Impact of Automated Truck Platooning on the Performance of Freeway Mixed Traffic Flow

Vehicle platooning service through wireless communication and automated driving technology has become a reality. Vehicle platooning means that several vehicles travel like a train on the road with a minimum safety distance, which leads to the enhancement of safety, mobility, and energy savings. This study proposed a framework for exploring traﬃc mobility and safety performance due to the market penetration rate (MPR) of truck platoons based on microscopic traﬃc simulations. A platoon formation algorithm was developed and run on the VISSIM platform to simulate automated truck maneuvering. As a result of the mobility analysis, it was found that the diﬀerence in network mobility performance was not signiﬁcant up to MPR 80%. Regarding the mobility performance of the truck-designated lane, it was found that the average speed was lower than in other lanes. In the truck-designated lane of the on-ramp section, the average speed was identiﬁed to be approximately 33% lower. From the viewpoint of network safety, increasing the MPR of the truck platoon has a positive eﬀect on longitudinal safety but has a negative eﬀect on lateral safety. The safety analysis of the truck-designated lane indicated that the speed diﬀerence by lane of MPR 100% is 2.5 times higher than that of MPR 0%. This study is meaningful in that it explores traﬃc ﬂow performance on mobility and safety in the process of platoon formation. The outcomes of this study are expected to be utilized as fundamentals to support the novel traﬃc operation strategy in platooning environments.


Introduction
e development of automated vehicles technology is expected to transform the roads now used as movement spaces into productive spaces, which will lead to unprecedented changes in human life. One of the services using automated vehicles is vehicle platooning, which means that several vehicles travel together at a minimum safety distance through V2X (vehicle-to-everything) communication technology. Platooning services will be applied primarily to trucks because of their characteristics. In the case of trucks, accidents caused by human factors such as drowsiness are frequent and are likely to be large. e typical expected effects of platooning include enhanced safety, fuel saving, and environmental improvement, along with an economic effect. In terms of safety, autonomous driving and V2X technology allow vehicles in the platoon to avoid traffic accidents by quickly responding to unexpected situations [1][2][3][4]. In addition, since several vehicles travel at short intervals, the air resistance is reduced, and fuel is saved, thereby enhancing the competitiveness of the truck [5][6][7]. Finally, it is expected that the platooning can shorten the travel time by increasing the road capacity, and the trucks are expected to contribute to the reduction in the labor force by reducing the workload of the truck driver through the platooning because trucks are characterized by frequent overnight or long-distance operations [8][9][10][11].
e technology for automated vehicles and wireless communications, infrastructure, the legal system, and traffic operations and management plans should be developed before platooning can be commercialized. According to the EU truck platooning roadmap, the trucks, except for the leader in the platoon, are expected to reach the SAE level 4, which means they are capable of autonomous driving without a driver by 2025 [12]. In addition, the V2X communication required to realize such technology is rapidly advancing, and 5th generation communication technology (5G) is being commercialized. is developing technology will provide information to the automated vehicle to enable a prompt response when an unexpected situation occurs. It will be possible to provide realtime information using big data through the cooperative intelligent transport systems (C-ITS) infrastructure [13]. For truck platooning, legal standards and operational strategies related to automated vehicles should be established. Although some studies have been conducted on automated vehicle-only lanes [14], the automated vehicle must be mainstream to validate the operation of an automated vehicle-designated lane. However, early in its introduction, the truck platoon will be driven on existing truck restricted lanes. erefore, it is necessary to prepare for situations in which there is no platoononly lane. In addition, platooning can have a negative effect on the surrounding general vehicles, and the performance of the entire traffic flow can be lowered by the interactions between the vehicle platoons and the general vehicles. In the platooning environment, the possibility of a general vehicle lane change failure increases, and the driver's psychological anxiety can be increased in the process of switching control from manual driving to automated driving [11,15]. In preparation for such mixed traffic conditions, it is necessary to develop an effective traffic management strategy to optimize the performance of the road traffic system by understanding the interactions between the vehicle platoons and general vehicles.
ere have been many studies using driving simulation and microtraffic simulation to evaluate the effects of automated vehicles and platooning in previous studies [16][17][18]. Existing research on platooning focuses on the safety analysis of the platoon and the effect of a platoon dedicated lane [14,19]. However, under the present legal system, trucks are allowed to run on designated lanes, and there have been no studies on the new operational strategy view of the situation in which there is no platoon dedicated lane. e mobility performance and merging characteristics were evaluated in the previous studies for identifying the effectiveness of truck platooning [20,21]. However, it is necessary to evaluate the traffic safety of mixed traffic flow by identifying the interactions between truck platoons and general vehicles. erefore, it is necessary to develop a management strategy for the platooning to improve the mobility and safety of the traffic flow in terms of traffic management. e purpose of this study is to present the platoon formation algorithm and apply it to a simulation to identify the effect of the truck platoon on the freeway onramp area according to the market penetration rate (MPR) of the truck platoon. e proposed algorithm consists of three components: the truck sequencing in the platoon, the determination of platoon completion, and a speed control algorithm. To discover the effect of the truck platoon on traffic flow, we implemented a truck platoon in the COM interface environment of VISSIM, a microtraffic simulation program. e platoon MPR of trucks was used as an analysis scenario component. e effects of truck platooning on the on-ramp were identified in terms of traffic mobility and safety according to the MPR. e remainder of this paper is organized as follows. Section 2 presents the proposed simulation methodology including an overall analysis framework incorporating the proposed platoon formation algorithm. Section 3 presents the analysis results and discussions for traffic mobility and safety. Finally, Section 4 presents the conclusion with a summary of this study and future research directions based on the limitations identified while conducting this study.

