NSC LM22672MRE-ADJ 1a simple switcherâ®, step-down voltage regulator with feature Datasheet

LM22672
1A SIMPLE SWITCHER®, Step-Down Voltage Regulator
with Features
General Description
Features
The LM22672 series of regulators are monolithic integrated
circuits which provide all of the active functions for a stepdown (buck) switching regulator capable of driving up to 1A
loads with excellent line and load regulation characteristics.
High efficiency (>90%) is obtained through the use of a low
ON-resistance N-channel MOSFET. The series consists of a
fixed 5V output and an adjustable version.
The SIMPLE SWITCHER® concept provides for an easy to
use complete design using a minimum number of external
components and National’s WEBENCH® design tool.
National’s WEBENCH® tool includes features such as external component calculation, electrical simulation, thermal simulation, and Build-It boards for easy design-in. The switching
clock frequency is provided by an internal fixed frequency oscillator which operates at 500 kHz. The switching frequency
can also be adjusted with an external resistor or synchronized
to an external clock up to 1MHz. It is also possible to selfsynchronize multiple regulators to share the same switching
frequency. The LM22672 series also has built in thermal shutdown, current limiting and an enable control input that can
power down the regulator to a low 25 µA quiescent current
standby condition. An adjustable soft-start feature is provided
by selecting an appropriate external soft-start capacitor.
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Wide input voltage range: 4.5V to 42V
Internally compensated voltage mode control
Stable with low ESR ceramic capacitors
200 mΩ N-channel MOSFET
Output voltage options:
-ADJ (outputs as low as 1.285V)
-5.0 (output fixed to 5V)
±1.5% feedback reference accuracy
Switching frequency of 500 kHz, adjustable between 200
kHz and 1 MHz
-40°C to 125°C operating junction temperature range
Precision enable pin
Integrated boot diode
Adjustable soft-start
Fully WEBENCH® enabled
Step-down and inverting buck-boost applications
Package
■ PSOP-8 (Exposed Pad)
Applications
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Industrial Control
Telecom and Datacom Systems
Embedded Systems
Automotive Telematics and Body Electronics
Conversions from Standard 24V, 12V and 5V Input Rails
Simplified Application Schematic
30076701
© 2009 National Semiconductor Corporation
300767
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LM22672 1A SIMPLE SWITCHER®, Step-Down Voltage Regulator with Features
December 18, 2009
LM22672
Connection Diagram
30076740
8-Lead Plastic PSOP-8 Package
NS Package Number MRA08B
Ordering Information
Output Voltage
Order Number
ADJ
LM22672MR-ADJ
Package Type
NSC Package Drawing
Supplied As
ADJ
LM22672MRE-ADJ
250 Units in Tape and Reel
ADJ
LM22672MRX-ADJ
2500 Units in Tape and Reel
5.0
LM22672MR-5.0
5.0
LM22672MRE-5.0
250 Units in Tape and Reel
5.0
LM22672MRX-5.0
2500 Units in Tape and Reel
95 Units in Rails
PSOP-8 Exposed Pad
MRA08B
95 Units in Rails
Pin Descriptions
Pin
Name
Description
Application Information
1
BOOT
Bootstrap input
Provides the gate voltage for the high side NFET.
2
SS
Soft-start pin
An external capacitor and an internal 50 µA current source set the time
constant for the rise of the error amplifier reference. Pin can be left floating
and internal soft-start will be default.
3
4
RT/SYNC Oscillator frequency adjust pin or
frequency synchronization
A resistor connected from this pin to GND adjusts the oscillator frequency.
This pin can also accept an input for synchronization from an external
clock. Pin can be left floating and internal setting will be default to 500 kHz.
FB
Feedback pin
Inverting input to the internal voltage error amplifier.
5
EN
Precision enable pin
When pulled low regulator turns off.
6
GND
System ground
Provide good capacitive decoupling between VIN and this pin.
7
VIN
Source input voltage
Input to the regulator. Operates from 4.5V to 42V.
8
SW
Switch pin
Attaches to the switch node.
