INTERSIL ISL6219

ISL6219
®
Data Sheet
June 2002
Microprocessor CORE Voltage Regulator
Precision Multi-Phase BUCK PWM
Controller for Mobile Applications
The ISL6219 provides core-voltage regulation by driving up
to three interleaved synchronous-rectified buck-converter
channels in parallel. Intersil multi-phase controllers together
with ISL6207 gate drivers form the basis for the most reliable
power-supply solutions available to power the latest
industry-leading microprocessors. Multi-phase buckconverter architecture uses interleaved timing to multiply
ripple frequency and reduce input and output ripple currents.
Lower ripple results in lower total component cost, reduced
dissipation, and smaller implementation area. Preconfigured for 3-phase operation, the ISL6219 also offers 2phase operation. Simply connect the unused PWM pin to
+5V. The channel switching frequency is adjustable in the
range of 100kHz to 1.5MHz giving the designer the ultimate
flexibility in managing the balance between high-speed
response and good thermal management.
New features on the ISL6219 include Dynamic-VID™
technology allowing seamless on-the-fly VID changes with
no need for any additional external components. When the
ISL6219 receives a new VID code, it incrementally steps the
output voltage to the new level. Dynamic VID™ changes are
fast and reliable with no output voltage overshoot or
undershoot.
Like other Intersil multiphase controllers, the ISL6219 uses
cost and space-saving rDS(ON) sensing for channel current
balance and dynamic voltage positioning. Channel current
balancing is automatic and accurate with the integrated
current-balance control system. Over current protection can
be tailored to any application with no need of additional
parts.
An integrated DAC decodes the 5-bit logic signal present at
VID0-VID4 and provides an accurate reference for precision
voltage regulation. The high-bandwidth error amplifier and
accurate voltage reference all work together to provide
better than 0.8% total system accuracy, and to enable the
fastest transient response available. A window comparator
toggles PGOOD if the output voltage moves out of range
and acts to protect the load in case of over voltage.
1
FN9080.1
Features
• Multi-Phase Power Conversion
• Active Channel Current Balancing
• Lossless current sense scheme
- Uses MOSFET’s RDS(ON)
- Optional current sense method higher precision
• Precision CORE Voltage Regulation
- ±0.8% System Accuracy Over Temperature
• Microprocessor Voltage Identification Input
- Dynamic VID technology
- 5-Bit VID Input
- 1.100V to 1.850V in 25mV Steps
• Programmable Droop Voltage
• Fast Transient Recovery Time
• Over Voltage, Under Voltage and Overcurrent Protection
• Power-Good Output
• 2 or 3 Phase Operation
• User selectable Switching Frequency of 100K - 1.5MHz
- 200KHz - 4.5MHz Effective Ripple Frequency
Ordering Information
PART NUMBER
ISL6219CA
TEMP. (oC)
PACKAGE
-10 to 85
28-Ld SSOP
PKG. NO.
M28.15
Pinout
ISL6219 (28 LEAD SSOP)
TOP VIEW
VID 0
1
28
VCC
VID 1
2
27
NC
VID 2
3
26
NC
VID 3
4
25
PGOOD
VID 4
5
24
NC
NC
6
23
ISEN1
FSET/EN
7
22
PWM1
NC
8
21
PWM2
FB
9
20
ISEN2
COMP
10
19
ISEN3
NC
11
18
PWM3
NC
12
17
NC
NC
13
16
VSEN
GND
14
15
NC
CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures.
1-888-INTERSIL or 321-724-7143 | Intersil (and design) is a trademark of Intersil Americas Inc.
Copyright © Intersil Americas Inc. 2002. All Rights Reserved
Dynamic VID is a trademark of Intersil Americas Inc.
ISL6219
Block Diagram
VCC
PGOOD
POWER-ON
RESET (POR)
VSEN
+
UV
THREE-STATE
-
X 0.92
OV
LATCH
+
CLOCK AND
SAWTOOTH
GENERATOR
+
OV
∑
-
X1.15
+
+
PWM1
PWM
-
SOFTSTART
AND FAULT
LOGIC
FSET/EN
-
∑
+
PWM2
PWM
-
COMP
+
∑
+
-
VID0
PWM3
PWM
-
VID1
VID2
DYNAMIC
VID
D/A
VID3
+
VID4
-
E/A
CURRENT
FB
CORRECTION
PHASE
NUMBER
CHANNEL
DETECTOR
ISEN1
I_TOT
-
+
∑
+
OC
+
I_TRIP
GND
2
+
ISEN2
ISEN3
ISL6219
Typical Application - 3-Phase Buck Converter
+5V
VIN
VCC
BOOT
UGATE
EN
RFB
PHASE
PWM1
RC
ISL6207
DRIVER
+5V
LGATE
GND
CC
FB
L1
+5V
COMP
VIN
VCC
VSEN
VCC
PGOOD
ISL6219
RISEN1
EN
ISEN1
VID0
BOOT
UGATE
PWM2
PHASE
ISL6207
DRIVER
LGATE
PWM1
VID1
PWM2
VID2
L2
GND
RISEN2
ISEN2
VID3
PWM3
VID4
FSET/EN
RISEN3
+5V
VIN
ISEN3
VCC
RT
BOOT
UGATE
EN
GND
PWM3
L3
PHASE
ISL6207
DRIVER
LGATE
GND
3
µP
LOAD
CO
ISL6219
Functional Pin Descriptions
VID0, VID1, VID2, VID3, VID4 (Pins 1, 2, 3, 4, 5)
These are the inputs to the internal DAC that provide the
reference voltage for output regulation. Each pin has an
internal 20µA pull-up current source to 2.5V making the parts
compatible with CMOS and TTL logic from 5V down to 2.5V.
When a VID change is detected the reference voltage slowly
ramps up or down to the new value in 25mV steps. Connect
these pins to either open-drain or active-pull-up type outputs.
Pulling these pins above 2.9V can cause a reference offset
inaccuracy.
FSET/EN (Pin 7)
This pin has two functions. A resistor placed from FS to
ground sets the switching frequency. There is an inverse
relationship between the value of the resistor and the
switching frequency. This pin can also be used to enable the
IC. See Figure 8 for details.
FB (Pin 8) and COMP (Pin 9)
The internal error amplifier’s inverting input and output
respectively. These pins are connected to an external R-C
network to compensate the regulator.
