LTC4280IUFD#TR Linear Technology, LTC4280IUFD#TR Datasheet - Page 18

LTC4280IUFD#TR

Manufacturer Part Number

LTC4280IUFD#TR

Description

Manufacturer

Linear Technology

Datasheet

1.LTC4280IUFDTR.pdf (28 pages)

Specifications of LTC4280IUFD#TR

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LTC4280

APPLICATIONS INFORMATION

of R5 resistance, the absence of a drain bypass capacitor,

a combination of bus wiring inductance and bus supply

output impedance. To prevent this second type of oscillation

avoid load capacitance below 10μF, alternately connect an

external capacitor from the MOSFET gate to ground with

a value greater than 1.5μF.

Supply Transients

The LTC4280 is designed to ride through supply transients

caused by load steps. If there is a shorted load and the

parasitic inductance back to the supply is greater than

0.5μH, there is a chance that the supply collapses before

the active current limit circuit brings down the GATE pin.

If this occurs, the undervoltage monitors pull the GATE

pin low. The undervoltage lockout circuit has a 2μs ﬁ lter

time after V

2μs to shut the GATE off, but it is recommended to add a

ﬁ lter capacitor C

by a transient. Eventually either the UV pin or undervoltage

lockout responds to bring the current under control before

the supply completely collapses.

Supply Transient Protection

The LTC4280 is safe from damage with supply voltages up

to 24V. However, spikes above 24V may damage the part.

During a short-circuit condition, large changes in current

ﬂ owing through power supply traces may cause inductive

voltage spikes which exceed 24V. To minimize such spikes,

the power trace inductance should be minimized by using

wider traces or heavier trace plating. Also, a snubber circuit

dampens inductive voltage spikes. Build a snubber by using

a 100Ω resistor in series with a 0.1μF capacitor between

input can also prevent damage from voltage surges.

Design Example

As a design example, take the following speciﬁ cations:

= 11.6V, and I

design is shown in Figure 1.

= 330μF, V

= 12V, I

and GND. A surge suppressor, Z1 in Figure 1, at the

MAX

UV(ON)

drops below 2.74V. The UV pin reacts in

C ADDRESS = 1010011. This completed

= 5A, I

to prevent unwanted shutdown caused

= 10.75V, V

INRUSH

OV(OFF)

= 1A, 5ms FILTER time,

= 14.0V, V

PWRGD(UP)

Selection of the sense resistor, R

threshold of 25mV:

The MOSFET is sized to handle the power dissipation during

inrush when output capacitor C

method to determine power dissipation during inrush is

based on the principle that:

This uses:

or 0.024 joules. Calculate the time it takes to charge up

The power dissipated in the MOSFET:

The SOA (safe operating area) curves of candidate MOSFETs

must be evaluated to ensure that the heat capacity of the

package tolerates 6W for 4ms. The SOA curves of the

Fairchild FDC653N provide for 2A at 12V (24W) for 10ms,

satisfying this requirement. Since the FDC653N has less

than 8μF of gate capacitance and we are using a GATE

RC network, the short-circuit stability of the current limit

should be checked and improved by adding a capacitor

from GATE to SOURCE if needed.

The inrush current is set to 1A using C1:

OUT

Energy in CL = Energy in Q1

Energy in C

STARTUP

DISS

1 0 33

MAX

Energyin C

•

INRUSH

STARTUP

GATE

•

0 005

•

INRUSH

μA

or C

(

0 33

1 6

0 33

OUT

, is set by the overcurrent

.8 8 nF

is being charged. A

•

)( )

4280f

LTC4280IUFD#TR Linear Technology, LTC4280IUFD#TR Datasheet - Page 18

LTC4280IUFD#TR

Specifications of LTC4280IUFD#TR

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