Drones

23 pages, 11401 KB

Open AccessArticle

HSFANet: Hierarchical Scale-Sensitive Feature Aggregation Network for Small Object Detection in UAV Aerial Images

by Hongxing Zhang, Zhonghong Ou, Siyuan Yao, Yifan Zhu, Yangfu Zhu, Hailin Li, Shigeng Wang, Yang Guo and Meina Song

Drones 2025, 9(9), 659; https://doi.org/10.3390/drones9090659 - 19 Sep 2025

Abstract

Small object detection in aerial images, particularly from Unmanned Aerial Vehicle (UAV) platforms, remains a significant challenge due to limited object resolution, dense scenes, and background interference. However, existing small object detectors often overlook making full use of hierarchical features and inevitably introduce [...] Read more.

Small object detection in aerial images, particularly from Unmanned Aerial Vehicle (UAV) platforms, remains a significant challenge due to limited object resolution, dense scenes, and background interference. However, existing small object detectors often overlook making full use of hierarchical features and inevitably introduce noise interference because of hierarchical upsampling operations, and commonly used loss metrics lack sensitivity to scale information; these two issues jointly lead to performance deterioration. To address these issues, we propose Hierarchical Scale-Sensitive Feature Aggregation Network (HSFANet), a novel framework that conducts robust cross-layer feature interaction to perceive the small objects’ position information in hierarchical feature pyramids and enforces the model to balance the multi-scale prediction heads for accurate instances localization. HSFANet introduces a Dynamic Position Aggregation (DPA) module to explicitly enhance the object area in both shallow and deep layers, which is capable of exploiting the complementarily salient representation of the small objects. Additionally, an efficient Scale-Sensitive Loss (SSL) is proposed to balance the small object detection outputs in hierarchical prediction heads, thereby effectively improving the performance of small object detection. Extensive experiments on two challenging UAV benchmarks, VisDrone and UAVDT, demonstrate that HSFANet achieves state-of-the-art (SOTA) results, with a 1.3% gain in overall average precision (AP) and a notable 2.2% improvement in AP for small objects on VisDrone. On UAVDT, HSFANet outperforms previous methods by 0.3% in overall AP and 16.7% in small object AP. These results highlight the effectiveness of HSFANet in enhancing small object detection performance in complex aerial imagery, making it well suited for practical UAV-based applications. Full article

(This article belongs to the Special Issue Intelligent Image Processing and Sensing for Drones, 2nd Edition)

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23 pages, 9262 KB

Open AccessArticle

An Algorithm for Planning Coverage of an Area with Obstacles with a Heterogeneous Group of Drones Using a Genetic Algorithm and Parameterized Polygon Decomposition

by Kirill Yakunin, Yan Kuchin, Elena Muhamedijeva, Adilkhan Symagulov and Ravil I. Mukhamediev

Drones 2025, 9(9), 658; https://doi.org/10.3390/drones9090658 - 18 Sep 2025

Abstract

The paper presents an algorithm for planning agricultural field surveying routes in the presence of obstacles, designed to address precision agriculture tasks. Unlike classical methods, which are typically limited to straightforward zigzag (Zamboni) traversal and basic perimeter-based obstacle avoidance, the proposed algorithm accounts [...] Read more.

The paper presents an algorithm for planning agricultural field surveying routes in the presence of obstacles, designed to address precision agriculture tasks. Unlike classical methods, which are typically limited to straightforward zigzag (Zamboni) traversal and basic perimeter-based obstacle avoidance, the proposed algorithm accounts for heterogeneous unmanned aerial vehicles (UAVs) of varying types, ranges, costs, and speeds, along with a mobile ground platform that enables drone takeoff and landing at multiple points along the road. The key innovation lies in a two-stage optimization procedure: initially, a random set of field partitions into multiple sub-polygons with predefined area proportions (considering internal obstacles) is generated. Subsequently, the optimal partitioning is selected, and based on this, a genetic algorithm is applied to optimize flight parameters, including flight angle, entry points, composition, and sequence of drone launches, and the ground platform route. This approach achieves more localized coverage of individual field segments, with each segment serviced by an appropriate drone type, while also enabling flexible movement of the ground platform, thereby reducing unnecessary flights. This brings down the price of the coverage by 10–30% in some cases. The concluding section discusses future directions, including the incorporation of three-dimensional terrain considerations, dynamic factors (such as changing weather conditions and drone stoppages due to technical issues), and automated collision avoidance in intersecting route segments. Full article

(This article belongs to the Special Issue Recent Developments in Artificial Intelligence and Interdisciplinary Research for UAV Application)

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28 pages, 616 KB

Open AccessArticle

UAVThreatBench: A UAV Cybersecurity Risk Assessment Dataset and Empirical Benchmarking of LLMs for Threat Identification

by Padma Iyenghar

Drones 2025, 9(9), 657; https://doi.org/10.3390/drones9090657 - 18 Sep 2025

Abstract

UAVThreatBench introduces the first structured benchmark for evaluating large language models in cybersecurity threat identification for unmanned aerial vehicles operating within industrial indoor settings, aligned with the European Radio Equipment Directive. The benchmark consists of 924 expert-curated industrial scenarios, each annotated with five [...] Read more.