GND (Pin 14)
Return for VCC and signal ground for the IC.
4
VSEN (Pin 15)
Power good monitor input. Connect to the microprocessorCORE voltage.
PWM3, PWM2, PWM1 (Pins 18, 21, 22)
Pulse-width modulation outputs. These logic outputs tell the
driver IC(s) when to turn the MOSFETs on and off.
ISEN3, ISEN2, ISEN1 (PINS 19, 20, 23)
Current sense inputs. A resistor connected between these
pins and the respective phase nodes has a current
proportional to the current in the lower MOSFET during its
conduction interval. The current is used as a reference for
channel balancing, load sharing, protection, and load-line
regulation.
PGOOD (Pin 25)
Power good. This pin is an open-drain logic signal that
indicates when the microprocessor CORE voltage (VSEN
pin) is within specified limits and soft-start has timed out.
VCC (Pin 28)
Bias supply voltage for the controller. Connect this pin to a
5V power supply.
ISL6219
Absolute Maximum Ratings
Thermal Information
Supply Voltage, VCC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7V
Input, Output, or I/O Voltage . . . . . . . . . . GND -0.3V to VCC + 0.3V
ESD Classification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3kV
Thermal Resistance (Typical, Note 1)
Recommended Operating Conditions
θJA (oC/W)
SSOP Package . . . . . . . . . . . . . . . . . . . . . . . . . . . .
100
Maximum Junction Temperature . . . . . . . . . . . . . . . . . . . . . . .150oC
Maximum Storage Temperature Range . . . . . . . . . -65oC to 150oC
Maximum Lead Temperature (Soldering 10s) . . . . . . . . . . . . .300oC
Supply Voltage. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . +5V ±5%
Ambient Temperature . . . . . . . . . . . . . . . . . . . . . . . . -10oC to 85oC
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.
NOTE:
1. θJA is measured with the component mounted on a high effective thermal conductivity test board in free air. (See Tech Brief TB379 for details.)
Operating Conditions: VCC = 5V, TA = -10oC to 85oC, Unless Otherwise Specified
Electrical Specifications
Parameter
Test Conditions
Min
Typ
Max
Units
RT = 100kΩ, EN = 5V
-
9.3
15
mA
RT = 100kΩ, EN = 0V
4.5
8.8
14
mA
VCC Rising
4.25
4.38
4.5
V
VCC Falling
3.75
3.88
4.0
V
-0.8
-
0.8
%VID
VID Pull Up
-
2.5
-
V
VID Input Low Level
-
-
0.8
V
2.0
-
-
V
-20
-
20
%
280
336
kHz
1500
kHz
INPUT SUPPLY POWER
Input Supply Current
Power-On Reset Threshold
SYSTEM ACCURACY
System Accuracy
VID Input High Level (Note 3)
OSCILLATOR
Accuracy
Frequency
RT = 100kΩ (±1%)
224
Adjustment Range
Guaranteed by design
100
Disable Voltage
-
1.23
1.1
V
Sawtooth Amplitude
-
1.54
-
V
Duty-Cycle Range Functional
0
-
75
%
ERROR AMPLIFIER
Open-Loop Gain
Guaranteed by design
-
72
-
dB
Open-Loop Bandwidth
Guaranteed by design
-
18
-
MHz
Slew Rate
CL=100pF, RL = 10kΩ to ground
-
5.3
-
V/µs
Maximum Output Voltage
RL = 10kΩ to ground
3.6
4.1
-
V
Minimum Output Voltage
RL = 10kΩ to ground
-
0.23
0.5
V
Full Scale Input Current
-
50
-
µA
Over-Current Trip Level
-
75
-
µA
-
0.18
0.4
V
ISEN
POWER GOOD MONITOR
PGOOD Low Output Voltage
IPGOOD = 4mA
PROTECTION and MONITOR
5
ISL6219
Operating Conditions: VCC = 5V, TA = -10oC to 85oC, Unless Otherwise Specified (Continued)
Electrical Specifications
Parameter
Test Conditions
Overvoltage Threshold
Undervoltage Threshold
Min
Typ
Max
Units
VSEN Rising
112
115
12
%VDAC
VSEN Falling
-
VID
-
%VDAC
VSEN Rising
85
92
95
%VDAC
VSEN Falling
80
83
90
%VDAC
NOTES:
2. These parts are designed and adjusted for accuracy within the system tolerance given in the Electrical Specifications. The system tolerance
accounts for offsets in the differential and error amplifiers; reference-voltage inaccuracies; temperature drift; and the full DAC adjustment range.
3. VID input levels above 2.9V may produce an reference-voltage offset inaccuracy. Use a current limit resistor (10K) when pull up to 5V.
.
CC
RC
VIN
COMP
-
L1
-
+
PWM
CIRCUIT
+
ISEN1
RISEN1
-
DAC
&
REFERENCE
VIN
PWM
CIRCUIT
+
PWM2
-
L2
ISL6207
FB
+
PWM1
ISL6207
ERROR
AMPLIFIER
PWM
CIRCUIT
AVERAGE
IOUT
VOUT
ISEN2
CO
RISEN2
VIN
-
CURRENT
SENSE
-
CURRENT
SENSE
-
CURRENT
SENSE
PWM3
+
+
ISL6207
+
RFB
ISEN3
RISEN3
VSEN
FIGURE 1. SIMPLIFIED BLOCK DIAGRAM OF THE ISL6219
6
L3
µP
LOAD
ISL6219
Operation
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.
Multi-Phase Power Conversion
Multi-phase power conversion provides the most costeffective 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 cost-saving advantages
with improved response time, superior ripple cancellation,
and excellent thermal distribution.
INTERLEAVING
The switching of each channel in a multi-phase converter is
timed to be symmetrically out of phase with each of the other
channels. In a 3-phase converter, each channel switches 1/3
cycle after the previous channel and 1/3 cycle before the
following channel. As a result, the three-phase converter has
a combined ripple frequency three times greater than the
ripple frequency of any one phase. In addition, the peak-topeak amplitude of the combined inductor currents is reduced
in proportion to the number of phases (Equations 1 and 2).
Increased ripple frequency and lower ripple amplitude mean
that the designer can use less per-channel inductance and
lower total output capacitance for any performance
specification.
