Comprehensive Remote Sensing Image Interpretation through Fine-Grained Panoptic Perception
Konsep Inti
Panoptic Perception is a novel task that integrates pixel-level, instance-level, and image-level interpretation of remote sensing images to achieve a more thorough and universal understanding.
Abstrak
The paper proposes a novel task called Panoptic Perception that aims to achieve comprehensive remote sensing image interpretation. Unlike conventional single-task models, Panoptic Perception simultaneously performs fine-grained instance segmentation, background semantic segmentation, and image captioning.
The key highlights are:
- Panoptic Perception integrates pixel-level, instance-level, and image-level understanding to construct a universal interpretation framework.
- The authors construct a new benchmark dataset called FineGrip that supports multi-modal tasks including fine-grained instance segmentation, semantic segmentation, and image captioning.
- A semi-automatic annotation system is designed to enhance annotation efficiency by leveraging the zero-shot generalization ability of foundation models.
- An end-to-end panoptic perception baseline method is introduced that demonstrates the feasibility of the proposed task and the beneficial effect of multi-task joint optimization.
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Panoptic Perception
Statistik
The FineGrip dataset contains 2,649 remote sensing images, 12,054 fine-grained instance segmentation masks, 7,599 background semantic masks, and 13,245 captioning sentences.
The dataset covers 20 fine-grained foreground aircraft categories and 5 background stuff categories.
Kutipan
"Panoptic Perception integrates pixel-level, instance-level, and image-level understanding to construct a universal interpretation framework."
"The proposed panoptic perception integrates pixel-level, instance-level, and image-level understanding to construct a universal interpretation framework."
Pertanyaan yang Lebih Dalam
How can the proposed panoptic perception task be extended to other remote sensing application domains beyond airport scenes
The proposed panoptic perception task can be extended to other remote sensing application domains beyond airport scenes by adapting the model to different types of remote sensing imagery and target objects. For instance, in agricultural monitoring, the model can be trained to recognize various crops, pests, and soil types. In disaster management, it can be used to identify damaged buildings, roads, and other infrastructure. By adjusting the categories and training data, the panoptic perception model can be tailored to different remote sensing applications. Additionally, incorporating domain-specific knowledge and features can enhance the model's performance in diverse scenarios.
What are the potential challenges in achieving end-to-end joint optimization across the segmentation and captioning tasks, and how can they be addressed
Achieving end-to-end joint optimization across the segmentation and captioning tasks poses several challenges. One challenge is balancing the contribution of each task during training to prevent one task from dominating the optimization process. This can be addressed by carefully tuning the weights assigned to each task in the loss function. Another challenge is ensuring that the model effectively integrates information from both tasks to improve overall performance. This can be addressed by designing a model architecture that facilitates information flow between the segmentation and captioning modules, allowing them to interact and complement each other. Additionally, incorporating task-specific constraints and regularization techniques can help guide the joint optimization process and prevent overfitting.
How can the semi-automatic annotation system be further improved to handle a wider range of remote sensing targets and scenes
To further improve the semi-automatic annotation system for handling a wider range of remote sensing targets and scenes, several enhancements can be implemented.
Enhanced Prompt Generation: Develop more sophisticated algorithms for generating bounding box prompts based on the characteristics of different remote sensing targets. This can involve incorporating domain-specific knowledge and leveraging advanced computer vision techniques.
Improved Annotation Refinement: Implement more efficient and accurate methods for refining segmentation annotations, such as leveraging active learning strategies to prioritize challenging or ambiguous regions for manual correction.
Domain Adaptation: Explore techniques for domain adaptation to improve the generalization of the annotation system across different remote sensing scenes and target objects. This can involve fine-tuning the system on diverse datasets to enhance its performance in varied environments.
Interactive Annotation Tools: Develop interactive annotation tools that allow users to provide feedback and corrections during the annotation process, enabling real-time adjustments and improvements to the annotations.
Automated Quality Control: Implement automated quality control mechanisms to detect and correct annotation errors, ensuring the accuracy and consistency of the annotated data. This can involve the use of anomaly detection algorithms and validation checks to identify and rectify inconsistencies in the annotations.