NSC LM3481

LM3481
High Efficiency Low-Side N-Channel Controller for
Switching Regulators
General Description
Key Specifications
The LM3481 is a versatile Low-Side N-FET high performance
controller for switching regulators. It is suitable for use in
topologies requiring a low-side FET, such as boost, flyback,
SEPIC, etc. The LM3481 can be operated at extremely high
switching frequencies in order to reduce the overall solution
size. The switching frequency of the LM3481 can be adjusted
to any value between 100 kHz and 1 MHz by using a single
external resistor or by synchronizing it to an external clock.
Current mode control provides superior bandwidth and transient response in addition to cycle-by-cycle current limiting.
Current limit can be programmed with a single external resistor.
The LM3481 has built in protection features such as thermal
shutdown, short-circuit protection and over voltage protection. Power saving shutdown mode reduces the total supply
current to 5µA and allows power supply sequencing. Internal
soft-start limits the inrush current at start-up.
■ Wide supply voltage range of 2.97V to 48V
■ 100 kHz to 1 MHz Adjustable and Synchronizable clock
frequency
■ ±1.5% (over temperature) internal reference
■ 10 µA shutdown current (over temperature)
Features
■
■
■
■
■
■
■
■
10-lead MSOP package
Internal push-pull driver with 1A peak current capability
Current limit and thermal shutdown
Frequency compensation optimized with a capacitor and
a resistor
Internal softstart
Current Mode Operation
Adjustable Undervoltage Lockout with Hysteresis
Pulse Skipping at Light Loads
Applications
■ Distributed Power Systems
■ Notebook, PDA, Digital Camera, and other Portable
Applications
■ Offline Power Supplies
■ Set-Top Boxes
Typical Application Circuit
201365a5
Typical SEPIC Converter
© 2007 National Semiconductor Corporation
201365
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LM3481 High Efficiency Low-Side N-Channel Controller for Switching Regulators
November 16, 2007
LM3481
Connection Diagram
20136502
10-Lead Mini SOIC Package (MSOP-10 Package)
Package Marking and Ordering Information
Order Number
Package Type
Package Marking
Supplied As:
LM3481MM
MSOP-10
SJPB
1000 units on Tape and Reel
LM3481MMX
MSOP-10
SJPB
3500 units on Tape and Reel
Pin Description
Pin Name
Pin Number
Description
ISEN
1
Current sense input pin. Voltage generated across an external sense
resistor is fed into this pin.
UVLO
2
Under voltage lockout pin. A resistor divider from VIN to ground is
connected to the UVLO pin. The ratio of these resistances determine
the input voltage which allows switching and the hysteresis to disable
switching.
COMP
3
Compensation pin. A resistor and capacitor combination connected to
this pin provides compensation for the control loop.
FB
4
Feedback pin. Inverting input of the error amplifier.
AGND
5
Analog ground pin. Internal bias circuitry reference. Should be
connected to PGND at a single point.
FA/SYNC/SD
6
Frequency adjust, synchronization, and shutdown pin. A resistor
connected from this pin to ground sets the oscillator frequency. An
external clock signal at this pin will synchronize the controller to the
frequency of the clock. A high level on this pin for ≥ 30 µs will turn the
device off and the device will then draw 5 µA from the supply typically.
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PGND
7
Power ground pin. External power circuitry reference. Should be
connected to AGND at a single point.
DR
8
Drive pin of the IC. The gate of the external MOSFET should be
connected to this pin.
VCC
9
Driver supply voltage pin. Typically a capacitor is tied from the VCC pin
to ground.
VIN
10
Power supply input pin.