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2
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
VIN to GND
EN Pin Voltage
SS, RT/SYNC Pin Voltage
SW to GND (Note 2)
BOOT Pin Voltage
FB Pin Voltage
Power Dissipation
43V
-0.5V to 6V
-0.5V to 7V
-5V to VIN
VSW + 7V
-0.5V to 7V
Internally Limited
150°C
260°C
±2 kV
-65°C to +150°C
Operating Ratings
(Note 1)
Supply Voltage (VIN)
Junction Temperature Range
4.5V to 42V
-40°C to +125°C
Electrical Characteristics
Limits in standard type are for TJ = 25°C only; limits in boldface type apply over the
junction temperature (TJ) range of -40°C to +125°C. Minimum and Maximum limits are guaranteed through test, design, or statistical
correlation. Typical values represent the most likely parametric norm at TA = TJ = 25°C, and are provided for reference purposes
only. Unless otherwise specified: VIN = 12V.
Symbol
Parameter
Conditions
Min
(Note 5)
Typ
(Note 4)
Max
(Note 5)
Units
Feedback Voltage
VIN = 8V to 42V
4.925/4.9
5.0
5.075/5.1
V
Feedback Voltage
VIN = 4.7V to 42V
1.266/1.259
1.285
1.304/1.311
V
3.4
6
mA
LM22672-5.0
VFB
LM22672-ADJ
VFB
All Output Voltage Versions
IQ
ISTDBY
Quiescent Current
VFB = 5V
Standby Quiescent Current
EN Pin = 0V
ICL
Current Limit
IL
Output Leakage Current
25
40
µA
1.5
1.7/1.8
A
VIN = 42V, EN Pin = 0V, VSW = 0V
0.2
2
µA
VSW = -1V
0.1
3
µA
1.3/1.2
0.2
0.24/0.32
Ω
Oscillator Frequency
400
500
600
kHz
TOFFMIN
Minimum Off-time
100
200
300
ns
TONMIN
Minimum On-time
RDS(ON)
fO
Switch On-Resistance
100
IBIAS
Feedback Bias Current
VFB = 1.3V (ADJ Version Only)
VEN
Enable Threshold Voltage
Falling
VENHYST
Enable Voltage Threshold
Hysteresis
IEN
ns
230
1.3
1.6
nA
1.9
0.6
V
V
Enable Input Current
EN Input = 0V
6
µA
FSYNC
Synchronization Frequency
VSYNC = 3.5V, 50% duty-cycle
1
MHz
VSYNC
Synchronization Threshold
Voltage
1.75
V
ISS
Soft-Start Current
TSD
Thermal Shutdown
Threshold
θJA
Thermal Resistance
30
MR Package, Junction to ambient
temperature resistance (Note 6)
3
50
70
µA
150
°C
60
°C/W
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LM22672
Junction Temperature
Soldering Information
Infrared (5 sec.)
ESD Rating (Note 3)
Human Body Model
Storage Temperature Range
Absolute Maximum Ratings (Note 1)
LM22672
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur, including inoperability and degradation of device reliability
and/or performance. Functional operation of the device and/or non-degradation at the Absolute Maximum Ratings or other conditions beyond those indicated in
the recommended Operating Ratings is not implied. The recommended Operating Ratings indicate conditions at which the device is functional and should not be
operated beyond such conditions.
Note 2: The absolute maximum specification of the ‘SW to GND’ applies to DC voltage. An extended negative voltage limit of -10V applies to a pulse of up to 50
ns.
Note 3: ESD was applied using the human body model, a 100 pF capacitor discharged through a 1.5 kΩ resistor into each pin.
Note 4: Typical values represent most likely parametric norms at the conditions specified and are not guaranteed.
Note 5: Min and Max limits are 100% production tested at 25°C. Limits over the operating temperature range are guaranteed through correlation using Statistical
Quality Control (SQC) methods. Limits are used to calculate National’s Average Outgoing Quality Level (AOQL).
Note 6: The value of θJA for the PSOP-8 exposed pad (MR) package of 60°C/W is valid if package is mounted to 1 square inch of copper. The θJA value can
range from 42 to 115°C/W depending on the amount of PCB copper dedicated to heat transfer.
Typical Performance Characteristics
Unless otherwise specified the following conditions apply: Vin =
12V, TJ = 25°C.
