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CAT6202VP2-GT3 Datasheet, PDF (4/10 Pages) ON Semiconductor – 500 mA / 13 V Adjustable CMOS LDO Regulator
CAT6202
Pin Function
VIN is the supply pin for both the LDO’s operation and the
load the LDO is driving. It is recommended that a 1 mF
ceramic bypass capacitor be placed between the VIN pin and
ground in close proximity to the device. When using longer
connections to the power supply, CIN value can be increased
without limit. The operating input voltage range is from
3.3 V to 13 V.
FLT is an active low open−drain output indicating one of 3
fault conditions:
1. Input under−voltage: VIN is below the intended
output voltage
2. Over−current. Brief over−current events are
masked by a 3 ms time delay. CAT6202 will limit
current anytime the load tries to draw more than
the maximum allowed however reporting of this
event will occur only if the event lasts longer than
the delay timer. Events terminating before the
timer reaches its full count are ignored and the
timer is reset.
3. Over−temperature shutdown has occurred.
EN is an active HIGH logic level input for switching the
regulator’s output between ON and OFF. A weak internal
pull down assures that if EN pin is left open, the circuit is
disabled.
BYP controls the soft−start feature for the regulator. When
large capacitive loads are present at the regulator’s output,
enabling the regulator will produce large current surges on
the VIN supply line. To reduce these surges the regulator can
be turned on gently by connecting a capacitor between the
BYP pin and ground. The larger the capacitance value the
more slowly VOUT approaches its programmed value. The
table below gives a list of common capacitor values and their
resulting turn−on times. If the soft−start feature is not
desired, this pin should be left floating.
Capacitance [nF]
0
10
100
tON [ms]
0.2
1
10
GND is the ground reference for the LDO. The TDFN
package center metal pad is internally connected to GND. If
electrical contact is made with this pad, it should be to GND
and/or the ground plane of the PCB. Connection to the
ground plane enhances thermal conductivity drawing heat
out of the package and into the surrounding PCB.
ILIM stands for Current Limit and is the control input for
setting the point at which the current limit is invoked. ILIM
is defined as the current at which VOUT is still within 80%
of its nominal value and should not be confused with ISC, the
short circuit current, measured at VOUT = 0 V, which is
typically 100 mA greater than ILIM.
A resistor REXT placed between ILIM and GND selects the
trip current according to a formula:
ILIMIT
+
ILIMIT0
)
Current_Limit_Factor(CLF)
REXT
(eq. 1)
ILIM0 is the built−in minimum current limit (typically
150 mA), and CLF is a numerical value (typical 30,000
Volts) which relates the allowable load current to a
resistance value. The value of this resistor is determined by
the following equation:
REXT(W)
+
CLF(V)
ILIM(A) * ILIM0(A)
(eq. 2)
It is recommended that ILIM be set with at least 50%, and
preferably 60%, higher than the maximum intended
continuous IOUT.
Example: Set ILIMIT = 800 mA
REXT(W)
+
30, 000 V
0.8 A * 0.15
A
+
47
KW
(eq. 3)
VADJ is the output voltage control pin. A resistor divider
placed between VOUT and GND whose center point
connects to VADJ sets the LDO regulator’s output voltage.
Typical VADJ value is 1.25 V. The current through the
resistor divider can be anywhere between 10 mA and 1 mA.
The higher this current is, the lower the noise.
VOUT is the LDO regulator output. A small 2.2 mF ceramic
bypass capacitor is required between VOUT and ground.
For better transient response, its value can be increased to
4.7 mF. This capacitor should be located near the device.
ǒ Ǔ VOUT + VADJ
1
)
R1
R2
(eq. 4)
VOUT is protected against short circuits and over−temp
operation by internal circuitry. In the event of an
over−current, the LDO behaves like a current source,
limiting current at the output. The maximum current
allowed is set by REXT, the resistor between ILIM and GND.
If the load attempts to draw more than the allowed current,
VOUT and IOUT decrease together and thus limit the total
power delivered.
VOUT is protected against the application of voltages
greater than VIN. For example, in automotive applications,
if CAT6202 is powering a remote load and damage occurs
to a wiring harness shorting a powered line, Battery + for
instance, to VOUT, CAT6202 will not be damaged by this
higher voltage being applied to VOUT.
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