Abstract
Phoenix palms cover more than 1.3 million hectares in the Mediterranean, Middle East, and North Africa regions and they represent highly valued assets for economic, environmental, and cultural purposes. Despite their importance, information on the number of palm trees and the palm distribution across different scenes is difficult to obtain and, therefore, limited. In this work, we present the first region-wide spatial inventory of Phoenix dactylifera (date palm) and Phoenix canariensis (canary palm) trees, based on remote imagery from the Alicante province in Spain. A deep learning architecture that was based on convolutional neural networks (CNN) was implemented to generate a detection model able to locate and classify individual palms trees from aerial high-resolution RGB images. When considering that creating large labeled image datasets is a constraint in object detection applied to remote sensing data, as a strategy for pre-training detection models on a similar task, imagery and palm maps from the autonomous community of the Canary Islands were used. Subsequently, these models were transferred for re-training with imagery from Alicante. The best performing model was capable of mapping Phoenix palms in different scenes, with a changeable appearance, and with varied ages, achieving a mean average precision (mAP) value of 0.861. In total, 511,095 Phoenix palms with a probability score above 0.5 were detected over an area of 5816 km2. The detection model, which was obtained from an out-of-the-box object detector, RetinaNet, provides a fast and straightforward method to map isolated and densely distributed date and canary palms—and other Phoenix palms. The inventory of palm trees established here provides quantitative information on Phoenix palms distribution, which could be used as a baseline for long-term monitoring of palms’ conditions. In addition to boosting palm tree inventory across multiple landscapes at a large scale, the detection model demonstrates how image processing techniques that are based on deep learning leverage image understanding from remote sensing data.
Highlights
Phoenix palms cover more than 1.3 million hectares of agricultural land in the Mediterranean, Middle East, and North Africa regions [1]
The study contribution refers to presenting the application of a well-established object detection architecture in Computer Vision into an Earth Observation (EO) problem, such as tree inventory, to demonstrate to the EO community how image processing techniques that are based on deep learning leverage image understanding from remote sensing (RS) data
As the changeable scenes and appearances of Phoenix palms represent a challenge for deep learning object detection, not to mention that the use of remote sensing data is a challenge itself, here was presented a detection model for generating the first Phoenix palm tree inventory on a region-wide scale
Summary
Phoenix palms cover more than 1.3 million hectares of agricultural land in the Mediterranean, Middle East, and North Africa regions [1]. Ex Chabaud), because of fruit production [2,3], historic heritage conservation [4,5], and ornamental use [6,7]. The most common species of the Phoenix genus are the date palm (P. dactylifera L.) and the canary palm Because of their exploitation since ancient times for trade commerce, nutrition, health, landscape, construction, and others, date palms and canary palms represent high-valued assets in the socio-economic development of these regions [2,8,9,10]. The protection and preservation of Phoenix palms are critical to ensure the well-being of the societies that benefit from their derived products and services
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