Behavior-Aware Pedestrian Trajectory Prediction in Ego-Centric Camera Views with Spatio-Temporal Ego-Motion Estimation

Czech, Phillip; Braun, Markus; Kreßel, Ulrich; Yang, Bin

doi:10.3390/make5030050

Cited by 4 publications

(4 citation statements)

References 50 publications

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“…In general, previous works only make predictions for a single future trajectory, that is, they are deterministic (Rasouli et al 2017, Bhattacharyya et al 2018, Rasouli et al 2019, Czech et al 2023. However, in a real traffic environment, there are multiple future modes for pedestrians.…”

Section: Multi-modal Trajectory Predictionmentioning

confidence: 99%

“…The ability to accurately forecast future pedestrian behavior is a relatively simple task for humans, yet it remains a significant challenge for machines at present. Prior research has primarily concentrated on utilizing Recurrent Neural Networks (RNNs) to model (Rasouli et al 2017, Bhattacharyya et al 2018, Rasouli et al 2019, Quan et al 2021, Xue et al 2020, Neumann and Vedaldi 2021, Yao et al 2021, Wang et al 2022, Czech et al 2022, Kalatian and Farooq 2022, Fu and Zhao 2023, Choi et al 2021, Czech et al 2023, with particular emphasis on Long Short-Term Memory (LSTM) (Hochreiter and Schmidhuber 1997) or Gate Recurrent Unit (GRU) (Cho et al 2014). Giuliari et al (2021) incorporated the Transformer Network into trajectory prediction due to its outstanding performance in sequence modeling.…”

Section: Introductionmentioning

confidence: 99%

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VOSTN: Variational One-shot Transformer Network for Pedestrian Trajectory Prediction

Wang,

Sang,

Chen

et al. 2024

Phys. Scr.

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The accurate and reliable prediction of pedestrian future trajectories is of crucial significance for ensuring the safe navigation of autonomous driving systems. This paper introduces a novel approach called the Variational One-Shot Transformer Network (VOSTN) for the prediction of future trajectories within the 2D on-board domain. VOSTN presents an innovative method called the One-Shot Generation Block, which aims to generate queries simultaneously in order to predict future trajectories in a parallel manner. The utilization of the parallel prediction effectively addresses the issue of error accumulation resulting from autoregression, improves the efficiency of inference time, and enhances the precision of long-term trajectory prediction. And the cross-attention module investigates the inter-relationship between trajectory and ego-motion. Given the inherent stochasticity of pedestrian movement, we employ the Conditional Variational AutoEncoder to forecast available multimodal trajectories. Experimental results demonstrate that our model effectively exploits the information associated with trajectory and ego-motion, leading to the acquisition of more comprehensive feature representations. Moreover, our model outperforms the performance of existing methods on the two 2D on-board domain datasets. Our deterministic/multimodal prediction models show a reduction in the bounding box center final displacement error by 8% / 9% and 0.7% / 3% on PIE and JAAD, respectively, when compared to the most optimal baseline.

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Section: Multi-modal Trajectory Predictionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

VOSTN: Variational One-shot Transformer Network for Pedestrian Trajectory Prediction

Wang,

Sang,

Chen

et al. 2024

Phys. Scr.

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“…The interaction between vehicles and pedestrians is a significant factor in predicting their future trajectories. We build upon the work of [59,60,137,138] and implement a VPI cell into the LSTM to improve trajectory prediction by encoding vehicle-pedestrian interaction features into the individual agent LSTM. The process of extracting features related to vehicle-pedestrian interactions involves two steps, and each step has two stages, as depicted in Figure 4.…”

Section: Vehicle-pedestrian Interaction (Vpi) Feature Extractionmentioning

confidence: 99%

“…Expanding on this insightful understanding and drawing inspiration from comprehensive studies [59,60,137,138], we propose the integration of an additional memory cell and dynamic rescaling of the output gate in response to changes in vehicle-pedestrian spatial interaction. We have developed a concept termed the "vehicle-pedestrian interaction (VPI) cell" to further augment the intrinsic interactions among these cues.…”

Section: Trajectory Encodingmentioning

confidence: 99%

Holistic Spatio-Temporal Graph Attention for Trajectory Prediction in Vehicle–Pedestrian Interactions

Alghodhaifi,

Lakshmanan

2023

Sensors

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Ensuring that intelligent vehicles do not cause fatal collisions remains a persistent challenge due to pedestrians’ unpredictable movements and behavior. The potential for risky situations or collisions arising from even minor misunderstandings in vehicle–pedestrian interactions is a cause for great concern. Considerable research has been dedicated to the advancement of predictive models for pedestrian behavior through trajectory prediction, as well as the exploration of the intricate dynamics of vehicle–pedestrian interactions. However, it is important to note that these studies have certain limitations. In this paper, we propose a novel graph-based trajectory prediction model for vehicle–pedestrian interactions called Holistic Spatio-Temporal Graph Attention (HSTGA) to address these limitations. HSTGA first extracts vehicle–pedestrian interaction spatial features using a multi-layer perceptron (MLP) sub-network and max pooling. Then, the vehicle–pedestrian interaction features are aggregated with the spatial features of pedestrians and vehicles to be fed into the LSTM. The LSTM is modified to learn the vehicle–pedestrian interactions adaptively. Moreover, HSTGA models temporal interactions using an additional LSTM. Then, it models the spatial interactions among pedestrians and between pedestrians and vehicles using graph attention networks (GATs) to combine the hidden states of the LSTMs. We evaluate the performance of HSTGA on three different scenario datasets, including complex unsignalized roundabouts with no crosswalks and unsignalized intersections. The results show that HSTGA outperforms several state-of-the-art methods in predicting linear, curvilinear, and piece-wise linear trajectories of vehicles and pedestrians. Our approach provides a more comprehensive understanding of social interactions, enabling more accurate trajectory prediction for safe vehicle navigation.

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Ego-Centric Pedestrian Trajectory Prediction Considering Camera Motion Parameters

Ji,

Liu,

Zheng

et al. 2024

International Conference on Transportation and Development 2024

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Behavior-Aware Pedestrian Trajectory Prediction in Ego-Centric Camera Views with Spatio-Temporal Ego-Motion Estimation

Cited by 4 publications

References 50 publications

VOSTN: Variational One-shot Transformer Network for Pedestrian Trajectory Prediction

VOSTN: Variational One-shot Transformer Network for Pedestrian Trajectory Prediction

Holistic Spatio-Temporal Graph Attention for Trajectory Prediction in Vehicle–Pedestrian Interactions

Ego-Centric Pedestrian Trajectory Prediction Considering Camera Motion Parameters

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