Tree Species Classification of Drone Hyperspectral and RGB Imagery with Deep Learning Convolutional Neural Networks

Nezami, Somayeh; Khoramshahi, Ehsan; Nevalainen, Olli; Pölönen, Ilkka; Honkavaara, Eija

doi:10.3390/rs12071070

Cited by 105 publications

(52 citation statements)

References 31 publications

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“…By combining remote sensing data with artificial intelligence techniques, it is possible to properly map tree species and improve accuracy in applications regarding vegetation monitoring. In recent years, multiple frameworks have been implemented to assess the performance of such algorithms to accomplish this task (2,5,15,(35)(36)(37). During the past years, the detection and extraction of trees in high-resolution imagery were performed with more traditional machine learning algorithms, like support vector machine (SVM), random forest (RF), artificial neural networks (ANN), and others (38)(39)(40)(41).…”

Section: P R E P R I N Tmentioning

confidence: 99%

“…However, state-of-the-art deep learningbased methods should be capable of identifying single treespecies with an attractive accuracy and computational load even in RGB images. Recently, deep learning-based methods have been implemented in multiple remote sensing, specifically for image segmentation, classification, and object detection approaches (37,(47)(48)(49). Deep learning techniques are among the most recently adopted approaches to process remote sensing data (50)(51)(52).…”

Section: P R E P R I N Tmentioning

confidence: 99%

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Mapping Single Palm-Trees Species in Forest Environments with a Deep Convolutional Neural Network

Lsd¹,

MdSd²,

Deg³

et al. 2021

Preprint

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Accurately mapping individual tree species in densely forested environments is crucial to forest inventory. When considering only RGB images, this is a challenging task for many automatic photogrammetry processes. The main reason for that is the spectral similarity between species in RGB scenes, which can be a hindrance for most automatic methods. State-of-the-art deep learning methods could be capable of identifying tree species with an attractive cost, accuracy, and computational load in RGB images. This paper presents a deep learning-based approach to detect an important multi-use species of palm trees (Mauritia flexuosa; i.e., Buriti) on aerial RGB imagery. In South-America, this palm tree is essential for many indigenous and local communities because of its characteristics. The species is also a valuable indicator of water resources, which comes as a benefit for mapping its location. The method is based on a Convolutional Neural Network (CNN) to identify and geolocate singular tree species in a high-complexity forest environment, and considers the likelihood of every pixel in the image to be recognized as a possible tree by implementing a confidence map feature extraction. This study compares the performance of the proposed method against state-of-the-art object detection networks. For this, images from a dataset composed of 1,394 airborne scenes, where 5,334 palm-trees were manually labeled, were used. The results returned a mean absolute error (MAE) of 0.75 trees and an F1-measure of 86.9%. These results are better than both Faster R-CNN and RetinaNet considering equal experiment conditions. The proposed network provided fast solutions to detect the palm trees, with a delivered image detection of 0.073 seconds and a standard deviation of 0.002 using the GPU. In conclusion, the method presented is efficient to deal with a high-density forest scenario and can accurately map the location of single species like the M flexuosa palm tree and may be useful for future frameworks.

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Section: P R E P R I N Tmentioning

confidence: 99%

Section: P R E P R I N Tmentioning

confidence: 99%

Mapping Single Palm-Trees Species in Forest Environments with a Deep Convolutional Neural Network

Lsd¹,

MdSd²,

Deg³

et al. 2021

Preprint

View full text Add to dashboard Cite

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“…The spectral content originates from the images, which are radiometrically calibrated using the mapping camera software package with the aim of creating homogenous looking image blocks and orthophotos [22]. Alternatively, more advanced methods like radiometric block adjustment [23,24] can be done on the individual images. However, when the spectral information is projected to the point cloud it can be done in different ways as each point is seen in more than one aerial image [25].…”

Section: Introductionmentioning

confidence: 99%

Extraction of Spectral Information from Airborne 3D Data for Assessment of Tree Species Proportions

