LTC4215IGN#TR Linear Technology, LTC4215IGN#TR Datasheet - Page 16

LTC4215IGN#TR

Manufacturer Part Number

LTC4215IGN#TR

Description

IC,Power Control/Management,CMOS,SSOP,16PIN,PLASTIC

Manufacturer

Linear Technology

Datasheet

1.LTC4215IGNTR.pdf (28 pages)

Specifications of LTC4215IGN#TR

Linear Misc Type

Positive Low Voltage

Family Name

LTC4215

Package Type

SSOP N

Operating Supply Voltage (min)

2.9V

Operating Supply Voltage (max)

15V

Operating Temperature (min)

-40C

Operating Temperature (max)

85C

Operating Temperature Classification

Industrial

Product Depth (mm)

3.99mm

Product Height (mm)

1.5mm

Mounting

Surface Mount

Pin Count

Lead Free Status / Rohs Status

Not Compliant

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LTC4215/LTC4215-2

APPLICATIONS INFORMATION

and C2 are cleared by removal of the fault condition, the

switch is allowed to turn on again.

The LTC4215 will set bit D2 and turn off in the event of

an overcurrent fault, preventing it from remaining in an

overcurrent condition. If conﬁ gured to auto-retry, the

LTC4215 will continually attempt to restart after cool-down

cycles until it succeeds in starting up without generating

an overcurrent fault.

Data Converter

The LTC4215 incorporates an 8-bit Δ∑ A/D converter

that continuously monitors three different voltages. The

Δ∑ 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

38.6mV full scale and 151μV 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

converter so that registers E, F , and G may be written to

and read from for software testing.

Conﬁ 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 LTC4215 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 cur-

rent limit circuit is set by the capacitance and resistance at

and SENSE pins is monitored with a

the gate of the external MOSFET, and larger gate capaci-

tance makes the current limit loop more stable. Usually

a total of 8nF gate to source capacitance is sufﬁ cient for

stability and is typically provided by inherent MOSFET C

however the stability of the loop is degraded by increasing

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 ﬁ 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 ﬁ 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

5Ω and 500Ω.

The second type of source follower oscillation occurs at

frequencies between 200kHz and 800kHz due to the load

capacitance being between 0.2μF and 9μF , the presence

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 LTC4215 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

SENSE

or by reducing the size of the resistor on a gate RC

4215fe

LTC4215IGN#TR Linear Technology, LTC4215IGN#TR Datasheet - Page 16

LTC4215IGN#TR

Specifications of LTC4215IGN#TR

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