arxiv_cv 85% Match Research Paper Robotics engineers,Computer vision researchers,AI scientists 2 weeks ago

CLOVER: Context-aware Long-term Object Viewpoint- and Environment- Invariant Representation Learning

computer-vision › scene-understanding

📄 Abstract

Abstract: Mobile service robots can benefit from object-level understanding of their environments, including the ability to distinguish object instances and re-identify previously seen instances. Object re-identification is challenging across different viewpoints and in scenes with significant appearance variation arising from weather or lighting changes. Existing works on object re-identification either focus on specific classes or require foreground segmentation. Further, these methods, along with object re-identification datasets, have limited consideration of challenges such as outdoor scenes and illumination changes. To address this problem, we introduce CODa Re-ID: an in-the-wild object re-identification dataset containing 1,037,814 observations of 557 objects across 8 classes under diverse lighting conditions and viewpoints. Further, we propose CLOVER, a representation learning method for object observations that can distinguish between static object instances without requiring foreground segmentation. We also introduce MapCLOVER, a method for scalably summarizing CLOVER descriptors for use in object maps and matching new observations to summarized descriptors. Our results show that CLOVER achieves superior performance in static object re-identification under varying lighting conditions and viewpoint changes and can generalize to unseen instances and classes.

Authors (3)

Dongmyeong Lee

Amanda Adkins

Joydeep Biswas

Submitted

July 12, 2024

arXiv Category

cs.CV

arXiv PDF

Key Contributions

Introduces CLOVER, a representation learning method for object observations that is invariant to viewpoint and environmental changes, enabling robust object re-identification for mobile robots. It also presents CODa Re-ID, a large-scale, in-the-wild dataset specifically designed to address challenges like diverse lighting and viewpoints.

Business Value

Improves the situational awareness and navigation capabilities of mobile robots and autonomous systems by enabling reliable object recognition and tracking in complex, dynamic environments.

Paper Metadata

Innovation Type

Algorithmic & Dataset

Deployment Feasibility

High, particularly for robotics applications where robust object recognition is critical.

Limitations Addressed

Object re-identification challenges across different viewpoints and appearance variations (weather, lighting),Limited consideration of outdoor scenes and illumination changes in existing methods/datasets,Requirement for foreground segmentation in some prior works

Performance Gains

Enables distinguishing static object instances without requiring foreground segmentation, and robust re-identification across diverse conditions.

Technical Tags

object re-identificationrepresentation learningviewpoint invariantenvironment invariantmobile robotsdatasetlighting changesappearance variation

Research Topics

Computer VisionRoboticsRepresentation LearningObject RecognitionScene Understanding

Methods & Architectures

CLOVER (Context-aware Long-term Object Viewpoint- and Environment- Invariant Representation Learning)CODa Re-ID dataset Representation Learning Models

Applications & Tasks

Robotics Autonomous Systems Surveillance Computer Vision Object re-identification across viewpointsAppearance variation due to lighting/weatherLimited consideration of outdoor scenesNeed for foreground segmentation Learning viewpoint and environment invariant object representationsRe-identifying objects for mobile robotsCreating a challenging in-the-wild object re-identification dataset

Datasets & Benchmarks

Datasets

CODa Re-ID

Object re-identification accuracy

Related Fields

RoboticsComputer VisionRepresentation LearningObject RecognitionScene UnderstandingMachine Learning

Keywords

object re-identificationrepresentation learningviewpoint invariantenvironment invariantmobile robotsdatasetlighting changesappearance variationCODa Re-IDCLOVERautonomous systemsscene understanding

Academic Context

#Computer Vision#Robotics#Representation Learning#Object Recognition#Scene Understanding

Commercial Potential

Potential Products

Object recognition modules for robotsRobust tracking systems for autonomous vehicles

Target Industries

RoboticsAutomotiveLogisticsSecurityAutonomous Systems

Use Case Examples

Enabling robots to recognize and track objects across different locations and timesImproving autonomous navigation by maintaining object identitySecurity surveillance systems that can track individuals or objects

Competitive Edge

Offers more robust object re-identification across challenging viewpoint and environmental variations compared to methods that require foreground segmentation or are limited to specific conditions.

Market Opportunity

Growing market for autonomous robots and AI-powered perception systems.

Revenue Models

Licensing of algorithmsintegration into robotic platforms.

Resource Requirements

Compute Needs

Moderate to High, depending on the complexity of the representation learning model.

Data Requirements

Large-scale, diverse object re-identification dataset (like CODa Re-ID) covering various viewpoints and environmental conditions.

Deployment Constraints

Real-time performance requirements for robotic applications.

Scalability

The representation learning approach is generally scalable to new objects and environments.

Production Readiness

Maturity Level

Research/Development

Time to Market

2-3 years for integration into commercial robotic systems.

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