NSC LM3475MF

LM3475
Hysteretic PFET Buck Controller
General Description
Features
The LM3475 is a hysteretic P-FET buck controller designed
to support a wide range of high efficiency applications in a
very small SOT23-5 package. The hysteretic control scheme
has several advantages, including simple system design
with no external compensation, stable operation with a wide
range of components, and extremely fast transient response. Hysteretic control also provides high efficiency operation, even at light loads. The PFET architecture allows for
low component count as well as 100% duty cycle and ultralow dropout operation.
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Easy to use control methodology
0.8V to VIN adjustable output range
High Efficiency (90% typical)
± 0.9% ( ± 1.5% over temp) feedback voltage
100% duty cycle capable
Maximum operating frequency up to 2MHz
Internal Soft-Start
Enable pin
SOT23-5 package
Applications
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TFT Monitor
Auto PC
Vehicle Security
Navigation Systems
Notebook Standby Supply
Battery Powered Portable Applications
Distributed Power Systems
Typical Application Circuit
20070101
© 2004 National Semiconductor Corporation
DS200701
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LM3475 Hysteretic PFET Buck Controller
October 2004
LM3475
Connection Diagram
Top View
20070102
5 Lead Plastic SOT23-5
NS package Number MF05A
Package Marking and Ordering Information
Order Number
Package Type
Package Marking
Supplied As:
LM3475MF
SOT23-5
S65B
1000 units on Tape and Reel
LM3475MFX
SOT23-5
S65B
3000 units on Tape and Reel
Pin Description
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Pin Name
Pin Number
FB
1
Feedback input. Connect to a resistor divider between the output
and GND.
Description
GND
2
Ground.
EN
3
Enable. Pull this pin above 1.5V (typical) for normal operation.
When EN is low, the device enters shutdown mode.
VIN
4
Power supply input.
PGATE
5
Gate drive output for the external PFET.
2
Lead Temperature
Vapor Phase (60 sec.)
Infared (15 sec.)
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
VIN
−0.3V to 16V
PGATE
−0.3V to 16V
FB
−0.3V to 5V
EN
−0.3V to 16V
Storage Temperature
Operating Ratings (Note 1)
Supply Voltage
440mW
ESD Susceptibilty
Human Body Model (Note 3)
2.7V to 10V
Operating Junction
Temperature
−65˚C to 150˚C
Power Dissipation (Note 2)
215˚C
220˚C
−40˚C to +125˚C
2.5kV
Electrical Characteristics
Specifications in Standard type face are for TJ = 25˚C, and in bold type face apply over the full Operating Temperature
Range (TJ = −40˚C to +125˚C). Unless otherwise specified, VIN = EN = 5.0V. Datasheet min/max specification limits are guaranteed by design, test, or statistical analysis.
Symbol
IQ
Parameter
Quiescent Current
Conditions
EN = VIN (PGATE
Open)
EN = 0V
Min
Typ
Max
170
260
320
4
7
10
0.788
0.8
0.812
Unit
µA
VFB
Feedback Voltage
%∆VFB/∆VIN
Feedback Voltage
Line Regulation
2.7V < VIN < 10V
0.01
VHYST
Comparator
Hysteresis
2.7V < VIN < 10V
−40˚C to +125˚C
21
21
28
32
mV
IFB
FB Bias Current
50
600
nA
VthEN
Enable Threshold
Voltage
1.5
1.8
V
Increasing
1.2
Hysteresis
IEN
RPGATE
IPGATE
Enable Leakage
Current
Driver Resistance
Driver Output Current
%/V
365
EN = 10V
.025
Source
ISOURCE = 100mA
2.8
Sink
ISink = 100mA
1.8
Source
VPGATE = 3.5V
CPGATE = 1nF
0.475
Sink
VPGATE = 3.5V
CPGATE = 1nF
1.0
V
mV
1
µA
Ω
A
TSS
Soft-Start Time
2.7V < VIN < 10V
(EN Rising)
TONMIN
Minimum On-Time
PGATE Open
VUVD
Under Voltage
Detection
Measured at the FB
Pin
3
0.487
4
ms
180
ns
0.56
0.613
V
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LM3475
Absolute Maximum Ratings (Note 1)
LM3475
Electrical Characteristics
(Continued)
Note 1: Absolute maximum ratings are limits beyond which damage to the device may occur. Operating Ratings are conditions for which the device is intended to
be functional, but device parameter specifications may not be guaranteed. For guaranteed specifications and test conditions, see the Electrical Characteristics.
