NCP1597BMNTXG ONSEMI [ON Semiconductor], NCP1597BMNTXG Datasheet - Page 7
NCP1597BMNTXG
Manufacturer Part Number
NCP1597BMNTXG
Description
1 MHz, 2 A Synchronous Buck Regulator
Manufacturer
ONSEMI [ON Semiconductor]
Datasheet
1.NCP1597BMNTXG.pdf
(9 pages)
Programming the Output Voltage
from the output voltage to FB pin (see Figure 3). So the
output voltage is calculated according to Eq.1.
Inductor Selection
regulator. The selection of inductor involves trade−offs
among size, cost and efficiency. The inductor value is
selected according to the equation 2.
Where V
f − switching frequency, 1.0 MHz;
I
current;
V
maintain a maximum ripple current within 30% of the
maximum load current. If the ripple current exceeds this
30% limit, the next larger value should be selected.
the maximum load current and its saturation current should
be about 30% higher. For robust operation in fault conditions
(start−up or short circuit), the saturation current should be
high enough. To keep the efficiency high, the series
resistance (DCR) should be less than 0.1 W, and the core
material should be intended for high frequency applications.
Output Capacitor Selection
and also provides energy storage. So the major parameter
necessary to define the output capacitor is the maximum
allowed output voltage ripple of the converter. This ripple is
related to capacitance and the ESR. The minimum
capacitance required for a certain output ripple can be
calculated by Equation 4.
ripple
in(max)
The output voltage is set using a resistive voltage divider
The inductor is the key component in the switching
Choose a standard value close to the calculated value to
The inductor’s RMS current rating must be greater than
The output capacitor acts to smooth the dc output voltage
− Ripple current, usually it’s 20% − 30% of output
− maximum input voltage.
out
− the output voltage;
L +
Figure 3. Output divider
V
f @ I
out
V
V
out
ripple
+ V
out
R1
R2
FB
@ 1 *
@
R
1
R
) R
V
FB
2
V
in(max)
out
2
APPLICATION INFORMATION
(eq. 1)
(eq. 2)
http://onsemi.com
7
Where V
calculated by equation 5.
ESR according to Equation 3. If ESR exceeds the value from
Eq.4, multiple capacitors should be used in parallel.
In addition, both surface mount tantalum and through−hole
aluminum electrolytic capacitors can be used as well.
Maximum Output Capacitor
overcurrent limit. It limits the maximum allowed output
capacitor to startup successfully. The maximum allowed
output capacitor can be determined by the equation:
Where T
D
example, with 3.3 V/2.0 A output and 20% ripple, the max
allowed output capacitors is 90 mF.
Input Capacitor Selection
The input capacitor can be calculated by Equation 6.
Where V
Power Dissipation
6−pin, DFN package that dissipates up to 1.0 W at T
+70°C. When the die temperature reaches +165°C, the
NCP1597B shuts down (see the Thermal−Overload
Protection section). The power dissipated in the device is the
sum of the power dissipated from supply current (PQ),
power dissipated due to switching the internal power
MOSFET (P
current through the internal power MOSFET (PON). The
total power dissipated in the package must be limited so the
junction temperature does not exceed its absolute maximum
rating of +150°C at maximum ambient temperature.
iPP
The required ESR for this amount of ripple can be
Based on Equation 2 to choose capacitor and check its
Ceramic capacitor can be used in most of the applications.
NCP1597B family has internal 1 ms fixed soft−start and
This is assuming that a constant load is connected. For
The NCP1597B is available in a thermally enhanced
D
max
is the current ripple.
ripple
in(ripple)
+
SS(min)
C
C
in(min)
V
SW
out(max)
V
in(min)
is the allowed output voltage ripple.
out
), and the power dissipated due to the RMS
is the minimum soft−start period (1ms);
C
is the required input ripple voltage.
+ I
OUT(min)
is the maximum duty cycle.
+
out(max)
ESR +
I
lim(min)
+
@ D
8 @ f @ V
V
V
I
* I
ripple
out
ripple
max
I
load(max)
ripple
T
@
SS(min)
f @ V
ripple
in(ripple)
1
*
Di
p−p
2
(eq. 3)
(eq. 4)
(eq. 5)
(eq. 6)
(eq. 7)
A
=
Related parts for NCP1597BMNTXG
Image
Part Number
Description
Manufacturer
Datasheet
Request
R
Part Number:
Description:
THERMISTOR 100K OHM NTC 0402 SMD
Manufacturer:
Murata Electronics North America
Datasheet:
Part Number:
Description:
THERMISTOR 100K OHM NTC 0402 SMD
Manufacturer:
Murata Electronics North America
Datasheet:
Part Number:
Description:
THERMISTOR 68K OHM NTC 0402 SMD
Manufacturer:
Murata Electronics North America
Datasheet:
Part Number:
Description:
THERMISTOR 10K OHM NTC 0402 SMD
Manufacturer:
Murata Electronics North America
Datasheet:
Part Number:
Description:
THERMISTOR 47K OHM NTC 0402 SMD
Manufacturer:
Murata Electronics North America
Datasheet:
Part Number:
Description:
THERMISTOR 4.7K OHM NTC 0402 SMD
Manufacturer:
Murata Electronics North America
Datasheet:
Part Number:
Description:
THERMISTOR 47K OHM NTC 0402 SMD
Manufacturer:
Murata Electronics North America
Datasheet:
Part Number:
Description:
THERMISTOR 10K OHM NTC 0402 SMD
Manufacturer:
Murata Electronics North America
Datasheet:
Part Number:
Description:
THERMISTOR 470K OHM NTC 0402 SMD
Manufacturer:
Murata Electronics North America
Datasheet:
Part Number:
Description:
THERMISTOR 22K OHM NTC 0402 SMD
Manufacturer:
Murata Electronics North America
Datasheet:
Part Number:
Description:
THERMISTOR 220K OHM NTC 0402 SMD
Manufacturer:
Murata Electronics North America
Datasheet:
Part Number:
Description:
THERMISTOR 150 OHM NTC 0402 SMD
Manufacturer:
Murata Electronics North America
Datasheet:
Part Number:
Description:
THERMISTOR 15K OHM NTC 0402 SMD
Manufacturer:
Murata Electronics North America
Datasheet:
Part Number:
Description:
THERMISTOR 150K OHM NTC 0402 SMD
Manufacturer:
Murata Electronics North America
Datasheet:
Part Number:
Description:
THERMISTOR 1.5K OHM NTC 0402 SMD
Manufacturer:
Murata Electronics North America
Datasheet: