| _version_ |
1860797415305510912
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| building |
INTELEK Repository
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| collection |
Online Access
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| collectionurl |
https://intelek.unisza.edu.my/intelek/pages/search.php?search=!collection407072
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| date |
2015-12-30 15:28:46
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| format |
Restricted Document
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| id |
12624
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| institution |
UniSZA
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| internalnotes |
1. Adediji, A. T., Mandeep, J. S. and Ismail, M. (2014). Meteorological Characterization of Effective Earth Radius Factor (k-Factor) Wireless Radio Link Over Akure, Nigeria. Metrology Society of India 29 (2): 131-141 2. Abidin, Z. Z., Adnan, S. B. R. S. and Ibrahim, Z.A. (2009). RFI profiles of prime candidate sites for the first radio astronomical telescope in Malaysia. New Astronomy 15(3): 307–312. 3. Merola, L. (2006). A Study of the Effects of Sunrise and Sunset on the Ionosphere as Observed by VLF Wave Behavior (online). http://solar-center.stanford.edu/SID/StudentWork/LeandraMerola.pdf (21 April 2015) 4. Ezekoye, B. A. and Obodo, R. M. (2007). The Effects of Solar Radiations on Telecommunications. The Pacific Journal of Science and Technology 8 (1): 109-117 5. MCMC manual of ‘Spectrum Plan (2006). MCMC manual of ‘Spectrum Plan, Malaysian Communication and Multimedia Commission’ (2006). Resources Assignment Management Department Available: http://www.mcmc.gov.my/what_we_do/spectrum/plan.asp. 6. Abidin, Z. Z., Ibrahim, Z. A., Rosli, Z., Malim, S. F. F., Anim, N. M. and Noorazlan, N. (2012). An RFI Investigation for Setting up a VLBI Station below 2.8 GHz in Malaysia. New Astronomy 17 : 61-64. 7. Abidin, Z.Z., Umar, R., Ibrahim, Z. A., Rosli, Z., Asanok, K. and Gasiprong, N. (2013). Investigation on the Frequency Allocation for Radio Astronomy at the L Band. Publications of the Astronomical Society of Australia (PASA) 30: 47-57. 8. Umar, R., Abidin, Z. Z., Ibrahim, Z. A., Rosli, Z. and Noorazlan, N. (2014). Selection of Radio Astronomical Observation Sites and Its Dependence on Human Generated RFI. Research in Astronomy and Astrophysics 14 (2) : 241-248.
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6931-01-FH02-ESERI-15-04689.jpg
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| person |
norman
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| recordtype |
oai_dc
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| resourceurl |
https://intelek.unisza.edu.my/intelek/pages/view.php?ref=12624
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| spelling |
12624 https://intelek.unisza.edu.my/intelek/pages/view.php?ref=12624 https://intelek.unisza.edu.my/intelek/pages/search.php?search=!collection407072 Restricted Document Article Journal image/jpeg inches 96 96 norman 768 35 35 1409 2015-12-30 15:28:46 1409x768 6931-01-FH02-ESERI-15-04689.jpg UniSZA Private Access The effect of solar radiation on radio signal for radio astronomy purposes [Kesan radiasi solar terhadap isyarat radio untuk kajian astronomi radio] Malaysian Journal of Analytical Sciences Radio astronomy is a subfield of astronomy which is discovers the celestial objects at radio frequencies. Observation in radio astronomy is conducted using single antenna or array of antennas, known as radio telescope. Other than that, radio astronomy also holds an advantage over other alternatives to optical astronomy due to its capability of observing from the ground level. In this study, the effect of solar radiation that contributes the Radio Frequency Interferences (RFI) is reviewed. The low RFI level is required to set up the radio telescope for radio astronomy observation. The effect of solar radiation on radio signal was investigated by determining the RFI pattern using spectrum analyzer. The solar radiation data was obtained from weather station located at KUSZA Observatory, East Coast Environmental Research Institute (ESERI), UniSZA. We can conclude that the solar radiation factor give the minimum significant effect to radio signal. 