UAVThreatBench introduces the first structured benchmark for evaluating large language models in cybersecurity threat identification for unmanned aerial vehicles operating within industrial indoor settings, aligned with the European Radio Equipment Directive. The benchmark consists of 924 expert-curated industrial scenarios, each annotated with five cybersecurity threats, yielding a total of 4620 threats mapped to directive articles on network and device integrity, personal data and privacy protection, and prevention of fraud and economic harm. Seven state-of-the-art models from the OpenAI GPT family and the LLaMA family were systematically assessed on a representative subset of 100 scenarios from the UAVThreatBench dataset. The evaluation applied a fuzzy matching threshold of 70 to compare model-generated threats against expert-defined ground truth. The strongest model identified nearly nine out of ten threats correctly, with close to half of the scenarios achieving perfect alignment, while other models achieved lower but still substantial alignment. Semantic error analysis revealed systematic weaknesses, particularly in identifying availability-related threats, backend-layer vulnerabilities, and clause-level regulatory mappings. UAVThreatBench therefore establishes a reproducible foundation for regulatory-compliant cybersecurity threat identification in safety-critical unmanned aerial vehicle environments. The complete benchmark dataset and evaluation results are openly released under the MIT license through a dedicated online repository. Full article

(This article belongs to the Special Issue Advances in Detection, Security, and Communication for UAV: 2nd Edition)

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25 pages, 27717 KB

Open AccessArticle

MCS-Sim: A Photo-Realistic Simulator for Multi-Camera UAV Visual Perception Research

by Qiming Qi, Guoyan Wang, Yonglei Pan, Hongqi Fan and Biao Li

Drones 2025, 9(9), 656; https://doi.org/10.3390/drones9090656 - 18 Sep 2025

Abstract

Multi-camera systems (MCSs) are pivotal in aviation surveillance and autonomous navigation due to their wide coverage and high-resolution sensing. However, challenges such as complex setup, time-consuming data acquisition, and costly testing hinder research progress. To address these, we introduce MCS-Sim, a photo-realistic [...] Read more.

Multi-camera systems (MCSs) are pivotal in aviation surveillance and autonomous navigation due to their wide coverage and high-resolution sensing. However, challenges such as complex setup, time-consuming data acquisition, and costly testing hinder research progress. To address these, we introduce MCS-Sim, a photo-realistic MCSsimulator for UAV visual perception research. MCS-Sim integrates vision sensor configurations, vehicle dynamics, and dynamic scenes, enabling rapid virtual prototyping and multi-task dataset generation. It supports dense flow estimation, 3D reconstruction, visual simultaneous localization and mapping, object detection, and tracking. With a hardware-in-loop interface, MCS-Sim facilitates closed-loop simulation for system validation. Experiments demonstrate its effectiveness in synthetic dataset generation, visual perception algorithm testing, and closed-loop simulation. Here we show that MCS-Sim significantly advances multi-camera UAV visual perception research, offering a versatile platform for future innovations. Full article

(This article belongs to the Special Issue When Deep Learning Meets Geometry for Air-to-Ground Perception on Drones: 2nd Edition)

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16 pages, 3030 KB

Open AccessArticle

Spatiotemporal Monitoring of Large Woody Debris Mobility and Distribution Using Unmanned Aerial Vehicles Along the Oshirarika River, Northern Japan

by Yasutaka Nakata, Masato Hayamizu and Nobuo Ishiyama

Drones 2025, 9(9), 655; https://doi.org/10.3390/drones9090655 - 18 Sep 2025

Abstract

Large woody debris (LWD) in river systems serves beneficial ecological functions and poses potential hazards during flood events. Managing LWD requires a balanced understanding of its dynamics. This study employed unmanned aerial vehicles (UAVs) for high-resolution, spatiotemporal monitoring of LWD distribution and mobility [...] Read more.

