LNK454 Datasheet, PDF(5/20 Page) Power Integrations, Inc. – LED Driver IC with TRIAC Dimming, Single-Stage PFC and Constant Current Control for Non-Isolated Applications

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LNK454 Datasheet, PDF (5/20 Pages) Power Integrations, Inc. – LED Driver IC with TRIAC Dimming, Single-Stage PFC and Constant Current Control for Non-Isolated Applications

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LNK454/456-458/460

IC Supply and BYPASS Pin

The internal 5.85 V regulator charges the bypass capacitor

connected to the BYPASS pin to 5.85 V by drawing current

from the voltage on the DRAIN pin whenever the power MOSFET

is off. The BYPASS pin is the internal supply voltage node.

When the power MOSFET is on, the device operates from the

energy stored in the bypass capacitor. Extremely low power

consumption of the internal circuitry allows LinkSwitch-PL to

operate continuously from current it takes from the DRAIN pin.

A bypass capacitor value of 1 ÂµF is sufficient for both high

frequency decoupling and energy storage. Dimming

applications may require a higher bypass capacitor value.

Overload Protection

In case of overload, the system will increase the operating

frequency and on-time each AC half-cycle until the maximum

frequency and maximum on-time are reached. When this state

is reached, the controller enters auto-restart protection, thus

inhibiting the gate of the power MOSFET for approximately

1.28 s if the main line frequency is 50 Hz, 1.02 s if it is 60 Hz.

After this auto-restart off-time expires, the power MOSFET is

re-enabled and a normal start-up is initiated, i.e. at fMIN and

tON(MIN), stepping up until regulation is achieved again. In case of

a persistent overload condition, the auto-restart duty cycle DCAR

is ~33%.

During phase angle dimming when the conduction angle is

small the AC input voltage is present for only short periods of

time. In that case the IC should not rely on the integrated

high-voltage current source, but instead external bias circuitry

should be used to supply the IC from the output (DES and RES in

Figure 4). If the output voltage is less than 7 V, external bias

circuitry should be implemented. This is accomplished by

adding an auxiliary winding on the transformer, which is then

rectified and filtered via a diode (ultrafast) and capacitor. The

winding voltage (turns) should be selected such that the maximum

IC consumption can be supported at the lowest operating

output current.

Start-up, Switching Frequency and On-time Range

At start-up the controller uses an initial switching frequency fMIN

and minimum on-time tON(MIN). The charging of the output

capacitor together with the energy delivery to the output LEDs

determines a step-by-step increase of the power MOSFET

switching frequency and on-time updated every half-cycle of the

AC input voltage.

The steady-state switching frequency and on-time are

determined by the line voltage, voltage drop across the LEDs

and converter efficiency.

At light load when the device reaches the minimum frequency

fMIN and on-time tON(MIN), the controller regulates by skipping

cycles. In this mode of operation the input current is not power

factor corrected and the average output current is not guaranteed

to fall within the normal range. A properly designed supply will

not operate in this mode under normal load conditions.

A power supply designed correctly will operate within the

switching frequency range [fMIN â¦ fMAX], with an on-time falling

between tON(MIN) and tON(MAX) when connected to a normal load.

Overload protection is inhibited during phase dimming when the

TRIAC conduction duty cycle is less than 60%.

Output Overvoltage Protection

If a no-load condition is present on the output of the supply, the

output overvoltage Zener (DZOV in Figure 4) will conduct once its

threshold is reached. A voltage VOV in excess of VFB(AR) = 2 V will

appear across the FEEDBACK pin and the IC will enter auto-

restart.

Output Short-Circuit

If the output of the supply (i.e. the LED load) is short-circuited,

then a large amount of energy will be delivered to the sense

resistor, generating a high-voltage at the FEEDBACK pin. If this

condition develops more than 2 V on the FEEDBACK pin, then

the IC will interpret this event as an output short-circuit and will

enter auto-restart.

Safe Operating Area (SOA) Protection

If 3 consecutive cycles of the power MOSFET are prematurely

terminated due to the power MOSFET current exceeding the

current limit after the leading edge blanking time, SOA protection

mode is triggered and the IC will enter auto-restart.

Hysteretic Thermal Shutdown

The thermal shutdown circuitry senses the die junction

temperature. The thermal shutdown threshold is set to 142 Â°C

typical with a 75 Â°C hysteresis. When the die temperature rises

above this threshold (142 Â°C) the power MOSFET is disabled

and remains disabled until the die temperature falls by 75 Â°C, at

which point the power MOSFET is re-enabled.

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Rev. C 10/11

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