Detecting Slums from SPOT Data in Casablanca Morocco Using an Object Based Approach

doi:10.4236/jgis.2011.33018

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Journal of Geographic Information System, 2011, 3, 217-224

doi:10.4236/jgis.2011.33018 Published Online July 2011 (http://www.SciRP.org/journal/jgis)

Detecting Slums from SPOT Data in Casablanca Morocco

Using an Object Based Approach

Hassan Rhinane1*, Atika Hilali1, Aziza Berrada1, Mustapha Hakdaoui2

1Faculté des S ciences Aïn Chock , Université Hassan II-Casablanca, Casablanca, Maroc

2Faculté des Sciences Ben M’sik, Université Hassan II-Mohammedia-Casablanca, Casablanca, Maroc

E-mail: h.rhinane@gmail.com, a.hilali@fsac.ac.ma, berrada_a zi za@yahoo.fr , hakdaoui@gm ail.com

Received April 2, 2011; revised May 23, 2011; accepted June 5, 2011

Abstract

Casablanca, Morocco’s economic capital continues today to fight against the proliferation of informal settle-

ments affecting its urban fabric illustrated especially by the slums. Actually Casablanca represents 25% of

the total slums of Morocco [1]. These are the habitats of all deprived of healthy sanitary conditions and

judged precarious from the perspective humanitarian and below the acceptable. The majority of the inhabi-

tants of these slums are from the rural exodus with insufficient income to meet the basic needs of daily life.

Faced with this situation and to eradicate these habitats, the Moroccan government has launched since 2004

an entire program to create cities without slums (C.W.S.) to resettle or relocate families. Indeed the process

control and monitoring of this program requires first identifying and detecting spatial habitats. To achieve

these tasks, conventional methods such as information gathering, mapping, use of databases and statistics

often have shown their limits and are sometimes outdated. It is within this framework and that of the great

German Morocco project “Urban agriculture as an integrative factor of development that fits our project de-

tection of slums in Casablanca. The use of satellite imagery, particularly the HSR, has the advantage of

providing the physical coverage of urban land but it raises the difficulty of choosing the appropriate method

to apply.This paper is actually to develop new approaches based mainly on object-oriented classification of

high spatial resolution satellite images for the detection of slums.This approach has been developed for

mapping the urban land through by integration of several types of information (spectral, spatial, contextual ...)

(Hofmann, P ., 2001, Herold et al. 2002b; Van Der Sande et al., 2003, Benz et al., 2004, Nobrega et al.,

2006). In order to refine the result of classification, we applied mathematical morphology and in particular

the closing filter. The data from this classification (binary image), which then will be used in a spatial data-

base (ArcGIS).

Keywords: Slums, Urban Remote Sensing, SPOT 5, Object Based Image Analysis, ArcGis

1. Introduction

The study by the World Bank [1] showed that Casa-

blanca has the largest population of slums with approxi-

mately 45,000 households located in 270 nuclei, or a

quarter of the total national population of urban slums.

This type of habitat is populated by the most impove-

rished social strata, not complying with the Building

Standards (illegal or non-regulatory), with a low or ab-

sent infrastructure and no security measure [2]. Often

these habitats are covered with recycled materials (sheets,

plastics, wood ...) and organized as clusters of strong

condensation of several informal settlements. Some

neighbourhoods such as Hay Mohammadi, Ben M’sik,

Sidi Moumen has always housed the largest concentra-

tions of slums and even wealth y neighbourho ods as Anfa,

Ain Diab, Racine, California have their own islands of

poverty so that it becomes excessive to conclude to a real

structure of spatial segregation [3]. View the restriction

of traditional methods employed (field visits/observation)

and the unknown dynamic of the metropolitan population

[4], the Moroccan government adopted in January 2005,

a new innovative approach to monitor and map the slums

through remote sensing (aerial photographs, satellite im-

agery ...) in some pilot cities.

Certainly, satellite imagery has shown several ad-

H. RHINANE ET AL.

218

vances in extraction of different urban entities providing

timely and accurate responses to the occupation of urban

land. However, very few studies have focused on map-

ping slums in urban areas [2,5-10] but their application

in urban North Africa today remains marginal or even

absent.

