ETC LX1672

LX1672
L I N F I N I T Y
Multiple Output LoadSHARE™ PWM
D I V I S I O N
P RELIMINARY D ATA S HEET
KEY FEATURES
DESCRIPTION
This patented approach also gives
system designers maximum flexibility
with respect to MOSFET supply. Each
phase can utilize different supply voltages,
for efficient use of available supplies,
while programming the ratio of current
pulled from each using one of three
methods (see application section).
The LX1672 incorporates fully
programmable
soft-start
sequencing
capabilities.
Each output can be
configured to come up in any order
necessary as required by the application.
The LX1672 features an additional
Linear Regulator Driver output, which
when coupled with an inexpensive
MOSFET is capable of supplying up to 5A
for I/O, memory, and other supplies
surrounding today’s micro-processor
designs.
Each regulator voltage output is
programmed via a simple voltage-divider
network. The LX1672, utilizing MOSFET
RDS(ON) impedance, monitors maximum
current limit conditions, in each PWM
phase without the use of expensive current
sense resistors.
Up to Three Independently
Regulated Outputs
DDR Termination Compliant
Bi-phase Current Sharing
Outputs As Low As 0.8V
Generated From An Internal 1%
Reference
Multiphase High Current Output
Reduces Required Capacitance
Integrated High Current MOSFET
Drivers
300KHz, 500KHz and 600KHz
High Frequency Operation
Minimizes External Component
Requirements
Independent Phase Programmable
Soft-Start and Power Sequencing
Adjustable Linear Regulator Driver
Output
No current-sense resistors
WWW . Microsemi .C OM
The LX1672 is a highly integrated
power supply controller IC featuring
two PWM switching regulator stages
with an additional onboard linear
regulator driver.
The two constant frequency voltagemode PWM phases can be easily
configured as a single Bi-Phase high
current output, two independently
regulated outputs, or as a DDR memory
I/O supply with a tracking DDR
termination voltage supply. Power loss
and noise, due to the ESR of the input
capacitors, are minimized by operating
each PWM output 180° out of phase.
This architecture also minimizes
capacitor
requirements
while
maximizing regulator response.
In bi-phase operation, the high
current output utilizes a patented current
sharing architecture, called Forced
Current Sharing†, to allow accurate
current sharing without the use of
expensive current sense resistors.
APPLICATIONS/BENEFITS
Multi-Output Power Supplies
Video Card Power Supplies
DDR, VDDQ and Termination
Supply
PC Peripherals
Portable PC Processor and I/O
Supply
IMPORTANT: For the most current data, consult MICROSEMI’s website: http://www.microsemi.com
LoadSHARE is a Trademark of Microsemi Corporation
PRODUCT HIGHLIGHT
DDR Term ination
Refer to Typical
Application for
com plete circuit.
Mem ory Core
....
12V
5V
LX1672
Graphics
Controller
Mem ory Bus
DDR Mem ory
LX1672
3.3V
I/O
TA (°C)
0 to 70
0 to 70
0 to 70
Copyright  2000
Rev. 0.3l, 2002-10-10
PACKAGE ORDER INFO
Plastic TSSOP
Switching
Frequency (kHz) PW 28-Pin
300
LX1672-03CPW
500
LX1672-05CPW
600
Plastic MLPQ
38-Pin
LX1672-03CLQ
LQ
LX1672-06CLQ
Microsemi
Linfinity Microelectronics Division
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 1
LX1672
L I N F I N I T Y
Multiple Output LoadSHARE™ PWM
D I V I S I O N
P RELIMINARY D ATA S HEET
PACKAGE PIN OUT
The limitation on transient time is thermal and is due to zener diodes on the
supply pins, brief application of maximum voltages will increase current into that
pin and increase package power dissipation..
x= Denote Phases 1 & 2
LQ
27
3
26
4
25
5
24
6
23
7
22
8
21
9
20
10
19
11
18
12
17
13
16
14
15
VC2
VC1
HO1
LO1
PG1
VCCL
VCC
VS1
CS1
EO1
FB1
SS1
DIS1
VS2
PW PACKAGE
(Top View)
HO2
VC2
LDGD
LDFB
LDDIS
DGND
AGND
RSVD
SS2
RF2
FB2
EO2
1
38
37
36
35
34
33
32
31
2
30
3
29
4
28
5
27
Connect Bottom to
Power GND
6
7
26
25
N.C.
N.C.
VCCL
VCC
DIS2
DIS1
N.C.
8
24
N.C.
9
23
10
22
PWGD
N.C.
11
12
PW Plastic TSSOP 28-Pin
THERMAL RESISTANCE-JUNCTION TO AMBIENT,
28
2
21
13
14
15
16
17
18
19
20
N.C.
N.C.
CS2
VS2
SS1
FB1
EO1
CS1
VS1
THERMAL DATA
1
LO1
HO1
VC1
N.C
.
N.C.
Note: Exceeding these ratings could cause damage to the device. All voltages are with
respect to Ground. Currents are positive into, negative out of specified
terminal.
HO2
LO2
PG2
LDGD
LDFB
LDDIS
DGND
AGND
DIS2
SS2
RF2
FB2
EO2
CS2
LO2
PG1
Supply Voltage (VCC) DC ................................................................ -0.3V to 5.5V
Supply Voltage (VCC) Transient...................................................... -0.3V to 6.0V
Driver Supply Voltage (VCx, VCCL) DC............................................ -0.3V to 16V
Driver Supply Voltage (VCx, VCCL) Transient ................................. -0.3V to 18V
Current Sense Inputs (VSX, CSX) ...................................................... -0.3V to 12V
Error Amplifier Inputs (FBX, RF2) ................................................... -0.3V to 5.5V
Input Voltage (SS/ SHDN) ................................................................. -0.3V to5.5V
Output Drive Peak Current Source (HOx, LOx)................................... 1A (500ns)
Output Drive Peak Current Sink (HOx, LOx) ...................................... 1A (500ns)
Operating Junction Temperature.................................................................. 150°C
Storage Temperature Range...........................................................-65°C to 150°C
Lead Temperature (Soldering 180 seconds)................................................. 235°C
WWW . Microsemi .C OM
ABSOLUTE MAXIMUM RATINGS
θJA
85°C/W
θJA
35°C/W
(N.C. – No Internal Connection
N/U – Not Used)
Plastic MLPQ 38-Pin
THERMAL RESISTANCE-JUNCTION TO AMBIENT,
Junction Temperature Calculation: TJ = TA + (PD x θJC).