Efficiency vs IOUT and VIN
VOUT = 3.3V
Normalized Switching Frequency vs Temperature
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30076727
Current Limit vs Temperature
Normalized RDS(ON) vs Temperature
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30076703
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Normalized Enable Threshold Voltage vs Temperature
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30076710
Standby Quiescent Current vs Input Voltage
Normalized Feedback Voltage vs Temperature
30076707
30076706
Normalized Feedback Voltage vs Input Voltage
Switching Frequency vs RT/SYNC Resistor
30076713
30076709
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LM22672
Feedback Bias Current vs Temperature
LM22672
Soft-start Current vs Temperature
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LM22672
Typical Application Circuit and Block Diagram
30076714
FIGURE 1. 3.3V VOUT, 1A at 600 kHz
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LM22672
Detailed Operating Description
The LM22672 switching regulator features all of the functions
necessary to implement an efficient high voltage buck regulator using a minimum of external components. This easy to
use regulator integrates a 42V N-Channel switch with an output current capability of 1A. The regulator control method is
based on voltage mode control with input voltage feed forward. The loop compensation is integrated into the LM22672
so that no external compensation components need to be selected or utilized. Voltage mode control offers short minimum
on-times allowing short duty-cycles necessary in high input
voltage applications. The operating frequency is fixed at 500
kHz to allow for small external components while avoiding
excessive switching losses. The switching frequency can be
adjusted with an external resistor from 200 kHz to 1 MHz or
it can be synchronized to an external clock up to 1 MHz. The
output voltage can be set as low as 1.285V with the -ADJ
device. Fault protection features include current limiting, thermal shutdown and remote shutdown capability. The device is
available in the PSOP-8 package featuring an exposed pad
to aid thermal dissipation.
The functional block diagram with typical application of the
LM22672 are shown in Figure 1.
The internal compensation of the -ADJ option of the LM22672
is optimized for output voltages up to 5V. If an output voltage
of 5V or higher is needed, the -5.0 fixed output voltage option
with an additional external resistive feedback voltage divider
may also be used.
Where VD is the forward voltage drop across the re-circulating
Schottky diode and VQ is the voltage drop across the internal
power N-FET of the LM22672. The RDS(ON) of the FET is
specified in the electrical characteristics section of this
datasheet to calculate VQ according to the FET current. F is
the switching frequency.
Minimum Duty-Cycle
Besides a minimum off-time, there is also a minimum on-time
which will take effect when the output voltage is adjusted very
low and the input voltage is very high. Should the operation
require an on-time shorter than minimum, individual switching
pulses will be skipped.
Pulse skipping is a normal mode of operation which appears
as a decrease in switching frequency. It has no effect on operation or regulation except for an increase in output ripple
voltage. The pulse skipping function is required to maintain
proper regulation and overcurrent protection under the full
range of operating conditions.
The specified typical minimum on time of 100 ns is based on
the blanking time during current limit operation. During normal
operation, the minimum on-time will also include the effect of
propagation delay. Assume approximately 150 ns as a typical
operating minimum on time.
Precision Enable
The precision enable pin (EN) can be used to shut down the
power supply. Connecting this pin to ground or to a voltage
less than typical 1.6V will completely turn off the regulator.
The current drain from the input supply when off is typically
25 µA with 12V input voltage. The power consumed during
this off state is mostly defined by an internal 2 MΩ resistor to
VIN. The enable pin has an internal pull-up current source of
approximately 6 µA. When driving the enable pin, the high
voltage level for the on condition should not exceed the 6V
absolute maximum limit. When enable control is not required,
the EN pin should be left floating. The precision feature enables simple sequencing of multiple power supplies with a
resistor divider from another power supply.
The EN pin can also be used as an external UVLO to disable
the part when input voltage falls below a lower boundary of
operation. This is often used to prevent battery discharge or
early turn-on. Using EN as en external UVLO is also recommended to prevent abnormal device operation in applications
where the input voltage falls below the minimum operating
voltage of 4.5V, during power down for example.
where D is the duty-cycle.
Current Limit
When the power switch turns on, the slight capacitance loading of the Schottky diode, D1, causes a leading-edge current
spike with an extended ringing period. This spike can cause
the current limit comparator to trip prematurely. A leading
edge blanking time (TBLK) of 100 ns (typical) is used to avoid
sampling the spike.
When the switch current reaches the current limit threshold
the switch is immediately turned off. If TON is larger than the
minimum (100 ns typical) the switcher will hold the output
current flat at the set current limit value. But if TON is at or
decreases to the minimum TON (100 ns typical) the switching
frequency decreases to 1/5 the typical frequency. This effectively causes the output current to fold back to a lower and
safe value. When the current limit condition is removed the
switching frequency is restored to nominal. This 5X frequency
fold back will result in a lower duty cycle pulse of the power
switch to minimize the overall fault condition power dissipation.