Large woody debris (LWD) in river systems serves beneficial ecological functions and poses potential hazards during flood events. Managing LWD requires a balanced understanding of its dynamics. This study employed unmanned aerial vehicles (UAVs) for high-resolution, spatiotemporal monitoring of LWD distribution and mobility along the Oshirarika River in northern Japan. UAV imagery enabled efficient LWD recruitment and transport assessments. The spatial distribution analysis revealed that >90% of LWD was deposited on bar surfaces, underscoring the role of geomorphic features in controlling LWD accumulation. Generalized linear mixed models revealed that the maximum water level and the frequency of its rise above 0.8 m were the most influential predictors of the number of recruited and transported LWD. Additionally, the topographic position—channel, lower bar, or higher bar—exhibited a significant negative association, indicating greater LWD mobility and deposition in lower elevation zones. This trend may be attributed to infrequent high-magnitude flood events, which likely result in relatively limited LWD dynamics in higher bar areas. These findings demonstrate the utility of UAV-based monitoring coupled with GLMMs for capturing the spatial and temporal dynamics of LWD. The ability to link hydrological fluctuations and LWD behavior provides a valuable framework for management and ecological restoration in steep, forested watersheds. Full article

(This article belongs to the Special Issue Drones for Green Areas, Green Infrastructure and Landscape Monitoring)

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28 pages, 3131 KB

Open AccessArticle

A Lightweight and Dynamic Authentication Scheme Based on Blockchain and aSVC for UAV Swarm

by Jianbo Jiao, Bing Chen, Feng Hu and Yunkun Wu

Drones 2025, 9(9), 654; https://doi.org/10.3390/drones9090654 - 17 Sep 2025

Abstract

The rapid development of Unmanned Aerial Vehicle (UAV) swarm technology has led to its increasingly vital role in intelligent transportation, environmental monitoring, and emergency response. However, existing centralized identity authentication mechanisms are susceptible to single points of failure and identity forgery in dynamic [...] Read more.

The rapid development of Unmanned Aerial Vehicle (UAV) swarm technology has led to its increasingly vital role in intelligent transportation, environmental monitoring, and emergency response. However, existing centralized identity authentication mechanisms are susceptible to single points of failure and identity forgery in dynamic environments. While blockchain technology offers a distributed trust architecture, its inherent high storage and computational overhead pose significant challenges for resource-constrained UAV networks. To mitigate these challenges, this paper introduces a novel lightweight and dynamic identity authentication scheme that integrates blockchain with aggregatable subvector commitments (aSVC). This proposed scheme employs aSVC to effectively compress identity states, complemented by efficient batch authentication and asynchronous update mechanisms. Consequently, this approach reduces on-chain storage overhead to a constant level and achieves a statistically significant optimization of the computational complexity for batch authentication, transforming key cryptographic operations from linear dependence on the number of UAVs to a constant level. Full article

(This article belongs to the Special Issue IoT-Enabled UAV Networks for Secure Communication)

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30 pages, 3141 KB

Open AccessArticle

Lyapunov-Based Deep Deterministic Policy Gradient for Energy-Efficient Task Offloading in UAV-Assisted MEC

by Jianhua Liu, Xudong Zhang, Haitao Zhou, Xia Lei, Huiru Li and Xiaofan Wang

Drones 2025, 9(9), 653; https://doi.org/10.3390/drones9090653 - 16 Sep 2025

Abstract

The demand for low-latency computing from the Internet of Things (IoT) and emerging applications challenges traditional cloud computing. Mobile Edge Computing (MEC) offers a solution by deploying resources at the network edge, yet terrestrial deployments face limitations. Unmanned Aerial Vehicles (UAVs), leveraging their [...] Read more.

The demand for low-latency computing from the Internet of Things (IoT) and emerging applications challenges traditional cloud computing. Mobile Edge Computing (MEC) offers a solution by deploying resources at the network edge, yet terrestrial deployments face limitations. Unmanned Aerial Vehicles (UAVs), leveraging their high mobility and flexibility, provide dynamic computation offloading for User Equipments (UEs), especially in areas with poor infrastructure or network congestion. However, UAV-assisted MEC confronts significant challenges, including time-varying wireless channels and the inherent energy constraints of UAVs. We put forward the Lyapunov-based Deep Deterministic Policy Gradient (LyDDPG), a novel computation offloading algorithm. This algorithm innovatively integrates Lyapunov optimization with the Deep Deterministic Policy Gradient (DDPG) method. Lyapunov optimization transforms the long-term, stochastic energy minimization problem into a series of tractable, per-timeslot deterministic subproblems. Subsequently, DDPG is utilized to solve these subproblems by learning a model-free policy through environmental interaction. This policy maps system states to optimal continuous offloading and resource allocation decisions, aiming to minimize the Lyapunov-derived “drift-plus-penalty” term. The simulation outcomes indicate that, compared to several baseline and leading algorithms, the proposed LyDDPG algorithm reduces the total system energy consumption by at least 16% while simultaneously maintaining low task latency and ensuring system stability. Full article

