Satellite-Based Approach for Multi-temporal PM10 Analysis Over Malaysia

Asmala Ahmad, Mazlan Hashim, M. Nizam Ayof, Agus Setyo Budi

ICOQSIA 2005, 6 8 December, Penang, Malaysia.

SATELLITE-BASED APPROACH FOR MULTI-TEMPORAL

PM10 ANALYSIS OVER MALAYSIA

ASMALA AHMAD, MAZLAN HASHIM, M. NIZAM AYOF, AGUS SETYO BUDI

Dept. of Science and Mathematics, Centre of Academic Services (CAS), National Technical University, College of Malaysia (KUTKM), Locked Bag 1200, Ayer Keroh, 75450 Malacca, Malaysia

asmala@kutkm.edu.myDept. of Remote Sensing, Faculty of Geoinformation Science and Engineering, Universiti Teknologi Malaysia (UTM),

Locked Bag 791, 80990 Johor Bahru,Malaysia.

mazlan@fksg.utm.myDept. of Science and Mathematics, Centre of Academic Services (CAS), National Technical University, College of Malaysia (KUTKM), Locked Bag 1200, Ayer Keroh, 75450 Malacca, Malaysia

Dept. of Science and Mathematics, Centre of Academic Services (CAS), National Technical University, College of Malaysia (KUTKM), Locked Bag 1200, Ayer Keroh, 75450 Malacca, Malaysia

Abstract: This study aims to analyse one of the haze major constituent, particulate matter sizing less than 10 micron (PM 10) from space-borne platform. Seven dates of NOAA-14 AVHRR satellite were successfully recorded for this purpose. These remotely sensed data represented the seven days during the September 1997 thick haze episode in Malaysia. Five locations of air pollution station were selected where PM10 has been measured. Visible (0.58 - 0.68 (m) and Near Infrared (0.725 - 1.00 (m) of AVHRR band was utilised for this purpose. Relationship between the satellite reflectance and the corresponding PM 10 ground measured API was determined using regression analysis. Variation of PM 10 concentration for seven days was then analysed using the obtained model. Finally, accuracy of the result was assessed using RMSE technique. The result proven that remote sensing technique using NOAA-14 AVHRR data was capable of quantifying PM 10 concentration spatially and continuously. Complementarily, DMSP and Earth Probe TOMS satellite data were also used as comparison.

Keywords: Haze, PM 10, API, NOAA-14 AVHRR, regression

1. Introduction

In recent times, reduced visibility has become a recurrent phenomenon across areas of Southeast Asia, resulting from biomass burning in Kalimantan and Sumatra. Haze events have been recorded in 1983, 1990, 1991, 1994, 1997 and 1998 (Radojevic and Hassan 1999, Muraleedharan et al. 2000). Koe et al. (2001) noted that reduced visibility in Malaysia during the 1997 haze episode was the result of long range transport of smoke from Sumatra. Haze from biomass burning contains large amount of trace gases (e.g., CO, NO2, SO2) and particles matter (e.g., organic matter, graphitic carbon), which are hazardous to health. Lung and eye deceases have been identified as the common immediate effect of haze. In long term, haze is capable of increasing the atmospheric greenhouse effects besides affecting the tropospheric chemistry. In big cities, emission from industrial and vehicle have acted as local contributors that worsen the situation.

Main constrains over conventional monitoring instruments are that they could not detect an early sign of haze and is impractical for large areas or for continuous monitoring. Besides that they are also logistically expensive and time consuming. The 1997 haze events prompt the need for searching of an alternative method for determining and monitoring haze in Malaysia.

Remote sensing offers a cheap, fast and more reliable alternative to monitor haze continuously over any given areas and at any time. The current study is an extension of previous work that earlier discussed on techniques for determination and mapping of haze from NOAA-14 AVHRR scene (Asmala and Mazlan, 1997, 2000, 2002).

2. Materials

Materials used in this study are as follows:

2.1 Ground-truth data

Conventional measurements of haze were complementarily used throughout performing multi-temporal analysis of haze. API (Air Pollution Index) measurements for PM 10 from 1st to 30th September 1997 area were obtained from ASMA (Alam Sekitar Malaysia Sdn. Bhd.) to represent the actual haze intensity over the study area the Peninsular Malaysia (Figure 1).

