RDK-268 Power Integrations, RDK-268 Datasheet - Page 7

RDK-268

Manufacturer Part Number

RDK-268

Description

REFERENCE DESIGN LINKSWITCH-PL

Manufacturer

Power Integrations

Series

LinkSwitch®-PLr

Datasheet

1.RDK-268.pdf (20 pages)

Specifications of RDK-268

Mfg Application Notes

LinkSwitch-PL Family AppNote

Design Resources

RDR-268

Current - Output / Channel

366mA

Outputs And Type

1, Non-Isolated

Voltage - Output

2.5 V ~ 3.5 V

Voltage - Input

85 ~ 265VAC

Utilized Ic / Part

LNK454DG

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Features

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

Other names

596-1423

Current page: 7 of 20
Download datasheet (2Mb)

Bleeder Circuit

Resistor R10, R11 and C6 form a bleeder network which

ensures the initial input current is high enough meet the TRIAC

holding current requirement, especially during small conduction

angles. For non-dimming application R10, R11 and C6 may be

omitted.

Input Rectifier and EMI Filter

EMI filtering is provided by L1 and a pi (π) filter formed by C4, L2

and C5. Resistors R2 and R9 dampen the self resonances of

the filter stages and reduce the resultant peaks in the

conducted EMI spectrum. As shown the design meets

EN55015 conducted limits with >20 dB margin.

The incoming AC is rectified by BR1 and filtered by C4 and C5.

The total effective input capacitance, the sum of C4 and C5,

was selected to ensure correct zero crossing detection of the

AC input by the LinkSwitch-PL device, necessary for correct

dimming operation.

Primary Components

The LNK457DG device (U1) incorporates the power switching

device, oscillator, CC control engine, startup, and protection

functions. The integrated 725 V power MOSFET provides

extended design margin, improving robustness during line

surge events even in high line applications. The device is

powered from the BYPASS pin via the decoupling capacitor C9.

At start-up, C9 is charged by U1 from an internal current source

via the DRAIN pin and then during normal operation it is

supplied by the output via R15 and D4. For non-dimming

designs D4 and R15 may be omitted.

The rectified and filtered input voltage is applied to one end of

the primary winding of T1. The other side of the transformer’s

primary winding is driven by the integrated power MOSFET in

U1. The leakage inductance drain voltage spike is limited by an

RCD-R clamp consisting of D2, R13, R12, and C7.

Diode D6 is used to protect the IC from negative ringing (drain

voltage below source voltage) when the power MOSFET is off

and the input voltage is below the reflected output voltage (V

Output Rectification

The secondary of the transformer is rectified by D5, a Schottky

barrier type for higher efficiency, and filtered by C11. Resistor

R17 and C10 damp high frequency ringing and improve

conducted and radiated EMI.

Output Feedback

The CC mode set-point is determined by the voltage drop that

appears across R18 which is then fed to the FEEDBACK pin of

U1. Output overvoltage protection is provided by VR2 and R21.

Application Considerations

Input Capacitor Selection

For correct operation during dimming, the LinkSwitch-PL device

must detect line voltage zero crossing. This is sensed internally

via the drain node at the point the DC bus falls to <19 V. The

requirement for the DC bus to reach this level on each half-cycle

www.powerint.com

limits the maximum capacitance on the DC side of the input

bridge rectifier. Typically the maximum capacitance value

needed for high power factor also results in meeting the 19 V

limit however during development, this should be verified on an

oscilloscope.

If a reduction in capacitance is required and this results in

increased conducted EMI then capacitance may be added

before the input rectifier which effectively isolates it from the bus

capacitance.

For applications intended for use with leading edge TRIAC

dimmers, film capacitors are recommended as ceramic

capacitors typically create audible noise.

Output Capacitor Selection

Output capacitance has a direct effect on the output load (LED)

ripple current. The larger the capacitance, the lower the ripple

current. Excessive capacitance can prevent the output reaching

regulation within the auto-restart time and either cause failure to

start or require several start-up attempts (hiccups). Too little

capacitance can cause the voltage of the FEEDBACK pin to

exceed the cycle skipping mode threshold, degrading PF and

causing output flicker while dimming.

Therefore the output capacitance value should be selected

such that the ripple voltage across the output current sense

resistor (R18 in Figure 7) and fed into the FEEDBACK pin is

within the range of 100 mVp-p ≤ V

target value of 290 mVp-p.

The output capacitor type is not critical. Non-electrolytic

capacitors are attractive in terms of lifetime (ceramics and solid

dielectric types do not have an electrolyte that evaporates over

time) however electrolytic types offer the best volumetric

efficiency vs. cost. If multi-layer ceramics are selected, verify

the data sheet curves of capacitance vs. applied voltage and

temperature coefficient. The typical capacitance value may be

50% lower across temperature and/or close to rated voltage.

For all capacitor types verify the capacitor(s) selected are rated

for the output ripple current. For electrolytic types, this requires

selecting a low ESR type. A temperature rating of 105 °C or

higher is recommended for long lifetime. For typical designs

there is minimal self heating of the output capacitor and

therefore lifetime is determined by the internal ambient

temperature and broadly follows the Arrhenius equation, i.e.

lifetime doubles for every 10 °C drop in operating temperature.

For example the selection of a capacitor with a rated life of

5,000 hours at 105 °C would have an expected lifetime of

40,000 hours at 75 °C. End of life is typically defined for an

electrolytic capacitor as a doubling of the ESR and the

capacitance reducing by 20%. This often has little impact to

the performance seen by the end user and extends the fit for

purpose lifetime.

Feedback Pin Signal

During normal non-dimming (full power) operation, the FEEDBACK

pin threshold voltage (the voltage developed across the current

sense resistor) is 290 mV. For best output current regulation,

between 100 mVp-p to 400 mVp-p of voltage ripple is recommended.

LNK454/456-458/460

FEEDBACK

≤ 400 mVp-p with a

Rev. A 11/01/10

RDK-268 Power Integrations, RDK-268 Datasheet - Page 7

RDK-268

Specifications of RDK-268

Related parts for RDK-268