Overall
Framework. An overall framework consisting of three steps is presented in Figure 1.
Step 1 includes the proposed platoon formation algorithm developed in this study.
Step 2 is the simulation experiments and consists of the section for setting scenarios and networks and the section for conducting simulations using VISSIM. In this study, the rate of platooning among trucks is defined as the MPR, and the MPR is a scenario component. e COM interface collects the trajectory data of each individual vehicle at each time step and controls the speed of the individual trucks in the platoon according to the platoon formation algorithm.
Step 3 identifies the mobility and safety performance from the aspect of the overall performance of the network and the performance on the truck platoon designation lane using individual vehicle trajectory data derived from the simulation.

Development of the Platoon Formation Algorithm.
ree important parameters including platoon size, intraplatoon spacing, and interplatoon spacing need to be determined for the truck platooning. e platoon size represents the number of trucks in the platoon, and the interplatoon spacing is the spacing between the trucks in the platoon. On the other hand, the intraplatoon spacing means the spacing between platoons. ese parameters can support decision making for establishing platoon operation strategies in different traffic conditions. e platooning algorithms in previous studies attempted to maintain platoons based on intelligent driver models (IDM) [14,17]. Unlike existing studies, the proposed platoon formation algorithm in this study is an algorithm that is designed to form platoons based on the aforementioned platoon formation parameters for the purpose of analyzing the interaction between the platoons and the general vehicles more effectively. In addition, a nice feature of the proposed algorithm is the implementation of the operating situation of autonomous emergency braking systems (AEBS) by changes in acceleration patterns. e platoon formation algorithm is shown in Figure 2, and the parameters associated with the platoon formation algorithm are defined in Table 1. e proposed algorithm consists of three components, which are the truck sequencing in the platoon (Part 1), the determination of platoon completion (Part 2), and the speed control algorithm (Part 3). In Part 1 and Part 3, the algorithm proceeds on an individual vehicle basis in the platoon, and in Part 2, the algorithm proceeds on a platoon basis. e truck sequencing algorithm determines the order of the subject vehicles in the platoon and assigns the sequence number of each truck, as shown in Part 1. Here, a vehicle designated as the platoon leader (Lead PL ) does not give up the role of the platoon leader unless an exceptional case occurs, which means that a truck capable of forming the platoon enters in front of the leader (Lead PL ) when the platoon size does not exceed a predefined maximum threshold (Max PL ). e sequence number (Ord PL ) of the new platoon leader is designated as 1, and the sequence number of the following platoon members is set to the next sequence number from the truck in the front. e completion of the platoon defined in this study is a case where the platoon size reaches a predefined maximum value (Max PL ). It is assumed that a new truck cannot enter the completed platoon. e platoon size that is currently being formed before reaching the maximum platoon size is indicated by PL Con in Part 1. It is expected that a traffic operations agency can implement a traffic management strategy that controls the platoon formation parameters while monitoring the driving conditions of the platoon using the sequencing information.
e second algorithm illustrated in Part 2 is to determine whether the platoon formation is completed or not. In the case of the incomplete platoon, it provides information on the platoon size being formed by all trucks in the platoon (PL Con ). On the other hand, if the platoon is completed, all trucks in the platoon share the information that the platoon has been completed (PL Com ). e information obtained from the proposed determination algorithm for platoon completion is used in the truck sequencing algorithm in the next simulation time step. e last component is a speed control algorithm, as shown in Part 3, which manages the desired speed and spacing of the trucks in the platoon. First, the algorithm identifies the sequence number of the subject truck and checks the required speed and spacing accordingly. For example, if there is no preceding vehicle, the subject vehicle travels at the platoon-keeping speed (V PL ), and the leader and platoon members in which the preceding vehicle exists attempt to travel while maintaining the interplatoon spacing and the intraplatoon spacing. Under these circumstances, the acceleration of the subject vehicle is adjusted to achieve the desired speed and spacing. en, the vehicle maneuvering is determined by two driving modes including the comfort driving mode and the emergency braking mode based on the time to collision (TTC). e acceleration rates in this application adopted values proposed in the literature [16,22]. e acceleration at which AEBS operated in this study is derived from equations (1)-(3) based on the threshold recommended by the literature [22]. In the comfort mode, where the inverse TTC is less than 0.68 seconds, equation (1) is applied when the acceleration is required. On the other hand, when deceleration is required, the acceleration is determined by equation (2). When the inverse TTC is 0.68 seconds or longer, the AEBS is activated in this study because it is expected that a dangerous situation to require rapid deceleration would occur. Equation (3) presents an acceleration to be used for activating the AEBS, which is −6(m/s 2 ). e speed at the next time step according to the acceleration derived from equations (1)-(3) is obtained by equation (4). Additionally, a newly estimated speed does not exceed the speed limit and the minimum speed. To achieve the desired speed and spacing, the obtained speed is used as the speed of the next simulation time step. e VISSIM COM interface is used for updating the speed at every second.
Comfort mode to require acceleration: Comfort mode to require deceleration: AEBS mode to require rapid deceleration: Step Is the subject vehicle PL Com ?
Is the preceding vehicle PL Com ?