Maximum Duty-Cycle / Dropout
Voltage
The typical maximum duty-cycle is 90% at 500 kHz switching
frequency. This corresponds to a typical minimum off-time of
200 ns. When operating at switching frequencies higher than
500 kHz, the 200 ns minimum off-time results in a lower maximum duty-cycle limit than 90%. This forced off-time is important to provide enough time for the Cboot capacitor to charge
during each cycle.
The lowest input voltage required to maintain operation is:
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Switching Frequency Setting and
Synchronization
There are three different modes for the RT/SYNC pin. It can
be left floating for a 500 kHz switching frequency.
A resistor from the RT/SYNC pin to ground can be used to
adjust the switching frequency between 200 kHz and 1 MHz.
An external synchronization pulse can be applied to the RT/
SYNC pin for switching frequencies up to 1 MHz. The
LM22672 internally sets the RT/SYNC mode during start up.
Many applications are limited to lower switching frequencies
due to minimum on-time and minimum off-time requirements
as well as increased switching losses at switching frequencies higher than 500 kHz. In case of synchronizing to an
external sync pulse, the clock pulse must be in a valid low or
high state when the LM22672 starts up and can be applied
after device regulation. The internal oscillator will synchronize
to the external sync pulse rising edge. If the external sync
pulse is disconnected the LM22672 switching frequency will
return to default 500 kHz (typ.).
When operating at frequencies above 500 kHz, external components such as the inductor and the output capacitors cannot be reduced dramatically. This is due to the fixed internal
compensation and stability requirements. Running the
LM22672 at frequencies higher than 500 kHz is intended for
applications with EMI or beat frequency concerns. The flexibility of increasing the switching frequency above 500 kHz can
be used to operate outside a critical signal frequency band of
an application. This can also be used to set multiple switchers
in an application to the same frequency to reduce beat frequencies and simplify filtering.
See the current limit section of this datasheet for information
about the safe operating area. When synchronizing to an external synchronization pulse, the LM22672 will not fold back
the switching frequency in an over current condition.
The typical curve below shows adjusted switching frequencies with different frequency set resistors from the RT/SYNC
pin to ground.
30076750
FIGURE 2. Output Current in Foldback vs.
Nominal Duty Cycle
The percentage of output current limit fold back is affected by
duty cycle, inductance, and switching frequency.
See Figure 2 for details.
The current limit will only protect the inductor from a runaway
condition if the LM22672 is operating in its safe operating
area. A runaway condition of the inductor is potentially catastrophic to the application. For every design, the safe operating
area needs to be calculated. Factors in determining the safe
operating area are the switching frequency, input voltage,
output voltage, minimum on-time and feedback voltage during an over current condition.
As a first pass check, if the following equation holds true, a
given design is considered in a safe operating area and the
current limit will protect the circuit:
VIN x TBLK x F < VOUT x 0.724
If the equation above does not hold true, the following secondary equation will need to hold true to be in safe operating
area:
If both equations do not hold true, a particular design will not
have an effective current limit function which might damage
the circuit during startup, over current conditions, or steady
state over current and short circuit condition. Oftentimes a
reduction of the maximum input voltage or reduction of the
switching frequency will bring a design into the safe operating
area.
When synchronized to an external sync pulse, the LM22672
will not fold back the switching frequency in an over current
condition.
Soft-Start
The soft-start feature allows the regulator to gradually reach
the initial steady state operating point, thus reducing start-up
stresses and surges. The soft-start can be adjusted by selecting an external soft-start capacitor. An internal 50 µA
current source charges up the external soft-start capacitor.
The generated voltage is the voltage the internal reference
limits. If no external soft-start capacitor is used, there is an
internal soft-start feature with 500 µs (typical) start-up time.
30076713
FIGURE 3. Switching Frequency vs RT/SYNC Resistor
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LM22672
Recommended soft-start capacitor values are between 100
nF to 1 µF.
LM22672
of 5V or higher is needed, the -5.0 option with an additional
external resistor divider may also be used.
The typical location of the internal compensation poles and
zeros as well as the DC gain is given in Table 1. The LM22672
has internal type III compensation allowing for the use of most
output capacitors including ceramics.
This information can be used to calculate the transfer function
from the FB pin to the internal compensation node (input to
the PWM comparator in the block diagram).
