STEM: Semantic target search and exploration using MAVs in cluttered environments

Journal Article (2026)
Author(s)

Nikhil Sethi (Student TU Delft)

Max Lodel (TU Delft - Mechanical Engineering)

Laura Ferranti (TU Delft - Mechanical Engineering)

Robert Babuška (Czech Technical University, TU Delft - Mechanical Engineering)

Javier Alonso-Mora (TU Delft - Mechanical Engineering)

Research Group
Learning & Autonomous Control
DOI related publication
https://doi.org/10.1007/s10514-026-10247-6 Final published version
More Info
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Publication Year
2026
Language
English
Research Group
Learning & Autonomous Control
Journal title
Autonomous Robots
Issue number
3
Volume number
50
Article number
32
Downloads counter
5
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Abstract

Autonomous target search is crucial for deploying Micro Aerial Vehicles (MAVs) in emergency response and rescue missions. Existing approaches either focus on 2D semantic navigation in structured environments – which is less effective in complex 3D settings, or on robotic exploration in cluttered spaces – which often lacks the semantic reasoning needed for efficient target search. This paper overcomes these limitations by proposing a novel framework that utilizes a semantically-guided viewpoint planner to minimize target search and exploration time in unstructured 3D environments using an MAV. Specifically, we develop a combinatorial planner that generates efficient semantic exploration plans by prioritizing viewpoints that likely lead to the target. To guide the planner towards the target, an active perception pipeline is developed that propagates semantic priorities of observed objects into neighboring frontier voxels for computing semantic information gains of frontier viewpoints. In addition, we demonstrate how LLM-based similarity scores can be leveraged as semantic priority input to our pipeline. Evaluations in two distinct simulation environments show that the proposed method consistently outperforms baselines by quickly finding the target while maintaining reasonable exploration times. Real-world experiments with an MAV further demonstrate the method’s ability to handle practical constraints like limited battery life, small sensor range, and semantic uncertainty.