Figure 1 : (a) Study area, and (b) Combination of band 1 (0.58 - 0.68 (m), 2 (0.725 - 1.00 (m) and 4 (10.30 - 11.30 (m) of NOAA-14 AVHRR data dated 22 September 1997, were used to differentiate between haze (orange), low clouds (yellow) and high clouds (white).

2.2 Satellite data

Seven sets of NOAA-14 AVHRR data dated 22, 23, 25, 2, 28, 29 and 30 September 1997 acquired from SEAFDEC (Southeast Asia Fishery Development Centre) receiving station were used. NOAA-14 AVHRR was suitable for haze study as it offers high spectral and temporal resolution with a minimum cost. Some useful characteristics of NOAA-14 AVHRR satellite are shown in Table 1.

2.3 Ancillary data

Meteorological information over study area, including visibility, air temperature, pressure, relative humidity, wind, etc were obtained from MMS (Malaysian Meteorological Service).

Table 1: NOAA-14 AVHRR sensor and spectral characteristics

AVHRR Sensor characteristics

Swath width

2399km

Resolution at nadir

1.1km approx.

Altitude

833km

Quantisation

10 bit

Orbit type

Sun synchronous

No. of orbits per day

14.1 (approx.)

AVHRR Spectral characteristics

Channel No

Wavelength (microns)

Typical use

1

0.58 - 0.68

Daytime cloud and surface mapping

2

0.725 - 1.00

Land-water boundaries

3

3.55 - 3.93

Night cloud mapping, sea surface temperature

3A

N/A

Snow and ice detection

3B

N/A

Night cloud mapping, sea surface temperature

4

10.30 - 11.30

Night cloud mapping, sea surface temperature

5

11.50 - 12.50

Sea surface temperature

(Source: Kidwell et al., 1995)

3. Method

Four modules incorporated in this study are (a) Derivation of haze model, (b) Sampling and Regression analysis, (c) Multi-temporal analysis, and (d) Visual analysis from other satellite data.

3.1 Derivation of haze model

Prior to further data processing, post launch calibration of visible and near infrared channel was earlier implemented in order to compensate data degradation due to extreme temperature change before and after launching of AVHRR sensor to space (Rao et al., 1996). Clouds and haze were successfully differentiated using thresholding technique (Baum et al., 1997). This to ensure both were not being misinterpreted between each other. Model used in this study is based on Siegenthaler and Baumgartner (1996), which make use of skylight to indicate the existence of haze. Skylight is an indirect radiation, which occurs when radiation from the sun being scattered by elements within the haze layer. It is not a direct radiation, which is dominated by pixels on the earth surface. Figure 2 shows electromagnetic radiation path propagating from the sun towards the NOAA-14 AVHRR satellite penetrating through a haze layer. Path number 1, 3 and 4 are skylight caused by direct radiation, whereas path 2 is indirect radiation.

(Source : Modified after Siegenthaler and Baumgartner, 1996)

Figure 2 : Model used in this study is based on the skylight parameter

This model can be described by:

( - R = L V

(1)

where,( :reflectance recorded by satellite sensor,

R:reflectance from known object from earth surface ,

L:skylight, and

V:lost radiation caused by scattering and absorption.

3.2 Sampling and regression analysis

From the NOAA-14 AVHRR data, calibration pixels were sampled within a radius of 2.5 km from each of the air pollution stations in order to execute regression analysis. The best regression models for PM10 is shown below where the R2 (coefficient of determination) obtained is 0.5098 (Figure 3).

Figure 3 : Regression model for PM 10

3.3 Multi-temporal analysis

Multi-temporal analysis was performed at two selected cities, Prai Station in Penang and Pasir Gudang Station (Figure 4) in Johor. Results of the analysis were shown as graphs of haze intensity variation (API vs time) for all the five major components throughout the seven NOAA-14 AVHRR acquisition dates (Figure 6). Root-mean-square error (RMSE) analysis was carried out where ground-truth measured API and model derived API were used as input. Obtained RMSE both cities are shown in Table 2.

(2)

where:

n

:sample size,

APIcalculated:Air Pollution Index calculated by model

APImeasured:Air Pollution Index measured by air station

3.4 Visual analysis from other satellite data

Visually, the scenario was also observed from other satellite data such as DMSP (Defence Meteorological Satellite Program) satellite (Figure 7) and Earth Probe TOMS (Total Ozone Mapping Spectrometer) satellite (Figure 8).

