Real-World Anomaly Detection in Surveillance Videos

Sultani, Waqas; Chen, Chen; Shah, Mubarak

doi:10.1109/cvpr.2018.00678

Cited by 1,397 publications

(1,251 citation statements)

References 39 publications

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“…The segments from abnormal videos have been grouped into positive instances, and the segments of the normal videos have been grouped into the negative instances. Where, C a and C n are the representation for positive group and negative group respectively [3].…”

Section: A Feature Extraction Through the 3d Resnetmentioning

confidence: 99%

“…Equations 3 and 4 are to avoid case 1 of the false alarm, when the model predicts a normal instance as an abnormal instance. Equation 3 compares the maximum ranked instances from each group [3], where the maximum ranked instance from the positive group is most likely to be the true positive and the maximum ranked instance from the negative group can be the case of false positive. Equation 4 compares the maximum ranked instance and minimum ranked instance from the positive group, where the maximum ranked instance from the positive group is most likely to be the true positive and the minimum ranked instance from the positive group can be the case of false positive.…”

Section: B Deep Multiple Instance Learning and Proposed Ranking Lossmentioning

confidence: 99%

“…where, l 1 (C a , C n ) , l 2 (C a , C a ) , l 3 (C a , C n ) and l 4 (C a , C n ) are defined as below: l 4 (C a , C n ) = max 0, 1 − M 3 (S (I a )) + max i∈Cn S I i n (12) As in the study of W. Sultani et al [3], to maintain the temporal smoothness of the abnormality score and to maintain the sparsity of the abnormal scores, two constraints have been proposed as below:…”

Section: B Deep Multiple Instance Learning and Proposed Ranking Lossmentioning

confidence: 99%

“…have been proposed to detect abnormal activities in videos. Recently, W. Sultani et al [3], has proposed a new approach to solve all the shortcomings of the traditional approaches. In their method, to detect the abnormal activity, they have trained their model with the help of multiple instance learning (MIL) [13], [14] by utilizing the weakly labeled training videos.…”

Section: Introductionmentioning

confidence: 99%

“…Where recent advancement of 3D deep neural network in the video action recognition task motivates us to use 3D ResNet [15], [16] in the abnormal activity detection task. Extracted features from 3D ResNet and video-level labeling are used to train the model in a weakly-supervised manner with the help of deep MIL [3], [13] along with the new proposed ranking loss.…”

Section: Introductionmentioning

confidence: 99%

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3D ResNet with Ranking Loss Function for Abnormal Activity Detection in Videos

Dubey

Boragule

Jeon

2019

2019 International Conference on Control, Automation and Information Sciences (ICCAIS)

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Abnormal activity detection is one of the most challenging tasks in the field of computer vision. This study is motivated by the recent state-of-art work of abnormal activity detection, which utilizes both abnormal and normal videos in learning abnormalities with the help of multiple instance learning by providing the data with video-level information. In the absence of temporal-annotations, such a model is prone to give a false alarm while detecting the abnormalities. For this reason, in this paper, we focus on the task of minimizing the false alarm rate while performing an abnormal activity detection task. The mitigation of these false alarms and recent advancement of 3D deep neural network in video action recognition task collectively give us motivation to exploit the 3D ResNet in our proposed method, which helps to extract spatial-temporal features from the videos. Afterwards, using these features and deep multiple instance learning along with the proposed ranking loss, our model learns to predict the abnormality score at the video segment level. Therefore, our proposed method 3D deep Multiple Instance Learning with ResNet (MILR) along with the new proposed ranking loss function achieves the best performance on the UCF-Crime benchmark dataset, as compared to other state-of-art methods. The effectiveness of our proposed method is demonstrated on the UCF-Crime dataset.

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Section: A Feature Extraction Through the 3d Resnetmentioning

confidence: 99%

Section: B Deep Multiple Instance Learning and Proposed Ranking Lossmentioning

confidence: 99%

Section: B Deep Multiple Instance Learning and Proposed Ranking Lossmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

3D ResNet with Ranking Loss Function for Abnormal Activity Detection in Videos

Dubey

Boragule

Jeon

2019

2019 International Conference on Control, Automation and Information Sciences (ICCAIS)

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AI and core electoral processes: Mapping the horizons

Simoes,

MacCarthaigh

2023

AI Magazine

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It is well documented that there has been significant enthusiasm across the globe in respect of using AI for all forms of social activity. However, the electoral process – the time, place, and manner of elections within democratic nations – is one of few sectors in which there has been limited penetration of AI. Electoral management bodies in many countries have recently started exploring and deliberating over the use of AI in the electoral process. In this paper, we consider five avenues within the core electoral process which have potential for AI usage, and map the challenges involved in using AI within them. These five avenues are: voter list maintenance, determining polling booth locations, polling booth protection processes, voter authentication, and video monitoring of elections. Within each avenue, we lay down the context, illustrate current or potential usage of AI, and discuss extant or potential ramifications of AI usage, as well as potential directions for mitigating risks when considering AI usage. We believe that the scant current usage of AI within electoral processes provides a very rare opportunity to deliberate on the risks and mitigation possibilities prior to actual and widespread AI deployment. This paper is an attempt to map the horizons of risks and opportunities in using AI within electoral processes and to help shape the debate around the topic.

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Abnormal behavior detection of stationary objects in surveillance videos with visualization and classification

Sharma

Gangadharappa

2022

Concurrency and Computation

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Anomaly detection in video systems has been popular over several years. It is still challenging to detect anomalies in a static object. To manage this objective, we focus on changes in the position of a stationary object in videos. In a normal scenario, the pixel values of the static object are fixed while in abnormal motion the fixed values change.We introduce a new concept to determine anomalies based on manual annotations in each video frame, only over a part of a static object in a frame such that it can be taken as a reference for the whole. Through color channel splitting we determine mask image, from which handcrafted features such as scratch area, perimeter, equivalent diameter and density are calculated. In the next step, we analyze frame-wise changes in feature values using a linear regression model, feature values are constant when the object remains stationary while there is a rise or fall in values when an object changes location. We classify feature values through anomaly scores and thresholds. In this model, we are evaluating our proposed framework on 12 real-time video datasets. Results are compared with existing techniques which are outperforming in terms of accuracy, mean square error and area under the curve.

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Real-World Anomaly Detection in Surveillance Videos

Cited by 1,397 publications

References 39 publications

3D ResNet with Ranking Loss Function for Abnormal Activity Detection in Videos

3D ResNet with Ranking Loss Function for Abnormal Activity Detection in Videos

AI and core electoral processes: Mapping the horizons

Abnormal behavior detection of stationary objects in surveillance videos with visualization and classification

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