Abstract

Abstract. The deep learning (DL) models require timely updates to continue their reliability and robustness in prediction, classification, and segmentation tasks. When the deep learning models are tested with a limited test set, the model will not reveal the drawbacks. Every deep learning baseline model needs timely updates by incorporating more data, change in architecture, and hyper parameter tuning. This work focuses on updating the Conditional Generative Adversarial Network (C-GAN) based epiphyte identification deep learning model by incorporating 4 different generator architectures of GAN and two different loss functions. The four generator architectures used in this task are Resnet-6. Resnet-9, Resnet-50 and Resnet-101. A new annotation method called background removed annotation was tested to analyse the improvement in the epiphyte identification protocol. All the results obtained from the model by changing the above parameters are reported using two common evaluation metrics. Based on the parameter tuning experiment, Resnet-6, and Resnet- 9, with binary cross-entropy (BCE) as the loss function, attained higher scores also Resnet-6 with MSE as loss function performed well. The new annotation by removing the background had minimal effect on identifying the epiphytes.

Highlights

  • Neural network (NN) algorithms are used in many digital data analysis (Tefas et al, 2013)

  • deep learning (DL) algorithms consist of deep neural network components and their organisation collectively referred as their architecuture

  • Several state of the art DL architectures are used for image classification, object detection, and image segmentation tasks (Zhao et al, 2019; Nida et al, 2015)

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Summary

Introduction

Neural network (NN) algorithms are used in many digital data analysis (Tefas et al, 2013). Deep learning-based data analysis are a part of NN algorithms and are robust for applications with data generated by numerous sources (Jia et al, 2017 and Najafabadi et al, 2015). These deep learning (DL) algorithms are capable of understanding data and its pattern from an experiential learning and derive the features from input data and generate learned models (Harshvardhan et al, 2020). DL algorithms consist of deep neural network components and their organisation collectively referred as their architecuture. Several state of the art DL architectures are used for image classification, object detection, and image segmentation tasks (Zhao et al, 2019; Nida et al, 2015)

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