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Geocarto International Volume 37, 2022 - Issue 26
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Review Article

Texture analysis approaches in modelling informal settlements: a review

D. Matariraa School of Agriculture, Earth and Environmental Science, University of KwaZulu-Natal, Pietermaritzburg, South AfricaCorrespondence[email protected]
,
O. Mutangab Department of Geography, Pietermaritzburg, South Africa
&
M. Naiduc Department of Humanities, School of Social Sciences, University of KwaZulu-Natal, Durban, South Africa
Pages 13451-13478 | Received 27 Sep 2021, Accepted 22 May 2022, Published online: 13 Jun 2022

References

  • Amorim LMDE, Barros Filho MNM, Cruz D. 2014. Urban texture and space configuration: An essay on integrating socio-spatial analytical techniques. Cities. 39:58–67.
  • Ansari RA, Buddhiraju KM, Bhattacharya A. 2019a. Textural classification of remotely sensed images using multiresolution techniques. Geocarto Intern. 35(14):1580–1602.
  • Ansari RA, Buddhiraju KM. 2019a. Textural segmentation of remotely sensed images using multiresolution analysis for slum area identification. European J Remote Sensing. 52(sup2):74–88.
  • Ansari RA, Buddhiraju KM. 2019c. Texture based identification of informal settlements in contourlet feature space. IEEE International Symbosium on Multimedia.
  • Ansari RA, Malhotra R, Buddhiraju KM. Texture based identification of informal settlements in contourlet feature space. Proceedings - 2019 IEEE International Symposium on Multimedia, ISM 2019, 2019b. p. 267–270.
  • Armi LS, Fekri-Ershad S. 2019. Texture image analysis and texture classification methods—a review. Intern Online J Image Processing Pattern Recog. 2:1–29.
  • Arribas-Bel D, Patino JE, Duque JC. 2017. Remote sensing-based measurement of living environment deprivation: improving classical approaches with machine learning. PLoS One. 12(5):e0176684.
  • Barros Filho M, Sobreira F. 2005. Assessing texture pattern in slum across scales an unsupervised approach. Centre for Advanced Spatial Analysis. Torrington Place, Gower St London, WC1E 7HB: University College London.
  • Barros Filho MN, Sobreira FJA. 2008. Accuracy of Lacunarity Algorithms InTexture Classification Of High Spatial Resolution Images From Urban areas The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, XXXVII.
  • Baud I, Kuffer M, Pfeffer K, Sliuzas R, Karuppannan S. 2010. Understanding heterogeneity in metropolitan India: The added value of remote sensing data for analyzing sub-standard residential areas. Int J Appl Earth Obs Geoinf. 12(5):359–374.
  • Baykal IC. 2019. Performance Comparison of Texture Classifiers on Small Windows. International Artificial Intelligence and Data Processing Symposium (IDAP). IEEE.
  • Brelsford C, Martin T, Hand J, Bettencourt LMA. 2018. Toward cities without slums: Topology and the spatial evolution of neighborhoods. Sci Adv. 4(8)
  • Bürgmann T. 2015. Investigating the Separability of Slums in Mumbai based on RADARSAT Images using Object-based Image Analysis Methods [bachelor's thesis]. Faculty of Information Management and Media Bachelor Degree Program Geo-Information Management.
  • Ciriza R, Sola I, Albizua L, Álvarez-Mozos J, González-Audícana M. 2017. Automatic detection of uprooted orchards based on orthophoto texture analysis. Remote Sensing. 9(5):492.
  • Duque J, Patino J, Betancourt A. 2017. Exploring the potential of machine learning for automatic slum identification from VHR imagery. Remote Sensing. 9(9):895.
  • Duque JC, Patino JE, Ruiz LA, Pardo-Pascual JE. 2015. Measuring intra-urban poverty using land cover and texture metrics derived from remote sensing data. Landscape Urban Plann. 135:11–21.
  • Ella L. A., van den Bergh F., van Wyk B. J. & van Wyk M. A. 2008. A comparison of texture feature algorithms for urban settlement classification. In IGARSS 2008-2008 IEEE International Geoscience and Remote Sensing Symposium,3, III–1308. IEEE.
