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1. Seeing Through Pixel Motion: Learning Obstacle Avoidance from Optical Flow with One Camera

Author

Hu, Yu, Zhang, Yuang, Song, Yunlong, Deng, Yang, Yu, Feng, Zhang, Linzuo, Lin, Weiyao, Zou, Danping, and Yu, Wenxian

Subjects
Computer Science - Robotics
Abstract

Optical flow captures the motion of pixels in an image sequence over time, providing information about movement, depth, and environmental structure. Flying insects utilize this information to navigate and avoid obstacles, allowing them to execute highly agile maneuvers even in complex environments. Despite its potential, autonomous flying robots have yet to fully leverage this motion information to achieve comparable levels of agility and robustness. Challenges of control from optical flow include extracting accurate optical flow at high speeds, handling noisy estimation, and ensuring robust performance in complex environments. To address these challenges, we propose a novel end-to-end system for quadrotor obstacle avoidance using monocular optical flow. We develop an efficient differentiable simulator coupled with a simplified quadrotor model, allowing our policy to be trained directly through first-order gradient optimization. Additionally, we introduce a central flow attention mechanism and an action-guided active sensing strategy that enhances the policy's focus on task-relevant optical flow observations to enable more responsive decision-making during flight. Our system is validated both in simulation and the real world using an FPV racing drone. Despite being trained in a simple environment in simulation, our system is validated both in simulation and the real world using an FPV racing drone. Despite being trained in a simple environment in simulation, our system demonstrates agile and robust flight in various unknown, cluttered environments in the real world at speeds of up to 6m/s.

Published
2024

2. Learning Quadrotor Control From Visual Features Using Differentiable Simulation

Author

Heeg, Johannes, Song, Yunlong, and Scaramuzza, Davide

Subjects
Computer Science - Robotics
Abstract

The sample inefficiency of reinforcement learning (RL) remains a significant challenge in robotics. RL requires large-scale simulation and, still, can cause long training times, slowing down research and innovation. This issue is particularly pronounced in vision-based control tasks where reliable state estimates are not accessible. Differentiable simulation offers an alternative by enabling gradient back-propagation through the dynamics model, providing low-variance analytical policy gradients and, hence, higher sample efficiency. However, its usage for real-world robotic tasks has yet been limited. This work demonstrates the great potential of differentiable simulation for learning quadrotor control. We show that training in differentiable simulation significantly outperforms model-free RL in terms of both sample efficiency and training time, allowing a policy to learn to recover a quadrotor in seconds when providing vehicle state and in minutes when relying solely on visual features. The key to our success is two-fold. First, the use of a simple surrogate model for gradient computation greatly accelerates training without sacrificing control performance. Second, combining state representation learning with policy learning enhances convergence speed in tasks where only visual features are observable. These findings highlight the potential of differentiable simulation for real-world robotics and offer a compelling alternative to conventional RL approaches., Comment: Under Submission

Published
2024

3. Residual Policy Learning for Perceptive Quadruped Control Using Differentiable Simulation

Author

Luo, Jing Yuan, Song, Yunlong, Klemm, Victor, Shi, Fan, Scaramuzza, Davide, and Hutter, Marco

Subjects
Computer Science - Robotics
Abstract

First-order Policy Gradient (FoPG) algorithms such as Backpropagation through Time and Analytical Policy Gradients leverage local simulation physics to accelerate policy search, significantly improving sample efficiency in robot control compared to standard model-free reinforcement learning. However, FoPG algorithms can exhibit poor learning dynamics in contact-rich tasks like locomotion. Previous approaches address this issue by alleviating contact dynamics via algorithmic or simulation innovations. In contrast, we propose guiding the policy search by learning a residual over a simple baseline policy. For quadruped locomotion, we find that the role of residual policy learning in FoPG-based training (FoPG RPL) is primarily to improve asymptotic rewards, compared to improving sample efficiency for model-free RL. Additionally, we provide insights on applying FoPG's to pixel-based local navigation, training a point-mass robot to convergence within seconds. Finally, we showcase the versatility of FoPG RPL by using it to train locomotion and perceptive navigation end-to-end on a quadruped in minutes.

