What does this research mean for the field?

The primary challenges in optical remote sensing object detection are annotation bottlenecks, extreme scale variations, and domain adaptation failures, with future advancements relying on foundation models, efficient architectures, and standardized benchmarks. Novelty: ClaimNovelty.SYNTHESIS. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

This review aims to analyze and categorize various object detection methodologies applied to optical remote sensing images.

April 25, 2026Open Access

Object Detection in Optical Remote Sensing Images: A Systematic Review of Methods, Benchmarks, and Operational Applications

Key Points

This review aims to analyze and categorize various object detection methodologies applied to optical remote sensing images.
Reviewed 189 studies published from 2010 to 2025 using PRISMA guidelines.
Categorized methodologies into template matching, knowledge-based, object-based image analysis, and machine learning-based methods.
Evaluated performance characteristics, computational requirements, and suitability for different applications.
Identified three main challenges: annotation bottleneck for deep learning, extreme scale variation in scenes, and domain adaptation failures.
73 studies provided quantitative results on standard benchmarks, showcasing the effectiveness of different approaches.
Proposed future directions focusing on foundation models for zero-shot detection and efficient architectures for resource-constrained deployment.

Abstract

Object detection in optical remote sensing imagery has emerged as a crucial task in computer vision, with applications ranging between environmental monitoring to disaster management, precision agriculture, and urban planning. This review systematically examines current methodologies, categorising them into four principal approaches: (1) template matching-based methods, which leverage predefined patterns for object identification; (2) knowledge-based methods, which incorporate geometric and contextual information to enhance detection accuracy; (3) object-based image analysis (OBIA), which segments images into meaningful objects using spectral and spatial properties; (4) machine learning-based methods, particularly deep convolutional neural networks (CNNs), which have revolutionised the field through automatic feature learning. Each methodology’s performance characteristics, computational requirements, and suitability for different remote sensing applications are analysed. Our systematic review, following PRISMA guidelines, analysed 189 studies published from 2010 to 2025, of which 73 provided quantitative results on standard benchmarks. The three most critical challenges identified are as follows: (1) annotation bottleneck, as dense bounding box labelling of remote sensing imagery remains highly labour-intensive for deep learning approaches, (2) extreme scale variation spanning 2–3 orders of magnitude within single scenes, and (3) domain adaptation failures when models encounter new geographic regions or sensor characteristics. This review identifies critical research gaps and proposes prioritised future directions, emphasising foundation models for zero-shot detection, efficient architectures for resource-constrained deployment, and standardised benchmarks with size-specific metrics. The analysis provides practitioners with evidence-based decision frameworks for method selection and researchers with a roadmap for advancing object detection in remote sensing applications.

Object Detection in Optical Remote Sensing Images: A Systematic Review of Methods, Benchmarks, and Operational Applications

Key Points

Abstract

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