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1. Virtual Elastic Tether: a New Approach for Multi-agent Navigation in Confined Aquatic Environments

Author

Yao, Kanzhong, Cheng, Xueliang, Groves, Keir, Lennox, Barry, Marjanovic, Ognjen, and Watson, Simon

Subjects
Computer Science - Robotics, Electrical Engineering and Systems Science - Systems and Control
Abstract

Underwater navigation is a challenging area in the field of mobile robotics due to inherent constraints in self-localisation and communication in underwater environments. Some of these challenges can be mitigated by using collaborative multi-agent teams. However, when applied underwater, the robustness of traditional multi-agent collaborative control approaches is highly limited due to the unavailability of reliable measurements. In this paper, the concept of a Virtual Elastic Tether (VET) is introduced in the context of incomplete state measurements, which represents an innovative approach to underwater navigation in confined spaces. The concept of VET is formulated and validated using the Cooperative Aquatic Vehicle Exploration System (CAVES), which is a sim-to-real multi-agent aquatic robotic platform. Within this framework, a vision-based Autonomous Underwater Vehicle-Autonomous Surface Vehicle leader-follower formulation is developed. Experiments were conducted in both simulation and on a physical platform, benchmarked against a traditional Image-Based Visual Servoing approach. Results indicate that the formation of the baseline approach fails under discrete disturbances, when induced distances between the robots exceeds 0.6 m in simulation and 0.3 m in the real world. In contrast, the VET-enhanced system recovers to pre-perturbation distances within 5 seconds. Furthermore, results illustrate the successful navigation of VET-enhanced CAVES in a confined water pond where the baseline approach fails to perform adequately., Comment: This work has been submitted to the Wiley for possible publication

Published
2024

2. Collaborative Aquatic Positioning System Utilising Multi-beam Sonar and Depth Sensors

Author

Cheng, {Xueliang, Lennox, Barry, and Groves, Keir

Subjects
Computer Science - Robotics
Abstract

Accurate positioning of remotely operated underwater vehicles (ROVs) in confined environments is crucial for inspection and mapping tasks and is also a prerequisite for autonomous operations. Presently, there are no positioning systems available that are suited for real-world use in confined underwater environments, unconstrained by environmental lighting and water turbidity levels and have sufficient accuracy for long-term, reliable and repeatable navigation. This shortage presents a significant barrier to enhancing the capabilities of ROVs in such scenarios. This paper introduces an innovative positioning system for ROVs operating in confined, cluttered underwater settings, achieved through the collaboration of an omnidirectional surface vehicle and an ROV. A formulation is proposed and evaluated in the simulation against ground truth. The experimental results from the simulation form a proof of principle of the proposed system and also demonstrate its deployability. Unlike many previous approaches, the system does not rely on fixed infrastructure or tracking of features in the environment and can cover large enclosed areas without additional equipment., Comment: This work has been submitted to the IEEE for possible publication

Published
2024

3. Millimeter-Wave Sensing for Avoidance of High-Risk Ground Conditions for Mobile Robots

Author

Blanche, Jamie, Nandakumar, Shivoh Chirayil, Mitchell, Daniel, Harper, Sam, Groves, Keir, West, Andrew, Lennox, Barry, Watson, Simon, Flynn, David, and Yamamoto, Ikuo

