Техническая Спецификация для Texas Instruments LM3481 SEPIC Evaluation Board LM3481SEPICEVAL/NOPB LM3481SEPICEVAL/NOPB
Модели
LM3481SEPICEVAL/NOPB
Board Configuration
4
Board Configuration
4.1
Output Voltage Option
A jumper has been provided on the evaluation board in order to select the output voltage option of 12V or
5V. Shorting the jumper ses the output voltage to 12V. Leaving the jumper open will set the output voltage
to 5V.
5V. Shorting the jumper ses the output voltage to 12V. Leaving the jumper open will set the output voltage
to 5V.
4.2
Under-Voltage Lock-Out (UVLO)
The LM3481 evaluation board has a resistor divider connected to the UVLO pin to set the on and off
thresholds to 4.25V and 4.05V, respectively. There is also a jumper J1 on the board that provides the
‘Enable’ feature. If the jumper is open, the board will not produce an output voltage.
thresholds to 4.25V and 4.05V, respectively. There is also a jumper J1 on the board that provides the
‘Enable’ feature. If the jumper is open, the board will not produce an output voltage.
4.3
Output Voltage Ripple
Output voltage ripple measurement should be taken directly across the output capacitor C12 between
terminals P3 and P4. Care must be taken to minimize the loop area between the scope probe tip and the
ground lead in order to minimize noise in the measurement. This can be achieved by removing the probe’s
spring tip and ground lead and then wrap a bare wire around the scope probe shaft. The bare wire should
be in contact with the probe shaft since this is the ground lead for the probe. The measurement can be
taken by connecting the bare wire onto the ground side of the capacitor and the probe tip onto the positive
side of the capacitor.
terminals P3 and P4. Care must be taken to minimize the loop area between the scope probe tip and the
ground lead in order to minimize noise in the measurement. This can be achieved by removing the probe’s
spring tip and ground lead and then wrap a bare wire around the scope probe shaft. The bare wire should
be in contact with the probe shaft since this is the ground lead for the probe. The measurement can be
taken by connecting the bare wire onto the ground side of the capacitor and the probe tip onto the positive
side of the capacitor.
shows a diagram of this measurement technique.
4.4
External Clock Synchronization
A SYNC terminal has been provided on the evaluation board in order to synchronize the converter to an
external clock or other fixed frequency signal. For complete information on setting up the external clock,
see the LM3481/LM3481Q High Efficiency Low-Side N-Channel Controller for Switching Regulators Data
Sheet (
external clock or other fixed frequency signal. For complete information on setting up the external clock,
see the LM3481/LM3481Q High Efficiency Low-Side N-Channel Controller for Switching Regulators Data
Sheet (
4.5
Active Loads
Many constant-current types of active loads can exhibit an initial short circuit, which is sustained well
beyond the normal soft-start cycle. To avoid loss of regulation of the output voltage during current limit
during startup, wait until the output voltage is up before turning on the load. Using an active load with a
constant-resistance mode will avoid this startup timing issue.
beyond the normal soft-start cycle. To avoid loss of regulation of the output voltage during current limit
during startup, wait until the output voltage is up before turning on the load. Using an active load with a
constant-resistance mode will avoid this startup timing issue.
4.6
SEPIC Operation and Advantages
The Single Ended Primary Inductance Converter (SEPIC) is a DC-DC converter that allows the output
voltage to be either higher than or lower than the input voltage. The SEPIC capacitor is charged to a
voltage potential of approximately V
voltage to be either higher than or lower than the input voltage. The SEPIC capacitor is charged to a
voltage potential of approximately V
IN
. This capacitor acts as an AC short placing the two coils of the
inductor in parallel. The duty cycle relationship and operation is similar to that of the Buck-Boost. During
the on-time of the MOSFET a voltage of V
the on-time of the MOSFET a voltage of V
IN
is applied across the mutual inductor. During the off-time of
MOSFET, the mutual inductor voltage flies to V
OUT
refreshing the charge on the output capacitor. Since the
SEPIC capacitor is charged to V
IN
, the voltage across the MOSFET is V
IN
+ V
OUT
. Additionally, the current
through the MOSFET is I
IN
+ I
OUT
.
The SEPIC has quite a few advantages over the inverting Buck-Boost and the Flyback topology. The
power MOSFET and the diode voltages in the Flyback topology are unclamped and are largely functions
of the transformer leakage inductance and the stray capacitance. This causes large voltage spikes at the
switching intervals. Compared to this for the SEPIC topology the MOSFET and the diode are clamped by
the output and blocking capacitors and thus there is little circuit ringing. The SEPIC also has a common
ground, unlike the Buck-Boost topology, which makes the input and output voltage sensing very easy.
power MOSFET and the diode voltages in the Flyback topology are unclamped and are largely functions
of the transformer leakage inductance and the stray capacitance. This causes large voltage spikes at the
switching intervals. Compared to this for the SEPIC topology the MOSFET and the diode are clamped by
the output and blocking capacitors and thus there is little circuit ringing. The SEPIC also has a common
ground, unlike the Buck-Boost topology, which makes the input and output voltage sensing very easy.
3
SNVA461A – September 2011 – Revised April 2013
AN-2094 LM3481 SEPIC Evaluation Board
Copyright © 2011–2013, Texas Instruments Incorporated