SlideShare a Scribd company logo

Google's driverless car technology

Download as DOCX, PDF
Harshdeep Kaur
Harshdeep Kaur

The document discusses Google's driverless car project. It describes how the car uses sensors like LIDAR, radar and cameras to navigate roads autonomously. It summarizes the components of the car including hardware like sensors and software for artificial intelligence. It provides details on how the car was tested, including routes driven and miles completed without accidents. It concludes that fully autonomous vehicles could help reduce accidents and increase mobility.

Technology
1 of 11
Wireless sensor Networks GOOGLE Driverless Car Harshdeep kaur S.c.d Govt college harshdeep1641991@gmail.com
Google driverless car Harshdeep kaur S.c.d govt college Ludhiana harshdeep1641991@gmail.com Abstract objective:- Driver error is the most common cause of traffic accidents India contributes 6 % of the world's road accident deaths.India contributes 6 % of the world's road accident deaths Cell phones in-car, entertainment systems, more traffic and more complicated road systems making it more frequent by this improving technology our car will do the concentrating for us. it will be the engine pulling the industry forward. Consumers are eager for new mobility alternatives that would allow them to stay connected and recapture the time and psychic energy they squander in traffic jams and defensive driving Scope: - It can steer itself while looking out for obstacles. It can accelerate itself to the correct speed limit. It can stop and go itself based on any traffic condition. Reduction in car accidents by automated collision avoidance system. it can also avoid human errors. It is fuel efficient and also safe for highways. Components:- Google Maps, Hardware Sensors, LIDAR ,Video Camere,Position Estimator, Distance Sensor, Automotive Night Vision, Artificial Intelligence Conclusion:- the reliability efficiency and cost effectiveness of autonomous vehicle depend mainly on how judiciously its navigation sensors , perception unit and computer control unit is in corporate. The driver’s activity is influenced by several factors that depend on driver itself and is environment such as traffic density, traffic status, time of travel and weather. Thus the driving activity deals with a combined driver vehicle-environment system. The vehicle is required to blend its environmental perception capabilities with its intelligent controls in order to affect optimal path-planning strategies and minimize criteria such as time of travel, fuel consumption, exposure to danger etc. however basic driving functions consists of lane-keeping, safe distance maintenance, timely lane changing anthese driving tasks is collision avoidance.
Introduction In the 21 century. so many operates operate automatically which start from food factories to food factories machines to aeroplane which fly’s on autopilot without the need of human pilots then come missals and satellite which are programmed and manuring is done automatically to reach the destination there are some metro train also which run on the command of autonomous software now the new things has come which was suppose to be looking impossible .that is moving a vehicle on crowed roads but these has been made possible by Google From the invention of the car there is a great relation between human and car. Because by the invention of the car the automobile industry was established, by this car the travelling time from one place to another place is reduced. The car brings royalty from the invention. As cars are coming on roads at that time there are so many accidents are occurring due to lack of driving knowledge & drink driving and soon, In that view only the Google took a great project, i.e. Google Driverless Car in these the Google puts the technology . The input video camera was fixed beside the front mirror inside the car, A LIDAR sensor was fixed on the top of the vehicle, RADAR sensor on the front of the vehicle and a position sensor attached to one of the rear wheels that helps locate the cars position on the map, The Computer, Router, Switch, Fan, Inverter, rear Monitor, Topcon, Velodyne, Applanix and Battery are kept inside the car. These all components are connected to computer’s CPU and the monitor is fixed on beside of the driver seat, these we can observe in that monitor and can operate all the operations. The system combines information gathered from Google street view with artificial intelligence software that combines input from video camera inside the car, a LIDAR sensor on the top of the vehicle, RADAR sensors on the front of the vehicle and a position sensor attached to one of the rear wheel that helps to locate the car position on the map. At the same time some hardware components are used in the car these are APPIANIX PCS, VELODYNE, SWITCH,TOPCON, REAR MONITOR, COMPUTER, ROUTER, FAN, INVERTER and BATTERY along with some software program is installed in it. By all the components combined together to operate the car without the DRIVER. i.e., the car drives itself only Google hopes to have fully autonomous vehicles on the road by 2020, taking the driver completely out of the equation and handing the virtual wheel to its sophisticated combination of software and sensors, which continue to improve and evolve, “transform people’s lives through mobility,” citing cases of blind and older drivers who would suddenly have more freedom. Google's robotic cars have about $150,000 in equipment including a $70,000 LIDAR system. The range finder mounted on the top is a Velodyne 64-beam laser. This laser allows the vehicle to generate a detailed 3D map of its environment. The car then takes these generated maps and combines them with high- resolution maps of the world, producing different types of data models that allow it to drive itself.
HISTORY The Sebastian Thrun was invented the Google driverless car. He was director of the Stanford Artificial Intelligence laboratory. Sebastian friends were killed in car accident, so that he decided there should not be any accidents on the road by car. By that decision only the Google Driverless car was invented. ”Our goal is to help prevent traffic accidents, free up people’s time and reduce carbon emission by fundamentally changing car use”-Sebastian Thrun The Google Driverless car was tested in the year 2010; Google has tested several vehicles equipped with the system, driving 1,609 kilometers (1,000 mi) without any human intervention, in addition to 225,308 kilometers (140,000 mi) with occasional human intervention. Google expects that the increased accuracy of its automated driving system could help reduce the number of traffic-related injuries and deaths, while using energy and space on roadways more efficiently. It was introduced in oct-2010 and it becomes legal in Nevada at June 2011, August 2012- Accident. The project team has equipped a test fleet of at least eight vehicles, consisting of six Toyota Prius, an Audi TT, and a Lexus RX450h, each accompanied in the driver's seat by one of a dozen drivers with unblemished driving records and in the passenger seat by one of Google's engineers. The car has traversed San Francisco's Lombard Street, famed for its steep hairpin turns and through city traffic. The vehicles have driven over the Golden Gate Bridge and on the Pacific Coast Highway, and have circled Lake Tahoe. The system drives at the speed limit it has stored on its maps and maintains its distance from other vehicles using its system of sensors. The system provides an override that allows a human driver to take control of the car by stepping on the brake or turning the wheel, similar to cruise control systems already in cars. Components Google Map: Google Maps is a Google service offering powerful, user-friendly mapping technology and local business information-including business locations, contact information, and driving directions.
Google Street View: Google Street View (GSV) has rapidly expanded to provide street-level images of entire cities all around the world. The number and density of geo-positioned images available make this service truly unprecedented. A Street View user can wander through city streets, enabling a wide range of uses such as scouting a neighborhood, or finding specific items such as bike racks or mail boxes. LIDAR Sensor: Light Detection and Ranging is an optical remote sensing technology that can measure the distance to, or other properties of a target by illuminating the target with light, often using pulses from a laser. LIDAR uses ultraviolet, visible, or near infrared light to image objects and can be used with a wide range of targets, including non-metallic objects, rocks, rain, chemical compounds, aerosols, clouds and even single molecules. A narrow laser beam can be used to map physical features with very high resolution. The LIDAR (Light detection and Ranging) sensor is a scanner. It will rotate in the circle. It is fixed on the top of the car. In the scanner contains the 64 lasers that are send surroundings of the car through the air. These the laser is hits objects around the car and again comes back to it. By these known How far that objects are from the car and also it calculates the time to reach that object. These are can see in monitor in a 3D object with the map. The monitor is fixed in front seat. “The heart of the system generates a detailed 3D map of environment (velodyne 64- beam laser). The map accessed from the GPRS connection.
Radar sensor: The three RADAR sensors were fixed in front of the bumper and one in the rear bumper. These will measures the distance to various obstacles and allow the system to reduce the speed of the car. The back side of sensor will locates the position of the car on the map. Radar (Radio Detection And Ranging) is an object- detection system which uses radio waves to determine the range, altitude, direction, or speed of objects. It can be used to detect aircraft, ships, spacecraft, guided missiles, motor vehicles, weather formations, and terrain. The radar dish or antenna transmits pulses of radio waves or microwaves which bounce off any object in their path. The object returns a tiny part of the wave’s energy to a dish or antenna which is usually located at the same site as the transmitter. For example, when the car was travelling on the road then RADAR sensor was projected on road from front and back side of the car. Position Sensor: This device provides the latitude, longitude and altitude together with the corresponding standard deviation and the standard NMEA messages with a frequency of 5 Hz. When geostationary satellites providing the GPS drift correction are visible from the car, the unit enters the differential GPS mode (high precision GPS). When no correction signal is available, the device outputs standard precision GPS. This sensor is mounted on left rear wheel measure lateral movement and determines cars position on map Video camera: The video camera was fixed near the rear view mirror. That will detect traffic lights and any moving objects front of the car. For example if any vehicle or traffic detected then the car will be slow down automatically, these all will be done by the artificial intelligence software only. Position estimator: A sensor mounted on the left rear wheel. By these sensor only measures small movements made by the car and helps to accurately locate its position on the map. The position of the car can be seen on the monitor performing much the same function as amildy interested human motorist the camera reads road signs, detect traffics lights, and keep out for pedestrians , cyclist , other motorist and similar obstacles