2
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
VIN pin Voltage
FB Pin Voltage
FA/SYNC/SD Pin Voltage
COMP Pin Voltage
UVLO Pin Voltage
VCC Pin Voltage
DR Pin Voltage
ISEN Pin Voltage
Peak Driver Output Current
Power Dissipation
-0.4V to 50V
-0.4V to 6V
-0.4V to 6V
-0.4V to 6V
-0.4V to 6V
-0.4V to 6V
-0.4V to 6V
–0.4V to 600 mV
1.0A
Internally Limited
Operating Ratings
−65°C to +150°C
+150°C
2 kV
215°C
220°C
(Note 1)
Supply Voltage
Junction Temperature Range
Switching Frequency
Range
2.97V to 48V
−40°C to +125°C
100 kHz to 1 MHz
Electrical Characteristics
VIN=12V, RFA=40 kΩ unless otherwise indicated under the Conditions column. Typicals and limits appearing in plain type apply
for TJ = 25°C. Limits appearing in boldface type apply over the full Operating Temperature Range (-40°C to 125°C). Datasheet
min/max specification limits are guaranteed by design, test, or statistical analysis. (Notes 3, 4)
Symbol
Parameter
Conditions
VCOMP = 1.4V,
Min
Typical
Max
Units
1.256
1.275
1.294
V
VFB
Feedback Voltage
ΔVLINE
Feedback Voltage Line
Regulation
2.97 ≤ VIN ≤ 48V
0.003
%/V
ΔVLOAD
Output Voltage Load
Regulation
IEAO Source/Sink
±0.5
%/V
VUVLOSEN
Undervoltage Lockout
Reference Voltage
VUVLO Ramping Down
IUVLO
UVLO Source Current
Enabled
VUVLOSD
UVLO Shutdown Voltage
ICOMP
COMP pin Current Sink
VCOMP
2.97 ≤ VIN ≤ 48V
1.345
1.430
1.517
V
3
5
6
µA
VFB = 0V
VFB = 1.275V
0.7
V
640
µA
1
V
fnom
Nominal Switching
Frequency
RFA = 40 kΩ
Vsync-HI
Threshold for
Synchronization on
FA/SYNC/SD pin
Synchronization Voltage
Rising
1.4
V
Vsync-LOW
Threshold for
Synchronization on
FA/SYNC/SD pin
Synchronization Voltage
Falling
0.7
V
RDS1 (ON)
Driver Switch On
Resistance (top)
IDR = 0.2A, VIN= 5V
4
Ω
RDS2 (ON)
Driver Switch On
Resistance (bottom)
IDR = 0.2A
2
Ω
VDR (max)
Maximum Drive Voltage
Swing(Note 6)
Dmax
Maximum Duty Cycle
85
tmin (on)
Minimum On Time
250
ISUPPLY
Supply Current (switching) (Note 8)
3.7
5.0
VFA/SYNC/SD = 3V(Note 9),
VIN = 12V
9
15
IQ
Quiescent Current in
Shutdown Mode
VFA/SYNC/SD = 3V(Note 9),
VIN = 5V
5
10
406
475
VIN < 6V
VIN
VIN ≥ 6V
6
3
550
kHz
V
%
ns
mA
µA
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LM3481
Storage Temperature Range
Junction Temperature
ESD Susceptibilty
Human Body Model (Note 2)
Lead Temperature
MM Package
Vapor Phase (60 sec.)
Infared (15 sec.)
Absolute Maximum Ratings (Note 1)
LM3481
Symbol
Parameter
Conditions
Min
Typical
Max
Units
VSENSE
Current Sense Threshold
Voltage
100
160
190
mV
VSC
Over Load Current Limit
Sense Voltage
157
220
275
mV
VSL
Internal Compensation
Ramp Voltage
VOVP
Output Over-voltage
Protection (with respect to VCOMP = 1.4V
feedback voltage) (Note 7)
26
85
135
mV
VOVP(HYS)
Output Over-Voltage
Protection Hysteresis
VCOMP = 1.4V
28
70
106
mV
Gm
Error Amplifier
Transconductance
VCOMP = 1.4V
216
450
690
µmho
AVOL
Error Amplifier Voltage
Gain
VCOMP = 1.4V
IEAO = 100 µA (Source/Sink)
35
60
66
V/V
IEAO
Error Amplifier Output
Current (Source/ Sink)
Source, VCOMP = 1.4V, VFB =
1.1V
475
640
837
µA
Sink, VCOMP = 1.4V, VFB = 1.4V
VEAO
Error Amplifier Output
Voltage Swing
90
mV
31
65
100
µA
Upper Limit
VFB = 0V
COMP Pin Floating
2.45
2.70
2.93
V
Lower Limit
VFB = 1.4V
0.32
0.60
0.90
V
tSS
Internal Soft-Start Delay
VFB = 1.2V, COMP Pin Floating
15
ms
tr
Drive Pin Rise Time
Cgs = 3000 pf, VDR = 0V to 3V
25
ns
tf
Drive Pin Fall Time
Cgs = 3000 pf, VDR = 3V to 0V
VSD
Shutdown signal threshold Output = High (Shutdown)
(Note 5) FA/SYNC/SD pin Output = Low (Enable)
ISD
Shutdown Pin Current
FA/SYNC/SD pin
TSD
Thermal Shutdown
165
°C
Tsh
Thermal Shutdown
Hysteresis
10
°C
θJA
Thermal Resistance
200
°C/W
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25
1.31
0.40
0.68
VSD = 5V
−1
VSD = 0V
20
MM Package
4
ns
1.40
V
V
µA
Note 2: The human body model is a 100 pF capacitor discharged through a 1.5kΩ resistor into each pin.
Note 3: All limits are guaranteed at room temperature (standard type face) and at temperature extremes (bold type face). All room temperature limits are 100%
tested. All limits at temperature extremes are guaranteed via correlation using standard Statistical Quality Control (SQC) methods. All limits are used to calculate
Average Outgoing Quality Level (AOQL).
Note 4: Typical numbers are at 25°C and represent the most likely norm.
