Image recognition is not very effective in the water environment due to multiple factors, such as high scattering and high scattering in the water column. This is why the relevant parameters in the Faster R-CNN network model need to adjust continuously to improve the effectiveness of water detection. The control variable method adjusts the program's learning rate by tuning the network model's parameters. Then, the number of training rounds is adjusted according to the loss function of each round, and finally, we can get the number of matches with the minimum loss function. Based on the experimental results on the dataset, it is shown that the proposed method not only selects the learning rate with the best detection results but also has the strongest robustness and achieves a 96%-99% recognition rate for passenger ships, cargo ships, warships, and bridges compared with other learning rates. Experiments show that the Faster R-CNN network model detects water targets with significant results, and the best network model learning rate parameter is 6×10-3.

기술 트렌드가 증가함에 따라, 엄청난 양의 데이터가 생성되고 있습니다. 많은 양의 데이터가 소비되는 기술 분야 중 하나는 컴퓨터 비전이다. 인간은 기계와 비교할 때 시각에 영향을 미치는 표정, 조명 또는 시야각과 같은 외부 조건에서도 얼굴이나 사물을 쉽게 감지하고 인식할 수 있다. 그 이유는 그것과 관련된 높은 차원 의 데이터 때문이다. 데이터 차원성은 모든 관측치에서 측정되는 변수의 총 수를 말합니다. 이번 사업은 안 면인식시스템에 적합한 다양한 차원감소 기법을 비교하고 조도가 다양한 안면이미지로 구성된 다양한 데이 터세트로 테스트해 모델의 정확도 향상에 도움이 되는 기법의 앙상블 모델을 제안하고 성능을 측정하는 것 이 목적이다.렉스 배경과 표현. 제안된 앙상블 모델은 주성분 분석(PCA)과 로컬 선형 임베딩(LLE)이라는 두 가지 차원 감소 기술의 혼합에서 벡터를 추출하고, 이를 밀도 높은 컨볼루션 신경망(CNN)을 통해 전달하여 야생 면(LFW) 데이터 세트의 얼굴을 예측한다. 이 모형은 0.95의 검정 정확도와 0.94의 검정 F1 점수로 수행 됩니다. 제안된 시스템은 시스템이 얼굴을 예측할 수 있는 제안된 앙상블 모델과 통합된 웹캠에서 라이브 비 디오 스트림을 캡처하는 플라스크를 사용하여 개발된 웹 앱을 포함한다.

The use of radar-based systems for vessel monitoring is not suitable in populated areas, due to the high electromagnetic emissions. In this paper, a camera based vessel recognition system for application in the context of Vessel Traffic Services (VTS) and Homeland Protection (HP) is proposed. Our approach is designed to extend the functionality of traditional VTS systems by permitting the classification of both cooperative and non-cooperative targets, using camera images only. This allows enhancing the surveillance function in populated areas, where public opinion is strongly concerned about electromagnetic emissions and therefore antennas are suspiciously observed and radars are not allowed. Experiments have been carried out on a publicly available data set of images coming from the ARGOS boat traffic monitoring system in the City of Venice (Italy). The obtained classification accuracy of 89.6% (with 11 different classes of boats) demonstrates the effectiveness of the proposed approach.

This paper presents a vision-based fall detection system to automatically monitor and detect people’s fall accidents, particularly those of elderly people or patients. For video analysis, the system should be able to extract both spatial and temporal features so that the model captures appearance and motion information simultaneously. Our approach is based on 3-dimensional convolutional neural networks, which can learn spatiotemporal features. In addition, we adopts a thermal camera in order to handle several issues regarding usability, day and night surveillance and privacy concerns. We design a pan-tilt camera with two actuators to extend the range of view. Performance is evaluated on our thermal dataset: TCL Fall Detection Dataset. The proposed model achieves 90.2% average clip accuracy which is better than other approaches.

As drones gain more popularity these days, drone detection becomes more important part of the drone systems for safety, privacy, crime prevention and etc. However, existing drone detection systems are expensive and heavy so that they are only suitable for industrial or military purpose. This paper proposes a novel approach for training Convolutional Neural Networks to detect drones from images that can be used in embedded systems. Unlike previous works that consider the class probability of the image areas where the class object exists, the proposed approach takes account of all areas in the image for robust classification and object detection. Moreover, a novel loss function is proposed for the CNN to learn more effectively from limited amount of training data. The experimental results with various drone images show that the proposed approach performs efficiently in real drone detection scenarios.