19 6 Malaysian Society of Analytical Sciences Malaysian Society of Analytical Sciences 1374-1381 1. Adediji, A. T., Mandeep, J. S. and Ismail, M. (2014). Meteorological Characterization of Effective Earth Radius Factor (k-Factor) Wireless Radio Link Over Akure, Nigeria. Metrology Society of India 29 (2): 131-141 2. Abidin, Z. Z., Adnan, S. B. R. S. and Ibrahim, Z.A. (2009). RFI profiles of prime candidate sites for the first radio astronomical telescope in Malaysia. New Astronomy 15(3): 307–312. 3. Merola, L. (2006). A Study of the Effects of Sunrise and Sunset on the Ionosphere as Observed by VLF Wave Behavior (online). http://solar-center.stanford.edu/SID/StudentWork/LeandraMerola.pdf (21 April 2015) 4. Ezekoye, B. A. and Obodo, R. M. (2007). The Effects of Solar Radiations on Telecommunications. The Pacific Journal of Science and Technology 8 (1): 109-117 5. MCMC manual of ‘Spectrum Plan (2006). MCMC manual of ‘Spectrum Plan, Malaysian Communication and Multimedia Commission’ (2006). Resources Assignment Management Department Available: http://www.mcmc.gov.my/what_we_do/spectrum/plan.asp. 6. Abidin, Z. Z., Ibrahim, Z. A., Rosli, Z., Malim, S. F. F., Anim, N. M. and Noorazlan, N. (2012). An RFI Investigation for Setting up a VLBI Station below 2.8 GHz in Malaysia. New Astronomy 17 : 61-64. 7. Abidin, Z.Z., Umar, R., Ibrahim, Z. A., Rosli, Z., Asanok, K. and Gasiprong, N. (2013). Investigation on the Frequency Allocation for Radio Astronomy at the L Band. Publications of the Astronomical Society of Australia (PASA) 30: 47-57. 8. Umar, R., Abidin, Z. Z., Ibrahim, Z. A., Rosli, Z. and Noorazlan, N. (2014). Selection of Radio Astronomical Observation Sites and Its Dependence on Human Generated RFI. Research in Astronomy and Astrophysics 14 (2) : 241-248.
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| spellingShingle |
The effect of solar radiation on radio signal for radio astronomy purposes [Kesan radiasi solar terhadap isyarat radio untuk kajian astronomi radio]
|
| summary |
Radio astronomy is a subfield of astronomy which is discovers the celestial objects at radio frequencies. Observation in radio astronomy is conducted using single antenna or array of antennas, known as radio telescope. Other than that, radio astronomy also holds an advantage over other alternatives to optical astronomy due to its capability of observing from the ground level. In this study, the effect of solar radiation that contributes the Radio Frequency Interferences (RFI) is reviewed. The low RFI level is required to set up the radio telescope for radio astronomy observation. The effect of solar radiation on radio signal was investigated by determining the RFI pattern using spectrum analyzer. The solar radiation data was obtained from weather station located at KUSZA Observatory, East Coast Environmental Research Institute (ESERI), UniSZA. We can conclude that the solar radiation factor give the minimum significant effect to radio signal.
|
| title |
The effect of solar radiation on radio signal for radio astronomy purposes [Kesan radiasi solar terhadap isyarat radio untuk kajian astronomi radio]
|
| title_full |
The effect of solar radiation on radio signal for radio astronomy purposes [Kesan radiasi solar terhadap isyarat radio untuk kajian astronomi radio]
|
| title_fullStr |
The effect of solar radiation on radio signal for radio astronomy purposes [Kesan radiasi solar terhadap isyarat radio untuk kajian astronomi radio]
|
| title_full_unstemmed |
The effect of solar radiation on radio signal for radio astronomy purposes [Kesan radiasi solar terhadap isyarat radio untuk kajian astronomi radio]
|
| title_short |
The effect of solar radiation on radio signal for radio astronomy purposes [Kesan radiasi solar terhadap isyarat radio untuk kajian astronomi radio]
|
| title_sort |
effect of solar radiation on radio signal for radio astronomy purposes [kesan radiasi solar terhadap isyarat radio untuk kajian astronomi radio]
|