Note 5: The FA/SYNC/SD pin should be pulled to VIN through a resistor to turn the regulator off. The voltage on the FA/SYNC/SD pin must be above the max
limit for the Output = High longer than 30 µs to keep the regulator off and must be below the minimum limit for Output = Low to keep the regulator on.
Note 6: The drive pin voltage, VDR, is equal to the input voltage when input voltage is less than 6V. VDR is equal to 6V when the input voltage is greater than or
equal to 6V.
Note 7: The over-voltage protection is specified with respect to the feedback voltage. This is because the over-voltage protection tracks the feedback voltage.
The over-voltage threshold can be calculated by adding the feedback voltage (VFB) to the over-voltage protection specification.
Note 8: For this test, the FA/SYNC/SD Pin is pulled to ground using a 40 kΩ resistor .
Note 9: For this test, the FA/SYNC/SD Pin is pulled to 3V using a 40 kΩ resistor.
Typical Performance Characteristics
Unless otherwise specified, VIN = 12V, TJ = 25°C.
Comp Pin Voltage vs. Load Current
Switching Frequency vs. RFA
20136546
20136547
Efficiency vs. Load Current (3.3VIN and 12VOUT)
Efficiency vs. Load Current (5VIN and 12VOUT)
20136549
20136548
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LM3481
Note 1: Absolute Maximum Ratings are limits beyond which damage to the device may occur. Operating Ratings indicates conditions for which the device is
intended to be functional, but does not guarantee specific performance limits. For guaranteed specifications and test conditions, see the Electrical Characteristics.
The guaranteed specifications apply only for the test conditions.
LM3481
Efficiency vs. Load Current (9VIN and 12VOUT)
Frequency vs. Temperature
20136550
201365a7
COMP Pin Source Current vs. Temperature
ISupply vs. Input Voltage (Non-Switching)
20136552
20136553
ISupply vs. Input Voltage (Switching)
Shutdown Threshold Hysteresis vs. Temperature
20136556
20136554
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LM3481
Drive Voltage vs. Input Voltage
Short Circuit Protection vs. VIN
20136557
20136558
Current Sense Threshold vs. Input Voltage
Compensation Ramp Amplitude vs. Input Voltage
20136559
20136560
Minimum On-Time vs. Temperature
201365a8
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LM3481
Functional Block Diagram
20136506
The voltage sensed across the sense resistor generally contains spurious noise spikes, as shown in Figure 1. These
spikes can force the PWM comparator to reset the RS latch
prematurely. To prevent these spikes from resetting the latch,
a blank-out circuit inside the IC prevents the PWM comparator
from resetting the latch for a short duration after the latch is
set. This duration, called the blank-out time, is typically 250
ns and is specified as tmin (on) in the electrical characteristics
section.
Under extremely light load or no-load conditions, the energy
delivered to the output capacitor when the external MOSFET
is on during the blank-out time is more than what is delivered
to the load. An over-voltage comparator inside the LM3481
prevents the output voltage from rising under these conditions
by sensing the feedback (FB pin) voltage and resetting the
RS latch. The latch remains in a reset state until the output
decays to the nominal value. Thus the operating frequency
decreases at light loads, resulting in excellent efficiency.
Functional Description
The LM3481 uses a fixed frequency, Pulse Width Modulated
(PWM), current mode control architecture. In a typical application circuit, the peak current through the external MOSFET
is sensed through an external sense resistor. The voltage
across this resistor is fed into the ISEN pin. This voltage is then
level shifted and fed into the positive input of the PWM comparator. The output voltage is also sensed through an external
feedback resistor divider network and fed into the error amplifier (EA) negative input (feedback pin, FB). The output of
the error amplifier (COMP pin) is added to the slope compensation ramp and fed into the negative input of the PWM
comparator.
At the start of any switching cycle, the oscillator sets the RS
latch using the SET/Blank-out and switch logic blocks. This
forces a high signal on the DR pin (gate of the external MOSFET) and the external MOSFET turns on. When the voltage
on the positive input of the PWM comparator exceeds the
negative input, the RS latch is reset and the external MOSFET
turns off.
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8
LM3481
20136507
FIGURE 1. Basic Operation of the PWM comparator
falling slopes, Mon and −Moff respectively. Where Mon is the
inductor slope during the switch on-time and −Moff is the inductor slope during the switch off-time and are related to M1
and −M2 by:
OVER VOLTAGE PROTECTION
The LM3481 has over voltage protection (OVP) for the output
voltage. OVP is sensed at the feedback pin (FB). If at anytime
the voltage at the feedback pin rises to VFB + VOVP, OVP is
triggered. See the electrical characteristics section for limits
on VFB and VOVP.
OVP will cause the drive pin (DR) to go low, forcing the power
MOSFET off. With the MOSFET off, the output voltage will
drop. The LM3481 will begin switching again when the feedback voltage reaches VFB + (VOVP - VOVP(HYS)). See the electrical characteristics section for limits on VOVP(HYS).
