TY - GEN
T1 - Classification of fruit ripeness grades using a convolutional neural network and data augmentation
AU - Rodriguez, Mauricio
AU - Pastor, Franco
AU - Ugarte, Willy
N1 - Publisher Copyright:
© 2021 IEEE Computer Society. All rights reserved.
PY - 2021/1/27
Y1 - 2021/1/27
N2 - Currently the classification processes of the degree of maturity of fruits require the use of complex systems, which, most of the times, are not within the reach of small farmers or consumers who do not have knowledge of the characteristics that a fruit must have in order to be catalogued as immature, mature or rotten. For this reason, a tool that can be accessed by anyone, was designed and implemented through a mobile application that served as an interface. This article describes the use of a convolutional neural network for the classification of the degree of maturity of the following fruits: red apple, green apple, banana, orange and strawberry. First, two sets of images were constructed. Secondly, the data augmentation technique was performed and then the training of the convolutional neuronal network was performed using the dataset images as input. In order to know the performance of the different models generated, the following metrics were used: precision, accuracy, recall, log loss, and f1 score. The best average precision obtained was 96.34%.
AB - Currently the classification processes of the degree of maturity of fruits require the use of complex systems, which, most of the times, are not within the reach of small farmers or consumers who do not have knowledge of the characteristics that a fruit must have in order to be catalogued as immature, mature or rotten. For this reason, a tool that can be accessed by anyone, was designed and implemented through a mobile application that served as an interface. This article describes the use of a convolutional neural network for the classification of the degree of maturity of the following fruits: red apple, green apple, banana, orange and strawberry. First, two sets of images were constructed. Secondly, the data augmentation technique was performed and then the training of the convolutional neuronal network was performed using the dataset images as input. In order to know the performance of the different models generated, the following metrics were used: precision, accuracy, recall, log loss, and f1 score. The best average precision obtained was 96.34%.
UR - https://www.scopus.com/pages/publications/85101227688
U2 - 10.23919/FRUCT50888.2021.9347597
DO - 10.23919/FRUCT50888.2021.9347597
M3 - Contribución a la conferencia
AN - SCOPUS:85101227688
T3 - Conference of Open Innovation Association, FRUCT
BT - Proceedings of the 28th Conference of Open Innovations Association FRUCT, FRUCT 2021
A2 - Balandin, Sergey
A2 - Deart, Vladimir
A2 - Tyutina, Tatiana
PB - IEEE Computer Society
T2 - 28th Conference of Open Innovations Association FRUCT, FRUCT 2021
Y2 - 27 January 2021 through 29 January 2021
ER -