Computer: information from various sensors is fed into the car’s central computer. here the data is analysed and steering acieration and brakes adjusted accordingly. Importantly , the computer needs yo understand not only the traffic laws but also the unspoken assumption of road users Automative night vision: automotive night vision comes in two flavors near and far infrared .the near infrared technology detects the portion of the ir band nearest to visible light. Special bulbs mounted next to the headlights are aimed straight ahead like a car’s high beam, the NIR system is illuminate the surroundings with infrared light in the wavelength of 800 to 900 nm. How the car work’s Google’s driverless car tech uses an array of detection technologies including sonar devices, stereo cameras, lasers, and radar. All these components have different ranges and fields of view, but each serves a particular purpose according to the patent filings Google has made on its driverless cars. Anyone who has ever seen an image of Google’s self-driving Prius has probably noticed one of these systems poking up above the vehicle — the LIDAR laser remote sensing system. According to Google engineers, this is at the heart of object detection The LIDAR system bolted to the top of Google’s self-driving car is crucially important for several reasons. First, it’s highly accurate up to a range of 100 meters. There are a few detection technologies on the car that work at greater distances, but not with the kind of accuracy you get from a laser. It simply bounces a beam off surfaces and measures the reflection to determine distance. The device used by Google — a Velodyne 64-beam laser — can also rotate 360-degrees and take up to 1.3 million readings per second, making it the most versatile sensor on the car. Mounting it on top of the car ensures its view isn’t obstructed. Google mounts regular cameras around the exterior of the car in pairs with a small separation between them. The overlapping fields of view create a parallax not unlike your own eyes that allow the system to track an object’s distance in real time. As long as it has been spotted by more than one camera, the car knows where it is. These stereo cameras have a 50-degree field of view, but they’re only accurate up to about 30 meters. Google’s LIDAR system is great for generating an accurate map of the car’s surroundings, but it’s not ideal for monitoring the speed of other cars in real time. That’s why the front and back bumper of the driverless car includes radar. This is one of the few technologies Google employs in its driverless car that you can already get in mainstream vehicles. Conventional vehicles use radar to warn you of an impending impact or even apply the brakes to prevent one, but the Google car uses radar to adjust the throttle and brakes continuously. It’s essentially adaptive cruise control that always takes into account the movement of cars around you. The radar system is probably paired with sonar in at least some of Google’s test cars. While radar works up to 200 meters away, sonar is only good for 6 meters. They both have a narrow field of view, so the car knows things are about to get messy if another vehicle crosses the radar and sonar beams. This signal could be used to swerve, apply the brakes, or pre-tension the seatbelts.
Google’s software integrates all the data from these remote sensing systems (as much as 1GB per second) to build a map of the car’s position. Other cars are rendered as rough blocks with shifting, amorphous edges. It doesn’t have to be perfect — it’s not like the Google car needs to get close enough to test the accuracy of the borders. GPS is only accurate to within a few meters, so it’s remarkable the car can even stay in the right lane, let alone avoid collisions. Testing The project team has equipped a test group of at least ten cars, including six Toyota Prius, an Audi TT, and three Lexus RX450h, each accompanied in the driver's seat by one of a dozen drivers with unblemished driving records and in the passenger seat by one of Google's engineers. The car has traversed San Francisco's Lombard Street, famed for its steep hairpin turns, and through city traffic. The vehicles have driven over the Golden Gate Bridge and around Lake Tahoe. The system drives at the speed limit it has stored on its maps and maintains its distance from other vehicles using its system of sensors. The system provides an override that allows a human driver to take control of the car by stepping on the brake or turning the wheel, similar to cruise control systems already found in many cars today. On March 28, 2012, Google posted a YouTube video showing Steve Mahan, a resident of Morgan Hill, California, being taken on a ride in Google's self-driving Toyota Prius. In the video, Mahan states "Ninety- five percent of my vision is gone, I'm well past legally blind". In the description of the YouTube video, it is noted that the carefully programmed route takes him from his home to a drive-through restaurant, then to the dry cleaning shop, and finally back home. In August 2012, the team announced that they have completed over 300,000 autonomous-driving miles (500,000 km) accident-free, typically have about a dozen cars on the road at any given time, and are starting to test them with single drivers instead of in pairs. Four U.S. states have passed laws permitting autonomous cars as of December 2013: Nevada, Florida, California, and Michigan. A law proposed in Texas would establish criteria for allowing "autonomous motor vehicles". In April 2014, the team announced that their vehicles have now logged nearly 700,000 autonomous miles (1.1 million km). In late May, Google revealed a new prototype of its driverless car, which had no steering wheel, gas pedal, or brake pedal, being 100% autonomous.
Vehicle communication system Individual vehicles may benefit from information obtained from other vehicles in the vicinity, especially information relating to traffic congestion and safety hazards. Vehicular communication systems use vehicles and roadside units as the communicating nodes in a peer-to-peer network, providing each other with information. As a cooperative approach, vehicular communication systems can allow all cooperating vehicles to be more effective. According to a 2010 study by the National Highway Traffic Safety Administration, vehicular communication systems could help avoid up to 81 percent of all traffic accidents.[ In 2012, computer scientists at the University of Texas in Austin began developing smart intersections designed for autonomous cars. The intersections will have no traffic lights and no stop signs, instead using computer programs that will communicate directly with each car on the road. Through the implementation of Global Positioning System (GPS), navigation of the autonomous vehicles is simplified. The location of the vehicle can also be acquired by the longitude and latitude obtained by the Google Inside the car:‘The car will pick you up, take you where you want to go and then can go off and do errands like pick up your dry-cleaning, freeing you to do other things, you step inside and sink into soft Hermes orange leather seats. It is surprisingly spacious, uncluttered by the normal ‘car’ things like pedals, a steering wheel and handbrake. Instead there are two buttons – green for Go and red for Stop. There is an oblong flat screen in front of you which shows the time, date, temperature and a computer- generated image of the road ahead. Beneath the high-tech screen is a storage bay for luggage. Hit the Go button and take off. The electric engine purrs into life, taking me to a top speed of 25mph. Security Concerns The widespread implementation of driverless cars, as safe as they are designed to be, indeed has some chance in posing as a threat to a passenger. Buyers will essentially have to make a personal decision as to which is safer: the machine’s calculated decision versus a human’s natural intuition z At times, airplanes and traffic control systems fail due to such technological anomalies. The buyer must then weigh the benefits with such a concern. What makes the driverless car vulnerable to this risk?
ADVANTAGES 1) Self-driving cars would save lives: This is the most obvious one. In the United States from automobile crashes . And roughly 40 percent of fatal accidents are caused by alcohol, distraction, drugs, or fatigue, all of which go away once you take human off the wheel. Letting robots take the wheel would save lives. 2) Commutes would become quicker and less stressful: Research shows that long commutes increase the risk of obesity, divorce, stress, sleeplessness, and neck pain 3) Driverless cars will be more fuel-efficient:. What's more, cars would no longer need to be so big and hulking — since their users don't need to fear crashing as much. That all boosts fuel efficiency. 4) Driverless cars will waste less fuel on things like looking for parking. study found that in congested urban areas, drivers waste an absurd amount of gasoline circling the blocks looking for parking. Intelligent self-driving cars could presumably improve on this — particularly if they could communicate with each other. 5) More and more people will be able to drive. There are plenty of people who are not allowed to drive right now. Everyone under 16 . The elderly . The disabled . People who are intoxicated or on medication. People who are sleeping. All of those people would now be able to get around in driverless cars. 6) Driverless cars could make car-sharing more popular. we spend a lot of money for cars that sit in the parking lot most of the time. In theory, self-driving cars could be used more productively — say, through car-sharing services. That might mean fewer cars overall. 8) Self-driving cars could make the transition to electric vehicles easier. As Google consultant Brad Templeton self-driving cars will allow car manufacturers to radically change their designs. And that could have big implications for electric vehicles. DISADVANTAGE 1) Safety and regulatory concerns. This is one of the big hurdles self-driving cars will have to surmount before catching on — since self-driving cars will likely have to meet more rigorous standards than regular cars. "The first accident that's caused by a computer malfunction will freak everyone out far beyond the thousands of car accidents caused by humans,". WHO IS LIABLE IF A SELF-DRIVING CAR CRASHES? THE MANUFACTURER? THE PASSENGER? 2) Legal challenges. Even if self-driving vehicles are safer, they'll likely never be crash-free. What happens if a pedestrian suddenly jumps out in front of a car? Who would be at fault if the self-driving vehicle hits something or someone? The manufacture ? The person sitting in the car ?
3) Big disruptions in the labor market. In theory, many of those jobs could be replaced by self-driving cars, which would create plenty of dislocation and hardship (as well as possible opposition to the technology). 4) More driving overall and higher energy use. Yes, self-driving cars could be more fuel efficient. But it's also entirely possible that people will end up driving them more, especially if it's cheaper and more convenient. The end result could conceivably be an increase in fuel use or planet-warming greenhouse-gas emissions. (The technical term for this is the "rebound effect.") 5) Suburban sprawl could expand. Right now, there's a serious limit to how sprawled-out a city can get — as a rule, people tend to prefer to keep their commutes under an hour. But if self-driving cars can offer quick, efficient transportation, then we could see more people spread out to the suburbs. It's not clear if this is a problem, but it could be one unexpected side effect. 6) Privacy issues. There are lots of possible issues here. Many of the benefits from self-driving cars come from the vehicles being able to communicate and share data with each other. Likewise, crash data will almost certainly be stored for use by manufacturers and to sort out liability But how much data will be stored? And how will it be shared? In Conclusion In conclusion, upon addressing the mechanics of the driverless car as well as its benefits and potential issues, it is quite interesting to see how the world will actually become by the year 2040. Is IEEE correct? Will the rite of passage of attaining one’s driver license cease to exist? It is truly in the reader’s discretion to determine and weigh the impacts that the driverless car will have on society in the future. Until then, it is fascinating to see the effects this creation will have on the states in which it is legalized as well as on the people that have chosen to experiment with it. Work cited www.google.com www.slideshare.com www.vox.com www.theneweconomy.com en.wikipedia.org sites.google.com

