The Experts below are selected from a list of 360 Experts worldwide ranked by ideXlab platform
Anon Namin - One of the best experts on this subject based on the ideXlab platform.
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determination of solar cell electrical parameters and resistances using color and white led based solar Simulators with high amplitude pulse input voltages
Renewable Energy, 2013Co-Authors: Anon Namin, Dhirayut Chenvidhya, C Jivacate, K Kirtikara, Jutturit ThongpronAbstract:Advances in LEDs allow construction of LED solar Simulators for characterization of solar cells at moderate costs. Four single-color LED Simulators and one multi-color LED Simulators are constructed. High irradiance is obtained by employing high pulsing voltages to LEDs. Using the Simulators electrical parameters and resistances of solar cell are made. Applying correction methods recommended in the IEC 891 Standard, results from the red and blue LED Simulators and the Class AAA simulator are in good agreement.
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construction of tungsten halogen pulsed led and combined tungsten halogen led solar Simulators for solar cell characterization and electrical parameters determination
International Journal of Photoenergy, 2012Co-Authors: Anon Namin, Dhirayut Chenvidhya, C Jivacate, K Kirtikara, Jutturit ThongpronAbstract:- characterization of solar cells is generally done under natural sunlight or solar Simulators operating in either a continuous mode or a pulse mode. Simulators are classified on three features of irradiance, namely, spectral match with respect to air mass 1.5, spatial uniformity, and temporal stability. Commercial solar Simulators use Xenon lamps and halogen lamps, whereas LED-based solar Simulators are being developed. In this work, we build and test seven Simulators for solar cell characterization, namely, one tungsten halogen simulator, four monochromatic (red, green, blue, and white) LED Simulators, one multicolor LED simulator, and one tungsten halogen-blue LED simulator. The seven Simulators provide testing at nonstandard test condition. High irradiance from Simulators is obtained by employing elevated supply voltage to tungsten halogen lamps and high pulsing voltages to LEDs. This new approach leads to higher irradiance not previously obtained from tungsten halogen lamps and LEDs. From - curves, electrical parameters of solar cell are made and corrected based on methods recommended in the IEC 60891 Standards. Corrected values obtained from non-STC measurements are in good agreement with those obtained from Class AAA solar simulator.
Jutturit Thongpron - One of the best experts on this subject based on the ideXlab platform.
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determination of solar cell electrical parameters and resistances using color and white led based solar Simulators with high amplitude pulse input voltages
Renewable Energy, 2013Co-Authors: Anon Namin, Dhirayut Chenvidhya, C Jivacate, K Kirtikara, Jutturit ThongpronAbstract:Advances in LEDs allow construction of LED solar Simulators for characterization of solar cells at moderate costs. Four single-color LED Simulators and one multi-color LED Simulators are constructed. High irradiance is obtained by employing high pulsing voltages to LEDs. Using the Simulators electrical parameters and resistances of solar cell are made. Applying correction methods recommended in the IEC 891 Standard, results from the red and blue LED Simulators and the Class AAA simulator are in good agreement.
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construction of tungsten halogen pulsed led and combined tungsten halogen led solar Simulators for solar cell characterization and electrical parameters determination
International Journal of Photoenergy, 2012Co-Authors: Anon Namin, Dhirayut Chenvidhya, C Jivacate, K Kirtikara, Jutturit ThongpronAbstract:- characterization of solar cells is generally done under natural sunlight or solar Simulators operating in either a continuous mode or a pulse mode. Simulators are classified on three features of irradiance, namely, spectral match with respect to air mass 1.5, spatial uniformity, and temporal stability. Commercial solar Simulators use Xenon lamps and halogen lamps, whereas LED-based solar Simulators are being developed. In this work, we build and test seven Simulators for solar cell characterization, namely, one tungsten halogen simulator, four monochromatic (red, green, blue, and white) LED Simulators, one multicolor LED simulator, and one tungsten halogen-blue LED simulator. The seven Simulators provide testing at nonstandard test condition. High irradiance from Simulators is obtained by employing elevated supply voltage to tungsten halogen lamps and high pulsing voltages to LEDs. This new approach leads to higher irradiance not previously obtained from tungsten halogen lamps and LEDs. From - curves, electrical parameters of solar cell are made and corrected based on methods recommended in the IEC 60891 Standards. Corrected values obtained from non-STC measurements are in good agreement with those obtained from Class AAA solar simulator.
Dhirayut Chenvidhya - One of the best experts on this subject based on the ideXlab platform.
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determination of solar cell electrical parameters and resistances using color and white led based solar Simulators with high amplitude pulse input voltages
Renewable Energy, 2013Co-Authors: Anon Namin, Dhirayut Chenvidhya, C Jivacate, K Kirtikara, Jutturit ThongpronAbstract:Advances in LEDs allow construction of LED solar Simulators for characterization of solar cells at moderate costs. Four single-color LED Simulators and one multi-color LED Simulators are constructed. High irradiance is obtained by employing high pulsing voltages to LEDs. Using the Simulators electrical parameters and resistances of solar cell are made. Applying correction methods recommended in the IEC 891 Standard, results from the red and blue LED Simulators and the Class AAA simulator are in good agreement.