( V IN – V OUT ) V OUT
I L, PP = ----------------------------------------------------L fS V
(EQ. 1)
IN
In Equation 1, VIN and VOUT are the input and output
voltages respectively, L is the single-channel inductor value,
and fS is the switching frequency.
( V IN – N V OUT ) V OUT
I PP = ----------------------------------------------------------L fS V
(EQ. 2)
IN
The output capacitors conduct the ripple component of the
inductor current. In the case of multi-phase converters, the
capacitor current is the sum of the ripple currents from each
of the individual channels. Compare Equation 1 to the
expression for the peak-to-peak current after the summation
of N symmetrically phase-shifted inductor currents in Equation 2. 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.
Input-capacitor current, 10A/DIV
IL1 + IL2 + IL3, 7A/DIV
IL3, 7A/DIV
Channel 3
input current
10A/DIV
PWM3, 5V/DIV
IL2, 7A/DIV
PWM2, 5V/DIV
Channel 2
input current
10A/DIV
IL1, 7A/DIV
Channel 1
input current
10A/DIV
PWM1, 5V/DIV
1µs/div
FIGURE 2. PWM AND INDUCTOR-CURRENT WAVEFORMS
FOR 3-PHASE CONVERTER
Figure 2 illustrates the multiplicative effect on output ripple
frequency. The three channel currents (IL1, IL2, and IL3),
combine to form the AC ripple current and the DC load
current. The ripple component has three times the ripple
frequency of each individual channel current. Each PWM
pulse is terminated 1/3 of a cycle, or 1.33µs, after the PWM
pulse of the previous phase. The peak-to-peak current
waveforms for each phase is about 7A, and the dc
components of the inductor currents combine to feed the load.
1µs/div
FIGURE 3. CHANNEL INPUT CURRENTS AND INPUTCAPACITOR RMS CURRENT FOR 3-PHASE
CONVERTER
Another benefit of interleaving is to reduce input ripple
current. Input capacitance is determined in part by the
maximum input ripple current. Multi-phase topologies can
improve overall system cost and size by lowering input ripple
current and allowing the designer to reduce the cost of input
capacitance. The example in Figure 3 illustrates input
currents from a three-phase converter combining to reduce
the total input ripple current.
The converter depicted in Figure 3 delivers 36A to a 1.5V
load from a 12V input. The rms input capacitor current is
5.9A. Compare this to a single-phase converter also down
7
ISL6219
12V to 1.5V at 36A. The single-phase converter has 11.9A
rms input capacitor current. The single-phase converter
must use an input capacitor bank with twice the rms current
capacity as the equivalent three-phase converter.
Figures 14, 15 and 16 the section entitled can be used to
determine the input-capacitor rms current based on load
current, duty cycle, and the number of channels. They are
provided as aids in determining the optimal input capacitor
solution. Figure 16 shows the single phase input-capacitor
rms current for comparisson.
VIN
In
r DS ( ON )
I
SEN = I L ------------------------R ISEN
CHANNEL N
UPPER MOSFET
IL
SAMPLE
&
HOLD
ISEN(n)
-
RISEN
+
I
r
L DS ( ON )
+
CHANNEL N
LOWER MOSFET
PWM OPERATION
The number of active channels selected determines the
timing for each channel. By default, the timing mode for the
ISL6219 is 3-phase. The designer can select 2-phase timing
by connecting PWM3 to VCC.
One switching cycle for the ISL6219 is defined as the time
between PWM1 pulse termination signals (the internal signal
that initiates a falling edge on PWM1). The cycle time is the
inverse of the switching frequency selected by the resistor
connected between the FS pin and ground (see Switching
Frequency). Each cycle begins when a clock signal
commands the channel-1 PWM output to go low. This
signals the channel-1 MOSFET driver to turn off the
channel-1 upper MOSFET and turn on the channel-1
synchronous MOSFET. If two-channel operation is selected,
the PWM2 pulse terminates 1/2 of a cycle later. If three
channels are selected the PWM2 pulse terminates 1/3 of a
cycle after PWM1, and the PWM3 output will follow after
another 1/3 of a cycle.
Once a channel’s PWM pulse terminates, it remains low for
a minimum of 1/4 cycle. This forced off time is required to
assure an accurate current sample as described in Current
Sensing. Following the 1/4-cycle forced off time, the
controller enables the PWM output. Once enabled, the PWM
output transitions high when the sawtooth signal crosses the
adjusted error-amplifier output signal, VCOMP as illustrated
in Figures 1 and 5. This is the signal for the MOSFET driver
to turn off the synchronous MOSFET and turn on the upper
MOSFET. The output will remain high until the clock signals
the beginning of the next cycle by commanding the PWM
pulse to terminate.
CURRENT SENSING
Intersil multi-phase controllers sense 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, channelcurrent balance, module current sharing, and overcurrent
protection. If desired, an independent current-sense resistor
in series with the lower-MOSFET source can serve as a
sense element in place of the MOSFET rDS(ON).
8
ISL6219 INTERNAL CIRCUIT
EXTERNAL CIRCUIT
FIGURE 4. INTERNAL AND EXTERNAL CURRENT-SENSING
CIRCUITRY
The ISEN input for each channel uses a ground-referenced
amplifier to reproduce a signal proportional to the channel
current (Figure 4). After sufficient settling time, the sensed
current is sampled, and the sample is used for current
balance, load-line regulation and overcurrent protection. The
ISL6219 samples channel current once each cycle. Figure 4
shows how the sampled current, In, is created from the
channel current IL. The circuitry in Figure 4 represents the
current measurement and sampling circuitry for channel n in
an N-channel converter. This circuitry is repeated for each
channel in the converter but will not be active in unused
channels.
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.
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
multi-phase controllers guarantee current balance by
comparing each channel’s current to the average current
delivered by all channels and making an appropriate
adjustment to each channel’s pulse width based on the
error. Intersil’s patented current-balance method is
illustrated in Figure 5 where the average of the 2 or 3
sampled channel currents combines with the channel 1
sample, I1, to create an error signal IER. The filtered error
signal modifies the pulse width commanded by VCOMP to
correct any unbalance and force IER toward zero.
