Micronote 1311 - (AN-22) LX1741 / LX1742 Boost Converter Design Hint (512.02 kB)

LX1741/LX1742 BOOST CONVERTER
APPLICATION NOTE
LX1741 / LX1742 BOOST
CONVERTER DESIGN HINT
AN-22
Application Engineer: Michael Calvert
I N T E G R A T E D
Copyright  2002
Rev. 1.0, 2002-12-03
P R O D U C T S
Microsemi
Integrated Products
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 1
LX1741/LX1742 BOOST CONVERTER
APPLICATION NOTE
TABLE OF CONTENTS
Introduction............................................................................................................................................3
LX1741 / LX1742 Design Note ..............................................................................................................3
Design Example: LX741 ........................................................................................................................4
Design Summary ...................................................................................................................................8
Power and Thermal Considerations ......................................................................................................8
Design Tools..........................................................................................................................................9
Conclusion...........................................................................................................................................10
LX1741 Sepic ......................................................................................................................................11
LX1742 Application..............................................................................................................................12
LX1742 Output Disconnect..................................................................................................................13
References and Appendix ...................................................................................................................14
Copyright  2002
Rev. 1.0, 2002-12-03
Microsemi
Integrated Products
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 2
LX1741/LX1742 BOOST CONVERTER
APPLICATION NOTE
INTRODUCTION
The LX1741 and LX1742 Boost Controllers offer high efficiency performance and provide power management
circuit designers with the ability to approach a broad range of design applications with a flexible and easy-toimplement solution. This application hint provides an overview of these two products and describes their overall
functions in regard to practical design applications. Please refer to the LX1741 and LX1742 data sheets for a
complete discussion regarding electrical performance and packaging information. Table 1 provides a comparison
of the LX1741 and LX1742 features.
Internal
FET
External
FET
Max VIN
ISRC
(MAX)
VOUT
(MAX)
Package
Type
Operating
Temp.
LX1741
No
Yes
6.0V
800mA
(rms)
Application
Dependent
MSOP or
MLP
0 ~ 70°C
LX1742
Yes
No
6.0V
25V
MSOP
0 ~ 70 C
500mA
(rms)
TABLE 1 – FEATURES
L1
LX1741 AND LX1742
C2
The LX1741 and LX1742 are very similar devices.
Both of these controllers implement a Pulse
Frequency Modulation-type (PFM) topology and
provide designers with a cost effective SMPS
controller solution for a variety of real-world battery
(e.g., Lithium-Ion) driven applications (e.g., pagers,
wireless phones, personal digital assistants, etc…).
The LX1741 or LX1742 support a broad range of
output voltages and can source over 100mA of
output current depending upon input voltage. One
particular low current application that benefits from
the selection of either the LX1741 or LX1742
includes Liquid Crystal Display (LCD) biasing.
Each device has 8 functional pins that are
designated as IN (voltage input), OUT (voltage
output), CS (current sense – used to set the peak
