A Minimal-Input Framework for Cut-In Detection and Pair-Specific Risk Analysis in Highway Trajectory Data - Traj2Rel-SFC: Trajectory-to-Relation Reconstruction and Context Signatures for Cut-In Interactions
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Examensarbete för masterexamen
Master's Thesis
Master's Thesis
Modellbyggare
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Sammanfattning
Highway cut-ins create new same-lane leader–follower interactions that may require
the follower to brake, yet most analysis pipelines depend on dataset-provided lane and
neighbour identifiers, limiting reuse across datasets. This thesis presents Traj2Rel
SFC, a minimal-input framework that reconstructs lane assignment and same-lane
relations from trajectory geometry (x,y) and lane-marking metadata, detects cut-ins
as explicit cutter–follower pairs, computes pair-specific surrogate safety measures
(DHW, THW, TTC, DRAC), and encodes surrounding traffic context as reversible
16-bit Hilbert space-filling-curve signatures.
Evaluated on 60 highD recordings (with highD lane/neighbour identifiers used
only as reference labels, and highD indicator columns used only once to calibrate a
fixed geometry convention for pairwise SSM computation), the framework achieves
mean reconstruction accuracy >0.9998, cut-in detection F1 > 0.999, and context
signature agreement of 99.49% over 1.4M stage rows. Multi-indicator analysis
shows that THW, TTC, and DRAC capture complementary severity aspects; only
0.08% of events exceed the hard-braking DRAC threshold. Decision-stage features
predict execution-stage THW risk with ROC-AUC 0.82 under leave-one-recording-out
cross-validation, and SFC context features alone achieve AUC 0.62, showing that
spatial context signatures carry standalone predictive signal, although they do not
significantly improve AUC over the kinematic-only model. A small exploratory
extension on 10 exiD recordings further shows that the same lane-reconstruction
and cut-in mining core can be moved to highly interactive highway entry/exit scenes
without redesigning the pipeline, although this add-on is intentionally limited and is
not presented as a second benchmark.
From a software-engineering perspective, the result is a portable and auditable
analysis pipeline: method inputs are explicitly restricted, intermediate relations are
reconstructable and testable, and outputs can be reproduced without relying on
dataset-specific derived fields.
Beskrivning
Ämne/nyckelord
cut-in detection, minimal-input reconstruction, pair-specific risk analysis, surrogate safety measures, deceleration rate to avoid crash, interaction context signature, space-filling curve, risk prediction, highD, reproducibility.
