUTPUT CAPACITOR SELECTION
The output capacitor is selected to meet both the dynamic
load requirements and the voltage ripple requirements. The
load transient a microprocessor impresses is characterized
by high slew rate (di/dt) current demands. In general,
multiple high quality capacitors of different size and dielectric
are paralleled to meet the design constraints.
Should the load be characterized by high slew rates, attention
should be particularly paid to the selection and placement of
high-frequency decoupling capacitors (MLCCs, typically -
multi-layer ceramic capacitors). High frequency capacitors
supply the initially transient current and slow the load rate-of-
change seen by the bulk capacitors. The bulk filter capacitor
values are generally determined by the ESR (effective series
resistance) and capacitance requirements.
High frequency decoupling capacitors should be placed as
close to the power pins of the load, or for that reason, to any
decoupling target they are meant for, as physically possible.
Attention should be paid as not to add inductance in the
circuit board wiring that could cancel the usefulness of these
low inductance components. Consult with the manufacturer
of the load on specific decoupling requirements.
Use only specialized low-ESR capacitors intended for
switching-regulator applications for the bulk capacitors. The
bulk capacitor’s ESR determines the output ripple voltage
and the initial voltage drop following a high slew-rate
transient’s edge. In most cases, multiple capacitors of small
case size perform better than a single large case capacitor.
Bulk capacitor choices include aluminum electrolytic, OS-Con,
Tantalum and even ceramic dielectrics. An aluminum
electrolytic capacitor’s ESR value is related to the case size
with lower ESR available in larger case sizes. However, the
equivalent series inductance (ESL) of these capacitors
increases with case size and can reduce the usefulness of the
capacitor to high slew-rate transient loading. Unfortunately,
ESL is not a specified parameter. Consult the capacitor
manufacturer and/or measure the capacitor’s impedance with
frequency to help select a suitable component.
OUTPUT INDUCTOR SELECTION
One of the parameters limiting the converter’s response to a
load transient is the time required to change the inductor
current. In a multi-phase converter, small inductors reduce
the response time with less impact to the total output ripple
current (as compared to single-phase converters).
The output inductor of each power channel controls the
ripple current. The control IC is stable for channel ripple
current (peak-to-peak) up to twice the average current. A
single channel’s ripple current is approximated by:
The current from multiple channels tend to cancel each other
and reduce the total ripple current. The total output ripple
current can be determined using the curve in Figure 27; it
PUMOS 2,VIN
IOUT
N
------------- ILPP,
2
-------------–
t2
2
----
fS
≈
PUMOS 3,VIN Qrr fS
=
PUMOS 4,rDS ON()
IOUT
N
-------------
2
dIPP
2
12
----------
+=
1.0
0.8
0.6
0.4
0.2
0
00.1 0.2 0.3 0.4 0.5
DUTY CYCLE (VO/VIN)
FIGURE 27. RIPPLE CURRENT vs DUTY CYCLE
CURRENT MULTIPLIER, KCM
ILPP,
VIN VOUT
–
FSW L⋅
--------------------------------VOUT
VIN
----------------
×=
ISL6567
25
provides the total ripple current as a function of duty cycle
and number of active channels, normalized to the parameter
KNORM at zero duty cycle.
where L is the channel inductor value.
Find the intersection of the active channel curve and duty
cycle for your particular application. The resulting ripple
current multiplier from the y-axis is then multiplied by the
normalization factor, KNORM, to determine the total output
ripple current for the given application.
INPUT CAPACITOR SELECTION
The important parameters for the bulk input capacitors are
the voltage rating and the RMS current rating. For reliable
operation, select bulk input capacitors with voltage and
current ratings above the maximum input voltage and
largest RMS current required by the circuit. The capacitor
voltage rating should be at least 1.25 times greater than the
maximum input voltage. The input RMS current required for
a multi-phase converter can be approximated with the aid
of Figure 28. For a more exact calculation of the input RMS
current use the following equation:
As 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. Figure 28 can be used to determine the input-
capacitor RMS current function of duty cycle, maximum
sustained output current (IO), and the ratio of the peak-to-
peak inductor current (IL,PP) to the maximum sustained load
current, IO.
Use a mix of input bypass capacitors to control the input
voltage ripple. Use ceramic capacitance for the high
frequency decoupling and bulk capacitors to supply the
RMS current. Minimize the connection path inductance of
the high frequency decoupling ceramic capacitors (from
drain of upper MOSFET to source of lower MOSFET).
