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Driving simulator

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Driving simulator developed by University of Valencia in Spain, used in evaluation of drivers, roads, in-vehicle information system devices and other areas
Portable in-vehicle simulator from Drive Square for defensive driving based on a real car and virtual reality glasses (2017)

Driving simulators are used for entertainment as well as in training of driver's education courses taught in educational institutions and private businesses. They are also used for research purposes in the area of human factors and medical research, to monitor driver behavior, performance, and attention and in the car industry to design and evaluate new vehicles or new advanced driver assistance systems.

Training

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Driving simulators are being increasingly used for training drivers. Versions exist for cars, trucks, buses, etc.

Uses

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  • Novice driver training and testing
  • Professional driver training and testing
  • Training in critical driving conditions
  • Testing the effects of impairment on driver performance
  • Analysis of the driver behaviours
  • Analysis of driver responses
  • Evaluating user performances in different conditions (handling of controls)
  • Assessing fitness to drive for aging drivers
  • Testing future in-vehicle technologies on drivers or passengers (Human -Machine Interface)
  • entertainment and fun

Types

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  • Ambulance simulator: Used to train and assess ambulance drivers in basic and advanced vehicle control skills as well as how to respond to emergencies and interact with other emergency responders.
  • Car simulator: Used to train and test novice drivers in all the skills required to pass a driver's license road test as well as hazard perception and crash risk mitigation.
  • Modular-design simulator: Interchangeable vehicle cabins or cockpits can be configured for use as tractor/trailer trucks, dump trucks and other construction vehicles, airport-operated vehicles, emergency response and police pursuit vehicles, buses, subway trains, passenger vehicles, and heavy equipment such as cranes.
  • Multi-station driving simulator: This type of simulator enables one instructor to train more drivers at the same time thus saving time and reducing costs... These systems are equipped with instructor stations connected to control several driving simulators.
  • Truck simulator: Used to train and assess novice and experienced truck drivers in skills ranging from basic control maneuvers, e.g. shifting and backing, to advanced skills, e.g. fuel efficiency, rollover prevention, defensive driving.
  • Bus simulator: is used to train bus drivers on route familiarisation, safe driving techniques, fuel efficiency techniques. It can be used for training drivers on a variety of bus models and on different types of gear transmissions.
  • Physical simulator: Large scale simulators employ Stewart platforms and xy tables to physically move the driver around in 6-axis space, simulating acceleration, braking and centripetal forces, similar to physical flight simulators.

Entertainment

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In the 1980s, it became a trend for arcade racing games to use hydraulic motion simulator arcade cabinets.[1][2] The trend was sparked by Sega's "taikan" games, with "taikan" meaning "body sensation" in Japanese.[2] The "taikan" trend began when Yu Suzuki's team at Sega (later known as Sega AM2) developed Hang-On (1985), a racing video game where the player sits on and moves a motorbike replica to control the in-game actions.[3] Suzuki's team at Sega followed it with hydraulic motion simulator cockpit cabinets for later racing games such as Out Run (1986). Sega have since continued to manufacture motion simulator cabinets for arcade racing games through to the 2010s.[1]

In 1991, Namco released the arcade game Mitsubishi Driving Simulator, co-developed with Mitsubishi. It was a serious educational street driving simulator that used 3D polygon technology and a sit-down arcade cabinet to simulate realistic driving, including basics such as ensuring the car is in neutral or parking position, starting the engine, placing the car into gear, releasing the hand-brake, and then driving. The player can choose from three routes while following instructions, avoiding collisions with other vehicles or pedestrians, and waiting at traffic lights; the brakes are accurately simulated, with the car creeping forward after taking the foot off the brake until the hand-brake is applied. Leisure Line magazine considered it the "hit of the show" upon its debut at the 1991 JAMMA show. It was designed for use by Japanese driving schools, with a very expensive cost of AU$150,000 or US$117,000 (equivalent to $273,000 in 2023) per unit.[4]

Advances in processing power have led to more realistic simulators known as sim racing games on home systems, beginning with Papyrus Design Group's groundbreaking IndyCar Racing (1993) and Grand Prix Legends (1998) for PC and Gran Turismo (1997) for home consoles.

Occasionally, a racing game or driving simulator will also include an attachable steering wheel that can be used to play the game in place of a controller. The wheel, which is usually plastic, may also include pedals to add to the game's reality. These wheels are usually used only for arcade and computer games.

In addition to the myriad commercial releases there is a bustling community of amateur coders working on closed and open source free simulators. Some of the major features popular with fans of the genre are online racing, realism and diversity of cars and tracks.

Research

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Driving simulators are used at research facilities for many purposes. Many vehicle manufacturers operate driving simulators, e.g. BMW, Ford, Renault. Many universities also operate simulators for research. Driving simulators allow researchers to study driver training issues and driver behavior under conditions in which it would be illegal and/or unethical to place drivers. For instance, studies of driver distraction would be dangerous and unethical (because of the inability to obtain informed consent from other drivers) to do on the road.

With the increasing use of various in-vehicle information systems (IVIS) such as satellite navigation systems, cell phones, DVD players and e-mail systems, simulators are playing an important rule in assessing the safety and utility of such devices.

