Abstract
In the past decades, sub-pixel mapping algorithms have been extensively developed due to the large number of different applications. However, most of the sub-pixel mapping algorithms are based on single-temporal images, and the results are usually compromised without auxiliary information due to the ill-posed problem of sub-pixel mapping. In this paper, a novel spatial-temporal sub-pixel mapping algorithm based on swarm intelligence theory is proposed for multitemporal remote sensing imagery. Swarm intelligence theory involves clonal selection sub-pixel mapping (CSSM), which evolves the solution by emulating the biological advantage of the human immune system, and differential evolution sub-pixel mapping (DESM), which optimizes the solution by intelligent operations and heuristic searching in the solution pool. In addition, considering the under-determined problem of sub-pixel mapping, the spatial-temporal sub-pixel mapping method is used to obtain the distribution information at a fine spatial resolution from the bitemporal image pair, which exactly regularizes the ill-posed problem. Furthermore, the short-interval temporal information and the fine spatial distribution information within the bitemporal image pair can be integrated for further use, such as timely and detailed land-cover change detection (LCCD). To verify the validation of the swarm intelligence theory based spatial-temporal sub-pixel mapping algorithm, the proposed algorithm was compared with several traditional sub-pixel mapping algorithms, in both synthetic and real image experiments. The experimental results confirm that the proposed algorithm outperforms the traditional approaches, achieving a better sub-pixel mapping result both qualitatively and quantitatively, as well as improving the subsequent LCCD performance.
Highlights
Due to the resolution constraint of sensors, in that the instantaneous field of view (FOV) is usually larger than the land-cover objects the sensors observe [1], the mixed pixel is a common phenomenon in remote sensing imagery acquired by moderate/low-resolution sensors
Since the experimental datasets were bitemporal image pairs, land-cover change detection (LCCD) was conducted between the sub-pixel mapping result and the fine spatial resolution image during each experiment
× 60); (j)image pixel of swapping sub-pixel mapping (PSSM);image (k) sub-pixel mapping based on a genetic sub-pixel mapping based on differential evolution (DESM); (m) sub-pixelbased bare algorithm soil (60 ×(GASM); 60); (j) (l) pixel swapping sub-pixel mapping (PSSM); (k) Sub-pixel mapping on clonal selection (n) spatial-temporal sub-pixel mapping based on a pixel on a mapping genetic based algorithm (GASM); (l)(CSSM); Sub-pixel mapping based on differential evolution (DESM); swapping mapping algorithm (SSMPS); spatial-temporal sub-pixel (n) mapping based on a genetic algorithm (m) Sub-pixel based on(o)clonal selection (CSSM); Spatial-temporal sub-pixel mapping (p) spatial-temporal sub-pixel mapping based on differential evolution (SSMDE); and (q) based(SSMGA); on a pixel swapping algorithm (SSMPS); (o) Spatial-temporal sub-pixel mapping based on a spatial-temporal sub-pixel mapping based on clonal selection (SSMCS)
Summary
Due to the resolution constraint of sensors, in that the instantaneous field of view (FOV) is usually larger than the land-cover objects the sensors observe [1], the mixed pixel is a common phenomenon in remote sensing imagery acquired by moderate/low-resolution sensors. Most of the current sub-pixel mapping algorithms are based on single-temporal images and only rely on the spatial dependence assumption, which cannot provide sufficient spatial distribution information for the reconstruction of mixed pixels. (1) A spatial-temporal sub-pixel mapping model is built to obtain the distribution pattern information from the fine spatial resolution image with the same FOV according to the differential of each land-cover type between the fine and the coarse images, which helps to provide the sub-pixel mapping problem with a corroborative constraint and exactly regularizes this under-determined problem. (2) A promising swarm intelligence algorithm, which includes a clonal selection algorithm (SSMCS) and a differential evolution algorithm (SSMDE), is successfully incorporated into the framework of the spatial-temporal sub-pixel mapping method, which transforms the sub-pixel mapping problem into an optimization problem and searches for an optimal solution by maximizing the spatial dependence index (SDI).
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