The θJA numbers are guidelines for the thermal performance of the device/pc-board system.
All of the above assume no ambient airflow.
PACKAGE DATA
Copyright  2000
Rev. 0.3l, 2002-10-10
Microsemi
Linfinity Microelectronics Division
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 2
LX1672
L I N F I N I T Y
Multiple Output LoadSHARE™ PWM
D I V I S I O N
P RELIMINARY D ATA S HEET
NAME
DESCRIPTION
FB1
Bi-Phase Operation: Phase 1 and 2 Voltage Feedback
Single Phase Operation: Phase 1 Voltage Feedback – connected to the output through a resistor network to
set desired output voltage of Phase 1
EOX
Error Amplifier Output – Sets external compensation for the corresponding phase denoted by “X”.
FB2
Bi-phase Operation: Load Sharing Voltage Sense Feedback – Connect filtered phase 2 switching output (preinductor) to FB2 to ensure proper current sharing between phase 1 and phase 2.
Single Phase Operation: Phase 2 Voltage Feedback – connected to the output through a resistor network (post
inductor) to set desired output voltage of Phase 2.
RF2
Bi-Phase Operation: Load Sharing Voltage Sense Feedback Reference – Sets reference for current sharing
control loop. Connecting filtered phase 1 switching output (pre-inductor) to REF2 forces average current in
phase 2 to be equal to phase 1.
Single Phase Operation: Phase 2 Voltage Reference – connected to SS2 pin as reference.
VCC
IC supply voltage (nominal 5V).
VCCL
Power supply pin for all Low side drivers.
LDFB
Low Dropout Regulator Voltage Feedback – Sets output voltage of external MOSFET via resistor network.
CSX
Over-Current Limit Set – Connecting a resistor between CS pin and the source of the high-side MOSFET sets the
current-limit threshold for the corresponding phase denoted by “X”. Exceeding the current-limit threshold forces
the corresponding phase into hiccup mode protection. A minimum of 1KΩ must be in series with this input.
SSX
Soft-start/Hiccup Capacitor Pin – During start-up, the voltage on this pin controls the output voltage of its
respective regulator. An internal 20kΩ resistor and the external capacitor set the time constant for soft-start
function. The Soft-start function does not initialize until the supply voltage exceeds the UVLO threshold. When
an over-current condition occurs, this capacitor is used for the timing of hiccup mode protection.
AGND
Analog ground reference.
DGND
Digital ground reference.
LDGD
Low Dropout Regulator Gate Drive – Connects to gate of external N-Channel MOSFET for linear regulator
function.
Driver Power Ground. Connects to the source of the bottom N-channel MOSFETS of phase 1 where X=1, and
phase 2 where X=2 for the TSSOP. The MLPQ package has a common PG output .
HOX
High Side MOSFET Gate Driver – “X” denotes corresponding phase.
LOX
Low Side MOSFET Gate Driver – “X” denotes corresponding phase.
VCX
Phase High-Side MOSFET Gate Driver Supply – Connect to separate supply or boot strap supply to ensure
proper high-side gate driver supply voltage. “X” denotes corresponding phase. If the phase is not used connect to
VCC.
LDDIS
LDO Disable input. High disables the LDO output. This pin has a 100KΩ nominal pulldown resistor
VSX
Voltage reference for Current sense. This is also the supply pin for the Current Sense Comparator.
“X” denotes corresponding phase. This pin cannot be left floating, if the phase is not used connect to VCC
DISX
PWM Disable Input – High disables the PWM output. This pin has a nominal 80KΩ pulldown resistor. “X”
denotes corresponding phase.
PWGD
Open drain output , high at end of Soft Start and no Fault. Pulls low if any Fault condition occurs.
This output is present on the MLP package only.
Copyright  2000
Rev. 0.3l, 2002-10-10
Microsemi
Linfinity Microelectronics Division
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 3
PACKAGE DATA
PGX
WWW . Microsemi .C OM
FUNCTIONAL PIN DESCRIPTION
LX1672
L I N F I N I T Y
Multiple Output LoadSHARE™ PWM
D I V I S I O N
P RELIMINARY D ATA S HEET
Parameter
`
SWITCHING REGULATORS
Input Voltage
Input Voltage
Operation Current
Reference Voltage
`
`
`
`
Symbol
VCC
Min
LX1672
Typ
4.5
ICC
VSS
Static and Dynamic
TA = 25°C
0°C < TA < 70°C
TSSOP Package
MLPQ PAckage
LX1672-03 Load = 3000pF
LX1672-05 Load = 3000pF
LX1672-06 Load = 3000pF
Common Mode Input Voltage = 1V
0.792
0.784
-1
-1
-6.0
3.8
VCSX = VVSX – 0.3V , VVSX = 5V
Referenced to VSX , VVSX = 5V
45
260
0.808
0.816
1
1
250
150
6.0
70
16
5
100
3.5
.1
100
Current into VSX pins
LX1672-03
LX1672-05
LX1672-06
10
0.8
85
75
70
I Source = 2mA
I Sink = 10uA
Input Offset Voltage < 20mV
0 and 3.5 V Common Mode Input Voltage
Static
Static
CL = 3000pF
ISOURCE = 20mA, VCCL = 12V
ISINK = 20mA, VCCL = 12V
Max
5.5
16
VCCL, VCX
10
255
425
510
Microsemi
Linfinity Microelectronics Division
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Units
V
V
mA
V
%
%
nS
nS
%
%
%
mV
dB
MHz
V
mV
V
nA
50
300
350
55
340
µA
mV
nS
2
5
mA
0.25
mA
mA
nS
V
V
2.5
3
50
11
0.15
300
500
600
1.25
345
575
690
KHz
KHz
KHz
VPP
Page 4
ELECTRICALS
Line Regulation (Note 2)
Load Regulation (Note 2)
Minimum Pulse Width
Minimum Pulse Width
Maximum Duty Cycle
Maximum Duty Cycle
Maximum Duty Cycle
ERROR AMPLIFIERS
Input Offset Voltage
Vos
DC Open Loop Gain
Unity Gain Bandwidth
UGBW
High Output Voltage
VOH
Low Output Voltage
VOL
Input Common Mode Range
Input Bias Current
IIN
CURRENT SENSE
Current Sense Bias Current
ISET
Trip Threshold
VTRIP
Current Sense Delay
TCSD
Current Sense Comparator
ICSX
Operating Current
OUTPUT DRIVERS – N-CHANNEL MOSFETS
Low Side Driver Operating Current
IVCCL
High Side Driver Operating Current
IVCX
Drive Rise Time, Fall Time
TRF
High Level Output Voltage
VDH
Low Level Output Voltage
VDL
OSCILLATOR
PWM Switching Frequency
FSW
PWM Switching Frequency
PWM Switching Frequency
Ramp Amplitude
VRAMP
Copyright  2000
Rev. 0.3l, 2002-10-10
Test Conditions
WWW . Microsemi .C OM
ELECTRICAL CHARACTERISTICS
Unless otherwise specified, the following specifications apply over the operating ambient temperature 0°C ≤ TA ≤ 70°C except where
otherwise noted and the following test conditions: VCC = 5V, VCCL = 5V, VCX = 12V, HOX = LOX = 3000pF Load.
