744309025 查看數據表(PDF) - International Rectifier
零件编号
产品描述 (功能)
生产厂家
744309025
International Rectifier
744309025 Datasheet PDF : 53 Pages
| |||
IR3846
the sampled current is higher than the OC Limit, an
OC event is detected.
When an Over Current event is detected, the
converter enters hiccup mode. Hiccup mode is
performed by latching the OC signal and pulling the
Intl_SS signal to ground for 20.48 mS (typ.). OC
signal clears after the completion of hiccup mode and
the converter attempts to return to the nominal output
voltage using a soft start sequence. The converter will
repeat hiccup mode and attempt to recover until the
overload or short circuit condition is removed.
Because the IR3846 uses valley current sensing, the
actual DC output current limit will be greater than OC
limit. The DC output current is approximately half of
peak to peak inductor ripple current above selected
OC limit. OC Limit, inductor value, input voltage,
output voltage and switching frequency are used to
calculate the DC output current limit for the converter.
Equation (2) to determine the approximate DC output
current limit.
I OCP
I LIMIT
i
2
(2)
IOCP
ILIMIT
∆i
= DC current limit hiccup point
= Current Limit Valley Point
= Inductor ripple current
Figure 11: Timing Diagram for Current Limit Hiccup
THERMAL SHUTDOWN
Temperature sensing is provided inside IR3846. The
trip threshold is typically 145oC. When trip threshold is
exceeded, thermal shutdown turns off both MOSFETs
and resets the internal soft start.
Automatic restart is initiated when the sensed
temperature drops within the operating range. There
is a 20oC hysteresis in the thermal shutdown
threshold.
REMOTE VOLTAGE SENSING
True differential remote sensing in the feedback loop
is critical to high current applications where the output
voltage across the load may differ from the output
voltage measured locally across an output capacitor
at the output inductor, and to applications that require
die voltage sensing.
The RS+ and RS- pins of the IR3846 form the inputs
to a remote sense differential amplifier (RSA) with
high speed, low input offset and low input bias current
which ensure accurate voltage sensing and fast
transient response in such applications.
The input range for the differential amplifier is limited
to 1.5V below the VCC rail. Note that IR3846
incorporates a smart LDO which switches the VCC rail
voltage depending on the loading. When determining
the input range assume the part is in light load and
using the lower VCC rail voltage.
There are two remote sense configurations that are
usually implemented. Figure 12 shows a general
remote sense (RS) configuration. This configuration
allows the RSA to monitor output voltages above
VCC. A resistor divider is placed in between the
output and the RSA to provide a lower input voltage to
the RSA inputs. Typically, the resistor divider is
calculated to provide VREF (0.6V) across the RSA
inputs which is then outputted to RSo. The input
impedance of the RSA is 63 KOhms typically and
should be accounted for when determining values for
the resistor divider. To account for the input
impedance, assume a 63 KOhm resistor in parallel to
the lower resistor in the divider network. The
compensation is then designed for 0.6V to match the
RSo value.
Low voltage applications can use the second remote
sense configuration. When the output voltage range
is within the RSA input specifications, no resistor
divider is needed in between the converter output and
RSA. The second configuration is shown in Figure
13. The RSA is used as a unity gain buffer and
compensation is determined normally.
21 www.irf.com © 2013 International Rectifier
August 01, 2013
Share Link: