CrownViM: Context Clustering Meets Vision Mamba for Precise Tree Crown Segmentation in Aerial RGB Imagery
Highlights
- CrownViM: First SSM-based framework for tree crown delineation.
- High segmentation accuracy with low parameter count, surpassing Mask R-CNN.
- Context Clustering Vision Mamba + MaskFormer enables precise crown separation.
- Sparse-annotation loss reduces dependency on full pixel-level masks.
Abstract
1. Introduction
2. Related Work
3. Materials and Methods
3.1. Data Collection
- (1)
- The OAM-TCD dataset (Veitch–Michaelis et al., 2024) [43], illustrated in Figure 2a, is an open-source resource for individual tree crown segmentation in high-resolution aerial imagery developed by ETH Zürich and collaborators. It contains 5072 annotated images (2048 × 2048 pixels at 10 cm/pixel resolution) with instance masks delineating >280,000 individual trees and 56,000 tree clusters. Globally sampled across biomes including urban and forest landscapes, the dataset incorporates geographical and ecological diversity through multi-stage sampling and filtering protocols. Primarily applied in ecological monitoring and forest restoration assessment, it enhances quantitative canopy cover accuracy. The high-resolution nature imposes computational constraints: pixel-level operations exhibit quadratic scaling with image edge length, while memory requirements increase linearly with resolution, creating challenges for model parameter optimization and computational efficiency.
- (2)
- The single-tree segmentation dataset (SSD), illustrated in Figure 2b, was developed by the State Key Laboratory of Surveying, Mapping and Remote Sensing Information Engineering at Wuhan University. This specialized dataset serves high-precision single-tree segmentation research, comprising 731 aerial images at 1024 × 1024 pixel resolution. Collected through stratified regional sampling, the dataset captures canopy distribution patterns across diverse forest stands, including coniferous, broad-leaved, and mixed forest types. The high-canopy-closure characteristic of these forests leads to overlapping crown edges and complex shadow patterns, posing significant challenges for accurate edge detection and instance segmentation, which consequently limits segmentation accuracy.
3.2. Deep Learning Method
3.2.1. Mamba and MaskFormer
3.2.2. Overall Architecture
3.2.3. CCViM Feature Encoder with Contextual Clustering
3.2.4. MaskFormer Decoder with Masked Attention
3.2.5. Loss Function
4. Experiments
4.1. Implementation Details
4.2. Configuration of Scan Directions and Local Clusters
4.3. Evaluation Index
4.4. State-of-the-Art Comparison
4.5. Ablation Experiment
4.6. Generalization
4.7. Generalization Experiment
5. Discussion
5.1. State Space Modeling: A Robust Framework for ITCD
5.2. Boundary Separation in Complex Crown Structures
5.3. Balancing Accuracy and Efficiency
5.4. Practical Significance of Sparse-Annotation Supervision
5.5. Limitations and Future Directions
6. Conclusions
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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| Hardware Environment | CPU | AMD EPYC 7763 |
| RAM | 128 G | |
| GPU | NVIDIA RTX 4090 | |
| Video Memory | 24 G | |
| Software Environment | OS | Ubantu 22.04 |
| CUDA Toolkit 12.2; Python 3.8; Pytorch-GPU 1.8.0 | ||
| Data | Metrics | MaskFormer -Swim-T | Mask R-CNN -r50 | Mask RCNN -Swin | Mask2Former | YOLOv8-Seg | Ours |
|---|---|---|---|---|---|---|---|
| OAM-TCD Dataset | Delineation accuracy (%) | 73.67 | 77.92 | 79.15 | 80.23 | 74.45 | 81.85 |
| Precision (%) | 79.43 | 88.75 | 85.62 | 84.78 | 80.32 | 87.18 | |
| Recall (%) | 83.75 | 87.21 | 86.45 | 87.19 | 81.67 | 88.40 | |
| Dice (%) | 78.06 | 82.34 | 81.23 | 81.89 | 76.56 | 84.51 | |
| FPS | 12.5 | 14.2 | 13.8 | 15.6 | 35.3 | 18.7 | |
| Single-tree Dataset | Delineation accuracy (%) | 71.83 | 75.17 | 76.42 | 77.89 | 74.33 | 82.49 |
| 640 × 640 | FLOPs(G) | 105 | 144 | 141 | 112 | 78 | 96 |
| Total Reference Crowns | Error Type | ResNet50 | Swin Transformer | CrownViM |
|---|---|---|---|---|
| 348 | Over-segmented | 43 | 32 | 21 |
| Missed | 102 | 67 | 29 |
| Ablation Variant | Delineation Accuracy (%) | Precision (%) | Recall (%) | Dice (%) |
|---|---|---|---|---|
| w/o Horizontal scan | 80.12 | 86.05 | 87.02 | 83.15 |
| w/o Vertical scan | 80.45 | 86.31 | 87.45 | 83.46 |
| CC clusters: 4 (reduced) | 79.80 | 85.57 | 86.81 | 82.53 |
| CC clusters: 25 (increased) | 81.23 | 86.72 | 87.75 | 83.95 |
| Full supervision loss | 75.92 | 81.62 | 79.82 | 78.36 |
| Full model | 81.85 | 87.18 | 88.40 | 84.51 |
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Share and Cite
Shi, E.; Shi, Z.; Su, F.; Li, L.; Liu, R.; Wan, F.; Zhou, K. CrownViM: Context Clustering Meets Vision Mamba for Precise Tree Crown Segmentation in Aerial RGB Imagery. Remote Sens. 2026, 18, 860. https://doi.org/10.3390/rs18060860
Shi E, Shi Z, Su F, Li L, Liu R, Wan F, Zhou K. CrownViM: Context Clustering Meets Vision Mamba for Precise Tree Crown Segmentation in Aerial RGB Imagery. Remote Sensing. 2026; 18(6):860. https://doi.org/10.3390/rs18060860
Chicago/Turabian StyleShi, Erkang, Ziyang Shi, Fulin Su, Lin Li, Ruifeng Liu, Fangying Wan, and Kai Zhou. 2026. "CrownViM: Context Clustering Meets Vision Mamba for Precise Tree Crown Segmentation in Aerial RGB Imagery" Remote Sensing 18, no. 6: 860. https://doi.org/10.3390/rs18060860
APA StyleShi, E., Shi, Z., Su, F., Li, L., Liu, R., Wan, F., & Zhou, K. (2026). CrownViM: Context Clustering Meets Vision Mamba for Precise Tree Crown Segmentation in Aerial RGB Imagery. Remote Sensing, 18(6), 860. https://doi.org/10.3390/rs18060860

