The feds are investigating Tesla’s autopilot AGAIN — here’s why
What does this mean for the future of self-driving cars?
How Tesla’s Autopilot works
Tesla’s Autopilotuses cameras, radar, and ultrasonic sensors to support two major features: Traffic-Aware Cruise Control and Autosteer.
Traffic-Aware Cruise Control, also known as adaptive cruise control, maintains a safe distance between the car and other vehicles that are driving ahead of it. This technology primarily uses cameras in conjunction with artificial intelligence algorithms to detect surrounding objects such as vehicles, pedestrians and cyclists, and estimate their distances. Autosteer uses cameras to detect clearly marked lines on the road to keep the vehicle within its lane.
In addition to its Autopilot capabilities, Tesla has been offering what it calls “full self-driving” features that includeauto parkandauto lane change. Since its first offering of the Autopilot system and other self-driving features, Tesla has consistently warned users that these technologies require active driver supervision and that these features do not make the vehicle autonomous.
Tesla is beefing up the AI technology that underpins Autopilot. The company announced on Aug. 19, 2021, that it isbuilding a supercomputer using custom chips. The supercomputer will help train Tesla’s AI system to recognize objects seen in video feeds collected by cameras in the company’s cars.
Autopilot does not equal autonomous
Advanced driver-assistance systems have been supported on a wide range of vehicles for many decades. The Society of Automobile Engineers divides the degree of a vehicle’s automation intosix levels, starting from Level 0, with no automated driving features, to Level 5, which represents full autonomous driving with no need for human intervention.
Within these six levels of autonomy, there is a clear and vivid divide between Level 2 and Level 3. In principle, at Levels 0, 1, and 2, the vehicle should be primarily controlled by a human driver, with some assistance from driver-assistance systems. At Levels 3, 4, and 5, the vehicle’s AI components and related driver-assistance technologies are the primary controllers of the vehicle. For example, Waymo’sself-driving taxis, which operate in the Phoenix area, are Level 4, which means they operate without human drivers but only under certain weather and traffic conditions.
Tesla Autopilot is considered a Level 2 system, and hence the primary controller of the vehicle should be a human driver. This provides a partial explanation for the incidents cited by the federal investigation. Though Tesla says it expects drivers to be alert at all times when using the Autopilot features, some drivers treat the Autopilot as having autonomous driving capability with little or no need for human monitoring or intervention. This discrepancy between Tesla’s instructions anddriver behaviorseems to be a factor in the incidents under investigation.
Another possible factor is how Tesla assures that drivers are paying attention. Earlier versions of Tesla’s Autopilotwere ineffective in monitoring driver attentionand engagement level when the system is on. The company instead relied on requiring drivers to periodically move the steering wheel, which can be done without watching the road. Tesla recently announced that it has begun usinginternal cameras to monitor drivers’ attentionand alert drivers when they are inattentive.
Another equally important factor contributing to Tesla’s vehicle crashes is the company’s choice of sensor technologies. Tesla has consistentlyavoided the use of lidar. In simple terms,lidar is like radarbut with lasers instead of radio waves. It’s capable of precisely detecting objects and estimating their distances. Virtually all major companies working on autonomous vehicles, including Waymo, Cruise, Volvo, Mercedes, Ford, and GM, are using lidar as an essential technology for enabling automated vehicles to perceive their environments.
By relying on cameras, Tesla’s Autopilot is prone to potential failures caused by challenging lighting conditions, such as glare and darkness. In its announcement of the Tesla investigation, the NHTSA reported that most incidents occurred after dark where there were flashing emergency vehicle lights, flares, or other lights. Lidar, in contrast, can operate under any lighting conditions and can “see” in the dark.
Fallout from the investigation
The preliminary evaluation will determine whether the NHTSA should proceed with an engineering analysis, which could lead to a recall. The investigation could eventually lead to changes in future Tesla Autopilot and its other self-driving system. The investigation might also indirectly have a broader impact on the deployment of future autonomous vehicles; in particular, the investigation may reinforce the need for lidar.
Although reports in May 2021 indicated thatTesla was testing lidar sensors, it’s not clear whether the company was quietly considering the technology or using it to validate their existing sensor systems. Tesla CEO Elon Musk called lidar “a fool’s errand” in 2019, saying it’s expensive and unnecessary.
However, just as Tesla is revisiting systems that monitor driver attention, the NHTSA investigation could push the company to consider adding lidar or similar technologies to future vehicles.
Article byHayder Radha, Professor of Electrical and Computer Engineering,Michigan State University
This article is republished fromThe Conversationunder a Creative Commons license. Read theoriginal article.
Story byThe Conversation
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