LX1672
L I N F I N I T Y
Multiple Output LoadSHARE™ PWM
D I V I S I O N
P RELIMINARY D ATA S HEET
Parameter
`
`
`
Symbol
UVLO AND SOFT-START (SS)
Start-Up Threshold (VCX), (VCCL)
Start-Up Threshold (VCC)
Hysteresis Vcc
SS Input Resistance
RSS
SS Shutdown Threshold
VSHDN
Hiccup Mode Duty Cycle
LINEAR REGULATOR CONTROLLER
Voltage Reference Tolerance
Source Current
IHDRV
Sink Current
ILDRV
DISABLE INPUT
PWM Disable
DISX
LDO Disable
LDDIS
Test Conditions
Min
3.5
4.0
CSS = 0.1µF
VLDFB = 0.8V, COUT = 330µF
Vout = 10V
Vout = 0.4V
LX1672
Typ
4.0
4.25
0.1
20
0.15
10
2
Pulldown Resistance
4.5
4.5
Units
V
V
V
KΩ
V
%
0.2
%
mA
mA
1.0
80
2.5
100
V
ΚΩ
V
KΩ
30
Pulldown Resistance
Max
WWW . Microsemi .C OM
ELECTRICAL CHARACTERISTICS
Unless otherwise specified, the following specifications apply over the operating ambient temperature 0°C ≤ TA ≤ 70°C except where
otherwise noted and the following test conditions: VCC = 5V, VCCL = 5V, VCX = 12V, HOX = LOX = 3000pF Load
Note 1 –X = Phase 1,2
Note 2 – System Specification
ELECTRICALS
Copyright  2000
Rev. 0.3l, 2002-10-10
Microsemi
Linfinity Microelectronics Division
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 5
LX1672
L I N F I N I T Y
Multiple Output LoadSHARE™ PWM
D I V I S I O N
P RELIMINARY D ATA S HEET
RSET
ISET
CS1
+12V
CS Comp
IRESET
PWM
+
VTRIP
VS1
V in
ISET
R
Q
S
Q
VC1
R2
CIN
R1
HO1
V out 1
L1
ESR
EO1
WWW . Microsemi .C OM
BLOCK DIAGRAM
COUT
LO1
PG1
+5V
Error Comp
+
FB1
VCCL
Hiccup
-
+
Amplifier/
Compensation
VREF
16V
20k
Ramp
Oscillator
UVLO
16V
+5V
UVLO
VCC
S
F
FAULT S
S
R
5.5V
TEMP
SS1
SS2
PWGD
(MLP Only)
DIS1
SS
CSS
Figure 1 – Block Diagram of PWM Phase 1
+V
+12V
LDGD
VC1
VREF
BLOCK DIAGRAM
+
VOUT3
LDFB
-
+5V
LDDIS
Figure 2 – LDO Controller Block Diagram
Copyright  2000
Rev. 0.3l, 2002-10-10
Microsemi
Linfinity Microelectronics Division
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 6
LX1672
L I N F I N I T Y
Multiple Output LoadSHARE™ PWM
D I V I S I O N
P RELIMINARY D ATA S HEET
RSET
WWW . Microsemi .C OM
BLOCK DIAGRAM
ISET
+5V
CS2
Vin
CS Comp
IRESET
VS2
VTRIP
PWM
+
R
Q
ISET
S
Q
VC2
CIN
HO2
L2
V out 2
EO2
LO2
LPF2
ESR
COUT
PG2
+5V
Error Comp
+
FB2
VCCL
Hiccup
-
+ Amplifier/
Compensation
VREF
RF2
16V
20k
Ramp
Oscillator
LPF1
UVLO
+5V
16V
UVLO
VCC
S
F
FAULT S
R
SS1
S
TEMP
5.5V
SS2
PHASE1
SS
CSS
DIS 2
Figure 3– Block Diagram of Phase 2 Connected in LoadSHARE Mode
Note: With the MLPQ package there is only one PGX output (PG1 and PG2 are common)
BLOCK DIAGRAM
Copyright  2000
Rev. 0.3l, 2002-10-10
Microsemi
Linfinity Microelectronics Division
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 7
LX1672
L I N F I N I T Y
Multiple Output LoadSHARE™ PWM
D I V I S I O N
P RELIMINARY D ATA S HEET
HO2
LO2
PG2
LDGD
+3.3V
+5V
+2.7V
VC2
VC1
HO1
LO1
PG1
LDFB
LDDIS VCCL
DGND VCC
AGND
DIS2
SS2
RF2
FB2
+12V
WWW . Microsemi .C OM
APPLICATION CIRCUIT
+5V
+
L1
+
+5V
VS1
CS1
EO1
1.5VDC
FB1
SS1
EO2
DIS1
CS2
VS2
+3.3V
+
L2
+
Figure 4 – Bi-Phase Operation With Phase 1 & 2 LoadSHARing From 5V & 3.3V
APPLICATION
Copyright  2000
Rev. 0.3l, 2002-10-10
Microsemi
Linfinity Microelectronics Division
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 8
LX1672
L I N F I N I T Y
Multiple Output LoadSHARE™ PWM
D I V I S I O N
P RELIMINARY D ATA S HEET
HO2
LO2
PG2
LDGD
+3.3V
+5V
+2.7V
LDFB
LDDIS
DGND
AGND
DIS2
SS2
RF2
FB2
VC2
VC1
HO1
LO1
PG1
VCCL
VCC
VS1
CS1
EO1
FB1
SS1
EO2
DIS1
CS2
VS2
+12V
WWW . Microsemi .C OM
APPLICATION CIRCUIT
+5V
+
L1
+
2.8VDC
+5V
+5V
+
L2
+
1.40VDC
Figure 5 – Bi-Phase Operation with Phase 2 Output Tracking The Output of Phase 1.