inductor current limit), SHDN (active-low shutdown –
disables the controller and reduces supply current to
< 1mA), GND (circuit ground), FB (feedback – a
resistor divider network is connected between this
pin and ground to establish VOUT), ADJ (adjust –
provides for external control of the output voltage by
up to ±15%), and NDRV (n-channel mosfet driver
output – LX1741 only) or, SW (switch – LX1742
only: inductor output & diode (anode) input
connection – this pin is high impedance in shutdown
mode).
Copyright  2002
Rev. 1.0, 2002-12-03
°
NDRV
IN
SHDN
R1
C1
SRC
LX1741
FB
ADJ
CS
GND
RCS
R2
FIGURE 1 – TYPICAL LX1741 APPLICATION CIRCUIT
The LX1741 requires an external N-channel
MOSFET to complete the DC-DC converter circuit.
This feature provides the designer with maximum
flexibility regarding the selection of a device that
minimizes switching losses for a particular
application. The external MOSFET is driven from the
NDRV pin and Figure 1 shows a typical LX1741
application circuit.
The LX1742 simplifies a portion of the design
effort by incorporating the N-channel MOSFET
device. Applications that have relaxed efficiency
and/or increased reliability requirements benefit from
this added feature. Figure 2 illustrates a typical
LX1742 application.
The LX1742 replaces the
NDRV pin (found in the LX1741) with the SW (i.e.,
switch) pin and requires the inductor’s output and
the diode’s anode to be connected to this pin.
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LX1741/LX1742 BOOST CONVERTER
L1
APPLICATION NOTE
= 10mV). We will determine R1 using formula 1.0
where VREF = 1.29V or 1.20V for the LX1741 and
LX1742 respectively:
CR1
Eq 1
SW
IN
SHDN
OUT
R1
LX1742
FB
CS
GND
RCS
R2
]
FIGURE 2 – TYPICAL LX1742 APPLICATION CIRCUIT
Other critical design considerations apply to the
selection of the inductor, capacitors, diode and
transistor. The designer can minimize inductor size,
input ripple current, and output ripple voltage by
setting the peak inductor current level to 1.5X the
expected maximum DC input current. Low ESR
capacitors are recommended because they reduce
output voltage ripple induced by the inductor’s
switching current. Multi-layer ceramic capacitors
with X5R or X7R dielectric make a superior choice
because they feature small size, very low ESR, and
a temperature stable dielectric. Low ESR electrolytic
capacitors such as solid tantalum or OS-CON types
are also acceptable (note: a brief review of capacitor
types is provided in the Appendix). When choosing
the diode, the designer should consider the device’s
average and peak current ratings with respect to the
application’s output and peak inductor current
requirements.
We’ll select an R1 value using a 1% resistor that
is the closest to 414.3KΩ (i.e., R1 equals 412KΩ).
Now, we need to determine the Peak Inductor
Therefore, we will start by
Current (IPEAK).
determining IIN using the efficiency equation where
Output Power (POUT) is equal to the Efficiency (η)
multiplied by the Input Power (PIN):
Eq. 2
POUT = η(PIN )
Recall that power is equal to voltage multiplied by
current (i.e., P = V*I). Therefore, we can rewrite the
efficiency equation and solve for IIN where, VIN
equals 3.6V, VOUT equals 12.0V, IOUT equals 40mA
(maximum) and ŋ is estimated from the device’s
efficiency versus output current curve.
Moreover, the diode’s reverse breakdown voltage
characteristic must be capable of withstanding a
negative voltage transition that is greater than
VOUT. A properly sized Schottky diode will typically
meet these requirements for a broad range of
applications. Finally, overall circuit efficiency is
further enhanced by selecting a MOSFET device
that exhibits a low RDS(ON) and gate charge
characteristic.
Typical Efficiency versus Output
Current Curves for the LX1741 and LX1742 are
shown in Figure 3.0 and Figure 4.0 respectively.
100
90
Efficiency
ADJ
[
 VOUT - VREF 
=