Analysis Environments.
e simulation experiments were conducted to evaluate the impacts of freeway truck platooning on traffic mobility and safety by applying the proposed platoon formation algorithm through the VISSIM software. e range of spatial analysis was selected as the freeway on-ramp section. From the perspective of freeway traffic safety, the on-ramp area is of keen interest because frequent merging situations based on the interaction between platoons and general entering vehicles lead to a high crash potential. e other consideration is that, according to the Korean Road Traffic Act, the trucks must travel in the rightmost lane on a three-lane freeway segment, which is the designated lane for trucks in Korea. Existing studies evaluated the effectiveness when the leftmost lane was used for the high-occupancy lane (HOV) or dedicated lane [21,23]. On the other hand, this study conducted simulation experiments based on the current Korean traffic regulation that trucks should travel in the designated rightmost lane on freeways. us, the analysis network is set up as a 3-lane 15.4 km virtual freeway with an on-ramp, and the network structure is shown in Figure 1. en, the truck platooning was restricted to only the rightmost lane. e section from the network starting point up to 10 km is section A, with no change in geometry. Section B is a 0.4 km on-ramp located next to section A. Finally, section C is the 5 km main line after the on-ramp. e demand volume of the mainline freeway is 3,500 veh/h, which corresponds to traffic conditions representing a level of service (LOS) C based on the Korean Highway Capacity Manual [24]. is is because the design level of service of the freeway is the C-D level. In addition, the Korean Policy for Road Geometry Designs was used to determine the geometric conditions to install a one-lane on-ramp in the simulation network [25].
It is assumed that all the entering vehicles are passenger cars on a one-lane on-ramp with an initial speed of 60 km/ h. An on-ramp traffic volume of 500 veh/h was used in this application. e proportions of the vehicle types were determined by the actual observations from the Gyeongbu freeway.
e proportions of passenger cars, trucks, and buses are 79%, 17%, and 4%, respectively. e speed limit of trucks is 90 km/h, and the minimum speed is 50 km/h. e platoon-keeping speed is 80 km/h based on the assumption that the autonomous truck capable of forming platoons must follow the traffic regulation. is is because the trucks cannot accelerate when the platoon speed is equal to the speed limit.
Traffic mobility and safety analysis were conducted with an interplatoon spacing of 5 m, an intraplatoon spacing of 50 m, and platoon sizes of 2, 4, 6, 8, and 10, which were determined based on existing studies dealing with field and simulation implementation [26][27][28]. To evaluate the impact of an increased number of trucks capable of platooning, the MPR was increased from 0% to 100% at 20% intervals. As a result, a total of 6 scenarios were determined by considering MPRs. To increase the reliability of the simulation results, different random seeds were applied, and 5 simulation runs were conducted for each scenario. en, the average of the results of the five runs was presented. e simulation analysis time was 2,000-sec, and a warm-up time period of 600-sec was provided to ensure an even distribution of the vehicles across the network.