The internal bias of the LM3481 comes from either the internal
bias voltage generator as shown in the block diagram or directly from the voltage at the VIN pin. At input voltages lower
than 6V the internal IC bias is the input voltage and at voltages
above 6V the internal bias voltage generator of the LM3481
provides the bias.
M1 = Mon x RSEN
−M2 = −Moff x RSEN
For the boost topology:
Mon = VIN / L
−Moff = (VIN − VOUT) / L
M1 = [VIN / L] x RSEN
−M2 = [(VIN − VOUT) / L] x RSEN
M2 = [(VOUT − VIN) / L] x RSEN
Current mode control has an inherent instability for duty cycles greater than 50%, as shown in Figure 2, where the control
signal slope, MC, equals zero. In Figure 2, a small increase in
the load current causes the sampled signal to increase by
ΔVsamp0. The effect of this load change, ΔVsamp1, at the end
of the first switching cycle is :
SLOPE COMPENSATION RAMP
The LM3481 uses a current mode control scheme. The main
advantages of current mode control are inherent cycle-by-cycle current limit for the switch and simpler control loop characteristics. It is easy to parallel power stages using current
mode control since current sharing is automatic. However
there is a natural instability that will occur for duty cycles, D,
greater than 50% if additional slope compensation is not addressed as described below.
The current mode control scheme samples the inductor current, IL, and compares the sampled signal, Vsamp, to a internally generated control signal, Vc. The current sense resistor,
RSEN, as shown in Figure 5, converts the sampled inductor
current, IL, to the voltage signal, Vsamp, that is proportional to
IL such that:
From the above equation, when D > 0.5, ΔVsamp1 will be
greater than ΔVsamp0. In other words, the disturbance is divergent. So a very small perturbation in the load will cause
the disturbance to increase. To ensure that the perturbed signal converges we must maintain:
Vsamp = IL x RSEN
The rising and falling slopes, M1 and −M2 respectively, of
Vsamp are also proportional to the inductor current rising and
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LM3481
20136509
FIGURE 2. Sub-Harmonic Oscillation for D>0.5
20136511
FIGURE 3. Compensation Ramp Avoids Sub-Harmonic Oscillation
To prevent the sub-harmonic oscillations, a compensation
ramp is added to the control signal, as shown in Figure 3.
With the compensation ramp, ΔVsamp1 and the convergence
criteria are expressed by,
increases the amplitude of the compensation ramp as shown
in Figure 4.
201365a1
FIGURE 4. Additional Slope Compensation Added Using
External Resistor RSL
The compensation ramp has been added internally in the
LM3481. The slope of this compensation ramp has been selected to satisfy most applications, and it's value depends on
the switching frequency. This slope can be calculated using
the formula:
Where,
ΔVSL = K x RSL
K = 40 µA typically and changes slightly as the switching frequency changes. Figure 6 shows the effect the current K has
on ΔVSLand different values of RSL as the switching frequency
changes.
A more general equation for the slope compensation ramp,
MC, is shown below to include ΔVSL caused by the resistor
RSL.
MC = VSL x fS
In the above equation, VSL is the amplitude of the internal
compensation ramp and fS is the controller's switching frequency. Limits for VSL have been specified in the electrical
characteristics section.
In order to provide the user additional flexibility, a patented
scheme has been implemented inside the IC to increase the
slope of the compensation ramp externally, if the need arises.
Adding a single external resistor, RSL(as shown in Figure 5)
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MC = (VSL + ΔVSL) x fS
10
FREQUENCY ADJUST/SYNCHRONIZATION/SHUTDOWN
The switching frequency of the LM3481 can be adjusted between 100 kHz and 1 MHz using a single external resistor.
This resistor must be connected between the FA/SYNC/SD
pin and ground, as shown in Figure 7. Please refer to the typical performance characteristics to determine the value of the
resistor required for a desired switching frequency.
The following equation can also be used to estimate the frequency adjust resistor.
Where fS is in kHz and RFA in kΩ.
The LM3481 can be synchronized to an external clock. The
external clock must be connected between the FA/SYNC/SD
pin and ground, as shown in Figure 8. The frequency adjust
resistor may remain connected while synchronizing a signal,
therefore if there is a loss of signal, the switching frequency
will be set by the frequency adjust resistor.
It is also necessary to have the width of the synchronization
pulse narrower than the duty cycle of the converter and to
have the synchronization pulse width ≥ 300 ns.
The FA/SYNC/SD pin also functions as a shutdown pin. If a
high signal (refer to the electrical characteristics section for
definition of high signal) appears on the FA/SYNC/SD pin, the
LM3481 stops switching and goes into a low current mode.
The total supply current of the IC reduces to 5 µA, typically,
under these conditions.
Figure 9 and Figure 10 shows an implementation of a shutdown function when operating in frequency adjust mode and
synchronization mode respectively. In frequency adjust
mode, connecting the FA/SYNC/SD pin to ground forces the
clock to run at a certain frequency. Pulling this pin high shuts
down the IC. In frequency adjust or synchronization mode, a
high signal for more than 30 µs shuts down the IC.
