LaneQuest: An accurate and energy-efficient lane detection system

Aly, H. H.; Basalamah, Anas; Youssef, Moustafa

doi:10.1109/percom.2015.7146523

Cited by 46 publications

(20 citation statements)

References 30 publications

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“…In this case, car detection must be enabled only when the user is driving on the rightmost lane. While at the moment ParkMaster assumes the user is always doing so, we believe vision-based [40] or sensors-based [6,7,10,15,43] solutions for lane detection can be easily integrated with ParkMaster to trigger the detection only when the user is driving on the right lane.…”

Section: Heuristicsmentioning

confidence: 99%

Parkmaster

Grassi

Jamieson

Bahl

et al. 2017

Proceedings of the Second ACM/IEEE Symposium on Edge Computing

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We present the design and implementation of ParkMaster, a system that leverages the ubiquitous smartphone to help drivers find parking spaces in the urban environment. ParkMaster estimates parking space availability using video gleaned from drivers' dash-mounted smartphones on the network's edge, uploading analytics about the street to the cloud in real time as participants drive. Novel lightweight parked-car localization algorithms enable the system to estimate each parked car's approximate location by fusing information from phone's camera, GPS, and inertial sensors, tracking and counting parked cars as they move through the driving car's camera frame of view. To visually calibrate the system, ParkMaster relies only on the size of well-known objects in the urban environment for on-the-go calibration. We implement and deploy ParkMaster on Android smartphones, uploading parking analytics to the Azure cloud. On-the-road experiments in three different environments comprising Los Angeles, Paris and an Italian village measure the end-to-end accuracy of the system's parking estimates (close to 90%) as well as the amount of cellular data usage the system requires (less than one megabyte per hour). Drill-down microbenchmarks then analyze the factors contributing to this end-to-end performance, as video resolution, vision algorithm parameters, and CPU resources. CCS CONCEPTS • Information systems-> Mobile information processing systems; • Human-centered computing-> Ubiquitous and mobile computing systems and tools;

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Section: Heuristicsmentioning

confidence: 99%

Parkmaster

Grassi

Jamieson

Bahl

et al. 2017

Proceedings of the Second ACM/IEEE Symposium on Edge Computing

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“…To estimate σ h , we use the ground-truth data. Note that, unlike the input positioning data which has highly dynamic and variable accuracy, the sensors heading accuracy has a more consistent accuracy outdoors [4]. Hence, we use a fixed σ h calculated based on the Median Absolute Deviation (MAD) of the direction changes in our ground truth data, which is a robust estimator of σ h [4,28]:…”

Section: Transition Probability Distribution (B)mentioning

confidence: 99%

semMatch

Aly

Youssef

2015

Proceedings of the 23rd SIGSPATIAL International Conference on Advances in Geographic Information Systems

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“…CARLOC's use of vehicle sensors and crowd-sourced landmarks, together with advanced map matching, gives it an order of magnitude higher accuracy than the prior work. LaneQuest [2] uses probabilistic methods to estimate which lane a car is driving on, a qualitatively different problem than ours. LaneQuest, however, uses crowd-sourced anchors, but, unlike CARLOC, cannot leverage vehicle sensors to detect these.…”

Section: Related Workmentioning

confidence: 99%

Carloc

Jiang

Qiu

McCartney

et al. 2015

Proceedings of the 13th ACM Conference on Embedded Networked Sensor Systems

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Precise positioning of an automobile to within lane-level precision can enable better navigation and context-awareness. However, GPS by itself cannot provide such precision in obstructed urban environments. In this paper, we present a system called CARLOC for lanelevel positioning of automobiles. CARLOC uses three key ideas in concert to improve positioning accuracy: it uses digital maps to match the vehicle to known road segments; it uses vehicular sensors to obtain odometry and bearing information; and it uses crowd-sourced location estimates of roadway landmarks that can be detected by sensors available in modern vehicles. CARLOC unifies these ideas in a probabilistic position estimation framework, widely used in robotics, called the sequential Monte Carlo method. Through extensive experiments on a real vehicle, we show that CARLOC achieves sub-meter positioning accuracy in an obstructed urban setting, an order-of-magnitude improvement over a high-end GPS device.

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LaneQuest: An accurate and energy-efficient lane detection system

Cited by 46 publications

References 30 publications

Parkmaster

Parkmaster

semMatch

Carloc

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