TY - JOUR
T1 - Towards a framework for agent-based image analysis of remote-sensing data
AU - Hofmann, P.
AU - Lettmayer, P.
AU - Blaschke, T.
AU - Belgiu, M.
AU - Wegenkittl, S.
AU - Graf, R.
AU - Lampoltshammer, T.J.
AU - Andrejchenko, V.
N1 - Cited By :31
Export Date: 14 December 2023
Correspondence Address: Hofmann, P.; Interfaculty Department of Geoinformatics – Z_GIS, Schillerstr. 30, Austria; email: [email protected]
Funding details: FWF P25449
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PY - 2015
Y1 - 2015
N2 - Object-based image analysis (OBIA) as a paradigm for analysing remotely sensed image data has in many cases led to spatially and thematically improved classification results in comparison to pixel-based approaches. Nevertheless, robust and transferable object-based solutions for automated image analysis capable of analysing sets of images or even large image archives without any human interaction are still rare. A major reason for this lack of robustness and transferability is the high complexity of image contents: Especially in very high resolution (VHR) remote-sensing data with varying imaging conditions or sensor characteristics, the variability of the objects’ properties in these varying images is hardly predictable. The work described in this article builds on so-called rule sets. While earlier work has demonstrated that OBIA rule sets bear a high potential of transferability, they need to be adapted manually, or classification results need to be adjusted manually in a post-processing step. In order to automate these adaptation and adjustment procedures, we investigate the coupling, extension and integration of OBIA with the agent-based paradigm, which is exhaustively investigated in software engineering. The aims of such integration are (a) autonomously adapting rule sets and (b) image objects that can adopt and adjust themselves according to different imaging conditions and sensor characteristics. This article focuses on self-adapting image objects and therefore introduces a framework for agent-based image analysis (ABIA). © 2015 Taylor & Francis.
AB - Object-based image analysis (OBIA) as a paradigm for analysing remotely sensed image data has in many cases led to spatially and thematically improved classification results in comparison to pixel-based approaches. Nevertheless, robust and transferable object-based solutions for automated image analysis capable of analysing sets of images or even large image archives without any human interaction are still rare. A major reason for this lack of robustness and transferability is the high complexity of image contents: Especially in very high resolution (VHR) remote-sensing data with varying imaging conditions or sensor characteristics, the variability of the objects’ properties in these varying images is hardly predictable. The work described in this article builds on so-called rule sets. While earlier work has demonstrated that OBIA rule sets bear a high potential of transferability, they need to be adapted manually, or classification results need to be adjusted manually in a post-processing step. In order to automate these adaptation and adjustment procedures, we investigate the coupling, extension and integration of OBIA with the agent-based paradigm, which is exhaustively investigated in software engineering. The aims of such integration are (a) autonomously adapting rule sets and (b) image objects that can adopt and adjust themselves according to different imaging conditions and sensor characteristics. This article focuses on self-adapting image objects and therefore introduces a framework for agent-based image analysis (ABIA). © 2015 Taylor & Francis.
KW - agent-based image analysis
KW - agent-based systems
KW - automation of image analysis
KW - autonomous systems
KW - object-based image analysis
KW - remote sensing
KW - Autonomous agents
KW - Image enhancement
KW - Remote sensing
KW - Software agents
KW - Software engineering
KW - Agent based
KW - Agent-based systems
KW - Automated image analysis
KW - Autonomous systems
KW - Object based image analysis
KW - Object based image analysis (OBIA)
KW - Remotely sensed images
KW - Sensor characteristics
KW - Image analysis
U2 - 10.1080/19479832.2015.1015459
DO - 10.1080/19479832.2015.1015459
M3 - Article
SN - 1947-9832
VL - 6
SP - 115
EP - 137
JO - International Journal of Image and Data Fusion
JF - International Journal of Image and Data Fusion
IS - 2
ER -