Recommended

Google's Driverless Car report
Google's Driverless Car reportGoogle's Driverless Car report
Google's Driverless Car reportManasa Chowdary
 
Google self driving car technology
Google self driving car technologyGoogle self driving car technology
Google self driving car technologypriyaprabhu95
 
Google driverless car with working
Google driverless car with workingGoogle driverless car with working
Google driverless car with workingPiyush tyagi
 
google driver less car
google driver less cargoogle driver less car
google driver less carPratheesh Nair
 
Google Driverless (Autonomous) Car
Google Driverless (Autonomous) CarGoogle Driverless (Autonomous) Car
Google Driverless (Autonomous) CarFarhan Badar
 
Google's Driverless Car
Google's Driverless CarGoogle's Driverless Car
Google's Driverless Caraishu nischala
 
Finalreport
FinalreportFinalreport
FinalreportManasa Chowdary
 
Googlecar 150915202230-lva1-app6892
Googlecar 150915202230-lva1-app6892Googlecar 150915202230-lva1-app6892
Googlecar 150915202230-lva1-app6892syedjabir
 

Recommended

Google's Driverless Car report
Google's Driverless Car reportGoogle's Driverless Car report
Google's Driverless Car reportManasa Chowdary
 
Google self driving car technology
Google self driving car technologyGoogle self driving car technology
Google self driving car technologypriyaprabhu95
 
Google driverless car with working
Google driverless car with workingGoogle driverless car with working
Google driverless car with workingPiyush tyagi
 
google driver less car
google driver less cargoogle driver less car
google driver less carPratheesh Nair
 
Google Driverless (Autonomous) Car
Google Driverless (Autonomous) CarGoogle Driverless (Autonomous) Car
Google Driverless (Autonomous) CarFarhan Badar
 
Google's Driverless Car
Google's Driverless CarGoogle's Driverless Car
Google's Driverless Caraishu nischala
 
Finalreport
FinalreportFinalreport
FinalreportManasa Chowdary
 
Googlecar 150915202230-lva1-app6892
Googlecar 150915202230-lva1-app6892Googlecar 150915202230-lva1-app6892
Googlecar 150915202230-lva1-app6892syedjabir
 
Final google driverless car (ashok k)
Final google driverless car (ashok k)Final google driverless car (ashok k)
Final google driverless car (ashok k)Ashok Kumbhar
 
Google driverless car technical seminar report (.docx)
Google driverless car technical seminar report (.docx)Google driverless car technical seminar report (.docx)
Google driverless car technical seminar report (.docx)gautham p
 
Google Driverless Car Final
Google Driverless Car FinalGoogle Driverless Car Final
Google Driverless Car Finalnandini sharma
 
Google self driving car technology
Google self driving car technology Google self driving car technology
Google self driving car technology suraj bhatta
 
Google driver less car
Google driver less carGoogle driver less car
Google driver less carSonam Meshram
 
(The google car) Presentation
(The google car) Presentation(The google car) Presentation
(The google car) PresentationAsif Choudhury
 
Google's Driverless Car
Google's Driverless CarGoogle's Driverless Car
Google's Driverless CarManasa Chowdary
 
Google's Driverless Car Project
Google's Driverless Car ProjectGoogle's Driverless Car Project
Google's Driverless Car ProjectRay Yip
 
Google CAR
Google CARGoogle CAR
Google CARBinoy Binu
 
Report 0515
Report 0515Report 0515
Report 0515Udomsin Srisuchinwong
 
Techtalk. emerging technolgy. driverless car
Techtalk. emerging technolgy. driverless carTechtalk. emerging technolgy. driverless car
Techtalk. emerging technolgy. driverless carPurva Kini
 
Google car
Google carGoogle car
Google carClifford Sugermen
 
Google's Driverless car
Google's Driverless carGoogle's Driverless car
Google's Driverless carSai Teja
 
Google Driverless Cars
Google Driverless CarsGoogle Driverless Cars
Google Driverless CarsSumit .
 