APPLICATION
Copyright  2000
Rev. 0.3l, 2002-10-10
Microsemi
Linfinity Microelectronics Division
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 9
LX1672
L I N F I N I T Y
Multiple Output LoadSHARE™ PWM
D I V I S I O N
P RELIMINARY D ATA S HEET
GENERAL DESCRIPTION
The LX1672 is a voltage-mode pulse-width modulation
controller integrated circuit. The internal ramp generator
frequency is fixed to 300kHz.
The device has external
compensation, for more flexibility of output current magnitude.
UNDER VOLTAGE LOCKOUT (UVLO)
At power up, the LX1672 monitors the supply voltage for
VCC, VCCL, and VCX (there is no requirement for sequencing
the supplies). Before all supplies reach their under-voltage lockout (UVLO) thresholds, the soft-start (SS) pin is held low to
prevent soft-start from beginning, the oscillator is disabled and
all MOSFETs are held off. There is an internal delay that will
filter out transients less that 1.5uSec.
.
Over-current protection can also be implemented using a sense
resistor, instead of using the RDS(ON) of the upper MOSFET, for
greater set-point accuracy.
OSCILLATOR FREQUENCY
SOFT-START
Once the supplies are above the UVLO threshold, the soft-start
capacitor begins to be charged by the reference through a 20kΩ
internal resistor. The capacitor voltage at the SS pin rises as a
simple RC circuit. The SS pin is connected to the error
amplifier’s non-inverting input that controls the output voltage.
The output voltage will follow the SS pin voltage if sufficient
charging current is provided to the output capacitor.
The simple RC soft-start allows the output to rise faster at the
beginning and slower at the end of the soft-start interval. Thus,
the required charging current into the output capacitor is less at
the end of the soft-start interval. A comparator monitors the SS
pin voltage and indicates the end of soft-start when SS pin
voltage reaches 95% of VREF.
OVER-CURRENT PROTECTION (OCP) AND HICCUP
The LX1672 uses the RDS(ON) of the upper MOSFET, together
with a resistor (RSET) to set the actual current limit point. The
current sense comparator senses the MOSFET current 350nS
after the top MOSFET is switched on in order to reduce
inaccuracies due to ringing. A current source supplies a current
(ISET), whose magnitude is 50µA. The set resistor RSET is
selected to set the current limit for the application. RSET and VSX
should be connected directly at the upper MOSFET drain and
source to get an accurate measurement across the low resistance
RDS(ON).
An internal oscillator sets the PWM switching frequency at
300KHz, 500KHz or 600KHz.
THEORY OF OPERATION
CONFIGURATION
FOR
A
BI-PHASE, LOADSHARE
The basic principle used in LoadSHARING, in a multiple phase
buck converter topology is that if multiple, identical, inductors
have the same identical voltage impressed across their leads, they
must then have the same identical current passing through them.
The current that we would like to balance between inductors is
mainly the DC component along with as much as possible the
transient current. All inductors in a multiphase buck converter
topology have their output side tied together at the output filter
capacitors. Therefore this side of all the inductors have the same
identical voltage.
If the input side of the inductors can be forced to have the same
equivalent DC potential on this lead, then they will have the same
DC current flowing. To achieve this requirement, phase 1 will be
the control phase that sets the output operating voltage, under
normal PWM operation. To force the current of phase 2 to be
equal to the current of phase 1, a second feedback loop is used.
Phase 2 has a low pass filter connected from the input side of each
inductor. This side of the inductors has a square wave signal that
is proportional to its duty cycle. The output of each LPF is a DC
(+ some AC) signal that is proportional to the magnitude and duty
cycle of its respective inductor signal. The second feedback loop
will use the output of the phase 1 LPF as a reference signal for an
error amplifier that will compare this reference to the output of the
phase 2 LPF. This error signal will be amplified and used to
control the PWM circuit of phase 2. Therefore, the duty cycle of
phase 2 will be set so that the equivalent voltage potential will be
forced across the phase 2 inductor as compared to the phase 1
inductor. This will force the current in the phase 2 inductor to
follow and be equal to the current in the phase 1 inductor.
There are four methods that can be used to implement the
LoadSHARE feature of the LX1672 in the Bi-Phase mode of
operation.
Microsemi
Linfinity Microelectronics Division
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 10
APPLICATION
When the sensed voltage across RDS(ON) plus the set resistor
exceeds the 300mV, VTRIP threshold, the OCP comparator
outputs a signal to reset the PWM latch and to start hiccup mode.
The soft-start capacitor (CSS) is discharged slowly (10 times
slower than when being charged up by RSS). When the voltage
on the SS pin reaches a 0.1V threshold, hiccup finishes and the
circuit soft-starts again. During hiccup both MOSFETs for that
phase are held off.
Copyright  2000
Rev. 0.3l, 2002-10-10
Hiccup is disabled during the soft-start interval, allowing start
up with maximum current. If the rate of rise of the output voltage
is too fast, the required charging current to the output capacitor
may be higher than the limit-current. In this case, the peak
MOSFET current is regulated to the limit-current by the currentsense comparator. If the MOSFET current still reaches its limit
after the soft-start finishes, the hiccup is triggered again. When the
output has a short circuit the hiccup circuit ensures that the
average heat generation in both MOSFETs and the average current
is much less than in normal operation,.
WWW . Microsemi .C OM
THEORY OF OPERATION
LX1672
L I N F I N I T Y
Multiple Output LoadSHARE™ PWM
D I V I S I O N
P RELIMINARY D ATA S HEET
THEORY OF OPERATION (CONTINUED)
BI-PHASE, LOADSHARE ( FEEDBACK DIVIDER METHOD)
The first method is to change the ratio of the inductors
equivalent series resistance, (ESR). As can be seen in the
previous example, if the offset error is zero and the ESR of the
two inductors are identical, then the two inductor currents will be
identical. To change the ratio of current between the two
inductors, the value of the inductor’s ESR can be changed to
allow more current to flow through one inductor than the other.
The inductor with the lower ESR value will have the larger
current. The inductor currents are directly proportional to the
ratio of the inductor’s ESR value.
