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Sains Malaysiana 43(3)(2014):
475–481
Suatu Kajian Perintis Menggunakan Pendekatan Kalut bagi Pengesanan Sifat dan Peramalan Siri Masa Kepekatan PM (A Pilot Study using Chaotic Approach to Determine Characteristics
and Forecasting of PM10 Concentration Time
Series)
NOR ZILA ABD HAMID1* & MOHD
SALMI
MD
NOORANI2 1Jabatan Matematik, Fakulti Sains dan Matematik,
Universiti Pendidikan Sultan Idris 35900 Tanjung Malim, Perak, Malaysia
2Pusat Pengajian Sains Matematik, Fakulti
Sains dan Teknologi 43600 Bangi, Selangor, Malaysia
Received: 16 May 2013/Accepted: 15 July 2013
ABSTRAK
Peramalan kepekatan PM10 adalah penting kerana menyedut udara
mengandungi PM10 boleh membawa kepada pelbagai penyakit kronik
seperti kanser dan bronkitis. Kajian ini merupakan kajian perintis
menggunakan pendekatan kalut bagi meramal PM10 di Malaysia. Data yang dikaji adalah siri masa
PM10 mengikut
jam yang dicerap di stesen penanda aras yang terletak dalam daerah
Jerantut di negeri Pahang. Pendekatan kalut mempunyai dua langkah
iaitu pembinaan semula ruang fasa dan proses peramalan. Melalui
langkah 1, ruang fasa pelbagai-matra dibina menggunakan parameter
masa tunda τ = 7 dan matra pembenaman m = 4 yang masing-masing
diperoleh daripada kaedah maklumat purata bersama dan kaedah Cao.
Hasil daripada gambarajah ruang fasa dan juga plot parameter kaedah
Cao mempamerkan bahawa data bersifat kalut. Melalui langkah 2, peramalan
satu jam ke hadapan selama sebulan siri masa PM10 dijalankan menggunakan
kaedah penghampiran setempat. Nilai pekali kolerasi antara data
ramalan dan data sebenar hanyalah 0.5692. Namun, graf perbandingan
menunjukkan bahawa data ramalan adalah hampir dengan data sebenar
dengan nilai ralat punca min kuasa dua peramalan adalah 7.6814.
Ini menunjukkan kesesuaian penggunaan kaedah penghampiran setempat
dalam meramal siri masa PM10 dan ia merupakan petanda
positif bahawa pendekatan kalut ini boleh diguna pakai ke atas siri
masa bahan pencemar di Malaysia.
Kata kunci: Kaedah penghampiran setempat; Malaysia; pendekatan
kalut; peramalan; PM10
ABSTRACT
Forecasting of PM10 concentration is important as breathing
air containing PM10 can lead to chronic diseases such as
cancer and bronchitis. This study is a pilot study using chaotic
approach to forecast PM10 in Malaysia. Studied data is a time series of
observed hourly PM10 at benchmark station located in the district
of Jerantut in Pahang state. Chaotic approach has two steps, namely
the phase space reconstruction and the forecasting process. Through
step 1, multi-dimensional phase space is reconstructed using the
parameters of the delay time τ = 7 and embedding dimension
m = 4, respectively, derived from the average mutual information
and Cao method. The results from the phase space diagram and parameter
plot of Cao method demonstrates that the data are chaotic. Through
step 2, 1 h ahead forecasting for a month PM10 time series is carried
out using the local approximation method. Correlation coefficient
value between the actual and forecasted data is only 0.5692. However,
comparison graphs show that forecasted data are close to the actual
data with root mean square error value 7.6814. This demonstrates
the suitability of the local approximation method to forecast the
time series of PM10 and it's a positive sign
that this chaotic approach is applicable to the time series of pollutants
in Malaysia.
Keywords: Chaotic approach; forecast; local
approximation method; Malaysia; PM10
REFERENCES
Abarbanel, H.D.I. 1996. Analysis of Observed Chaotic Data.
New York: Springer-Verlag, Inc.
Afroz, R., Hassan, M.N. & Ibrahim, N.A. 2003. Review of
air pollution and health impacts in Malaysia. Environmental Research 92(2):
71-77.
Awang, M., Jaafar, A.B., Abdullah, A.M., Ismail, M., Hassan,
M.N., Abdullah, R., Johan, S. & Noor, H. 2000. Air quality in Malaysia:
Impacts, management issues and future challenges. Respirology 5:
183-196.
Cao, L. 1997. Practical method for determining the minimum
embedding dimension of a scalar time series. Physica D 110: 43-50.