Note 2: The maximum allowable power dissipation is a function of the maximum junction temperature, TJ_MAX, the junction-to-ambient thermal resistance, θJA and
the ambient temperature, TA. The maximum allowable power dissipation at any ambient temperature is calculated using:
PD_MAX = (TJ_MAX - TA)/θJA. The maximum power dissipation of 0.44W is determined using TA = 25˚C, θJA = 225˚C/W, and TJ_MAX = 125˚C.
Note 3: The human body model is a 100 pF capacitor discharged through a 1.5kΩ resistor into each pin.
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4
Quiescent Current vs Input Voltage
Feedback Voltage vs Temperature
20070122
20070123
Hysteresis Voltage vs Input Voltage
Hysteresis Voltage vs Temperature
20070124
20070125
Efficiency vs Input Voltage
IOUT = 2A
Efficiency vs Load Current
20070126
20070127
5
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LM3475
Typical Performance Characteristics Unless specified otherwise, all curves taken at VIN = 5V,
VOUT = 2.5V, L = 10 µH, COUT = 100 µF, ESR = 100mΩ, and TA = 25˚C.
LM3475
Typical Performance Characteristics Unless specified otherwise, all curves taken at VIN = 5V, VOUT
= 2.5V, L = 10 µH, COUT = 100 µF, ESR = 100mΩ, and TA = 25˚C. (Continued)
Start Up
Output Ripple Voltage
20070128
20070129
Load Transient Response with External Ramp
(Circuit from Figure 3)
Load Transient Response
(Typical Application Circuit from Figure 5)
20070131
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20070132
6
LM3475
Block Diagram
20070103
Operation Description
OVERVIEW
The LM3475 is a buck (step-down) DC-DC controller that
uses a hysteretic control architecture, which results in Pulse
Frequency Modulated (PFM) regulation. The hysteretic control scheme does not utilize an internal oscillator. Switching
frequency depends on external components and operating
conditions. Operating frequency decreases at light loads,
resulting in excellent efficiency compared to PWM architectures. Because switching is directly controlled by the output
conditions, hysteretic control provides exceptional load transient response.
HYSTERETIC CONTROL CIRCUIT
The LM3475 uses a comparator-based voltage control loop.
The voltage on the feedback pin is compared to a 0.8V
reference with 21mV of hysteresis. When the FB input to the
comparator falls below the reference voltage, the output of
the comparator goes low. This results in the driver output,
PGATE, pulling the gate of the PFET low and turning on the
PFET.
With the PFET on, the input supply charges COUT and
supplies current to the load through the PFET and the inductor. Current through the inductor ramps up linearly, and the
output voltage increases. As the FB voltage reaches the
upper threshold (reference voltage plus hysteresis) the output of the comparator goes high, and the PGATE turns the
PFET off. When the PFET turns off, the catch diode turns on,
and the current through the inductor ramps down. As the
output voltage falls below the reference voltage, the cycle
repeats. The resulting output, inductor current, and switch
node waveforms are shown in Figure 1.
20070104
FIGURE 1. Hysteretic Waveforms
The LM3475 operates in discontinuous conduction mode at
light load current and continuous conduction mode at heavy
load current. In discontinuous conduction mode, current
through the inductor starts at zero and ramps up to the peak,
then ramps down to zero. The next cycle starts when the FB
voltage reaches the reference voltage. Until then, the inductor current remains zero. Operating frequency is low, as are
switching losses. In continuous conduction mode, current
always flows through the inductor and never ramps down to
zero.
SOFT-START
The LM3475 includes an internal soft-start function to protect
components from excessive inrush current and output voltage overshoot. As VIN rises above 2.7V (typical), the internal
bias circuitry becomes active. When EN goes high, the
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LM3475
Operation Description
MINIMUM ON/OFF TIME
(Continued)
To ensure accurate comparator switching, the LM3475 imposes a blanking time after each comparator state change.
This blanking time is 180ns typically. Immediately after the
comparator goes high or low, it will be held in that state for
the duration of the blanking time. This helps keep the hysteretic comparator from improperly responding to switching
noise spikes (See Reducing Switching Noise) and ESL
spikes (See Output Capacitor Selection) at the output.
device enters soft-start. During soft-start, the reference voltage is ramped up to the nominal value of 0.8V in approximately 4ms. Duty cycle and output voltage will increase as
the reference voltage is ramped up.