  • Ella LA, Van Den Bergh F, Van Wyk BJ, Van Wyk MA. 2008b. A comparison of texture feature algorithms for urban settlement classification. GARSS 2008. IEEE International, IEEE,. In Geoscience and Remote Sensing Symposium, 2008. IGARSS 2008. IEEE International, 3, IEEE.
  • Ella L. A., Van Den Bergh F., Van Wyk, B. J. & Van Wyk, M. A. 2008a. A comparison of texture feature algorithms for urban settlement classification. In Geoscience and Remote Sensing Symposium, 2008. IGARSS 2008. IEEEInternational, 3, IEEE, III–1308.
  • Engstrom R, Copenhaver A, Newhouse D, Haldavanekar V, Hersh J. 2017. Evaluating the relationship between spatial and spectral features derived from high spatial resolution satellite data and urban poverty in Colombo, Sri Lanka. IEEE Xplore.
  • Fallatah A, Jones S, Mitchell D, Kohli D. 2019. Mapping informal settlement indicators using object-oriented analysis in the Middle East. Int J Digital Earth. 12(7):802–824.[
  • Fallatah A, Jones S, Mitchell D. 2020. Object-based random forest classification for informal settlements identification in the Middle East: Jeddah a case study. Int J Remote Sens. 41(11):4421–4445.
  • Fekri-Ershad S. 2020. Bark texture classification using improved local ternary patterns and multilayer neural network. Expert Syst Appl. 158:113509.
  • Fernandes E. 2011. Regularization of informal settlements in Latin America. Cambridge, MA, USA: Policy Focus Report • Lincoln Institute of Land Policy.
  • Gevaert CM, Persello C, Sliuzas R, Vosselman G. 2017. Informal settlement classification using point-cloud and image-based features from UAV data. ISPRS J Photogramm Remote Sens. 125:225–236.
  • Ghaffarian S, Emtehani S. 2021. Monitoring urban deprived areas with remote sensing and machine learning in case of disaster recovery. Climate. 9(4):58.
  • Giannini MB, Merola P. 2012. Texture analysis for urban areas classification in high resolution satellite imagery. Appl Rem Sens J. 2:65–71.
  • Gibson L, Adeleke A, Hadden R, Rush D. 2021. Spatial metrics from LiDAR roof mapping for fire spread risk assessment of informal settlements in Cape Town, South Africa. Fire Saf J. 120:103053.
  • Gilbert A. 2007. The return of the slum: Does language matter? International Journal of Urban and Regional Res. 31(4):697–713.
  • Girija G, Nikhila RI. 2018. Slum extraction approaches from high resolution satellite data—a case study of Madurai City. Intern J Pure Appl Math. 119 14509–14514.
  • Graesser J, Cheriyadat A, Vatsavai RR, Chandola V, Long J, Bright E. 2012. Image based characterization of formal and informal neighborhoods in an urban landscape. IEEE J Sel Top Appl Earth Observations Remote Sensing. 5(4):1164–1176.
  • Haralick R, Shanmugam K, Dinstein I. 1973. Textural features for image classification. IEEE Transactions on Systems. Man Cybernetics. 3:610–621.
  • Hofmann P, Taubenbock H, Werthmann C. 2015. Monitoring and Modelling of Informal Settlements -A review on recent developments and challenges. 2015 Joint Urban Remote Sensing Event (JURSE):1–4.
  • Kabir S, He D-C, Sanusi MA, Wan Hussina WMA. 2010. Texture analysis of IKONOS satellite imagery for urban land use and land cover classification. Imaging Sci J. 58(3):163–170.
  • Khumalo PP, Tapamo JR, Van Den Bergh F. 2011. Rotation invariant texture feature algorithms for urban settlement classification. GeoScience and Remote Sensing Symbosium (IGARSS). IEEE Intern; p. 511–514.
  • Kit O, Lüdeke M, Reckien D. 2012a. Texture-based identification of urban slums in Hyderabad, India using remote sensing data. Appl Geogr. 32(2):660–667.