Subjects
Computer Science - Robotics
Abstract

Mobile robot autonomy has made significant advances in recent years, with navigation algorithms well developed and used commercially in certain well-defined environments, such as warehouses. The common link in usage scenarios is that the environments in which the robots are utilized have a high degree of certainty. Operating environments are often designed to be robot friendly, for example augmented reality markers are strategically placed and the ground is typically smooth, level, and clear of debris. For robots to be useful in a wider range of environments, especially environments that are not sanitized for their use, robots must be able to handle uncertainty. This requires a robot to incorporate new sensors and sources of information, and to be able to use this information to make decisions regarding navigation and the overall mission. When using autonomous mobile robots in unstructured and poorly defined environments, such as a natural disaster site or in a rural environment, ground condition is of critical importance and is a common cause of failure. Examples include loss of traction due to high levels of ground water, hidden cavities, or material boundary failures. To evaluate a non-contact sensing method to mitigate these risks, Frequency Modulated Continuous Wave (FMCW) radar is integrated with an Unmanned Ground Vehicle (UGV), representing a novel application of FMCW to detect new measurands for Robotic Autonomous Systems (RAS) navigation, informing on terrain integrity and adding to the state-of-the-art in sensing for optimized autonomous path planning. In this paper, the FMCW is first evaluated in a desktop setting to determine its performance in anticipated ground conditions. The FMCW is then fixed to a UGV and the sensor system is tested and validated in a representative environment containing regions with significant levels of ground water saturation., Comment: 6 pages, 9 figures

Published
2022

4. MIRRAX: A Reconfigurable Robot for Limited Access Environments

Author

Cheah, Wei, Groves, Keir, Martin, Horatio, Peel, Harriet, Watson, Simon, Marjanovic, Ognjen, and Lennox, Barry

Subjects
Computer Science - Robotics
Abstract

The development of mobile robot platforms for inspection has gained traction in recent years with the rapid advancement in hardware and software. However, conventional mobile robots are unable to address the challenge of operating in extreme environments where the robot is required to traverse narrow gaps in highly cluttered areas with restricted access. This paper presents MIRRAX, a robot that has been designed to meet these challenges with the capability of re-configuring itself to both access restricted environments through narrow ports and navigate through tightly spaced obstacles. Controllers for the robot are detailed, along with an analysis on the controllability of the robot given the use of Mecanum wheels in a variable configuration. Characterisation on the robot's performance identified suitable configurations for operating in narrow environments. The minimum lateral footprint width achievable for stable configuration ($<2^\text{o}$~roll) was 0.19~m. Experimental validation of the robot's controllability shows good agreement with the theoretical analysis. A further series of experiments shows the feasibility of the robot in addressing the challenges above: the capability to reconfigure itself for restricted entry through ports as small as 150mm diameter, and navigating through cluttered environments. The paper also presents results from a deployment in a Magnox facility at the Sellafield nuclear site in the UK - the first robot to ever do so, for remote inspection and mapping., Comment: 12 pages, Accepted for IEEE Transactions on Robotics

Published
2022
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6. Federated Reinforcement Learning for Collective Navigation of Robotic Swarms

Author

Na, Seongin, Rouček, Tomáš, Ulrich, Jiří, Pikman, Jan, Krajník, Tomáš, Lennox, Barry, and Arvin, Farshad

Subjects
Computer Science - Robotics, Computer Science - Machine Learning
Abstract

The recent advancement of Deep Reinforcement Learning (DRL) contributed to robotics by allowing automatic controller design. The automatic controller design is a crucial approach for designing swarm robotic systems, which require more complex controllers than a single robot system to lead a desired collective behaviour. Although the DRL-based controller design method showed its effectiveness, the reliance on the central training server is a critical problem in real-world environments where robot-server communication is unstable or limited. We propose a novel Federated Learning (FL) based DRL training strategy (FLDDPG) for use in swarm robotic applications. Through the comparison with baseline strategies under a limited communication bandwidth scenario, it is shown that the FLDDPG method resulted in higher robustness and generalisation ability into a different environment and real robots, while the baseline strategies suffer from the limitation of communication bandwidth. This result suggests that the proposed method can benefit swarm robotic systems operating in environments with limited communication bandwidth, e.g., in high-radiation, underwater, or subterranean environments., Comment: 10 pages, 8 figures, submitted to IEEE Transactions on Cognitive and Developmental Systems Journal (R1)

Published
2022

7. Robust SLAM Systems: Are We There Yet?

Author

Bujanca, Mihai, Shi, Xuesong, Spear, Matthew, Zhao, Pengpeng, Lennox, Barry, and Lujan, Mikel