15215334 pss7
15215334 pss715215334 pss7
15215334 pss7vivianwong0501
 
Google driverless car
Google driverless carGoogle driverless car
Google driverless carRavi Jakashania
 
Google SDC disengagements Report annual-15
Google SDC disengagements Report annual-15Google SDC disengagements Report annual-15
Google SDC disengagements Report annual-15Frédéric Lambert
 
Robotic car seminar report
Robotic car seminar reportRobotic car seminar report
Robotic car seminar reportVvs Pradeep
 
Google driverless car
Google driverless carGoogle driverless car
Google driverless carpiyupatel99
 
Google Self Driving Car
Google Self Driving CarGoogle Self Driving Car
Google Self Driving Carfirstmsc
 
Google driverless cars
Google driverless carsGoogle driverless cars
Google driverless carselan_chezhian94
 
Seminar Report 20071127
Seminar Report 20071127Seminar Report 20071127
Seminar Report 20071127tomelf2007
 

More Related Content

What's hot

Final google driverless car (ashok k)
Final google driverless car (ashok k)Final google driverless car (ashok k)
Final google driverless car (ashok k)Ashok Kumbhar
 
Google driverless car technical seminar report (.docx)
Google driverless car technical seminar report (.docx)Google driverless car technical seminar report (.docx)
Google driverless car technical seminar report (.docx)gautham p
 
Google Driverless Car Final
Google Driverless Car FinalGoogle Driverless Car Final
Google Driverless Car Finalnandini sharma
 
Google self driving car technology
Google self driving car technology Google self driving car technology
Google self driving car technology suraj bhatta
 
Google driver less car
Google driver less carGoogle driver less car
Google driver less carSonam Meshram
 
(The google car) Presentation
(The google car) Presentation(The google car) Presentation
(The google car) PresentationAsif Choudhury
 
Google's Driverless Car Project
Google's Driverless Car ProjectGoogle's Driverless Car Project
Google's Driverless Car ProjectRay Yip
 
Techtalk. emerging technolgy. driverless car
Techtalk. emerging technolgy. driverless carTechtalk. emerging technolgy. driverless car
Techtalk. emerging technolgy. driverless carPurva Kini
 
Google's Driverless car
Google's Driverless carGoogle's Driverless car
Google's Driverless carSai Teja
 
Google Driverless Cars
Google Driverless CarsGoogle Driverless Cars
Google Driverless CarsSumit .
 
Google SDC disengagements Report annual-15
Google SDC disengagements Report annual-15Google SDC disengagements Report annual-15
Google SDC disengagements Report annual-15Frédéric Lambert
 
Robotic car seminar report
Robotic car seminar reportRobotic car seminar report
Robotic car seminar reportVvs Pradeep
 
Google driverless car
Google driverless carGoogle driverless car
Google driverless carpiyupatel99
 
Google Self Driving Car
Google Self Driving CarGoogle Self Driving Car
Google Self Driving Carfirstmsc
 

What's hot (20)

Final google driverless car (ashok k)
Final google driverless car (ashok k)Final google driverless car (ashok k)
Final google driverless car (ashok k)
 
Google driverless car technical seminar report (.docx)
Google driverless car technical seminar report (.docx)Google driverless car technical seminar report (.docx)
Google driverless car technical seminar report (.docx)
 
Google Driverless Car Final
Google Driverless Car FinalGoogle Driverless Car Final
Google Driverless Car Final
 
Google self driving car technology
Google self driving car technology Google self driving car technology
Google self driving car technology
 
Google driver less car
Google driver less carGoogle driver less car
Google driver less car
 
(The google car) Presentation
(The google car) Presentation(The google car) Presentation
(The google car) Presentation
 
Google's Driverless Car
Google's Driverless CarGoogle's Driverless Car
Google's Driverless Car
 
Google's Driverless Car Project
Google's Driverless Car ProjectGoogle's Driverless Car Project
Google's Driverless Car Project
 
Google CAR
Google CARGoogle CAR
Google CAR
 
Report 0515
Report 0515Report 0515
Report 0515
 
Techtalk. emerging technolgy. driverless car
Techtalk. emerging technolgy. driverless carTechtalk. emerging technolgy. driverless car
Techtalk. emerging technolgy. driverless car
 
Google car
Google carGoogle car
Google car
 
Google's Driverless car
Google's Driverless carGoogle's Driverless car
Google's Driverless car
 
Google Driverless Cars
Google Driverless CarsGoogle Driverless Cars
Google Driverless Cars
 
15215334 pss7
15215334 pss715215334 pss7
15215334 pss7
 
Google driverless car
Google driverless carGoogle driverless car
Google driverless car
 
Google SDC disengagements Report annual-15
Google SDC disengagements Report annual-15Google SDC disengagements Report annual-15
Google SDC disengagements Report annual-15
 
Robotic car seminar report
Robotic car seminar reportRobotic car seminar report
Robotic car seminar report
 
Google driverless car
Google driverless carGoogle driverless car
Google driverless car
 
Google Self Driving Car
Google Self Driving CarGoogle Self Driving Car
Google Self Driving Car
 

Viewers also liked

Seminar Report 20071127
Seminar Report 20071127Seminar Report 20071127
Seminar Report 20071127tomelf2007
 
Smart quill seminar report final
Smart quill seminar report finalSmart quill seminar report final
Smart quill seminar report finalPramod Kumar
 
Google Driverless Car
Google Driverless CarGoogle Driverless Car
Google Driverless CarRunam Sharma
 

Viewers also liked (9)

Google driverless cars
Google driverless carsGoogle driverless cars
Google driverless cars
 
Seminar Report 20071127
Seminar Report 20071127Seminar Report 20071127
Seminar Report 20071127
 
tile device
tile device tile device
tile device
 
Smart Quill Paras
Smart Quill ParasSmart Quill Paras
Smart Quill Paras
 
Seminar report
Seminar reportSeminar report
Seminar report
 
Project ara report 2
Project ara report 2Project ara report 2
Project ara report 2
 
Smart quill seminar report final
Smart quill seminar report finalSmart quill seminar report final
Smart quill seminar report final
 
Tiles presentation
Tiles presentationTiles presentation
Tiles presentation
 
Google Driverless Car
Google Driverless CarGoogle Driverless Car
Google Driverless Car
 

Similar to Google's driverless car technology

GOOGLE'S AUTONOMUS CAR
GOOGLE'S AUTONOMUS CARGOOGLE'S AUTONOMUS CAR
GOOGLE'S AUTONOMUS CARjolsnaj
 
Autonomous car(driver less car) (self driving car)
Autonomous car(driver less car) (self driving car)Autonomous car(driver less car) (self driving car)
Autonomous car(driver less car) (self driving car)basawanna
 
A seminar report_on_google_driverless_caR
A seminar report_on_google_driverless_caRA seminar report_on_google_driverless_caR
A seminar report_on_google_driverless_caRKaziAfrozAlam
 
A SEMINAR REPORT ON GOOGLE DRIVERLESS CAR
A SEMINAR REPORT ON GOOGLE DRIVERLESS CARA SEMINAR REPORT ON GOOGLE DRIVERLESS CAR
A SEMINAR REPORT ON GOOGLE DRIVERLESS CARWhitney Anderson
 
Google driver less car presentation (ppt) 2017 Hemant pratap singh
Google driver less car presentation (ppt) 2017 Hemant pratap singh Google driver less car presentation (ppt) 2017 Hemant pratap singh
Google driver less car presentation (ppt) 2017 Hemant pratap singh HEMANT PRATAP SINGH
 
Autonomous car ; google car
Autonomous car ; google carAutonomous car ; google car
Autonomous car ; google carsachin kumar
 
Google car (self driving car )
Google car (self driving car )Google car (self driving car )
Google car (self driving car )imrana326
 
An autonomous driverless car
An autonomous driverless carAn autonomous driverless car
An autonomous driverless carAlexander Decker
 
Week 8 Expository Essay 2 Revision 65 pointsContent and De.docx
Week 8 Expository Essay 2 Revision 65 pointsContent and De.docxWeek 8 Expository Essay 2 Revision 65 pointsContent and De.docx
Week 8 Expository Essay 2 Revision 65 pointsContent and De.docxmelbruce90096
 
GOOGLE CAR(autonomous car)
GOOGLE CAR(autonomous car)GOOGLE CAR(autonomous car)
GOOGLE CAR(autonomous car)SACHIN KS
 

Similar to Google's driverless car technology (20)

GOOGLE'S AUTONOMUS CAR
GOOGLE'S AUTONOMUS CARGOOGLE'S AUTONOMUS CAR
GOOGLE'S AUTONOMUS CAR
 
GOOGLE DRIVERLESS CAR
GOOGLE DRIVERLESS CAR GOOGLE DRIVERLESS CAR
GOOGLE DRIVERLESS CAR
 
Autonomous car(driver less car) (self driving car)
Autonomous car(driver less car) (self driving car)Autonomous car(driver less car) (self driving car)
Autonomous car(driver less car) (self driving car)
 
