Platoon (automobile)

Last updated
Platooning Back 022414 Final noTpye.jpg

In transportation, platooning or flocking is a method for driving a group of vehicles together. It is meant to increase the capacity of roads via an automated highway system. [1]

Contents

Platoons decrease the distances between cars or trucks using electronic, and possibly mechanical, coupling. This capability would allow many cars or trucks to accelerate or brake simultaneously. This system also allows for a closer headway between vehicles by eliminating reacting distance needed for human reaction.

Platoon capability might require buying new vehicles, or it may be something that can be retrofitted. Drivers would probably need a special license endorsement on account of the new skills required and the added responsibility when driving in the lead.

Smart cars with artificial intelligence could automatically join and leave platoons. The automated highway system is a proposal for one such system, where cars organise themselves into platoons of 8 to 25.

Potential benefits

Potential disadvantages

Automated highway system

An automated highway system (AHS), or smart road, is a proposed intelligent transportation system technology designed to provide for driverless cars on specific right-of ways. It is most often recommended as a means of traffic congestion relief, on the grounds that it would drastically reduce following distances and headway, thus allowing a given stretch of road to carry more cars.

Principle

In one scheme, the roadway has magnetized stainless-steel spikes driven one meter apart in its center.[ citation needed ] The car senses the spikes to measure its speed and locate the center of the lane. Furthermore, the spikes can have either magnetic north or magnetic south facing up. The roadway thus provides small amounts of digital data describing interchanges and recommended speeds.

The cars have power steering and automatic speed controls, which are controlled by a computer.

The cars organize themselves into platoons of 8 to 25 cars. The cars within a platoon drive themselves a meter apart, so that air resistance is minimized. The distance between platoons is the conventional braking distance. If anything goes wrong, the maximum number of harmed cars should be one platoon.

An overview of platooning systems is given in Bergenhem et al. [7]

Platooning of trucks has been proposed as a concept to reduce the energy consumption of semi-trucks and improve the feasibility of electric semi-trucks. [8]

Early development

The origin of research on AHS was done by a team from Ohio State University led by Dr. Robert E. Fenton, based on funding from the U.S. Federal Highway Administration. Their first automated vehicle was built in 1962, and is believed to be the first land vehicle to contain a computer. Steering, braking and speed were controlled through the onboard electronics, which filled the trunk, back seat and most of the front of the passenger side of the car. Research continued at OSU until federal funding was cut in the early 1980s.

Deployments

United States

The USDOT-sponsored National Automated Highway System Consortium (NAHSC) project, a prototype automated highway system, was tested in San Diego County, California in 1997 along Interstate 15. However, despite the technical success of the program, investment has moved more toward autonomous intelligent vehicles rather than building specialized infrastructure. The AHS system places sensory technology in cars that can read passive road markings, and use radar and inter-car communications to make the cars organize themselves without the intervention of drivers. Such an autonomous cruise control system is being developed by Mercedes-Benz, BMW, Volkswagen and Toyota. [9]

The Federal Highway Administration in 2013 funded two research projects in heavy truck platooning (without steering automation). One is led by Auburn University [10] with Peterbilt, American Trucking Associations, Meritor Wabco, and Peloton Technology and the other is led by California Department of Transportation, with UC Berkeley and Volvo Trucks.

SARTRE

The SARTRE Project (Safe Road Trains for the Environment), is a European Commission funded project investigating implementation of platooning on unmodified European motorways. [11] The project begun in September 2009, and vehicle platooning, as envisaged by the SARTRE project, is a convoy of vehicles in which a professional driver in a lead vehicle heads a line of closely following vehicles. Each following vehicle autonomously measures the distance, speed and direction and adjusts to the vehicle in front. Once in the platoon, drivers can do other things while the platoon proceeds towards its long-haul destination. All vehicles are detached and can leave the procession at any time. [12] [13]

In January 2011, SARTRE made the first successful demonstration of its platooning technology at the Volvo Proving Ground near Gothenburg, Sweden, in which a lead truck was followed by a car. In January 2012, SARTRE made a second demonstration in Barcelona, Spain, in which a lead truck was followed by three cars driven entirely autonomously at speeds of up to 90 km/h (56 mph) with a gap between of at most 6 m (20 ft). The companies that participated in SARTRE were Volvo Trucks and Volvo Car Corporation. [13]

EU Truck Platooning Challenge

During its Presidency of the European Union in 2016, the Netherlands organised a European Truck Platooning Challenge. [14] Six brands of automated trucks [15] DAF Trucks, Daimler Trucks, Iveco, MAN Truck & Bus, Scania AB and Volvo Trucks – ran on public roads from several European cities to the Netherlands.