Self Synchronize
It is also possible to self-synchronize multiple LM22672 regulators to share the same switching frequency. This can be
done by attaching the RT/SYNC pins together and putting a
1 kΩ resistor to ground. The diagram in Figure 4 illustrates
this setup. The two regulators will be clocked at the same frequency but slightly phase shifted according to the minimum
off-time of the regulator with the fastest running oscillator. The
slight phase shift helps to reduce the stress on the input capacitors of the power supply.
TABLE 1.
Corners
Frequency
Pole 1
150 kHz
Pole 2
250 kHz
Pole 3
100 Hz
Zero 1
1.5 kHz
Zero 2
15 kHz
DC gain
37.5 dB
For the power stage transfer function the standard voltage
mode formulas for the double pole and the ESR zero apply:
30076730
FIGURE 4. Self Synchronizing Setup
Boot Pin
The peak ramp level of the oscillator signal feeding into the
PWM comparator is VIN/10 which equals a gain of 20dB of
this modulator stage of the IC. The -5.0 fixed output voltage
option has twice the gain of the compensation transfer function compared to the -ADJ option which is 43.5dB instead of
37.5dB.
Generally, calculation as well as simulation can only aid in
selecting good power stage components. A good design practice is to test for stability with load transient tests or loop
measurement tests. Application note AN-1889 shows how to
easily perform a loop transfer function measurement with only
an oscilloscope and a function generator.
The LM22672 integrates an N-Channel FET switch and associated floating high voltage level shift / gate driver. This gate
driver circuit works in conjunction with an internal diode and
an external bootstrap capacitor. A 0.01 µF ceramic capacitor
connected with short traces between the BOOT pin and the
SW pin is recommended to effectively drive the internal FET
switch. During the off-time of the switch, the SW voltage is
approximately -0.5V and the external bootstrap capacitor is
charged from the internal supply through the internal bootstrap diode. When operating with a high PWM duty-cycle, the
buck switch will be forced off each cycle to ensure that the
bootstrap capacitor is recharged. See the maximum duty-cycle section for more details.
Application Information
Thermal Protection
EXTERNAL COMPONENTS
The following design procedures can be used to design a nonsynchronous buck converter with the LM22672.
Internal Thermal Shutdown circuitry protects the LM22672 in
the event the maximum junction temperature is exceeded.
When activated, typically at 150°C, the regulator is forced into
a low power reset state. There is a typical hysteresis of 15
degrees.
Inductor
The inductor value is determined based on the load current,
ripple current, and the minimum and maximum input voltage.
To keep the application in continuous current conduction
mode (CCM), the maximum ripple current, IRIPPLE , should be
less than twice the minimum load current.
The general rule of keeping the inductor current peak-to-peak
ripple around 30% of the nominal output current is a good
compromise between excessive output voltage ripple and excessive component size and cost. Using this value of ripple
current, the value of inductor, L, is calculated using the following formula:
Internal Compensation
The LM22672 has internal compensation designed for a stable loop with a wide range of external power stage components.
Insuring stability of a design with a specific power stage (inductor and output capacitor) can be tricky. The LM22672
stability can be verified over varying loads and input and output voltages using WEBENCH® Designer online circuit simulation tool at www.national.com. A quick start spreadsheet
can also be downloaded from the online product folder.
The internal compensation of the -ADJ option of the LM22672
is optimized for output voltages below 5V. If an output voltage
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of at least 100 µF is recommended. An approximation for the
output voltage ripple is:
In applications with Vout less than 3.3V, where input voltage
may fall below the operating minimum of 4.5V, it is critical that
low ESR output capacitors are selected. This will limit potential output voltage overshoots as the input voltage falls below
device normal operation range.
If the switching frequency is set higher than 500 kHz, the capacitance value may not be reduced accordingly due to stability requirements. The internal compensation is optimized
for circuits with a 500 kHz switching frequency. See the internal compensation section for more details.
Cboot Capacitor
The bootstrap capacitor between the BOOT pin and the SW
pin supplies the gate current to turn on the N-channel MOSFET. The recommended value of this capacitor is 10 nF and
should be a good quality, low ESR ceramic capacitor.
It is possible to put a small resistor in series with the Cboot
capacitor to slow down the turn-on transition time of the internal N-channel MOSFET. Resistors in the range of 10Ω to
50Ω can slow down the transition time. This can reduce EMI
of a switched mode power supply circuit. Using such a series
resistor is not recommended for every design since it will increase the switching losses of the application and makes
thermal considerations more challenging.