UNDER VOLTAGE DETECTION
When the output voltage falls below 70% (typical) of the
normal voltage, as measured at the FB pin, the device turns
off PFET and restarts a new soft-start cycle. In short circuit,
the PFET is always on, and the converter is effectively a
resistor divider from input to output to ground. Whether the
part restarts depends on the power path resistance and the
short circuit resistance. This feature should not be considered as overcurrent protection or output short circuit protection.
At very low or very high duty cycle operation, maximum
frequency will be limited by the blanking time. The maximum
operating frequency can be determined by the following
equations:
FMAX = D / tonmin
FMAX = (1-D) / toffmin
Where D is the duty cycle, defined as VOUT/VIN, and tonmin
and toffmin is the sum of the blanking time, the propagation
delay time and the PFET delay time (see Figure 1).
PGATE
During switching, the PGATE pin swings from VIN (off) to
ground (on). As input voltage increases, the time it takes to
slew the gate of the PFET on and off also increases. Also, as
the PFET gate voltage approaches VIN, the PGATE current
driving capability decreases. This can cause a significant
additional delay in turning the switch off when using a PFET
with a low threshold voltage. These two effects will increase
power dissipation and reduce efficiency. Therefore, a PFET
with relatively high threshold voltage and low gate capacitance is recommended.
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ENABLE PIN (EN)
The LM3475 provides a shutdown function via the EN pin to
disable the device. The device is active when the EN pin is
pulled above 1.5V (typ) and in shutdown mode when EN is
below 1.135V (typ). In shutdown mode, total quiescent current is less than 10µA. The EN pin can be directly connected
to VIN for always-on operation.
8
SETTING OUTPUT VOLTAGE
Where delay is the sum of the LM3475 propagation delay
time and the PFET delay time. The propagation delay is
90ns typically.
The output voltage is programmed using a resistor divider
between VOUT and GND as shown in Figure 2. The feedback
resistors can be calculated as follows:
Minimum output ripple voltage can be determined using the
following equation:
VOUT_PP = VHYST ( R1 + R2 ) / R2
USING A FEED-FORWARD CAPACITOR
The operating frequency and output ripple voltage can also
be significantly influenced using a speed up capacitor, Cff, as
shown in Figure 2. Cff is connected in parallel with the high
side feedback resistor, R1. The output ripple causes a current to be sourced or sunk through this capacitor. This current is essentially a square wave. Since the input to the
feedback pin (FB) is a high impedance node, the bulk of the
current flows through R2. This superimposes a square wave
ripple voltage on the FB node. The end result is a reduction
in output ripple and an increase in operating frequency.
When adding Cff, calculate the formula above with α= 1. The
value of Cff depends on the desired operating frequency and
the value of R2. A good starting point is 1nF ceramic at
100kHz decreasing linearly with increased operating frequency. Also note that as the output voltage is programmed
below 1.6V, the effect of Cff will decrease significantly.
Where Vfb is 0.8V typically.
The feedback resistor ratio, α = (R1+R2) / R2, will also be
used below to calculate output ripple and operating frequency.
INDUCTOR SELECTION
The most important parameters for the inductor are the
inductance and the current rating. The LM3475 operates
over a wide frequency range and can use a wide range of
inductance values. Minimum inductance can be calculated
using the following equation:
Where D is the duty cycle, defined as VOUT/VIN, and ∆I is the
allowable inductor ripple current.
Maximum allowable inductor ripple current should be calculated as a function of output current (IOUT) as shown below:
∆Imax = IOUT x 0.3
The inductor must also be rated to handle the peak current
(IPK) and RMS current given by:
IPK = (IOUT + ∆I/2) x 1.1
20070115
FIGURE 2. Hysteretic Window
SETTING OPERATING FREQUENCY AND OUTPUT
RIPPLE
Although hysteretic control is a simple control scheme, the
operating frequency and other performance characteristics
depend on external conditions and components. If the inductance, output capacitance, ESR, VIN, or Cff is changed, there
will be a change in the operating frequency and possibly
output ripple. Therefore, care must be taken to select components which will provide the desired operating range. The
best approach is to determine what operating frequency is
desirable in the application and then begin with the selection
of the inductor and output capacitor ESR. The design process usually involves a few iterations to select appropriate
standard values that will result in the desired frequency and
ripple.
