A Novel Deep Learning-Based Hybrid Method for the Determination of Productivity of Agricultural Products Apple Case Study.
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A Novel Deep Learning-Based Hybrid Method for the Determination of Productivity of Agricultural Products Apple Case Study.docx
1. Base paper Title: A Novel Deep Learning-Based Hybrid Method for the Determination of
Productivity of Agricultural Products: Apple Case Study
Modified Title: An Innovative Hybrid Approach Based on Deep Learning to Assess
Agricultural Productivity: An Analysis of Apple's Situation
Abstract
The production of agricultural products and the high yield in these products are of
critical importance for the continuation of human life. In recent years, machine learning and
deep learning technologies have been widely used in determining agricultural productivity. The
purpose of this study was to estimate the yield of apple fruit by using a novel deep learning-
based hybrid method. First, by using images belonging to the golden and royal gala apple
varieties, a classification was made with the help of a convolutional neural network (CNN) that
was designed for the study. Then, using classical machine learning algorithms and bagging and
boosting algorithms, a hybrid application was performed by classifying the images whose
feature extractions were done with the designed CNN. The results of the study, presented on 4
separate datasets (Datasets A, B, C, and D), were evaluated based on accuracy, precision, recall,
F-measure, and Cohen kappa scores. Considering the accuracy results for Datasets B, C, and
D, it was determined that the hybrid model that gave the best result was the CNN-SVM model.
For Dataset A, the CNN-SVM and CNN-Gradient Boosting hybrid models gave the best and
same accuracy. Dataset C was determined as the most appropriate dataset in terms of the more
balanced distribution of train, test, and validation size in the datasets, the results of the proposed
hybrid CNN model, and the evaluation of the results of the model. For Dataset C, it was found
that the accuracy of the hybrid model was 99.70%. Precision, recall, f-measure, and Cohen
kappa scores were 99%. The results of the study revealed that the hybrid models showed
effective results in determining the productivity of apple fruit through images belonging to the
golden and royal gala varieties.
Existing System
Agriculture is the process of producing food, fiber, and other products through the
cultivation of certain plants. After the production process, product efficiency gains great
importance, and it also plays a very important role in the economy of countries. Although there
is an impact of global warming, there are decreases in fruit and vegetable production and yields
2. due to the lack of knowledge of farmers and incorrect irrigation methods. Though the World
Health Organization (WHO) says that people should consume an average of 400 grams of fruits
and vegetables per day, this does not seem possible. Fruit and vegetable yields show a decrease
in many countries. In order to prevent this yield decrease, important agricultural countries of
the world have been developing smart agricultural systems to ensure obtaining even greater
yields by preventing yield reduction in fruit and vegetable production caused by farmers, to
carry out water use more consciously, and to identify diseases and wild-harmfulpoisonous
herbs in plants. In the yield and disease determination models developed with smart agricultural
systems, image data and metadata of them are used. Inferences are made by training these data
with statistical results and models. According to FAO data, apple, which makes up 10% of the
world’s fruit production, is the third most-produced fruit after bananas and watermelons [1].
World apple production was being estimated at 79.4 million tons in the 2019-2020 season,
while this production was predicted to be 76.1 million tons in the 2020-2021 season by a
decrease of about 4.1% [1]. This research was conducted to predict apple fruit yield. For the
purpose of the research, a dataset consisting of images belonging to low-yielding and high-
yielding Royal Gala and Golden varieties of apple fruit was used. Due to the fact that the dataset
had a small number of images, GAN (Generative Adversarial Network) was used to increase
this number instead of the classic data augmentation methods. Based on their weights, the
images augmented by the GAN method were classified as High Yield Golden, Low Yield
Golden, High Yield Royal Gala, and Low Yield Royal Gala. In the next step, four different
datasets (Dataset A, Dataset B, Dataset C, and Dataset D) were created to observe the results
of the classified images. First, the performance of the CNN architecture designed for this study
was examined for each dataset. In the next stage, the image features were extracted by the
designed CNN architecture. Finally, these features were classified by machine learning (ML),
bagging, and boosting algorithms, and then a hybrid model was proposed.
Drawback in Existing System
Data Quality and Availability:
The success of deep learning models heavily depends on the quality and quantity of
data. If there is a lack of high-quality, diverse, and representative data for apple
productivity, it can lead to biased or inaccurate model predictions.
3. Limited availability of labeled data for training the model can be a significant
challenge. Annotating agricultural data, especially at scale, can be time-consuming and
expensive.
Computational Resources:
Deep learning models, especially complex ones, can require significant
computational resources for training and inference. This may limit the applicability of
the proposed method in resource-constrained environments or for farmers with limited
access to advanced technology.
Cost of Implementation:
The cost of implementing and maintaining the proposed method, including hardware,
software, and training, should be considered. High costs may limit its adoption,
especially in regions with limited resources.
Regulatory and Privacy Concerns:
Depending on the region, there may be regulatory hurdles related to the use of deep
learning models in agriculture. Additionally, privacy concerns related to the collection
and use of farm data need careful consideration.
Proposed System
Problem Definition:
Clearly define the problem: Determination of agricultural productivity for apple
crops.
Specify the target variable (e.g., yield per acre) and the factors influencing
productivity.
Interpretability and Explainability:
Incorporate techniques for model interpretability (e.g., SHAP values, feature
importance plots) to enhance transparency and trust.
4. Deployment and Integration:
Deploy the trained model in a suitable environment, considering factors like latency
and scalability.
Integrate the model into a user-friendly interface for stakeholders, such as farmers or
agricultural advisors.
Continuous Monitoring and Updating:
Implement a system for continuous monitoring of model performance in real-world
conditions.
Update the model as needed based on new data and evolving agricultural practices.
Algorithm
Convolutional Neural Networks (CNNs):
CNNs are well-suited for image-related tasks, making them applicable to agricultural
scenarios where visual data, such as images of crops or orchards, may be available.
They can be used for feature extraction and image classification.
Recurrent Neural Networks (RNNs):
RNNs are suitable for sequential data, which can be valuable in agriculture for
modeling temporal patterns. For instance, RNNs can be used to analyze time-series data
related to weather conditions, soil moisture, or other variables that impact productivity.
Explainable AI (XAI) Techniques:
Given the importance of interpretability in agricultural decision-making,
incorporating XAI techniques, such as LIME (Local Interpretable Model-agnostic
Explanations) or SHAP (SHapley Additive exPlanations), can help in understanding
and justifying model predictions.
5. Advantages
Improved Accuracy and Precision:
Deep learning models, when trained on large and diverse datasets, can capture
complex patterns and relationships within the data. This can lead to improved accuracy
and precision in predicting agricultural productivity compared to traditional methods.
Feature Learning and Representation:
Auto encoders and other deep learning architectures are capable of learning
meaningful representations of input data. This can lead to better feature extraction,
allowing the model to focus on the most relevant aspects of the data for productivity
determination.
Scientific Understanding:
The development of a deep learning-based hybrid method can contribute to a better
scientific understanding of the complex relationships within agricultural ecosystems.
This understanding can, in turn, inform further research and advancements in precision
agriculture.
Resource Optimization:
By predicting productivity levels, farmers can optimize the use of resources such as
water, fertilizers, and pesticides. This can lead to more sustainable agricultural
practices, reducing waste and environmental impact.
Software Specification
Processor : I3 core processor
Ram : 4 GB
Hard disk : 500 GB
Software Specification
Operating System : Windows 10 /11
Frond End : Python
6. Back End : Mysql Server
IDE Tools : Pycharm