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construction of tungsten halogen pulsed led and combined tungsten halogen led solar Simulators for solar cell characterization and electrical parameters determination
International Journal of Photoenergy, 2012Co-Authors: Anon Namin, Dhirayut Chenvidhya, C Jivacate, K Kirtikara, Jutturit ThongpronAbstract:- characterization of solar cells is generally done under natural sunlight or solar Simulators operating in either a continuous mode or a pulse mode. Simulators are classified on three features of irradiance, namely, spectral match with respect to air mass 1.5, spatial uniformity, and temporal stability. Commercial solar Simulators use Xenon lamps and halogen lamps, whereas LED-based solar Simulators are being developed. In this work, we build and test seven Simulators for solar cell characterization, namely, one tungsten halogen simulator, four monochromatic (red, green, blue, and white) LED Simulators, one multicolor LED simulator, and one tungsten halogen-blue LED simulator. The seven Simulators provide testing at nonstandard test condition. High irradiance from Simulators is obtained by employing elevated supply voltage to tungsten halogen lamps and high pulsing voltages to LEDs. This new approach leads to higher irradiance not previously obtained from tungsten halogen lamps and LEDs. From - curves, electrical parameters of solar cell are made and corrected based on methods recommended in the IEC 60891 Standards. Corrected values obtained from non-STC measurements are in good agreement with those obtained from Class AAA solar simulator.
C Jivacate - One of the best experts on this subject based on the ideXlab platform.
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determination of solar cell electrical parameters and resistances using color and white led based solar Simulators with high amplitude pulse input voltages
Renewable Energy, 2013Co-Authors: Anon Namin, Dhirayut Chenvidhya, C Jivacate, K Kirtikara, Jutturit ThongpronAbstract:Advances in LEDs allow construction of LED solar Simulators for characterization of solar cells at moderate costs. Four single-color LED Simulators and one multi-color LED Simulators are constructed. High irradiance is obtained by employing high pulsing voltages to LEDs. Using the Simulators electrical parameters and resistances of solar cell are made. Applying correction methods recommended in the IEC 891 Standard, results from the red and blue LED Simulators and the Class AAA simulator are in good agreement.
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construction of tungsten halogen pulsed led and combined tungsten halogen led solar Simulators for solar cell characterization and electrical parameters determination
International Journal of Photoenergy, 2012Co-Authors: Anon Namin, Dhirayut Chenvidhya, C Jivacate, K Kirtikara, Jutturit ThongpronAbstract:- characterization of solar cells is generally done under natural sunlight or solar Simulators operating in either a continuous mode or a pulse mode. Simulators are classified on three features of irradiance, namely, spectral match with respect to air mass 1.5, spatial uniformity, and temporal stability. Commercial solar Simulators use Xenon lamps and halogen lamps, whereas LED-based solar Simulators are being developed. In this work, we build and test seven Simulators for solar cell characterization, namely, one tungsten halogen simulator, four monochromatic (red, green, blue, and white) LED Simulators, one multicolor LED simulator, and one tungsten halogen-blue LED simulator. The seven Simulators provide testing at nonstandard test condition. High irradiance from Simulators is obtained by employing elevated supply voltage to tungsten halogen lamps and high pulsing voltages to LEDs. This new approach leads to higher irradiance not previously obtained from tungsten halogen lamps and LEDs. From - curves, electrical parameters of solar cell are made and corrected based on methods recommended in the IEC 60891 Standards. Corrected values obtained from non-STC measurements are in good agreement with those obtained from Class AAA solar simulator.
K Kirtikara - One of the best experts on this subject based on the ideXlab platform.
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determination of solar cell electrical parameters and resistances using color and white led based solar Simulators with high amplitude pulse input voltages
Renewable Energy, 2013Co-Authors: Anon Namin, Dhirayut Chenvidhya, C Jivacate, K Kirtikara, Jutturit ThongpronAbstract:Advances in LEDs allow construction of LED solar Simulators for characterization of solar cells at moderate costs. Four single-color LED Simulators and one multi-color LED Simulators are constructed. High irradiance is obtained by employing high pulsing voltages to LEDs. Using the Simulators electrical parameters and resistances of solar cell are made. Applying correction methods recommended in the IEC 891 Standard, results from the red and blue LED Simulators and the Class AAA simulator are in good agreement.
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construction of tungsten halogen pulsed led and combined tungsten halogen led solar Simulators for solar cell characterization and electrical parameters determination
International Journal of Photoenergy, 2012Co-Authors: Anon Namin, Dhirayut Chenvidhya, C Jivacate, K Kirtikara, Jutturit ThongpronAbstract:- characterization of solar cells is generally done under natural sunlight or solar Simulators operating in either a continuous mode or a pulse mode. Simulators are classified on three features of irradiance, namely, spectral match with respect to air mass 1.5, spatial uniformity, and temporal stability. Commercial solar Simulators use Xenon lamps and halogen lamps, whereas LED-based solar Simulators are being developed. In this work, we build and test seven Simulators for solar cell characterization, namely, one tungsten halogen simulator, four monochromatic (red, green, blue, and white) LED Simulators, one multicolor LED simulator, and one tungsten halogen-blue LED simulator. The seven Simulators provide testing at nonstandard test condition. High irradiance from Simulators is obtained by employing elevated supply voltage to tungsten halogen lamps and high pulsing voltages to LEDs. This new approach leads to higher irradiance not previously obtained from tungsten halogen lamps and LEDs. From - curves, electrical parameters of solar cell are made and corrected based on methods recommended in the IEC 60891 Standards. Corrected values obtained from non-STC measurements are in good agreement with those obtained from Class AAA solar simulator.
