PROHIBITED OBJECT RECOGNITION SIMILARITY-BASED USING SIAMESE NETWORK IN X-RAY BAGGAGE INSPECTION
Baggage and passengers are two inseparable elements, which is why passenger baggage screening is a crucial process in transportation, especially in air travel, sea vessels, trains, and others. In the baggage screening process, the main source currently used is human professionals. However, human...
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| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/73913 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Baggage and passengers are two inseparable elements, which is why passenger
baggage screening is a crucial process in transportation, especially in air travel,
sea vessels, trains, and others. In the baggage screening process, the main source
currently used is human professionals. However, human professionals are subject
to performance changes caused by fatigue, emotions, and other factors. Therefore,
an automated system is needed to assist humans in identifying hazardous objects
present in passenger baggage.
This research proposes an automated system that assists humans in identifying
hazardous objects. The study adopts a different approach from the typical object
recognition approach, which is the similarity approach. The similarity approach
overcomes the limitations of the commonly used object recognition approaches
(classification/probability approaches) in that it can identify partially occluded
objects, while classification/probability approaches require complete object
samples during the training process to achieve recognition.
In this research, three main experimental scenarios were conducted. Firstly, an
experimental scenario was conducted to implement Region Proposal Network
(RPN) as a detector. Secondly, an experimental scenario was conducted to
implement various types of deep learning architectures and Siamese Neural
Networks (SNN). Thirdly, an experimental scenario was conducted to combine the
RPN and SNN architectures. The study utilized image size of 75x75x3, batch size of
32, and several deep learning encoders such as ResNet50, ResNet101,
EfficientNetB7, and InceptionV3. The research results showed that the SNN
achieved the best performance with an accuracy score of 88%, while conventional
deep learning models only achieved an accuracy score of 74%. This research
demonstrates that the SNN model can identify novel objects that have not been seen
in the training data, eliminating the need to retrain the model. |
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