The objective of this work is to extract, identify and

map these slums in the city of Casablanca in 2004

through an object-oriented classification of a SPOT-5 at

2.5 m spatial resolution.

2. Material and Methods

2.1. Location of the Study

Morocco’s economic capital and one of the largest cities

in the continent, Casablanca is the largest city in Mo-

rocco with more than 3 million inhabitants with a total

area of 1,140.54 km2 [1] (Figure 1). Casablanca is

located on the Atlantic coast about 100 km south of the

administrative capital (Rabat). The Wilaya of Greater

Casablanca includes two prefectures (Mohammedia &

Casablanca) and two Provinces (Nouaceur or Nouasser

and Mediouna) for a total of 17 municipalities, 10 urban

and seven rural communities.

2.2. Available Data and Preprocessing

Satellite images become now an essential tool for plan-

ning and land development due to the frequency of shots

and the spatial resolution more and more efficient. The

launch of satellites with high spatial resolution (HSR),

such as SPOT-5 (2002) with 10 m spatial resolution

multi-spectral mode and 5 m spatial resolution in pan-

chromatic mode, allowed the extraction of different ur-

ban entities. The main data used in this work are:

 Image of SPOT-5 Casablanca taken March 16, 2004,

georeferenced, orthorectified and merged with 2.5 m

spatial resolution. This picture was taken during a

sunny month which helped the contrast between dif-

ferent urban entities. To improve the visual quality of

this picture we have carried image enhancement and

filtering operations (Figure 2).

 Cards Master of Urban Planning of the Wilaya of

Greater Casablanca provided by the Urban Agency of

Casablanca used to validate.

 Topographic map of the city of Casablanca, (NI-29-

sheet XI-3B) wide 1/50000 used for tracking in the

field and for areas difficult to access. The images of

Google Earth Server Map and Goog le Map have been

very useful.

The satellite data processing was performed on Erdas

Imagine then Envi Zoom. The classification results were

vectorized and exported to ArcGIS.

2.3. Methodological Approach

The study of the urban fabric has always interested

Figure 1. Geographical location of the city of Casablanca.

H. RHINANE ET AL.219

04 7002 350Me te rs

06345 Meters

Figure 2. (a) merged Image SPOT-5 of the city of Casablanca; (b) Overview of slums on image SOPT-5 of Casablanca.

several researchers in management and urban planning.

The use of satellite imagery has the advantage of pro-

viding the physical coverage of urban land but it raises

the difficulty of choosing the appropriate method to

apply. Several pattern recognition algorithms are used in

urban areas on images HSR: the urban morphology

[11-15], INDVI [16], the image thresholding [17], neural

networks [18,19], semi-automatic procedure [20], Digital

Elevation Model [21], yet the object - oriented approach

[22,23], the index of landscape [10], clustering and

geographic information system [24,25].

Choosing one method over another is not easy and

depends on data availability and purpose of the study. In

the context of detecting the slums, some studies have

used aerial photographs [7], others a semi automatic [20 ]

or supervised classification by maximum likelihood [10].

Also, urban space, by its very heterogeneous nature,

becomes more complex to study by the presence in soil

of many objects different by their shape, direction, size,

material depending on the type of habitat [2] and this in

addition to the constraints inherent to the pixel size (2.5

m) [10]. The combination of the texture will certainly

improve the quality of classification [26-28] and will

make easier the identification of the slums among other

objects with similarities and which can lead to confusion

in interpretation (built dense, unhealthy habitat, roof...).

Since decades, the approach classification “object -

oriented” has been developed for mapping the urban land

through the integration of several types of information

(spectral, spatial, contextual ...) [6,23,29-31] hence its

adoption for this project. Figure 3 illustrates the metho-

dology adopted in this work to map the slums of Casa-

blanca.