(This article belongs to the Section Drone Communications)

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22 pages, 1483 KB

Open AccessArticle

Fusing Adaptive Game Theory and Deep Reinforcement Learning for Multi-UAV Swarm Navigation

by Guangyi Yao, Lejiang Guo, Haibin Liao and Fan Wu

Drones 2025, 9(9), 652; https://doi.org/10.3390/drones9090652 - 16 Sep 2025

Abstract

To address issues such as inadequate robustness in dynamic obstacle avoidance, instability in formation morphology, severe resource conflicts in multi-task scenarios, and challenges in global path planning optimization for unmanned aerial vehicles (UAVs) operating in complex airspace environments, this paper examines the advantages [...] Read more.

To address issues such as inadequate robustness in dynamic obstacle avoidance, instability in formation morphology, severe resource conflicts in multi-task scenarios, and challenges in global path planning optimization for unmanned aerial vehicles (UAVs) operating in complex airspace environments, this paper examines the advantages and limitations of conventional UAV formation cooperative control theories. A multi-UAV cooperative control strategy is proposed, integrating adaptive game theory and deep reinforcement learning within a unified framework. By employing a three-layer information fusion architecture—comprising the physical layer, intent layer, and game-theoretic layer—the approach establishes models for multi-modal perception fusion, game-theoretic threat assessment, and dynamic aggregation-reconstruction. This optimizes obstacle avoidance algorithms, facilitates interaction and task coupling among formation members, and significantly improves the intelligence, resilience, and coordination of formation-wide cooperative control. The proposed solution effectively addresses the challenges associated with cooperative control of UAV formations in complex traffic environments. Full article

(This article belongs to the Special Issue Cooperative Perception for Modern Transportation)

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24 pages, 2714 KB

Open AccessArticle

Drone Monitoring and Behavioral Analysis of White-Beaked Dolphins (Lagenorhynchus albirostris)

by Ditte Grønnegaard Lauridsen, Niels Madsen, Sussie Pagh, Maria Glarou, Cino Pertoldi and Marianne Helene Rasmussen

Drones 2025, 9(9), 651; https://doi.org/10.3390/drones9090651 - 16 Sep 2025

Abstract

Marine mammals serve as indicator species for environmental and human health. However, they are increasingly exposed to pressure from human activities and climate change. The white-beaked dolphin (Lagenorhynchus albirostris) (WBD) is among the species negatively affected by these conditions. To support [...] Read more.

Marine mammals serve as indicator species for environmental and human health. However, they are increasingly exposed to pressure from human activities and climate change. The white-beaked dolphin (Lagenorhynchus albirostris) (WBD) is among the species negatively affected by these conditions. To support conservation and management efforts, a deeper understanding of their behavior and movement patterns is essential. One approach is drone-based monitoring combined with artificial intelligence (AI), allowing efficient data collection and large-scale analysis. This study aims to: (1) investigate the use of drone imagery and AI to monitor and analyze marine mammal behavior, and (2) test the application of machine learning (ML) to identify behavioral patterns. Data were collected in Skjálfandi Bay, Iceland, between 2021 and 2023. Three behavioral types were identified: Traveling, Milling, and Respiration. The AI_RGB model showed high performance on Traveling behavior (precision 92.3%, recall 96.9%), while the AI_gray model achieved higher precision (97.3%) but much lower recall (9.5%). The model struggled to classify Respiration accurately (recall 1%, F1-score 2%). A key challenge was misidentification of WBDs due to visual overlap with birds, waves, and reflections, resulting in high false positive rates. Multimodal AI systems may help reduce such errors in future research. Full article

(This article belongs to the Special Issue Innovative Approaches to Biodiversity and Ecology Monitoring: Artificial Intelligence (AI) and Drone Technology)

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25 pages, 5138 KB

Open AccessArticle

Off-Policy Deep Reinforcement Learning for Path Planning of Stratospheric Airship

by Jiawen Xie, Wanning Huang, Jinggang Miao, Jialong Li and Shenghong Cao

Drones 2025, 9(9), 650; https://doi.org/10.3390/drones9090650 - 16 Sep 2025

Abstract

The stratospheric airship is a vital platform in near-space applications, and achieving autonomous transfer has become a key research focus to meet the demands of diverse mission scenarios. The core challenge lies in planning feasible and efficient paths, which is difficult for traditional [...] Read more.