Datacommunication presentation
Datacommunication presentationDatacommunication presentation
Datacommunication presentation
 
Autonomouscar
Autonomouscar Autonomouscar
Autonomouscar
 
DriverlessCars
DriverlessCarsDriverlessCars
DriverlessCars
 
A seminar report_on_google_driverless_caR
A seminar report_on_google_driverless_caRA seminar report_on_google_driverless_caR
A seminar report_on_google_driverless_caR
 
A SEMINAR REPORT ON GOOGLE DRIVERLESS CAR
A SEMINAR REPORT ON GOOGLE DRIVERLESS CARA SEMINAR REPORT ON GOOGLE DRIVERLESS CAR
A SEMINAR REPORT ON GOOGLE DRIVERLESS CAR
 
Google driver less car presentation (ppt) 2017 Hemant pratap singh
Google driver less car presentation (ppt) 2017 Hemant pratap singh Google driver less car presentation (ppt) 2017 Hemant pratap singh
Google driver less car presentation (ppt) 2017 Hemant pratap singh
 
Autonomous car ; google car
Autonomous car ; google carAutonomous car ; google car
Autonomous car ; google car
 
Anshal ppt
Anshal pptAnshal ppt
Anshal ppt
 
Google car (self driving car )
Google car (self driving car )Google car (self driving car )
Google car (self driving car )
 
DRIVER LESS CAR
DRIVER LESS CARDRIVER LESS CAR
DRIVER LESS CAR
 
Autonomous car
Autonomous carAutonomous car
Autonomous car
 
Autonomous Vehicles
Autonomous VehiclesAutonomous Vehicles
Autonomous Vehicles
 
Auto pilot mode/Autonomus car
Auto pilot mode/Autonomus carAuto pilot mode/Autonomus car
Auto pilot mode/Autonomus car
 
An autonomous driverless car
An autonomous driverless carAn autonomous driverless car
An autonomous driverless car
 
Sazz
SazzSazz
Sazz
 
Week 8 Expository Essay 2 Revision 65 pointsContent and De.docx
Week 8 Expository Essay 2 Revision 65 pointsContent and De.docxWeek 8 Expository Essay 2 Revision 65 pointsContent and De.docx
Week 8 Expository Essay 2 Revision 65 pointsContent and De.docx
 
GOOGLE CAR(autonomous car)
GOOGLE CAR(autonomous car)GOOGLE CAR(autonomous car)
GOOGLE CAR(autonomous car)
 

Recently uploaded

Manual 508 Accessibility Compliance Audit
Manual 508 Accessibility Compliance AuditManual 508 Accessibility Compliance Audit
Manual 508 Accessibility Compliance AuditSkynet Technologies
 
Time Series Foundation Models - current state and future directions
Time Series Foundation Models - current state and future directionsTime Series Foundation Models - current state and future directions
Time Series Foundation Models - current state and future directionsNathaniel Shimoni
 
(How to Program) Paul Deitel, Harvey Deitel-Java How to Program, Early Object...
(How to Program) Paul Deitel, Harvey Deitel-Java How to Program, Early Object...(How to Program) Paul Deitel, Harvey Deitel-Java How to Program, Early Object...
(How to Program) Paul Deitel, Harvey Deitel-Java How to Program, Early Object...AliaaTarek5
 
Take control of your SAP testing with UiPath Test Suite
Take control of your SAP testing with UiPath Test SuiteTake control of your SAP testing with UiPath Test Suite
Take control of your SAP testing with UiPath Test SuiteDianaGray10
 
Emixa Mendix Meetup 11 April 2024 about Mendix Native development
Emixa Mendix Meetup 11 April 2024 about Mendix Native developmentEmixa Mendix Meetup 11 April 2024 about Mendix Native development
Emixa Mendix Meetup 11 April 2024 about Mendix Native developmentPim van der Noll
 
Modern Roaming for Notes and Nomad – Cheaper Faster Better Stronger
Modern Roaming for Notes and Nomad – Cheaper Faster Better StrongerModern Roaming for Notes and Nomad – Cheaper Faster Better Stronger
Modern Roaming for Notes and Nomad – Cheaper Faster Better Strongerpanagenda
 
The State of Passkeys with FIDO Alliance.pptx
The State of Passkeys with FIDO Alliance.pptxThe State of Passkeys with FIDO Alliance.pptx
The State of Passkeys with FIDO Alliance.pptxLoriGlavin3
 
Generative Artificial Intelligence: How generative AI works.pdf
Generative Artificial Intelligence: How generative AI works.pdfGenerative Artificial Intelligence: How generative AI works.pdf
Generative Artificial Intelligence: How generative AI works.pdfIngrid Airi González
 
Decarbonising Buildings: Making a net-zero built environment a reality
Decarbonising Buildings: Making a net-zero built environment a realityDecarbonising Buildings: Making a net-zero built environment a reality
Decarbonising Buildings: Making a net-zero built environment a realityIES VE
 
Passkey Providers and Enabling Portability: FIDO Paris Seminar.pptx
Passkey Providers and Enabling Portability: FIDO Paris Seminar.pptxPasskey Providers and Enabling Portability: FIDO Paris Seminar.pptx
Passkey Providers and Enabling Portability: FIDO Paris Seminar.pptxLoriGlavin3
 
The Ultimate Guide to Choosing WordPress Pros and Cons
The Ultimate Guide to Choosing WordPress Pros and ConsThe Ultimate Guide to Choosing WordPress Pros and Cons
The Ultimate Guide to Choosing WordPress Pros and ConsPixlogix Infotech
 
Sample pptx for embedding into website for demo
Sample pptx for embedding into website for demoSample pptx for embedding into website for demo
Sample pptx for embedding into website for demoHarshalMandlekar2
 
TeamStation AI System Report LATAM IT Salaries 2024
TeamStation AI System Report LATAM IT Salaries 2024TeamStation AI System Report LATAM IT Salaries 2024
TeamStation AI System Report LATAM IT Salaries 2024Lonnie McRorey
 
What is DBT - The Ultimate Data Build Tool.pdf
What is DBT - The Ultimate Data Build Tool.pdfWhat is DBT - The Ultimate Data Build Tool.pdf
What is DBT - The Ultimate Data Build Tool.pdfMounikaPolabathina
 
A Journey Into the Emotions of Software Developers
A Journey Into the Emotions of Software DevelopersA Journey Into the Emotions of Software Developers
A Journey Into the Emotions of Software DevelopersNicole Novielli
 
UiPath Community: Communication Mining from Zero to Hero
UiPath Community: Communication Mining from Zero to HeroUiPath Community: Communication Mining from Zero to Hero
UiPath Community: Communication Mining from Zero to HeroUiPathCommunity
 
Enhancing User Experience - Exploring the Latest Features of Tallyman Axis Lo...
Enhancing User Experience - Exploring the Latest Features of Tallyman Axis Lo...Enhancing User Experience - Exploring the Latest Features of Tallyman Axis Lo...
Enhancing User Experience - Exploring the Latest Features of Tallyman Axis Lo...Scott Andery
 
Moving Beyond Passwords: FIDO Paris Seminar.pdf
Moving Beyond Passwords: FIDO Paris Seminar.pdfMoving Beyond Passwords: FIDO Paris Seminar.pdf
Moving Beyond Passwords: FIDO Paris Seminar.pdfLoriGlavin3
 
Testing tools and AI - ideas what to try with some tool examples
Testing tools and AI - ideas what to try with some tool examplesTesting tools and AI - ideas what to try with some tool examples
Testing tools and AI - ideas what to try with some tool examplesKari Kakkonen
 
The Future Roadmap for the Composable Data Stack - Wes McKinney - Data Counci...
The Future Roadmap for the Composable Data Stack - Wes McKinney - Data Counci...The Future Roadmap for the Composable Data Stack - Wes McKinney - Data Counci...
The Future Roadmap for the Composable Data Stack - Wes McKinney - Data Counci...Wes McKinney
 

Recently uploaded (20)

Manual 508 Accessibility Compliance Audit
Manual 508 Accessibility Compliance AuditManual 508 Accessibility Compliance Audit
Manual 508 Accessibility Compliance Audit
 
Time Series Foundation Models - current state and future directions
Time Series Foundation Models - current state and future directionsTime Series Foundation Models - current state and future directions
Time Series Foundation Models - current state and future directions
 
(How to Program) Paul Deitel, Harvey Deitel-Java How to Program, Early Object...
(How to Program) Paul Deitel, Harvey Deitel-Java How to Program, Early Object...(How to Program) Paul Deitel, Harvey Deitel-Java How to Program, Early Object...
(How to Program) Paul Deitel, Harvey Deitel-Java How to Program, Early Object...
 