Published
2024

4. Back to Newton's Laws: Learning Vision-based Agile Flight via Differentiable Physics

Author

Zhang, Yuang, Hu, Yu, Song, Yunlong, Zou, Danping, and Lin, Weiyao

Subjects
Computer Science - Robotics
Abstract

Swarm navigation in cluttered environments is a grand challenge in robotics. This work combines deep learning with first-principle physics through differentiable simulation to enable autonomous navigation of multiple aerial robots through complex environments at high speed. Our approach optimizes a neural network control policy directly by backpropagating loss gradients through the robot simulation using a simple point-mass physics model and a depth rendering engine. Despite this simplicity, our method excels in challenging tasks for both multi-agent and single-agent applications with zero-shot sim-to-real transfer. In multi-agent scenarios, our system demonstrates self-organized behavior, enabling autonomous coordination without communication or centralized planning - an achievement not seen in existing traditional or learning-based methods. In single-agent scenarios, our system achieves a 90% success rate in navigating through complex environments, significantly surpassing the 60% success rate of the previous state-of-the-art approach. Our system can operate without state estimation and adapt to dynamic obstacles. In real-world forest environments, it navigates at speeds up to 20 m/s, doubling the speed of previous imitation learning-based solutions. Notably, all these capabilities are deployed on a budget-friendly $21 computer, costing less than 5% of a GPU-equipped board used in existing systems. Video demonstrations are available at https://youtu.be/LKg9hJqc2cc.

Published
2024

5. Agile Robotics: Optimal Control, Reinforcement Learning, and Differentiable Simulation

Author

Song, Yunlong and Scaramuzza, Davide

Subjects
Computer Science - Robotics
Abstract

Control systems are at the core of every real-world robot. They are deployed in an ever-increasing number of applications, ranging from autonomous racing and search-and-rescue missions to industrial inspections and space exploration. To achieve peak performance, certain tasks require pushing the robot to its maximum agility. How can we design control algorithms that enhance the agility of autonomous robots and maintain robustness against unforeseen disturbances? This paper addresses this question by leveraging fundamental principles in optimal control, reinforcement learning, and differentiable simulation., Comment: This abstract has been accepted for the Robotics: Science and Systems (RSS) Pioneers Workshop, 2024

Published
2024

6. Learning Quadruped Locomotion Using Differentiable Simulation

Author

Song, Yunlong, Kim, Sangbae, and Scaramuzza, Davide

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

This work explores the potential of using differentiable simulation for learning quadruped locomotion. Differentiable simulation promises fast convergence and stable training by computing low-variance first-order gradients using robot dynamics. However, its usage for legged robots is still limited to simulation. The main challenge lies in the complex optimization landscape of robotic tasks due to discontinuous dynamics. This work proposes a new differentiable simulation framework to overcome these challenges. Our approach combines a high-fidelity, non-differentiable simulator for forward dynamics with a simplified surrogate model for gradient backpropagation. This approach maintains simulation accuracy by aligning the robot states from the surrogate model with those of the precise, non-differentiable simulator. Our framework enables learning quadruped walking in simulation in minutes without parallelization. When augmented with GPU parallelization, our approach allows the quadruped robot to master diverse locomotion skills on challenging terrains in minutes. We demonstrate that differentiable simulation outperforms a reinforcement learning algorithm (PPO) by achieving significantly better sample efficiency while maintaining its effectiveness in handling large-scale environments. Our method represents one of the first successful applications of differentiable simulation to real-world quadruped locomotion, offering a compelling alternative to traditional RL methods., Comment: 8th Annual Conference on Robot Learning (CoRL)

Published
2024

7. Flymation: Interactive Animation for Flying Robots

Author

Song, Yunlong and Scaramuzza, Davide

Subjects
Computer Science - Robotics
Abstract

Trajectory visualization and animation play critical roles in robotics research. However, existing data visualization and animation tools often lack flexibility, scalability, and versatility, resulting in limited capability to fully explore and analyze flight data. To address this limitation, we introduce Flymation, a new flight trajectory visualization and animation tool. Built on the Unity3D engine, Flymation is an intuitive and interactive tool that allows users to visualize and analyze flight data in real time. Users can import data from various sources, including flight simulators and real-world data, and create customized visualizations with high-quality rendering. With Flymation, users can choose between trajectory snapshot and animation; both provide valuable insights into the behavior of the underlying autonomous system. Flymation represents an exciting step toward visualizing and interacting with large-scale data in robotics research., Comment: This work was presented at Workshop at ICRA 2023 ( The Role of Robotics Simulators for Unmanned Aerial Vehicles)