4. Results and Discussion

Result of this study was presented as PM 10 concentration map for the whole Peninsular Malaysia. PM 10 condition for 26 September 1997, 7.29 GMT is shown in Figure 5. RMSE for selected big cities; Prai and Pasir Gudang are 31 and 27 respectively. It was believed that the relatively high gained RMSE was due to limited number of air pollution stations used. Future study will consider of using more air pollution stations as well as higher resolution satellite data in order to obtain better accuracy.

Table 2 : RMSE for PM 10 concentration at Penang and Johor Bahru

LocationPM10 (API)

Prai, Penang31

Pasir Gudang, Johor Bahru27

5. Conclusion

The study shows that remote sensing technique is capable of monitoring and quantifying PM 10 concentration continuously with minimum cost and time. These are useful in order to provide haze early warnings, so that necessary measures could be taken effectively by both government authorised party as well as public.

(a)

(b)

Figure 4 : Multitemporal trend of calculated and measured PM 10 at (a) Prai, Penang, and (b) Pasir Gudang, Johor.

PM10(API)

0 (Awan)

151-200

1-50 201-250

51-100

251-300

101-150

Figure 5 : PM 10 concentration map of Peninsular Malaysia for 26 September 1997, 7.29 GMT

Figure 6 : Haze visual analysis from band 1, 2 and 4 of NOAA-14 AVHRR satellite data for March 1997 (a)22nd, (b)23rd, (c)25th, (d)26th, (e)28th, (f)29th and (g)30th .

Landcover Water StableFire CloudBoundary N/A

(Source : National Geophysical Data Center, NOAA, USA)

Figure 7 : Haze visual analysis from DMSP satellite data for March 1997 (a)22nd, (b)23rd, (c)25th, (d)26th, (e)28th, (f)29th and (g)30th .

(Source: Goddard Space Flight Center, USA)

Figure 8 : Haze visual analysis from Earth Probe TOMS satellite data for March 1997 (a)22nd, (b) 23rd, (c)26th, (d)28th, (e)29th and (f)30th .

References

Alam Sekitar Malaysia Sd. Bhd. (1998). Measurement of Air Pollution Index (API). ASMA: Unpublished.

Asmala Ahmad and Mazlan Hashim (2002). Determination of Haze Using NOAA-14 Satellite Data. Proceedings on The 23rd Asian Conference on Remote Sensing 2002 in Kathmandu, Nepal, 25-29 November 2002.

Asmala Ahmad, and Mazlan Hashim, (1997). Determination of Haze from Satellite Remotely Sensed Data : Some Preliminary Results. Proceedings on The 18th Asian Conference on Remote Sensing 1997 at Nikko Hotel, Kuala Lumpur.

Asmala Ahmad, and Mazlan Hashim, (2000). Determination of Haze Air Pollution Index from Forest Fire Emission during the 1997 Thick Haze Episode in Malaysia using NOAA AVHRR Data. Malaysian Journal of Remote Sensing & GIS. 1 : 77-84.

Baum, B.A. (1997). Discrimination between clouds and smoke/fires in daytime AVHRR data. NASA Langley Research Center Atmospheric Sciences Division Radiation Sciences Branch Homepage [Online] Available, http://asd-www.larc.nasa.gov/~baum/Pathfinder/smoke.htmlDefense Meteorological Satellite Programme (DMSP) Website, http://dmsp.ngdc.noaa.gov/dmsp.htmlEarth Probe TOMS Website, http://toms.gsfc.nasa.gov/eptoms/ep.htmlKidwell, K. B., comp. and ed., 1995, NOAA-14 Polar Orbiter Data (TIROS-N, NOAA-14-6, NOAA-14-7, NOAA-14-8, NOAA-14-9, NOAA-14-10, NOAA-14-11, NOAA-14-12, and NOAA-14) Users Guide: Washington, D.C., NOAA-14/NESDIS.

Koe, L. C. C, Arellano, A. F, and McGregor, J. L. (2001). Investigating the haze transport from 1997 biomass burning in Southeast Asia: its impact on Singapore. Atmospheric Environment 35, 27232734,.

