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Prompt Learning with Optimal Transport for Efficient Few-Shot Temporal Action Localization


Основні поняття
A novel prompt learning framework with optimal transport that effectively aligns multiple prompts to video features across different temporal scales, enabling robust and accurate few-shot temporal action localization.
Анотація

The paper introduces a novel approach to temporal action localization (TAL) in few-shot learning settings. It addresses the limitations of conventional single-prompt learning methods that often lead to overfitting due to the inability to generalize across varying contexts in real-world videos.

Key highlights:

  • Proposes a multi-prompt learning framework enhanced with optimal transport to capture the diversity of camera views, backgrounds, and objects in videos.
  • The multi-prompt design allows the model to learn a set of diverse prompts for each action, capturing general characteristics more effectively and distributing the representation to mitigate overfitting.
  • Employs optimal transport theory to efficiently align these prompts with action features, optimizing for a comprehensive representation that adapts to the multifaceted nature of video data.
  • Experiments demonstrate significant improvements in action localization accuracy and robustness in few-shot settings on THUMOS-14 and EpicKitchens100 datasets.
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Статистика
The moment a golfer swings and hits a ball in front of a fairway with trees. The necessity for few-shot learning methods in temporal action localization (TAL) stems from the inherent challenge of annotating video data, as annotators must watch videos in their entirety to accurately label action instances.
Цитати
"Current approaches to few-shot learning for temporal action localization take a meta-learning approach [34, 37], where each test video is aligned to a small subset of the training data in many 'episodes.' These methods require learning a model from initialization, with no priors, consuming large amounts of memory and compute." "A recent training paradigm, prompt learning, has been used to reduce the number of trainable parameters, where all parameters of the model are fixed, and a learnable context vector is added to the prompt to improve the alignment between the prompt and the image features. [8,15,60,61]."

Ключові висновки, отримані з

by Edward Fish,... о arxiv.org 03-29-2024

https://arxiv.org/pdf/2403.18915.pdf
PLOT-TAL -- Prompt Learning with Optimal Transport for Few-Shot Temporal  Action Localization

Глибші Запити

How can the proposed multi-prompt framework be extended to other video understanding tasks beyond temporal action localization, such as video classification or video question answering

The proposed multi-prompt framework can be extended to other video understanding tasks by adapting the concept of multiple prompts and optimal transport alignment to suit the specific requirements of each task. For video classification, the model can be trained with multiple prompts representing different aspects or features of the videos, such as objects, scenes, or actions. These prompts can help the model capture a more comprehensive understanding of the video content, leading to improved classification accuracy. Additionally, the optimal transport-based alignment can be utilized to align these prompts with the video features, optimizing the representation learning process. In the case of video question answering, the multi-prompt framework can be leveraged to generate prompts that encapsulate relevant information for answering questions about the video content. By incorporating prompts that focus on key elements or events in the video, the model can better comprehend the context and provide accurate answers. The optimal transport alignment can then be used to align these prompts with the video features and question embeddings, facilitating effective reasoning and inference. Overall, by customizing the prompts and alignment strategy to suit the specific requirements of video classification or question answering tasks, the multi-prompt framework can be extended to enhance performance and adaptability across a range of video understanding applications.

What are the potential drawbacks or limitations of the optimal transport-based alignment approach, and how could they be addressed in future work

While the optimal transport-based alignment approach offers significant benefits in improving the discriminative ability of the model and enhancing feature alignment, there are potential drawbacks and limitations that should be considered for future work. One limitation is the computational complexity of the optimal transport algorithm, especially when dealing with high-dimensional feature spaces or large-scale datasets. This can lead to increased training and inference times, making the approach less scalable for real-world applications. To address this limitation, future research could focus on developing more efficient optimization techniques or approximations that maintain the effectiveness of optimal transport while reducing computational overhead. Another drawback is the sensitivity of optimal transport to noise and outliers in the data, which can impact the quality of the alignment and overall performance of the model. To mitigate this issue, incorporating robust optimization strategies or regularization techniques into the alignment process could help improve the model's resilience to noisy data and enhance its generalization capabilities. Furthermore, the optimal transport-based alignment approach may require careful hyperparameter tuning and fine-tuning to achieve optimal results, which can be challenging and time-consuming. Future work could explore automated methods for hyperparameter optimization or adaptive learning strategies to streamline the tuning process and improve the overall efficiency of the alignment approach.

Given the importance of temporal dynamics in video understanding, how could the model's ability to capture and leverage temporal information be further improved beyond the current feature pyramid approach

To further enhance the model's ability to capture and leverage temporal information beyond the current feature pyramid approach, several strategies can be explored: Temporal Attention Mechanisms: Introducing temporal attention mechanisms can help the model focus on relevant temporal segments within the video, allowing it to dynamically adjust the importance of different frames based on the context of the action being localized. Temporal Convolutional Networks: Incorporating temporal convolutional layers can enable the model to capture long-range temporal dependencies and patterns in the video data, enhancing its ability to recognize complex action sequences and dynamics. Recurrent Neural Networks (RNNs): Utilizing RNNs, such as Long Short-Term Memory (LSTM) or Gated Recurrent Unit (GRU), can enable the model to learn sequential patterns and temporal relationships over extended time periods, improving its understanding of temporal dynamics. Temporal Segmentation: Implementing a temporal segmentation approach to divide the video into meaningful segments based on action boundaries or temporal cues can help the model focus on specific temporal intervals, facilitating more precise action localization and classification. By integrating these advanced techniques and methodologies into the model architecture, the model's temporal understanding and analysis capabilities can be significantly enhanced, leading to improved performance in capturing and leveraging temporal information for video understanding tasks.
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