Subjects
Computer Science - Robotics
Abstract

Progress in the last decade has brought about significant improvements in the accuracy and speed of SLAM systems, broadening their mapping capabilities. Despite these advancements, long-term operation remains a major challenge, primarily due to the wide spectrum of perturbations robotic systems may encounter. Increasing the robustness of SLAM algorithms is an ongoing effort, however it usually addresses a specific perturbation. Generalisation of robustness across a large variety of challenging scenarios is not well-studied nor understood. This paper presents a systematic evaluation of the robustness of open-source state-of-the-art SLAM algorithms with respect to challenging conditions such as fast motion, non-uniform illumination, and dynamic scenes. The experiments are performed with perturbations present both independently of each other, as well as in combination in long-term deployment settings in unconstrained environments (lifelong operation)., Comment: IROS 2021

Published
2021

8. Accelerated Sim-to-Real Deep Reinforcement Learning: Learning Collision Avoidance from Human Player

Author

Niu, Hanlin, Ji, Ze, Arvin, Farshad, Lennox, Barry, Yin, Hujun, and Carrasco, Joaquin

Subjects
Computer Science - Artificial Intelligence, Computer Science - Robotics
Abstract

This paper presents a sensor-level mapless collision avoidance algorithm for use in mobile robots that map raw sensor data to linear and angular velocities and navigate in an unknown environment without a map. An efficient training strategy is proposed to allow a robot to learn from both human experience data and self-exploratory data. A game format simulation framework is designed to allow the human player to tele-operate the mobile robot to a goal and human action is also scored using the reward function. Both human player data and self-playing data are sampled using prioritized experience replay algorithm. The proposed algorithm and training strategy have been evaluated in two different experimental configurations: \textit{Environment 1}, a simulated cluttered environment, and \textit{Environment 2}, a simulated corridor environment, to investigate the performance. It was demonstrated that the proposed method achieved the same level of reward using only 16\% of the training steps required by the standard Deep Deterministic Policy Gradient (DDPG) method in Environment 1 and 20\% of that in Environment 2. In the evaluation of 20 random missions, the proposed method achieved no collision in less than 2~h and 2.5~h of training time in the two Gazebo environments respectively. The method also generated smoother trajectories than DDPG. The proposed method has also been implemented on a real robot in the real-world environment for performance evaluation. We can confirm that the trained model with the simulation software can be directly applied into the real-world scenario without further fine-tuning, further demonstrating its higher robustness than DDPG. The video and code are available: https://youtu.be/BmwxevgsdGc https://github.com/hanlinniu/turtlebot3_ddpg_collision_avoidance

Published
2021

9. Omnipotent Virtual Giant for Remote Human-Swarm Interaction

Author

Jang, Inmo, Hu, Junyan, Arvin, Farshad, Carrasco, Joaquin, and Lennox, Barry

Subjects
Computer Science - Robotics
Abstract

This paper proposes an intuitive human-swarm interaction framework inspired by our childhood memory in which we interacted with living ants by changing their positions and environments as if we were omnipotent relative to the ants. In virtual reality, analogously, we can be a super-powered virtual giant who can supervise a swarm of mobile robots in a vast and remote environment by flying over or resizing the world and coordinate them by picking and placing a robot or creating virtual walls. This work implements this idea by using Virtual Reality along with Leap Motion, which is then validated by proof-of-concept experiments using real and virtual mobile robots in mixed reality. We conduct a usability analysis to quantify the effectiveness of the overall system as well as the individual interfaces proposed in this work. The results revealed that the proposed method is intuitive and feasible for interaction with swarm robots, but may require appropriate training for the new end-user interface device., Comment: Submitted to IROS2019. The full demo video is available in https://youtu.be/LOIJPFM8YRA

Published
2019

11. Prediction of Fuel Debris Location in Fukushima Nuclear Power Plant using Machine Learning

Author

Alrawash Saed, Hale Matthew F., Lennox Barry, Joyce Malcolm J., West Andrew, Watanabe Minoru, Zhang Zhongming, and Aspinall Michael D.

