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Generating Realistic LiDAR Scenes with Curve-based Diffusion Models


Conceitos Básicos
LiDAR Diffusion Models (LiDMs) can efficiently generate high-quality and realistic LiDAR scenes from diverse conditions such as semantic maps, camera views, and text prompts.
Resumo

The paper proposes LiDAR Diffusion Models (LiDMs), a novel generative framework for efficient and realistic LiDAR scene generation. The key contributions are:

  1. LiDMs leverage range images as the data representation, which enables reversible and lossless conversion between range images and point clouds, and benefits from highly optimized 2D convolutional operations.

  2. To achieve LiDAR-realistic generation, LiDMs incorporate three core designs: curve-wise compression to maintain the curve-like patterns, point-wise coordinate supervision to regularize the scene-level geometry, and patch-wise encoding to capture the full context of 3D objects.

  3. LiDMs support diverse conditioning inputs, including semantic maps, camera views, and text prompts, enabling applications such as Semantic-Map-to-LiDAR, Camera-to-LiDAR, and zero-shot Text-to-LiDAR generation.

  4. Extensive experiments demonstrate that LiDMs outperform previous state-of-the-art methods on both unconditional and conditional LiDAR scene generation, while achieving a significant speedup of up to 107x.

  5. The paper introduces three novel perceptual metrics (FRID, FSVD, FPVD) to comprehensively evaluate the quality of generated LiDAR scenes.

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Estatísticas
Throughput of LiDMs is around 107x faster than point-based DMs (LiDARGen). Inference speed of LiDMs is around 4.6x faster than LiDARGen.
Citações
"To enable conditional LiDAR-realistic scene generation, we thereby propose a curve-based generator, termed LiDAR Diffusion Models (LiDMs), to answer the aforementioned questions and tackle the shortcomings of recent works." "LiDMs leverage range images as the representations of LiDAR scenes, which are prevalent in various downstream tasks such as detection [34, 43], semantic segmentation [44, 65], and generation [73]." "To further improve the realistic simulation of real-world LiDAR data, we focus on three key components: pattern realism, geometry realism, and object realism."

Principais Insights Extraídos De

by Haoxi Ran,Vi... às arxiv.org 04-02-2024

https://arxiv.org/pdf/2404.00815.pdf
Towards Realistic Scene Generation with LiDAR Diffusion Models

Perguntas Mais Profundas

How can LiDMs be extended to handle more diverse and complex conditioning inputs beyond the ones explored in this paper, such as multi-modal sensor fusion or interactive user guidance

LiDMs can be extended to handle more diverse and complex conditioning inputs by incorporating multi-modal sensor fusion and interactive user guidance. For multi-modal sensor fusion, LiDMs can be trained to integrate data from various sensors like cameras, radars, and LiDAR to provide a more comprehensive understanding of the environment. This fusion of data can enhance the realism and accuracy of the generated LiDAR scenes. Additionally, by incorporating interactive user guidance, LiDMs can take real-time feedback or instructions from users to adapt the generated scenes according to specific requirements or scenarios. This interactive feature can make LiDMs more versatile and adaptable to dynamic situations.

What are the potential limitations of the current LiDM approach, and how could future research address them to further improve the realism and controllability of generated LiDAR scenes

The current LiDM approach may have limitations in terms of generating highly detailed and realistic LiDAR scenes, especially when it comes to capturing fine details, sharp boundaries, and complex object interactions. Future research could address these limitations by: Enhancing Autoencoder Performance: Improving the autoencoder architecture to better preserve scene-level geometry, sharper boundaries, and intricate object details during the compression process. Incorporating Advanced Loss Functions: Implementing more sophisticated loss functions that focus on capturing fine details and improving the overall quality of the generated scenes. Exploring Advanced Diffusion Models: Investigating more advanced diffusion models or hybrid approaches that combine different generative techniques to enhance the realism and controllability of LiDAR scene generation. Data Augmentation and Regularization: Utilizing advanced data augmentation techniques and regularization methods to train LiDMs on a more diverse and extensive dataset, enabling them to learn a wider range of scene variations and complexities. By addressing these potential limitations, future research can further improve the realism and controllability of generated LiDAR scenes, making them more suitable for a wide range of applications in autonomous driving, robotics, and other related fields.

Given the efficient and high-quality LiDAR scene generation capabilities of LiDMs, how could they be leveraged to benefit downstream tasks in autonomous driving, robotics, and other domains that rely on LiDAR data

Given the efficient and high-quality LiDAR scene generation capabilities of LiDMs, they can be leveraged to benefit downstream tasks in various domains: Autonomous Driving: LiDMs can be used to generate realistic LiDAR scenes for training autonomous driving systems, enabling them to learn from diverse and complex scenarios in a simulated environment. This can enhance the robustness and adaptability of autonomous vehicles to different road conditions. Robotics: In robotics applications, LiDMs can assist in simulating LiDAR data for robot navigation, object detection, and mapping tasks. The generated scenes can be used to train robot perception systems and improve their performance in real-world scenarios. Environmental Monitoring: LiDMs can be applied to generate LiDAR scenes for environmental monitoring tasks such as forestry management, disaster response, and urban planning. The generated scenes can provide valuable insights into the environment and help in decision-making processes. Virtual Reality and Simulation: LiDMs can be utilized in virtual reality and simulation applications to create immersive and realistic virtual environments. By generating high-quality LiDAR scenes, LiDMs can enhance the visual fidelity and interactivity of virtual simulations for training and entertainment purposes.
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