Japan

In January 2018, trucks from different manufacturers were successfully driven by platooning for the first time on the Shin-Tomei Expressway in Japan. [16]

In February, 2021, Ministry of Economy, Trade and Industry (METI) and Ministry of Land, Infrastructure, Transport and Tourism (MLIT) successfully achieved traveling of trucks on part of the Shin-Tomei Expressway in a platoon in which no drivers were present in either the second or the following trucks, with staff in only the passenger seat for security purposes. [17]

South Korea

In November 2019, Hyundai Motor Group successfully conducted its first platooning of trucks on a highway for the first time in Korea. Demonstrations of platooning, cut-in/cut-out of other vehicles, simultaneous emergency braking, and V2V communication technology were conducted. [18] [19]

See also

Related Research Articles

<span class="mw-page-title-main">Self-driving car</span> Vehicle operated with reduced human input

A self-driving car, also known as an autonomous car (AC), driverless car, or robotic car (robo-car), is a car that is capable of driving without human input. Self-driving cars are responsible all driving activities including perceiving the environment, monitoring important systems, and controlling the vehicle, including navigating from origin to destination.

<span class="mw-page-title-main">Automotive safety</span> Study and practice to minimize the occurrence and consequences of motor vehicle accidents

Automotive safety is the study and practice of automotive design, construction, equipment and regulation to minimize the occurrence and consequences of traffic collisions involving motor vehicles. Road traffic safety more broadly includes roadway design.

<span class="mw-page-title-main">Advanced driver-assistance system</span> Electronic systems that help a vehicle driver while driving or parking

An advanced driver-assistance system (ADAS) includes technologies that assist drivers with the safe operation of a vehicle. Through a human-machine interface, ADAS increases car and road safety. ADAS uses automated technology, such as sensors and cameras, to detect nearby obstacles or driver errors, and respond accordingly. ADAS can enable various levels of autonomous driving.

<span class="mw-page-title-main">Lane departure warning system</span> Mechanism designed to warn a driver when the vehicle begins to move out of its lane

In road-transport terminology, a lane departure warning system (LDWS) is a mechanism designed to warn the driver when the vehicle begins to move out of its lane on freeways and arterial roads. These systems are designed to minimize accidents by addressing the main causes of collisions: driver error, distractions and drowsiness. In 2009 the U.S. National Highway Traffic Safety Administration (NHTSA) began studying whether to mandate lane departure warning systems and frontal collision warning systems on automobiles.

<span class="mw-page-title-main">Vehicular automation</span> Automation for various purposes of vehicles

Vehicular automation involves the use of mechatronics, artificial intelligence, and multi-agent systems to assist the operator of a vehicle such as a car, lorries, aircraft, or watercraft. A vehicle using automation for tasks such as navigation to ease but not replace human control, qualify as semi-autonomous, whereas a fully self-operated vehicle is termed autonomous.

Brake assist or emergency brake assist (EBA) is a term for an automobile braking technology that increases braking pressure in an emergency. The first application was developed jointly by Daimler-Benz and TRW/LucasVarity. Research conducted in 1992 at the Mercedes-Benz driving simulator in Berlin revealed that more than 90% of drivers fail to brake with enough force when faced with an emergency.

<span class="mw-page-title-main">Adaptive cruise control</span> Cruise control advanced driver-assistance system

Adaptive cruise control (ACC) is a type of advanced driver-assistance system for road vehicles that automatically adjusts the vehicle speed to maintain a safe distance from vehicles ahead. As of 2019, it is also called by 20 unique names that describe that basic functionality. This is also known as Dynamic cruise control.

<span class="mw-page-title-main">Energy-efficient driving</span> Driving using techniques that reduce fuel consumption

Energy-efficient driving techniques are used by drivers who wish to reduce their fuel consumption, and thus maximize fuel efficiency. Many drivers have the potential to improve their fuel efficiency significantly. Simple things such as keeping tires properly inflated, having a vehicle well-maintained and avoiding idling can dramatically improve fuel efficiency. Careful use of acceleration and deceleration and especially limiting use of high speeds helps efficiency. The use of multiple such techniques is called "hypermiling".