VREF


[
]
12.0V
−
1.29V


49.9KΩ
 = 414.3KΩ
1.29V


R1 = R 2 
COUT
80
70
60
50
1
5
15
40
Output Current (mA)
FIGURE 3 – LX1741 EFFICIENCY VS. OUTPUT CURRENT
(VIN = 3.6V, VOUT = 12V, L = 47µH, RCS = 4KΩ)
LX1741 DESIGN EXAMPLE
Let’s work through a typical application using the
LX1741. We’ll assume that an input voltage supply
of 3.6V is available. We need to drive an application
that requires an output of 12.0V and 40.0mA (i.e.,
480mW). The first step in selecting the desired
output voltage is to determine the value of R1 and
R2. We’ll start with an R2 value less than 100KΩ to
minimize VFB offset error (e.g., IFB*R2 = 200nA*50KΩ
Copyright  2002
Rev. 1.0, 2002-12-03
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Integrated Products
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Page 4
LX1741/LX1742 BOOST CONVERTER
at 350mA. Figure 6 shows the IPEAK value versus
input voltage relationship as inductance values
increase from 27µH to 94µH and the RCS value
remains fixed at 4KΩ.
100
90
7
80
RCS (Kohms)
Efficiency
APPLICATION NOTE
70
60
50
1
6
15
40
Output Current (mA)
6
5
4
3
2
2.5
FIGURE 4 – LX1742 EFFICIENCY VS. OUTPUT CURRENT
(VIN = 3.6V, VOUT = 12V, L= 47µH, RCS = 4KΩ)
An efficiency value of approximately 0.85 is found
from the curve in Figure 3.
Now, IIN may be
estimated as follows:
4.5
Input Voltage (V)
FIGURE 5 – RCS (KΩ) VS. INPUT VOLTAGE
(Note: IPEAK = 350mA, L = 27µH (bottom), 47µH (middle),
94µH (top), tD = 618ns, IMIN = 145mA)
400
 [I
× VOUT ] 
 =
I IN =  OUT
 η × VIN 
 [40mA × 12V ] 

 = 156mA
 0.85 × 3.6V 
Ipeak (mA)
Eq 3
3.5
Now that the input current has been determined,
we are ready to calculate the peak inductor current.
IPEAK is a function of several parameters, specifically:
IMIN, VIN, L, tD, ISCALE, and RCS. VIN is already defined
herein
as
3.6V.
The
ELECTRICAL
CHARACTERISTICS section of the LX1741 data
sheet provides the values parameters IMIN and tD. For
this example, we will use the LX1741’s nominal IMIN
and ISCALE value of 145mA and 31mA/kΩ respectively
(note: these values change to 104mA and 22mA/kΩ
respectively for the LX1742). The parameter tD is a
switching delay related to the operation of the
feedback comparator circuit (see Block diagram in
data sheet). A typical value for tD, at 25°C, is 620ns.
Microsemi recommends using an inductor (L) value
of 47µH (i.e., this value works for a broad power
conversion range).
A higher inductance value may improve efficiency
at the expense of degrading the overall output
voltage ripple performance. Inserting a smaller
inductance value will degrade efficiency. Moreover,
the designer is encouraged to consider IPEAK
variation over the input voltage range as a smaller
inductance increases IPEAK variation versus a larger
inductance. Figure 5 illustrates the RCS versus input
voltage relationship as inductance values increase
from 27µH to 94µH and the IPEAK value remains fixed
Copyright  2002
Rev. 1.0, 2002-12-03
375
350
325
300
275
250
2.5
3.5
4.5
Input Voltage (V)
FIGURE 6 – IPEAK (mA) VS. INPUT VOLTAGE
(Note: RCS = 4.02KΩ, ISCALE = 31mA/KΩ, L = 27µH (top),
47µH (middle), 94µH (bottom), tD = 618ns, IMIN = 145mA)
Using this information, we are ready to determine
the RCS value required to set the IPEAK value for our
application. From our previous calculation, IIN was
determined to be 245mA. We will multiple this
number by a factor of 1.5 to ensure that we have
sufficient margin (over temperature and device-todevice variability) and reduce the risk of hitting
current-limit (continuous-mode operation). Therefore,
IPEAK = 1.5(IIN) = 1.5(156)mA = 235mA < 800mARMS
(ISRC). Note: The maximum IPEAK value is limited by
the ISRC value (max. = 0.8ARMS : LX1741). Now we
can solve for RCS by using formula 5 where:
Eq 4
 VIN 
 t D + (I SCALE × R CS ) hence:
 L 
I PEAK = I MIN + 
Eq 5
 1
R CS = 
 I SCALE

V  
 I PEAK − I MIN −  IN  t D  or,
 L  

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LX1741/LX1742 BOOST CONVERTER
APPLICATION NOTE