Subjects
Physics, QC1-999
Abstract

Accurate fuel debris location is crucial part of the decommissioning of the Fukushima Nuclear Power plants. Conventional methods face challenges due to extreme radiation and complex structure of the materials involved. In this study, we propose a novel approach utilising neutron detection and machine learning to estimate fuel material location. Geant4 simulations and pythonTM scripts have been used to generate a comprehensive dataset to train a machine learning model using MATLAB’s regression learner. A Gaussian Process Regression model was chosen for training and prediction. The results show excellent prediction performance to estimate the corium thickness effectively and to locate the nuclear fuel material with a mean square error (MSE) of 0.01. By combining the machine learning with nuclear simulation codes, this promises to enhance the nuclear decommissioning efforts to retrieve nuclear fuel debris.

Published
2024
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19. Cover Image

Author

Mitchell, Daniel, primary, Emor Baniqued, Paul Dominick, additional, Zahid, Abdul, additional, West, Andrew, additional, Nouri Rahmat Abadi, Bahman, additional, Lennox, Barry, additional, Liu, Bin, additional, Kizilkaya, Burak, additional, Flynn, David, additional, Francis, David John, additional, Pulgarin, Erwin Jose Lopez, additional, Zhao, Guodong, additional, Kivrak, Hasan, additional, Blanche, Jamie Rowland Douglas, additional, David, Jennifer, additional, Wang, Jingyan, additional, Bolarinwa, Joseph, additional, Yao, Kanzhong, additional, Groves, Keir, additional, Qi, Liyuan, additional, Shawky, Mahmoud A., additional, Giuliani, Manuel, additional, Sandison, Melissa, additional, Popoola, Olaoluwa, additional, Marjanovic, Ognjen, additional, Bremner, Paul, additional, Harper, Samuel Thomas, additional, Nandakumar, Shivoh, additional, Watson, Simon, additional, Agrawal, Subham, additional, Lim, Theodore, additional, Johnson, Thomas, additional, Ahmad, Wasim, additional, Xu, Xiangmin, additional, Meng, Zhen, additional, and Jiang, Zhengyi, additional

Published
2023
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20. Lessons learned: Symbiotic autonomous robot ecosystem for nuclear environments

Author

Mitchell, Daniel, primary, Emor Baniqued, Paul Dominick, additional, Zahid, Abdul, additional, West, Andrew, additional, Nouri Rahmat Abadi, Bahman, additional, Lennox, Barry, additional, Liu, Bin, additional, Kizilkaya, Burak, additional, Flynn, David, additional, Francis, David John, additional, Pulgarin, Erwin Jose Lopez, additional, Zhao, Guodong, additional, Kivrak, Hasan, additional, Blanche, Jamie Rowland Douglas, additional, David, Jennifer, additional, Wang, Jingyan, additional, Bolarinwa, Joseph, additional, Yao, Kanzhong, additional, Groves, Keir, additional, Qi, Liyuan, additional, Shawky, Mahmoud A., additional, Giuliani, Manuel, additional, Sandison, Melissa, additional, Popoola, Olaoluwa, additional, Marjanovic, Ognjen, additional, Bremner, Paul, additional, Harper, Samuel Thomas, additional, Nandakumar, Shivoh, additional, Watson, Simon, additional, Agrawal, Subham, additional, Lim, Theodore, additional, Johnson, Thomas, additional, Ahmad, Wasim, additional, Xu, Xiangmin, additional, Meng, Zhen, additional, and Jiang, Zhengyi, additional

Published
2023
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22. Fast Collision-Free Multi-Vehicle Lane Change Motion Planning and Control Framework in Uncertain Environments

Author

Liu, Tianhao, Chai, Runqi, Chai, Senchun, Arvin, Farshad, Zhang, Jinning, and Lennox, Barry

