基于互联车辆数据的降雨强度对州际交通速度的影响

R. Sakhare, Yunchang Zhang, Howell Li, D. Bullock
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引用次数: 4

摘要

随着互联车辆数据和高分辨率天气数据的出现,有机会开发具有高时空保真度的模型,以表征天气对州际交通速度的影响。在这项研究中,获得了2021年和2022年42个雨天的41234次独特旅行的275422次旅行记录。根据NOAA高分辨率快速刷新(HRRR)数据的降水率,将这些行程记录分为无雨、小雨、中雨、大雨和暴雨期。据观察,与无雨相比,暴雨期间的平均速度下降了约8.4%。同样,随着降雨强度的增加,交通速度的四分位数范围从每小时8.34英里增加到每小时12.24英里。本研究还开发了一种分解方法,使用logit模型来表征天气相关变量(降水率、能见度、温度、风和白天或夜晚)与州际减速之间的关系。估算结果表明,降水速率每增加1 mm/h,驾驶员减速的比值比增加5.8%。研究发现,逆风对速度降低的影响只有10%,而夜间的速度降低比白天的速度降低高1.68倍。额外的解释变量揭示了驾驶员在恶劣天气环境下的速度选择,提供了比单一降水强度测量更多的信息。这项研究的结果将特别有助于机构和汽车制造商向驾驶员提供提前警告,并建立自动驾驶汽车控制的阈值。
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Impact of Rain Intensity on Interstate Traffic Speeds Using Connected Vehicle Data
With the emergence of connected vehicle data and high-resolution weather data, there is an opportunity to develop models with high spatial-temporal fidelity to characterize the impact of weather on interstate traffic speeds. In this study, 275,422 trip records from 41,234 unique journeys on 42 rainy days in 2021 and 2022 were obtained. These trip records are categorized as no rain, slight rain, moderate rain, heavy rain, and very heavy rain periods using the precipitation rate from NOAA High-Resolution Rapid-Refresh (HRRR) data. It was observed that average speeds decreased by approximately 8.4% during conditions classified as very heavy rain compared to no rain. Similarly, the interquartile range of traffic speeds increased from 8.34 mph to 12.24 mph as the rain intensity increased. This study also developed a disaggregate approach using logit models to characterize the relationship between weather-related variables (precipitation rate, visibility, temperature, wind, and day or night) and interstate speed reductions. Estimation results reveal that the odds ratio of reducing speed is 5.8% higher for drivers if the precipitation rate is increased by 1 mm/h. The headwind was found to have a positive significant impact of only up to a 10% speed reduction, and speed reduction is greater during nighttime conditions compared to daytime conditions by a factor of 1.68. The additional explanatory variables shed light on drivers’ speed selection in adverse weather environments, providing more information than the single precipitation intensity measure. Results from this study will be particularly helpful for agencies and automobile manufacturers to provide advance warnings to drivers and establish thresholds for autonomous vehicle control.
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