光流
可解释性
人工智能
计算机科学
特征(语言学)
机器学习
一般化
里程计
深度学习
计算机视觉
模式识别(心理学)
卷积神经网络
面子(社会学概念)
视觉里程计
特征提取
姿势
特征学习
核(代数)
弹道
适应性
特征选择
流量(数学)
上下文图像分类
稀疏逼近
点(几何)
趋同(经济学)
图像(数学)
特征工程
眼动
面部识别系统
点云
数据建模
计算复杂性理论
自适应光学
接头(建筑物)
作者
Qiang Liu,Baojia Chen,Zhiqiang Hao,Xinlong Li,Leilei Xiang,Juan Liu
标识
DOI:10.1109/tpami.2025.3627192
摘要
Contemporary deep learning approaches for optical flow estimation continue to face persistent challenges in model interpretability, generalization capacity, and deployment efficiency, significantly constraining their practical implementation. This limitation becomes particularly critical in applications such as visual odometry (VO), where precise sparse point tracking supersedes the conventional emphasis on dense optical flow accuracy. Moreover, the lack of a joint framework combining keypoint detection and optical flow estimation limits sparse optical flow performance. To address these fundamental issues, we propose a novel dual-task imperative learning framework that synergistically optimizes sparse optical flow estimation (iFLOW) with adaptive keypoint detection (iPOINT). Our methodology implements an Expectation-Maximization (EM) paradigm where iFLOW and iPOINT undergo alternating optimization through a Gauss-Newton reasoning engine. This innovative architecture leverages convolutional feature advantages under the generalized feature invariance principle. The resulting imperative learning mechanism imbues our framework with enchanced interpretability and cross-domain adaptability while maintaining computational efficiency. Through comparative evaluations against classical and learning-based baselines, our ultra-compact models (0.05M parameters for iFLOW, 0.09M for iPOINT) demonstrate remarkable performance across multiple metrics (End-point Error, F1-all, VO trajectory accuracy) despite requiring only 200 training image pairs.
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