NQ12T50SMA16 Datasheet, PDF(11/15 Page) SynQor Worldwide Headquarters – 16A Non-Isolated, SMT DC/DC Converter with wide trim

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NQ12T50SMA16 Datasheet, PDF (11/15 Pages) SynQor Worldwide Headquarters – 16A Non-Isolated, SMT DC/DC Converter with wide trim

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Technical Specification

Non-Isolated

SMT Converter

9.6 - 14.4Vin 16A

there is also no concern with operation or startup into large

capacitive loads. The voltage may rise slowly while charging

the output capacitance, but it will rise.

There are also no problems starting into a load that has a resis-

tive V-I curve. As long as the load draws less than the current

limit value at 1/2 of the unit's setpoint voltage, proper startup

is ensured.

Internal Over-Voltage Protection: To fully protect from

excessive output voltage, the NQ12 series contains two levels

of Output Over-Voltage Shutdown circuitry.

The first type monitors the output at the load via the Sense+ pin

(or the output if Sense+ is left open). If the sensed voltage

exceeds the (optionally trimmed) setpoint by ~10% this protec-

tive circuit asserts the converter's low-side switch until the out-

put returns to normal. This circuit tracks the trimmed setpoint;

the +10% threshold is maintained over the wide trim range of

the T50 model. This circuit can also be benignly activated dur-

ing the response to a large, fast drop in load current. In this

instance the converter's normal transient response is momen-

tarily overridden by this OVP. The result is a slight asymmetry

in the converter's observed transient response.

It should be noted that there is no limit on this OVP; if a pow-

erful external source attempts to raise the output of an NQ12

converter beyond 110% of its setpoint, the converter will sacri-

fice itself trying to draw down that external source and protect

its load from the overvoltage.

The second Output Over-Voltage Shutdown circuit indepen-

dently compares the voltage at the converter's output pin with

that of a redundant reference. If the output ever exceeds

~125% of nominal setpoint, both converter switches are dis-

abled. After the output voltage returns to normal, a softstart

cycle is initiated.

This OVP is independent of the trimmed setpoint. As such, the

converter's load is protected from faults in the external trim cir-

cuitry (such as a trim pin shorted to ground). Since the setpoint

of this OVP does not track trim, it is set at 125% of 5.0V, or

6.2V, in the wide-trim T50 model.

Over-Temperature Shutdown: A temperature sensor on

the converter senses the average temperature of the module.

The thermal shutdown circuit is designed to turn the converter

off when the temperature at the sensed location reaches the

Over-Temperature Shutdown value. It will allow the converter to

turn on again when the temperature of the sensed location falls

by the amount of the Over-Temperature Shutdown Restart

Hysteresis value.

Product # NQ12T50SMA16

Phone 1-888-567-9596

APPLICATION CONSIDERATIONS

Input Filtering/Capacitance/Damping: The filter circuit

of Figure C is often added to the converter's input to prevent

switching noise from reaching the input voltage bus.

Figure C: NQ12 converter with Input Filter

In the SMA16 (surface mount) converters Cin = 30ÂµF and in the

VMA16 (SIP) converters Cin = 45ÂµF of high quality ceramic

capacitors. With Lin of 1ÂµH, Cd should be 100-200ÂµF and Rd

should be 0.1-0.2W, in most applications. For more informa-

tion on designing the input filter and choosing proper values,

contact SynQor technical support.

With the values listed above, the ripple current in L1 will be

below 100mA RMS for all units. The full-load worst-case filter

operation is summarized in Table 1.

Vout

Model

0.9

1.0

1.2

1.5

1.8

2.0

2.5

3.3

5.0

Current

(A RMS)

5.2

5.5

6.0

6.7

7.4

7.8

8.8

10.4

12.3

Ripple

(V RMS)

0.06

0.07

0.08

0.09

0.11

0.13

0.15

0.16

Current in L1

(mA RMS)

Vp Ripple

(V RMS)

0.04

0.05

0.06

0.07

0.08

0.09

0.10

0.11

Current in L1

(mA RMS)

Table 1: Full Load Input Filter Performance, SMA16

Adding significant external pure ceramic capacitance directly

across the converter's input pins is not recommended. Parasitic

inductance associated with the input pin geometry and PCB

traces can create a high-Q CLC circuit with any external capac-

itors. Just a few nano-Henries of parasitic inductance can cre-

ate a resonance (or an overtone) near the converter's switching

frequency. Cin has a reactance of 10-20mW at the 330kHz

switching frequency. To avoid this high-frequency resonance,

any external input filter should exhibit a net source impedance

of at least 20mW resistive through this frequency range. This

requirement is easily met with the damping elements discussed

above. Adding a small amount (a few ÂµF) of high-frequency

external ceramic will not violate it.

If using converters at higher powers, do consider the ripple cur-

rent rating of Cd. Contact SynQor technical support for more

Doc.# 005-2NS12TE Rev. A

5/28/04

Page 11

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