20136513
FIGURE 5. Increasing the Slope of the Compensation
Ramp
20136551
FIGURE 6. ΔVSL vs RSL
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LM3481
It is good design practice to only add as much slope compensation as needed to avoid subharmonic oscillation. Additional slope compensation minimizes the influence of the
sensed current in the control loop. With very large slope compensation the control loop characteristics are similar to a
voltage mode regulator which compares the error voltage to
a saw tooth waveform rather than the inductor current.
LM3481
20136514
FIGURE 7. Frequency Adjust
20136515
FIGURE 8. Frequency Synchronization
20136516
FIGURE 9. Shutdown Operation in Frequency Adjust Mode
20136517
FIGURE 10. Shutdown Operation in Synchronization Mode
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Short Circuit Protection
When the voltage across the sense resistor (measured on the
ISEN Pin) exceeds 220 mV, short-circuit current limit gets activated. A comparator inside the LM3481 reduces the switching frequency by a factor of 8 and maintains this condition until
the short is removed.
20136596
FIGURE 11. UVLO Pin Resistor Divider
Typical Applications
The LM3481 may be operated in either continuous or discontinuous conduction mode. The following applications are designed for continuous conduction operation. This mode of
operation has higher efficiency and lower EMI characteristics
than the discontinuous mode.
load and output capacitor. The ratio of these two cycles determines the output voltage. The output voltage is defined as:
BOOST CONVERTER
The most common topology for the LM3481 is the boost or
step-up topology. The boost converter converts a low input
voltage into a higher output voltage. The basic configuration
for a boost regulator is shown in Figure 12. In continuous
conduction mode (when the inductor current never reaches
zero at steady state), the boost regulator operates in two cycles. In the first cycle of operation, MOSFET Q is turned on
and energy is stored in the inductor. During this cycle, diode
D1 is reverse biased and load current is supplied by the output
capacitor, COUT.
In the second cycle, MOSFET Q is off and the diode is forward
biased. The energy stored in the inductor is transferred to the
(ignoring the voltage drop across the MOSFET and the
diode), or
where D is the duty cycle of the switch, VD1 is the forward
voltage drop of the diode, and VQ is the drop across the MOSFET when it is on. The following sections describe selection
of components for a boost converter.
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LM3481
If the UVLO pin function is not desired, select R8 and R7 of
equal magnitude greater than 100 kΩ. This will allow VIN to
be in control of the UVLO thresholds. The UVLO pin may also
be used to implement the enable/disable function. If a signal
pulls the UVLO pin below the 1.43V (typical) threshold, the
converter will be disabled.
Under Voltage Lockout (UVLO) Pin
The UVLO pin provides user programmable enable and shutdown thresholds. The UVLO pin is compared to an internal
reference of 1.43V (typical), and a resistor divider programs
the enable threshold, VEN. When the IC is enabled, a 5 μA
current is sourced out of the UVLO pin, which effectively
causes a hysteresis, and the UVLO shutdown threshold,
VSH, is now lower than the enable threshold. Setting these
thresholds requires two resistors connected from the VIN pin
to the UVLO pin and from the UVLO pin to GND (see Figure
11). Select the desired enable, VEN, and UVLO shutdown,
VSH, threshold voltages and use the following equations to
determine the resistance values:
LM3481
20136522
FIGURE 12. Simplified Boost Converter Diagram (a) First cycle of operation. (b) Second cycle of operation
the converter will operate in discontinuous conduction mode.
If ΔiL is smaller than IL, the inductor current will stay above
zero and the converter will operate in continuous conduction
mode. All the analysis in this datasheet assumes operation in
continuous conduction mode. To operate in continuous conduction mode, the following conditions must be met:
POWER INDUCTOR SELECTION
The inductor is one of the two energy storage elements in a
boost converter. Figure 13 shows how the inductor current
varies during a switching cycle. The current through an inductor is quantified as:
IL > ΔiL
Choose the minimum IOUT to determine the minimum L. A
common choice is to set (2 x ΔiL) to 30% of IL. Choosing an
appropriate core size for the inductor involves calculating the
average and peak currents expected through the inductor. In
a boost converter,
IL_peak = IL(max) + ΔiL(max)
A core size with ratings higher than these values should be
chosen. If the core is not properly rated, saturation will dramatically reduce overall efficiency.
The LM3481 can be set to switch at very high frequencies.
When the switching frequency is high, the converter can operate with very small inductor values. With a small inductor
value, the peak inductor current can be extremely higher than
the output currents, especially under light load conditions.
The LM3481 senses the peak current through the switch. The
peak current through the switch is the same as the peak current calculated above.
20136524
FIGURE 13. a. Inductor current b. Diode current c. Switch
current
If VL(t) is constant, diL(t)/dt must be constant. Hence, for a
given input voltage and output voltage, the current in the inductor changes at a constant rate.