Published
2023

8. Reaching the Limit in Autonomous Racing: Optimal Control versus Reinforcement Learning

Author

Song, Yunlong, Romero, Angel, Mueller, Matthias, Koltun, Vladlen, and Scaramuzza, Davide

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

A central question in robotics is how to design a control system for an agile mobile robot. This paper studies this question systematically, focusing on a challenging setting: autonomous drone racing. We show that a neural network controller trained with reinforcement learning (RL) outperformed optimal control (OC) methods in this setting. We then investigated which fundamental factors have contributed to the success of RL or have limited OC. Our study indicates that the fundamental advantage of RL over OC is not that it optimizes its objective better but that it optimizes a better objective. OC decomposes the problem into planning and control with an explicit intermediate representation, such as a trajectory, that serves as an interface. This decomposition limits the range of behaviors that can be expressed by the controller, leading to inferior control performance when facing unmodeled effects. In contrast, RL can directly optimize a task-level objective and can leverage domain randomization to cope with model uncertainty, allowing the discovery of more robust control responses. Our findings allowed us to push an agile drone to its maximum performance, achieving a peak acceleration greater than 12 times the gravitational acceleration and a peak velocity of 108 kilometers per hour. Our policy achieved superhuman control within minutes of training on a standard workstation. This work presents a milestone in agile robotics and sheds light on the role of RL and OC in robot control.

Published
2023
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9. Learning to Walk and Fly with Adversarial Motion Priors

Author

L'Erario, Giuseppe, Hanover, Drew, Romero, Angel, Song, Yunlong, Nava, Gabriele, Viceconte, Paolo Maria, Pucci, Daniele, and Scaramuzza, Davide

Subjects
Computer Science - Robotics
Abstract

Robot multimodal locomotion encompasses the ability to transition between walking and flying, representing a significant challenge in robotics. This work presents an approach that enables automatic smooth transitions between legged and aerial locomotion. Leveraging the concept of Adversarial Motion Priors, our method allows the robot to imitate motion datasets and accomplish the desired task without the need for complex reward functions. The robot learns walking patterns from human-like gaits and aerial locomotion patterns from motions obtained using trajectory optimization. Through this process, the robot adapts the locomotion scheme based on environmental feedback using reinforcement learning, with the spontaneous emergence of mode-switching behavior. The results highlight the potential for achieving multimodal locomotion in aerial humanoid robotics through automatic control of walking and flying modes, paving the way for applications in diverse domains such as search and rescue, surveillance, and exploration missions. This research contributes to advancing the capabilities of aerial humanoid robots in terms of versatile locomotion in various environments., Comment: This paper has been accepted for publication at the IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), Abu Dhabi, 2024

Published
2023

10. Contrastive Learning for Enhancing Robust Scene Transfer in Vision-based Agile Flight

Author

Xing, Jiaxu, Bauersfeld, Leonard, Song, Yunlong, Xing, Chunwei, and Scaramuzza, Davide

Subjects
Computer Science - Robotics, Computer Science - Computer Vision and Pattern Recognition
Abstract

Scene transfer for vision-based mobile robotics applications is a highly relevant and challenging problem. The utility of a robot greatly depends on its ability to perform a task in the real world, outside of a well-controlled lab environment. Existing scene transfer end-to-end policy learning approaches often suffer from poor sample efficiency or limited generalization capabilities, making them unsuitable for mobile robotics applications. This work proposes an adaptive multi-pair contrastive learning strategy for visual representation learning that enables zero-shot scene transfer and real-world deployment. Control policies relying on the embedding are able to operate in unseen environments without the need for finetuning in the deployment environment. We demonstrate the performance of our approach on the task of agile, vision-based quadrotor flight. Extensive simulation and real-world experiments demonstrate that our approach successfully generalizes beyond the training domain and outperforms all baselines.

