Litcius/Paper detail

Context Model for Pedestrian Intention Prediction Using Factored Latent-Dynamic Conditional Random Fields

Satyajit Neogi, Michael Hoy, Kang Dang, Hang Yu, Justin Dauwels

2020IEEE Transactions on Intelligent Transportation Systems32 citationsDOIOpen Access PDF

Abstract

Smooth handling of pedestrian interactions is a key requirement for Autonomous Vehicles (AV) and Advanced Driver Assistance Systems (ADAS). Such systems call for early and accurate prediction of a pedestrian’s crossing/not-crossing behaviour in front of the vehicle. Existing approaches to pedestrian behaviour prediction make use of pedestrian motion, his/her location in a scene and static context variables such as traffic lights, zebra crossings etc. We stress on the necessity of early prediction for smooth operation of such systems. We introduce the influence of vehicle interactions on pedestrian intention for this purpose. In this paper, we show a discernible advance in prediction time aided by the inclusion of such vehicle interaction context. We apply our methods to two different datasets, one in-house collected - NTU dataset and another public real-life benchmark - JAAD dataset. We also propose a generalization of the Latent-Dynamic Conditional Random Fields (LDCRF), called Factored LDCRF (FLDCRF), for improved sequence prediction performance. FLDCRF outperforms Long Short-Term Memory (LSTM) networks across the datasets over identical time-series features. While the existing best system predicts pedestrian stopping behaviour with 70% accuracy 0.38 seconds before the actual events, our system achieves such accuracy at least 0.9 seconds on an average before the actual events across datasets.

Topics & Concepts

PedestrianComputer scienceContext (archaeology)Benchmark (surveying)Advanced driver assistance systemsConditional random fieldArtificial intelligenceMachine learningEngineeringGeodesyBiologyPaleontologyTransport engineeringGeographyAutonomous Vehicle Technology and SafetyTraffic and Road SafetyVideo Surveillance and Tracking Methods