Input Capacitor
Good quality input capacitors are necessary to limit the ripple
voltage at the VIN pin while supplying most of the switch current during on-time. When the switch turns on, the current into
the VIN pin steps to the peak value, then drops to zero at turnoff. The average current into VIN during switch on-time is the
load current. The input capacitance should be selected for
RMS current, IRMS, and minimum ripple voltage. A good approximation for the required ripple current rating necessary is
IRMS > IOUT / 2.
Quality ceramic capacitors with a low ESR should be selected
for the input filter. To allow for capacitor tolerances and voltage effects, multiple capacitors may be used in parallel. If step
input voltage transients are expected near the maximum rating of the LM22672, a careful evaluation of ringing and possible voltage spikes at the VIN pin should be completed. An
additional damping network or input voltage clamp may be
required in these cases.
Usually putting a higher ESR electrolytic input capacitor in
parallel to the low ESR bypass capacitor will help to reduce
excessive voltages during a line transient and will also move
the resonance frequency of the input filter away from the regulator bandwidth.
Resistor Divider
For the -5.0 option no resistor divider is required for 5V output
voltage. The output voltage should be directly connected to
the FB pin. Output voltages above 5V can use the -5.0 option
with a resistor divider as an alternative to the -ADJ option.
This may offer improved loop bandwidth in some applications.
See the Internal Compensation section for more details.
For the -ADJ option no resistor divider is required for 1.285V
output voltage. The output voltage should be directly connected to the FB pin. Other output voltages can use the -ADJ
option with a resistor divider.
The resistor values can be determined by the following equations:
-ADJ option:
-5.0 option:
Output Capacitor
The output capacitor can limit the output ripple voltage and
provide a source of charge for transient loading conditions.
Multiple capacitors can be placed in parallel. Very low ESR
capacitors such as ceramic capacitors reduce the output ripple voltage and noise spikes, while higher value capacitors in
parallel provide large bulk capacitance for transient loading
and unloading. Therefore, a combination of parallel capacitors, a single low ESR SP or Poscap capacitor, or a high value
of ceramic capacitor provides the best overall performance.
Output capacitor selection depends on application conditions
as well as ripple and transient requirements. Typically a value
Where VFB = 1.285V typical for the -ADJ option and 5V for the
-5.0 option
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LM22672
where F is the switching frequency which is 500 kHz without
an external frequency set resistor or external sync signal applied to the RT/SYNC pin. If the switching frequency is set
higher than 500kHz, the inductance value may not be reduced
accordingly due to stability requirements. The internal compensation is optimized for circuits with a 500 kHz switching
frequency. See the internal compensation section for more
details. This procedure provides a guide to select the value of
the inductor L. The nearest standard value will then be used
in the circuit.
Increasing the inductance will generally slow down the transient response but reduce the output voltage ripple amplitude.
Reducing the inductance will generally improve the transient
response but increase the output voltage ripple.
The inductor must be rated for the peak current, IPK+, to prevent saturation. During normal loading conditions, the peak
current occurs at maximum load current plus maximum ripple.
Under an overload condition as well as during load transients,
the peak current is limited to 1.5A typical (1.8A maximum).
This requires that the inductor be selected such that it can run
at the maximum current limit and not only the steady state
current.
Depending on inductor manufacturer, the saturation rating is
defined as the current necessary for the inductance to reduce
by 30% at 20°C. In typical designs the inductor will run at
higher temperatures. If the inductor is not rated for enough
current, it might saturate and due to the propagation delay of
the current limit circuitry, the power supply may get damaged.
LM22672
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 most important layout rule is to keep the AC current loops
as small as possible. Figure 6 shows the current flow of a buck
converter. The top schematic shows a dotted line which represents the current flow during the FET switch on-state. The
middle schematic shows the current flow during the FET
switch off-state.
The bottom schematic shows the currents referred to as AC
currents. These AC currents are the most critical since current
is changing in very short time periods. The dotted lines of the
bottom schematic are the traces to keep as short as possible.
This will also yield a small loop area reducing the loop inductance. To avoid functional problems due to layout, review the
PCB layout example. Best results are achieved if the placement of the LM22672, the bypass capacitor, the Schottky
diode and the inductor are placed as shown in the example.