Published
2023

11. Contrastive Initial State Buffer for Reinforcement Learning

Author

Messikommer, Nico, Song, Yunlong, and Scaramuzza, Davide

Subjects
Computer Science - Machine Learning
Abstract

In Reinforcement Learning, the trade-off between exploration and exploitation poses a complex challenge for achieving efficient learning from limited samples. While recent works have been effective in leveraging past experiences for policy updates, they often overlook the potential of reusing past experiences for data collection. Independent of the underlying RL algorithm, we introduce the concept of a Contrastive Initial State Buffer, which strategically selects states from past experiences and uses them to initialize the agent in the environment in order to guide it toward more informative states. We validate our approach on two complex robotic tasks without relying on any prior information about the environment: (i) locomotion of a quadruped robot traversing challenging terrains and (ii) a quadcopter drone racing through a track. The experimental results show that our initial state buffer achieves higher task performance than the nominal baseline while also speeding up training convergence.

Published
2023

12. Agilicious: Open-Source and Open-Hardware Agile Quadrotor for Vision-Based Flight

Author

Foehn, Philipp, Kaufmann, Elia, Romero, Angel, Penicka, Robert, Sun, Sihao, Bauersfeld, Leonard, Laengle, Thomas, Cioffi, Giovanni, Song, Yunlong, Loquercio, Antonio, and Scaramuzza, Davide

Subjects
Computer Science - Robotics
Abstract

Autonomous, agile quadrotor flight raises fundamental challenges for robotics research in terms of perception, planning, learning, and control. A versatile and standardized platform is needed to accelerate research and let practitioners focus on the core problems. To this end, we present Agilicious, a co-designed hardware and software framework tailored to autonomous, agile quadrotor flight. It is completely open-source and open-hardware and supports both model-based and neural-network--based controllers. Also, it provides high thrust-to-weight and torque-to-inertia ratios for agility, onboard vision sensors, GPU-accelerated compute hardware for real-time perception and neural-network inference, a real-time flight controller, and a versatile software stack. In contrast to existing frameworks, Agilicious offers a unique combination of flexible software stack and high-performance hardware. We compare Agilicious with prior works and demonstrate it on different agile tasks, using both model-based and neural-network--based controllers. Our demonstrators include trajectory tracking at up to 5g and 70 km/h in a motion-capture system, and vision-based acrobatic flight and obstacle avoidance in both structured and unstructured environments using solely onboard perception. Finally, we demonstrate its use for hardware-in-the-loop simulation in virtual-reality environments. Thanks to its versatility, we believe that Agilicious supports the next generation of scientific and industrial quadrotor research., Comment: 14 pages, 5 figures, 2 tables

Published
2023
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13. Actor-Critic Model Predictive Control

Author

Romero, Angel, Song, Yunlong, and Scaramuzza, Davide

Subjects
Computer Science - Robotics
Abstract

An open research question in robotics is how to combine the benefits of model-free reinforcement learning (RL) - known for its strong task performance and flexibility in optimizing general reward formulations - with the robustness and online replanning capabilities of model predictive control (MPC). This paper provides an answer by introducing a new framework called Actor-Critic Model Predictive Control. The key idea is to embed a differentiable MPC within an actor-critic RL framework. The proposed approach leverages the short-term predictive optimization capabilities of MPC with the exploratory and end-to-end training properties of RL. The resulting policy effectively manages both short-term decisions through the MPC-based actor and long-term prediction via the critic network, unifying the benefits of both model-based control and end-to-end learning. We validate our method in both simulation and the real world with a quadcopter platform across various high-level tasks. We show that the proposed architecture can achieve real-time control performance, learn complex behaviors via trial and error, and retain the predictive properties of the MPC to better handle out of distribution behaviour., Comment: 6 pages, 5 figures

Published
2023

14. Autonomous Drone Racing: A Survey

Author

Hanover, Drew, Loquercio, Antonio, Bauersfeld, Leonard, Romero, Angel, Penicka, Robert, Song, Yunlong, Cioffi, Giovanni, Kaufmann, Elia, and Scaramuzza, Davide