Malaysian Meteorological Service (1997a). : Upper Air Data for September 1997. Kuala Lumpur : MMS.

Malaysian Meteorological Service (1997b). : Visibility for September 1997. Kuala Lumpur : MMS.

Muraleedharan, T. R., Rajojevic, M., Waugh, A., and Caruana, A.: Chemical characteristics of haze in Brunei Darussalam during the 1998 episode. Atmospheric Environment 34, 27252731, 2000.

Rao, C.R.N. and Chen, J. (1996), Post-launch calibration of the visible and near-infrared channels of the Advanced Very High Resolution Radiometer on the NOAA-14 spacecraft International Journal of Remote Sensing, 17, 2743-2747.

Radojevic, M. and Hassan, H. (1999). Air quality in Brunei Darussalam during the 1998 haze episode. Atmospheric Environment 33, 35613568.

Siegenthaler, R., and Baumgartner, M.F. (1996). Haze and Miss Phenomena in the Swiss Lowlands Analysed with Spaceborne (NOAA-14 AVHRR) and Airborne (Imaging Spectrometry) Data in Parlow, E. Progress in Environmental Remote Sensing Research and Application. 453-459.

Station

A.

Kuala Lumpur, Wilayah

P

ersekutuan

B

.

Prai,

Penang

C

.

Pasir

Gudang

,

Johor

D.

Bukit

Rambai

,

Melaka

E

.

Bukit

Kuang

,

Terengganu

(a)

(b)

Measurement from station

Calculated from model

Measurement from station

Calculated from model

(a)

(b)

(c)

(d)

(e)

(f)

(g)

(g)

(f)

(e)

(d)

(c)

(b)

(a)

EMBED Excel.Sheet.8

27

_1034474970.bin

_1192027107.unknown

_1192026187.xlsPM10_Chart

260

260

260

260

260

260

260

260

260

260

260

260

260

113

113

113

113

113

113

113

113

113

113

113

113

113

56

56

56

56

56

56

56

56

56

56

56

56

56

118

118

118

118

118

118

118

118

118

118

118

118

118

82

82

82

82

82

82

82

82

82

82

82

82

82

146

146

146

146

146

146

146

146

146

146

146

146

146

118

118

118

118

118

118

118

118

118

118

118

118

118

63

63

63

63

63

63

63

63

63

63

63

63

63

46

46

46

46

46

46

46

46

46

46

46

46

46

70

70

70

70

70

70

70

70

70

70

70

70

70

199

199

199

199

199

199

199

199

199

199

199

199

199

124

124

124

124

124

124

124

124

124

124

124

124

124

120

120

120

120

120

120

120

120

120

120

120

120

120

194

194

194

194

194

194

194

194

194

194

194

194

194

131

131

131

131

131

131

131

131

131

131

131

131

131

231

231

231

231

231

231

231

231

231

231

231

231

231

186

186

186

186

186

186

186

186

186

186

186

186

186

80

80

80

80

80

80

80

80

80

80

80

80

80

142

142

142

142

142

142

142

142

142

142

142

142

142

169

169

169

169

169

169

169

169

169

169

169

169

169

153

153

153

153

153

153

153

153

153

153

153

153

153

140

140

140

140

140

140

140

140

140

140

140

140

140

124

124

124

124

124

124

124

124

124

124

124

124

124

160

160

160

160

160

160

160

160

160

160

160

160

160

97

97

97

97

97

97

97

97

97

97

97

97

97

100

100

100

100

100

100

100

100

100

100

100

100

100

98

98

98

98

98

98

98

98

98

98

98

98

98

88

88

88

88

88

88

88

88

88

88

88

88

88

109

110

111

112

113

114

115

116

117

118

119

120

121

64

64

64

64

64

64

64

64

64

64

64

64

64

85

85

85

85

85

85

85

85

85

85

85

85

85

55

55

55

55

55

55

55

55

55

55

55

55

55

61

61

61

61

61

61

61

61

61

61

61

61

61

49

49

49

49

49

49

49

49

49

49

49

49

49

44

44

44

44

44

44

44

44

44

44

44

44

44

pm10

Band 1 (Reflectance)

PM10 (API)

