NCP1396ADR2G ON Semiconductor, NCP1396ADR2G Datasheet - Page 22

NCP1396ADR2G

Manufacturer Part Number

NCP1396ADR2G

Description

IC CTRLR OVP HV 16SOIC

Manufacturer

ON Semiconductor

Type

High Performance Resonant Mode Controllersr

Datasheet

1.NCP1396BDR2G.pdf (25 pages)

Specifications of NCP1396ADR2G

Pwm Type

Voltage Mode

Number Of Outputs

Frequency - Max

575kHz

Duty Cycle

52%

Voltage - Supply

10.5 V ~ 20 V

Buck

Boost

Flyback

Inverting

Doubler

Divider

Cuk

Isolated

Yes

Operating Temperature

-40°C ~ 125°C

Package / Case

16-SOIC (3.9mm Width, 15 Leads)

Frequency-max

575kHz

Number Of Pwm Outputs

On/off Pin

Adjustable Output

Switching Freq

58.2 TO 575kHz

Operating Supply Voltage (max)

20V

Output Current

1000A

Synchronous Pin

Rise Time

40ns

Fall Time

20ns

Operating Temperature Classification

Automotive

Mounting

Surface Mount

Pin Count

Package Type

SOIC

Output Voltage Range

20 V

Power Dissipation

42 mW

Operating Temperature Range

- 40 C to + 125 C

Mounting Style

SMD/SMT

Input Voltage

12V

Frequency

500kHz

Supply Voltage Range

20V

Digital Ic Case Style

SOIC

No. Of Pins

Svhc

No SVHC (15-Dec-2010)

Base Number

1396

Rohs Compliant

Yes

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Other names

NCP1396ADR2GOSTR

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reaches the VtimerON level (4 V typical), then all pulses

are stopped. If the fault input signal is still present, then the

controller permanently stays off and the voltage on the

timer capacitor does not move (Itimer is on and the voltage

is clamped to 5 V). If the fault input signal is removed

(because pulses are off for instance), Itimer turns off and

the capacitor slowly discharges to ground via a resistor

installed in parallel with it. As a result, the designer can

easily determine the time during which the power supply

stays locked by playing on Rtimer. Now, when the timer

capacitor voltage reaches 1 V typical (VtimerOFF), the

comparator instructs the internal logic to issues pulses as on

a clean soft- - start sequence (soft- - start is activated). Please

note that the discharge resistor can not be lower than 4 V

Fast Input

as its voltage exceeds 1 V typical, all pulses are off and

maintained off as long as the fault is present. When the pin

is released, pulses come back and the soft- - start is activated.

observe the feedback pin via a resistive divided and thus

implement skip cycle operation. The resonant converter

The fast input is not affected by a delayed action. As soon

Thanks to the low activation level of 1 V, this pin can

Figure 49. Skip cycle can be implemented via two

resistors on the FB pin to the Fast fault input

Fault is Gone

Figure 48. A resistor can easily program the capacitor discharge time

Fast Fault

SMPS Stops

http://onsemi.com

Reset at Re- -start

/ Itimer otherwise the voltage on Ctimer will not reach the

turn- - off voltage of 4 V.

Mlower and Mupper are internally pulled down to ground.

current, once averaged, gives an image of the input power

in case Vin is kept constant via a PFC circuit. If the output

loading increases above a certain level, the voltage on this

pin will pass the 1 V threshold and start the timer. If the

overload stays there, after a few tens of milli- - seconds,

switching pulses will disappear and a protective

auto- - recovery cycle will take place. Adjusting the resistor

R in parallel with the timer capacitor will give the

flexibility to adjust the fault burst mode.

can be designed to lose regulation in light load conditions,

forcing the FB level to increase. When it reaches the

programmed level, it triggers the fast fault input and stops

pulses. Then Vout slowly drops, the loop reacts by

decreasing the feedback level which, in turn, unlocks the

pulses, Vout goes up again and so on: we are in skip cycle

mode.

Startup Behavior

consumption is kept to Istrup, allowing to crank- - up the

converter via a resistor connected to the bulk capacitor.

When V

high first and then output Mupper. This sequence will

always be the same whatever triggers the pulse delivery:

fault, OFF to ON etc Pulsing the output Mlower high first

gives an immediate charge of the bootstrap capacitor.

Then, the rest of pulses follow, delivered at the highest

switching value, set by the resistor on pin 2. The soft- - start

capacitor ensures a smooth frequency decrease to either the

programmed minimum value (in case of fault) or to a value

corresponding to the operating point if the feedback loop

closes first. Figure 50 shows typical signals evolution at

power on.

In both cases, when the fault is validated, both outputs

On Figure 46 example, a voltage proportional to primary

When the V

reaches the V

SMPS Re- -starts

voltage grows- - up, the internal current

CC(on)

4 V

1 V

level, output Mlower goes

NCP1396ADR2G ON Semiconductor, NCP1396ADR2G Datasheet - Page 22

NCP1396ADR2G

Specifications of NCP1396ADR2G

Available stocks

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