It is also recommended to use 2oz copper boards or thicker
to help thermal dissipation and to reduce the parasitic inductances of board traces.
30076723
FIGURE 5. Resistive Feedback Divider
A maximum value of 10 kΩ is recommended for the sum of
R1 and R2 to keep high output voltage accuracy for the –ADJ
option. A maximum of 2 kΩ is recommended for the -5.0 output voltage option. For the 5V fixed output voltage option, the
total internal divider resistance is typically 9.93 kΩ.
At loads less than 5 mA, the boot capacitor will not hold
enough charge to power the internal high side driver. The
output voltage may droop until the boot capacitor is
recharged. Selecting a total feedback resistance to be below
3 kΩ will provide some minimal load and can keep the output
voltage from collapsing in such low load conditions.
Catch Diode
A Schottky type re-circulating diode is required for all
LM22672 applications. Ultra-fast diodes which are not Schottky diodes are not recommended and may result in damage
to the IC due to reverse recovery current transients. The near
ideal reverse recovery characteristics and low forward voltage drop of Schottky diodes are particularly important diode
characteristics for high input voltage and low output voltage
applications common to the LM22672. The reverse recovery
characteristic determines how long the current surge lasts
each cycle when the N-channel MOSFET is turned on. The
reverse recovery characteristics of Schottky diodes minimizes the peak instantaneous power in the switch occurring
during turn-on for each cycle. The resulting switching losses
are significantly reduced when using a Schottky diode. The
reverse breakdown rating should be selected for the maximum VIN, plus some safety margin. A rule of thumb is to select
a diode with the reverse voltage rating of 1.3 times the maximum input voltage.
The forward voltage drop has a significant impact on the conversion efficiency, especially for applications with a low output
voltage. ‘Rated’ current for diodes varies widely from various
manufacturers. The worst case is to assume a short circuit
load condition. In this case the diode will carry the output current almost continuously. For the LM22672 this current can
be as high as 1.5A (typical). Assuming a worst case 1V drop
across the diode, the maximum diode power dissipation can
be as high as 1.5W.
30076724
FIGURE 6. Current Flow in a Buck Application
Thermal Considerations
The two highest power dissipating components are the recirculating diode and the LM22672 regulator IC. The easiest
method to determine the power dissipation within the
LM22672 is to measure the total conversion losses (Pin –
Pout) then subtract the power losses in the Schottky diode
and output inductor. An approximation for the Schottky diode
loss is:
P = (1 - D) x IOUT x VD
An approximation for the output inductor power is:
Circuit Board Layout
P = IOUT2 x R x 1.1,
Board layout is critical for switching power supplies. First, the
ground plane area must be sufficient for thermal dissipation
purposes. 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 L di/dt noise spikes.
The magnitude of this noise tends to increase as the output
current increases. This parasitic spike noise may turn into
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where R is the DC resistance of the inductor and the 1.1 factor
is an approximation for the AC losses. The regulator has an
exposed thermal pad to aid power dissipation. Adding several
vias under the device to the ground plane will greatly reduce
the regulator junction temperature. Selecting a diode with an
exposed pad will aid the power dissipation of the diode. The
most significant variables that affect the power dissipated by
the LM22672 are the output current, input voltage and operating frequency. The power dissipated while operating near
12
nection from the IC exposed pad to the PC board is critical.
Excessive voids will greatly diminish the thermal dissipation
capacity. The junction-to-ambient thermal resistance of the
LM22672 PSOP-8 package is specified in the electrical characteristics table under the applicable conditions.
13
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LM22672
the maximum output current and maximum input voltage can
be appreciable. The junction-to-ambient thermal resistance of
the LM22672 will vary with the application. The most significant variables are the area of copper in the PC board, the
number of vias under the IC exposed pad and the amount of
forced air cooling provided. The integrity of the solder con-
LM22672
PCB Layout Example
30076741
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14
LM22672
Schematic for Buck/Boost
(Inverting) Application
See AN-1888 for more information on the inverting (buckboost) application generating a negative output voltage from
a positive input voltage.
30076726
15
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LM22672
Physical Dimensions inches (millimeters) unless otherwise noted
8-Lead Plastic PSOP-8 Package
NS Package Number MRA08B
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16
LM22672
Notes
17
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LM22672 1A SIMPLE SWITCHER®, Step-Down Voltage Regulator with Features
Notes
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