DRIVERLESS CAR

An autonomous car (also known as a driverless car, self-driving car, robotic car and unmanned ground vehicle is a vehicle that is capable of sensing its environment and navigating without human input. Many such systems are evolving, but as of 2017 no cars permitted on public roads were fully autonomous. They all require a human at the wheel who must be ready to take control at any time.

FIRST IN:

Navlab autonomous cars 1 through 5. NavLab 1 (farthest in photo) was started in 1984 and completed in 1986. Navlab 5 (closest vehicle), finished in 1995, was the first car to drive coast-to-coast (USA) autonomously.

GOOGLE PROJECT:

Google kickstarted its own self-driving car project in 2008, and it has been rumbling on ever since, first with modified Toyota Prius and then with customised Lexus SUVs, which took the car's existing sensors, such as the cruise-control cameras, and added a spinning laser scanner on the top.

10 THING GOOGLE CAR USED:

LASER RANGE FINDER:-

The heart of Google’s self driving car is the rotating roof top camera, Lidar, which is a laser range finder. With its array of 64 laser beams, this camera creates 3D images of objects helping the car see hazards along the way. This device calculates how far an object is from the moving vehicle based on the time it takes for the laser beams to hit the object and come back. These high intensity lasers can calculate distance and create images for objects in an impressive 200m range.

FRONT CAMERA FOR NEAR VISION:-

FRONT CAMERA FOR NEAR VISION

A camera mounted on the windshield takes care of helping the car ‘see’ objects right in front of it. These include the usual suspects- pedestrians, and other motorists. This camera also detects and records information about road signs and traffic lights, which is intelligently interpreted by the car’s in built software.
BUMPER MOUNTED RADAR:-

BUMPER MOUNTED RADAR

4 radars mounted on the car’s front and rear bumpers enable the car to be aware of vehicles in front of it and behind it. Most of us are familiar with this technology as it is the same as the adaptive cruise control systems our cars are based. The radar sensor on the car’s bumpers keeps a ‘digital eye’ on the car ahead. The software is programmed to (at all times) maintain a distance of 2-4 seconds (it could even be higher) vis-a-vis the car ahead of it. So with this technology the car will automatically speed up or slow down depending on the behaviour of the car/driver ahead. Google’s self-driving cars use this technology to keep passengers and other motorists safe by avoiding bumps and crashes.

AREAL READS PRICISE GEO-LOCATION:-

LOCATION

An aerial on the rear of the car receives information about the precise location of the car, thanks to GPS satellites. The car’s GPS inertial navigation unit works with the sensors to help the car localise itself. But GPS estimates may be off by several metres due to signal disturbances and other interferences from the atmosphere. To minimise the degree of uncertainty, the GPS data is compared with sensor map data previously collected from the same location. As the vehicle moves, the vehicle’s internal map is updated with new positional information displayed by the sensors.

ALTRA SONIC SENSOR IN REAR WHEEL:-

ULTRASONIC SENSORS ON REAR WHEELS

An ultrasonic sensor on one of the rear wheels helps keep track of the movements of the car and will alert the car about the obstacles in the rear. These ultrasonic sensors are already in action in some of the technologically advanced cars of today. Cars that offer automatic ‘Reverse Park Assist’ technology utilise such sensors to help navigate the car into tight reverse parking spots. Typically, these sensors get activated when the car is engaged in the reverse gear.

DEVICES WITHIN CAR:-

CAR

Inside the car are altimeters, gyroscopes, and tachymeters that determine the very precise position of the car thanks to the various parameters they measure. This offers highly accurate data for the car to operate safely.

SYNERGISTIC COMBINING OF SENSORS

All the data gathered by these sensors is collated and interpreted together by the car’s CPU or in built software system to create a safe driving experience.

PROGRAMMED TO INTERPRET COMMON ROAD SIGNS

The software has been programmed to rightly interpret common road behaviour and motorist signs. For example, if a cyclist gestures that he intends to make a manoeuvre, the driverless car interprets it correctly and slows down to allow the motorist to turn. Predetermined shape and motion descriptors are programmed into the system to help the car make intelligent decisions. For instance, if the car detects a 2 wheel object and determines the speed of the object as 10mph rather than 50 mph, the car instantly interprets that this vehicle is a bicycle and not a motorbike and behaves accordingly. Several such programs fed into the car’s central processing unit will work simultaneously, helping the car make safe and intelligent decisions on busy roads.

MAPPING IN ADVANCE

At the moment, before a self-driven car is tested, a regular car is driven along the route and maps out the route and it’s road conditions including poles, road markers, road signs and more. This map is fed into the car’s software helping the car identify what is a regular part of the road. As the car moves, its Velodyne laser range finder kicks in (see point 1) and generates a detailed 3D map of the environment at that moment. The car compares this map with the pre-existing map to figure out the non-standard aspects in the road, rightly identifying them as pedestrians and/or other motorists, thus avoiding them.

PROGRAMMING REAL LIFE ROAD BEHAVIOUR

Google engineers have programmed some real life behaviour in these cars. While the vehicle does slow down to allow other motorists to go ahead, especially in 4 way intersections, the car has also been programmed to advance ahead if it detects that the other vehicle is not moving.

Though Google’s self-driving car is not here yet, all this technology sure does make it exciting. And perhaps we are closer to driving one that we let ourselves believe.