Deep Learning and Phenology Enhance Large-Scale Tree Species Classification in Aerial Imagery during a Biosecurity Response

The ability of deep convolutional neural networks (deep learning) to learn complex visual characteristics offers a new method to classify tree species using lower-cost data such as regional aerial RGB imagery. In this study, we use 10 cm resolution imagery and 4600 trees to develop a deep learning model to identify Metrosideros excelsa (pōhutukawa)—a culturally important New Zealand tree that displays distinctive red flowers during summer and is under threat from the invasive pathogen Austropuccinia psidii (myrtle rust). Our objectives were to compare the accuracy of deep learning models that could learn the distinctive visual characteristics of the canopies with tree-based models (XGBoost) that used spectral and textural metrics. We tested whether the phenology of pōhutukawa could be used to enhance classification by using multitemporal aerial imagery that showed the same trees with and without widespread flowering. The XGBoost model achieved an accuracy of 86.7% on the dataset with strong phenology (flowering). Without phenology, the accuracy fell to 79.4% and the model relied on the blueish hue and texture of the canopies. The deep learning model achieved 97.4% accuracy with 96.5% sensitivity and 98.3% specificity when leveraging phenology—even though the intensity of flowering varied substantially. Without strong phenology, the accuracy of the deep learning model remained high at 92.7% with sensitivity of 91.2% and specificity of 94.3% despite significant variation in the appearance of non-flowering pōhutukawa. Pooling time-series imagery did not enhance either approach. The accuracy of XGBoost and deep learning models were, respectively, 83.2% and 95.2%, which were of intermediate precision between the separate models.

[1]  Geoffrey E. Hinton,et al.  Deep Learning , 2015, Nature.

[2]  Sakari Tuominen,et al.  Tree species classification from airborne hyperspectral and LiDAR data using 3D convolutional neural networks , 2021, Remote Sensing of Environment.

[3]  Maitiniyazi Maimaitijiang,et al.  Urban Tree Species Classification Using a WorldView-2/3 and LiDAR Data Fusion Approach and Deep Learning , 2019, Sensors.

[4]  J. Dymond,et al.  LiDAR-Based Regional Inventory of Tall Trees—Wellington, New Zealand , 2018, Forests.

[5]  Tianqi Chen,et al.  XGBoost: A Scalable Tree Boosting System , 2016, KDD.

[6]  Thomas Blaschke,et al.  Object based image analysis for remote sensing , 2010 .

[7]  J. Ditomaso,et al.  Enhancing the effectiveness of biological control programs of invasive species through a more comprehensive pest management approach. , 2017, Pest management science.

[8]  Michael A. Lefsky,et al.  Review of studies on tree species classification from remotely sensed data , 2016 .

[9]  Janet Franklin,et al.  A Convolutional Neural Network Classifier Identifies Tree Species in Mixed-Conifer Forest from Hyperspectral Imagery , 2019, Remote. Sens..

[10]  Peter Whittle,et al.  The Role of Surveillance Methods and Technologies in Plant Biosecurity , 2014 .

[11]  Gaël Varoquaux,et al.  Scikit-learn: Machine Learning in Python , 2011, J. Mach. Learn. Res..

[12]  Huili Gong,et al.  Development of spectral-phenological features for deep learning to understand Spartina alterniflora invasion , 2020, Remote Sensing of Environment.

[13]  Mryka Hall-Beyer,et al.  Practical guidelines for choosing GLCM textures to use in landscape classification tasks over a range of moderate spatial scales , 2017 .

[14]  Clement Atzberger,et al.  Individual Tree Crown Segmentation and Classification of 13 Tree Species Using Airborne Hyperspectral Data , 2018, Remote. Sens..

[15]  Benoit Rivard,et al.  Variability in leaf optical properties of Mesoamerican trees and the potential for species classification. , 2006, American journal of botany.

[16]  O. Phillips,et al.  Using the U‐net convolutional network to map forest types and disturbance in the Atlantic rainforest with very high resolution images , 2019, Remote Sensing in Ecology and Conservation.

[17]  M. Onishi,et al.  Explainable identification and mapping of trees using UAV RGB image and deep learning , 2021, Scientific Reports.

[18]  Jonathan P. Dash,et al.  Assessing very high resolution UAV imagery for monitoring forest health during a simulated disease outbreak , 2017 .

[19]  John A. Gamon,et al.  Assessing leaf pigment content and activity with a reflectometer , 1999 .

[20]  Geraint Rees,et al.  Clinically applicable deep learning for diagnosis and referral in retinal disease , 2018, Nature Medicine.

