LTC4280
17
4280f
APPLICATIONS INFORMATION
pin or bit A3 going from high to low, if the UV pin is brought
below its 0.4V reset threshold for 2約, or if INTV
CC
falls
below its 2.64V undervoltage lockout threshold. Finally,
when EN is brought from high to low, only FAULT bits
D0-D3 are cleared, and bit D4, that indicates a EN change
of state, is set. Note that faults that are still present, as
indicated in STATUS Register C, cannot be cleared.
The FAULT register is not cleared when auto-retrying.
When auto-retry is disabled the existence of a D0, D1
or D2 fault keeps the switch off. As soon as the fault is
cleared, the switch turns on. If auto-retry is enabled, then
a high value in C0, C1 or C2 holds the switch off and the
fault register is ignored. Subsequently, when bits C0, C1
and C2 are cleared by removal of the fault condition, the
switch is allowed to turn on again.
The LTC4280 will set bit D2 and turn off in the event of
an overcurrent fault, preventing it from remaining in an
overcurrent condition. If con gured to auto-retry, the
LTC4280 will continually attempt to restart after cool-down
cycles until it succeeds in starting up without generating
an overcurrent fault.
Data Converter
The LTC4280 incorporates an 8-bit ? A/D converter
that continuously monitors three different voltages. The
? architecture inherently averages signal noise during
the measurement period. The SOURCE pin has a 1/12.5
resistive divider to monitor a full-scale voltage of 15.4V
with 60mV resolution. The ADIN pin is monitored with a
1.235V full-scale and 4.82mV resolution, and the voltage
between the V
DD
and SENSE pins is monitored with a
38.6mV full-scale and 151糣 resolution.
Results from each conversion are stored in registers E
(Sense), F (Source) and G (ADIN), as seen in Tables 6-8,
and are updated 10 times per second. Setting CONTROL
register bit A5 invokes a test mode that halts the data
converter so that registers E, F, and G may be written to
and read from for software testing.
Con guring the GPIO Pin
Table 2 describes the possible states of the GPIO pin using
the control register bits A6 and A7. At power-up, the default
state is for the GPIO pin to go high impedance when power
is good (FB pin greater than 1.235V). Other applications
for the GPIO pin are to pull down when power is good, a
general purpose output and a general purpose input.
Current Limit Stability
For many applications the LTC4280 current limit will be
stable without additional components. However there
are certain conditions where additional components
may be needed to improve stability. The dominant pole
of the current limit circuit is set by the capacitance and
resistance at the gate of the external MOSFET, and larger
gate capacitance makes the current limit loop more stable.
Usually a total of 8nF gate to source capacitance is suf cient
for stability and is typically provided by inherent MOSFET
C
GS
, however the stability of the loop is degraded by
increasing R
SENSE
or by reducing the size of the resistor
on a gate RC network if one is used, which may require
additional gate to source capacitance. Board level short-
circuit testing in highly recommended as board layout can
also affect transient performance, for stability testing the
worst case condition for current limit stability occurs when
the output is shorted to ground after a normal startup.
There are two possible parasitic oscillations when the
MOSFET operates as a source follower when ramping
at power-up or during current limiting. The rst type of
oscillation occurs at high frequencies, typically above
1MHz. This high frequency oscillation is easily damped
with R5 as shown in Figure 1. In some applications, one
may nd that R5 helps in short-circuit transient recovery
as well. However, too large of an R5 value will slow down
the turn-off time. The recommended R5 range is between
5?and 500?
The second type of source follower oscillation occurs at
frequencies between 200kHz and 800kHz due to the load
capacitance being between 0.2糉 and 9糉, the presence