 3.6V 
1


620ns  = 1317Ω
 235mA − 145mA
 32mA/KΩ 
 47µH 

RCS = 
We select an RCS value using 1% resistors that is
the closest to the calculated RCS value; hence, RCS
equals 1.37KΩ.
Connecting this resistor (RCS)
between the CS pin and ground sets the IPEAK value
in circuit. Now that we have determined values for
R1, IPEAK, and RCS, what about calculating the output
ripple voltage? The total output ripple voltage is
determined from formula 6:
Eq. 6
VRIPPLE = ∆VDROOP + ∆VOVERSHOOT + 10mV
Figure 7A illustrates the (ideal) switching waveform
relationships with respect to the Droop and
Overshoot voltage. The overshoot voltage occurs
when the inductor charging cycle ends and the
inductor current is released to the load.
The
overshoot voltage is a function of the inductor, output
capacitor, Peak Inductor Current, output current,
input voltage, output voltage, and an estimate of the
voltage drop across the diode (e.g., 0.5v). The
overshoot voltage is improved by increasing the
output capacitance but degrades slightly with
increasing input voltage. The droop voltage occurs
when the output voltage begins to decrease below
the feedback threshold. The droop voltage is a
function of the inductor, output capacitor, Peak
Inductor Current, output current, input voltage, and
an estimate of the voltage drop across the inductor
and the FET’s RDS_ON (e.g., 0.5v). Droop voltage
improves by increasing either output voltage or
output capacitance (or, both). Finally, there is a
10mV transition error voltage associated with the
feedback switching circuit that adds to the total output
ripple voltage. Figure 7B shows actual waveforms.
FIGURE 7B – ACTUAL SWITCHING WAVEFORMS
(VIN = 3V, VOUT = 12V, IOUT = 11mA)
The delta (∆) VDROOP and VOVERSHOOT are
determined from equations 7 and 8 respectively:
Eq 7
∆VDROOP
L

 C (I PK × I OUT )
OUT 

=
VIN − 0.5
Eq 8
∆VOVERSHOOT
1 ×  L (I × I )2
 PK OUT
2 C
 OUT 
=
VOUT + 0.5 − VIN
Let’s determine the ∆VDROOP for our application
example. Recall that in the previous example, IPEAK
was determined to be 368mA. We’ll start by using
the inductor value of 47mH and choose COUT equal to
4.7mF. Inserting these values into equation 7 and
solving for the ∆VDROOP yields the following result:
VOVERSHOOT
VOUT
∆VDROOP
VDROOP
(235mA × 50mA )
 47µH
4.7µF 