Abstract

In this article, we focus on the design, test and validation of a hierarchical control framework capable of optimizing lane change trajectories and steering the motion of multiple automated guided vehicles (AGVs) in an uncertain environment. In the upper-level maneuver planning phase, a convex feasible set-based real-time optimization algorithm is adopted to plan the optimal motion trajectories for AGVs. The main novelty of this approach lies in its optimization process, where a sequence of convex feasible sets around the current solution is iteratively constructed such that the nonconvex collision avoidance constraints can be approximated. Subsequently, an improved sequential convex programming (SCP) algorithm is designed and applied to reshape the current maneuver trajectory in the preconstructed convex feasible sets and reduce the error caused by successive linearization of vehicle kinematics and constraints. The planned lane change trajectories are then provided to the lower-level motion controller, where a deep reinforcement learning (DRL)-based collision-free tracking control method is established and applied onboard to produce the control commands. This approach has the capability to deal with unexpected obstacles (e.g., those that suddenly appear around the vehicle). The proposed training method integrates a consensus algorithm with actor-critic deep reinforcement learning to allow multiagent training to achieve faster training speed and improved performance compared with single-agent training. The feasibility and effectiveness of the proposed design are verified by carrying out simulation case studies. Moreover, the validity of the designed hierarchical control framework is further confirmed by executing hardware-in-the-loop tests.

Published
2024
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32. CARMA II: A ground vehicle for autonomous surveying of alpha, beta and gamma radiation

Author

Groves, Keir, Nourirahmatabadi, Bahman, West, Andrew, Nancekievill, Matthew, Lennox, Barry, Marjanovic, Ognjen, and Ballard, Christopher

Subjects
Artificial Intelligence, Computer Science Applications
Abstract

Surveying active nuclear facilities for spread of alpha and beta contamination is currently performed by human operators. However, a skills gap of qualified workers is emerging and is set to worsen in the near future due to under recruitment, retirement and increased demand. This paper presents an autonomous ground vehicle that can survey nuclear facilities for alpha, beta and gamma radiation and generate radiation heatmaps. New methods for preventing the robot from spreading radioactive contamination using a state-machine and radiation costmaps are introduced. This is the first robot that can detect alpha and beta contamination and autonomously re-plan around the contamination without the wheels passing over the contaminated area. Radiation avoidance functionality is proven experimentally to reduce alpha and beta contamination spread as well as gamma radiation dose to the robot. The robot’s survey area is defined using a custom designed, graphically controlled area coverage planner. It was concluded that the robot is highly suited to certain monotonous room scale radiation surveying tasks and therefore provides the opportunity for financial savings, to mitigate a future skills gap, and provision of radiation surveys that are more granular, accurate and repeatable than those currently performed by human operators.

Published
2023

36. ACEFusion - Accelerated and Energy-Efficient Semantic 3D Reconstruction of Dynamic Scenes

Author

Bujanca, Mihai, Lennox, Barry, and Luján, Mikel

Abstract

ACEFusion is the first 3D reconstruction system able to capture the geometry and semantics of dynamic scenes using an RGB-D camera in real-time on a robotic computing platform. Harnessing the hardware accelerators of an Nvidia Jetson AGX Xavier, the system uses heterogeneous computing to achieve 30 FPS under a 30W power budget. Using a data-parallel design, we perform most image computation on the dedicated hardware accelerators, freeing the general purpose cores and GPU to process 3D geometry. To further increase efficiency, we employ a hybrid geometry representation with octrees for static-semantic reconstruction and surfels for dynamic reconstruction. ACEFusion achieves competitive results on standard benchmarks while efficiently performing a more complex overall task than existing SLAM techniques. Figure 1 shows the output of our system on a dynamic sequence.