In some circumstances, it may be necessary to deliberately
design some channel-current unbalance into the system. In
a highly compact design, one or two channels may be able
to cool more effectively than the other(s) due to nearby air
flow or heat sinking components. The other channel(s) may
ISL6219
have more difficulty cooling with comparatively less air flow
and heat sinking. The hotter channels may also be located
close to other heat-generating components tending to drive
their temperature even higher. In these cases, a proper
selection of the current sense resistors (RISEN in Figure 4)
introduces channel current unbalance into the system.
Increasing the value of RISEN in the cooler channels and
decreasing it in the hotter channels moves all channels into
thermal balance at the expense of current balance.
OUTPUT CURRENT, 20A/DIV
0A
OUTPUT VOLTAGE,
500mV/DIV
OVERCURRENT PROTECTION
The average current, IAVG in Figure 5, is continually
compared with a constant 75µA reference current. If the
average current at any time exceeds the reference current,
the comparator triggers the converter to shut down. All PWM
signals are placed in a high-impedance state which signals
the drivers to turn off both upper and lower MOSFETs. The
system remains in this state while the controller counts 2048
phase-clock cycles.
0V
5ms/DIV
FIGURE 6. OVERCURRENT BEHAVIOR IN HICCUP MODE
EXTERNAL CIRCUIT
VCOMP
CC
RC
+
+
-
ISL6219 INTERNAL CIRCUIT
COMP
PWM1
ERROR AMPLIFIER
FB
-
SAWTOOTH SIGNAL
f(jω)
I3
IER
IAVG
-
÷N
+
RFB
+
+
VDROOP
IAVG
-
Σ
VCOMP
REFERENCE
VOLTAGE(VDAC)
I2
VSEN
I1
VOUT
FIGURE 5. CHANNEL-1 PWM FUNCTION AND CURRENTBALANCE ADJUSTMENT
This is followed by a soft-start attempt (see Soft-Start). If the
soft-start attempt is successful, operation will continue as
normal. Should the soft-start attempt fail, the ISL6219
repeats the 2048-cycle wait period and follows with another
soft-start attempt. This hiccup mode of operation continues
indefinitely as shown in Figure 6 as long as the controller is
enabled or until the overcurrent condition resolves.
FIGURE 7. OUTPUT-VOLTAGE AND LOAD-LINE
REGULATION
TABLE 1. VOLTAGE IDENTIFICATION CODES
VID4
VID3
VID2
VID1
VID0
VDAC
1
1
1
1
1
Off
1
1
1
1
0
1.100
1
1
1
0
1
1.125
The ISL6219 uses a digital to analog converter (DAC) to generate a reference voltage based on the logic signals at pins
VID4 to VID0. The DAC decodes the a 5-bit logic signal (VID)
into one of the discrete voltages shown in Table 1. Each VID
input offers a 20µA pull up to 2.5V for use with open-drain outputs. External pull-up resistors or active-high output stages
can augment the pull-up current sources, but a slight accuracy error can occur if they are pulled above 2.9V.
1
1
1
0
0
1.150
1
1
0
1
1
1.175
1
1
0
1
0
1.200
1
1
0
0
1
1.225
1
1
0
0
0
1.250
1
0
1
1
1
1.275
The integrating compensation network shown in Figure 7
assures that the steady-state error in the output voltage is
limited to the error in the reference voltage (output of the
DAC).
1
0
1
1
0
1.300
1
0
1
0
1
1.325
1
0
1
0
0
1.350
1
0
0
1
1
1.375
VOLTAGE REGULATION
9
ISL6219
TABLE 1. VOLTAGE IDENTIFICATION CODES (Continued)
LOAD-LINE REGULATION
VID4
VID3
VID2
VID1
VID0
VDAC
1
0
0
1
0
1.400
1
0
0
0
1
1.425
1
0
0
0
0
1.450
0
1
1
1
1
1.475
0
1
1
1
0
1.500
0
1
1
0
1
1.525
In applications with high transient current slew rates, the
lowest-cost solution for maintaining regulation often requires
some kind of controlled output impedance. The average
current of all active channels driven into FB pin. Average full
channel current is defined as 50 µA. This forces IAVG into the
summing node of the error amplifier and produces a voltage
drop across the feedback resistor, RFB, proportional to the
output current. In Figure 7, the steady-state value of
VDROOP is simply
0
1
1
0
0
1.550
0
1
0
1
1
1.575
0
1
0
1
0
1.600
0
1
0
0
1
1.625
0
1
0
0
0
1.650
0
0
1
1
1
1.675
0
0
1
1
0
1.700
0
0
1
0
1
1.725
0
0
1
0
0
1.750
0
0
0
1
1
1.775
0
0
0
1
0
1.800
0
0
0
0
1
1.825
0
0
0
0
0
1.850
OVERVOLTAGE PROTECTION
If the ISL6219 detects output voltages above 115% of VID,
the controller will immediately commands all PWM outputs
low. This directs the Intersil drivers to turn on the lower
MOSFETs and protect the load by preventing any further
increase in output voltage. Once the output voltage falls to
the level set by the VID code, the PWM outputs enter highimpedance mode. The Intersil drivers respond by turning off
both upper and lower MOSFETs. If the overvoltage condition
reoccurs, the ISL6219 will again command the lower
MOSFETs to turn on. The ISL6219 will continue to protect
the load in this fashion as long as the overvoltage repeats.
After detecting an overvoltage condition, the ISL6219
terminated normal PWM operation until it is reset by power
cycle in which VCC is removed below the POR falling
threshold and restored above the POR rising threshold as
described in Enable and Disable and Electrical
Specifications.
Under-Voltage
V DROOP = I AVG R FB
(EQ. 3)
As IAVG increased (more current demand at output), the voltage
at inverting node of error amplifier will be higher. This makes the
error amplifier adjusting the output voltage lower. Therefore, the
output voltage decreases as output current increases.
In the case that each channel uses the same value for RISEN to
sense channel current, and this is almost always true, a more
complete expression for VDROOP can be determined from the
expression for IAVG as it is derived from Figures 4 and 5.