Subjects
Computer Science - Robotics
Abstract

Over the last decade, the use of autonomous drone systems for surveying, search and rescue, or last-mile delivery has increased exponentially. With the rise of these applications comes the need for highly robust, safety-critical algorithms which can operate drones in complex and uncertain environments. Additionally, flying fast enables drones to cover more ground which in turn increases productivity and further strengthens their use case. One proxy for developing algorithms used in high-speed navigation is the task of autonomous drone racing, where researchers program drones to fly through a sequence of gates and avoid obstacles as quickly as possible using onboard sensors and limited computational power. Speeds and accelerations exceed over 80 kph and 4 g respectively, raising significant challenges across perception, planning, control, and state estimation. To achieve maximum performance, systems require real-time algorithms that are robust to motion blur, high dynamic range, model uncertainties, aerodynamic disturbances, and often unpredictable opponents. This survey covers the progression of autonomous drone racing across model-based and learning-based approaches. We provide an overview of the field, its evolution over the years, and conclude with the biggest challenges and open questions to be faced in the future., Comment: 26 pages

Published
2023
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16. Learning Deep Sensorimotor Policies for Vision-based Autonomous Drone Racing

Author

Fu, Jiawei, Song, Yunlong, Wu, Yan, Yu, Fisher, and Scaramuzza, Davide

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

Autonomous drones can operate in remote and unstructured environments, enabling various real-world applications. However, the lack of effective vision-based algorithms has been a stumbling block to achieving this goal. Existing systems often require hand-engineered components for state estimation, planning, and control. Such a sequential design involves laborious tuning, human heuristics, and compounding delays and errors. This paper tackles the vision-based autonomous-drone-racing problem by learning deep sensorimotor policies. We use contrastive learning to extract robust feature representations from the input images and leverage a two-stage learning-by-cheating framework for training a neural network policy. The resulting policy directly infers control commands with feature representations learned from raw images, forgoing the need for globally-consistent state estimation, trajectory planning, and handcrafted control design. Our experimental results indicate that our vision-based policy can achieve the same level of racing performance as the state-based policy while being robust against different visual disturbances and distractors. We believe this work serves as a stepping-stone toward developing intelligent vision-based autonomous systems that control the drone purely from image inputs, like human pilots.

Published
2022

17. Weighted Maximum Likelihood for Controller Tuning

Author

Romero, Angel, Govil, Shreedhar, Yilmaz, Gonca, Song, Yunlong, and Scaramuzza, Davide

Subjects
Computer Science - Robotics
Abstract

Recently, Model Predictive Contouring Control (MPCC) has arisen as the state-of-the-art approach for model-based agile flight. MPCC benefits from great flexibility in trading-off between progress maximization and path following at runtime without relying on globally optimized trajectories. However, finding the optimal set of tuning parameters for MPCC is challenging because (i) the full quadrotor dynamics are non-linear, (ii) the cost function is highly non-convex, and (iii) of the high dimensionality of the hyperparameter space. This paper leverages a probabilistic Policy Search method - Weighted Maximum Likelihood (WML)- to automatically learn the optimal objective for MPCC. WML is sample-efficient due to its closed-form solution for updating the learning parameters. Additionally, the data efficiency provided by the use of a model-based approach allows us to directly train in a high-fidelity simulator, which in turn makes our approach able to transfer zero-shot to the real world. We validate our approach in the real world, where we show that our method outperforms both the previous manually tuned controller and the state-of-the-art auto-tuning baseline reaching speeds of 75 km/h., Comment: 8 pages

Published
2022

18. Learning Perception-Aware Agile Flight in Cluttered Environments

Author

Song, Yunlong, Shi, Kexin, Penicka, Robert, and Scaramuzza, Davide

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

Recently, neural control policies have outperformed existing model-based planning-and-control methods for autonomously navigating quadrotors through cluttered environments in minimum time. However, they are not perception aware, a crucial requirement in vision-based navigation due to the camera's limited field of view and the underactuated nature of a quadrotor. We propose a learning-based system that achieves perception-aware, agile flight in cluttered environments. Our method combines imitation learning with reinforcement learning (RL) by leveraging a privileged learning-by-cheating framework. Using RL, we first train a perception-aware teacher policy with full-state information to fly in minimum time through cluttered environments. Then, we use imitation learning to distill its knowledge into a vision-based student policy that only perceives the environment via a camera. Our approach tightly couples perception and control, showing a significant advantage in computation speed (10 times faster) and success rate. We demonstrate the closed-loop control performance using hardware-in-the-loop simulation.

