ST1S10PHR STMicroelectronics, ST1S10PHR Datasheet - Page 10

IC REG 3A 900KHZ STEPDWN PWRSO-8

ST1S10PHR

Manufacturer Part Number
ST1S10PHR
Description
IC REG 3A 900KHZ STEPDWN PWRSO-8
Manufacturer
STMicroelectronics
Type
Step-Down (Buck)r
Datasheet

Specifications of ST1S10PHR

Internal Switch(s)
Yes
Synchronous Rectifier
Yes
Number Of Outputs
1
Voltage - Output
0.8 ~ 15.3 V
Current - Output
3A
Frequency - Switching
900kHz
Voltage - Input
2.5 ~ 18 V
Operating Temperature
-25°C ~ 125°C
Mounting Type
Surface Mount
Package / Case
8-SOIC (3.9mm Width) Exposed Pad, 8-eSOIC. 8-HSOIC
Output Voltage
0.8 V to 15.3 V
Output Current
3 A
Input Voltage
2.5 V to 18 V
Switching Frequency
0.9 MHz
Operating Temperature Range
- 25 C to + 125 C
Mounting Style
SMD/SMT
Duty Cycle (max)
90 %
For Use With
497-8407 - BOARD EVAL STP04CM05/ST1S10497-8216 - BOARD EVAL BASED ON ST1S10497-8229 - BOARD EVAL BASED ON ST1S10
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
Power - Output
-
Lead Free Status / Rohs Status
Lead free / RoHS Compliant
Other names
497-6904-2
ST1S10PHR

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Application information
5.4
5.5
10/26
reduce ripple voltages due to the parasitic inductive effect, the output capacitor connection
paths should be kept as short as possible.
The ST1S10 has been designed to perform best with ceramic capacitors. Under typical
application conditions a minimum ceramic capacitor value of 22 µF is recommended on the
output, but higher values are suitable considering that the control loop has been designed to
work properly with a natural output LC frequency provided by a 3.3 µH inductor and 22 µF
output capacitor. If the high capacitive load application circuit shown in
47 µF (or 2 x 22 µF capacitors in parallel) could be needed as described in the OCP and
SCP operation
The use of ceramic capacitors with voltage ratings in the range of 1.5 times the maximum
output voltage is recommended.
Output capacitor (0.8 V < V
For applications with lower output voltage levels (V
inductor values should be selected in a way that improves the DC-DC control loop behavior.
In this output condition two cases must be considered: V
For V
shown in
For V
the 2 x 22 µF output capacitors as shown in
Output voltage selection
The output voltage can be adjusted from 0.8 V up to 85% of the input voltage level by
connecting a resistor divider (see R1 and R2 in the typical application circuit) between the
output and the V
compromise in terms of current consumption. Once the R2 value is selected, R1 can be
calculated using the following equation:
Equation 6
R1 = R2 x (V
where V
Lower values are suitable as well, but will increase current consumption. Be aware that duty
cycle must be kept below 85% at all application conditions, so that:
Equation 7
D = (V
where V
drop across the internal PDMOS.
Note that once the output current is fixed, higher V
of the device leading to an increase in the operating junction temperature. It is
recommended to select a V
thermal shut-down protection threshold (150°C typ.) at the rated output current. The
following equation can be used to calculate the junction temperature (T
IN
IN
OUT
> 8 V, a 100 µF electrolytic capacitor with ESR < 0.1
< 8 V the use of 2 x 22 µF capacitors in parallel to the output is recommended, as
FB
F
Figure
is the voltage drop across the internal NMOS, and V
+ V
= 0.8 V (typ.).
OUT
F
Section
) / (V
4.
FB
- V
pin. A resistor divider with R2 in the range of 20 k
FB
IN
-V
) / V
5.8.5. of this document.
SW
FB
) < 0.85
OUT
Doc ID 13844 Rev 4
level which maintains the junction temperature below the
OUT
Figure
< 2.5 V)
OUT
OUT
5.
levels increase the power dissipation
< 2.5 V) the output capacitance and
IN
> 8 V and V
Ω
should be added in parallel to
SW
represents the voltage
Ω
IN
Figure 3
J
is a suitable
):
< 8 V.
is used, a
ST1S10

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