The important quantities in determining a proper inductance
value are IL (the average inductor current) and ΔiL (the inductor current ripple difference between the peak inductor current
and the average inductor current). If ΔiL is larger than IL, the
inductor current will drop to zero for a portion of the cycle and
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14
The peak current through the switch is equal to the peak inductor current.
Isw(peak) = IL(max) + ΔiL
Therefore for a boost converter
Combining the two equations yields an expression for RSEN
A 100 pF capacitor may be connected between the feedback
and ground pins to reduce noise.
The maximum amount of current that can be delivered at the
output can be controlled by the sense resistor, RSEN. Current
limit occurs when the voltage that is generated across the
sense resistor equals the current sense threshold voltage,
VSENSE. Limits for VSENSE have been specified in the electrical
characteristics section. This can be expressed as:
Evaluate RSEN at the maximum and minimum VIN values and
choose the smallest RSEN calculated.
20136520
FIGURE 14. Adjusting the Output Voltage
Note that since ΔVSL = RSL x K as defined earlier, RSLcan be
used to provide an additional method for setting the current
limit. In some designs RSL can also be used to help filter noise
to keep the ISEN pin quiet.
CURRENT LIMIT WITH ADDITIONAL SLOPE
COMPENSATION
If an external slope compensation resistor is used (see Figure
5) the internal control signal will be modified and this will have
an effect on the current limit.
If RSL is used, then this will add to the existing slope compensation. The command voltage, VCS, will then be given by:
POWER DIODE SELECTION
Observation of the boost converter circuit shows that the average current through the diode is the average load current,
and the peak current through the diode is the peak current
through the inductor. The diode should be rated to handle
more than the inductor peak current. The peak diode current
can be calculated using the formula:
VCS = VSENSE − ΔVSL
Where VSENSE is a defined parameter in the electrical characteristics section and ΔVSL is the additional slope compensation generated as discussed in the Slope Compensation
Ramp section. This changes the equation for RSEN to:
ID(Peak) = [IOUT/ (1−D)] + ΔiL
In the above equation, IOUT is the output current and ΔiL has
been defined in Figure 13.
The peak reverse voltage for a boost converter is equal to the
regulator output voltage. The diode must be capable of handling this peak reverse voltage. To improve efficiency, a low
forward drop Schottky diode is recommended.
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LM3481
Isw(peak) x RSEN = VSENSE
PROGRAMMING THE OUTPUT VOLTAGE AND OUTPUT
CURRENT
The output voltage can be programmed using a resistor divider between the output and the feedback pins, as shown in
Figure 14. The resistors are selected such that the voltage at
the feedback pin is 1.275V. RF1 and RF2 can be selected using
the equation,
LM3481
boost application, low values can cause impedance interactions. Therefore a good quality capacitor should be chosen in
the range of 100 µF to 200 µF. If a value lower than 100 µF is
used, then problems with impedance interactions or switching
noise can affect the LM3481. To improve performance, especially with VIN below 8V, it is recommended to use a 20Ω
resistor at the input to provide a RC filter. This resistor is
placed in series with the VIN pin with only a bypass capacitor
attached to the VIN pin directly (see Figure 15). A 0.1 µF or 1
µF ceramic capacitor is necessary in this configuration. The
bulk input capacitor and inductor will connect on the other side
of the resistor with the input power supply.
POWER MOSFET SELECTION
The drive pin, DR, of the LM3481 must be connected to the
gate of an external MOSFET. In a boost topology, the drain
of the external N-Channel MOSFET is connected to the inductor and the source is connected to the ground. The drive
pin voltage, VDR, depends on the input voltage (see typical
performance characteristics). In most applications, a logic
level MOSFET can be used. For very low input voltages, a
sub-logic level MOSFET should be used.
The selected MOSFET directly controls the efficiency. The
critical parameters for selection of a MOSFET are:
1. Minimum threshold voltage, VTH(MIN)
2. On-resistance, RDS(ON)
3. Total gate charge, Qg
4. Reverse transfer capacitance, CRSS
5. Maximum drain to source voltage, VDS(MAX)
The off-state voltage of the MOSFET is approximately equal
to the output voltage. VDS(MAX) of the MOSFET must be
greater than the output voltage. The power losses in the
MOSFET can be categorized into conduction losses and ac
switching or transition losses. RDS(ON) is needed to estimate
the conduction losses. The conduction loss, PCOND, is the
I2R loss across the MOSFET. The maximum conduction loss
is given by:
20136593
FIGURE 15. Reducing IC Input Noise
OUTPUT CAPACITOR SELECTION
The output capacitor in a boost converter provides all the output current when the inductor is charging. As a result it sees
very large ripple currents. The output capacitor should be capable of handling the maximum rms current. The rms current
in the output capacitor is:
where DMAX is the maximum duty cycle.