<span class="mw-page-title-main">Collision avoidance system</span> Motorcar safety system

A collision avoidance system (CAS), also known as a pre-crash system, forward collision warning system (FCW), or collision mitigation system, is an advanced driver-assistance system designed to prevent or reduce the severity of a collision. In its basic form, a forward collision warning system monitors a vehicle's speed, the speed of the vehicle in front of it, and the distance between the vehicles, so that it can provide a warning to the driver if the vehicles get too close, potentially helping to avoid a crash. Various technologies and sensors that are used include radar (all-weather) and sometimes laser (LIDAR) and cameras to detect an imminent crash. GPS sensors can detect fixed dangers such as approaching stop signs through a location database. Pedestrian detection can also be a feature of these types of systems.

<span class="mw-page-title-main">Safe Road Trains for the Environment</span>

Safe Road Trains for the Environment (SARTRE) is a European Commission-funded project to investigate and trial technologies and strategies for the safe platooning of road vehicles, a transportation concept in which several vehicles are electronically linked together in a "road train", with only the lead driver in active control. The three-year project was launched in 2009. The research and development was carried out by several European auto manufactures with Volvo at the lead. A first practical test successfully took place in December 2010. In September Volvo announced that the SARTRE research project had come to a close, and that the company was ready to look into putting its finished product on the road.

<span class="mw-page-title-main">Automated emergency braking system</span>

The World Forum for Harmonization of Vehicle Regulations define AEBS. UN ECE regulation 131 requires a system which can automatically detect a potential forward collision and activate the vehicle braking system to decelerate a vehicle with the purpose of avoiding or mitigating a collision. UN ECE regulation 152 says deceleration has to be at least 5 metres per second squared.

<span class="mw-page-title-main">History of self-driving cars</span> Overview of the history of self-driving cars

Experiments have been conducted on self-driving cars since 1939; promising trials took place in the 1950s and work has proceeded since then. The first self-sufficient and truly autonomous cars appeared in the 1980s, with Carnegie Mellon University's Navlab and ALV projects in 1984 and Mercedes-Benz and Bundeswehr University Munich's Eureka Prometheus Project in 1987. Since then, numerous major companies and research organizations have developed working autonomous vehicles including Mercedes-Benz, General Motors, Continental Automotive Systems, Autoliv Inc., Bosch, Nissan, Toyota, Audi, Volvo, Vislab from University of Parma, Oxford University and Google. In July 2013, Vislab demonstrated BRAiVE, a vehicle that moved autonomously on a mixed traffic route open to public traffic.

Peloton Technology was an American automated and connected vehicle technology company established in 2011 and headquartered in Mountain View, California. It primarily developed a vehicle "platooning" system to enable pairs of trucks to operate at close following distances with a stated goal of improving safety and fuel efficiency. Peloton Technology was the first company to test a non-research commercial truck platooning system on public roads in the United States. In 2016 it publicly stated it would be the first company to offer a commercial platooning system for use by truck fleets in 2017. By mid-2018 that deadline had slipped to "by the end of 2018."

Increases in the use of autonomous car technologies are causing incremental shifts in the responsibility of driving, with the primary motivation of reducing the frequency of traffic collisions. Liability for incidents involving self-driving cars is a developing area of law and policy that will determine who is liable when a car causes physical damage to persons or property. As autonomous cars shift the responsibility of driving from humans to autonomous car technology, there is a need for existing liability laws to evolve to reasonably identify the appropriate remedies for damage and injury. As higher levels of autonomy are commercially introduced, the insurance industry stands to see higher proportions of commercial and product liability lines, while personal automobile insurance shrinks.

Torc Robotics (Torc), an independent subsidiary of Daimler Truck, is an American autonomous truck company headquartered in Blacksburg, Virginia, with operations in Albuquerque, New Mexico; Austin, Texas; and Stuttgart, Germany. Torc is testing autonomous trucks in Virginia, New Mexico, and Texas and is taking a pure play approach to commercialization – focusing at first on one platform in one region.

<span class="mw-page-title-main">Lane centering</span> Mechanism designed to keep a car centered in the lane

In road-transport terminology, lane centering, also known as auto steer or autosteer, is an advanced driver-assistance system that keeps a road vehicle centered in the lane, relieving the driver of the task of steering. Lane centering is similar to lane departure warning and lane keeping assist, but rather than warn the driver, or bouncing the car away from the lane edge, it keeps the car centered in the lane. Together with adaptive cruise control (ACC), this feature may allow unassisted driving for some length of time. It is also part of automated lane keeping systems.

