參數(shù)資料
型號(hào): LM2641-ADJMDC
廠商: NATIONAL SEMICONDUCTOR CORP
元件分類: 穩(wěn)壓器
英文描述: DUAL SWITCHING CONTROLLER, 345 kHz SWITCHING FREQ-MAX, UUC
封裝: DIE
文件頁(yè)數(shù): 8/22頁(yè)
文件大?。?/td> 531K
代理商: LM2641-ADJMDC
Design Procedure (Continued)
case, the manufacturer’s specified inductance value is usu-
ally the maximum value, which means the actual inductance
in your application will be much less.
An inductor with a flatter inductance curve is preferable,
since the loop characteristics of any switching converter are
affected somewhat by inductance value. An inductor which
has a more constant inductance value will give more consis-
tent loop bandwidth when the load current is varied.
The data sheet for the inductor must be reviewed carefully to
verify that the selected component will have the desired
inductance at the frequency and current for the application.
Current Rating
This specification may be the most confusing of all when
picking an inductor, as manufacturers use different methods
for specifying an inductor’s current rating.
The current rating specified for an inductor is typically given
in RMS current, although in some cases a peak current
rating will also be given (usually as a multiple of the RMS
rating) which gives the user some indication of how well the
inductance operates in the saturation region.
Other things being equal, a higher peak current rating is
preferred, as this allows the inductor to tolerate high values
of ripple current without significant loss of inductance.
In the some cases where the inductance vs. current curve is
relatively flat, the given current rating is the point where the
inductance drops 10% below the nominal value. If the induc-
tance varies a lot with current, the current rating listed by the
manufacturer may be the “center point” of the curve. This
means if that value of current is used in your application, the
amount of inductance will be less than the specified value.
DC Resistance
The DC resistance of the wire used in an inductor dissipates
power which reduces overall efficiency. Thicker wire de-
creases resistance, but increases size, weight, and cost. A
good tradeoff is achieved when the inductor’s copper wire
losses are about 2% of the maximum output power.
Selecting An Inductor
Determining the amount of inductance required for an appli-
cation can be done using the formula:
Where:
V
IN is the maximum input voltage.
V
OUT is the output voltage.
F is the switching frequency, F
OSC
I
RIPPLE is the inductor ripple current. In general, a good value
for this is about 30% of the DC output current.
It can be seen from the above equation, that increasing the
switching frequency reduces the amount of required induc-
tance proportionally. Of course, higher frequency operation
is typically less efficient because switching losses become
more predominant as a percentage of total power losses.
It should also be noted that reducing the inductance will
increase inductor ripple current (other terms held constant).
This is a good point to remember when selecting an inductor:
increased ripple current increases the FET conduction
losses, inductor core losses, and requires a larger output
capacitor to maintain a given amount of output ripple volt-
age. This means that a cheaper inductor (with less induc-
tance at the operating current of the application) will cost
money in other places.
INPUT CAPACITORS
The switching action of the high-side FET requires that high
peak currents be available to the switch or large voltage
transients will appear on the V
IN line. To supply these peak
currents, a low ESR capacitor must be connected between
the drain of the high-side FET and ground. The capacitor
must be located as close as possible to the FET (maximum
distance = 0.5 cm).
A solid Tantalum or low ESR aluminum electrolytic can be
used for this capacitor. If a Tantalum is used, it must be able
to withstand the turn-ON surge current when the input power
is applied. To assure this, the capacitor must be surge tested
by the manufacturer and guaranteed to work in such appli-
cations.
Caution: If a typical off-the-shelf Tantalum is used that has
not been surge tested, it can be blown during power-up and
will then be a dead short. This can cause the capacitor to
catch fire if the input source continues to supply current.
Voltage Rating
For an aluminum electrolytic, the voltage rating must be at
least 25% higher than the maximum input voltage for the
application.
Tantalum capacitors require more derating, so it is recom-
mended that the selected capacitor be rated to work at a
voltage that is about twice the maximum input voltage.
Current Rating
Capacitors are specified with an RMS current rating. To
determine the requirement for an application, the following
formula can be used:
It is also recommended that a 0.1F ceramic capacitor be
placed from V
IN to ground for high frequency bypassing,
located as close as possible to the V
IN pin.
OUTPUT CAPACITORS
The output capacitor(s) are critical in loop stability (covered
in a previous section) and also output voltage ripple.
The types best suited for use as output capacitors are alu-
minum electrolytics and solid Tantalum.
Aluminum Electrolytics
The primary advantage of aluminum electrolytics is that they
typically give the maximum capacitance-to-size ratio, and
they are reasonably priced. However, it must be noted that
aluminum electrolytics used in high-performance switching
regulator designs must be high frequency, low ESR types
such as Sanyo OSCON or Panasonic HFQ which are spe-
cifically designed for switching applications. Capacitors such
as these with good high frequency (
≥ 100kHz) specifications
are not cheap.
Aluminum electrolytic capacitors should generally not be
used in switching regulator applications where the ambient
temperature goes below 0C. A typical low-voltage aluminum
electrolytic has an ESR vs. Temperature curve that is fairly
flat from 25C to 125C. However, a temperature change
from 25C to 0C will approximately double the ESR, and it
will double again going from 0C down to 20C.
Tantalum
LM2641
www.national.com
16
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LM2641MTC-ADJ/NOPB 功能描述:DC/DC 開(kāi)關(guān)控制器 RoHS:否 制造商:Texas Instruments 輸入電壓:6 V to 100 V 開(kāi)關(guān)頻率: 輸出電壓:1.215 V to 80 V 輸出電流:3.5 A 輸出端數(shù)量:1 最大工作溫度:+ 125 C 安裝風(fēng)格: 封裝 / 箱體:CPAK
LM2641MTCX-ADJ 功能描述:DC/DC 開(kāi)關(guān)控制器 RoHS:否 制造商:Texas Instruments 輸入電壓:6 V to 100 V 開(kāi)關(guān)頻率: 輸出電壓:1.215 V to 80 V 輸出電流:3.5 A 輸出端數(shù)量:1 最大工作溫度:+ 125 C 安裝風(fēng)格: 封裝 / 箱體:CPAK
LM2641MTCX-ADJ/NOPB 功能描述:DC/DC 開(kāi)關(guān)控制器 RoHS:否 制造商:Texas Instruments 輸入電壓:6 V to 100 V 開(kāi)關(guān)頻率: 輸出電壓:1.215 V to 80 V 輸出電流:3.5 A 輸出端數(shù)量:1 最大工作溫度:+ 125 C 安裝風(fēng)格: 封裝 / 箱體:CPAK
LM2642 制造商:未知廠家 制造商全稱:未知廠家 功能描述:
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