Simulation Calibrations.
e simulation calibration was conducted to make simulation experiments more realistic based on the comparison of actual traffic data and simulation data. Traffic speed data collected from the vehicle detection systems installed on the Shingal JC-Kiheung IC on the Gyeongbu freeway were used for the calibration in this study. is section of the freeway has been equipped with connected vehicle systems infrastructure for a truck platooning pilot study. "U-statistic" presented in equation (5) was used to determine the acceptability of simulation results. In general, u-statistic close to 0 represents that actual and simulated data are similar. In case the u-statistic is less than 0.1, calibration results can be accepted [29]. e result of deriving the average of U-statistic obtained by repeating simulations 5 times is presented in Table 2. It can be said that the calibration result is acceptable because U-statistics less than 0.1 are achieved.
where V i is the actual speed (km/h) and V i is the simulation speed (km/h). In addition to the simulation calibration aforementioned, this study adjusted the Wiedemann 99 model parameters of VISSIM using the recommended values presented in the literature [30] to simulate the  Table 3. Parameter values corresponding to the autonomous driving level 4 defined by the American Society of Automotive Engineers (SAE) were adopted. In our simulation experiment, a truck platoon travels based on the proposed platoon formation algorithm. On the other hand, parameters presented in Table 3 are adopted for simulating the maneuvering of individual autonomous trucks to which the platooning algorithm is not applied.

Overall Mobility Performance of the Network.
e mobility analysis of the network was conducted based on time and space using the average speed indicator. e simulation network for analyzing spatiotemporal patterns of mobility consists of section B with on-ramp, 2 km of section A, and 1 km of section C, which are upstream and downstream sections around section B, respectively. For the 3.4 km analysis space, we constructed 34 space cells in a 100 m unit and 40 time cells in 50 sec for a 2,000-sec analysis time. A total of 1,360 time-space cells were used for the spatiotemporal analysis. e average speed (V) of each cell was quantified and classified according to the categorization of congestion levels (k) on Korean freeways such as congestion-free, light congestion, and heavy congestion as presented in equation (6). If the average speed of a cell is more than 80 km/h, it is classified as congestion-free. Light congestion is classified as 40 km/h-80 km/h and heavy congestion is less than 40 km/h. After counting the number of classified congestion levels, the number of time-space cells by congestion level against the total number of cells was quantified and presented as in equation (7). Table 4 shows the results of analyzing the rate of congestion (ROC) by congestion level according to MPR. As a result, heavy congestion did not occur in all MPRs, and the mobility performance difference between the MPR 0-80% was insignificant. However, the scenario in which light congestion cells occupy the largest percentage is MPR 100%, and the ROC in this scenario is identified as 13%. For the MPR 100% scenarios with the lowest mobility performance, the results of the average speed according to spatiotemporal analysis were additionally presented. As a result of the analysis, it was found that the speed decreases slightly in section B, which affects the speed of the upstream section A as time goes by. e reason for the decrease in mobility performance is that the vehicles entering from the on-ramp change their path into or between platoons for the lane change. In particular, it is believed that the performance is poor at 100% MPR because trucks travel at a lower platoon-keeping speed compared to the speed of general vehicles.

Categorization of congestion level
Heavy congestion(k � 3), V < 40(km/h), ROC k � number of cells for congestion level k total number of cells in time − space diagram * 100(%), where k is the level of congestion, V is the average speed, ROC is the rate of congestion, and m is the count.

