Your search keyword '"Ravi Bhandari"' showing total 5 results

1. enVolve: Are You Listening? Inertial Sensing to Monitor the Involvement of Silent Listeners during an Online Interaction

Author

Garvit Chugh, Suchetana Chakraborty, Ravi Bhandari, and Sandip Chakraborty

Published

2022

2. RoadCare

Author

Ravi Bhandari, Saurabh Tiwari, and Bhaskaran Raman

Subjects

Warning system, business.industry, Computer science, media_common.quotation_subject, Deep learning, 010401 analytical chemistry, 010501 environmental sciences, 01 natural sciences, 0104 chemical sciences, Transport engineering, ComputerSystemsOrganization_MISCELLANEOUS, Road surface, Global Positioning System, Unsupervised learning, Quality (business), Artificial intelligence, Cluster analysis, business, Scale (map), 0105 earth and related environmental sciences, media_common

Abstract

Roads form a critical part of any region's infrastructure. Their constant monitoring and maintenance is thus essential. Traditional monitoring mechanisms are heavy-weight, and hence have insufficient coverage. In this paper, we explore the use of crowd-sourced intelligent measurements from commuters' smart-phone sensors. Specifically, we propose a deep-learning based approach to road surface quality monitoring, using accelerometer and GPS sensor readings. Through extensive data collection of over 36 hours on different kinds of roads, and subsequent evaluation based on this, we show that the approach can achieve high accuracy (98.5%) in a three-way classification of road surface quality. We also show how the classification can be extended to a finer grained 11-point scale of road quality. The model is also efficient: it can be implemented on today's smart-phones, thus making it practical. Our approach, called RoadCare, enables several useful smart-city applications such as spatio-temporal monitoring of the city's roads, early warning of bad road conditions, as well as choosing the "smoothest" road route to a destination.

Published

2020

3. DeepLane

Author

Akshay Uttama Nambi, Bhaskaran Raman, Venkata N. Padmanabhan, and Ravi Bhandari

Subjects

050210 logistics & transportation, business.industry, Computer science, Speed limit, Deep learning, 05 social sciences, Real-time computing, ComputerApplications_COMPUTERSINOTHERSYSTEMS, ComputerSystemsOrganization_PROCESSORARCHITECTURES, Tracking (particle physics), 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Inertial measurement unit, Position (vector), Assisted GPS, 0502 economics and business, Global Positioning System, Lane detection, Artificial intelligence, business

Abstract

Current smartphone-based navigation applications fail to provide lane-level information due to poor GPS accuracy. Detecting and tracking a vehicle's lane position on the road assists in lane-level navigation. For instance, it would be important to know whether a vehicle is in the correct lane for safely making a turn, perhaps even alerting the driver in advance if it is not, or whether the vehicle's speed is compliant with a lane-specific speed limit. Recent efforts have used road network information and inertial sensors to estimate lane position. While inertial sensors can detect lane shifts over short windows, it would suffer from error accumulation over time. In this paper we present DeepLane, a system that leverages the back camera of a windshield-mounted smartphone to provide an accurate estimate of the vehicle's current lane. We employ a deep learning based technique to classify the vehicle's lane position. DeepLane does not depend on any infrastructure support such as lane markings and works even when there are no lane markings, a characteristic of many roads in developing regions.We perform extensive evaluation of DeepLane on real world datasets collected in developed and developing regions. DeepLane can detect vehicle's lane position with an accuracy of over 90% in both day and night conditions. We have implemented DeepLane as an Android-app that runs at 5 fps on CPU and upto 15 fps on smart-phone's GPU and can also assist existing navigation applications with lane-level information.

Published

2018

4. HAMS

Author

Akshay Uttama Nambi, Venkata N. Padmanabhan, Ravi Bhandari, Harshvardhan Kalra, Ishit Mehta, Aditya Virmani, Shruthi Bannur, and Bhaskaran Raman

Subjects

Computer science, 010401 analytical chemistry, 05 social sciences, Real-time computing, Mobile computing, 050301 education, Ranging, 01 natural sciences, 0104 chemical sciences, law.invention, law, Distraction, Lane detection, Android (operating system), Installed base, Radar, 0503 education

Abstract

Road safety is a major public health issue the world over. Many studies have found that the primary factors responsible for road accidents center on the driver and her/his driving. Hence, there is the need to monitor driver's state and her/his driving, with a view to providing effective feedback. Our proposed demo is of HAMS, a windshield-mounted, smartphone-based system that uses the front camera to monitor the driver and back camera to monitor her/his driving behaviour. The objective of HAMS is to provide ADAS-like functionality with low-cost devices that can be retrofitted onto the large installed base of vehicles that lack specialized and expensive sensors such as LIDAR and RADAR. Our demo would show HAMS in action on an Android smartphone to monitor the state of the driver, specifically such as drowsiness, distraction and gaze, and vehicle ranging, lane detection running on pre-recorded videos from drives.

Published

2018

5. Poster

Author

Ravi Bhandari, Bhaskaran Raman, and Venkata N. Padmanabhan

Subjects

Focus (computing), Derailment, Computer science, Train, Red light, Computer security, computer.software_genre, Mobile device, computer

Abstract

Road accidents cause an estimated 1.3 million fatalities each year worldwide. We believe that mobile devices can play a positive role by detecting various driving related events like red light cutting, rash driving and many more. We focus on a specific problem that is responsible for many accidents in India: the stopping behaviour of buses especially in the vicinity of bus stops. We propose a smartphone-based system that specifically seeks to detect and report the following scenarios. Has the bus come to a complete stop(instead of a rolling stop)?Has the bus stopped in the left lane?Has the bus stopped exactly at the bus stop? thus prevent from derailment of trains

Published

2016