[21]  K. Cooper,et al.  Emergency response to the incursion of an exotic myrtaceous rust in Australia , 2011, Australasian Plant Pathology.

[22]  Patrick Mäder,et al.  Automated plant species identification—Trends and future directions , 2018, PLoS Comput. Biol..

[23]  Fabian Ewald Fassnacht,et al.  Convolutional Neural Networks enable efficient, accurate and fine-grained segmentation of plant species and communities from high-resolution UAV imagery , 2019, Scientific Reports.

[24]  M. Wingfield,et al.  The Myrtle rust pathogen, Puccinia psidii, discovered in Africa , 2013, IMA fungus.

[25]  Sebastian Egli,et al.  CNN-Based Tree Species Classification Using High Resolution RGB Image Data from Automated UAV Observations , 2020, Remote. Sens..

[26]  M. Wingfield,et al.  Rust (Puccinia psidii) recorded in Indonesia poses a threat to forests and forestry in South-East Asia , 2016, Australasian Plant Pathology.

[27]  C. Potter,et al.  Integrating multi-sensor remote sensing and species distribution modeling to map the spread of emerging forest disease and tree mortality , 2019, Remote Sensing of Environment.

[28]  Lars Brabyn,et al.  Combining QuickBird, LiDAR, and GIS topography indices to identify a single native tree species in a complex landscape using an object-based classification approach , 2016, Int. J. Appl. Earth Obs. Geoinformation.

[29]  Michael S. Bernstein,et al.  ImageNet Large Scale Visual Recognition Challenge , 2014, International Journal of Computer Vision.

[30]  Jian Sun,et al.  Deep Residual Learning for Image Recognition , 2015, 2016 IEEE Conference on Computer Vision and Pattern Recognition (CVPR).

[31]  Arnt-Børre Salberg,et al.  Tree species classification in Norway from airborne hyperspectral and airborne laser scanning data , 2018 .

[32]  M. Templeton,et al.  New Zealand pest management: current and future challenges , 2015 .

[33]  Sebastian Schmidtlein,et al.  Mapping forest tree species in high resolution UAV-based RGB-imagery by means of convolutional neural networks , 2020, ISPRS Journal of Photogrammetry and Remote Sensing.

[34]  Mariana Belgiu,et al.  Random forest in remote sensing: A review of applications and future directions , 2016 .

[35]  Matthew Nagel,et al.  Impact of the invasive rust Puccinia psidii (myrtle rust) on native Myrtaceae in natural ecosystems in Australia , 2015, Biological Invasions.

[36]  Peter T. Wolter,et al.  Improved forest classification in the northern Lake States using multi-temporal Landsat imagery , 1995 .

[37]  D. Kriticos,et al.  Improving border biosecurity: potential economic benefits to New Zealand , 2005 .

[38]  Leonhard Blesius,et al.  Tree Species Classification Using Hyperspectral Imagery: A Comparison of Two Classifiers , 2016, Remote. Sens..

[39]  Y. Shimabukuro,et al.  Tree species classification in tropical forests using visible to shortwave infrared WorldView-3 images and texture analysis , 2019, ISPRS Journal of Photogrammetry and Remote Sensing.

[40]  Marco Heurich,et al.  Large-Scale Mapping of Tree Species and Dead Trees in Šumava National Park and Bavarian Forest National Park Using Lidar and Multispectral Imagery , 2020, Remote. Sens..

[41]  C. Mundt Durable resistance: a key to sustainable management of pathogens and pests. , 2014, Infection, genetics and evolution : journal of molecular epidemiology and evolutionary genetics in infectious diseases.

[42]  Gregory Asner,et al.  Applications of Remote Sensing to Alien Invasive Plant Studies , 2009, Sensors.

[43]  Gregory Asner,et al.  A Spectral Mapping Signature for the Rapid Ohia Death (ROD) Pathogen in Hawaiian Forests , 2018, Remote. Sens..

[44]  A. Huete,et al.  A review of vegetation indices , 1995 .

[45]  D. Roberts,et al.  Hyperspectral discrimination of tropical rain forest tree species at leaf to crown scales , 2005 .

[46]  G. Arturo Sánchez-Azofeifa,et al.  The effect of seasonal spectral variation on species classification in the Panamanian tropical forest , 2012 .

[47]  A. E. B. Lacerda,et al.  Can we really manage tropical forests without knowing the species within? Getting back to the basics of forest management through taxonomy , 2010 .

[48]  A. Tait,et al.  Predicting the climatic risk of myrtle rust during its first year in New Zealand , 2018, New Zealand Plant Protection.