Mobility Performance in the Rightmost
Lane. e general vehicles entering from an on-ramp need to make a compulsory lane change to enter the main line. Traffic operation management in the on-ramp is necessary so that general vehicles can change lanes more safely. In the analysis network, the rightmost lane is the truck-designated lane, and the analysis of mobility performance is performed for the rightmost lane. e average speed results for the lanes selected as mobility indicators are presented in Figure 3. As a result of the analysis, the average speed of all lanes in section B is lower than that in sections A and C. Furthermore, the average speed of the rightmost lane in A and C sections is approximately 10% lower than that of the other lanes, while it is approximately 33% lower in B section. Because trucks drive at lower speeds than passenger cars, the average speed of the rightmost lane is seen as low. In section B especially, the speed of the rightmost lane seems to be lower because of the situations in which the truck that is driving in the main line decelerates due to the entering vehicle. erefore, it is necessary to establish a strategy to improve the mobility of the truck-designated lane in the on-ramp through the speed control of the truck platoon. is study suggests the characteristics of longitudinal and lateral conflicts by time and space according to the MPR. First, rear-end conflicts were selected as a longitudinal safety indicator. e rear-end conflicts can be identified using the safety distance (FD) and the follow distance (SD) derived from the simulation. e situation in which the SD is greater than the FD is defined as a conflict and represents a shorter distance than the minimum safe distance between a lead and the following vehicle [31]. A method of determining a conflict based on the analysis of SD and FD is expressed in equation (8). e number of conflicts (C) is quantified in the same time-space interval (t, s) as the mobility analysis. Equation (9) represents the number of conflicts for all vehicles (N) in a cell. A risk-free condition is defined for the numerical comparison of safety according to the MPR, and the risk-free condition means a situation in which there is no conflict. In this study, the case in which the number of conflicts in a single cell is 0 was defined as a risk-free cell (RFC), which is presented in equation (10). e ratio of RFCs to a total number of cells is defined as the rate of risk-free conditions (RORF). Figure 4(a) shows the RORF for each MPR derived using equation (11).
RORF � RFC total number of cells * 100(%),  Journal of Advanced Transportation 7 where SD is the safety distance, FD is the follow distance, C is the number of conflicts, m is the count, t is the time cell, s is the space cell, j is the number of vehicles, N is the total number of vehicles, T is the number of time cells, S is the number of space cells, RFC is the risk-free cells, and RORF is the rate of risk-free conditions. e results of the RORF analysis indicated that safety increases with increasing MPR. In particular, the RORF of MPR 100% was 51%, and it was observed that no rear-end conflicts occurred in more than half of the cells. e spatiotemporal analysis was performed for MPR 0% with the lowest RORF and MPR 100% with the highest RORF. e results of the spatiotemporal diagram analysis of the number of conflicts are shown in Figure 4(b). In both scenarios, it was found that the rear-end conflicts frequency was high at the on-ramp. At the MPR 0%, which is the lowest safety scenario, the number of rear-end conflicts in the B section was estimated to be approximately 1.42 times higher than that in the A and C sections. In the case of MPR 100%, which showed the highest safety, it was found that the average number of rear-end conflicts in all sections was approximately 5 conflicts lower. It has been identified that the increase in truck platoon positively affects the increase in longitudinal safety of all sections. e lane change conflict was defined and used as an indicator of lateral safety. In this study, we used information such as the speed and coordinates of individual vehicles derived from simulations to identify the lane change conflict. According to the SSAM report, conflict is classified as a lane change conflict when the starting point and ending point of the conflict occur in different lanes and the collision angle between the two vehicles is −30°to −85°or 30°to 85° [32]. erefore, the TTC was calculated according to equation (12) for vehicles in the lane change conflict range. e conflict threshold using the TTC proposed in the previous study is 1.5 seconds, and the method of determining the conflict in equation (13) is described [33]. e formula for calculating the number of conflicts by car is shown in equation (14) and the RORF is calculated in the same way as the number of rear-end conflicts.
Conflict determination � Conflict, TTC < 1.5 s, Not conflict, TTC ≥ 1.5 s, where TTC is the time to collision, x is the difference in x coordinate of two vehicles, y is the difference in y coordinate of two vehicles, V s is the subject vehicle speed, V t is the target vehicle speed, C is the number of conflicts, m is the count, t is the time cell, s is the space cell, j is the number of vehicles, and N is the total number of vehicles. e results of the RORF analysis on the lane change conflict are presented in Figure 5(a) to compare the difference in the lateral conflicts according to the MPR. As a result of the analysis, it was identified that the lateral safety decreases as the MPR increases, contrary to the longitudinal safety. e RORF of MPR 100% was 29%, which was 56%  Journal of Advanced Transportation lower than that of MPR 0%. Figure 5(b) shows a comparison of lane change conflicts between MPR 0% and MPR 100%. In both scenarios, it was found that the number of lane change conflicts in B section is approximately three times as many as in the A and C sections. e result of the network safety analysis shows that it is necessary to manage traffic to improve lateral safety rather than longitudinal safety. In addition, a platoon operation strategy should be established to reduce the conflict between the entering vehicle and the platoon in the on-ramp.