Take control of your SAP testing with UiPath Test Suite
Take control of your SAP testing with UiPath Test SuiteTake control of your SAP testing with UiPath Test Suite
Take control of your SAP testing with UiPath Test Suite
 
Emixa Mendix Meetup 11 April 2024 about Mendix Native development
Emixa Mendix Meetup 11 April 2024 about Mendix Native developmentEmixa Mendix Meetup 11 April 2024 about Mendix Native development
Emixa Mendix Meetup 11 April 2024 about Mendix Native development
 
Modern Roaming for Notes and Nomad – Cheaper Faster Better Stronger
Modern Roaming for Notes and Nomad – Cheaper Faster Better StrongerModern Roaming for Notes and Nomad – Cheaper Faster Better Stronger
Modern Roaming for Notes and Nomad – Cheaper Faster Better Stronger
 
The State of Passkeys with FIDO Alliance.pptx
The State of Passkeys with FIDO Alliance.pptxThe State of Passkeys with FIDO Alliance.pptx
The State of Passkeys with FIDO Alliance.pptx
 
Generative Artificial Intelligence: How generative AI works.pdf
Generative Artificial Intelligence: How generative AI works.pdfGenerative Artificial Intelligence: How generative AI works.pdf
Generative Artificial Intelligence: How generative AI works.pdf
 
Decarbonising Buildings: Making a net-zero built environment a reality
Decarbonising Buildings: Making a net-zero built environment a realityDecarbonising Buildings: Making a net-zero built environment a reality
Decarbonising Buildings: Making a net-zero built environment a reality
 
Passkey Providers and Enabling Portability: FIDO Paris Seminar.pptx
Passkey Providers and Enabling Portability: FIDO Paris Seminar.pptxPasskey Providers and Enabling Portability: FIDO Paris Seminar.pptx
Passkey Providers and Enabling Portability: FIDO Paris Seminar.pptx
 
The Ultimate Guide to Choosing WordPress Pros and Cons
The Ultimate Guide to Choosing WordPress Pros and ConsThe Ultimate Guide to Choosing WordPress Pros and Cons
The Ultimate Guide to Choosing WordPress Pros and Cons
 
Sample pptx for embedding into website for demo
Sample pptx for embedding into website for demoSample pptx for embedding into website for demo
Sample pptx for embedding into website for demo
 
TeamStation AI System Report LATAM IT Salaries 2024
TeamStation AI System Report LATAM IT Salaries 2024TeamStation AI System Report LATAM IT Salaries 2024
TeamStation AI System Report LATAM IT Salaries 2024
 
What is DBT - The Ultimate Data Build Tool.pdf
What is DBT - The Ultimate Data Build Tool.pdfWhat is DBT - The Ultimate Data Build Tool.pdf
What is DBT - The Ultimate Data Build Tool.pdf
 
A Journey Into the Emotions of Software Developers
A Journey Into the Emotions of Software DevelopersA Journey Into the Emotions of Software Developers
A Journey Into the Emotions of Software Developers
 
UiPath Community: Communication Mining from Zero to Hero
UiPath Community: Communication Mining from Zero to HeroUiPath Community: Communication Mining from Zero to Hero
UiPath Community: Communication Mining from Zero to Hero
 
Enhancing User Experience - Exploring the Latest Features of Tallyman Axis Lo...
Enhancing User Experience - Exploring the Latest Features of Tallyman Axis Lo...Enhancing User Experience - Exploring the Latest Features of Tallyman Axis Lo...
Enhancing User Experience - Exploring the Latest Features of Tallyman Axis Lo...
 
Moving Beyond Passwords: FIDO Paris Seminar.pdf
Moving Beyond Passwords: FIDO Paris Seminar.pdfMoving Beyond Passwords: FIDO Paris Seminar.pdf
Moving Beyond Passwords: FIDO Paris Seminar.pdf
 
Testing tools and AI - ideas what to try with some tool examples
Testing tools and AI - ideas what to try with some tool examplesTesting tools and AI - ideas what to try with some tool examples
Testing tools and AI - ideas what to try with some tool examples
 
The Future Roadmap for the Composable Data Stack - Wes McKinney - Data Counci...
The Future Roadmap for the Composable Data Stack - Wes McKinney - Data Counci...The Future Roadmap for the Composable Data Stack - Wes McKinney - Data Counci...
The Future Roadmap for the Composable Data Stack - Wes McKinney - Data Counci...
 