=
= 37.9mV
3.6v − 0.5v
Now let us determine the ∆VOVERSHOOT for our
application example:
VNDRV
∆VOVERSHOOT
IPEAK
IL
FIGURE 7A – IDEAL SWITCHING WAVEFORMS
Copyright  2002
Rev. 1.0, 2002-12-03
1 ×  47µH (235mA × 50mA)2
2  4.7µF 
= 10.6mV
=
12v + 0.5v − 3.6v
Combining the results of these calculations with
formula 6 provides an estimate of 58mV for the
output voltage ripple. What if we increased VIN or
COUT while holding the other parameters in formula 7
and 8 constant? Figure 8 and Figure 9 illustrate
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LX1741/LX1742 BOOST CONVERTER
Droop Voltage (mV)
40
35
30
25
20
15
10
5
0
2.5
3.5
(Note: IPEAK = 310mA, IOUT = 25mA, COUT =4.7µF (top), and
47µF(bottom))
Overshoot Voltage (mV)
Droop and Overshoot Voltage variation versus input
voltage for two values of output capacitance. The
Droop Voltage curve shows a voltage reduction as
VIN increases. The bottom curve (COUT = 47µF) in
Figure 8 demonstrates a significant reduction in
Droop voltage versus the top curve (COUT = 4.7µF).
The Overshoot Voltage curves in Figure 9
demonstrate a slight overshoot voltage increase as
VIN increases. However, note that the bottom curve
(COUT = 47µF) demonstrates a significant reduction in
overshoot voltage value versus the top curve (COUT =
4.7µF).
This exercise provides insight into the
criticality of selecting the size of the output capacitor
for a particular application.
The LX1742
demonstrates similar performance characteristic.
APPLICATION NOTE
60
50
40
30
20
10
0
2.5
3.5
4.5
Input Voltage (V)
FIGURE 9 – ∆VOVERSHOOT VS. INPUT VOLTAGE
(Note: IPEAK = 310mA, IOUT = 25mA, COUT = 4.7µF (top), and
47µF (bottom)).
4.5
Input Voltage (V)
FIGURE 8 – ∆VDROOP VS. INPUT VOLTAGE
Design Parameters
(IOUT = 40mA)
•
VIN = 3.6V
•
VOUT = 12.0V
•
IPEAK = 235mA
•
IOUT = 40mA @ η > 85%
•
IIN = 156mA (est.)
•
Output Ripple < 60mV
Measured Parameters
(IOUT = 5mA)
•
VIN = 3.60V
•
VOUT = 11.83V
•
IPEAK = 238mA
•
IOUT = 5mA @ η = 86.2%
•
IIN = 19mA
•
Output Ripple ~ 45mV
Measured Parameters
(IOUT = 40mA)
•
VIN = 3.58V
•
VOUT = 11.55V
•
IPEAK = 238mA
•
IOUT = 40mA @ η = 89.6%
•
IIN = 144mA
•
Output Ripple ~ 65mV
TABLE 2 – COMPARISON OF DESIGN VS. ACTUAL PERFORMANCE
Copyright  2002
Rev. 1.0, 2002-12-03
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Integrated Products
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 7
LX1741/LX1742 BOOST CONVERTER
APPLICATION NOTE
DESIGN SUMMARY
Figure 10 and Figure 11 show the actual switching
waveforms for the circuit based upon this design exercise.
Channel 2 shows the output ripple voltage, channel 3
shows the NDRV output (pin 8: LX1741), and channel 4
shows the inductor current. Figure 10 shows light load
(i.e., IOUT = 5mA) waveforms and Figure 11 shows heavy
load waveforms (i.e., IOUT = 40mA). Table 2 highlights
the variance between the design and measured
performance of the circuit.
These results show that we have achieved our
design requirements (at TA = 25°C). This circuit
maintained regulation up to IOUT = 56mA (VOUT =
11.4V) at room temperature.
However, some
performance variance over the entire operating
temperature range is to be expected and should be
thoroughly explored by the designer. Finally, the load