The following circuit description shows how to select the
inductor ESR for each phase where a different amount of power
is taken from two different input power supplies. A typical setup
will have a +5V power supply connected to the phase 1 half
bridge driver and a +3.3V power supply connected to the phase 2
half bridge driver. The combined power output for this core
voltage is 18W (+1.5V @ 12A). For this example the +5V power
supply will supply 7W and the +3.3V power supply will supply
the other 11W. 7W @ 1.5V is a 4.67A current through the phase
1 inductor. 11W @ 1.5V is a 7.33A current through the phase 2
inductor. The ratio of inductor ESR is inversely proportional to
the power level split.
ESR1 I 2
=
ESR 2 I1
The higher current inductor will have the lower ESR value. If the
ESR of the phase 1 inductor is selected as 10mΩ, then the ESR
value of the phase 2 inductor is calculated as:
 4.67 A 

 × 10 mΩ = 6.4 mΩ
 7.33 A 
Depending on the required accuracy of this power sharing;
inductors can be chosen from standard vendor tables with an ESR
ratio close to the required values. Inductors can also be designed
for a given application so that there is the least amount of
compromise in the inductor’s performance.
+5V @ 7W
6.4mΩ
L2
As in Figure 7, the millivolts of DC offset created by the
resistor divider network in the feedback path, appears as a voltage
generator between the ESR of the two inductors.
A divider in the feedback path from Phase 2 will cause the
voltage generator to be positive at Phase 2. With a divider in the
feedback path of Phase 1 the voltage generator becomes positive at
Phase 1. The Phase with the positive side of the voltage generator
will have the larger current. Systems that operate continuously
above a 30% power level can use this method, a down side is that
that the current difference between the two inductors still flows
during a no load condition.
This produces a low efficiency condition during a no load or
light load state, this method should not be used if a wide range of
output power is required.
The following description and Figure 8 show how to determine
the value of the resistor divider network required to generate the
offset voltage necessary to produce the different current ratio in the
two output inductors. The power sharing ratio is the same as that
of Figure 7. The Offset Voltage Generator is symbolic for the DC
voltage offset between Phase 1 & 2. This voltage is generated by
small changes in the duty cycle of Phase 2. The output of the LPF
is a DC voltage proportional to the duty cycle on its input. A small
amount of attenuation by a resistor divider before the LPF of Phase
2 will cause the duty cycle of Phase 2 to increase to produce the
added offset at V2. The high DC gain of the error amplifier will
force LPF2 to always be equal to LPF1. The following
calculations determine the value of the resistor divider necessary to
satisfy this example.
VOUT
APPLICATION
10mΩ
1.5V +
46.7mV
+3.3V @ 11W
4.67A
L1
Sometimes it is desirable to use the same inductor in both
phases while having a much larger current in one phase versus the
other. A simple resistor divider can be used on the input side of
the Low Pass Filter that is taken off of the switching side of the
inductors. If the Phase 2 current is to be larger than the current in
Phase 1; the resistor divider is placed in the feedback path before
the Low Pass Filter that is connected to the Phase 2 inductor. If the
Phase 2 current needs to be less than the current in Phase 1; the
resistor divider is then placed in the feedback path before the Low
Pass Filter that is connected to the Phase 1 inductor.
1.5V @ 12A
18W
7.33A
Figure 7 – Ratio LoadSHARE Using Inductor ESR
Copyright  2000
Rev. 0.3l, 2002-10-10
WWW . Microsemi .C OM
BI-PHASE, LOADSHARE ( ESR METHOD)
Microsemi
Linfinity Microelectronics Division
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 11
LX1672
L I N F I N I T Y
Multiple Output LoadSHARE™ PWM
D I V I S I O N
P RELIMINARY D ATA S HEET
WWW . Microsemi .C OM
THEORY OF OPERATION (CONTINUED)
.
+5V @ 7W
L1,
Switch
Side
Phase 2
Error Am p
100
62k
1.5V
+46.7m V
LPF1
PW M
Input
+
Not
Used
Resistor
Divider
L2,
Switch
Side
62k
Phase 1
LPF2
Offset
Voltage
Generator
Vout1
1.5V @ 12A
18W
+
62k
100
TBD
4.67A
4700pF
-
Resistor
Divider
ESR L1
10m Ω
V1
1.5V
+73.3m V
4700pF
ESR L2
10m Ω
V2
Phase 2
7.33A
+3.3V @ 11W
Figure 8 – LoadSHARE Using Feedback Divider Offset
Where V1 = 1.5467 ; V2 = 1.5733 and K =
V1
V2
then
TBD =
K × 100
1− K
= 5.814 K
APPLICATION
Copyright  2000
Rev. 0.3l, 2002-10-10
Microsemi
Linfinity Microelectronics Division
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 12
LX1672
L I N F I N I T Y
Multiple Output LoadSHARE™ PWM
D I V I S I O N
P RELIMINARY D ATA S HEET
.
BI-PHASE, LOADSHARE ( PROPORTIONAL METHOD)
Also a speed up capacitor can be used between the offset amplifier
output and the negative input of the Phase 2 error amplifier. This
will improve the transient response of the Phase 2 output current,
so that it will share more equally with phase 1 current during a
transient condition.
The best topology for generating a current ratio at full load
and proportional between full load and no load is shown in figure
9. The DC voltage difference between LPF1 and VOUT is a
voltage that is proportional to the current flowing in the Phase 1
inductor. This voltage can be amplified and used to offset the
voltage at LPF2 through a large impedance that will not
significantly alter the characteristics of the low pass filter. At no
load there will be no offset voltage and no offset current between
the two phases. This will give the highest efficiency at no load.
L1,
Switch
Side
The use of a MOSFET input amplifier is required for the buffer
to prevent loading the low pass filter. The gain of the offset
amplifier, and the value of Ra and Rb, will determine the ratio of
currents between the phases at full load. Two external amplifiers
are required or this method.
