UST: Unifying Spatio-Temporal Context for Trajectory Prediction in Autonomous Driving

Accurate human path forecasting in complex and crowded scenarios is critical for collision avoidance of autonomous driving and social robots navigation. It still remains as a challenging problem because of dynamic human interaction and intrinsic multimodality of human motion. Given the observation, there is a rich set of plausible ways for an agent to walk through the circumstance. To address those issues, we propose a spatio-temporal model that can aggregate the information from socially interacting agents and capture the multimodality of the motion patterns. We use mixture density functions to describe the human path and predict the distribution of future paths with explicit density. To integrate more factors to model interacting people, we further introduce a coordinate transformation to represent the relative motion between people. Extensive experiments over several trajectory prediction benchmarks demonstrate that our method is able to forecast various plausible futures in complex scenarios and achieves state-of-the-art performance.

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Trajectory distributions: A new description of movement for trajectory prediction

Computational Visual Media ◽

10.1007/s41095-021-0236-6 ◽

2021 ◽

Vol 8 (2) ◽

pp. 213-224

Author(s):

Pei Lv ◽

Hui Wei ◽

Tianxin Gu ◽

Yuzhen Zhang ◽

Xiaoheng Jiang ◽

...

Keyword(s):

Prediction Method ◽

Autonomous Driving ◽

Probability Method ◽

Trajectory Prediction ◽

Intelligent Robots ◽

Temporal Features ◽

Movement Characteristics ◽

The Social ◽

Benchmark Datasets ◽

Spatio Temporal

AbstractTrajectory prediction is a fundamental and challenging task for numerous applications, such as autonomous driving and intelligent robots. Current works typically treat pedestrian trajectories as a series of 2D point coordinates. However, in real scenarios, the trajectory often exhibits randomness, and has its own probability distribution. Inspired by this observation and other movement characteristics of pedestrians, we propose a simple and intuitive movement description called a trajectory distribution, which maps the coordinates of the pedestrian trajectory to a 2D Gaussian distribution in space. Based on this novel description, we develop a new trajectory prediction method, which we call the social probability method. The method combines trajectory distributions and powerful convolutional recurrent neural networks. Both the input and output of our method are trajectory distributions, which provide the recurrent neural network with sufficient spatial and random information about moving pedestrians. Furthermore, the social probability method extracts spatio-temporal features directly from the new movement description to generate robust and accurate predictions. Experiments on public benchmark datasets show the effectiveness of the proposed method.

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Trajectory Prediction-Based Local Spatio-Temporal Navigation Map for Autonomous Driving in Dynamic Highway Environments

IEEE Transactions on Intelligent Transportation Systems ◽

10.1109/tits.2021.3057110 ◽

2021 ◽

pp. 1-12

Author(s):

Mengyin Fu ◽

Ting Zhang ◽

Wenjie Song ◽

Yi Yang ◽

Meiling Wang

Keyword(s):

Autonomous Driving ◽

Trajectory Prediction ◽

Spatio Temporal

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Imaging through Scattering Media with a Learning Based Prior

Electronic Imaging ◽

10.2352/issn.2470-1173.2020.14.coimg-306 ◽

2020 ◽

Vol 2020 (14) ◽

pp. 306-1-306-6

Author(s):

Florian Schiffers ◽

Lionel Fiske ◽

Pablo Ruiz ◽

Aggelos K. Katsaggelos ◽

Oliver Cossairt

Keyword(s):

Optimization Problem ◽

Autonomous Driving ◽

Scattering Media ◽

Photon Scattering ◽

Point Spread ◽

Spread Function ◽

Radiative Transport Equation ◽

Spatio Temporal ◽

Transient Imaging

Imaging through scattering media finds applications in diverse fields from biomedicine to autonomous driving. However, interpreting the resulting images is difficult due to blur caused by the scattering of photons within the medium. Transient information, captured with fast temporal sensors, can be used to significantly improve the quality of images acquired in scattering conditions. Photon scattering, within a highly scattering media, is well modeled by the diffusion approximation of the Radiative Transport Equation (RTE). Its solution is easily derived which can be interpreted as a Spatio-Temporal Point Spread Function (STPSF). In this paper, we first discuss the properties of the ST-PSF and subsequently use this knowledge to simulate transient imaging through highly scattering media. We then propose a framework to invert the forward model, which assumes Poisson noise, to recover a noise-free, unblurred image by solving an optimization problem.

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Spatio-Temporal Context, Correlation Filter and Measurement Estimation Collaboration Based Visual Object Tracking

Sensors ◽

10.3390/s21082841 ◽

2021 ◽

Vol 21 (8) ◽

pp. 2841

Author(s):

Khizer Mehmood ◽

Abdul Jalil ◽

Ahmad Ali ◽

Baber Khan ◽

Maria Murad ◽

...

Keyword(s):

Kalman Filter ◽

Object Tracking ◽

Environmental Changes ◽

Correlation Filter ◽

Temporal Context ◽

Visual Object ◽

Target Model ◽

Change Of Scale ◽

Tracking Model ◽

Spatio Temporal

Despite eminent progress in recent years, various challenges associated with object tracking algorithms such as scale variations, partial or full occlusions, background clutters, illumination variations are still required to be resolved with improved estimation for real-time applications. This paper proposes a robust and fast algorithm for object tracking based on spatio-temporal context (STC). A pyramid representation-based scale correlation filter is incorporated to overcome the STC’s inability on the rapid change of scale of target. It learns appearance induced by variations in the target scale sampled at a different set of scales. During occlusion, most correlation filter trackers start drifting due to the wrong update of samples. To prevent the target model from drift, an occlusion detection and handling mechanism are incorporated. Occlusion is detected from the peak correlation score of the response map. It continuously predicts target location during occlusion and passes it to the STC tracking model. After the successful detection of occlusion, an extended Kalman filter is used for occlusion handling. This decreases the chance of tracking failure as the Kalman filter continuously updates itself and the tracking model. Further improvement to the model is provided by fusion with average peak to correlation energy (APCE) criteria, which automatically update the target model to deal with environmental changes. Extensive calculations on the benchmark datasets indicate the efficacy of the proposed tracking method with state of the art in terms of performance analysis.

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