regulation error - in this example - is approximately
1%.(Note: all scope photos shown in this document
were taken using a Tektronix TDS3034B; a Tektronix
TCP202 current probe was used for measuring
inductor current).
FIGURE 11 - LX1741 WAVE FORMS ILOAD = 40mA
VIN = 3.6V, VOUT = 11.6V, IPEAK = 238mA, η = 90%, VRIPPLE
< 100mV (COUT = 4.7µF)
POWER AND THERMAL CONSIDERATIONS
Designers often examine the maximum output
power capability of a DC-DC controller IC. Both
LX1741 and LX1742 are available in the 8-pin MSOP
package and this package’s thermal resistance (ΘJA)
is 206°C/W.
The device datasheets show a
maximum (ambient) junction temperature of (70°C)
150°C. However, at 150°C, degradation to the
internal voltage reference bandgap circuit will
preclude maintaining optimum output voltage
regulation. Moreover, product life-time is reduced
when operating at such a high junction temperature.
Hence, for practical design considerations, we’ll
estimate maximum power dissipation using a junction
temperature value of 75°C and ambient operating
condition of 30°C. Equation 9 describes total power
dissipation as a function of maximum junction
temperature, ambient temperature, and thermal
resistance.
Eq 9
PD =
FIGURE 10 – LX1741 WAVE FORMS ILOAD = 5mA
VIN = 3.6V, VOUT = 11.8V, IPEAK = 238mA, η = 86%, VRIPPLE
< 50mV (COUT = 4.7µF)
(T (
J max )
− TA
)
R ΘJA
Therefore, with respect to these operating
conditions, the maximum power dissipation for the
LX1741 or LX1742 is calculated to be:
PD =
(75°C − 30°C) = 0.22W
206°C/W
Reducing the ambient operating temperature will
allow the controller to dissipate more power
according to the relationship specified in equation 9.
Copyright  2002
Rev. 1.0, 2002-12-03
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Integrated Products
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Page 8
LX1741/LX1742 BOOST CONVERTER
APPLICATION NOTE
Reducing the junction temperature improves overall
reliability and product life. Equation 10 provides an
application specific estimate of the controller’s power
dissipation where IQ is the device quiescent current,
ISRC is the current through the external FET’s source,
RSRC is the internal current sense resistor, D is the
duty cycle, fSW is the maximum switching frequency
and, Qg is the gate charge of the external FET:
Application Notes: LX1741 / 1742 Formula Calculator
for AN22). The spreadsheet contains two sheets
titled 1741 and 1742. The calculator allows the
designer to input values for output voltage, output
current,
input
voltage,
output
capacitance,
inductance, output voltage selection resistor R2, and
the current limit resistor RCS. The calculator returns
values for estimating output voltage ripple (as a
function of droop and overshoot), the output voltage
selection resistor R1, the peak current, and the
output power. The value of peak current is also
calculated at RCS = 0Ω for reference. Now some
words of advice: the validity of calculator’s output is
dependent upon the validity of the input data.
Therefore, here are some guidelines for selecting
input values.
Eq 10
(
2
PD(IC) = VIN × I Q (MAX ) + I PEAK × R SRC × D + f SW × VIN × Q g
)
Eq 10.1
f SW

