Bernard Lange scite author profile

Safe and proactive planning in robotic systems generally requires accurate predictions of the environment. Prior work on environment prediction applied video frame prediction techniques to bird's-eye view environment representations, such as occupancy grids. ConvLSTM-based frameworks used previously often result in significant blurring and vanishing of moving objects, thus hindering their applicability for use in safety-critical applications. In this work, we propose two extensions to the ConvLSTM to address these issues. We present the Temporal Attention Augmented ConvLSTM (TAAConvLSTM) and Self-Attention Augmented ConvLSTM (SAAConvLSTM) frameworks for spatiotemporal occupancy prediction, and demonstrate improved performance over baseline architectures on the real-world KITTI and Waymo datasets. We provide our implementation at https://github.com/sisl/AttentionAugmentedConvLSTM.

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LOPR: Latent Occupancy PRediction using Generative Models

Lange¹,

Itkina²,

Kochenderfer³

2022

Preprint

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Environment prediction frameworks are essential for autonomous vehicles to facilitate safe maneuvers in a dynamic environment. Previous approaches have used occupancy grid maps as a bird's eye-view representation of the scene and optimized the prediction architectures directly in pixel space. Although these methods have had some success in spatiotemporal prediction, they are, at times, hindered by unrealistic and incorrect predictions. We postulate that the quality and realism of the forecasted occupancy grids can be improved with the use of generative models. We propose a framework that decomposes occupancy grid prediction into task-independent low-dimensional representation learning and task-dependent prediction in the latent space. We demonstrate that our approach achieves state-of-the-art performance on the real-world autonomous driving dataset, NuScenes. We provide our implementation at https:/github.com/sisl/LOPR.

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How Do We Fail? Stress Testing Perception in Autonomous Vehicles

Delecki

Itkina

Lange

et al. 2022

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How Do We Fail? Stress Testing Perception in Autonomous Vehicles

Delecki¹,

Itkina²,

Lange³

et al. 2022

Preprint

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Autonomous vehicles (AVs) rely on environment perception and behavior prediction to reason about agents in their surroundings. These perception systems must be robust to adverse weather such as rain, fog, and snow. However, validation of these systems is challenging due to their complexity and dependence on observation histories. This paper presents a method for characterizing failures of LiDAR-based perception systems for AVs in adverse weather conditions. We develop a methodology based in reinforcement learning to find likely failures in object tracking and trajectory prediction due to sequences of disturbances. We apply disturbances using a physicsbased data augmentation technique for simulating LiDAR point clouds in adverse weather conditions. Experiments performed across a wide range of driving scenarios from a real-world driving dataset show that our proposed approach finds high likelihood failures with smaller input disturbances compared to baselines while remaining computationally tractable. Identified failures can inform future development of robust perception systems for AVs.

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Building a Large-Scale Information System for the Education Sector: A Project Experience

Gruszczynski¹,

Lange²,

Maciejewski³

et al. 2005

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Implementing a large-scale information system for the education sector involves a number of engineering challenges, such as high security and correctness standards imposed by the law, a large and varied group of end users, or fault-tolerance and a distributed character of processing. In this paper we report on our experiences with building and deploying a senior high school recruitment system for five major cities in Poland. We discuss system architecture and design decisions, such as thin vs. rich client, on-line vs. off-line processing, dedicated network vs. Internet environment. We also analyse potential problems our present approach may cause in the future.

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Bernard Lange

Attention Augmented ConvLSTM for Environment Prediction

LOPR: Latent Occupancy PRediction using Generative Models

How Do We Fail? Stress Testing Perception in Autonomous Vehicles

How Do We Fail? Stress Testing Perception in Autonomous Vehicles

Building a Large-Scale Information System for the Education Sector: A Project Experience

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