Google's driverless car technology

  • 1. Wireless sensor Networks GOOGLE Driverless Car Harshdeep kaur S.c.d Govt college harshdeep1641991@gmail.com
  • 2. Google driverless car Harshdeep kaur S.c.d govt college Ludhiana harshdeep1641991@gmail.com Abstract objective:- Driver error is the most common cause of traffic accidents India contributes 6 % of the world's road accident deaths.India contributes 6 % of the world's road accident deaths Cell phones in-car, entertainment systems, more traffic and more complicated road systems making it more frequent by this improving technology our car will do the concentrating for us. it will be the engine pulling the industry forward. Consumers are eager for new mobility alternatives that would allow them to stay connected and recapture the time and psychic energy they squander in traffic jams and defensive driving Scope: - It can steer itself while looking out for obstacles. It can accelerate itself to the correct speed limit. It can stop and go itself based on any traffic condition. Reduction in car accidents by automated collision avoidance system. it can also avoid human errors. It is fuel efficient and also safe for highways. Components:- Google Maps, Hardware Sensors, LIDAR ,Video Camere,Position Estimator, Distance Sensor, Automotive Night Vision, Artificial Intelligence Conclusion:- the reliability efficiency and cost effectiveness of autonomous vehicle depend mainly on how judiciously its navigation sensors , perception unit and computer control unit is in corporate. The driver’s activity is influenced by several factors that depend on driver itself and is environment such as traffic density, traffic status, time of travel and weather. Thus the driving activity deals with a combined driver vehicle-environment system. The vehicle is required to blend its environmental perception capabilities with its intelligent controls in order to affect optimal path-planning strategies and minimize criteria such as time of travel, fuel consumption, exposure to danger etc. however basic driving functions consists of lane-keeping, safe distance maintenance, timely lane changing anthese driving tasks is collision avoidance.
  • 3. Introduction In the 21 century. so many operates operate automatically which start from food factories to food factories machines to aeroplane which fly’s on autopilot without the need of human pilots then come missals and satellite which are programmed and manuring is done automatically to reach the destination there are some metro train also which run on the command of autonomous software now the new things has come which was suppose to be looking impossible .that is moving a vehicle on crowed roads but these has been made possible by Google From the invention of the car there is a great relation between human and car. Because by the invention of the car the automobile industry was established, by this car the travelling time from one place to another place is reduced. The car brings royalty from the invention. As cars are coming on roads at that time there are so many accidents are occurring due to lack of driving knowledge & drink driving and soon, In that view only the Google took a great project, i.e. Google Driverless Car in these the Google puts the technology . The input video camera was fixed beside the front mirror inside the car, A LIDAR sensor was fixed on the top of the vehicle, RADAR sensor on the front of the vehicle and a position sensor attached to one of the rear wheels that helps locate the cars position on the map, The Computer, Router, Switch, Fan, Inverter, rear Monitor, Topcon, Velodyne, Applanix and Battery are kept inside the car. These all components are connected to computer’s CPU and the monitor is fixed on beside of the driver seat, these we can observe in that monitor and can operate all the operations. The system combines information gathered from Google street view with artificial intelligence software that combines input from video camera inside the car, a LIDAR sensor on the top of the vehicle, RADAR sensors on the front of the vehicle and a position sensor attached to one of the rear wheel that helps to locate the car position on the map. At the same time some hardware components are used in the car these are APPIANIX PCS, VELODYNE, SWITCH,TOPCON, REAR MONITOR, COMPUTER, ROUTER, FAN, INVERTER and BATTERY along with some software program is installed in it. By all the components combined together to operate the car without the DRIVER. i.e., the car drives itself only Google hopes to have fully autonomous vehicles on the road by 2020, taking the driver completely out of the equation and handing the virtual wheel to its sophisticated combination of software and sensors, which continue to improve and evolve, “transform people’s lives through mobility,” citing cases of blind and older drivers who would suddenly have more freedom. Google's robotic cars have about $150,000 in equipment including a $70,000 LIDAR system. The range finder mounted on the top is a Velodyne 64-beam laser. This laser allows the vehicle to generate a detailed 3D map of its environment. The car then takes these generated maps and combines them with high- resolution maps of the world, producing different types of data models that allow it to drive itself.
  • 4. HISTORY The Sebastian Thrun was invented the Google driverless car. He was director of the Stanford Artificial Intelligence laboratory. Sebastian friends were killed in car accident, so that he decided there should not be any accidents on the road by car. By that decision only the Google Driverless car was invented. ”Our goal is to help prevent traffic accidents, free up people’s time and reduce carbon emission by fundamentally changing car use”-Sebastian Thrun The Google Driverless car was tested in the year 2010; Google has tested several vehicles equipped with the system, driving 1,609 kilometers (1,000 mi) without any human intervention, in addition to 225,308 kilometers (140,000 mi) with occasional human intervention. Google expects that the increased accuracy of its automated driving system could help reduce the number of traffic-related injuries and deaths, while using energy and space on roadways more efficiently. It was introduced in oct-2010 and it becomes legal in Nevada at June 2011, August 2012- Accident. The project team has equipped a test fleet of at least eight vehicles, consisting of six Toyota Prius, an Audi TT, and a Lexus RX450h, each accompanied in the driver's seat by one of a dozen drivers with unblemished driving records and in the passenger seat by one of Google's engineers. The car has traversed San Francisco's Lombard Street, famed for its steep hairpin turns and through city traffic. The vehicles have driven over the Golden Gate Bridge and on the Pacific Coast Highway, and have circled Lake Tahoe. The system drives at the speed limit it has stored on its maps and maintains its distance from other vehicles using its system of sensors. The system provides an override that allows a human driver to take control of the car by stepping on the brake or turning the wheel, similar to cruise control systems already in cars. Components Google Map: Google Maps is a Google service offering powerful, user-friendly mapping technology and local business information-including business locations, contact information, and driving directions.
  • 5. Google Street View: Google Street View (GSV) has rapidly expanded to provide street-level images of entire cities all around the world. The number and density of geo-positioned images available make this service truly unprecedented. A Street View user can wander through city streets, enabling a wide range of uses such as scouting a neighborhood, or finding specific items such as bike racks or mail boxes. LIDAR Sensor: Light Detection and Ranging is an optical remote sensing technology that can measure the distance to, or other properties of a target by illuminating the target with light, often using pulses from a laser. LIDAR uses ultraviolet, visible, or near infrared light to image objects and can be used with a wide range of targets, including non-metallic objects, rocks, rain, chemical compounds, aerosols, clouds and even single molecules. A narrow laser beam can be used to map physical features with very high resolution. The LIDAR (Light detection and Ranging) sensor is a scanner. It will rotate in the circle. It is fixed on the top of the car. In the scanner contains the 64 lasers that are send surroundings of the car through the air. These the laser is hits objects around the car and again comes back to it. By these known How far that objects are from the car and also it calculates the time to reach that object. These are can see in monitor in a 3D object with the map. The monitor is fixed in front seat. “The heart of the system generates a detailed 3D map of environment (velodyne 64- beam laser). The map accessed from the GPRS connection.
  • 6. Radar sensor: The three RADAR sensors were fixed in front of the bumper and one in the rear bumper. These will measures the distance to various obstacles and allow the system to reduce the speed of the car. The back side of sensor will locates the position of the car on the map. Radar (Radio Detection And Ranging) is an object- detection system which uses radio waves to determine the range, altitude, direction, or speed of objects. It can be used to detect aircraft, ships, spacecraft, guided missiles, motor vehicles, weather formations, and terrain. The radar dish or antenna transmits pulses of radio waves or microwaves which bounce off any object in their path. The object returns a tiny part of the wave’s energy to a dish or antenna which is usually located at the same site as the transmitter. For example, when the car was travelling on the road then RADAR sensor was projected on road from front and back side of the car. Position Sensor: This device provides the latitude, longitude and altitude together with the corresponding standard deviation and the standard NMEA messages with a frequency of 5 Hz. When geostationary satellites providing the GPS drift correction are visible from the car, the unit enters the differential GPS mode (high precision GPS). When no correction signal is available, the device outputs standard precision GPS. This sensor is mounted on left rear wheel measure lateral movement and determines cars position on map Video camera: The video camera was fixed near the rear view mirror. That will detect traffic lights and any moving objects front of the car. For example if any vehicle or traffic detected then the car will be slow down automatically, these all will be done by the artificial intelligence software only. Position estimator: A sensor mounted on the left rear wheel. By these sensor only measures small movements made by the car and helps to accurately locate its position on the map. The position of the car can be seen on the monitor performing much the same function as amildy interested human motorist the camera reads road signs, detect traffics lights, and keep out for pedestrians , cyclist , other motorist and similar obstacles
