Artificial Intelligence-Based Real-Time Pineapple Quality Classification Using Acoustic Spectroscopy

The pineapple is an essential fruit in Taiwan. Farmers separate pineapples into two types, according to the percentages of water in the pineapples. One is the “drum sound pineapple” and the other is the “meat sound pineapple”. As there is more water in the meat sound pineapple, the meat sound pineap...

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Bibliographic Details
Published in:Agriculture (Basel) 2022-02, Vol.12 (2), p.129
Main Authors: Huang, Ting-Wei, Bhat, Showkat Ahmad, Huang, Nen-Fu, Chang, Chung-Ying, Chan, Pin-Cheng, Elepano, Arnold R.
Format: Article
Language:English
Subjects:
Accuracy
acoustic spectroscopy
Acoustics
Agriculture
agriculture engineering
Artificial intelligence
Artificial neural networks
Automation
Classification
convolutional neural network
Data collection
Deep learning
Farmers
Farms
Fruits
Machine learning
Meat
Moisture content
Neural networks
pineapple classification
Pineapples
Smartphones
Sound
Spectrograms
Spectroscopy
X-rays
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Summary:The pineapple is an essential fruit in Taiwan. Farmers separate pineapples into two types, according to the percentages of water in the pineapples. One is the “drum sound pineapple” and the other is the “meat sound pineapple”. As there is more water in the meat sound pineapple, the meat sound pineapple more easily rots and is more challenging to store than the drum sound pineapple. Thus, farmers need to filter out the meat sound pineapple, so that they can sell pineapples overseas. The classification, based on striking the pineapple fruit with rigid objects (e.g., plastic rulers) is most commonly used by farmers due to the negligibly low costs and availability. However, it is a time-consuming job, so we propose a method to automatically classify pineapples in this work. Using embedded onboard computing processors, servo, and an ultrasonic sensor, we built a hitting machine and combined it with a conveyor to automatically separate pineapples. To classify pineapples, we proposed a method related to acoustic spectrogram spectroscopy, which uses acoustic data to generate spectrograms. In the acoustic data collection step, we used the hitting machine mentioned before and collected many groups of data with different factors; some groups also included the noise in the farm. With these differences, we tested our deep learning-based convolutional neural network (CNN) performances. The best accuracy of the developed CNN model is 0.97 for data Group V. The proposed hitting machine and the CNN model can assist in the classification of pineapple fruits with high accuracy and time efficiency.
ISSN:2077-0472
2077-0472
DOI:10.3390/agriculture12020129