I OUT
I AVG = ------------N
I OUT
V DROOP = ------------N
r DS ( ON )
---------------------R ISEN
(EQ. 4)
r DS ( ON )
---------------------- R FB
R ISEN
ENABLE AND DISABLE
The internal power-on reset circuit (POR) prevents the
ISL6219 from starting before the bias voltage at VCC
reaches the POR-rising threshold as defined in Electrical
Specifications.The POR level is high enough to guarantee
that all parts of the ISL6219 can perform their functions
properly. When VCC is below the POR-rising threshold, the
PWM outputs are held in a high-impedance state to assure
the drivers remain off.
VCC
1.23V
+
-
-
EXTERNAL CIRCUIT
+5V
+
FSET/EN
ENABLE
E
C
B
DISABLE
FIGURE 8. OPTIONAL ENABLE (EN) FUNCTION
The VSEN pin also detects when the CORE voltage falls
more than 18% below the VID programmed level. This
causes PGOOD to go low, but has no other effect on
operation and is not latched.
10
ISL6219 has an optional enable feature. A PNP transistor
connects to pin 7 of ISL6219, as shown in Figure 8, can enable
or disable the IC. Connect the base of the PNP to a voltage
source which is greater than 1.23V plus the diode drop of PNP,
this will enable the IC. If connect it to ground, IC will disable.
ISL6219
The 11111 VID code is reserved as a signal to the controller
that no load is present. The controller will enter shut-down
mode after receiving this code and will start up upon
receiving any other code.
Voltage Regulation. If the new code remains stable for
another full cycle, the ISL6219 begins incrementing the
reference by making 25mV change every two switching
cycles until it reaches the new VID code.
To enable the controller, VCC must be greater than the POR
threshold; the base of PNP transistor must be greater than
1.23V; and VID cannot be equal to 11111. Once these
conditions are true, the controller immediately initiates a soft
start sequence.
Since the ISL6219 recognizes VID-code changes only at the
beginnings of switching cycles, up to one full cycle may pass
before a VID change registers. This is followed by a onecycle wait before the output voltage begins to change. Thus,
the total time required for a VID change, tDV, is dependent
on the switching frequency (fS), the size of the change
(∆VID), and the time before the next switching cycle begins.
The one-cycle uncertainty in Equation 6 is due to the
possibility that the VID code change may occur up to one full
cycle before being recognized. The time required for a
converter running with fS = 500kHz to make a 1.5V to 1.7V
reference-voltage change is between 30µs and 32µs as
calculated using Equation 6. This example is also illustrated
in Figure 10
SOFT-START
After the POR function is completed with VCC reaching
4.38V, the soft-start sequence is initiated. Soft-Start, by its
slow rise in CORE voltage from zero, avoids an over-current
condition by slowly charging the output capacitors. This
voltage rise is initiated by an internal DAC that slowly raises
the reference voltage to the error amplifier input. The voltage
rise is controlled by the oscillator frequency and the DAC
within the controller, therefore, the output voltage is
effectively regulated as it rises to the final programmed
CORE voltage value.
For the first 32 PWM switching cycles, the DAC output
remains inhibited and the PWM outputs remain in a highimpedance state. From the 33rd cycle and for another,
approximately 150 cycles the PWM output remains low,
clamping the lower output MOSFETs to ground. The time
variability is due to the error amplifier, sawtooth generator and
comparators moving into their active regions. After this short
interval, the PWM outputs are enabled and increment the
PWM pulse width from zero duty cycle to operational pulse
width, thus allowing the output voltage to slowly reach the
CORE voltage. The CORE voltage will reach its programmed
value before the 2048 cycles, but the PGOOD output will not
be initiated until the 2048th PWM switching cycle.
V COMP
DELAY TIME
PGOOD
VCORE
5V
VCC
The soft-start time, tSS, is determined by an 11-bit counter
that increments with every pulse of the phase clock. For
example, a converter switching at 250kHz has a soft-start
time of
T SS = 2048
------------- = 8.2ms
f SW
(EQ. 5)
Figure 9 shows the waveforms when the regulator is
operating at 200kHz. Note that the soft-start duration is a
function of the Channel Frequency as explained previously.
Also note the pulses on the COMP terminal. These pulses
are the current correction signal feeding into the comparator
input (see the Block Diagram).
DYNAMIC VID
The ISL6219 is capable of executing on-the-fly outputvoltage changes. At the beginning of the phase-1 switching
cycle (defined in the section entitled PWM Operation), the
ISL6219 checks for a change in the VID code. The VID code
is the bit pattern present at pins VID4-VID0 as outlined in
11
VIN = 12V
FIGURE 9. START-UP OF 3 PHASE SYSTEM OPERATING AT
200kHz
.
.
1 2 ∆V ID
1  2 ∆V ID
-----  ---------------- – 1 < t DV ≤ -----  -----------------
f S  0.025
f S  0.025 
(EQ. 6)
General Design Guide
This design guide is intended to provide a high-level
explanation of the steps necessary to create a multi-phase
power converter. It is assumed that the reader is familiar with
many of the basic skills and techniques referenced below. In
addition to this guide, Intersil provides complete reference
ISL6219
01110
VID, 5V/div
00110
VID CHANGE OCCURS
ANYWHERE HERE
current (see Equation 1); d is the duty cycle (VOUT/VIN); and
L is the per-channel inductance.
2
I L ,PP
 I M 2
(1 – d)
P LOW ,1 = r DS ( ON )  ----- ( 1 – d ) + ------------------------------12
 N
(EQ. 7)
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.
VREF, 100mV/div
1.5V
VOUT, 100mV/div
1.5V
5µs/div
FIGURE 10. DYNAMIC-VID WAVEFORMS FOR 500KHz
ISL6219 BASED MULTI-PHASE BUCK
CONVERTER
designs that include schematics, bills of materials, and
example board layouts for all common microprocessor
applications. See the application note AN1018 for additional
information on applications of this controller.
Power Stages
The first step in designing a multi-phase converter is to
determine the number of phases. This determination
depends heavily on the cost analysis which in turn depends
on system constraints that differ from one design to the next.
Principally, the designer will be concerned with whether
components can be mounted on both sides of the circuit
board; whether through-hole components are permitted on
either side; and the total board space available for powersupply circuitry. Generally speaking, the most economical
solutions will be for each phase to handle between 15 and
20A. All-surface-mount designs will tend toward the lower
end of this current range and, if through-hole MOSFETs can
be used, higher per-phase currents are possible. In cases
where board space is the limiting constraint, current can be
pushed as high as 30A per phase, but these designs require
heat sinks and forced air to cool the MOSFETs.
