LSN2A Datasheet, PDF(8/15 Page) Murata Manufacturing Co., Ltd. – Non-isolated, DOSA-SIP, 6/10/16A Selectable-Output DC/DC Converters

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LSN2A Datasheet, PDF (8/15 Pages) Murata Manufacturing Co., Ltd. – Non-isolated, DOSA-SIP, 6/10/16A Selectable-Output DC/DC Converters

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LSN2 Series

Non-isolated, DOSA-SIP, 6/10/16A

Selectable-Output DC/DC Converters

The highest temperatures in LSN2 SIPs occur at their output inductor,

whose heat is generated primarily by I2R losses. The derating curves were

developed using thermocouples to monitor the inductor temperature and

varying the load to keep that temperature below +110Â°C under the assorted

conditions of air ï¬ow and air temperature. Once the temperature exceeds

+115Â°C (approx.), the thermal protection will disable the converter. Automatic

restart occurs after the temperature has dropped below +110Â°C.

As you may deduce from the derating curves and observe in the efï¬ciency

curves on the following pages, LSN2 SIPs maintain virtually constant efï¬cien-

cy from half to full load, and consequently deliver very impressive temperature

performance even if operating at full load.

Lastly, when LSN2 SIPs are installed in system boards, they are obviously

subject to numerous factors and tolerances not taken into account here. If you

are attempting to extract the most current out of these units under demand-

ing temperature conditions, we advise you to monitor the output-inductor

temperature to ensure it remains below +110Â°C at all times.

Start Up Considerations

When power is ï¬rst applied to the DC/DC converter, operation is different than

when the converter is running and stabilized. There is some risk of start up

difï¬culties if you do not observe several application features. Lower output

voltage converters may have more problems here since they tend to have

higher output currents. Operation is most critical with any combination of the

following external factors:

1 â Low initial input line voltage and/or poor regulation of the input source.

2 â Full output load current on lower output voltage converters.

3 â Slow slew rate of input voltage.

4 â Longer distance to input voltage source and/or higher external input

source impedance.

5 â Limited or insufï¬cient ground plane. External wiring that is too small.

6 â Too small external input capacitance. Too high ESR.

7 â High output capacitance causing a start up charge overcurrent surge.

8 â Output loads with excessive inductive reactance or constant current

characteristics.

If the input voltage is already at the low limit before power is applied, the

start up surge current may instantaneously reduce the voltage at the input

terminals to below the speciï¬ed minimum voltage. Even if this voltage depres-

sion is very brief, this may interfere with the on-board controller and possibly

cause a failed start. Or the converter may start but the input current load will

now drive the input voltage below its running low limit and the converter will

shut down.

If you measure the input voltage before start up with a Digital Voltmeter (DVM),

the voltage may appear to be adequate. Limited external capacitance and/or

too high a source impedance may cause a short downward spike at power up,

causing an instantaneous voltage drop. Use an oscilloscope not a DVM to observe

this spike. The converterâs soft-start controller is sensitive to input voltage. What

matters here is the actual voltage at the input terminals at all times.

Symptoms of start-up difï¬culties may include failed started, output oscil-

lation or brief start up then overcurrent shutdown. Since the input voltage is

never absolutely constant, the converter may start up at some times and not

at others.

Solutions

To improve start up, review the conditions above. One of the better solutions

is to place a moderate size capacitor very close to the input terminals. You

may need two parallel capacitors. A larger electrolytic or tantalum cap sup-

plies the surge current and a smaller parallel low-ESR ceramic cap gives low

AC impedance. Too large an electrolytic capacitor may have higher internal

impedance (ESR) and/or lower the start up slew rate enough to upset the DC/

DCâs controller. Make sure the capacitors can tolerate reï¬ected switching cur-

rent pulses from the converter.

The capacitors will not help if the input source has poor regulation. A

converter which starts successfully at 3.3 Volts will turn off if the input voltage

decays to below the input voltage theshold, regardless of external capacitance.

Increase the input start up voltage if possible to raise the downward voltage

spike. Also, make sure that the input voltage ramps up in a reasonably short

time (less than a few milliseconds). If possible, move the input source closer

to the converter to reduce ohmic losses in the input wiring. Remember that

the input current is carried both by the wiring and the ground plane return.

Make sure the ground plane uses adequate thickness copper. Run additional

bus wire if necessary.

Any added output capacitor should use just enough capacitance (and

no more) to reduce output noise at the load and to avoid marginal thresh-

old noise problems with external logic. An output cap will also âdecoupleâ

inductive reactance in the load. Certain kinds of electronic loads include

âconstant currentâ characteristics which destabilize the output with insuf-

ï¬cient capacitance. If the wiring to the eventual load is long, consider placing

this decoupling cap at the load. Use the Remote Sense input to avoid ohmic

voltage drop errors.

An elegant solution to start up problems is to apply the input voltage with

the Remote On/Off control ï¬rst in the off setting (for those converters with an

On/Off Control). After the speciï¬ed start-up delay (usually under 20 mSec),

turn on the converter. The controller will have already been stabilized. The

short delay will not be noticed in most applications. Be aware of applications

which need âpower managementâ (phased start up).

Finally, it is challenging to model some application circuits with absolute

ï¬delity. How low is the resistance of your ground plane? What is the inductance

(and distributed capacitance) of external wiring? Even a detailed mathematical

model may not get all aspects of your circuit. Therefore it is difï¬cult to give cap

values which serve all applications. Some experimentation may be required.

Pre-Biased Startup

Newer systems with multiple power voltages have an additional problem

besides startup sequencing. Some sections have power already partially ap-

plied (possibly because of earlier power sequencing) or have leakage power

present so that the DC/DC converter must power up into an existing voltage.

This power may either be stored in an external bypass capacitor or supplied

by an active source.

This âpre-biasedâ condition can also occur with some types of program-

mable logic or because of blocking diode leakage or small currents passed

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