Datasheet
Table Of Contents
- FEATURES
- APPLICATIONS
- DESCRIPTION
- Electrical Specifications
- Performance Benefits
- Absolute Maximum Ratings
- Operating Ratings
- Electrical Characteristics
- Typical Performance Characteristics
- Block Diagram
- Design Steps for the LMZ22005 Application
- ENABLE DIVIDER, RENT, RENB AND RENHSELECTION
- OUTPUT VOLTAGE SELECTION
- SOFT-START CAPACITOR SELECTION
- TRACKING SUPPLY DIVIDER OPTION
- CO SELECTION
- CIN SELECTION
- POWER DISSIPATION AND BOARD THERMAL REQUIREMENTS
- PC BOARD LAYOUT GUIDELINES
- Additional Features
- Typical Application Schematic Diagram
- Power Module SMT Guidelines
- Revision History
4
5
6
7
3
2
1
PGND/EP
VOUT
SS
SYNC
FB
VIN
EN
AGND
V
IN
C
IN
2,3
10 PF
Enable
7V to 20V
U1
R
FBB
1.07k
LMZ22005TZ
3.3V
O
@ 5A
C
O
1,6
0.047 PF
C
O
5
220 PF
R
ENH
OPT
100:
R
ENT
42.2k
R
ENB
12.7k
R
FBT
3.32k
C
IN
1,5
0.047 PF
C
O
2
100 PF
OPT
+
D1 OPT
5.1V
SYNC
R
SN
OPT
1.50 k:
C
SS
0.47 PF
C
IN
6 OPT
150 PF
+
R
FRA
OPT
23.7:
LMZ22005
www.ti.com
SNVS686I –MARCH 2011–REVISED OCTOBER 2013
The inductor internal to the module is 3.3 μH. This value was chosen as a good balance between low and high
input voltage applications. The main parameter affected by the inductor is the amplitude of the inductor ripple
current (I
LR
). I
LR
can be calculated with:
I
LR P-P
=V
O
*(V
IN
- V
O
)/(3.3µH*f
SW
*V
IN
) (14)
Where V
IN
is the maximum input voltage and f
SW
is typically 812 kHz.
If the output current I
O
is determined by assuming that I
O
= I
L
, the higher and lower peak of I
LR
can be
determined.
Typical Application Schematic Diagram
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