2.4. Object-Oriented Classification

The object-oriented classification in ENVI is an iterative

process carried out in two stages:

 Segmentation: sequence of several steps of segment-

Object-Oriented

Classification

Post classification

Acquisition of image SPOT-5

(16 mars 2004)

Multi-r es olut ion Se

mentation

Fusion of image (panchromatic)

Spatial resolution 2.5m

NI-29-sheet

XI-3B

SIG

Treatment

of spatial analysis

Map of slums

Map

SDAU-2004

Evaluation

Figure 3. Methodological flowchart.

H. RHINANE ET AL.

220

ing the image into regions.

 Supervised classification.

2.4.1. Segmentation

It consists to subdivide the image in the visible range, in

homogeneous regions, taking into account the spectral

parameters (mean, standard deviation index calculation),

space (size, shape) and contextual (spatial relationships

between regions) [32-35]. During this process, segments

are created by fusion of adjacent pixels forming sub

objects that will be gradually merged with their neigh-

bors to create objects of sizes larger and larger with

similar forms well distributed in the urban space accord-

ing to a scale parameter (or criterion of heterogeneity)

defined by the user. The objects thus created are linked

together by a hierarchical network representing the rea-

lity on the field [28-36] (Figure 4). This parameter, also

called “weight” determines the segmentation process and

therefore the size of the segmented objects. The higher

this parameter is, the higher the items are of larger size.

These parameters were set at 30 for level 1 and 93.3 for

level 2.

2.4.2. Classification of the Image SPOT-5

After segmentation, the second step is to group objects

and assign them a p robab ility or d egree of belon ging to a

given class from the robust rules of recognition of the

regions. Several knowledge rules can be combined to

define the classification rule of a given object, corre-

sponding to the method of “nearest neighbors”, or the

method of “membership functions (fuzzy logic) or a

mixture of two [37].

Supervised classification in ENVI Feature Extraction

is an iterative process from the “nearest neighbor”

algorithm based on K-nearest neighbor. The advantage

of the approach “nearest neighbor” is that classes are

Figure 4. Principle of multi-resolution segmentation modi-

fied of [38].

defined based on a variety of attributes spatial, spectral

and textural and is dependent on the choice of training

sites.

The choice of training sites was an important step in

the classification process adopted. These training sites

were chosen carefully for they are as representative as

possible of the class slums. However, due to the strong

heterogeneity of the urban environment and the com-

plexity of the obj ects to be extracted, the result of object-

oriented classification of SPOT-5 image shows the pre-

sence of bad pixels assigned to predefined themes giving

a salt-effect pepper.

Certainly, the best classification results are closely

related to the choice of training sites and in order to

define the different thematic classes we performed an

unsupervised classification based primarily on spectral

signatures. Roughly, two classes are distinct urban image

SPOT-5 (Frames, vegetation (dense and grass)). Thus a

wide range, the most representative samples were

collected for major urban classes (vegetation, built and

slums). The result of this classification is a binary image

(slums/No-slums).

2.4.3. Vali da ti on of th e Cl assification

The evaluation of a classification is a complex concept

that includes the reference to several criteria that can

occur in several stages [39]. The main idea is to deter-

mine the accuracy of this classification by comparing the

results with data provided from the reality in the field.

These realities comes from Master Plan (Department of

Urban Planning of the Wilaya of Greater Casablanca [40]

provided by the urban agency in Casablanca and physical

verification.

In general, the classification evaluation is done by

calculating two indices from the confusion matrix: over-

all accuracy and Kappa index. The Kappa index indicates

how to classify the data agree with reference data [41,42]

Given that the main theme of this study focuses on one

topic or class slums, the evaluation of this classification

will be calculated manually empirically using the ge-

ographic information system (ArcGIS) and this by

calculating commission and omissions errors on this

class.

3. Results and Discussions

The choice of training sites was an important step in the

classification process adopted. These training sites were

chosen carefully for they are as representative as possible

of the class slums. However, due to the strong heteroge-

neity of the urban environment and the complexity of the

objects to be extracted, the result of object-oriented clas-

sification of SPOT-5 image shows the presence of bad

H. RHINANE ET AL.221

pixels assigned to predefined themes giving a salt-effect

pepper. The result of the classification (binary image) is

then exported to ArcGIS, mapping of slums in the city o f

Casablanca is achieved.