The death of Elaine Herzberg was the first recorded case of a pedestrian fatality involving a self-driving car, after a collision that occurred late in the evening of March 18, 2018. Herzberg was pushing a bicycle across a four-lane road in Tempe, Arizona, United States, when she was struck by an Uber test vehicle, which was operating in self-drive mode with a human safety backup driver sitting in the driving seat. Herzberg was taken to the local hospital where she died of her injuries.

<span class="mw-page-title-main">Self-driving truck</span> Type of autonomous vehicle

A self-driving truck, also known as an autonomous truck or robo-truck, is an application of self-driving technology aiming to create trucks that can operate without human input. Alongside light, medium, and heavy-duty trucks, many companies are developing self-driving technology in semi trucks to automate highway driving in the delivery process.

The impact of self-driving cars is anticipated to be wide-ranging in many areas of daily life. Self-driving cars have been the subject of significant research on their environmental, practical, and lifestyle consequences.

Regulation of self-driving cars, autonomous vehicles and automated driving system is an increasingly relevant topic in the automotive industry strongly related to the success of the actual technology. Multiple countries have passed local legislation and agreed on standards for the introduction of autonomous cars.

References

  1. Zabat, Stabile, Frascaroll, Browand, "The Aerodynamic Performance of Platoons", Path Research Report, ISSN   1055-1425, archived from the original on 2011-07-19{{citation}}: CS1 maint: multiple names: authors list (link)
  2. Rostami-shahrbabaki, Majid; Haghbayan, Seyed Arman; Akbarzadeh, Meisam; Bogenberger, Klaus (13 July 2022). On the Technical Feasibility of Vehicle to Vehicle Charging for Electric Vehicles via Platooning on Freeways. European control conference. London: IEEE. pp. 503–537.
  3. Greenberg, Andy. "Hackers Hijack a Big Rig Truck's Accelerator and Brakes". Wired.
  4. "Security experts hack into moving car and seize control". Reuters. 21 July 2015.
  5. "Commercial Vehicle Hacking: The New Hacking Frontier? - Kodsi Forensic Engineering Inc". 4 November 2015.
  6. Truck RPM Control on YouTube
  7. Carl Bergenhem, Henrik Pettersson, Erik Coelingh, Cristofer Englund, Steven Shladover, Sadayuki Tsugawa, "Overview of Platooning Systems", ITS World Congress, Vienna, 22–26 October 2012, https://publications.lib.chalmers.se/records/fulltext/174621/local_174621.pdf
  8. Guttenberg, Matthew; Sripad, Shashank; Viswanathan, Venkatasubramanian (2017). "Evaluating the Potential of Platooning in Lowering the Required Performance Metrics of Li-Ion Batteries to Enable Practical Electric Semi-Trucks". ACS Energy Letters. 2 (11): 2642–2646. doi: 10.1021/acsenergylett.7b01022 .
  9. Engineering Newsletters - ASME Archived 2010-07-05 at the Wayback Machine . Memagazine.org. Retrieved on 2013-09-04.
  10. "Auburn engineers collaborate with industry partners on truck platooning project". eng.auburn.edu. 2013-12-12. Retrieved 2023-08-09.
  11. "About the SARTRE project". The SARTRE Project. n.d. Archived from the original on 15 November 2010. Retrieved 18 January 2011.
  12. GCC staff (2010-12-11). "EU SARTRE road platooning project moving to testing phase; firsts tests of two-vehicle train by end of year". Green Car Congress . Retrieved 2013-11-25.
  13. 1 2 GCC staff (2012-01-24). "SARTRE project completes first successful on-road demo of multiple vehicle platooning". Green Car Congress . Retrieved 2013-11-25.
  14. "Archived copy". Archived from the original on 2022-01-19. Retrieved 2017-01-15.{{cite web}}: CS1 maint: archived copy as title (link)
  15. "What is the European Truck Platooning Challenge? – ACEA – European Automobile Manufacturers' Association". 10 March 2016.
  16. "World's First Test of Expressway Traveling of CACC - mounted Trucks Platooning with Drivers in the Following Trucks Launched". Toyota Tsusho . 12 January 2018. Retrieved 28 April 2022.
  17. "Successful Autonomous Driving Technology Tests for Truck Platooning". Ministry of Economy, Trade and Industry (METI) . 5 March 2021. Retrieved 28 April 2022.
  18. "WHAT IS PLATOONING?". 《Stock Logistic》. Retrieved June 27, 2019.
  19. "S. Korea to demonstrate first truck platooning on public road". 《Pulse News》. Retrieved November 26, 2020.
Videos
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.