LTC3425_15 Datasheet, PDF(15/24 Page) Linear Technology – 5A, 8MHz, 4-Phase Synchronous Step-Up DC/DC Converter

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LTC3425_15 Datasheet, PDF (15/24 Pages) Linear Technology – 5A, 8MHz, 4-Phase Synchronous Step-Up DC/DC Converter

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OPERATIO

Current Limit: The programmable current limit circuit sets

the maximum peak current in the NMOS switches. The

current limit level is programmed using a resistor to

ground on the ILIM pin. Do not use values below 75k. In

Burst Mode operation, the current limit is automatically

set to a nominal value of 0.6A peak for optimal efficiency.

ILIM

130

per

Phase

where I is in Amps and R is in kâ¦.

Synchronous Rectifier and Zero Current Amp: To pre-

vent the inductor current from running away, the PMOS

synchronous rectifier is only enabled when VOUT > (VIN +

0.3V) and FB is > 0.8V.The zero current amplifier monitors

the inductor current to the output and shuts off the

synchronous rectifier once the current is below 50mA

typical, preventing negative inductor current. If CCM is

tied high, the amplifier will allow up to 0.6A of negative

current in the synchronous rectifier.

Antiringing Control: The antiringing control connects a

resistor across the inductor to damp the ringing on SW in

discontinuous conduction mode. The LCSW ringing (L =

inductor, CSW = Capacitance on Switch pin) is low energy,

but can cause EMI radiation.

Power Good: An internal comparator monitors the FB

voltage. If FB drops 11.4% below the regulation value,

PGOOD will pull low (sink current should be limited to

10mA max). The output will stay low until the FB voltage

is within 9.5% of the regulation voltage. A filter prevents

noise spikes from causing nuisance trips.

Reference Output: The internal 1.22V reference is buff-

ered and brought out to REFOUT. It is active when REFEN

is pulled high (above 1.4V). For stability, a minimum of

0.1ÂµF capacitor must be placed on REFOUT. The output

can source up to 100ÂµA and sink up to 10ÂµA. For the lowest

possible quiescent current in Burst Mode operation, the

reference output should be disabled by grounding REFEN.

Thermal Shutdown: An internal temperature monitor will

start to reduce the programmed peak current limit if the

die temperature exceeds 135Â°C. If the die temperature

continues to rise and reaches 150Â°C, the part will go into

thermal shutdown and all switches will be turned off and

LTC3425

the soft-start capacitor will be reset. The part will be

enabled again when the die temperature has dropped

about 10Â°C. Note: Overtemperature protection is intended

to protect the device during momentary overload condi-

tions. Continuous operation above the specified maxi-

mum operating junction temperature may result in device

degradation or failure.

Burst Mode Operation

Burst Mode operation can be automatic or user controlled.

In automatic operation, the IC will automatically enter

Burst Mode operation at light load and return to fixed

frequency PWM mode for heavier loads. The user can

program the average load current at which the mode

transition occurs using a single resistor.

During Burst Mode operation, only Phase A is active and

the other three phases are turned off, reducing quiescent

current and switching losses by 75%. Note that the

oscillator is also shut down in this mode, since the on time

is determined by the time it takes the inductor current to

reach a fixed peak current, and the off time is determined

by the time it takes for the inductor current to return to

zero.

In Burst Mode operation, the IC delivers energy to the

output until it is regulated and then goes into a sleep mode

where the outputs are off and the IC is consuming only

12ÂµA of quiescent current. In this mode, the output ripple

has a variable frequency component with load current and

will be typically 2% peak-peak. This maximizes efficiency

at very light loads by minimizing switching and quiescent

losses. Burst Mode ripple can be reduced slightly by using

more output capacitance (47ÂµF or greater). This capacitor

does not need to be a low ESR type if low ESR ceramics are

also used. Another method of reducing Burst Mode ripple

is to place a small feedforward capacitor across the upper

resistor in the VOUT feedback divider network.

During Burst Mode operation, COMP is disconnected

from the error amplifier in an effort to hold the voltage on

the external compensation network where it was before

entering Burst Mode operation. To minimize the effects of

leakage current and stray resistance, voltage clamps limit

the min and max voltage on COMP during Burst Mode

operation. This minimizes the transient experienced when

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