In order to remove misclassified pixels and to refine

the result of classification, we applied mathematical mor-

phology and in particular the closing (succession of dila-

tion and erosion). The tests showed that the window of

the structuring element for better results is that of 9 * 9

(Figure 5).

After the classification and the passage of the filter

(closing), evaluation of results was done according to

quantitative (number of slums correctly present in the

SDAU, 2004; errors of commission and omission) and

qualitative methods (fo rm, difference between slums and

informal settlement...). The overlay map slums (SDAU)

in 2004, provided by the urban agency in Casablanca, on

the map after the object-oriented classification of the

SPOT-5 shows that 64 of 75 slums have been properly

classified and 29 items were incorrectly assigned to this

class. Thus, the commission error is 29 * 100/93 = 31%

and omission error is 11 * 100/64 = 17%, precision user

(Pu) is 64 * 100/93 = 69% and the accuracy of producer

(Pi) is 64 * 100/75 = 85%. We assume that the precision

obtained through the classification of object-oriented

image SPOT-5 is quite high.

Knowing the heterogeneity and complexity of the

spectral coverage of urban land, and for the spatial

resolution of the image used, some objects appear to

have similarities (show and textural) with slums which

implies their assignment to this class. Analysis of urban

objects committed to the class slums shows some visual

similarity between them because of their shape and their

spectral signature (Figures 6 and 7) these objects are

either slums, densely built or in some cases bare soil.

On slums that were omitted from the classification are

primarily small sizes averaging 3800 m2 or 240 pixels,

Figure 5. Image SPOT-5 classified.

02145 Meters

Figure 6. Section of the SPOT-5 image of the city of Casa-

blanca showing habitats unhealthy (white) assigned to the

class of slum.

Figure 7. Section of the SPOT-5 in the Casablanca slums

showing (red) unclassified.

these clusters are isolated rather than clustered buildings.

Also, these slums have different spectral responses from

those of all slums and who were chosen as training site

(Figure 8).

4. Conclusions

Through this study, we demonstrated the importance of

using satellite images with high spatial resolution

SPOT-5 in particular the id entification and quan tification

of these slums in the city of Casablanca. We also showed

that object-oriented classification approach has proven

remarkably effective for the extraction of slums (85%).

This result is satisfactory and fulfills ou r stated obj ectiv e.

It also confirms the relevance of the image to SPOT5 2.5

m spatial resolution to discriminate the class slums pre-

H. RHINANE ET AL.

222

(a)

(b)

Figure 8. Sections of the SPOT-5 wi th slums unc lassifie d.

ssent in a heterogeneous environment such as urban

areas.

Even if the result obtained using the “feature extrac-

tion” ENVI Zoom gives reliable results, but it never-

theless remains limited. This limitation is due to the fact

that some urban classes with a high spectral and textural

similarity may be confused and will diminish the quality

of the classification where the complexity of extracting

the urban class.

This research may provide a basis for more advanced

work on the implementation of a map of urban settlement

where we can distinguish between different urban en-

tities. Thus, the map after this classification will be used

as a basis for establishing a spatial vector database of the

slums of the city of Casablanca. Another approach based

on an analysis of the diachronic evolution of the class of

slums can also be the subject of new research or even an

estimate of the urban slum [43].To do so would require

several images taken at different times as this will also

identify the slums but also to assess the rate of pro-

gression and use of satellite images of higher resolution

will be an asset (eg IKONOS 1m spatial resolution).

5. References

[1] Banque mondial, “Rapport de L’Analyse D’lmpact Social

et Sur la Pauvreté,” 2006, p. 62.

[2] K. Busgeeth, J. Whisken and A. Brits, “Potential Appli-

cation of Remote Sensing in Monitoring Informal Settle-

ments in Developing Countries Where Complimentary

Data Does Not Exist,” Planning Africa Conference—

Shaping the Future, Johannesburg, 4-16 April 2008, pp.

314-328.