Safety Performance on the Rightmost
Lane. e safety analyses on the rightmost lane were conducted to evaluate the safety of the truck-designated lane. e speed difference between lanes was used as a surrogate safety measure of the truck-designated lane in the previous study [34]. e speed difference between lanes is obtained by equation (15). An analysis of variance (ANOVA) was performed to clearly identify the speed difference between lanes according to the MPR. e analysis results of the ANOVA are presented in Table 3. To identify the difference in speeds between lanes by MPRs, the ANOVA test was performed, and the analysis results are presented in Table 5. e speed difference between lanes according to the MPR was statistically significant at a 95% confidence level. In addition, the post hoc analysis was conducted to confirm the significance of the differences between the MPRs. In the MPR 20% to where V is the average speed by lane.

Conclusion
Recent advances in automated vehicle technology are expected to transform roads into productive spaces and lead to exceptional changes in the world. Specifically, platooning, one of the automated driving services is expected to improve traffic mobility and traffic safety. Platooning technology is advancing with the growth of the automated vehicle market and the commercialization of 5G and C-ITS infrastructures. According to the EU truck platoon roadmap, it is expected that multibrand platooning technology will be possible by 2025. To maximize the effect of platooning, it is necessary to establish a platoon operation strategy in terms of transportation management. In particular, a general vehicle entering an on-ramp must change lanes for merging into the main line. In this situation, a platoon operation strategy should be established so that the general vehicle can change lanes safely. In this study, it is necessary to identify the impact of traffic platooning on the traffic flow when a platoon-only lane is not operational before considering the platoon operation strategy. e purpose of this study is to identify traffic mobility and safety according to truck platooning on the freeway on-ramp. e platoon formation algorithm was developed to implement the platoon, and the algorithm consisted of the truck sequencing in the platoon, the determination of platoon completion, and the speed control algorithm. e VISSIM COM interface was used to run the proposed algorithm in microscopic traffic simulation environments. e analysis network is a 3-lane freeway with an on-ramp, and the truck drives in the rightmost lane, the designated lane. e main result of the mobility analysis is that as the MPR increases, the mobility of the truck-designated lane, as well as the mobility of the entire network, is reduced. In MPR 100%, the rate of congestion-free condition was 10% lower than in MPR 0%. e rate of risk-free conditions (ROFC) is defined to identify network safety. Longitudinal safety is improved as the MPR increases, while the lateral safety is reduced. e speed difference between lanes was used as an indicator to conduct a safety analysis of the truck-designated lane. e speed difference between lanes of MPR 100% was approximately 2.5 times higher than that of MPR 0%. An automated driving system can create a synergy effect when a traffic management strategy is introduced that considers interactions with general vehicles and automated vehicles.
is study is valuable because it explores traffic mobility and safety change through simulation before the introduction of the truck platoon. e following additional studies should be conducted to develop this research into a platoon management strategy. First, the proposed platoon formation algorithm does not include a component to simulate platoon dissipation, which is essential to fully reflect reality. However, a platoon dissolution algorithm that reflects car following and gap acceptance conditions should be developed, and a platoon operation strategy should be studied through an analysis of the off-ramp. It is also necessary to ensure that the platoon is formed efficiently, considering the vehicles that can be platooned in the same lane and the surrounding lanes. Second, the scenario of this study considered only the MPR of platoon trucks. However, for the strategy of cluster operation, it is necessary to perform an analysis considering the combination of platoon parameters such as platoon size, intraplatoon spacing, and interplatoon spacing. Further studies should be carried out in consideration of the various vehicle types of the platoon and the operation strategies, such as designated lanes, platoon-only lanes, and high-occupancy toll lanes. In addition, this study used traffic volume corresponding to the level of service (LOS) C, which is the design level of service for freeways [24], as the demand volume in simulation experiments. However, various congestion levels and ratios of trucks in the traffic stream should be taken into consideration in evaluating the impact of truck platooning. ird, we simulated the platoon maneuvering in the VISSIM by adjusting writable parameters such as speed and driving behavior parameters using COM interface. However, it is needed to simulate the behavior of the platoon using an external driver module to completely control the maneuvering of platoons in the simulation. Finally, if the actual maneuvering of automated vehicles is reflected in the simulation, a reliable platoon impact estimation can be obtained. In addition, although this study used safety distance and TTC-based indicators in the safety evaluation by truck platooning, it is necessary to perform the evaluation using a variety of surrogate safety measures.

Data Availability
e data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest
e authors declare that there are no conflicts of interest regarding the publication of this article.