4,376 research outputs found
Taking a closer look at domain shift: Category-level adversaries for semantics consistent domain adaptation
© 2019 IEEE. We consider the problem of unsupervised domain adaptation in semantic segmentation. The key in this campaign consists in reducing the domain shift, i.e., enforcing the data distributions of the two domains to be similar. A popular strategy is to align the marginal distribution in the feature space through adversarial learning. However, this global alignment strategy does not consider the local category-level feature distribution. A possible consequence of the global movement is that some categories which are originally well aligned between the source and target may be incorrectly mapped. To address this problem, this paper introduces a category-level adversarial network, aiming to enforce local semantic consistency during the trend of global alignment. Our idea is to take a close look at the category-level data distribution and align each class with an adaptive adversarial loss. Specifically, we reduce the weight of the adversarial loss for category-level aligned features while increasing the adversarial force for those poorly aligned. In this process, we decide how well a feature is category-level aligned between source and target by a co-training approach. In two domain adaptation tasks, i.e., GTA5-> Cityscapes and SYNTHIA-> Cityscapes, we validate that the proposed method matches the state of the art in segmentation accuracy
A Realism Metric for Generated LiDAR Point Clouds
A considerable amount of research is concerned with the generation of realistic sensor data. LiDAR point clouds are generated by complex simulations or learned generative models. The generated data is usually exploited to enable or improve downstream perception algorithms. Two major questions arise from these procedures: First, how to evaluate the realism of the generated data? Second, does more realistic data also lead to better perception performance? This paper addresses both questions and presents a novel metric to quantify the realism of LiDAR point clouds. Relevant features are learned from real-world and synthetic point clouds by training on a proxy classification task. In a series of experiments, we demonstrate the application of our metric to determine the realism of generated LiDAR data and compare the realism estimation of our metric to the performance of a segmentation model. We confirm that our metric provides an indication for the downstream segmentation performance
Towards Adaptive Semantic Segmentation by Progressive Feature Refinement
As one of the fundamental tasks in computer vision, semantic segmentation
plays an important role in real world applications. Although numerous deep
learning models have made notable progress on several mainstream datasets with
the rapid development of convolutional networks, they still encounter various
challenges in practical scenarios. Unsupervised adaptive semantic segmentation
aims to obtain a robust classifier trained with source domain data, which is
able to maintain stable performance when deployed to a target domain with
different data distribution. In this paper, we propose an innovative
progressive feature refinement framework, along with domain adversarial
learning to boost the transferability of segmentation networks. Specifically,
we firstly align the multi-stage intermediate feature maps of source and target
domain images, and then a domain classifier is adopted to discriminate the
segmentation output. As a result, the segmentation models trained with source
domain images can be transferred to a target domain without significant
performance degradation. Experimental results verify the efficiency of our
proposed method compared with state-of-the-art methods
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