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Group of Texas A&M University researchers investigates causes of unintended vehicle acceleration

Dr. Thomas Ferris, assistant professor in industrial and systems engineering, and his students in the Human Factors & Cognitive Systems Laboratory are collaborating with principal investigator Robert Wunderlich, researchers at the Texas A&M Transportation Institute (TTI), the University of Houston, the University of Michigan and Texas Tech University. This mega-team is investigating possible human- and vehicle-driven causes of unintended vehicle acceleration. The research was prompted after a series of accidents occurring in Toyota vehicles from 2002 to 2010.

“Unintended acceleration accidents are a complex problem with many potential causal factors,” Ferris said. “Humans are not very good at problem-solving under this sort of cognitive state so we are trying to use the computational power of the vehicle to detect when drivers exhibit particular stress patterns. If the car knows that the human driver is under the influence of a particular stressor, it can provide support that is more appropriately tailored to the driver’s cognitive state.”

 

The research is being conducted in a simulation facility at TTI, as well as a test track at Texas A&M’s RELLIS campus. Participants spend time driving in a simulator in the lab, or in a real vehicle on a controlled course, while being monitored using biometric sensors. Researchers monitor heart rate, galvanic skin response, thermal imagery and the amount of sweat a person produces to determine different patterns in changing levels of stress. By using the simulator, researchers are able to explore additional driver conditions, as it allows safely simulated unintended vehicle acceleration or distracted driving.

 

“What we are actually able to detect is a pattern in sympathetic autonomous nervous system arousal,” Ferris said. “When a surprising, mentally challenging, or strongly emotional experience occurs, the driver is feeling their sympathetic nervous system preparing to fight or flight – to assess a potential threat and to focus cognitive efforts on that threat.”

 

This is helpful to the person if they are trying to flee an attacking tiger, but can impair the ability to maintain control of a complex system such as a modern vehicle. In addition to distractions, a driver’s cognitive state could also be impacted by stress from an emotional response, being overworked or lack of sleep.

 

After the system determines the driver is operating under a problematic state, the researchers test several techniques to help the driver recover, such as disengaging the transmission, or removing distractions to call attention back to the road. This can be achieved by a flashing light on the dashboard or by turning off the radio.

 

Although the researchers are some distance away from installing this device in all new cars, the group is currently testing a prototype device developed by members of the research team. A number of upcoming studies will test this and other potential solutions in simulation studies, on the controlled test-track and maybe even in vehicles on active roadways. The idea is to ultimately test research participants in a realistic setting with real distractions and real emotional responses encountered in traffic.

The article is available here.

 

Original Source: Texas A&M Today

Group of Texas A&M University researchers investigates causes of unintended vehicle acceleration

Dr. Thomas Ferris, assistant professor in industrial and systems engineering, and his students in the Human Factors & Cognitive Systems Laboratory are collaborating with principal investigator Robert Wunderlich, researchers at the Texas A&M Transportation Institute (TTI), the University of Houston, the University of Michigan and Texas Tech University. This mega-team is investigating possible human- and vehicle-driven causes of unintended vehicle acceleration. The research was prompted after a series of accidents occurring in Toyota vehicles from 2002 to 2010.

“Unintended acceleration accidents are a complex problem with many potential causal factors,” Ferris said. “Humans are not very good at problem-solving under this sort of cognitive state so we are trying to use the computational power of the vehicle to detect when drivers exhibit particular stress patterns. If the car knows that the human driver is under the influence of a particular stressor, it can provide support that is more appropriately tailored to the driver’s cognitive state.”

 

The research is being conducted in a simulation facility at TTI, as well as a test track at Texas A&M’s RELLIS campus. Participants spend time driving in a simulator in the lab, or in a real vehicle on a controlled course, while being monitored using biometric sensors. Researchers monitor heart rate, galvanic skin response, thermal imagery and the amount of sweat a person produces to determine different patterns in changing levels of stress. By using the simulator, researchers are able to explore additional driver conditions, as it allows safely simulated unintended vehicle acceleration or distracted driving.

 

“What we are actually able to detect is a pattern in sympathetic autonomous nervous system arousal,” Ferris said. “When a surprising, mentally challenging, or strongly emotional experience occurs, the driver is feeling their sympathetic nervous system preparing to fight or flight – to assess a potential threat and to focus cognitive efforts on that threat.”

 

This is helpful to the person if they are trying to flee an attacking tiger, but can impair the ability to maintain control of a complex system such as a modern vehicle. In addition to distractions, a driver’s cognitive state could also be impacted by stress from an emotional response, being overworked or lack of sleep.

 

After the system determines the driver is operating under a problematic state, the researchers test several techniques to help the driver recover, such as disengaging the transmission, or removing distractions to call attention back to the road. This can be achieved by a flashing light on the dashboard or by turning off the radio.

 

Although the researchers are some distance away from installing this device in all new cars, the group is currently testing a prototype device developed by members of the research team. A number of upcoming studies will test this and other potential solutions in simulation studies, on the controlled test-track and maybe even in vehicles on active roadways. The idea is to ultimately test research participants in a realistic setting with real distractions and real emotional responses encountered in traffic.

The article is available here.

 

Original Source: Texas A&M Today

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