MOSFETs
The choice of MOSFETs depends on the current each
MOSFET will be required to conduct; the switching frequency;
the capability of the MOSFETs to dissipate heat; and the
availability and nature of heat sinking and air flow.
LOWER MOSFET POWER CALCULATION
The calculation for heat dissipated in the lower MOSFET is
simple, since virtually all of the heat loss in the lower
MOSFET is due to current conducted through the channel
resistance (rDS(ON)). In Equation 7, IM is the maximum
continuous output current; IL,PP is the peak-to-peak inductor
12
I

I M I PP
M I PP t
P LOW , 2 = V D ( ON ) f S  ----- t d1 +  ----- – --------- d2
 N- + -------2
N
2 
(EQ. 8)
Thus the total power dissipated in each lower MOSFET is
approximated by the summation of PL and PD.
UPPER MOSFET POWER CALCULATION
In addition to rDS(ON) losses, a large portion of the upperMOSFET losses are due to currents conducted across the
input voltage (VIN) during switching. Since a substantially
higher portion of the upper-MOSFET losses are dependant
on switching frequency, the power calculation is somewhat
more complex. Upper MOSFET losses can be divided into
separate components involving the upper-MOSFET
switching times; the lower-MOSFET body-diode reverserecovery charge, Qrr; and the upper MOSFET rDS(ON)
conduction loss.
When the upper MOSFET turns off, the lower MOSFET
does not conduct any portion of the inductor current until the
voltage at the phase node falls below ground. Once the
lower MOSFET begins conducting, the current in the upper
MOSFET falls to zero as the current in the lower MOSFET
ramps up to assume the full inductor current. In Equation 9,
the required time for this commutation is t1and the
associated power loss is PUP,1.
 I M I L ,PP  t 1 
P UP,1 ≈ V IN  ----- + -------------  ----  f S
2   2
N
(EQ. 9)
Similarly, the upper MOSFET begins conducting as soon as
it begins turning on. In Equation 10, this transition occurs
over a time t2, and the approximate the power loss is PUP,2.
 I M I L ,PP  t 2 
P UP, 2 ≈ V IN  ----- – -------------  ----  f S
2  2
N
(EQ. 10)
A third component involves the lower MOSFET’s reverserecovery charge, Qrr. Since the inductor current has fully
commutated to the upper MOSFET before the lowerMOSFET’s body diode can recover all of Qrr, it is conducted
ISL6219
Load-Line Regulation Resistor
through the upper MOSFET across VIN. The power
dissipated as a result is PUP,3 and is simply
(EQ. 11)
P UP,3 = V IN Q rr f S
Finally, the resistive part of the upper MOSFET’s is given in
Equation 12 as PUP,4.
The load-line regulation resistor is labeled RFB in Figure 7.
Its value depends on the desired full-load droop voltage
(VDROOP in Figure 7). If Equation 13 is used to select each
ISEN resistor, the load-line regulation resistor is as shown
in Equation 15.
V DROOP
R FB = -----------------------–6
50 ×10
2
 I M
I PP2
P UP,4 = r DS ( ON )  ----- d + ---------12
(EQ. 12)
 N
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 now be approximated as the summation of the results
from Equations 9, 10, 11 and 12. 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.
Current Sensing
Pins 23, 20 and 19 are the ISEN pins denoted ISEN1, ISEN2
and ISEN3 respectively. The resistors connected between
these pins and the phase nodes determine the gains in the
load-line regulation loop and the channel-current balance
loop. Select the values for these resistors based on the room
temperature rDS(ON) of the lower MOSFETs; the full-load
operating current, IFL; and the number of phases, N
according to Equation 13 (see also Figure 4).
r DS ( ON ) I FL
- -------R ISEN = ---------------------50 ×10 – 6 N
(EQ. 13)
In certain circumstances, it may be necessary to adjust the
value of one or more of the ISEN resistors. This can arise
when the components of one or more channels are inhibited
from dissipating their heat so that the affected channels run
hotter than desired (see the section entitled Channel-Current
Balance). In these cases, chose new, smaller values of RISEN
for the affected phases. Choose RISEN,2 in proportion to the
desired decrease in temperature rise in order to cause
proportionally less current to flow in the hotter phase.
∆T 2
R ISEN ,2 = R ISEN ---------∆T 1
(EQ. 14)
In Equation 14, make sure that ∆T2 is the desired temperature
rise above the ambient temperature, and ∆T1 is the measured
temperature rise above the ambient temperature. While a
single adjustment according to Equation 14 is usually
sufficient, it may occasionally be necessary to adjust RISEN
two or more times to achieve perfect thermal balance
between all channels.
13
(EQ. 15)
If one or more of the ISEN resistors was adjusted for thermal
balance as in Equation 14, the load-line regulation resistor
should be selected according to Equation16 where IFL is the
full-load operating current and RISEN(n) is the ISEN resistor
connected to the nth ISEN pin.
V DROOP
R FB = -------------------------------I FL r DS ( ON )
∑ RISEN ( n )
(EQ. 16)
n
Compensation
The two opposing goals of compensating the voltage
regulator are stability and speed. Depending on whether the
regulator employs the optional load-line regulation as
described in Load-Line Regulation, there are two distinct
methods for achieving these goals.
COMPENSATING A LOAD-LINE REGULATED
CONVERTER
The load-line regulated converter behaves in a similar
manner to a peak-current mode controller because the two
poles at the output-filter L-C resonant frequency split with
the introduction of current information into the control loop.
The final location of these poles is determined by the system
function, the gain of the current signal, and the value of the
compensation components, RC and CC.
Since the system poles and zero are effected by the values
of the components that are meant to compensate them, the
solution to the system equation becomes fairly complicated.
Fortunately there is a simple approximation that comes very
close to an optimal solution. Treating the system as though it
were a voltage-mode regulator by compensating the L-C
poles and the ESR zero of the voltage-mode approximation
yields a solution that is always stable with very close to ideal
transient performance.
The feedback resistor, RFB, has already been chosen as outlined in Load-Line Regulation Resistor. Select a target bandwidth for the compensated system, f0. The target bandwidth
must be large enough to assure adequate transient performance, but smaller than 1/3 of the per-channel switching frequency. The values of the compensation components
depend on the relationships of f0 to the L-C pole frequency
and the ESR zero frequency. For each of the three cases
ISL6219
CC will not need adjustment. Keep the value of CC from
Equations 17 unless some performance issue is noted.