Without the feedforward capacitor (Cff), the operating frequency (F) can be approximately calculated using the formula:
The inductance value and the resulting ripple is one of the
key parameters controlling operating frequency.
OUTPUT CAPACITOR SELECTION
Once the desired operating frequency and inductance value
are selected, ESR must be selected based on the equation
in the Setting Operating Frequency and Output Ripple. This
process may involve a few iterations to select standard ESR
and inductance values.
In general, the ESR of the output capacitor and the inductor
ripple current create the output ripple of the regulator. However, the comparator hysteresis sets the first order value of
this ripple. Therefore, as ESR and ripple current vary, operating frequency must also vary to keep the output ripple
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LM3475
Design Information
LM3475
Design Information
Capacitors with high ESL (equivalent series inductance) values should not be used. As shown in Figure 1, the output
ripple voltage contains a small step at both the high and low
peaks. This step is caused by and is directly proportional to
the output capacitor’s ESL. A large ESL, such as in an
electrolytic capacitor, can create a step large enough to
cause abnormal switching behavior.
(Continued)
voltage regulated. The hysteretic control topology is well
suited to using ceramic output capacitors. However, ceramic
capacitors have a very low ESR, resulting in a 90˚ phase
shift of the output voltage ripple. This results in low operating
frequency and increased output ripple. To fix this problem a
low value resistor could be added in series with the ceramic
output capacitor. Although counter intuitive, this combination
of a ceramic capacitor and external series resistance provide
highly accurate control over the output voltage ripple. Another method is to add an external ramp at the FB pin as
shown in Figure 3. By proper selection of R1 and C2, the FB
pin sees faster voltage change than the output ripple can
cause. As a result, the switching frequency is higher while
the output ripple becomes lower. The switching frequency is
approximately:
INPUT CAPACITOR SELECTION
A bypass capacitor is required between VIN and ground. It
must be placed near the source of the external PFET. The
input capacitor prevents large voltage transients at the input
and provides the instantaneous current when the PFET turns
on. The important parameters for the input capacitor are the
voltage rating and the RMS current rating. Follow the manufacturer’s recommended voltage de-rating. RMS current and
power dissipation (PD) can be calculated with the equations
below:
Other types of capacitor, such as Sanyo POSCAP, OS-CON,
and Nichicon ’NA’ series are also recommended and may be
used without additional series resistance. For all practical
purposes, any type of output capacitor may be used with
proper circuit verification.
20070120
FIGURE 3. External Ramp
DIODE SELECTION
The catch diode provides the current path to the load during
the PFET off time. Therefore, the current rating of the diode
must be higher than the average current through the diode,
which be calculated as shown:
ID_AVE = IOUT x (1 − D)
The peak voltage across the catch diode is approximately
equal to the input voltage. Therefore, the diode’s peak reverse voltage rating should be greater than 1.3 times the
input voltage.
A Schottky diode is recommended, since a low forward
voltage drop will improve efficiency.
For high temperature applications, diode leakage current
may become significant and require a higher reverse voltage
rating to achieve acceptable performance.
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P-CHANNEL MOSFET SELECTION
The PFET switch should be selected based on the maximum
Drain-Source voltage (VDS), Drain current rating (ID), maximum Gate-Source voltage (VGS), on resistance (RDSON),
and Gate capacitance. The voltage across the PFET when it
is turned off is equal to the sum of the input voltage and the
diode forward voltage. The VDS must be selected to provide
some margin beyond the sum of the input voltage and Vd.
Since the current flowing through the PFET is equal to the
current through the inductor, ID must be rated higher than the
maximum IPK. During switching, PGATE swings the PFET’s
gate from VIN to ground. Therefore, A PFET must be selected with a maximum VGS larger than VIN. To insure that
the PFET turns on completely and quickly, refer to the
PGATE section.
10
resistor in series with PGATE. However, this resistor will
increase the switching losses in the PFET and will lower
efficiency. Therefore it should be kept as small as possible
and only used when necessary. Another method to reduce
switching noise (other than good PCB layout, see Layout
section) is to use a small RC filter or snubber. The snubber
should be placed in parallel with the catch diode, connected
close to the drain of the PFET, as shown in Figure 4. Again,
the snubber should be kept as small as possible to limit its
impact on system efficiency. A typical range is a 10Ω-100Ω
resistor and a 470pF to 2.2nF ceramic capacitor.