Published
2022

19. Autonomous Ground Navigation in Highly Constrained Spaces: Lessons learned from The BARN Challenge at ICRA 2022

Author

Xiao, Xuesu, Xu, Zifan, Wang, Zizhao, Song, Yunlong, Warnell, Garrett, Stone, Peter, Zhang, Tingnan, Ravi, Shravan, Wang, Gary, Karnan, Haresh, Biswas, Joydeep, Mohammad, Nicholas, Bramblett, Lauren, Peddi, Rahul, Bezzo, Nicola, Xie, Zhanteng, and Dames, Philip

Subjects
Computer Science - Robotics
Abstract

The BARN (Benchmark Autonomous Robot Navigation) Challenge took place at the 2022 IEEE International Conference on Robotics and Automation (ICRA 2022) in Philadelphia, PA. The aim of the challenge was to evaluate state-of-the-art autonomous ground navigation systems for moving robots through highly constrained environments in a safe and efficient manner. Specifically, the task was to navigate a standardized, differential-drive ground robot from a predefined start location to a goal location as quickly as possible without colliding with any obstacles, both in simulation and in the real world. Five teams from all over the world participated in the qualifying simulation competition, three of which were invited to compete with each other at a set of physical obstacle courses at the conference center in Philadelphia. The competition results suggest that autonomous ground navigation in highly constrained spaces, despite seeming ostensibly simple even for experienced roboticists, is actually far from being a solved problem. In this article, we discuss the challenge, the approaches used by the top three winning teams, and lessons learned to direct future research.

Published
2022

20. Learning Minimum-Time Flight in Cluttered Environments

Author

Penicka, Robert, Song, Yunlong, Kaufmann, Elia, and Scaramuzza, Davide

Subjects
Computer Science - Robotics
Abstract

We tackle the problem of minimum-time flight for a quadrotor through a sequence of waypoints in the presence of obstacles while exploiting the full quadrotor dynamics. Early works relied on simplified dynamics or polynomial trajectory representations that did not exploit the full actuator potential of the quadrotor, and, thus, resulted in suboptimal solutions. Recent works can plan minimum-time trajectories; yet, the trajectories are executed with control methods that do not account for obstacles. Thus, a successful execution of such trajectories is prone to errors due to model mismatch and in-flight disturbances. To this end, we leverage deep reinforcement learning and classical topological path planning to train robust neural-network controllers for minimum-time quadrotor flight in cluttered environments. The resulting neural network controller demonstrates substantially better performance of up to 19\% over state-of-the-art methods. More importantly, the learned policy solves the planning and control problem simultaneously online to account for disturbances, thus achieving much higher robustness. As such, the presented method achieves 100% success rate of flying minimum-time policies without collision, while traditional planning and control approaches achieve only 40%. The proposed method is validated in both simulation and the real world, with quadrotor speeds of up to 42km/h and accelerations of 3.6g.

Published
2022
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24. Policy Search for Model Predictive Control with Application to Agile Drone Flight

Author

Song, Yunlong and Scaramuzza, Davide

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

Policy Search and Model Predictive Control~(MPC) are two different paradigms for robot control: policy search has the strength of automatically learning complex policies using experienced data, while MPC can offer optimal control performance using models and trajectory optimization. An open research question is how to leverage and combine the advantages of both approaches. In this work, we provide an answer by using policy search for automatically choosing high-level decision variables for MPC, which leads to a novel policy-search-for-model-predictive-control framework. Specifically, we formulate the MPC as a parameterized controller, where the hard-to-optimize decision variables are represented as high-level policies. Such a formulation allows optimizing policies in a self-supervised fashion. We validate this framework by focusing on a challenging problem in agile drone flight: flying a quadrotor through fast-moving gates. Experiments show that our controller achieves robust and real-time control performance in both simulation and the real world. The proposed framework offers a new perspective for merging learning and control., Comment: The paper has been accepted for publication in the IEEE Transactions on Robotics (T-RO), 2021