PM10 VS Band 1

PM10 = -0.2410*(Band 1)2+0.007*(Band 1)3+108.3328R2 = 0.5098

pm10_new

Jalur 1Jalur 2pm10

4035260

4336260

4236260

4135260

4236260

4135260

4337260

4034260

4034260

4337260

4135260

4434260

4135260

3836113

3634113

3735113

3735113

3836113

3634113

3836113

3634113

3533113

3937113

3735113

3933113

3735113

312756

332956

322856

322856

332856

312756

332956

312756

302656

343056

322856

342656

322756

4030118

3828118

3929118

3929118

4030118

3828118

4030118

3828118

3727118

4131118

3929118

4127118

3928118

282582

292782

292682

282682

292782

282582

302782

272582

272482

302882

292682

312482

282582

3230146

3432146

3331146

3331146

3432146

3230146

3432146

3230146

3129146

3533146

3230146

3230146

3531146

3228118

3126118

3228118

3127118

3228118

3127118

3329118

3026118

3026118

3329118

3026118

3026118

3327118

312963

323163

323163

313063

323163

313063

333263

302963

302963

333263

302963

302963

333063

353346

333246

343246

343246

353346

333146

353346

333146

323046

363446

333146

323146

363246

262170

272370

272370

262270

272370

262270

282470

252170

252170

282470

252170

252170

282270

3533199

3735199

3634199

3634199

3735199

3533199

3735199

3533199

3432199

3836199

3735199

3932199

4133199

3834124

3732124

3733124

3733124

3834124

3632124

3934124

3632124

3531124

3935124

4034124

3831124

3932124

3733120

3935120

3935120

3834120

3935120

3834120

4036120

3733120

3733120

4036120

3935120

4133120

4134120

4032194

3831194

3932194

3931194

4032194

3831194

4033194

3830194

3730194

4133194

4232194

4030194

4131194

3630131

3832131

3731131

3731131

3832131

3630131

3832131

3630131

3529131

3933131

3832131

4030131

3931131

4037231

4238231

4138231

3937231

4238231

3937231

4239231

3836231

3936231

4139231

4136231

4340231

4137231

4236186

4134186

4236186

4235186

4236186

4135186

4337186

4134186

4034186

4437186

4132186

4336186

4135186

322780

342980

342880

322880

342880

322780

342980

312780

312680

343080

332780

353080

332780

3633142

3332142

3533142

3532142

3533142

3532142

3634142

3431142

3331142

3834142

3430142

3634142

3432142

3233169

3435169

3434169

3234169

3435169

3233169

3535169

3133169

3232169

3436169

3333169

3537169

3333169

3434153

3635153

3535153

3534153

3635153

3434153

3636153

3333153

3333153

3636153

3634153

3533153

3334153

3331140

3229140

3330140

3330140

3231140

3329140

3431140

3229140

3128140

3132140

3427140

3028140

3129140

3230124

3431124

3431124

3330124

3431124

3330124

3532124

3129124

3229124

3532124

3430124

3329124

3130124

4134160

3933160

4133160

4133160

3934160

4132160

4234160

4032160

3931160

4035160

4231160

3832160

3933160

322797

342997

342897

332897

332997

322797

342997

312797

312697

343097

342797

322697

312797

3432100

3634100

3533100

3533100

3634100

3432100

3634100

3332100

3331100

3635100

3632100

3432100

3632100

323298

313098

323198

323198

313298

323098

333298

313098

302998

303398

303098

333098

303198

272388

292588

292588

282488

292588

282488

302688

262388

272388

342688

292388

272388

352488

3429109

3228110

3329111

3328112

3229113

3428114

3430115

3327116

3127117

3230118

3227119

3527120

3228121

322964

333164

333064

323064

333164

322964

343164

302964

312864

333264

332964

312864

342964

323085

353185

343085

333085

343185

332985

353185

322985

352885

323285

323185

322985

353085

353155

332955

343055

343055

333155

352955

333155

352955

322855

363255

333155

322955

323055

293161

313361

303261

303261

313361

293161

313361

293161

353061

283461

293361

293161

363261

322949

302749

302849

312849

302949

312749

292949

322749

292649

333049

302949

292749

292849

302344

312644

312544

302444

312544

302444

322644

292344

322344

292644

292644

292344

322444

_935242903.doc