Spelling suggestions: "subject:"pedestrian intention"" "subject:"edestrian intention""
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Modeling Spatiotemporal Pedestrian-Environment Interactions for Predicting Pedestrian Crossing Intention from the Ego-ViewChen, Chen (Tina) 08 1900 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / For pedestrians and autonomous vehicles (AVs) to co-exist harmoniously and safely in the real-world, AVs will need to not only react to pedestrian actions, but also anticipate their intentions. In this thesis, we propose to use rich visual and pedestrian-environment interaction features to improve pedestrian crossing intention prediction from the ego-view.We do so by combining visual feature extraction, graph modeling of scene objects and their relationships, and feature encoding as comprehensive inputs for an LSTM encoder-decoder network.
Pedestrians react and make decisions based on their surrounding environment, and the behaviors of other road users around them. The human-human social relationship has al-ready been explored for pedestrian trajectory prediction from the bird’s eye view in stationary cameras. However, context and pedestrian-environment relationships are often missing incurrent research into pedestrian trajectory, and intention prediction from the ego-view. To map the pedestrian’s relationship to its surrounding objects we use a star graph with the pedestrian in the center connected to all other road objects/agents in the scene. The pedestrian and road objects/agents are represented in the graph through visual features extracted using state of the art deep learning algorithms. We use graph convolutional networks, and graph autoencoders to encode the star graphs in a lower dimension. Using the graph en-codings, pedestrian bounding boxes, and human pose estimation, we propose a novel model that predicts pedestrian crossing intention using not only the pedestrian’s action behaviors(bounding box and pose estimation), but also their relationship to their environment.
Through tuning hyperparameters, and experimenting with different graph convolutions for our graph autoencoder, we are able to improve on the state of the art results. Our context-driven method is able to outperform current state of the art results on benchmark datasetPedestrian Intention Estimation (PIE). The state of the art is able to predict pedestrian crossing intention with a balanced accuracy (to account for dataset imbalance) score of 0.61, while our best performing model has a balanced accuracy score of 0.79. Our model especially outperforms in no crossing intention scenarios with an F1 score of 0.56 compared to the state of the art’s score of 0.36. Additionally, we also experiment with training the state of the art model and our model to predict pedestrian crossing action, and intention jointly. While jointly predicting crossing action does not help improve crossing intention prediction, it is an important distinction to make between predicting crossing action versus intention.
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Modeling Spatiotemporal Pedestrian-Environment Interactions for Predicting Pedestrian Crossing Intention from the Ego-ViewChen Chen (11014800) 06 August 2021 (has links)
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<p>For pedestrians and autonomous vehicles (AVs) to co-exist harmoniously and safely in
the real-world, AVs will need to not only react to pedestrian actions, but also anticipate
their intentions. In this thesis, we propose to use rich visual and pedestrian-environment
interaction features to improve pedestrian crossing intention prediction from the ego-view.
We do so by combining visual feature extraction, graph modeling of scene objects and their
relationships, and feature encoding as comprehensive inputs for an LSTM encoder-decoder
network.
</p>
<p>Pedestrians react and make decisions based on their surrounding environment, and the
behaviors of other road users around them. The human-human social relationship has already been explored for pedestrian trajectory prediction from the bird’s eye view in stationary
cameras. However, context and pedestrian-environment relationships are often missing in
current research into pedestrian trajectory, and intention prediction from the ego-view. To
map the pedestrian’s relationship to its surrounding objects we use a star graph with the
pedestrian in the center connected to all other road objects/agents in the scene. The pedestrian and road objects/agents are represented in the graph through visual features extracted
using state of the art deep learning algorithms. We use graph convolutional networks, and
graph autoencoders to encode the star graphs in a lower dimension. Using the graph en-
codings, pedestrian bounding boxes, and human pose estimation, we propose a novel model
that predicts pedestrian crossing intention using not only the pedestrian’s action behaviors
(bounding box and pose estimation), but also their relationship to their environment.
</p>
<p>Through tuning hyperparameters, and experimenting with different graph convolutions
for our graph autoencoder, we are able to improve on the state of the art results. Our context-
driven method is able to outperform current state of the art results on benchmark dataset
Pedestrian Intention Estimation (PIE). The state of the art is able to predict pedestrian
crossing intention with a balanced accuracy (to account for dataset imbalance) score of 0.61,
while our best performing model has a balanced accuracy score of 0.79. Our model especially
outperforms in no crossing intention scenarios with an F1 score of 0.56 compared to the state
of the art’s score of 0.36. Additionally, we also experiment with training the state of the art model and our model to predict pedestrian crossing action, and intention jointly. While
jointly predicting crossing action does not help improve crossing intention prediction, it is
an important distinction to make between predicting crossing action versus intention.</p>
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VR-BASED TESTING BED FOR PEDESTRIAN BEHAVIOR PREDICTION ALGORITHMSFaria Armin (16279160) 30 August 2023 (has links)
<p>Upon introducing semi- and fully automated vehicles on the road, drivers will be reluctant to focus on the traffic interaction and rely on the vehicles' decision-making. However, encountering pedestrians still poses a significant difficulty for modern automated driving technologies. Considering the high-level complexity in human behavior modeling to solve a real-world problem, deep-learning algorithms trained from naturalistic data have become promising solutions. Nevertheless, although developing such algorithms is achievable based on scene data collection and driver knowledge extraction, evaluation remains challenging due to the potential crash risks and limitations in acquiring ground-truth intention changes. </p>
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<p>This study proposes a VR-based testing bed to evaluate real-time pedestrian intention algorithms as VR simulators are recognized for their affordability and adaptability in producing a variety of traffic situations, and it is more reliable to conduct human-factor research in autonomous cars. The pedestrian wears the head-mounted headset or uses the keyboard input and makes decisions in accordance with the circumstances. The simulator has added a credible and robust experience, essential for exhibiting the real-time behavior of the pedestrian. While crossing the road, there exists uncertainty associated with pedestrian intention. Our simulator will anticipate the crossing intention with consideration of the ambiguity of the pedestrian behavior. The case study has been performed over multiple subjects in several crossing conditions based on day-to-day life activities. It can be inferred from the study outcomes that the pedestrian intention can be precisely inferred using this VR-based simulator. However, depending on the speed of the car and the distance between the vehicle and the pedestrian, the accuracy of the prediction can differ considerably in some cases.</p>
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