The stratospheric airship is a vital platform in near-space applications, and achieving autonomous transfer has become a key research focus to meet the demands of diverse mission scenarios. The core challenge lies in planning feasible and efficient paths, which is difficult for traditional algorithms due to the time-varying environment and the highly coupled multi-system dynamics of the airship. This study proposes a deep reinforcement learning algorithm, termed reward-prioritized Long Short-Term Memory Twin Delayed Deep Deterministic Policy Gradient (RPL-TD3). The method incorporates an LSTM network to effectively capture the influence of historical states on current decision-making, thereby improving performance in tasks with strong temporal dependencies. Furthermore, to address the slow convergence commonly seen in off-policy methods, a reward-prioritized experience replay mechanism is introduced. This mechanism stores and replays experiences in the form of sequential data chains, labels them with sequence-level rewards, and prioritizes high-value experiences during training to accelerate convergence. Comparative experiments with other algorithms indicate that, under the same computational resources, RPL-TD3 improves convergence speed by 62.5% compared to the baseline algorithm without the reward-prioritized experience replay mechanism. In both simulation and generalization experiments, the proposed method is capable of planning feasible paths under kinematic and energy constraints. Compared with peer algorithms, it achieves the shortest flight time while maintaining a relatively high level of average residual energy. Full article

(This article belongs to the Special Issue Design and Flight Control of Low-Speed Near-Space Unmanned Systems)

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16 pages, 1170 KB

Open AccessArticle

Development and Validation of an Amphibious Drone-Based In-Situ SPE System for Environmental Water Monitoring

by Osamu Kiguchi, Kouki Saitoh, Makoto Yoshida, Takero Kikuchi, Shunsuke Watanabe, Hirokazu Madokoro, Takeshi Nagayoshi, Makoto Inoue, Nobumitsu Kurisawa and Hitoshi Osawa

Drones 2025, 9(9), 649; https://doi.org/10.3390/drones9090649 - 15 Sep 2025

Abstract

To improve the efficiency of aquatic environmental monitoring, an in-situ solid-phase extraction (SPE) system using amphibious (waterproof) drones was developed and validated using recovery testing with samples containing known concentrations of systemic insecticides in the laboratory and using real samples from natural water [...] Read more.

To improve the efficiency of aquatic environmental monitoring, an in-situ solid-phase extraction (SPE) system using amphibious (waterproof) drones was developed and validated using recovery testing with samples containing known concentrations of systemic insecticides in the laboratory and using real samples from natural water bodies. The system used a water-resistant linear actuator for continuous aspiration at 1–10 mL min⁻¹ through a pre-washed hydrophilic–lipophilic balanced SPE cartridge. The system functioned properly during field sampling using vacuum-mode filtration to avoid overpressure, overcurrent, and contamination through repeated filtration. The recovery tests using 10 ng L⁻¹ of each target analyte in ultra-pure water samples produced satisfactory recovery results of 89–96% (relative standard deviation < 10%). In the real sampling of water bodies, the developed system was able to detect target analytes of 0.9–180 ng L⁻¹. The results are comparable to those obtained using in-situ manual SPE from boat sampling, irrespective of differences in the two aspiration systems. These findings suggest that the application of the developed drone-assisted in situ SPE system can improve the efficiency of real-sample monitoring of natural water bodies. Full article

(This article belongs to the Special Issue Drones in Hydrological Research and Management)

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23 pages, 2691 KB

Open AccessArticle

Secure Energy Efficiency Maximization for IRS-Assisted UAV Communication: Joint Beamforming Design and Trajectory Optimization

by Jiazheng Lv, Jianhua Cheng and Peng Li

Drones 2025, 9(9), 648; https://doi.org/10.3390/drones9090648 - 15 Sep 2025

Abstract

This paper addresses secure transmission in a high-occlusion urban environment, where an intelligent reflecting surface (IRS)-assisted unmanned aerial vehicle (UAV) communication system serves a legitimate user while countering an eavesdropper. The UAV signal is reflected to the base station through the IRS. We [...] Read more.

This paper addresses secure transmission in a high-occlusion urban environment, where an intelligent reflecting surface (IRS)-assisted unmanned aerial vehicle (UAV) communication system serves a legitimate user while countering an eavesdropper. The UAV signal is reflected to the base station through the IRS. We study the secure energy efficiency optimization problem. The tightly coupled optimization variables make the problem difficult to solve directly. Therefore, we decompose the original problem into three sub-problems. For the UAV active beamforming design, the closed-form solution can be obtained directly. For the IRS phase shift optimization, we propose an optimization algorithm based on Riemannian manifolds to obtain the optimal solution. Due to the non-convex fractional UAV trajectory optimization, it can be solved by successive convex approximation (SCA) and the Dinkelbach algorithm. Different comparison schemes are designed to evaluate the effectiveness of the proposed algorithm. The simulation results show that the proposed algorithm has improved advantages compared with other schemes. Full article