Where
At high switching frequencies the switching losses may be the
largest portion of the total losses.
The switching losses are very difficult to calculate due to
changing parasitics of a given MOSFET in operation. Often,
the individual MOSFET datasheet does not give enough information to yield a useful result. The following formulas give
a rough idea how the switching losses are calculated:
and D, the duty cycle is equal to (VOUT − VIN)/VOUT.
The ESR and ESL of the output capacitor directly control the
output ripple. Use capacitors with low ESR and ESL at the
output for high efficiency and low ripple voltage. Surface
mount tantalums, surface mount polymer electrolytic and
polymer tantalum, Sanyo- OSCON, or multi-layer ceramic capacitors are recommended at the output.
LAYOUT GUIDELINES
Good board layout is critical for switching controllers such as
the LM3481. First the ground plane area must be sufficient for
thermal dissipation purposes and second, appropriate guidelines must be followed to reduce the effects of switching noise.
Switch mode converters are very fast switching devices. In
such devices, the rapid increase of input current combined
with the parasitic trace inductance generates unwanted Ldi/
dt noise spikes. The magnitude of this noise tends to increase
as the output current increases. This parasitic spike noise
may turn into electromagnetic interference (EMI), and can also cause problems in device performance. Therefore, care
must be taken in layout to minimize the effect of this switching
noise. The current sensing circuit in current mode devices can
be easily effected by switching noise. This noise can cause
duty cycle jitter which leads to increased spectral noise. Although the LM3481 has 250 ns blanking time at the beginning
of every cycle to ignore this noise, some noise may remain
after the blanking time.
INPUT CAPACITOR SELECTION
Due to the presence of an inductor at the input of a boost
converter, the input current waveform is continuous and triangular, as shown in Figure 13. The inductor ensures that the
input capacitor sees fairly low ripple currents. However, as the
input capacitor gets smaller, the input ripple goes up. The rms
current in the input capacitor is given by:
The input capacitor should be capable of handling the rms
current. Although the input capacitor is not as critical in a
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16
The PGND and AGND pins have to be connected to the same
ground very close to the IC. To avoid ground loop currents
attach all the grounds of the system only at one point.
A ceramic input capacitor should be connected as close as
possible to the Vin pin and grounded close to the GND pin.
For a layout example please see Application Note 1204. For
more information about layout in switch mode power supplies
please refer to Application Note 1229.
COMPENSATION
For detailed explanation on how to select the right compensation components to attach to the compensation pin for a
boost topology please see Application Note 1286. When calculating the Error Amplifier DC gain, AEA, ROUT = 152 kΩ for
the LM3481.
20136597
FIGURE 16. Current Flow In A Boost Application
17
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LM3481
The most important layout rule is to keep the AC current loops
as small as possible. Figure 16 shows the current flow of a
boost converter. The top schematic shows a dotted line which
represents the current flow during on-state and the middle
schematic shows the current flow during off-state. The bottom
schematic shows the currents we refer to as AC currents.
They are the most critical ones since current is changing in
very short time periods. The dotted lined traces of the bottom
schematic are the once to make as short as possible.
LM3481
(MIN), the on-resistance, RDS(ON), the total gate charge, Qg, the
Designing SEPIC Using LM3481
reverse transfer capacitance, CRSS, and the maximum drain
to source voltage, VDS(MAX). The peak switch voltage in a
SEPIC is given by:
Since the LM3481 controls a low-side N-Channel MOSFET,
it can also be used in SEPIC (Single Ended Primary Inductance Converter) applications. An example of SEPIC using
the LM3481 is shown in Figure 17. As shown in Figure 17, the
output voltage can be higher or lower than the input voltage.
The SEPIC uses two inductors to step-up or step-down the
input voltage. The inductors L1 and L2 can be two discrete
inductors or two windings of a coupled transformer since
equal voltages are applied across the inductor throughout the
switching cycle. Using two discrete inductors allows use of
catalog magnetics, as opposed to a custom transformer. The
input ripple can be reduced along with size by using the coupled windings of transformer for L1 and L2.
Due to the presence of the inductor L1 at the input, the SEPIC
inherits all the benefits of a boost converter. One main advantage of SEPIC over a boost converter is the inherent input
to output isolation. The capacitor CS isolates the input from
the output and provides protection against shorted or malfunctioning load. Hence, the SEPIC is useful for replacing
boost circuits when true shutdown is required. This means
that the output voltage falls to 0V when the switch is turned
off. In a boost converter, the output can only fall to the input
voltage minus a diode drop.
The duty cycle of a SEPIC is given by:
VSW(PEAK) = VIN + VOUT + VDIODE
The selected MOSFET should satisfy the condition:
VDS(MAX) > VSW(PEAK)
The peak switch current is given by:
Where ΔIL1 and ΔIL2 are the peak-to-peak inductor ripple currents of inductors L1 and L2 respectively.