[3] M. Laoudi, “Casablanca a travers ses petits entrepreneurs

de lapauvrté. Apprécu sur les micro-activités marchande s

de rue dans une métropole maghrébine. Série thèse et

mémoire N 8. Université Hassan II Aîn Chock, Faculté

des lettres et sciences humaines Casablanca, 2001, p. 319,

320.

[4] S. Gadal, “Urbanisation et Dynamiques de Peuplements:

Casablanca, 1994-2002, UMR 63 IRD-UVSQ,” Ver-

sailles Saint-Quentin-en-Yvelines University, Ver- sailles,

2005.

[5] S. Mason, C. Fraser, “Image Sources For Informal

Settlement Management,” Photogrammetric Record, Vol.

16, No. 92, 1998, pp. 313-330.

[6] P. Hofmann, “Detecting Informal Settlements from IK-

ONOS Image Data Using Methods of Object Oriented

Image Analysis: An Example from Cape Town, South

Africa,” In: C. Jrgens, Ed., Remote Sensing of Urban Ar-

eas, Regensburger Geographische Schriften, Regensburg,

2001, pp. 107-118.

[7] P. Hurskainen and P. Pellikka, “Change Detection Of

Informal Settlements Using Multi-Temporal Aerial Pho-

tographs—The Case of Voi, SE-Kenya,” Proceedings of

the 5th AARSE Conference, 18-21 October 2004, Nairobi,

pp. .

[8] T. Lemma, “A Comparison of Methodologies for Moni-

toring Slum Conditions within Millennium Development

Goals, the Case Study of Addis ababa, Ethiopia, Thesis

for Master,” International Institute for Geo-information

Scinces and Eart h Observation, Ensch de, 2005.

[9] P. Hofmann, J. Strobl, T. Blaschke and H. Kux, “Detect-

ing Informal Settlements from Quickbird Data in Rio de

Janeiro Using an Object Based Approach,” Accessed 25

September 2007.

[10] G. Skupinski, D. BinhTran and C. Weber, (2009).

“Lesimages Satellites Spot Multi-Dates et la Métrique

Spatiale dans L’etude du Changement Urbain Et

Suburbain—Le Cas de la Basse Vallée de la Bruche

(Bas-Rhin, France),” Cybergeo: European Journal of

Geography, Systèmes, Modélisation, Géostatistiques,

article 439, mis en ligne le 12 mars 2009, modifié le 03

juin 2009.

http://cybergeo.revues.org/index21995.html.

[11] W. K. Pratt, “Digital Image Processing,” Willey in-

ter-sciences, New York, 1978, p. 743. M. Robin, “La

télédétection,” Nathan, Paris, 1995, p. 318

[12] Y. Baudot, “Télédétection Aérospatiale et Analyse

Géographique de la Population des Villes dans les Pays

en Développement,” Thèse de doctorat, Université Catho-

H. RHINANE ET AL.223

lique de Louvain, Louvain-la-Neuve, 1994.

[13] P. Terrettaz “Délimitation des agglomérations et

segmentation urbaine à l’aide d’images satellites Spot

HRV,” Thèse de Doctorat, Université de Fribourg, Fri-

bourg, 1998.

[14] J. A. Benediktsson, M. Pe saresi and K. Amason, “Classi-

fication and Feature Extraction for Remote Sensing Im-

ages From Urban Areas Based on Morphological Trans-

formations,” IEEE Transactions on Geoscience and Re-

mote Sensing, Vol. 41, No. 9, 2003, pp. 1940-1949.

[15] D. Sheeren, S. Lefèvre and J. Weber, “La Morpho-

Logiemathématique Binaire Pour L’extraction Auto-

matique des Bâtiments dans les Images THRS,” Revue

Internationale de Géomatique, Vol. 17, No. 3-4, 2007, pp.

333-352.