2021

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With the rapid development of photogrammetric software and accessible camera technology, land surveys and other mapping organizations now provide various point cloud and digital surface model products from aerial images, often including spectral information. In this study, methods for colouring the point cloud and the importance of different metrics were compared for tree species-specific estimates at a coniferous hemi-boreal test site in southern Sweden. A total of three different data sets of aerial image-based products and one multi-spectral lidar data set were used to estimate tree species-specific proportion and stem volume using an area-based approach. Metrics were calculated for 156 field plots (10 m radius) from point cloud data and used in a Random Forest analysis. Plot level accuracy was evaluated using leave-one-out cross-validation. The results showed small differences in estimation accuracy of species-specific variables between the colouring methods. Simple averages of the spectral metrics had the highest importance and using spectral data from two seasons improved species prediction, especially deciduous proportion. Best tree species-specific proportion was estimated using multi-spectral lidar with 0.22 root mean square error (RMSE) for pine, 0.22 for spruce and 0.16 for deciduous. Corresponding RMSE for aerial images was 0.24, 0.23 and 0.20 for pine, spruce and deciduous, respectively. For the species-specific stem volume at plot level using image data, the RMSE in percent of surveyed mean was 129% for pine, 60% for spruce and 118% for deciduous.

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“…Mapping and monitoring the tree species composition of Earth's forests using remote sensing technologies is a challenging task that has motivated an active research community over the past three decades [1][2][3][4][5][6][7]. In between the global coverage and long-standing historical records of satellite platforms [8][9][10] and the flexibility and high spatial resolution achieved by unmanned aircraft systems [11][12][13], airborne platforms provide a valuable intermediate scale of local to regional ecosystem monitoring capabilities [3,[14][15][16][17]. Passive optical (multispectral [10] and hyperspectral [18]) and active (such as Light Detection and Ranging (LiDAR) [19]) remote sensing systems have each been used to map tree species on their own with varying levels of success, but combining spectral and structural remote sensing data has been shown to generally improve tree species detection abilities compared to using any of them alone [2,3,14,[20][21][22].…”

Section: Introductionmentioning

confidence: 99%

“…SVM and RF tend to perform similarly in terms of classification accuracy and training time [29][30][31]. Neural networks are increasingly used in ecological remote sensing studies for their ability to identify trends and patterns from data, model complex relationships, accept a wide variety of input predictor data, and produce high accuracies, at the expense of requiring large amounts of training data [13,[32][33][34]. Tree species classification accuracies reported throughout the literature vary widely from approximately 60% to 95%, along with the type and number of sensors used, biodiversity within forests, and classification methods utilized [6].…”

Section: Introductionmentioning

confidence: 99%

Integrating National Ecological Observatory Network (NEON) Airborne Remote Sensing and In-Situ Data for Optimal Tree Species Classification

et al. 2020

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Accurately mapping tree species composition and diversity is a critical step towards spatially explicit and species-specific ecological understanding. The National Ecological Observatory Network (NEON) is a valuable source of open ecological data across the United States. Freely available NEON data include in-situ measurements of individual trees, including stem locations, species, and crown diameter, along with the NEON Airborne Observation Platform (AOP) airborne remote sensing imagery, including hyperspectral, multispectral, and light detection and ranging (LiDAR) data products. An important aspect of predicting species using remote sensing data is creating high-quality training sets for optimal classification purposes. Ultimately, manually creating training data is an expensive and time-consuming task that relies on human analyst decisions and may require external data sets or information. We combine in-situ and airborne remote sensing NEON data to evaluate the impact of automated training set preparation and a novel data preprocessing workflow on classifying the four dominant subalpine coniferous tree species at the Niwot Ridge Mountain Research Station forested NEON site in Colorado, USA. We trained pixel-based Random Forest (RF) machine learning models using a series of training data sets along with remote sensing raster data as descriptive features. The highest classification accuracies, 69% and 60% based on internal RF error assessment and an independent validation set, respectively, were obtained using circular tree crown polygons created with half the maximum crown diameter per tree. LiDAR-derived data products were the most important features for species classification, followed by vegetation indices. This work contributes to the open development of well-labeled training data sets for forest composition mapping using openly available NEON data without requiring external data collection, manual delineation steps, or site-specific parameters.

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Tree Species Classification of Drone Hyperspectral and RGB Imagery with Deep Learning Convolutional Neural Networks

Cited by 105 publications

References 31 publications

Mapping Single Palm-Trees Species in Forest Environments with a Deep Convolutional Neural Network

Mapping Single Palm-Trees Species in Forest Environments with a Deep Convolutional Neural Network

Extraction of Spectral Information from Airborne 3D Data for Assessment of Tree Species Proportions

Integrating National Ecological Observatory Network (NEON) Airborne Remote Sensing and In-Situ Data for Optimal Tree Species Classification

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