TOLiD: Bridging the Architecture Gap in Vision Foundation Model to LiDAR Pretraining via Token Lifting for Distillation

📅 2026-07-12
📈 Citations: 0
Influential: 0
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🤖 AI Summary
This work addresses the challenge of transferring knowledge from vision foundation models to LiDAR backbones, where existing cross-modal distillation methods struggle due to the simultaneous presence of modality and architectural discrepancies. To overcome this, the authors propose a decoupling strategy that introduces a student Vision Transformer (ViT) isomorphic to the teacher visual ViT. Point clouds are mapped to image-patch-aligned tokens via Frustum Pooling and Frustum Attention, enabling token-level distillation augmented with visibility-aware masks. Subsequently, masked bilinear sampling reconstructs point-level features from these tokens, facilitating deployment with LiDAR-only inputs. This approach is the first to disentangle modality adaptation from architectural differences, achieving substantial performance gains across five LiDAR datasets and four cross-sensor tasks, while remaining compatible with frozen backbones and lightweight prediction heads.
📝 Abstract
Cross-modal distillation from Vision Foundation Models (VFMs) to LiDAR backbones has recently emerged as a self-supervised pretraining strategy that reduces reliance on dense point-wise annotation for 3D scene understanding. However, existing distillation pipelines typically treat the VFM as a frozen feature source and train a heterogeneous 3D backbone to match fixed image embeddings, forcing the student to bridge both the modality gap and the cross-architecture gap between dense ViT token representations and sparse 3D encoders. We propose TOLiD, a self-supervised pretraining method for LiDAR representation learning that addresses this gap by coupling a LiDAR backbone with a student Vision Transformer (ViT) initialized from a frozen VFM teacher and applying supervision over compatible patch-token representations. TOLiD converts the set of point features within each image patch frustum into a token using Frustum Pooling followed by Frustum Attention, and performs token-level distillation with visibility masking. For LiDAR-only deployment, we lift token features back to per-point representations using masked bilinear sampling to avoid patches that have limited LiDAR points. We extensively evaluate TOLiD on five heterogeneous LiDAR datasets and four cross-sensor adaptation pairs, demonstrating improved transfer with frozen backbones and lightweight heads.
Problem

Research questions and friction points this paper is trying to address.

cross-modal distillation
Vision Foundation Models
LiDAR pretraining
architecture gap
3D scene understanding
Innovation

Methods, ideas, or system contributions that make the work stand out.

cross-modal distillation
token lifting
frustum attention
self-supervised pretraining
vision foundation model
S
Sutharsan Mahendran
SAIVT Group, School of Electrical Engineering and Robotics, Queensland University of Technology, Australia; CSIRO Robotics, CSIRO, Australia
D
Darshana Priyasad
SAIVT Group, School of Electrical Engineering and Robotics, Queensland University of Technology, Australia
K
Kaushik Roy
CSIRO Robotics, CSIRO, Australia
Tharindu Fernando
Tharindu Fernando
Queensland University of Technology
human behaviour analysistrajectory predictionmachine learning
Sridha Sridharan
Sridha Sridharan
Professor
computer visionmachine learningspeaker recognitionbiometricsimage processing
Clinton Fookes
Clinton Fookes
Queensland University of Technology
Computer VisionMachine LearningSignal ProcessingAIVideo Analytics/Biometrics/Medical Imaging
Peyman Moghadam
Peyman Moghadam
Principal Research Scientist, CSIRO | Professor (A), QUT
Embodied AIRoboticsSLAMMachine Learning