5,491 research outputs found
DyAnNet: A Scene Dynamicity Guided Self-Trained Video Anomaly Detection Network
Unsupervised approaches for video anomaly detection may not perform as good
as supervised approaches. However, learning unknown types of anomalies using an
unsupervised approach is more practical than a supervised approach as
annotation is an extra burden. In this paper, we use isolation tree-based
unsupervised clustering to partition the deep feature space of the video
segments. The RGB- stream generates a pseudo anomaly score and the flow stream
generates a pseudo dynamicity score of a video segment. These scores are then
fused using a majority voting scheme to generate preliminary bags of positive
and negative segments. However, these bags may not be accurate as the scores
are generated only using the current segment which does not represent the
global behavior of a typical anomalous event. We then use a refinement strategy
based on a cross-branch feed-forward network designed using a popular I3D
network to refine both scores. The bags are then refined through a segment
re-mapping strategy. The intuition of adding the dynamicity score of a segment
with the anomaly score is to enhance the quality of the evidence. The method
has been evaluated on three popular video anomaly datasets, i.e., UCF-Crime,
CCTV-Fights, and UBI-Fights. Experimental results reveal that the proposed
framework achieves competitive accuracy as compared to the state-of-the-art
video anomaly detection methods.Comment: 10 pages, 8 figures, and 4 tables. (ACCEPTED AT WACV 2023
Learning Deep Representations of Appearance and Motion for Anomalous Event Detection
We present a novel unsupervised deep learning framework for anomalous event
detection in complex video scenes. While most existing works merely use
hand-crafted appearance and motion features, we propose Appearance and Motion
DeepNet (AMDN) which utilizes deep neural networks to automatically learn
feature representations. To exploit the complementary information of both
appearance and motion patterns, we introduce a novel double fusion framework,
combining both the benefits of traditional early fusion and late fusion
strategies. Specifically, stacked denoising autoencoders are proposed to
separately learn both appearance and motion features as well as a joint
representation (early fusion). Based on the learned representations, multiple
one-class SVM models are used to predict the anomaly scores of each input,
which are then integrated with a late fusion strategy for final anomaly
detection. We evaluate the proposed method on two publicly available video
surveillance datasets, showing competitive performance with respect to state of
the art approaches.Comment: Oral paper in BMVC 201
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