Fidelity

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There exists a number of types research driving simulators, with a wide range of capabilities. The most complex, like the National Advanced Driving Simulator, have a full-sized vehicle body, with six-axis movement and 360-degree visual displays. On the other end of the range are simple desktop simulators that are often implemented using a computer monitor for the visual display and a videogame-type steering wheel and pedal input devices. These low cost simulators are used readily in the evaluation of basic and clinically oriented scientific questions.[5][6][7][8][9][10] The issue is complicated by political and economic factors, as facilities with low-fidelity simulators claim their systems are "good enough" for the job, while the high-fidelity simulator groups insist that their (considerably more expensive) systems are necessary. Research into motion fidelity indicates that, while some motion is necessary in a research driving simulator, it does not need to have enough range to match real-world forces.[11] Recent research has also considered the use of the real-time photo-realistic video content that reacts dynamically to driver behaviour in the environment.[12]

Validity

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There is a question of validity—whether results obtained in the simulator are applicable to real-world driving. One review of research studies found that driver behavior on a driving simulator approximates (relative validity) but does not exactly replicate (absolute validity) on-road driving behavior.[13] Another study found absolute validity for the types and number of driver errors committed on a simulator and on the road.[14] Yet another study found that drivers who reported impaired performance on a low fidelity driving simulator were significantly more likely to take part in an accident in which the driver was at least partially at fault, within five years after the simulator session.[15] Some research teams are using automated vehicles to recreate simulator studies on a test track, enabling a more direct comparison between the simulator study and the real world.[16] As computers have grown faster and simulation is more widespread in the automotive industry, commercial vehicle math models that have been validated by manufacturers are seeing use in simulators.

See also

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References

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  1. ^ a b "Sega's Wonderful Simulation Games Over The Years". Arcade Heroes. 6 June 2013. Retrieved 22 April 2021.
  2. ^ a b Horowitz, Ken (6 July 2018). The Sega Arcade Revolution: A History in 62 Games. McFarland & Company. pp. 96–9. ISBN 978-1-4766-3196-7.
  3. ^ "The Disappearance of Yu Suzuki: Part 1". 1Up.com. 2010. p. 2. Archived from the original on 2016-06-02. Retrieved 22 April 2021.
  4. ^ "Japanese JAMMA Show". Leisure Line. Australia: Leisure & Allied Industries. November 1991. p. 5.
  5. ^ Li, Z., & Milgram, P. (2005). An Investigation of the Potential to Influence Braking Behaviour Through Manipulation of Optical Looming Cues in a Simulated Driving Task. Proceedings of the Human Factors and Ergonomics Society Annual Meeting, 49(17), 1540–1544.
  6. ^ Matthews, R. W., Ferguson, S. A., Zhou, X., Sargent, C., Darwent, D., Kennaway, D. J., & Roach, G. D. (2012). Time-of-Day Mediates the Influences of Extended Wake and Sleep. Chronobiology International, 29(5): 572–579
  7. ^ Baulk, S. D., Biggs, S. N., Reid, K. J., van den Heuvel, C. J., & Dawson, D. (2008). Chasing the silver bullet: Measuring driver fatigue using simple and complex tasks. Accident Analysis & Prevention, 40(1), 396–402.
  8. ^ Telner, J. A., Wiesenthal, D. L., & Bialystok, E. (2009). Video Gamer Advantages in a Cellular Telephone and Driving Task. Proceedings of the Human Factors and Ergonomics Society Annual Meeting, 53(23), 1748–1752.
  9. ^ Telner, J. A. (2008). The effects of linguistic fluency on performance in a simulated cellular telephone and driving situation. Proceedings of the Human Factors and Ergonomics Society Annual Meeting, 1748–1752.
  10. ^ Rapoport, M. J., Weaver, B., Kiss, A., Zucchero Sarracini, C., Moller, H., Herrmann, N., Lanctôt, K., et al. (2011). The Effects of Donepezil on Computer-Simulated Driving Ability Among Healthy Older Adults: A Pilot Study. Journal of clinical psychopharmacology, 31(5), 587.
  11. ^ Greenberg J., Artz B., Cathey L. The Effect of Lateral Motion Cues During Simulated Driving. Driving Simulator Conference North America 2003 Proceedings, Dearborn, Michigan, October 8–10, 2003, CD-ROM (ISSN 1546-5071)
  12. ^ Heras, A.M.; Breckon, T.P.; Tirovic, M. (November 2011). "Video Re-sampling and Content Re-targeting for Realistic Driving Incident Simulation". Proc. 8th European Conference on Visual Media Production (PDF). pp. sp-2. Retrieved 8 April 2013.[permanent dead link]
  13. ^ Mullen, Nadia. Charlton, Judith, Devlin, Anna, and; Bédard, Michel (2011). Chapter 13: Simulator Validity: Behaviors Observed on the Simulator and on the Road. Handbook of Driving Simulation for Engineering, Medicine, and Psychology D. L. Fisher, Rizzo, M., Caird, Jeff K., and Lee, John D. (eds.). Boca Raton, FL, CRC Press/Taylor & Francis
  14. ^ Shechtman, Orit, Classen, Sherrilene, Awadzi, Kezia, Mann, William (2009). "Comparison of Driving Errors Between On-the-Road and Simulated Driving Assessment: A Validation Study." Traffic Injury Prevention 10(4): 379-385
  15. ^ Hoffman, L., & McDowd, J. M. (2010). Simulator driving performance predicts accident reports five years later. Psychology and Aging, 25(3), 741-745
  16. ^ "Program develops new test track capability Archived March 22, 2007, at the Wayback Machine". ITS Sensor. Winter 2004. Retrieved on February 14, 2007