The rms current through the switch is given by:
POWER DIODE SELECTION
The Power diode must be selected to handle the peak current
and the peak reverse voltage. In a SEPIC, the diode peak
current is the same as the switch peak current. The off-state
voltage or peak reverse voltage of the diode is VIN + VOUT.
Similar to the boost converter, the average diode current is
equal to the output current. Schottky diodes are recommended.
In the above equation, VQ is the on-state voltage of the MOSFET, Q1, and VDIODE is the forward voltage drop of the diode.
POWER MOSFET SELECTION
As in a boost converter, the parameters governing the selection of the MOSFET are the minimum threshold voltage, VTH
20136544
FIGURE 17. Typical SEPIC Converter
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18
SENSE RESISTOR SELECTION
The peak current through the switch, ISWPEAK, can be adjusted
using the current sense resistor, RSEN, to provide a certain
output current. Resistor RSEN can be selected using the formula:
IL2AVE = IOUT
Peak to peak ripple current, to calculate core loss if necessary:
Sepic Capacitor Selection
The selection of SEPIC capacitor, CS, depends on the rms
current. The rms current of the SEPIC capacitor is given by:
The SEPIC capacitor must be rated for a large ACrms current
relative to the output power. This property makes the SEPIC
much better suited to lower power applications where the rms
current through the capacitor is small (relative to capacitor
technology). The voltage rating of the SEPIC capacitor must
be greater than the maximum input voltage. Tantalum capacitors are the best choice for SMT, having high rms current
ratings relative to size. Ceramic capacitors could be used, but
the low C values will tend to cause larger changes in voltage
across the capacitor due to the large currents, and high C
value ceramics are expensive. Electrolytics work well for
through hole applications where the size required to meet the
rms current rating can be accommodated. There is an energy
balance between CS and L1, which can be used to determine
the value of the capacitor. The basic energy balance equation
is:
Maintaining the condition IL > ΔIL/2 to ensure continuous conduction mode yields the following minimum values for L1 and
L2:
Peak current in the inductor, to ensure the inductor does not
saturate:
Where
IL1PK must be lower than the maximum current rating set by
the current sense resistor.
The value of L1 can be increased above the minimum recommended value to reduce input ripple and output ripple.
However, once ΔIL1 is less than 20% of IL1AVE, the benefit to
output ripple is minimal.
By increasing the value of L2 above the minimum recommendation, ΔIL2 can be reduced, which in turn will reduce the
output ripple voltage:
is the ripple voltage across the SEPIC capacitor, and
is the ripple current through the inductor L1. The energy balance equation can be solved to provide a minimum value for
CS:
where ESR is the effective series resistance of the output capacitor.
19
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LM3481
If L1 and L2 are wound on the same core, then L1 = L2 = L.
All the equations above will hold true if the inductance is replaced by 2L. A good choice for transformer with equal turns
is Coiltronics CTX series Octopack.
SELECTION OF INDUCTORS L1 AND L2
Proper selection of the inductors L1 and L2 to maintain constant current mode requires calculations of the following parameters.
Average current in the inductors:
LM3481
placed in series with the VIN pin with only a bypass capacitor
attached to the VIN pin directly (see Figure 15). A 0.1 µF or 1
µF ceramic capacitor is necessary in this configuration. The
bulk input capacitor and inductor will connect on the other side
of the resistor with the input power supply.
Input Capacitor Selection
Similar to a boost converter, the SEPIC has an inductor at the
input. Hence, the input current waveform is continuous and
triangular. The inductor ensures that the input capacitor sees
fairly low ripple currents. However, as the input capacitor gets
smaller, the input ripple goes up. The rms current in the input
capacitor is given by:
Output Capacitor Selection
The output capacitor of the SEPIC sees very large ripple currents similar to the output capacitor of a boost converter. The
rms current through the output capacitor is given by:
The input capacitor should be capable of handling the rms
current. Although the input capacitor is not as critical in a
SEPIC application, low values can cause impedance interactions. Therefore a good quality capacitor should be chosen in
the range of 100 µF to 200 µF. If a value lower than 100 µF is
used, then problems with impedance interactions or switching
noise can affect the LM3481. To improve performance, especially with VIN below 8V, it is recommended to use a 20Ω
resistor at the input to provide a RC filter. This resistor is
The ESR and ESL of the output capacitor directly control the
output ripple. Use capacitors with low ESR and ESL at the
output for high efficiency and low ripple voltage. Surface
mount tantalums, surface mount polymer electrolytic and
polymer tantalum, Sanyo- OSCON, or multi-layer ceramic capacitors are recommended at the output for low ripple.
Other Application Circuits
20136543
FIGURE 18. Typical High Efficiency Step-Up (Boost) Converter
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20
LM3481
Physical Dimensions inches (millimeters) unless otherwise noted
10-Lead MSOP Package
NS Package Number MUB10A
21
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LM3481 High Efficiency Low-Side N-Channel Controller for Switching Regulators
Notes
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