I. Introduction

Automated driving and vehicle platoons can improve traffic safety, fuel efficiency, and traffic flow. In addition, connecting the vehicles enables the Following Vehicles (FVs) to react to the speed changes of a Lead Vehicle (LV) through Vehicle-to-Vehicle (V2V) communications. In platooning, the preassigned LV periodically broadcasts its status and attributes, whereas event-driven messages are disseminated when a situation of common interest, e.g., a hazard, occurs. Automated vehicles can also use this platooning strategy in dense traffic situations. A vehicle in front can broadcast its speed periodically to the vehicles behind and also inform them about an intention to brake. In V2V, communication delays are time-varying and can be very high in dense data and road traffic scenarios since packet drops require waiting for the next update [1]. In addition, since the rear vehicles are further away from the LV, they may experience more frequent outages and packet loss due to path loss, shadowing, and fading effects [2]. One solution to this is to maintain short gaps between the vehicles, as this is also good for fuel efficiency. However, even though the likelihood reduces, packet losses may still occur and cause problems with safety since there is less time to react in case, e.g., emergency braking should be necessary. On the other hand, having longer inter-vehicle distances can result in losing contact with the LV and leads to reduced fuel efficiency. To this end, being aware of the experienced communication delay, i.e., the delay between periodic updates from the leading vehicle, is an important factor in order to make suitable control decisions that enables fuel efficiency while providing safety.