  • Kit O, Lüdeke M. 2013. Automated detection of slum area change in Hyderabad, India using multitemporal satellite imagery. ISPRS J Photogramm Remote Sens. 83:130–137.
  • Kohli D, Sliuzas R, Stein A. 2016. Urban slum detection using texture and spatial metrics derived from satellite imagery. J Spatial Sci. 61(2):226–405.
  • Kohli D, Warwadekar P, Kerle N, Sliuzas R, Stein A. 2013. Transferability of object-oriented image analysis methods for slum identification. Remote Sens. 5(9):4209–4228.
  • Kuffer M, Pfeffer K, Sliuzas R, Baud I, Maarseveen M. 2017. Capturing the diversity of deprived areas with image-based features: The case of Mumbai. Remote Sens. 9(4):384.
  • Kuffer M, Pfeffer K, Sliuzas R, Baud I. 2016b. Extraction of slum areas from VHR imagery using GLCM variance. IEEE J Sel Top Appl Earth Observ Remote Sens. 9(5):1830–1840.
  • Kuffer M, Pfeffer K, Sliuzas R. 2016a. Slums from space—15 years of slum mapping using remote sensing. Remote Sens. 8(6):455.
  • Kuffer M, Sliuzas R, Pfeffer K, Baud I. 2015. The utility of the co-occurrence matrix to extract slum areas from VHR imagery. In 2015 Joint Urban Remote Sensing Event (JURSE). IEEE; p. 1–4.
  • Lai F, Yang X. 2020. Integrating spectral and non-spectral data to improve urban settlement mapping in a large Latin-American city. GISci Remote Sens. 57(6):830–844.
  • Lan Z, Liu Y. 2018. Study on multi-scalewindow determination for GLCM texture description in high-resolution remote sensing image geo-analysis supported by GIS and domain knowledge. Intern J Geo-Inform. 7.
  • Leao S, Leao D. 2011 Targeting housing problems through urban texture analysis. In Proceedings of the 12th International Conference on Computers in Urban Planning and Urban Management, Lake Louise, AB, Canada, 5–8 July.
  • Leonita G, Kuffer M, Sliuzas R, Persello C. 2018. Machine learning-based slum mapping in support of slum upgrading programs: The case of Bandung City, Indonesia. Remote Sens. 10(10):1522.
  • Luus FPS, Van Den Bergh F, Maharaj BTJ. 2014. Adaptive threshold-based shadow masking for across-date settlement classification of panchromatic quickbird images. IEEE Geosci Remote Sensing Lett. 11(6):1153–1157.
  • Ma L, Cheng L, Li M, Liu Y, Ma X. 2015. Training set size, scale, and features in geographic object-based image analysis of very high resolution unmanned aerial vehicle imagery. ISPRS J Photogramm Remote Sens. 102:14–27.
  • Ma L, Li M, Ma X, Cheng L, Du P, Liu Y. 2017. A review of supervised object-based land-cover image classification. ISPRS J Photogramm Remote Sens. 130:277–293.
  • Mahabir R, Croitoru A, Crooks A, Agouris P, Stefanidis A. 2018. A critical review of high and very high-resolution remote sensing approaches for detecting and mapping slums: trends, challenges and emerging opportunities. Urban Sci. 2(1):8.
  • Mahabir R, Crooks A, Croitoru A, Agouris P. 2016. The study of slums as social and physical constructs: challenges and emerging research opportunities. Regional Studies Regional Sci. 3(1):399–419.
  • Mboga N, Persello C, Bergado RJ, Stein A. 2017. Detection of Informal Settlements from VHR Images Using Convolutional Neural Networks. Remote Sens. 9(11):1106.
  • Mdakane L, Van den Bergh F. 2012. Extended local binary pattern features for improving settlement type classification of quickbird images.
  • Mhangara P, Odindi J. 2013. Potential of texture-based classification in urban landscapes using multispectral aerial photos. SAJS. 109(3/4):1–8.
  • Mudau N, Mhangara P. 2021. Investigation of informal settlement indicators in densely populated area using very high spatial resolution satellite imagery. Sustainability. 13(9):4735.