Chelani, A.B. & Devotta, S. 2006. Nonlinear analysis and
prediction of coarse particulate matter concentration in ambient air. Journal
Air and Waste Management Association 56: 78-84.
Chelani, A.B. & Devotta, S. 2007. Prediction of ambient
carbon monoxide concentration using nonlinear time series analysis technique. Transportation
Research Part D 12: 596-600.
Chelani, A.B. 2010. Nonlinear dynamical analysis of ground
level ozone concentrations at different temporal scales. Atmospheric
Environment 44: 4318-4324.
Chen, J., Islam, S. & Biswas, P. 1998. Nonlinear
dynamics of hourly O3 concentration:
Nonparametric short term prediction. Atmospheric Environment 32 (11):
1839-1848.
Dominick, D., Latif, M.T., Juahir, H., Aris, A.Z. &
Zain, S.M. 2012. An assessment of influence of meteorological factors on PM10 and NO2 at
selected stations in Malaysia. Sustainable Environment Research 22(5):
305-315.
Farmer, J.D. & Sidorowich, J.J. 1987. Predicting chaotic
time series. Physical Review Letters 59(8): 845-848.
Gueyan, D. & Leroux, J. 2008. Forecasting chaotic
systems: The role of Lyapunov Exponents. Chaos, Solitons and Fractal 41(5):
2401-2404.
Hamid, N.Z.A. & Noorani, M.S.M. 2013. Modeling of
prediction system: An application of the nearest neighbor approach to chaotic
data. Applied Mathematics and Computational Intelligence 2(1): 137-148.
Jabatan Alam Sekitar Malaysia, 2013. www.doe.gov.my. Diakses
pada 1 April 2013.
Juneng, L., Latif, M.T. & Tangang, F. 2011. Factors
influencing the variations of PM10 aerosol
dust in Klang Valley, Malaysia during the summer. Atmospheric Environment 45:
4370-4378.
Khatibi, R., Sivakumar, B., Ghorbani, M.A., Kisi, O., Kocak,
K. & Zadeh, D.F. 2012. Investigating chaos in river stage and discharge
time series. Journal of Hydrology 414-415: 108-117.
Khokhlov, V.N., Glushkov, A.V., Loboda, N.S. &
Bunyakova, Y.Y. 2008. Short-range predict of atmospheric pollutants using
nonlinear prediction method. Atmospheric Environment 42: 7284-7292.
Kocak, K., Saylan, L. & Sen, O. 2000. Nonlinear time
series prediction of O3 concentration
in Istanbul. Atmospheric Environment 34: 1267-1271.
Martuzzi, M., Mitis, F., Iavarone, I. & Serinelli, M.
2006. Health Impact of PM10 and Ozone in 13
Italian Cities. Denmark: World Health Organization Regional Office for
Europe.
Meng, Q. & Peng, Y. 2007. A new local linear prediction model
for chaotic time series. Physics Letters A 370: 465-470.
Radhakrishnan, P. & Dinesh, S. 2006. An alternative
approach to characterize time series data: Case study on Malaysian rainfall
data. Chaos, Solitons and Fractals 27: 511-518.
Regonda, S.K., Rajagopalan, B., Lali, U., Clark, M. &
Moon, Y.I. 2005. Local polynomial method for ensemble predict of time series. Nonlinear
Process in Geophysics 12: 397-406.
Ruhm, K.H. 2008. Deterministic, Nondeterministic Signals.
Institute for Dynamic Systems and Control, Zurich, Switzerland.
Sivakumar, B., Liong, S., Liaw, C. & Phoon, K. 1999.
Singapore rainfall behavior: Chaotic? Journal of Hydrologic Engineering January
1999: 38-48.
Sivakumar, B. 2002. A phase-space reconstruction approach to
prediction of suspended sediment concentration in rivers. Journal of
Hydrology 258: 149-162.
Ul-Saufie, A.Z., Yahaya, A.S., Ramli, N.A. & Hamid, H.A.
2011. Comparison between multiple linear regression and feed forward back
propagation neural network models for predicting PM10 concentration level based on gaseous and
meteorological parameters. International Journal of Applied Science and
Technology 1(4): 42-49.
Ul-Saufie, A.Z., Yahaya, A.S., Ramli, N.A. & Hamid, H.A.
2012. Performance of multiple linear regression model for long-term PM10 concentration prediction
based on gaseous and meteorological parameters. Journal of Applied Sciences 12(14):
1488-1494.
Velickov,
S. 2004. Nonlinear Dynamics and Chaos. Taylor & Francis Group plc.,
London.
*Corresponding author; email: nor_zila@yahoo.com
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