V
=  t OFF  OUT

 VIN


 


−1
In this design example, VIN = 3.6V and the
maximum quiescent current (IQ) from the LX1741
datasheet is 100mA. The internal current sense
resistor’s value is 200mΩ (typical). Duty cycle is an
estimate and should be maintained to within 85%
under full load. Switching frequency is estimated
using equation 10.1 where the converter’s off-time is
typically 300ns. Here, the gate charge is associated
with the external MOSFET (e.g., the FDV303N lists a
maximum gate charge of 2.3nC). Hence, the LX1741
maximum power dissipation for this example is
estimated as:
 3.6V × 100µA + (235mA)2 × 200mΩ × 
 = 11.8mW

 0.85 + 300kHz × 3.6V × 2nC


PD(IC) = 
The estimated power dissipation of the IC controller
in this application is less than the power value
calculated using equation 9 at TA equals 30°C;
therefore, it is safe to proceed with the design.
Equation 11 provides an estimate of the LX1742’s
controller’s power dissipation. Here, the designer
must consider the RDS(ON) and gate charge of the
internal MOSFET device.
Eq 11
PD(IC)
2

V × I
 IN Q(MAX) + I PEAK × (R DS(ON) + R SRC ) 
=


 × D + fSW × VIN × Qg


DESIGN TOOLS
After reading all this a designer might think, “so
many formulas, so little time?” Fortunately, help is on
the way. A simple Excel™ spreadsheet is available
at our website to help you quickly assess the impact
of varying the design parameters for a particular
application (i.e., refer to Article 1310 under
Copyright  2002
Rev. 1.0, 2002-12-03
1. The value of R2 should be set so as to minimize
error at the VFB input due to offset currents. A
value range between 45KΩ and 90KΩ will suffice
for most applications.
2. The Inductor (L) value of 47µH is presented as a
starting point for most LX1741 and LX1742
application circuits. Remember that selecting the
inductor value requires making trade-offs. For
example, the inductance value should be
sufficient to ensure proper energy storage under
worst-case input voltage and on/off-time
conditions. Further, the inductor core must not go
into saturation. Second, the designer should
minimize the device’s DC resistance to reduce
power loss (thus improving overall efficiency).
System-level EMI, cost, and mechanical size are
other factors that influence inductor selection
criteria.
For LX741 and LX1742 designs,
inductance values from 20µH to 100µH will
support a broad range of applications. Note that
small inductor values tend to increase peak
current variance due to deviations in the mean
value of the comparator delay (tD).
3. The value of the current limit resistor (RCS)
directly affects the value of peak current. The
LX1741 and LX1742 have an absolute maximum
switch current rating of 800mARMS and 500mARMS
respectively. Do not exceed these values.
Always use the smallest current limit resistor
value that your design can tolerate. Setting the
peak current excessively high burns away power
and reduces overall efficiency (and battery life!).
The LX1741 and LX1742 are designed to support
applications that have an output requirement of
less than 1.5W. Use this as your guideline.
Microsemi
Integrated Products
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 9
LX1741/LX1742 BOOST CONVERTER
APPLICATION NOTE
4. Input voltage is simple. Do not exceed 6.0V.
Start-up is guaranteed at 1.6V for very light
loads.
solutions. This application note provided a step-bystep design approach for determining critical circuit
values such as R1, R2, RCS, L, IPEAK, and COUT.
Moreover, relationship curves for RCS, IPEAK, ∆VDROOP,
and ∆VOVERSHOOT versus Input voltage were provided
to aid in the overall understanding of controller
performance.
Additional device and application
information is available from the LX1741 an LX1742
device datasheets available at www.microsemi.com.
5. Cost and the output voltage ripple essentially
define the output capacitor type and value.
These two constraints will set the calculator’s
limits (see Appendix).
CONCLUSION
The LX1741 and LX1742 PFM boost-mode controller
ICs offer designers a broad range of application
Parameter
Units
Typical
IMIN
mA
104.0
Notes
ISCALE
A/kΩ
2.23E-02
IOUT
mA
10.0
Application Parameter
tD
ns
773.0
from datasheet
VIN
V
3.60
Application Parameter
from datasheet
from datasheet
VOUT
V
15.00
Application Parameter
R2
Ω
49900
Application Parameter
RCS
Ω
4020
Application Parameter
L
COUT
VREF
µH
µF
47.0
Application Parameter