  • Mugiraneza T, Nascetti A, Ban Y. 2019. Worldview-2 data for hierarchical object-based urban land cover classification in Kigali: Integrating rule based approach with urban density and greenness indices. Remote Sens. 11(18):2128.
  • Naorem V, Kuffer M, Verplanke J, Kohli D. 2016. Robustness of rule sets using VHR imagery to detect informal settlements- a case of Mumbai, India.
  • Owen KK, Wong DW. 2013a. An approach to differentiate informal settlements using spectral, texture, geomorphology and road accessibility metrics. Appl Geogr. 38:107–118.
  • Owen KK, Wong DW. 2013b. Exploring structural differences between rural and urban informal settlements from imagery: thebasurerosof Cobán. Geocarto Intern. 28(7):562–581.
  • Patel A, Joseph G, Shrestha A, Foint Y. 2019. Measuring deprivations in the slums of Bangladesh: implications for achieving sustainable development goals. Housing Society. 46(2):81–109.
  • Persello C, Stein A. 2017. Deep fully convolutional networks for the detection of informal settlements in VHR images. IEEE Geosci Remote Sensing Lett. 14(12):2325–2329.
  • Prabhu R, Alagu Raja RA. 2018. Urban slum detection approaches from high-resolution satellite data using statistical and spectral based approaches. J Indian Soc Remote Sens. 46(12):2033–2044.
  • Prabhu R, Parvathavarthini B, Alagu Raja RA. 2021a. Slum extraction from high resolution satellite data using mathematical morphology based approach. Int J Remote Sens. 42(1):172–190.
  • Prabhu R, Parvathavarthini B, Alaguraja AR. 2021b. Integration of deep convolutional neural networks and mathematical morphology-based postclassification framework for urban slum mapping. J Appl Remote Sens. 15.
  • Prabhu R, Parvathavarthini B. 2021. An enhanced approach for informal settlement extraction from optical data using morphological profile-guided filters: A case study of Madurai city. Int J Remote Sens. 42(17):6688–6705.
  • Prabhu R, Umasree S, Avudaiammal R, Raja RA. 2017. Urban slum extraction using GLCM based Statistical approach from Very High Resolution Satellite data. ADVANCED COMPUTING (ICoAC 2017), 473.
  • Praptono NH, Sirait P. 2013. An Automatic Detection Method for High Density Slums based on Regularity Pattern of Housing using Gabor Filter and GINI Index. ICACSIS
  • Ramola A, Shakya AK, Van Pham D. 2020. Study of statistical methods for texture analysis and their modern evolutions. Eng Rep. 2(4)
  • Reba M, Seto KC. 2020. A systematic review and assessment of algorithms to detect, characterize, and monitor urban land change. Remote Sensing of Environment 242.
  • Roberti de Siqueira F, Robson Schwartz W, Pedrini H. 2013. Multi-scale graylevelco- occurrencematricesfortexturedescription. Neurocomputing. 120:336–345.
  • Samper J, Shelby JA, Behary D. 2020. The Paradox of Informal Settlements Revealed in an ATLAS of Informality: Findings from Mapping Growth in the Most Common Yet Unmapped Forms of Urbanization. Sustainability. 12(22):9510.
  • Sandborn A, Engstrom RN. 2016. Determining the relationship between census data and spatial features derived from high-resolution imagery in Accra, Ghana. IEEE J Sel Top Appl Earth Observations Remote Sensing. 9(5):1970–1977.
  • Satterthwaite D, Archer D, Colenbrander S, Dodman D, Hardoy J, Mitlin D, Patel S. 2020. Building resilience to climate change in informal settlements. One Earth. 2(2):143–156.
  • Schmitt A, Sieg T, Wurm M, Taubenböck H. 2018. Investigation on the separability of slums by multi-aspect TerraSAR-X dual-co-polarized high resolution spotlight images based on the multi-scale evaluation of local distributions. Int J Appl Earth Obs Geoinf. 64:181–198.
  • Shabat AM, Tapamo J-R. 2017. A comparative study of the use of local directional pattern for texture-based informal settlement classification. J Appl Res Technol. 15(3):250–258.
