Datasheet
( )
2
L Lrms
P I DCR» ´
OUT
(BR)R(min) OUT
V
V 1.25 V 1.25 24 V 30 V
0.8
³ = ´ = ´ =
( ) ( )
D avg OUT m ax
I I 2 A» =
( ) ( )
D peak L peak
I I 6.57 A= =
D(max) FD D(avg)
P V I 0.5 V 2 A 1W» ´ = ´ =
OUT
OUT
OUT(ripple) SW
I D
1 2 A 0.673 1
C 8 8 36 F
V 500mV 600kHz
´
æ ö
´
= ´ = ´ = m
ç ÷
è ø
f
( )
( )
OUT ripple
OUT
L peak
V
7 7 500mV
ESR 96m
8 I I 8 6.57 A 2 A
= ´ = ´ = W
- -
( )
RIPPLE
IN
SW
IN ripple
I
1.02 A
C 7.1 F
4 V 4 60mV 600kHz
> = = m
´ ´ ´ ´f
( )
IN ripple
RIPPLE
V
60mV
ESR 29m
2 I 2 1.02 A
< = = W
´ ´
TPS40210, TPS40211
SLUS772E –MARCH 2008– REVISED OCTOBER 2011
www.ti.com
A 10-μH inductor with a minimum RMS current rating of 6.13 A and minimum saturation current rating of 6.57 A
must be selected. A TDK RLF12560T-100M-7R5 7.5-A 10-μH inductor is selected.
This inductor power dissipation is estimated by Equation 40.
(40)
The TDK RLF12560T-100M-7R5 12.4-mΩ DCR dissipates 466 mW of power.
Rectifier Diode Selection
A low forward voltage drop schottky diode is used as a rectifier diode to reduce its power dissipation and improve
efficiency. Using 80% derating on V
OUT
for ringing on the switch node, the rectifier diode minimum reverse
break-down voltage is given by Equation 41.
(41)
The diode must have reverse breakdown voltage greater than 30 V. The rectifier diode peak and average
currents are estimated by Equation 42 and Equation 43.
(42)
(43)
The power dissipation in the diode is estimated by Equation 44.
(44)
For this design, the maximum power dissipation is estimated as 1 W. Reviewing 30-V and 40-V schottky diodes,
the MBRS340T3, 40-V, 3-A diode in an SMC package is selected. This diode has a forward voltage drop of
0.48-V at 6-A, so the conduction power dissipation is approximately 960 mW, less than half its rated power
dissipation.
Output Capacitor Selection
Output capacitors must be selected to meet the required output ripple and transient specifications.
(45)
(46)
A Panasonic EEEFC1V330P 35V 33-μF, 120-mΩ bulk capacitor and a 6.8-μF ceramic capacitor are selected to
provide the required capacitance and ESR at the switching frequency. The combined capacitance of 39.8 μF and
ESR of 60 mΩ are used in compensation calculations.
Input Capacitor Selection
Since a boost converter has continuous input current, the input capacitor senses only the inductor ripple current.
The input capacitor value can be calculated by Equation 47 and Equation 48 .
(47)
(48)
For this design to meet a maximum input ripple of 60 mV (1/2% of V
IN
nominal), a minimum 7.1-μF input
capacitor with ESR less than 29 mΩ is needed. A 10-μF X7R ceramic capacitor is selected.
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