(This article belongs to the Section Drone Communications)

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20 pages, 7629 KB

Open AccessArticle

Probability Maps and Search Strategies for Automated UAV Search in the Wadden Sea

by Ludmila Moshagen, Carlos Castelar Wembers and Georg Schildbach

Drones 2025, 9(9), 647; https://doi.org/10.3390/drones9090647 - 15 Sep 2025

Abstract

Search and rescue (SAR) operations with unmanned aerial vehicles (UAVs) have been the subject of numerous scientific studies. Their effectiveness relies on intelligent and efficient path planning. Not only can they save expensive resources, they can minimize potential risks for the rescue team. [...] Read more.

Search and rescue (SAR) operations with unmanned aerial vehicles (UAVs) have been the subject of numerous scientific studies. Their effectiveness relies on intelligent and efficient path planning. Not only can they save expensive resources, they can minimize potential risks for the rescue team. This paper deals with optimal path planning for automated UAV-SAR operations, tailored specifically to the challenging inter-tidal environment of the Wadden Sea. The aim is to minimize the search time and maximize the discovery probability of lost persons (LPs) with intelligent UAV path-planning strategies. To achieve this, first a dynamic probability map (PM) of the lost person’s possible location is generated. Two distinct methods are evaluated for this purpose: Monte Carlo simulations (MCSs), and a more efficient Markov chain (MAC) model. The PM then directly informs the UAV’s decision-making process. Then, several automated search strategies are systematically evaluated and compared in a comprehensive simulation study, from simple coverage patterns to advanced PM-driven algorithms. MAC-generated PMs prove to provide a fast and reliable foundation for time-critical applications such as SAR operations. Additionally, PM-based search strategies outperform standard search patterns, especially in larger search regions. Furthermore, the evaluation is extended to multi-UAV scenarios, showing in this case that an area-segmentation approach is most effective. The results validate and provide a considerable contribution for an efficient, time-critical framework for UAV deployment in complex, real-world SAR operations. Full article

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35 pages, 7969 KB

Open AccessArticle

Research on Dynamic Scheduling Strategy of Multi-Platform Unmanned Helicopters Based on Improved TS Algorithm

by Jingyu Cong, Wei Han, Fang Guo, Bing Wan, Xiaohua Han, Changjiu Li and Xichao Su

Drones 2025, 9(9), 646; https://doi.org/10.3390/drones9090646 - 15 Sep 2025

Abstract

In modern amphibious operations, the dynamic scheduling of shipborne unmanned helicopters faces challenges including highly uncertain operational environments, complex and variable mission requirements, and stringent resource constraints. To tackle this issue, this paper presents an integrated solution encompassing modeling, scheduling strategies, and optimization [...] Read more.

In modern amphibious operations, the dynamic scheduling of shipborne unmanned helicopters faces challenges including highly uncertain operational environments, complex and variable mission requirements, and stringent resource constraints. To tackle this issue, this paper presents an integrated solution encompassing modeling, scheduling strategies, and optimization algorithms. First, a Dynamic Scheduling Model for Integrated Operation-Support Activities of Shipborne Unmanned Helicopters (SUH-DSMIOSA) is developed, which integrates mission temporal constraints, heterogeneous unmanned helicopter resources, and deck support resource constraints to achieve integrated modeling of operational tasks and support operations. Second, a Multi-Modal Disturbance-Aware Adaptive Rescheduling Strategy (MDAARS) is designed, which adaptively selects targeted rescheduling schemes by identifying disturbance types and establishes a differentiated evaluation system to quantify their effects. And then, an Improved Tabu Search algorithm (I-TS) is proposed, enhancing search efficiency and solution quality through adaptive tabu length adjustment, enhanced neighborhood operations, and an intelligent restart strategy. The results show that the I-TS algorithm achieved an average convergence speed improvement of 40.2% and a solution quality enhancement of 1.76%. The algorithm reaches a normalized efficiency of 0.98 within 10 iterations and maintains excellent stability throughout the entire convergence process. When facing disturbance events, the proposed algorithm reduces the mission change rate by an average of 20.1% and improves the rescheduling success rate by 2.8% compared to other algorithms. This research provides theoretical support and technical pathways for efficient dynamic scheduling of unmanned helicopters in amphibious operations. Full article

(This article belongs to the Special Issue Autonomous Flight of Drone: Control, Trajectory Optimization and Mission Planning: 2nd Edition)

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30 pages, 2061 KB

Open AccessArticle

A Feature-Aware Elite Imitation MARL for Multi-UAV Trajectory Optimization in Mountain Terrain Detection

by Quanxi Zhou, Ye Tao, Qianxiao Su and Manabu Tsukada

Drones 2025, 9(9), 645; https://doi.org/10.3390/drones9090645 - 15 Sep 2025

Abstract

With the advancement of UAV trajectory planning and sensing technologies, unmanned aerial vehicles (UAVs) are now capable of performing high-performance ground detection and search tasks. Mountainous regions, due to their complex terrain, have long been a focal point in the field of remote [...] Read more.