  • Shekhar S. 2012. Detecting slums from Quickbird data in Pune using an object oriented approach. International achieves of the photogrammetry, remote sensing and spatial information sciences, 39(8): 519–524.
  • Singh S, Srivastava D. 2017. GLCM and Its Application in Pattern Recognition. 5th International Symposium on Computational and Business Intelligence, 2017.
  • Stasolla M, Gamba P. 2008. Spatial Indexes for the extraction of formal and informal human settlements from high-resolution SAR images. IEEE J Sel Top Appl Earth Observations Remote Sensing. 1(2):98–106.
  • Suhartini N, Jones P. 2020. Better understanding self-organizing cities: a typology of order and rules in informal settlements. JRCP. 31(3):237–263.
  • Taubenböck H, Kraff NJ, Wurm M. 2018. The morphology of the Arrival City: a global categorization based on literature surveys and remotely sensed data. Appl Geogr. 92:150–167.
  • Taubenböck H, Wiesner M. 2015. The spatial network of megaregions - Types of connectivity between cities based on settlement patterns derived from EO-data. Comput Environ Urban Syst. 54:165–180.
  • Undp. 2018. Human development indices and indicators: 2018 statistical update. UNDP: New York, NY, USA.
  • Un-Habitat. 2003. The challenge of slums-global report on human settlements. Earthscan: London, UK.
  • Un-Habitat. 2015. Informal settlements. New York, NY, USA: UN-Habitat. p. 1–8.
  • United-Nations 2015. The Millennium Development Goals Report 2015. Available online: http://www.un.org/. millenniumgoals/(accessed on 12 December 2016).
  • United-Nations 2019. World urbanization prospects 2018. New York, NY, USA: United Nations.
  • Van Den Bergh F. 2011. The effects of viewing-and illumination geome-try on settlement type classification of quickbird images. In Geoscience and Remote Sensing Symposium (IGARSS),2011 IEEE International, p. 1425–1428.
  • Verma D, Jana A, Ramamritham K. 2019. Transfer learning approach to map urban slums using high and medium resolution satellite imagery. Habitat International. 88:101981.
  • Wang J, Kuffer M, Pfeffer K. 2019a. The role of spatial heterogeneity in detecting urban slums. Comput Environ Urban Syst. 73:95–107.
  • Wang J, Kuffer M, Roy D, Pfeffer K. 2019b. Deprivation pockets through the lens of convolutional neural networks. Remote Sens Environ. 234:111448.
  • Wang T, Zhang H, Lin H, Fang C. 2016. Textural–spectral feature-based species classification of mangroves in mai po nature reserve from worldview-3 imagery. Remote Sensing. 8.
  • Weeks JR, Hill A, Stow D, Getis A, Fugate D. 2007. Can we spot a neighborhood from the air? Defining neighborhood structure in Accra, Ghana. GeoJ. 69(1–2):9–22.
  • Weigand M. 2017. SAR Image Feature Analysis for Slum Detection in Megacities [Masters thesis]. University of Augsburg Faculty of Applied Computer Science Chair of Geoinformatics
  • Wurm M, Taubenböck H, Weigand M, Schmitt A. 2017a. Slum mapping in polarimetric SAR data using spatial features. Remote Sens Environ. 194:190–204.
  • Wurm M, Weigand M, Schmitt A, Geiß C, Taubenböck H. 2017b. Exploitation of Textural and Morphological Image Features in Sentinel-2A Data for Slum Mapping. In Proceedings of the Urban Remote Sensing Event, Dubai, UAE, 6–8 March 2017.
  • Zhang J, Li P, Wang J. 2014. Urban built-up area extraction from landsat TM/ETM + images using spectral information and multivariate texture. Remote Sensing. 6(8):7339–7359.
  • Zhang Q, Wang J, Gong P, Shi P. 2003. Study of urban spatial patterns from SPOT panchromatic imagery using textural analysis. Int J Remote Sens. 24(21):4137–4160.
  • Zhou H, Fu L, Sharmaa RP, Lei Y, Guo J. 2021. A hybrid approach of combining random forest with texture analysis and vdvi for desert vegetation mapping based on UAV RGB data. Remote Sens. 13.

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