Notice: Function _load_textdomain_just_in_time was called incorrectly. Translation loading for the twentysixteen domain was triggered too early. This is usually an indicator for some code in the plugin or theme running too early. Translations should be loaded at the init action or later. Please see Debugging in WordPress for more information. (This message was added in version 6.7.0.) in /opt/bitnami/wordpress/wp-includes/functions.php on line 6121
{"id":4076,"date":"2016-08-17T18:08:21","date_gmt":"2016-08-17T18:08:21","guid":{"rendered":"https:\/\/www.trafficsafetystore.com\/blog\/?p=4076"},"modified":"2016-08-17T18:08:21","modified_gmt":"2016-08-17T18:08:21","slug":"autonomous-car-technology","status":"publish","type":"post","link":"https:\/\/staging.trafficsafetystore.com\/blog\/autonomous-car-technology\/","title":{"rendered":"Autonomous Car Technology – Past, Present, and Future"},"content":{"rendered":"

Building The Dream Of Automated Driving Cars<\/h2>

Throughout the past decade, we have witnessed one of the greatest strides in automobile technology with the focus on autonomous cars.<\/p>

Advancements have accelerated with the participation of the leading car developers including BMW, Ford, Audi, and most recently Google and Tesla entering the ring.<\/p>

While you may only recently have heard about self-driving cars in the news, you may be surprised to know that <\/span>researchers have been experimenting with self-driving vehicles<\/span><\/a> for over 45 years. <\/span><\/p>

An early article in IEEE Spectrum from July 1969 was published outlining technical research performed by and experimentation to produce the first vehicle that will operate autonomously. <\/span><\/p>

In their featured article<\/span><\/a>, lead engineers Robert E. Fenton and Karl W. Olson hypothesized that the future of automated vehicles would rely on \u201csmart infrastructure\u201d that would guide cars on roadways. One way to address the need for advanced infrastructure is by integrating beacons and other sensors into existing traffic equipment like road cones<\/a>. This will allow self-driving cars to navigate safely while also alerting humans to dangerous surroundings.\u00a0<\/span><\/p>

While their predictions are not too far off, we are seeing the future of self-driving cars evolving toward the direction of cars that can interpret and act based on their immediate environment. The future of smart cars relies upon the on-board technology of each car.<\/span><\/p>

Current And Future Technologies<\/h2>

Our application of technology will change as we advance towards the reality of self-driving vehicles. <\/span>Various techniques will be used<\/span><\/a> to allow vehicles to understand their surrounding environment in a dynamic driving environment, and the vehicle must be able to act in response to specific changes in their environment. <\/span><\/p>

These vehicles require a broad range of technologies and infrastructures to operate properly. Each vehicle is required to continuously collect and interpret vast amounts of information. Every system of the car must work with the surrounding environment, and technological advancements must be made to ensure autonomous vehicles work within several contexts, including: <\/span><\/p>

  1. Long-range radar<\/span><\/li>
  2. LIDAR (laser scan)<\/a><\/span><\/li>
  3. Cameras<\/span><\/li>
  4. Short\/medium-range radar<\/span><\/li>
  5. Ultrasound<\/span><\/li><\/ol>

    These technologies will be used in different capacities based on a particular need of the vehicle. This technology also has to work with signals made for humans like safety cones<\/a>, so automakers need to consider robots and humans at the same time.\u00a0<\/span><\/p>

    For example, Cameras will receive visual information to help the car\u2019s software determine traffic signals and cross traffic warning. Ultrasound will be used to inform about the immediate environment for parking assistance. <\/span><\/p>

    Each of these technologies will collect different information for the vehicle, and based on the information collected the car will make interpretations and make the appropriate response for that situation. <\/span><\/p>

    Classifications of Automated Vehicles<\/h2>

    As technology advances, our roads are being shared with automated vehicles that utilize a varying degree of technologies and applications. Different technologies allow for a wide range automation for vehicles. <\/span><\/p>

    These levels of automation describe various elements and capabilities of the vehicles as they pertain to driving automation. The five levels of automated vehicles represent capabilities and options for drivers. These standards include: <\/span><\/p>

    No Automation<\/span><\/h3>

    Requires driver input at all times. This type of vehicle the driver to perform all aspects of driving, and is the most common type of vehicle seen on the road today. Think of these as \u201cdumb cars\u201d because the vehicle provide no assistance to drivers.<\/span><\/p>

    Driver Assistance<\/span><\/h3>

    Vehicles that provide some driving mode-specific tasks by the car like steering or acceleration\/deceleration assistance. Drivers are required to perform all active driving duties, but automation technology exists to help with warnings and alerts. This is the last level of automation technology that many US states consider a vehicle to be \u201cnon-automated.\u201d<\/span><\/p>

    Partial Automation<\/span><\/h3>

    Similar to Driver Assistance technologies, these cars use information in their driving environment to assist drivers in limited real-time conditions. \u00a0These cars use information in their immediate surroundings to help the driver with some dynamic driving tasks, but still require the driver to perform all necessary reactions. This is the first level of automated vehicle technology that many US states begin to consider a vehicle to be \u201cautomated.\u201d<\/span><\/p>

    Conditional Automation<\/span><\/h3>

    At this level, the vehicle starts to monitor the driving environment, and specific performance modes allow the car to make decisions based on current conditions. The driver can intervene when appropriate, but the vehicle is able to take action based on minor driving conditions. <\/span><\/p>

    High Automation<\/span><\/h3>

    An Hgh Automated driving system allows the vehicle to take action in all aspects of a dynamic driving task even without the response of the driver. <\/span><\/p>

    Full Automation<\/span><\/h3>

    This is the ultimate level of automation for a vehicle because at this level the car is equipped with technologies that allow it to respond under all roadway and environmental conditions. This level of automation vehicles does not require the presence or input of a human driver. <\/span><\/p>

    Each level of automation requires different on-board technologies to collect and interpret different information so the vehicle can take appropriate actions. <\/span><\/p>

    Since vehicle automation at level 3 and beyond are considered by many states as automated vehicles, there are stringent requirements that must be met for automation. Among the factors that must be fulfilled for vehicles at level 3 and beyond to operate on public roads include: <\/span><\/p>