  • 7. Computer: information from various sensors is fed into the car’s central computer. here the data is analysed and steering acieration and brakes adjusted accordingly. Importantly , the computer needs yo understand not only the traffic laws but also the unspoken assumption of road users Automative night vision: automotive night vision comes in two flavors near and far infrared .the near infrared technology detects the portion of the ir band nearest to visible light. Special bulbs mounted next to the headlights are aimed straight ahead like a car’s high beam, the NIR system is illuminate the surroundings with infrared light in the wavelength of 800 to 900 nm. How the car work’s Google’s driverless car tech uses an array of detection technologies including sonar devices, stereo cameras, lasers, and radar. All these components have different ranges and fields of view, but each serves a particular purpose according to the patent filings Google has made on its driverless cars. Anyone who has ever seen an image of Google’s self-driving Prius has probably noticed one of these systems poking up above the vehicle — the LIDAR laser remote sensing system. According to Google engineers, this is at the heart of object detection The LIDAR system bolted to the top of Google’s self-driving car is crucially important for several reasons. First, it’s highly accurate up to a range of 100 meters. There are a few detection technologies on the car that work at greater distances, but not with the kind of accuracy you get from a laser. It simply bounces a beam off surfaces and measures the reflection to determine distance. The device used by Google — a Velodyne 64-beam laser — can also rotate 360-degrees and take up to 1.3 million readings per second, making it the most versatile sensor on the car. Mounting it on top of the car ensures its view isn’t obstructed. Google mounts regular cameras around the exterior of the car in pairs with a small separation between them. The overlapping fields of view create a parallax not unlike your own eyes that allow the system to track an object’s distance in real time. As long as it has been spotted by more than one camera, the car knows where it is. These stereo cameras have a 50-degree field of view, but they’re only accurate up to about 30 meters. Google’s LIDAR system is great for generating an accurate map of the car’s surroundings, but it’s not ideal for monitoring the speed of other cars in real time. That’s why the front and back bumper of the driverless car includes radar. This is one of the few technologies Google employs in its driverless car that you can already get in mainstream vehicles. Conventional vehicles use radar to warn you of an impending impact or even apply the brakes to prevent one, but the Google car uses radar to adjust the throttle and brakes continuously. It’s essentially adaptive cruise control that always takes into account the movement of cars around you. The radar system is probably paired with sonar in at least some of Google’s test cars. While radar works up to 200 meters away, sonar is only good for 6 meters. They both have a narrow field of view, so the car knows things are about to get messy if another vehicle crosses the radar and sonar beams. This signal could be used to swerve, apply the brakes, or pre-tension the seatbelts.
  • 8. Google’s software integrates all the data from these remote sensing systems (as much as 1GB per second) to build a map of the car’s position. Other cars are rendered as rough blocks with shifting, amorphous edges. It doesn’t have to be perfect — it’s not like the Google car needs to get close enough to test the accuracy of the borders. GPS is only accurate to within a few meters, so it’s remarkable the car can even stay in the right lane, let alone avoid collisions. Testing The project team has equipped a test group of at least ten cars, including six Toyota Prius, an Audi TT, and three Lexus RX450h, each accompanied in the driver's seat by one of a dozen drivers with unblemished driving records and in the passenger seat by one of Google's engineers. The car has traversed San Francisco's Lombard Street, famed for its steep hairpin turns, and through city traffic. The vehicles have driven over the Golden Gate Bridge and around Lake Tahoe. The system drives at the speed limit it has stored on its maps and maintains its distance from other vehicles using its system of sensors. The system provides an override that allows a human driver to take control of the car by stepping on the brake or turning the wheel, similar to cruise control systems already found in many cars today. On March 28, 2012, Google posted a YouTube video showing Steve Mahan, a resident of Morgan Hill, California, being taken on a ride in Google's self-driving Toyota Prius. In the video, Mahan states "Ninety- five percent of my vision is gone, I'm well past legally blind". In the description of the YouTube video, it is noted that the carefully programmed route takes him from his home to a drive-through restaurant, then to the dry cleaning shop, and finally back home. In August 2012, the team announced that they have completed over 300,000 autonomous-driving miles (500,000 km) accident-free, typically have about a dozen cars on the road at any given time, and are starting to test them with single drivers instead of in pairs. Four U.S. states have passed laws permitting autonomous cars as of December 2013: Nevada, Florida, California, and Michigan. A law proposed in Texas would establish criteria for allowing "autonomous motor vehicles". In April 2014, the team announced that their vehicles have now logged nearly 700,000 autonomous miles (1.1 million km). In late May, Google revealed a new prototype of its driverless car, which had no steering wheel, gas pedal, or brake pedal, being 100% autonomous.
  • 9. Vehicle communication system Individual vehicles may benefit from information obtained from other vehicles in the vicinity, especially information relating to traffic congestion and safety hazards. Vehicular communication systems use vehicles and roadside units as the communicating nodes in a peer-to-peer network, providing each other with information. As a cooperative approach, vehicular communication systems can allow all cooperating vehicles to be more effective. According to a 2010 study by the National Highway Traffic Safety Administration, vehicular communication systems could help avoid up to 81 percent of all traffic accidents.[ In 2012, computer scientists at the University of Texas in Austin began developing smart intersections designed for autonomous cars. The intersections will have no traffic lights and no stop signs, instead using computer programs that will communicate directly with each car on the road. Through the implementation of Global Positioning System (GPS), navigation of the autonomous vehicles is simplified. The location of the vehicle can also be acquired by the longitude and latitude obtained by the Google Inside the car:‘The car will pick you up, take you where you want to go and then can go off and do errands like pick up your dry-cleaning, freeing you to do other things, you step inside and sink into soft Hermes orange leather seats. It is surprisingly spacious, uncluttered by the normal ‘car’ things like pedals, a steering wheel and handbrake. Instead there are two buttons – green for Go and red for Stop. There is an oblong flat screen in front of you which shows the time, date, temperature and a computer- generated image of the road ahead. Beneath the high-tech screen is a storage bay for luggage. Hit the Go button and take off. The electric engine purrs into life, taking me to a top speed of 25mph. Security Concerns The widespread implementation of driverless cars, as safe as they are designed to be, indeed has some chance in posing as a threat to a passenger. Buyers will essentially have to make a personal decision as to which is safer: the machine’s calculated decision versus a human’s natural intuition z At times, airplanes and traffic control systems fail due to such technological anomalies. The buyer must then weigh the benefits with such a concern. What makes the driverless car vulnerable to this risk?
  • 10. ADVANTAGES 1) Self-driving cars would save lives: This is the most obvious one. In the United States from automobile crashes . And roughly 40 percent of fatal accidents are caused by alcohol, distraction, drugs, or fatigue, all of which go away once you take human off the wheel. Letting robots take the wheel would save lives. 2) Commutes would become quicker and less stressful: Research shows that long commutes increase the risk of obesity, divorce, stress, sleeplessness, and neck pain 3) Driverless cars will be more fuel-efficient:. What's more, cars would no longer need to be so big and hulking — since their users don't need to fear crashing as much. That all boosts fuel efficiency. 4) Driverless cars will waste less fuel on things like looking for parking. study found that in congested urban areas, drivers waste an absurd amount of gasoline circling the blocks looking for parking. Intelligent self-driving cars could presumably improve on this — particularly if they could communicate with each other. 5) More and more people will be able to drive. There are plenty of people who are not allowed to drive right now. Everyone under 16 . The elderly . The disabled . People who are intoxicated or on medication. People who are sleeping. All of those people would now be able to get around in driverless cars. 6) Driverless cars could make car-sharing more popular. we spend a lot of money for cars that sit in the parking lot most of the time. In theory, self-driving cars could be used more productively — say, through car-sharing services. That might mean fewer cars overall. 8) Self-driving cars could make the transition to electric vehicles easier. As Google consultant Brad Templeton self-driving cars will allow car manufacturers to radically change their designs. And that could have big implications for electric vehicles. DISADVANTAGE 1) Safety and regulatory concerns. This is one of the big hurdles self-driving cars will have to surmount before catching on — since self-driving cars will likely have to meet more rigorous standards than regular cars. "The first accident that's caused by a computer malfunction will freak everyone out far beyond the thousands of car accidents caused by humans,". WHO IS LIABLE IF A SELF-DRIVING CAR CRASHES? THE MANUFACTURER? THE PASSENGER? 2) Legal challenges. Even if self-driving vehicles are safer, they'll likely never be crash-free. What happens if a pedestrian suddenly jumps out in front of a car? Who would be at fault if the self-driving vehicle hits something or someone? The manufacture ? The person sitting in the car ?
  • 11. 3) Big disruptions in the labor market. In theory, many of those jobs could be replaced by self-driving cars, which would create plenty of dislocation and hardship (as well as possible opposition to the technology). 4) More driving overall and higher energy use. Yes, self-driving cars could be more fuel efficient. But it's also entirely possible that people will end up driving them more, especially if it's cheaper and more convenient. The end result could conceivably be an increase in fuel use or planet-warming greenhouse-gas emissions. (The technical term for this is the "rebound effect.") 5) Suburban sprawl could expand. Right now, there's a serious limit to how sprawled-out a city can get — as a rule, people tend to prefer to keep their commutes under an hour. But if self-driving cars can offer quick, efficient transportation, then we could see more people spread out to the suburbs. It's not clear if this is a problem, but it could be one unexpected side effect. 6) Privacy issues. There are lots of possible issues here. Many of the benefits from self-driving cars come from the vehicles being able to communicate and share data with each other. Likewise, crash data will almost certainly be stored for use by manufacturers and to sort out liability But how much data will be stored? And how will it be shared? In Conclusion In conclusion, upon addressing the mechanics of the driverless car as well as its benefits and potential issues, it is quite interesting to see how the world will actually become by the year 2040. Is IEEE correct? Will the rite of passage of attaining one’s driver license cease to exist? It is truly in the reader’s discretion to determine and weigh the impacts that the driverless car will have on society in the future. Until then, it is fascinating to see the effects this creation will have on the states in which it is legalized as well as on the people that have chosen to experiment with it. Work cited www.google.com www.slideshare.com www.vox.com www.theneweconomy.com en.wikipedia.org sites.google.com