Sains Malaysiana 46(12)(2017): 2523–2528

http://dx.doi.org/10.17576/jsm-2017-4612-30

 

Peramalan Bahan Pencemar Ozon (O3) di Universiti Pendidikan Sultan Idris, Tanjung Malim, Perak, MalaysiaMengikut Monsun dengan Menggunakan Pendekatan Kalut

(Forecasting Ozone Pollutant (O3) in Universiti Pendidikan Sultan Idris, Tanjung Malim,
Perak, Malaysia, based on Monsoon using Chaotic Approach)

 

WAN NUR AFATEEN BINTI WAN MOHD ZAIM* & NOR ZILA ABD HAMID

 

Jabatan Matematik, Fakulti Sains dan Matematik, Universiti Pendidikan Sultan Idris, 35900 Tanjung Malim, Perak Darul Ridzuan, Malaysia

 

Received: 14 February 2017/Accepted: 7 June 2017

 

ABSTRAK

Peramalan bahan kepekatan ozon (O3) adalah sangat penting kerana udara yang mengandungi O3 boleh menyebabkan pelbagai penyakit kronik seperti kanser dan asma. Kajian ini merupakan kajian rintis dengan menggunakan pendekaan kalut bagi meramal kepekatan O3 di kawasan pendidikan di Malaysia. Data yang dikaji merupakan siri masa O3 yang dicerap mengikut jam di stesen yang terletak di Universiti Pendidikan Sultan Idris, Tanjung Malim, Perak. Sebelum model peramalan dibina, siri masa diuji terlebih dahulu untuk mengenal pasti sama ada dinamik kalut hadir ataupun tidak. Pendekatan kalut mempunyai dua langkah iaitu pembinaan semula ruang fasa dan proses peramalan. Pembinaan semula ruang fasa memerlukan penetapan dua parameter terlebih dahulu iaitu masa tunda τ dan matra pembenaman m. Kedua-dua parameter tersebut masing-masing diperoleh daripada kaedah purata maklumat bersama dan kaedah Cao. Melalui plot ruang fasa dan kaedah Cao, sifat kalut didapati hadir dalam siri masa O3. Oleh itu, model peramalan melalui pendekatan kalut menggunakan kaedah penghampiran purata setempat dibina. Pendekatan kalut ini merupakan salah satu kaedah alternatif yang boleh digunakan untuk meramal siri masa O3. Pekali korelasi adalah dipilih sebagai petunjuk prestasi bagi memberi gambaran tentang kekuatan hubungan antara nilai sebenar dengan nilai peramalan. Nilai pekali korelasi bagi siri masa O3 ketika Monsun Timur Laut adalah 0.8921. Manakala, nilai pekali korelasi ketika Monsun Barat Daya adalah 0.9002. Diharap dengan pendekatan kalut ini dapat membantu pihak bertanggungjawab untuk mengawal pencemaran O3 di kawasan pendidikan di Malaysia.

 

Kata kunci: Kaedah penghampiran purata setempat; Monsun Barat Daya; Monsun Timur Laut; pendekatan kalut; ozon;

 

ABSTRACT

Forecasting concentration of ozone (O3) is very important because the air containing O3 can cause chronic diseases such as cancer and asthma. This study is a pilot study using chaotic approach to forecast the concentration of O3 in Malaysian education area. The studied data were the hourly O3 observed at the station located at Universiti Pendidikan Sultan Idris, Tanjung Malim, Perak. Before the forecasting model can be built, the time series are tested in advance to determine the existence of chaotic dynamics. Chaotic approach has two steps, namely the reconstruction of phase space and forecasting process. Before the phase space can be reconstructed, there are two parameters that need to be determined namely the delay time τ and embedding dimension m. Both of these parameters were obtained from the average mutual information method and Cao method, respectively. Through phase space plot and Cao method, chaotic dynamic are present in the studied O3 time series. Therefore, the forecasting model through chaotic approach using local mean approximation method is built. This chaotic approach is one of the alternative methods that can be used to forecast the O3 time series. Correlation coefficient is chosen to present the relationship between the observed value and forecasted value. The correlation coefficient for the O3 time series during Northeast Monsoon is 0.8921. Meanwhile, the value of the correlation coefficient during Southwest Monsoon is 0.9002. It is hoped that the chaotic approach can help responsible agency to manage O3 pollution in Malaysian education area.

 

Keywords: Chaotic approach; local average approximation method; Northeast Monsoon; ozone; Southwest Monsoon

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*Corresponding author; email: ateenzaim@gmail.com

 

 

 

 

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