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LTC3521 Datasheet, PDF (15/20 Pages) Linear Technology – Wide VIN, 1A Buck-Boost DC/DC and Dual 600mA Buck DC/DC Converters
LTC3521
applications information
from the following formulas, where f is the frequency in
MHz and L is the inductance in μH:
( ) ΔIL,P-P,BUCK
=
1•
fL
VOUT
VIN – VOUT
VIN
( ) ΔIL,P-P,BOOST
=
1
fL
•
VIN
VOUT – VIN
VOUT
In addition to affecting output current ripple, the size of
the inductor can also affect the stability of the feedback
loop. In boost mode, the converter transfer function has
a right half plane zero at a frequency that is inversely
proportional to the value of the inductor. As a result, a
large inductor can move this zero to a frequency that is
low enough to degrade the phase margin of the feedback
loop. It is recommended that the chosen inductor value be
less than 10μH if the buck-boost converter is to be used
in the boost region.
Buck-Boost Output Capacitor Selection
A low ESR output capacitor should be utilized at the buck-
boost converter output in order to minimize output volt-
age ripple. Multilayer ceramic capacitors are an excellent
choice as they have low ESR and are available in small
footprints. The capacitor should be chosen large enough
to reduce the output voltage ripple to acceptable levels.
Neglecting the capacitor ESR and ESL, the peak-to-peak
output voltage ripple can be calculated by the following
formulas, where f is the frequency in MHz, COUT is the
capacitance in μF, L is the inductance in μH and ILOAD is
the output current in amps:
( ) ΔVP-P,BOOST
=
ILOAD VOUT –
COUT • VOUT
VIN
•f
( ) ΔVP-P,BUCK
=
8
•L
•
1
COUT
•
f2
•
VIN – VOUT
VIN
VOUT
Since the output current is discontinuous in boost mode,
the ripple in this mode will generally be much larger than
the magnitude of the ripple in buck mode. In addition to
controlling the ripple magnitude, the value of the output
capacitor also affects the location of the resonant frequency
in the open loop converter transfer function. If the output
capacitor is too small, the bandwidth of the converter
will extend high enough to degrade the phase margin.
To prevent this from happening, it is recommended that
a minimum value of 10μF be used for the buck-boost
output capacitor.
Buck-Boost Input Capacitor Selection
The supply current to the buck-boost converter is provided
by the PVIN1 pin. It is recommended that a low ESR ceramic
capacitor with a value of at least 4.7μF be located as close
to this pin as possible.
Inductor Style and Core Material
Different inductor core materials and styles have an
impact on the size and price of an inductor at any given
peak current rating. Toroid or shielded pot cores in ferrite
or permalloy materials are small and reduce emissions,
but generally cost more than powdered iron core induc-
tors with similar electrical characteristics. The choice of
inductor style depends upon the price, sizing, and EMI
requirements of a particular application. Table 4 provides a
sampling of inductors that are well suited to many LTC3521
application circuits.
Table 4. Representative Surface Mount Inductors
MANU-
FACTURER
MAX
PART NUMBER VALUE CURRENT DCR HEIGHT
Taiyo Yuden NP03SB4R7M
4.7μH 1.2A 0.047Ω 1.8mm
NP03SB6R8M
6.8μH 1A 0.084Ω 1.8mm
Coilcraft MSS7341-502NL
5μH 2.3A 0.024Ω 4.1mm
DT1608C-472ML 4.7µH 1.2A 0.085Ω 2.92mm
Cooper- SD7030-5R0-R
Bussmann SD20-6R2-R
5µH 2.4A 0.026Ω 3mm
6.2µH 1.12A 0.072Ω 2mm
Sumida CDR6D23MNNP-4R2 4.2µH 2.6A 0.052Ω 2.5mm
CDRH4D16FB/ND- 6.8µH
6R8N
1A 0.081Ω 1.8mm
3521f
15