C2 (OPTIONAL)
CC
The optional capacitor C2, is sometimes needed to bypass
noise away from the PWM comparator (see Figure 5). Keep
a position available for C2, and be prepared to install a highfrequency capacitor of between 22pF and 150pF in case any
jitter problem is noted.
COMP
ISL6219
FB
+
RFB
VDROOP
COMPENSATION WITHOUT LOAD-LINE REGULATION
The non load-line regulated converter is accurately modeled
as a voltage-mode regulator with two poles at the L-C
resonant frequency and a zero at the ESR frequency. A type
III controller, as shown in Figure 12, provides the necessary
compensation.
VSEN
C2
FIGURE 11. COMPENSATION CONFIGURATION FOR
LOAD-LINE REGULATED ISL6219 CIRCUIT
defined below, there is a separate set of equations for the
compensation components.
Case 1:
COMP
FB
C1
R1
0.75V IN
C C = ----------------------------------2πV PP R FB f 0
+
RFB
VDROOP
VSEN
1
1
------------------≤ f 0 < -----------------------------2πC ( ESR )
2π LC
V PP ( 2π ) 2 f 02 LC
R C = R FB -------------------------------------------0.75 V
(EQ. 17)
IN
0.75V IN
C C = -----------------------------------------------------------( 2π ) 2 f 02 V PP R FB LC
Case 3:
CC
1
------------------> f0
2π LC
2πf 0 V pp LC
R C = R FB -----------------------------------0.75V IN
Case 2:
RC
ISL6219
RC
1
f 0 > -----------------------------2πC ( ESR )
2π f 0 V pp L
R C = R FB -----------------------------------------0.75 V IN ( ESR )
0.75V IN ( ESR ) C
C C = -----------------------------------------------2πV PP R FB f 0 L
In Equations 17, L is the per-channel filter inductance
divided by the number of active channels; C is the sum total
of all output capacitors; ESR is the equivalent-series
resistance of the bulk output-filter capacitance; and VPP is
the peak-to-peak sawtooth signal amplitude as described in
Figure 5 and Electrical Specifications.
Once selected, the compensation values in Equations 17
assure a stable converter with reasonable transient performance. In most cases, transient performance can be
improved by making adjustments to RC. Slowly increase the
value of RC while observing the transient performance on an
oscilloscope until no further improvement is noted. Normally,
14
FIGURE 12. COMPENSATION CIRCUIT FOR ISL6219 BASED
CONVERTER WITHOUT LOAD-LINE
REGULATION.
The first step is to choose the desired bandwidth, f0, of the
compensated system. Choose a frequency high enough to
assure adequate transient performance but not higher than
1/3 of the switching frequency. The type-III compensator has
an extra high-frequency pole, fHF. This pole can be used for
added noise rejection or to assure adequate attenuation at
the error-amplifier high-order pole and zero frequencies. A
good general rule is to chose fHF = 10 f0, but it can be higher
if desired. Choosing fHF to be lower than 10 f0 can cause
problems with too much phase shift below the system
bandwidth.
In the solutions to the compensation equations, there is a
single degree of freedom. For the solutions presented in
Equations 18, RFB is selected arbitrarily. The remaining
compensation components are then selected according to
Equations 18.
LC – C ( ESR )C 1 = ---------------------------------------R FB
2
V PP  2π f 0 f HF LC
 
R C = --------------------------------------------------------------------

2π
f
0.75 V IN
HF  LC – 1
ISL6219
C ( ESR )
R 1 = R FB ----------------------------------------LC – C ( ESR )
0.75V IN
C 2 = -----------------------------------------------------------------2
( 2π ) f 0 f HF LCR FB V PP
(EQ. 18)
0.75V IN
C C = --------------------------------------------------------------------------------

1
2πV PP R f 0  1 – -----------------------------
FB 
2πf HF LC

In Equations 18, L is the per-channel filter inductance
divided by the number of active channels; C is the sum total
of all output capacitors; ESR is the equivalent-series
resistance of the bulk output-filter capacitance; and VPP is
the peak-to-peak sawtooth signal amplitude as described in
Figure 5 and “Electrical Specifications”.
Output Filter Design
The output inductors and the output capacitor bank together
form a low-pass filter responsible for smoothing the pulsating
voltage at the phase nodes. The output filter also must
provide the transient energy during the interval of time after
the beginning of the transient until the regulator can fully
respond. Because it has a low bandwidth compared to the
switching frequency, the output filter necessarily limits the
system transient response leaving the output capacitor bank
to supply or sink load current while the current in the output
inductors increases or decreases to meet the demand.
In high-speed converters, the output capacitor bank is
usually the most costly (and often the largest) part of the
circuit. Output filter design begins with minimizing the cost of
this part of the circuit. The critical load parameters in
choosing the output capacitors are the maximum size of the
load step, ∆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 outputvoltage deviation is less than the allowable maximum.
Neglecting the contribution of inductor current and regulator
response, the output voltage initially deviates by an amount
di
∆V ≈ ( ESL ) ----- + ( ESR ) ∆I
dt
(EQ. 19)
The filter capacitor must have sufficiently low ESL and ESR
so that ∆V < ∆VMAX.
15
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 also creates the majority of
the output-voltage ripple. As the bulk capacitors sink and
source the inductor ac ripple current (see Interleaving and
Equation 2), a voltage develops across the bulk-capacitor
ESR equal to IPP (ESR). Thus, once the output capacitors
are selected, the maximum allowable ripple voltage,
VPP(MAX), determines the a lower limit on the inductance.
V – N V

OUT V OUT
 IN
L ≥ ( ESR ) -----------------------------------------------------------f S V IN V PP( MAX )
(EQ. 20)
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 limits on inductance.