(Continued)
The power loss in the PFET consists of switching losses and
conducting losses. Although switching losses are difficult to
precisely calculate, the equation below can be used to estimate total power dissipation. Increasing RDSON will increase
power losses and degrade efficiency. Note that switching
losses will also increase with lower gate threshold voltages.
PDswitch = RDSONx (IOUT)2x D + F x IOUTx VINx (ton + toff)/2
where:
ton = FET turn on time
toff = FET turn off time
A value of 10ns to 50ns is typical for ton and toff. Note that
the RDSON has a positive temperature coefficient. At 100˚C,
the RDSON may be as much as 150% higher than the value
at 25˚C.
The Gate capacitance of the PFET has a direct impact on
both PFET transition time and the power dissipation in the
LM3475. Most of the power dissipated in the LM3475 is used
to drive the PFET switch. This power can be calculated as
follows:
The amount of average gate driver current required during
switching (IG) is:
IG = Qg x F
And the total power dissipated in the device is:
IqVIN + IGVIN
Where Iq is typically 260µA as shown in the Electrical Characteristics table. As gate capacitance increases, operating
frequency may need to be reduced, or additional heat sinking may be required to lower the power dissipation in the
device.
In general, keeping the gate capacitance below 2000pF is
recommended to keep transition times (switching losses),
and power losses low.
20070105
FIGURE 4. PGATE Resistor and Snubber
Layout
PC board layout is very important in all switching regulator
designs. Poor layout can cause EMI problems, excess
switching noise and poor operation.
As shown in Figure 6 and Figure 7, place the ground of the
input capacitor as close as possible to the anode of the
diode. This path also carries a large AC current. The switch
node, the node connecting the diode cathode, inductor, and
PFET drain, should be kept as small as possible. This node
is one of the main sources for radiated EMI.
The feedback pin is a high impedance node and is therefore
sensitive to noise. Be sure to keep all feedback traces away
from the inductor and the switch node, which are sources of
noise. Also, the resistor divider should be placed close to the
FB pin. The gate pin of the external PFET should be located
close to the PGATE pin.
Using a large, continuous ground plane is also recommended, particularly in higher current applications.
REDUCING SWITCHING NOISE
Although the LM3475 employs internal noise suppression
circuitry, external noise may continue to be excessive. There
are several methods available to reduce noise and EMI.
MOSFETs are very fast switching devices. The fast increase
in PFET current coupled with parasitic trace inductance can
create unwanted noise spikes at both the switch node and at
VIN. Switching noise will increase with load current and input
voltage. This noise can also propagate through the ground
plane, sometimes causing unpredictable device performance. Slowing the rise and fall times of the PFET can be
very effective in reducing this noise. Referring to Figure 4,
the PFET can be slowed down by placing a small (1Ω-10Ω)
11
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LM3475
Design Information
LM3475
Layout
(Continued)
20070101
FIGURE 5.
Bill of Materials
Designator
Description
Part Number
Vendor
TAIYO YUDEN
CIN
10µF, 16V, X5R
EMK325BJ106MN
COUT
100µF, 6V, Ta
TPSY107M006R0100
AVX
CFF
1nF, 25V, X7R
VJ1206Y102KXXA
Vishay
D1
Schottky, 20V, 2A
CMSH2-20L
Central Semiconductor
Sumida
L1
10µH, 3.1A
CDRH103R100
Q1
30V, 2.5A
Si2343
Vishay
RFB2
1kΩ, 0805, 1%
CRW08051001F
Vishay
RFB1
2.15kΩ, 0805, 1%
CRCW08052151F
Vishay
20070106
FIGURE 6. Top Layer (Standard Board)
(2:1 Scale)
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12
LM3475
Layout
(Continued)
20070107
FIGURE 7. Top Layer (with External Ramp)
(2:1 Scale)
20070130
FIGURE 8. Bottom Layer
(2:1 Scale)
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LM3475 Hysteretic PFET Buck Controller
Physical Dimensions
inches (millimeters) unless otherwise noted
5 Lead Plastic SOT23-5
NS package Number MF05A
National does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and National reserves
the right at any time without notice to change said circuitry and specifications.
For the most current product information visit us at www.national.com.
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