[16] J. G. Masek, F. E. Lindsay and S. N. Goward, “Dynamics

of Urban Growth in the Washington D.C. Metropolitan

Area, 1973-1996, from Landsat Observations,” Interna-

tional Journal of Remote Sensing, Vol. 21, No. 18, 2000,

pp. 3473-3486. doi:10.1080/014311600750037507

[17] T. Fung, “An Assessment of TM Imagery for Land Cover

Change Detection,” IEEE Transactions on Geoscience

and Remote Sensing, Vol. 28, No. 4, 1990, pp. 681-684.

doi:10.1109/TGRS.1990.572980

[18] X. Chen, X. Li and J. Ma, “Urban Change Detection

Based on Self-Organizing Feature Map Neural Network,”

Proceedings of the IEEE International Symposium on

Geoscience and Remote Sensing, Vol. 5, 20-24 Septem-

ber 2004, pp. 3428-3431.

[19] P. Gamba, F. Dell’Acqua, “Increased Accuracy Multi-

band Urban Classification Using a Neuro-Fuzzy Classi-

fier,” International Journal of Remote Sensing, Vol. 24,

No. 4, 2003, pp. 827-834.

[20] M. Stasolla and P. Gamba, “Exploiting Spatial Patterns

For Informal Settlement Detection Inarid Environments

Using Optical Spaceborne Data,” International Archives

of Photogrammetry, Remote Sensing and Spatial Infor-

mation Sciences, Vol. 36, 2007, pp. .

[21] C. H. William, F. C. Williamand and K. Gyimah, “High-

Resolution Lidar-Based Landslide Hazard Mapping and

Modeling, UCSF Parnassus Campus, San Francisco,

USA,” Bulletin of Engineering Geology and the Envi-

ronment, Vol. 68, No. 2, 2009, pp. 263-276.

[22] V. Walter, “Object-Based Classification of Remote

Sensing Data for Change Detection,” ISPRS Journal of

Photogrammetry and Remote Sensing, Vol. 58, No. 3-4,

2004, pp. 225-238.

[23] U. C. Benz, P. Hofmann, G. Willhauck, I. Lingenfelder,

and M. Heynen, “Multi-Resolution, Object-Oriented

Fuzzy Analysis of Remote Sensing Data for GIS-ready

information,” ISPRS Journal of Photogrammetry and

Remote Sensing, Vol. 58, No. 3-4, January 2004, pp.

239-258.

[24] G. Sartori, G. Nembrini and F. Stauffer, “Monitoring of

Urban Growth of Informal Settlements and Population

Estimation from Aerial Photography and Satellite Imag-

ing,” 2002. Occasional paper-thirstycitiesinwar.com.

[25] J. Abbott, “The Use of GIS in Informal Settlement Up-

grading: Its Role and Impact on The Community and on

Local Government,” Habitat International, Vol. 27, No.

4, 2003, pp. 575-593.

doi:10.1016/S0197-3975(03)00006-7

[26] A. Michel and B. Lortic, “Typologies Urbaines Et

Télédétection Satellitaire: La Notion de Zones en Milieu

Urbain,” Espace Géographique (FRA), Vol. 21, No. 2,

1992, pp. 167-178.

[27] T. Bauer and K. Steinccocher, “Per_Parcel Land Classi-

fication in Urban Areas Applying a Rule-Based Tech-

nique,” GeoBIT/GIS, Vol. 6, 2001, pp. 24-27.

[28] A. Puissant and C. Weber, “Démarche Orientée

‘Objets-Attributs’ et Classification D'images THRS,”

Revue Française de Photogrammétrie et De Télé-

détection, Vol. 173-174, 2004, pp. 123-134.

[29] M. Herold, M. Gardner, B. Hadley and D. Roberts, 2002b.

“The Spectral Dimension in Urban Land Cover Mapping

from High-Resolution Optical Remote Sensing Data,”

Proceedings of the 3rd Symposium on Remote Sensing of

Urban Areas, June 2002, Istanbul, on CD Rom.

http://www.lavieeco.com/news/economie/Bidonvillesenc

ore-45-villes-a-traiter-d-ici-2012-17135.html (12/7/2010).

