Is attention to bounding boxes all you need for pedestrian action prediction?

Achaji, Lina; Moreau, Julien; Fouqueray, Thibault; Aioun, François; Charpillet, François

doi:10.48550/arxiv.2107.08031

Cited by 2 publications

(3 citation statements)

References 27 publications

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“…More successful approaches were designed to take into account temporal coherence in short-term motions of visual features of the pedestrians by using ConvLSTMs [10], [11], 3D Convolutions [12], [13], [14], or Spatio-Temporal DenseNet [15]. Approaches trying to minimize the inference time of their models by avoiding the usage of RGB images were explored: [16] proposes a transformer using only spatial positioning of the pedestrian based on 2D bounding box locations. Crossing prediction based on kinematics only was also explored with various available learning architectures to monitor temporal evolution of skeletal joints such as convolutions [17], [18], [19], recurrent cells [20], [21] or graph-based models [22].…”

Section: A Pedestrian Crossing Predictionmentioning

confidence: 99%

“…In its first year of existence, proposed approaches evaluated on the benchmarks [1] constantly report higher classification scores [19], [16], [26], [29], [30], [31], giving the impression of clear improvements in pedestrian intention prediction. Usually, a new algorithm is proposed and the implicit hypothesis towards the proposed contribution is made such that it yields an improved performance over the existing state-ofthe-art.…”

Section: B Cross-dataset Evaluationmentioning

confidence: 99%

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Assessing Cross-dataset Generalization of Pedestrian Crossing Predictors

Gesnouin¹,

Pechberti²,

Stanciulescu³

et al. 2022

Preprint

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Pedestrian crossing prediction has been a topic of active research, resulting in many new algorithmic solutions. While measuring the overall progress of those solutions over time tends to be more and more established due to the new publicly available benchmark and standardized evaluation procedures, knowing how well existing predictors react to unseen data remains an unanswered question. This evaluation is imperative as serviceable crossing behavior predictors should be set to work in various scenarii without compromising pedestrian safety due to misprediction. To this end, we conduct a study based on direct cross-dataset evaluation. Our experiments show that current state-of-the-art pedestrian behavior predictors generalize poorly in cross-dataset evaluation scenarii, regardless of their robustness during a direct training-test set evaluation setting. In the light of what we observe, we argue that the future of pedestrian crossing prediction, e.g. reliable and generalizable implementations, should not be about tailoring models, trained with very little available data, and tested in a classical train-test scenario with the will to infer anything about their behavior in real life. It should be about evaluating models in a crossdataset setting while considering their uncertainty estimates under domain shift.

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Section: A Pedestrian Crossing Predictionmentioning

confidence: 99%

Section: B Cross-dataset Evaluationmentioning

confidence: 99%

Assessing Cross-dataset Generalization of Pedestrian Crossing Predictors

Gesnouin¹,

Pechberti²,

Stanciulescu³

et al. 2022

Preprint

View full text Add to dashboard Cite

show abstract

“…Saleh et al employed a spatio-temporal densenet for classification based on sequences of pedestrian bounding boxes (14). Achaji et al incorporated a transformer for classifying pedestrian intentions based on bounding box features (15).…”

mentioning

confidence: 99%

Pedestrian Crossing Intention Prediction Model Considering Social Interaction between Multi-Pedestrians and Multi-Vehicles

Zhou

Lijun

Liu

et al. 2023

Transportation Research Record: Journal of the Transportation R

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Accurate pedestrian crossing intention prediction is critical for autonomous vehicles and advanced driver assistance systems. In multi-pedestrian and multi-vehicle interaction scenes, the social interaction between pedestrians and other traffic participants is ubiquitous, which affects pedestrian crossing decisions and the accuracy of prediction. However, previous studies on pedestrian crossing intention lack comprehensive consideration and mathematical modeling of the social interaction. We propose a “social interaction force” (SIF) to identify and quantify social interaction behaviors and combine the hidden Markov model (HMM) to predict pedestrian crossing intentions 1.0 s ahead. Firstly, a large dataset of pedestrian-vehicle interaction samples is collected from two views, and high-dimensional features are extracted for pedestrian intention prediction. Next, the concept of SIF is proposed to quantitatively characterize the influence of other pedestrians and vehicles on pedestrian crossing decisions, including “pedestrian interaction force” and “pedestrian-vehicle interaction force.” Finally, SIF, pedestrian features, and road structure features are input into HMM. Sliding time windows are applied to the HMM to achieve dynamic prediction of pedestrian intention sequences. Experimental results show that the recognition accuracy of the proposed model is 0.976, and the accuracy of 1.0 s ahead prediction is 0.932 with guaranteed prediction speed. The proposed model performance is superior to that of the most prevalent models developed thus far.

show abstract

Is attention to bounding boxes all you need for pedestrian action prediction?

Cited by 2 publications

References 27 publications

Assessing Cross-dataset Generalization of Pedestrian Crossing Predictors

Assessing Cross-dataset Generalization of Pedestrian Crossing Predictors

Pedestrian Crossing Intention Prediction Model Considering Social Interaction between Multi-Pedestrians and Multi-Vehicles

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