In the data file, NGSIM refers to the NGSIM trajectory data mentioned in the paper.
In the data file, WHUT contains the TVD trajectory data.
All code is stored in the “code” folder.
The filenames in the “code” folder correspond to the comparison model code and my complete model code, respectively.
Code Execution Order:
1. First, set up a virtual environment according to the requirements in `requirements.txt`.
2. Use the code in the “Data Preprocessing” section to build a standard training dataset. Note that you must manually adjust the prediction step size in the dataset to match that of each code file to ensure consistency.
3. Place the constructed data in a location accessible to all scripts, then run each script individually. To facilitate execution by readers, each .py file includes the model architecture, training code, testing code, validation code, and code for visualizing and saving results.

This dataset provides field-collected data from an electric vehicle (EV) platoon, specifically curated to analyze car-following behavior across different driving modes and control types.

By capturing data under both One-Pedal Driving (OPD) and Two-Pedal Driving (TPD)—and comparing Manual Driving against Adaptive Cruise Control (ACC)—the dataset offers a comprehensive look at how EV technology influences traffic flow.

Key Dataset Features

• Vehicle Composition: The data tracks a four-vehicle platoon consisting of one Internal Combustion Engine (ICE) lead vehicle followed by three EVs.

• Data Resolution: All trajectories are recorded at a high-frequency 10 Hz sampling rate.

• Sensor Integration: The dataset includes synchronized GPS trajectories for all four vehicles, ensuring precise spatial and temporal alignment.

Due to privacy constraints, we have provided anonymized samples with randomly shuffled data distributions to illustrate the data structure used in our experiments.

This repository is the replication package for COIN: Collaborative Interaction-Aware Multi-Agent Reinforcement Learning for Self-Driving Systems. It provides the codebase, dependencies, and instructions needed to reproduce the training and evaluation results of COIN in multi-agent self-driving scenarios.

ABSTRACT: Advanced driver assistance systems (ADASs) can greatly enhance road safety by providing real-time warnings to drivers in imminent crash situations. However, the provided warning time may deviate from its designed time. There is limited research on how warning uncertainties influence drivers’ behavior, safety performance, and trust. This study conducted a driving simulator study to examine how uncertainties in warnings impact driving behaviors and trust using a roundabout driving scenario. Two warning error distributions were constructed to represent low and high warning uncertainty levels. Thirty-six participants were recruited and randomly divided into two groups under the two uncertainty levels in a driving simulator experiment. The betweengroup analysis shows that the lower warning uncertainty level group results in higher trust and that trust increases (or decreases) over time under low (or high) uncertainty levels. The within-group analysis shows that higher warning errors downgrade drivers’ trust and safety performance when the errors are high.