[30] C. J. Van Der Sande, S. M. De Jong, A. P. J. De Roo, “A

Segmentation and Classification Approach of IKONOS-2

Imagery for Land-Cover Mapping to Assist Flood Risk

and Flood Damage Assessment,” International Journal of

Applied Earth Observation and Geoinformation, Vol. 4.

No. 3, 2003, pp. S217-S229.

doi:10.1016/S0303-2434(03)00003-5

[31] R. A. A. Nobrega, C. G. O’Hara, J. A. Quintanilha, “De-

tecting Roads in Informal Settlements Surrounding, Sa-

opaulo City by Using Object_Based Classification,”

Proceedings of the 1st International Conference on Ob-

ject- Based Image Analysis, Salzburg, 2006, pp. .

[32] M. Baatz and A. Schäpe, “Multiresolution Segmentation

—An Optimization Approach for High Quality Multi-

Scale Image Segmentation,” Angewandte geographische

Informationsverarbeitung XII: Beiträge zum

AGIT-Symposium, Salzburg, 2000, pp. 12-23.

[33] J. Schieve, “Segmentation of High-Resolution Remotely

Sensed Data—Concepts, Applications and Problems,”

Symposium on Geospatial Theory, Processings and Ap-

plications, Ottawa, 2002.

[34] T. Esch, A. Roth, S. Dech, “Robust Approach Towards

an Automated Detection of Built-up Areas from High

Resolution Radar Imagery,” Proceedings of the ISPRS

WG VII/1 “Human Settlements and Impact Analysis” 3rd

International Symposium Remote Sensing and Data Fu-

sion Over Urban Areas and the 5th International Sympo-

sium Remote Sensing of Urban Areas. Tempe, 14-16

March 2005.

[35] A. Karsenty, Antunes, B. A-F, Centeno, J-Silva. (2007)

“Classification Orientée Objet de la Perméabilité des Sols

en Zone Urbaine a L’aide D’imagerie Très Haute

Résolution et de Données Laser Scanner à Curitiba

(Brésil)” Anais XIII Simpósio Brasileiro de

Sensoriamento Re moto, Florianópolis, INPE, p. 565-572

[36] E. Freauman, E. Wolf, “Segmentation of Very High Spa-

H. RHINANE ET AL.

224

tial Resolution Satellite Images in Urban Areas for Seg-

ments-Based Classification,” Proceedings of the 3rd In-

ternational Symposium Remote Sensing and Data Fusion

Over Urban Areas, Tempe, 2005, pp. .

[37] L. Sparfel, F. Gourmelon and I. Le Berre, “Approch

Orienté-Objet de L’occupation des Sols en Zone Co-

tière,” Revue Télédétection, Vol. 8, No. 4, 2008, pp.

237-256.

[38] G. Willhauck, “Comparison of Object Oriented Classifi-

cation Techniques and Standard Image Analysis for the

Use of Change Detection between SPOT Multispectral

Satellite Images and Aerial Photos,” International Ar-

chives of Photogrammetry and Remote Sensing, Vol. 33,

2000, pp. 214-221.

[39] R. Caloz and C. Collet, “Précis de Télédétection,” Traite-

ments numériques d’images de télédétection, Presses de

l’Université du Québec/AUPELF, Sainte Foy, Vol. 3,

2001.

[40] SDAU (2004) “Plan de développement stratégique et

Schéma Directeur d’Aménagement urbain de la Wilaya

du Grand Casablanca, Projet de diagnostic et Enjeux du

développeme n t , rapport N°3.

[41] R. G. Congalton “Eview of Assessing the Accuracy of

Classifications of Remotely Sensed Data,” Remote Sens-

ing of Environment, Vol. 37, 1991, pp. 35-46.

doi:10.1016/0034-4257(91)90048-B

[42] R.-G. Conglaton and K. Green, “Assessing the Accuracu

of Remotely Sensed Data: Principles and Practices,”

Lewis Publishers, New York, 1999.

[43] M. Aminipouri, “Objected-Oriented Analysis of very

High Resolution Orthophotos for Estimating the Popula-

tion of Slum Areas,” Case of Dar-Es-Salam, Tanzania,

2009.