Offset Amp
LPF1
+
62k
+
Rin
-
-
Vos
Rf
Phase 2
Error Amp
+
RF2
+5V @ 7W
1.5V
+46.7mV
4700pF
L2,
Switch
Side
WWW . Microsemi .C OM
THEORY OF OPERATION (CONTINUED)
ESR L1
10mΩ
V1
4.67A
Phase 1
PWM
Input
Offset
Voltage
Generator
-
Vout
1.5V @ 12A
18W
+
FB2
62k
LPF2
62k
Ra
1.5V
+73.3mV
4700pF
1M
Rb
V2
ESR L2
10mΩ
Phase 2
7.33A
+3.3V @ 11W
Figure 9 –LoadSHARE Using Proportional Control
APPLICATION
Copyright  2000
Rev. 0.3l, 2002-10-10
Microsemi
Linfinity Microelectronics Division
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 13
LX1672
L I N F I N I T Y
Multiple Output LoadSHARE™ PWM
D I V I S I O N
P RELIMINARY D ATA S HEET
APPLICATION NOTE
The first decision to be made is the current sharing ratio,
follow the previous examples to understand the basics of
LoadSHARE. The most common reason to imbalance the current
in the two phases is because of limitations on the available power
from the input rails for each phase. Use the available input power
and total required output power to determine the inductor
currents for each phase.
All references are to Figure 9
1) Calculate the voltages V1 and V2.
V 1 = L 1 Current × L 1 ESR + Vout
V 2 = L 2 Current × L 2 ESR + Vout
A fourth but less desirable way to produce the ratio current
between the two phases is to add a resistor in series with one of
the inductors. This will reduce the current in the inductor that has
the resistor and increase the current in the inductor of the opposite
phase. The example of Figure 7 can be used to determine the
current ratio by adding the value of the series resistor to the ESR
value of the inductor. The added resistance will lower the overall
efficiency
LoadSHARE ERROR SOURCES
With the high DC feedback gain of this second loop, all phase
timing errors, RDS(On) mismatch, and voltage differences across the
half bridge drivers are removed from the current sharing accuracy.
The errors in the current sharing accuracy are derived from the
tolerance on the inductor’s ESR and the input offset voltage
specification of the error amplifier. The equivalent circuit is
shown next for an absolute worst case difference of phase currents
between the two inductors.
2) Select values for Ra and Rb (Ra is typically 62KΩ ; Rb
is typically 1MΩ)
Offset Error
5mV +
3) Calculate the offset voltage Vos at the output of the
offset amplifier
 V 2 − V1
Vos = V 2 − 
 × (Ra + Rb )
 Ra 
ESR L1
V1
Phase 1
VOUT
ESR L2
V2
Phase 2
Figure 6 – Error Amplitude
4) Calculate the value for Rf
Nominal ESR of 6mΩ. ESR ±5%
(select a value for Rin typically 5KΩ)
Max offset Error = 6mV
 Vos − Vout 

 Vout − V 1 
+5% ESR L1 = 6.3 mΩ
Rf = Rin 
-5% ESR L2 = 5.7 mΩ
Due to the high impedances in this circuit layout can effect the
actual current ratio by allowing some of the switching waveforms
to couple into the current summing path. It may be necessary to
make some adjustment in Rf after the final layout is evaluated.
Also the equation for Rf requires very accurate numbers for the
voltages to insure an accurate result.
If phase 1 current = 12 A =
V 1 − VOUT = 12 × 6.3 × 10
V 1 - VOUT
ESRL 1
−3
= 75.6 mV
V 2 = V1 + 6 mV = 81.6 mV
V 2 - VOUT 81.6 x 10−3
=
= 14.32 A
ESR L 2
5.7 x 10−3
APPLICATION
Phase 2 current =
Phase 2 current is 2.32A greater than Phase 1.
Input bias current also contributes to imbalance.
Copyright  2000
Rev. 0.3l, 2002-10-10
WWW . Microsemi .C OM
BI-PHASE, LOADSHARE (SERIES RESISTOR METHOD)
The circuit in Figure 9 sums a current through a 1MΩ resistor
(Rb) offsetting the phase 2 error amplifier to create an imbalance
in the L1 and L2 currents. Although there are many ways to
calculate component values the approach taken here is to pick Ra,
Rb, Rin, Vout, and inductor ESR. A value for the remaining
resistor Rf can then be calculated.
Microsemi
Linfinity Microelectronics Division
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 14
LX1672
L I N F I N I T Y
Multiple Output LoadSHARE™ PWM
D I V I S I O N
P RELIMINARY D ATA S HEET
OUTPUT INDUCTOR
OUTPUT CAPACITOR
The output inductor should be selected to meet the
requirements of the output voltage ripple in steady-state operation
and the inductor current slew-rate during transient. The peak-topeak output voltage ripple is:
VRIPPLE = ESR × I RIPPLE
where
∆I =
VIN − VOUT
L
×
(
ESR × I RIPPLE + ∆I < VEX
fs
Where IRIPPLE is the inductor ripple current, ∆I is the maximum
load current step change, and VEX is the allowed output voltage
excursion in the transient.
∆I should typically be in the range of 20% to 40% of the
maximum output current. Higher inductance results in lower
output voltage ripple, allowing slightly higher ESR to satisfy the
transient specification. Higher inductance also slows the inductor
current slew rate in response to the load-current step change, ∆I,
resulting in more output-capacitor voltage droop. When using
electrolytic capacitors, the capacitor voltage droop is usually
negligible, due to the large capacitance
The inductor-current rise and fall times are:
(V
∆I
IN
− VOUT
)
and
TFALL = L×
)
D
∆I is the inductor ripple current, L is the output inductor value
and ESR is the Effective Series Resistance of the output
capacitor.
TRISE = L×
The output capacitor is sized to meet ripple and transient
performance specifications. Effective Series Resistance (ESR) is a
critical parameter. When a step load current occurs, the output
voltage will have a step that equals the product of the ESR and the
current step, ∆I. In an advanced microprocessor power supply, the
output capacitor is usually selected for ESR instead of capacitance
or RMS current capability. A capacitor that satisfies the ESR
requirements usually has a larger capacitance and current
capability than strictly needed. The allowed ESR can be found by:
∆I
VOUT
WWW . Microsemi .C OM
APPLICATION NOTE
Electrolytic capacitors can be used for the output capacitor, but
are less stable with age than tantalum capacitors. As they age, their
ESR degrades, reducing the system performance and increasing the
risk of failure. It is recommended that multiple parallel capacitors
be used, so that, as ESR increase with age, overall performance
will still meet the processor’s requirements.
There is frequently strong pressure to use the least expensive
components possible, however, this could lead to degraded longterm reliability, especially in the case of filter capacitors.