Published
2022

37. Internal State-Based Risk Assessment for Robots in Hazardous Environment

Author

David, Jennifer, Bridgwater, Thomas, West, Andrew, Lennox, Barry, and Giuliani, Manuel

Abstract

Robots operating in a hazardous environment should be able to assess the risks involved before executing any given task. Though several risks can be considered in such a scenario, the risks based on environmental conditions are rarely explored. In this paper, we present a novel, risk-based navigation approach for robots in hazardous environments. We specifically investigate the environmental risks which can be measured and whose maximum state can be defined. These risks are integrated into the costmap of the robot to alter its traversability cost based on the robot’s current state. In doing so, the robot can adjust its path to account for hazards it has encountered on the fly. We term this approach as the Internal State-based Risk Assessment framework. We validate this framework using simulations where a robot must navigate through a nuclear environment whilst optimizing its path to avoid high radiation and high-temperature zones. We show that the robot can alter its path to account for the encountered hazards that have been mapped onto its internal state.

Published
2022

40. Real-Time Avoidance of Ionising Radiation Using Layered Costmaps for Mobile Robots

Author

West, Andrew, Wright, Thomas, Tsitsimpelis, Ioannis, Groves, Keir, Joyce, Malcolm J., Lennox, Barry, West, Andrew, Wright, Thomas, Tsitsimpelis, Ioannis, Groves, Keir, Joyce, Malcolm J., and Lennox, Barry

Abstract

Humans in hazardous environments take actions to reduce unnecessary risk, including limiting exposure to radioactive materials where ionising radiation can be a threat to human health. Robots can adopt the same approach of risk avoidance to minimise exposure to radiation, therefore limiting damage to electronics and materials. Reducing a robot’s exposure to radiation results in longer operational lifetime and better return on investment for nuclear sector stakeholders. This work achieves radiation avoidance through the use of layered costmaps, to inform path planning algorithms of this additional risk. Interpolation of radiation observations into the configuration space of the robot is accomplished using an inverse distance weighting approach. This technique was successfully demonstrated using an unmanned ground vehicle running the Robot Operating System equipped with compatible gamma radiation sensors, both in simulation and in real-world mock inspection missions, where the vehicle was exposed to radioactive materials in Lancaster University’s Neutron Laboratory. The addition of radiation avoidance functionality was shown to reduce total accumulated dose to background levels in real-world deployment and up to a factor of 10 in simulation.

Published
2022

41. Improved localization of radioactivity with a normalized sinc transform

Author

Tsitsimpelis, Ioannis, Alton, Tilly, West, A., Taylor, James, Livens, F. R., Lennox, Barry, Joyce, Malcolm, Tsitsimpelis, Ioannis, Alton, Tilly, West, A., Taylor, James, Livens, F. R., Lennox, Barry, and Joyce, Malcolm

Abstract

A technique for the in-situ localization of radioactivity is described in which the influence of gamma-radiation impinging on a high-Z collimator, by which the angular response of a scintillation detector is constrained in order to identify the position of the radiation source, is expressed mathematically by way of a normalized sinc transform. We test this approach by examining the utility of the sinc transform to express the angular responses derived from a slot-collimated cerium bromide detector, across a variety of energy regions. Individual spectra have been acquired as a function of angle to explore how the shape of the response of the collimator-detector arrangement changes for X-rays and gamma rays. A 90% improvement in localization is observed when defined in terms of the area described by the variance between the known location and that indicated by the response of the collimated system. This approach has the potential to improve source location accuracy and to further optimize autonomous robot exploration routines used to characterize contaminated environments associated with nuclear legacies and radiological emergencies.

Published
2022

49. Collaborative Coverage for a Network of Vacuum Cleaner Robots

Author

Hu, Junyan, Lennox, Barry, and Arvin, Farshad

Abstract

Coordination of mobile robot teams has attracted significant attention in the area of robotics research. As one of the most important techniques used in the multi-robot systems, coverage has shown great potential to be applied to many real-world applications. In this paper, we aim to provide a novel path planning method for multi-robot coverage with applications to cooperative autonomous vacuum cleaning. Some preliminary results are presented using an open-source simulator Webots, which lay the foundation for more in-depth theoretical analysis and practical implementation in the subsequent research.

Published
2021

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