Energy Sources of Mobile Robot Power Systems: A Systematic Review and Comparison of Efficiency

Mikołajczyk, Tadeusz; Mikołajewski, Dariusz; Kłodowski, Adam; Łukaszewicz, Andrzej; Mikołajewska, Emilia; Paczkowski, T.; Macko, Marek; Skornia, Marika

doi:10.3390/app13137547

Cited by 15 publications

(15 citation statements)

References 78 publications

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“…Detect and Avoid (DAA) technologies are key to unlocking commercially viable BVLOS operations, as they allow a safe and efficient integration into civilian airspace, by helping UAS to avoid collisions with other aircraft, buildings, and other obstacles. The growing number of UAS applications has made a necessity for sophisticated and highly dependable collision avoidance systems, as evident and incontestable from the public safety perspective [21]. Such systems are based on the use of sensors to detect and position obstacles to subsequently establish maneuvers to guarantee the safety of the aircraft.…”

Section: Detect and Avoid Technologiesmentioning

confidence: 99%

Enabling Technologies for the Navigation and Communication of UAS Operating in the Context of BVLOS

Politi,

Purucker,

Larsen

et al. 2024

Electronics

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Unmanned Aerial Systems (UAS) have rapidly gained attraction in recent years as a promising solution to revolutionize numerous applications and meet the growing demand for efficient and timely delivery services due to their highly automated operation framework. Beyond Visual Line of Sight (BVLOS) operations, in particular, offer new means of delivering added-value services via a wide range of applications. This "plateau of productivity" holds enormous promise, but it is challenging to equip the drone with affordable technologies which support the BVLOS use case. To close this gap, this work showcases the convergence of the automotive and aviation industries to advance BVLOS aviation for UAS in a practical setting by studying a combination of Commercial Off-The-Shelf (COTS) technologies and systems. A novel risk-based approach of investigating the key technological components, architectures, algorithms, and protocols is proposed that facilitate highly reliable and autonomous BVLOS operations, aiming to enhance the alignment between market and operational needs and to better identify integration requirements between the different capabilities to be developed.

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Section: Detect and Avoid Technologiesmentioning

confidence: 99%

Enabling Technologies for the Navigation and Communication of UAS Operating in the Context of BVLOS

Politi,

Purucker,

Larsen

et al. 2024

Electronics

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“…These planners [3][4][5] allow robots to make decisions about how they move from one location to another. This requires the use of route planning algorithms based on several criteria: requirements imposed by users [6][7][8], the multitude of obstacles that may appear (static or dynamic) [9][10][11][12], the energy resources available [13,14], the on-board capabilities for processing sensor data [15,16], and the communication system [17,18].…”

Section: Introductionmentioning

confidence: 99%

Optimizing an Autonomous Robot’s Path to Increase Movement Speed

Gorgoteanu,

Molder,

Popescu

et al. 2024

Electronics

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The goal of this study is to address the challenges associated with identifying and planning a mobile land robot’s path to optimize its speed in a stationary environment. Our focus was on devising routes that navigate around obstacles in various spatial arrangements. To achieve this, we employed MATLAB R2023b for trajectory simulation and optimization. On-board data processing was conducted, while obstacle detection relied on the omnidirectional video processing system integrated into the robot. Odometry was facilitated by engine encoders and optical flow sensors. Additionally, an external video system was utilized to verify the experimental data pertaining to the robot’s movement. Last but not least, the algorithms and hardware equipment used enabled the robot to go along the path at greater speeds. Limiting the amount of time and energy required to travel allowed us to avoid obstacles.

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“…UAVs can access risky or inaccessible locations without risking human lives. Therefore UAVs should be built to operate independently and avoid crashing into anything while in flight [ 15 ]. Precision agriculture is an application of UAVs that has been increasing rapidly worldwide.…”

Section: Introductionmentioning

confidence: 99%

“…Figure 1 shows the basic architecture of an anti-collision system that will be implemented in a vehicle. Anti-collision systems consist of two major parts: the input and output [ 15 ]. These parts can also be recognized as perspective and action.…”

Section: Introductionmentioning

confidence: 99%

Review on Type of Sensors and Detection Method of Anti-Collision System of Unmanned Aerial Vehicle

Chandran,

Sultan,

Łukaszewicz

et al. 2023

Sensors

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Unmanned aerial vehicle (UAV) usage is increasing drastically worldwide as UAVs are used in various industries for many applications, such as inspection, logistics, agriculture, and many more. This is because performing a task using UAV makes the job more efficient and reduces the workload needed. However, for a UAV to be operated manually or autonomously, the UAV must be equipped with proper safety features. An anti-collision system is one of the most crucial and fundamental safety features that UAVs must be equipped with. The anti-collision system allows the UAV to maintain a safe distance from any obstacles. The anti-collision technologies are of crucial relevance to assure the survival and safety of UAVs. Anti-collision of UAVs can be varied in the aspect of sensor usage and the system’s working principle. This article provides a comprehensive overview of anti-collision technologies for UAVs. It also presents drone safety laws and regulations that prevent a collision at the policy level. The process of anti-collision technologies is studied from three aspects: Obstacle detection, collision prediction, and collision avoidance. A detailed overview and comparison of the methods of each element and an analysis of their advantages and disadvantages have been provided. In addition, the future trends of UAV anti-collision technologies from the viewpoint of fast obstacle detection and wireless networking are presented.

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Energy Sources of Mobile Robot Power Systems: A Systematic Review and Comparison of Efficiency

Cited by 15 publications

References 78 publications

Enabling Technologies for the Navigation and Communication of UAS Operating in the Context of BVLOS

Enabling Technologies for the Navigation and Communication of UAS Operating in the Context of BVLOS

Optimizing an Autonomous Robot’s Path to Increase Movement Speed

Review on Type of Sensors and Detection Method of Anti-Collision System of Unmanned Aerial Vehicle

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