With the advancement of UAV trajectory planning and sensing technologies, unmanned aerial vehicles (UAVs) are now capable of performing high-performance ground detection and search tasks. Mountainous regions, due to their complex terrain, have long been a focal point in the field of remote sensing. Effective UAV search tasks in such areas must consider not only horizontal coverage but also variations in detection range and angle caused by changes in elevation. Conventional algorithms typically require complete prior knowledge of the environment for trajectory optimization and often depend on scenario-specific policy models, limiting their generalizability. To address these challenges, this paper proposes a Feature-Aware Elite Imitation Multi-Agent Reinforcement Learning (FA-EIMARL) algorithm that leverages partial terrain information to construct a feature extraction network. This approach enables batch training across diverse terrains without the need for full environmental maps. In addition, an elite imitation mechanism has been proposed for convergence acceleration and task performance enhancement. Simulation results demonstrate that the proposed method achieves superior reward performance, convergence rate, and computational efficiency while maintaining strong adaptability to varying terrains. Full article

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22 pages, 1167 KB

Open AccessArticle

CaST-MASAC: Integrating Causal Inference and Spatio-Temporal Attention for Multi-UAV Cooperative Task Planning

by Renjie Chen and Feng Hu

Drones 2025, 9(9), 644; https://doi.org/10.3390/drones9090644 - 14 Sep 2025

Abstract

The efficient coordination of multi-Unmanned Aerial Vehicle (UAV) systems in the increasingly complex domain of aerial tasks is hampered by significant challenges, including partial observability, low sample efficiency, and difficulties in inter-agent coordination. To address these issues, this paper introduces a novel Causal [...] Read more.

The efficient coordination of multi-Unmanned Aerial Vehicle (UAV) systems in the increasingly complex domain of aerial tasks is hampered by significant challenges, including partial observability, low sample efficiency, and difficulties in inter-agent coordination. To address these issues, this paper introduces a novel Causal Spatio-Temporal Multi-Agent Soft Actor–Critic (CaST-MASAC) framework. At its core, CaST-MASAC integrates two key innovations: (1) a spatio-temporal attention (STa) module that extracts features from historical observations to enable accurate target trajectory prediction and dynamic task assignment, thereby enhancing situational awareness and collaborative decision-making in highly dynamic and partially observable environments; and (2) a Causal Inference Experience Replay (CIER) mechanism that significantly improves sample efficiency and convergence speed by identifying and prioritizing experiences with a high causal impact on the task success. Evaluated in 4v4 and 2v2 multi-UAV aerial coordination simulation environments, CaST-MASAC demonstrates superior performance over state-of-the-art baselines such as MAPPO and QMIX in terms of task success rate, cumulative reward, and decision efficiency. Furthermore, extensive ablation studies validate the critical contributions of both the STa and CIER modules to the framework’s overall performance. Consequently, CaST-MASAC offers a novel and effective approach for developing robust and efficient multi-agent coordination strategies in complex dynamic environments. Full article

(This article belongs to the Special Issue Artificial Intelligence (AI) and Machine Learning (ML) in UAV Technology)

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16 pages, 8509 KB

Open AccessArticle

Selection and Optimization of Motor KV Values for Multi-Blade and High-Load Ratio UAVs

by Cong Huang, Huachun Wu, Yuzhe Xu and Qiang Li

Drones 2025, 9(9), 643; https://doi.org/10.3390/drones9090643 - 13 Sep 2025

Abstract

This paper proposes a method to enhance the load capacity and reduce the volume of an Unmanned Aerial Vehicle (UAV) by optimizing the motor’s KV value (a measure of RPM per volt) to match the specific aerodynamic characteristics of a multi-blade propeller system. [...] Read more.