20.0
Application Parameter
V
1.200
from datasheet
POUT
=
150
mW
R1
=
573.9
ΚΩ
IPEAK
=
252.9
mA
I PEAK (Rcs=0)
=
163.2
mA
mV
∆VDROOP
=
2
∆VOVERSHOOT
=
6
mV
∆VRIPPLE
=
18
mV
L
VIN
CIN
SW
IN
SHDN
VOUT
OUT
R1
LX1742
LX1742
COUT
FB
ADJ
CS
GND
R CS
R2
FIGURE 12 – LX1742 DESIGN CALCULATOR SPREADSHEET
Copyright  2002
Rev. 1.0, 2002-12-03
Microsemi
Integrated Products
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 10
LX1741/LX1742 BOOST CONVERTER
APPLICATION NOTE
LX1741 SEPIC
CR1
UPS5819
C6
1F
10V
L1
VBAT
VOUT
C4
Q1
FDV303N
C5
R1
78.7K
L2
22 H
25V
C2
R7
10K
6.3V
C1
GND
50V
LX1741
50V
R2
49.9K
R8
15K
SHDN
VADJ
FIGURE 13 – LX1741 SEPIC: TWO-CELL TO 3.3V
(see DN-099A for more information)
Efficiency (%)
80%
70%
60%
2
FIGURE 14 – SWITCHING WAVEFORMS
(Configuration: VIN = 5V, VOUT = 3.3V, IOUT = 150mA)Channel 1: VOUT
(AC coupled; 100mV/div)Channel 2: Switch voltage (DC coupled;
5V/div)Channel 3: L1 Inductor Current (200mA/div.)Channel 4: L2
Inductor Current (200mA/div.)
Copyright  2002
Rev. 1.0, 2002-12-03
3
4
5
6
7
Input Voltage
FIGURE 15 – EFFICIENCY VS. INPUT VOLTAGE
(IOUT = 100mA & 200mA)
Microsemi
Integrated Products
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 11
LX1741/LX1742 BOOST CONVERTER
APPLICATION NOTE
LX1742
CR1
UPS5819
3.6V
C1
R1
10K
+
5V @ 175mA
L1
6.3V
+
C2
U1
C3
OUT
SW
R3
226K
6.3V
FB
IN
/SHDN
ADJ
CS
GND
R4
72K
LX1742CDU
R2
10K
FIGURE 16 – LX1742 3.6V TO 5V BOOST (175mA)
(see DN-099B for more information)
Efficiency
80%
70%
60%
50%
25
45
65
85
105
125
145
165
185
Output Current
FIGURE 18 – EFFICIENCY VS. OUTPUT CURRENT (mA)
FIGURE 17 – SWITCHING WAVEFORMS
Copyright  2002
Rev. 1.0, 2002-12-03
Microsemi
Integrated Products
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 12
LX1741/LX1742 BOOST CONVERTER
APPLICATION NOTE
LX1742 OUTPUT DISCONNECT
RBias
147K
CR1
UPS5819
3.0V
18.0V
L1
+
C2
U1
/SHDN
+
ADJ
35V
35V
FB
IN
C1
C3
OUT
SW
R3
1M
CS
GND
R4
72K
LX1742CDU
R2
1K
FIGURE 19 – LX7142 WITH OUTPUT DISCONNECT (2N3906)
70%
69%
68%
Efficiency
67%
66%
65%
64%
63%
62%
61%
60%
0
2
4
6
8
10
12
14
Output Current
FIGURE 20 – EFFICIENCY VS. OUTPUT CURRENT (mA)
Copyright  2002
Rev. 1.0, 2002-12-03
Microsemi
Integrated Products
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 13
LX1741/LX1742 BOOST CONVERTER
APPLICATION NOTE
References
Microsemi (2000). LX1741: High efficiency, high voltage boost controller. [Data Sheet], Garden Grove, CA. Author
Microsemi (2000). LX1742: High efficiency, high voltage boost controller. [Data Sheet], Garden Grove, CA. Author
Appendix
A brief summary of the various capacitor types is provided below for the novice designer:
CERAMIC: Multi-layer ceramic capacitors are intended for applications that require a device with a small physical
size yet comparatively large electrical capacitance and high insulation resistance. The general-purpose ceramic
capacitors, (while not intended for precision applications) are suitable for use as bypass and filtering applications in
high frequency circuits where significant changes in capacitance, induced by temperature variation, can be
tolerated.
TANTALUM: There are three fundamental types of tantalum capacitors (tantalum foil, wet sintered anode, and solid
electrolyte). The designer usually selects tantalum foil capacitors when high voltage components are required or
when a substantial reverse voltage is applied to the capacitor (e.g., as in switched mode DC-DC conversion
circuits). Wet sintered anode capacitors are often used when low DC leakage is required. Finally, solid electrolyte
tantalum capacitors are preferred for their small size versus a given unit of capacitance.
ALUMINUM ELECTROLYTIC: Aluminum electrolytic capacitors are typically preferred for signal filtering and
bypass applications when large capacitance values are required and limited board space is available.
FILM: Film capacitors are separated into either film/foil capacitor and metal-film capacitor categories. The film/foil
capacitor is characterized by having a high insulation resistance and both excellent current carrying and pulse
handling capability. Moreover, these device types are known to provide superior capacitance stability. The metalfilm capacitor features high volume efficiency and self-healing properties.
Copyright  2002
Rev. 1.0, 2002-12-03
Microsemi
Integrated Products
11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570
Page 14