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Download Test Procedure for the NCP1013LED Evaluation Board Introduction:
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Test Procedure for the NCP1013LED Evaluation Board Introduction: The NCP1013LED Evaluation Board is a universal input, off‐line power supply intended to provide a constant current output with a maximum “header” voltage for powering strings of LEDs. The output has a constant current, constant voltage profile that depends on the circuit configuration. The evaluation board is configured to provide a nominal current of 700 mA with an open circuit clamp voltage of 8.6V nominal. It is power limited if the power exceeds 5W. A typical transfer function of the output voltage‐ current characteristic is illustrated below. 9 8 7 Output Voltage (V) 6 5 4 3 2 1 0 0 0.05 0.1 0.15 0.2 0.25 0.3 0.35 0.4 0.45 0.5 0.55 0.6 0.65 0.7 0.75 0.8 Output Current (A) Figure 1 IV Curve The switching topology is a discontinuous flyback converter operating at 100 kHz The output connector of the demo supply is a Tyco type connector and will either require a mating connector or the load should be “hard wired” to pad JP1 (‐) and JP2 (+) on the pc board. Test Equipment Required: 1. Adjustable, isolated AC power source capable of zero to 265 Vac output and up to 500 mA. AC source should have the capability of measuring output power in watts. If not, an AC line analyzer or AC wattmeter should be used. Wattmeter should be capable if reading down to 50 mW (for standby power measurements.) 2. Digital volt/amp meters to measure output current and voltage to the electronic load. 3. A variable electronic load or rheostat capable of up to a 5 amp load at 24 volts. If an electronic load is used it is preferable to have it operate in a constant resistance load mode. 4. Oscilloscope with probe to monitor output ripple on the demo converter. 3/4/2008 www.BDTIC.com/ON/ -1- www.onsemi.com Setup Procedure: Set the equipment as shown in the diagram on the next page so that the output voltage and current to the demo board can be measured. The oscilloscope should be set up so that the output ripple can be monitored. AC Source volts 115 Vac DVM - + AC out Vadj Iadj O'scope Board Under Test WATTS (Required if not in AC source) AC in + DC out Electronic Load amps + DVM - + Adj Figure 2 Test Setup Test Procedure: 1. Switch the electronic load on, set to constant resistance mode and the load adjust to zero load; switch all of the digital meters on (assuming they are wired properly for voltage and current sensing); turn the oscilloscope on with sensing in AC mode and 200 mV per division vertical and a sweep rate of 5 uS per division. Connect the scope probe to the demo board’s output terminals. 2. With the AC source OFF, set the current limit on the AC source to 500 mA and the output voltage to 115 Vac. 3. Turn on the AC source and the power supply demo board the open circuit output voltage should be in the range of 8.6 +1.5 volt/‐ 0.5 volts on the DVM. 4. Adjust the electronic load from no current load (high impedance) slowly until the output voltage measures 7.5V. The output current should measure 700 +/ 40mA. The output ripple on the oscilloscope should be less than 500 mV peak‐to‐peak. 5. Reduce the AC input to 90 Vac and make sure the conditions of test 4 above still hold. 6. Return the input to 115 Vac and continue to increase the load slowly and the current should remain constant within +/‐ 10% of the nominal rated output current level as the voltage collapses (constant current output). The NCP1013LED should be able to go all the way down to a couple of volts or less under heavy overload. 7. Set the electronic load to back to zero and the output voltage should return to the rated level. 8. Check the AC input power. It should be below 300 mW. 9. Adjust the AC input to 230 Vac and repeat tests (3) through (7). 10. Set the electronic load to zero and switch the AC source off. End of Test. 3/4/2008 www.BDTIC.com/ON/ -2- www.onsemi.com