This paper proposes a method to enhance the load capacity and reduce the volume of an Unmanned Aerial Vehicle (UAV) by optimizing the motor’s KV value (a measure of RPM per volt) to match the specific aerodynamic characteristics of a multi-blade propeller system. Given the fixed maximum output power of the motor when its volume and weight are determined, a higher-power-density motor structure can maximize blade lift by optimizing its output torque and speed. The electromagnetic structure of the motor is initially designed based on the aerodynamic characteristics of a 29-inch, four-blade model. Different motor Voltage-Turns (KV) value schemes are obtained by altering the number of winding turns and the wire diameter. Subsequently, the torque–speed output performance of the motor is calculated under constant power conditions. This data, in conjunction with the blade load, allow for a comparison of the motor’s output lift at different KV values. The optimal KV value for the motor is determined to be 116, resulting in a rated lift of 11.57 kg. This paper correctly analyzes the motor and blade as an integrated system, which is crucial for meaningful optimization in aerospace application. Full article

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33 pages, 22051 KB

Open AccessArticle

Gradient-Guided Search for Autonomous Contingency Landing Planning

by Huseyin Emre Tekaslan and Ella M. Atkins

Drones 2025, 9(9), 642; https://doi.org/10.3390/drones9090642 - 13 Sep 2025

Abstract

The growing reliance on autonomy in uncrewed aircraft systems (UASs) necessitates a real-time solution for assured contingency landing management during in-flight emergencies. This paper presents a novel gradient-guided search algorithm for risk-aware emergency landing trajectory generation with a wing-lift UAS loss-of-thrust use case. [...] Read more.

The growing reliance on autonomy in uncrewed aircraft systems (UASs) necessitates a real-time solution for assured contingency landing management during in-flight emergencies. This paper presents a novel gradient-guided search algorithm for risk-aware emergency landing trajectory generation with a wing-lift UAS loss-of-thrust use case. This framework integrates a compact four-dimensional discrete search space with aircraft kinematic and ground-risk cost. A multi-objective cost function is employed, combining flight envelope feasibility, optimal descent, and overflown population risk terms. To ensure discrete search convergence, a constrained hypervolume definition is introduced around the destination. A holding pattern identification algorithm is defined to minimize risk during the necessary flight path angle-constrained descent to final approach. Planner effectiveness is validated through randomly generated case studies over a region of Long Island, NY, under steady wind conditions. Benchmark comparisons with a 3D Dubins solver demonstrate the approach’s improved risk mitigation and acceptable real-time computation overhead. Future development will focus on integrating collision avoidance into the discrete search-based landing planner. Full article

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20 pages, 4263 KB

Open AccessArticle

Comparative Assessment of Remote and Proximal NDVI Sensing for Predicting Wheat Agronomic Traits

by Marko M. Kostić, Vladimir Aćin, Milan Mirosavljević, Zoran Stamenković, Krstan Kešelj, Nataša Ljubičić, Antonio Scarfone, Nikola Stanković and Danijela Bursać Kovačević

Drones 2025, 9(9), 641; https://doi.org/10.3390/drones9090641 - 13 Sep 2025

Abstract

Monitoring wheat traits across diverse environments requires reliable sensing tools that balance accuracy, cost, and scalability. This study compares the performance of proximal and UAV-derived NDVI sensing for predicting the key agronomic traits in winter wheat. The research was conducted at a long-term [...] Read more.

Monitoring wheat traits across diverse environments requires reliable sensing tools that balance accuracy, cost, and scalability. This study compares the performance of proximal and UAV-derived NDVI sensing for predicting the key agronomic traits in winter wheat. The research was conducted at a long-term NPK field experiment on Haplic Chernozem soils in Rimski Šančevi, Serbia, using UAV multispectral imagery and a handheld proximal sensor to collect NDVI data across 400 micro-plots and six phenological stages. The UAV-derived NDVI achieved a higher mean value (0.71 vs. 0.60), lower coefficient of variation (29.2% vs. 33.0%), and stronger correlation with the POM readings (R² = 0.92). For trait prediction, the UAV-based NDVI reached R² values up to 0.95 for grain yield and 0.84 for plant height, outperforming the POM (maximum R² = 0.94 and 0.83, respectively), and it showed superior temporal consistency (average R² = 0.74 vs. 0.64). Although the POM performed comparably during mid-season under controlled conditions, its sensitivity to operator handling and limited spatial resolution reduced robustness in more variable field scenarios. A cost–benefit analysis revealed that the POM offers advantages in affordability, ease of use, and deployment in small-scale settings, while UAV systems are better suited for large-scale monitoring due to their higher spatial resolution and data richness. The findings highlight the importance of selecting sensing technologies based on biological context, operational goals, and resource constraints, and suggest that combining methods through stratified sampling may improve the efficiency and accuracy of crop monitoring in precision agriculture. Full article

(This article belongs to the Special Issue Drones in Pest Management and Plant Disease Detecting: State of the Art, Achievements and Perspectives)

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