For bulk capacitance, several electrolytic or high-capacity MLC
capacitors may be needed. For surface mount designs, solid
tantalum capacitors can be used, but caution must be
exercised with regard to the capacitor surge current rating.
These capacitors must be capable of handling the surge-
current at power-up.
APPLICATION SYSTEM DC TOLERANCE
Although the ISL6567 features a tight voltage reference, the
overall system DC tolerance can be affected by the
tolerance of the other components employed. The resistive
divider used to set the output voltage will directly influence
the system DC voltage tolerance. Figure 29 details the
absolute worst case tolerance stack-up for 1% and 0.1%
feedback resistors, and assuming the ISL6567 is regulating
at 0.8% above its nominal reference. Other component
tolerance stack-ups may be investigated using the following
equation, where REFTM, RPTM, and RSTM are the tolerance
multipliers corresponding to VREF
, RS, and RP
, respectively.
KNORM
VOUT
LF
SW
⋅
--------------------=
ITOTAL
∆KNORM KCM
⋅=
IIN RMS()IO
2DD
2
–()⋅I2LPP,D
12
------
⋅+=
0.3
0.1
0
0.2
INPUT CAPACITOR CURRENT (IIN(RMS) / IO)
FIGURE 28. NORMALIZED INPUT RMS CURRENT vs DUTY
CYCLE FOR A 2-PHASE CONVERTER
00.2 0.50.1 0.3 0.4
DUTY CYCLE (VO /VIN)
IL,PP = 0
IL,PP = 0.5 x IO
IL,PP = 0.75 x IO
TOL
REFTM
k1–()RSTM
⋅RPTM
+
kR
PTM
⋅
-------------------------------------------------------------
⋅1–
100
------------------------------------------------------------------------------------------------= [%]
FIGURE 29. WORST CASE SYSTEM DC REGULATION
TOLERANCE (VREF AT 0.8% ABOVE NOMINAL)
0.8
1.0
1.2
1.4
1.6
1.8
2.0
2.2
2.4
2.6
2.8
123456789
10
Tolerance (%)
k = VOUT/VREF
RSTM = 1.01
RPTM = 0.99
RPTM = 0.999
RSTM = 1.001
REFTM = 1.008
REFTM = 1.008
ISL6567
26
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ISL6567
Quad Flat No-Lead Plastic Package (QFN)
Micro Lead Frame Plastic Package (MLFP)
L24.4x4
24 LEAD QUAD FLAT NO-LEAD PLASTIC PACKAGE
(COMPLIANT TO JEDEC MO-220VGGD-2 ISSUE C)
SYMBOL
MILLIMETERS
NOTESMIN NOMINAL MAX
A 0.80 0.90 1.00 -
A1 - - 0.05 -
A2 - - 1.00 9
A3 0.20 REF 9
b 0.18 0.23 0.30 5, 8
D 4.00 BSC -
D1 3.75 BSC 9
D2 1.95 2.10 2.25 7, 8
E 4.00 BSC -
E1 3.75 BSC 9
E2 1.95 2.10 2.25 7, 8
e 0.50 BSC -
k0.25 - - -
L 0.30 0.40 0.50 8
L1 - - 0.15 10
N242
Nd 6 3
Ne 6 3
P- -0.609
θ--129
Rev. 2 10/02
NOTES:
1. Dimensioning and tolerancing conform to ASME Y14.5-1994.
2. N is the number of terminals.
3. Nd and Ne refer to the number of terminals on each D and E.
4. All dimensions are in millimeters. Angles are in degrees.
5. Dimension b applies to the metallized terminal and is measured
between 0.15mm and 0.30mm from the terminal tip.
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.
7. Dimensions D2 and E2 are for the exposed pads which provide
improved electrical and thermal performance.
8. Nominal dimensions are provided to assist with PCB Land Pattern
Design efforts, see Intersil Technical Brief TB389.
9. Features and dimensions A2, A3, D1, E1, P & θ are present when
Anvil singulation method is used and not present for saw
singulation.
10. Depending on the method of lead termination at the edge of the
package, a maximum 0.15mm pull back (L1) maybe present. L
minus L1 to be equal to or greater than 0.3mm.
