Abstract
Random forest (RF) has obtained great success in hyperspectral image (HSI) classification. However, RF cannot leverage its full potential in the case of limited labeled samples. To address this issue, we propose a unified framework that embeds active learning (AL) and semi-supervised learning (SSL) into RF (ASSRF). Our aim is to utilize AL and SSL simultaneously to improve the performance of RF. The objective of the proposed method is to use a small number of manually labeled samples to train classifiers with relative high classification accuracy. To achieve this goal, a new query function is designed to query the most informative samples for manual labeling, and a new pseudolabeling strategy is introduced to select some samples for pseudolabeling. Compared with other AL- and SSL-based methods, the proposed method has several advantages. First, ASSRF utilizes the spatial information to construct a query function for AL, which can select more informative samples. Second, in addition to providing more labeled samples for SSL, the proposed pseudolabeling method avoids bias caused by AL-labeled samples. Finally, the proposed model retains the advantages of RF. To demonstrate the effectiveness of ASSRF, we conducted experiments on three real hyperspectral data sets. The experimental results have shown that our proposed method outperforms other state-of-the-art methods.
Highlights
Hyperspectral remote sensing can obtain a great deal of information about an object via hundreds of narrow, continuous spectral bands
(1) The Kennedy Space Center (KSC) data was acquired by the NASA Airborne Visible Infrared Imaging Spectrometer sensor over the KSC, Florida, on 23 March 1996
The results indicate that MS-cSV is the most time-consuming method, MCLU-ECBD and EQB require the least time cost, collaborative active and semi-supervised learning (CASSL), DRDbSSAL, and active semi-supervised random forest (ASSRF) need a medium computation time
Summary
Hyperspectral remote sensing can obtain a great deal of information about an object via hundreds of narrow, continuous spectral bands. Hyperspectral imaging techniques have been widely used in many applications, such as landmine detection [1], agricultural monitoring [2], land cover classification [3], and target detection [4]. Many of these applications are based on hyperspectral image (HSI) classification at the pixel level. In the past few years, various supervised classification methods, e.g., support vector machines (SVMs) [5,6], neural networks [7,8], and random forests (RFs) [9,10,11] have been successfully used for HSI classification. Supervised methods often require many informative samples with labels to train high-performing classifiers. We consider combining AL and SSL into random forest for HSI classification
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