2NCVO
L ≤ --------------------- ∆V MAX – ∆I ( ESR )
( ∆I ) 2
( 1.25 ) NC
L ≤ -------------------------- ∆V MAX – ∆I ( ESR )  V IN – V O


( ∆I ) 2
(EQ. 21)
(EQ. 22)
Equation 22 gives the upper limit on L for the cases when the
trailing edge of the current transient causes a greater outputvoltage deviation than the leading edge. Equation 21
addresses the leading edge. Normally, the trailing edge dictates
the selection of L because duty cycles are usually less than
50%. Nevertheless, both inequalities should be evaluated, and
L should be selected based on the lower of the two results. In
each equation, L is the per-channel inductance, C is the total
output capacitance, and N is the number of active channels.
Switching Frequency
There are a number of variables to consider when choosing
the switching frequency. There are considerable effects on
the upper-MOSFET loss calculation and, to a lesser extent,
the lower-MOSFET loss calculation. These effects are
outlined in MOSFETs, and they establish the upper limit for
the switching frequency. The lower limit is established by the
requirement for fast transient response and small outputvoltage ripple as outlined in Output Filter Design. Choose
the lowest switching frequency that allows the regulator to
meet the transient-response requirements. Switching
frequency is determined by the selection of the frequencysetting resistor,RT (see the figure Typical Application on
ISL6219
page 3). Figure 13 and Equation 23 are provided to assist in
the selecting the correct value for RT.
(EQ. 23)
RT (kΩ)
1000
100
0.3
INPUT-CAPACITOR CURRENT (IRMS / IO)
RT = 10
[11.09 – 1.13 log ( f S ) ]
IPP = 0
IPP = 0.5 IO
IPP = 0.25 IO
IPP = 0.75 IO
0.2
0.1
0
0
0.2
0.4
0.6
0.8
1.0
DUTY CYCLE (VIN / VO)
10
FIGURE 15. NORMALIZED INPUT-CAPACITOR RMS
CURRENT VS DUTY CYCLE FOR 3-PHASE
10
100
1000
SWITCHING FREQUENCY (KHZ)
10000
0.6
Input Capacitor Selection
The input capacitors are responsible for sourcing the ac
component of the input current flowing into the upper
MOSFETs. Their rms current capacity must be sufficient to
handle the ac component of the current drawn by the upper
MOSFETs which is related to duty cycle and the number of
active phases.
Figures 14 and 15 can be used to determine the inputcapacitor rms current as of duty cycle, maximum sustained
output current (IO), and the ratio of the combined peak-topeak inductor current (IL,PP) to IO. Figure 16 is provided as a
reference to demonstrate the dramatic reductions in inputcapacitor rms current upon the implementation of the
multiphase topology.
INPUT-CAPACITOR CURRENT ( IRMS / IO )
0.3
0.2
0.1
IPP = 0
IPP = 0.5 IO
IPP = 0.75 IO
0
0
0.2
0.4
0.6
0.8
DUTY CYCLE (VO /VIN )
FIGURE 14. NORMALIZED INPUT-CAPACITOR RMS
CURRENT VS DUTY CYCLE FOR 2-PHASE
16
1.0
INPUT-CAPACITOR CURRENT (IRMS / IO)
FIGURE 13. RT VS SWITCHING FREQUENCY
0.4
0.2
IPP = 0
IPP = 0.5 IO
IPP = 0.75 IO
0
0
0.2
0.4
0.6
0.8
1.0
DUTY CYCLE (VIN / VO)
FIGURE 16. NORMALIZED INPUT-CAPACITOR RMS
CURRENT VS DUTY CYCLE FOR SINGLE-PHASE
CONVERTER
ISL6219
Shrink Small Outline Plastic Packages (SSOP)
M16.15A
N
INDEX
AREA
H
0.25(0.010) M
16 LEAD SHRINK NARROW BODY SMALL OUTLINE
PLASTIC PACKAGE
B M
E
GAUGE
PLANE
-B-
INCHES
SYMBOL
1
2
3
L
0.25
0.010
SEATING PLANE
-A-
h x 45o
A
D
-C-
α
e
A2
A1
B
C
0.10(0.004)
0.17(0.007) M
C A M
B S
NOTES:
1. Symbols are defined in the “MO Series Symbol List” in Section 2.2 of
Publication Number 95.
MIN
MAX
MILLIMETERS
MIN
MAX
NOTES
A
0.053
0.069
1.35
1.75
-
A1
0.004
0.010
0.10
0.25
-
A2
-
0.061
-
1.54
-
B
0.008
0.012
0.20
0.30
9
C
0.007
0.010
0.18
0.25
-
D
0.189
0.196
4.80
4.98
3
E
0.150
0.157
3.81
3.98
4
e
0.025 BSC
0.635 BSC
-
H
0.228
0.244
5.80
6.19
-
h
0.0099
0.0196
0.26
0.49
5
L
0.016
0.050
0.41
1.27
6
N
α
16
0o
16
8o
0o
7
8o
2. Dimensioning and tolerancing per ANSI Y14.5M-1982.
3. Dimension “D” does not include mold flash, protrusions or gate burrs.
Mold flash, protrusion and gate burrs shall not exceed 0.15mm (0.006
inch) per side.
Rev. 0 5/96
4. Dimension “E” does not include interlead flash or protrusions. Interlead
flash and protrusions shall not exceed 0.25mm (0.010 inch) per side.
5. The chamfer on the body is optional. If it is not present, a visual index
feature must be located within the crosshatched area.
6. “L” is the length of terminal for soldering to a substrate.
7. “N” is the number of terminal positions.
8. Terminal numbers are shown for reference only.
9. Dimension “B” does not include dambar protrusion. Allowable dambar
protrusion shall be 0.10mm (0.004 inch) total in excess of “B” dimension at maximum material condition.
10. Controlling dimension: INCHES. Converted millimeter dimensions are
not necessarily exact.
All Intersil U.S. products are manufactured, assembled and tested utilizing ISO9000 quality systems.
Intersil Corporation’s quality certifications can be viewed at www.intersil.com/design/quality
Intersil products are sold by description only. Intersil Corporation reserves the right to make changes in circuit design, software and/or specifications at any time without
notice. Accordingly, the reader is cautioned to verify that data sheets are current before placing orders. Information furnished by Intersil is believed to be accurate and
reliable. However, no responsibility is assumed by Intersil or its subsidiaries for its use; nor for any infringements of patents or other rights of third parties which may result
from its use. No license is granted by implication or otherwise under any patent or patent rights of Intersil or its subsidiaries.
For information regarding Intersil Corporation and its products, see www.intersil.com
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