Microsemi’s demonstration boards use the CDE Polymer AL-EL
(ESRE) filter capacitors, which are aluminum electrolytic, and
have demonstrated reliability. The OS-CON series from Sanyo
generally provides the very best performance in terms of long term
ESR stability and general reliability, but at a substantial cost
penalty. The CDE Polymer AL-EL (ESRE) filter series provides
excellent ESR performance at a reasonable cost. Beware of offbrand, very low-cost filter capacitors, which have been shown to
degrade in both ESR and general electrolytic characteristics over
time.
.
The inductance value can be calculated by
L=
VIN − VOUT
∆I
×
D
fs
APPLICATION
Copyright  2000
Rev. 0.3l, 2002-10-10
Microsemi
Linfinity Microelectronics Division
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 15
LX1672
L I N F I N I T Y
Multiple Output LoadSHARE™ PWM
D I V I S I O N
P RELIMINARY D ATA S HEET
.
INPUT CAPACITOR
The input capacitor and the input inductor, if used, are to filter
the pulsating current generated by the buck converter to reduce
interference to other circuits connected to the same 5V rail. In
addition, the input capacitor provides local de-coupling for the
buck converter. The capacitor should be rated to handle the RMS
current requirements. The RMS current is:
I RMS = I L
Values of Css equal to .1uf or greater are unlikely to result in
saturation of the output inductor unless very large output capacitors
are used..
OVER-CURRENT PROTECTION
d(1 − d)
Where IL is the inductor current and d is the duty cycle. The
maximum value occurs when d = 50%, then IRMS =0.5IL. For 5V
input and output in the range of 2 to 3V, the required RMS
current is very close to 0.5IL.
Current limiting occurs at current level ICL when the voltage
detected by the current sense comparator is greater than the current
sense comparator threshold, VTRIP (300mV).
WWW . Microsemi .C OM
APPLICATION NOTE (CONTINUED)
I CL × R DS(ON) + I SET × R SET = VTRIP
So,
SOFT-START CAPACITOR
The value of the soft-start capacitor determines how fast the
output voltage rises and how large the inductor current is required
to charge the output capacitor. The output voltage will follow the
voltage at the SS pin if the required inductor current does not
exceed the maximum allowable current for the inductor. The SS
pin voltage can be expressed as:
(
VSS = V ref 1 − e
− t/R SSCSS
R SET =
VTRIP − I CL × R DS(ON)
I SET
=
300 mV − I CL × R DS(ON)
50 µA
Example:
For 10A current limit, using FDS6670A MOSFET (10mΩ
RDS(ON)):
)
R SET =
0.3 − 10 × 0.010
50 × 10− 6
= 4K Ω
Where RSS and CSS are the soft-start resistor and capacitor.
The current required to charge the output capacitor during the soft
start interval is.
Iout = Cout
dVss
dt
At higher PWM frequencies or low duty cycles where the upper
gate drive is less than 350nS wide the 350nS delay for current
limit enable may result in current pulses exceeding the desired
current limit set point. If the upper MOSFET on time is less than
350nS and a short circuit condition occurs the duty cycle will
increase, since Vout will be low. The current limit circuit will be
enabled when the upper gate drive exceeds 350nS although the
actual peak current limit value will be higher than calculated with
the above equation.
Taking the derivative with respect to time results in
Iout =
VrefCout − t/R SS C SS
e
RssCss
and at t=0
Im ax =
VrefCout
RssCss
Short circuit protection still exists due to the narrow pulse width
even though the magnitude of the current pulses will be higher than
the calculated value.
If OCP is not desired connect both VSX and VCX to VCC. Do
not leave them floating.
Microsemi
Linfinity Microelectronics Division
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 16
APPLICATION
The required inductor current for the output capacitor to follow
the soft start voltage equals the required capacitor current plus the
load current. The soft-start capacitor should be selected to
provide the desired power on sequencing and insure that the
overall inductor current does not exceed its maximum allowable
rating.
Copyright  2000
Rev. 0.3l, 2002-10-10
Note: Maximum RSET is 6KΩ. Any resistor 6KΩ or greater will not
allow startup since ICL will equal zero (50uA x 6KΩ=300mV).
LX1672
L I N F I N I T Y
Multiple Output LoadSHARE™ PWM
D I V I S I O N
P RELIMINARY D ATA S HEET
WWW . Microsemi .C OM
APPLICATION NOTE (CONTINUED)
.
OUTPUT DISABLE
The LX1672 PWM MOSFET driver outputs are shut off by
pulling the disable (DISX) pins above 1.2V.
The LDO voltage regulator has its own Disable pin (LDDIS)
for control of this output voltage. Pulling this pin above 3 V
disables the LDO.
PROGRAMMING THE OUTPUT VOLTAGE
The output Voltage is sensed by the feedback pin (FBX) which
is compared to a 0.8V reference. The output voltage can be set to
any voltage above 0.8V (and lower than the input voltage) by
means of a resistor divider R1-R2 (see Figure 1).
VOUT = VREF (1 + R 1 /R 2 )
Note: Keep R1 and R2 close to 1kΩ (order of magnitude)
DDR VTT TERMINATION VOLTAGE
Double Data Rate (DDR) SDRAM requires a termination
voltage (VTT) in addition to the line driver supply voltage
(VDDQ) and receiver supply voltage (VDD). Although it is not a
requirement VDD is generally equal to VDDQ so that only VTT
and VDDQ are required..
The LX1672 can supply both voltages by using two of the
three PWM phases. Since the currents for VTT and (VDD plus
VDDQ) are quite often several amps, (2A to 6A is common) a
switching regulator is a logical choice
VTT for DDR memory can be generated with the LX1672 by
using the positive input of the phase 2 error amplifier RF2 as a
reference input from an external reference voltage VREF which is
defined as one half of VDDQ. Using VREF as the reference input
will insure that all voltages are correct and track each other as
specified in the JEDEC (EIA/JESD8-9A) specification. The phase
2 output will then be equal to VREF and track the VDDQ supply
as required.
When an external reference is used the Soft Start will not be
functional for that phase
Copyright  2000
Rev. 0.3l, 2002-10-10
APPLICATION
See Microsemi Application Note 17 for more details.
Microsemi
Linfinity Microelectronics Division
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 17
LX1672
L I N F I N I T Y
Multiple Output LoadSHARE™ PWM
D I V I S I O N
P RELIMINARY D ATA S HEET
APPLICATION NOTE CONSIDERATIONS
The power N-MOSFET transistor’s total gate charge spec,
(Qg) should not exceed 40Nc when VCx = +12V. This
condition will guarantee operation over the specified ambient
temperature range. The Qg value of the N-MOSFET is
directly related to the amount of power dissipation inside the
IC package, from the two sets of MOSFET drivers. The
equation relating Qg to the power dissipation of a MOSFET
driver is: Pd = f * Qg * Vd . f = 300KHs and Vd is the
supply voltage for the MOSFET driver. The two bottom
MOSFET drivers are powered by the VCCL pin that is
connected to +5V. The upper MOSFET drivers can be
connected to the +12V supply or to a bootstrap supply
generated by it’s output bridge. The bootstrap supply will be
at +17V. Depending on the thermal environment of the
application circuit, the Qg value of the N-MOSFETs will have
to be less than the 40nC value. A typical configuration of the
input voltage rails to generate the output voltages required is
having the 5volt supply on phase 1, and the 3.3 volt supply on
phase 2. At the max Qg value, the two bottom MOSFET
drivers will dissipate 60mw each. The upper MOSFET drivers
for phases 1 and 2 operate off of +12volts. Their dissipation
is 144mw each. The total power dissipation for gate drive is
408 mw. Icc x Vcc =15ma x 5 V= 75mW. Total package
power dissipation = 483mW. Using the thermal equation of :
Tj = Ta + Pd * Oja, the Junction temperature for this IC
package is = 23 + .483 * 85 which = 64 deg C. This means
that the ambient temperature rise has to be less than 86 deg C.
The Soft-Start reference input has a 300mv threshold, above
which the PWM starts to operate. The internal operating
reference level is set at 800mv. This means that the output
voltage is 37.5% low when the PWM becomes active. This
starts each phase up in the current limit mode without Hiccup
operation. If more than one phase is using the 5volt rail for
conversion, then their soft-start capacitor values should be
changed so that the two phases do not start up together. This
will help reduce the amount of 5volt input capacitance
required. Also the VCC pin and the VCCL pin should be kept
separated and should be decoupled separately. This will
prevent the VCC pin from drooping back below the UVLO set
point during start up.
3.
If a phase is not used connect VSX and VCX pins to VCC.
Do not leave them floating. A floating VSX pin will result in
operation resembling a hiccup condition.
Copyright  2000
Rev. 0.3l, 2002-10-10
When phases 1 and 2 are used in the Bi-phase mode to current
share into the same output load, the phase 2 current is forced to
follow the phase 1 current. It is important to use a larger softstart capacitor on phase 2 than phase 1 so that the phase 1
current becomes active before phase 2 becomes active. This
will minimize any start up transient. It is also important to
disable phase 1 and 2 at the same time. Disabling phase 1
without disabling phase 2, in the Bi-phase mode, lets phase 2
turn on and off randomly because it has lost its reference.
5.
The minimum RSET resistor value is 1k ohm for the current
limit sensing. If this resistor becomes shorted, it will do
permanent damage to the IC.
6.
A resistor has been put in series with the gate of the LDO pass
transistor to reduce the output noise level. The resistor value
can be changed to optimize the output transient response versus
output noise.
7.
The LDO controller inside the IC uses the voltage at VC1 as
the drive voltage. Due to noise considerations ideally the
voltage on the VC1 pin would be a fixed +12volt supply. When
VC1 is connected to a bootstrap supply the LDO output will
reflect significant switching noise without filtering.
8.
To delay the turn on of the LDO controller output, a capacitor
should be connected between the LDDIS pin and the +5volts.
The LDDIS input has a 100K pull down resistor, which keeps
the LDO active until this pin is pulled high. During the power
up sequence the capacitor connected to the LDDIS pin will keep
the LDO off until this capacitor, being charge by the 100K pull
down resistor, goes through the low input threshold level.
Microsemi
Linfinity Microelectronics Division
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
APPLICATION
2.
4.
WWW . Microsemi .C OM
1.
Page 18
LX1672
L I N F I N I T Y
Multiple Output LoadSHARE™ PWM
D I V I S I O N
P RELIMINARY D ATA S HEET
PW
28-Pin Thin Small Shrink Outline (TSSOP)
Dim
3 2 1
P
E
F
D
A H
SEATING PLANE
LQ
B
L
G
C
M
A
B
C
D
E
F
G
H
L
M
P
*LC
MILLIMETERS
MIN
MAX
0.85
0.95
0.19
0.30
0.09
0.20
9.60
9.80
4.30
4.50
0.65 BSC
0.05
0.15
–
1.10
0.50
0.75
0°
8°
6.25
6.50
–
0.10
INCHES
MIN
MAX
0.033
0.037
0.007
0.012
0.003
0.008
0.378
0.390
0.169
.176
0.025 BSC
0.002
0.005
–
0.043
0.020
0.030
0°
8°
0.246
0.256
–
0.004
MILLIMETERS
MIN
MAX
0.20 REF
0.18
0.30
0.18
0.18
5.00 BSC
3.00
3.25
5.00
5.25
0.50 BSC
0
0.05
0.70
0.80
7.00 BSC
INCHES
MIN
MAX
0.0078 REF
0.007
0.011
0.007
0.007
.196 BSC
0.118
0.127
0.196
0.206
0.019 BSC
0
0.19
0.027
0.031
0.275 BSC
WWW . Microsemi .C OM
PACKAGE DIMENSIONS
38-Pin Thin Micro Lead Quad Package (MLPQ)
D
Dim
P
F
3
2
C
1
C
G
I
H
B
A
Note: Dimensions do not include mold flash or protrusions; these shall not exceed 0.155mm(0.006”) on any side. Lead dimension shall
not include solder coverage.
Copyright  2000
Rev. 0.3l, 2002-10-10
Microsemi
Linfinity Microelectronics Division
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 19
MECHANICALS
A
B
C
D
E
F
G
H
I
P
E
LX1672
L I N F I N I T Y
D I V I S I O N
Multiple Output LoadSHARE™ PWM
P RELIMINARY D ATA S HEET
WWW . Microsemi .C OM
NOTES
NOTES
PRODUCT PRELIMINARY DATA – Information contained in this document is pre-production
data, and is proprietary to Microsemi. It may not be modified in any way without the express
written consent of Microsemi. Product referred to herein is not guaranteed to achieve preliminary
or production status and product specifications, configurations, and availability may change at any
time.
Copyright  2000
Rev. 0.3l, 2002-10-10
Microsemi
Linfinity Microelectronics Division
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 20