Published
2021

27. Autonomous Overtaking in Gran Turismo Sport Using Curriculum Reinforcement Learning

Author

Song, Yunlong, Lin, HaoChih, Kaufmann, Elia, Duerr, Peter, and Scaramuzza, Davide

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

Professional race-car drivers can execute extreme overtaking maneuvers. However, existing algorithms for autonomous overtaking either rely on simplified assumptions about the vehicle dynamics or try to solve expensive trajectory-optimization problems online. When the vehicle approaches its physical limits, existing model-based controllers struggle to handle highly nonlinear dynamics, and cannot leverage the large volume of data generated by simulation or real-world driving. To circumvent these limitations, we propose a new learning-based method to tackle the autonomous overtaking problem. We evaluate our approach in the popular car racing game Gran Turismo Sport, which is known for its detailed modeling of various cars and tracks. By leveraging curriculum learning, our approach leads to faster convergence as well as increased performance compared to vanilla reinforcement learning. As a result, the trained controller outperforms the built-in model-based game AI and achieves comparable overtaking performance with an experienced human driver., Comment: Accepted for publication at the IEEE International Conference on Robotics and Automation (ICRA), Xi An, 2021

Published
2021

28. Autonomous Drone Racing with Deep Reinforcement Learning

Author

Song, Yunlong, Steinweg, Mats, Kaufmann, Elia, and Scaramuzza, Davide

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

In many robotic tasks, such as autonomous drone racing, the goal is to travel through a set of waypoints as fast as possible. A key challenge for this task is planning the time-optimal trajectory, which is typically solved by assuming perfect knowledge of the waypoints to pass in advance. The resulting solution is either highly specialized for a single-track layout, or suboptimal due to simplifying assumptions about the platform dynamics. In this work, a new approach to near-time-optimal trajectory generation for quadrotors is presented. Leveraging deep reinforcement learning and relative gate observations, our approach can compute near-time-optimal trajectories and adapt the trajectory to environment changes. Our method exhibits computational advantages over approaches based on trajectory optimization for non-trivial track configurations. The proposed approach is evaluated on a set of race tracks in simulation and the real world, achieving speeds of up to 60 km/h with a physical quadrotor., Comment: This paper has been accepted for publication at the IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), Prague, 2021. Copyright @ IEEE

Published
2021

29. Flightmare: A Flexible Quadrotor Simulator

Author

Song, Yunlong, Naji, Selim, Kaufmann, Elia, Loquercio, Antonio, and Scaramuzza, Davide

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

State-of-the-art quadrotor simulators have a rigid and highly-specialized structure: either are they really fast, physically accurate, or photo-realistic. In this work, we propose a novel quadrotor simulator: Flightmare. Flightmare is composed of two main components: a configurable rendering engine built on Unity and a flexible physics engine for dynamics simulation. Those two components are totally decoupled and can run independently of each other. This makes our simulator extremely fast: rendering achieves speeds of up to 230 Hz, while physics simulation of up to 200,000 Hz on a laptop. In addition, Flightmare comes with several desirable features: (i) a large multi-modal sensor suite, including an interface to extract the 3D point-cloud of the scene; (ii) an API for reinforcement learning which can simulate hundreds of quadrotors in parallel; and (iii) integration with a virtual-reality headset for interaction with the simulated environment. We demonstrate the flexibility of Flightmare by using it for two different robotic tasks: quadrotor control using deep reinforcement learning and collision-free path planning in a complex 3D environment., Comment: Accepted for publication at 4th Conference on Robot Learning (CoRL), Cambridge MA, USA. 2020

Published
2020

30. Super-Human Performance in Gran Turismo Sport Using Deep Reinforcement Learning

Author

Fuchs, Florian, Song, Yunlong, Kaufmann, Elia, Scaramuzza, Davide, and Duerr, Peter

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

Autonomous car racing is a major challenge in robotics. It raises fundamental problems for classical approaches such as planning minimum-time trajectories under uncertain dynamics and controlling the car at the limits of its handling. Besides, the requirement of minimizing the lap time, which is a sparse objective, and the difficulty of collecting training data from human experts have also hindered researchers from directly applying learning-based approaches to solve the problem. In the present work, we propose a learning-based system for autonomous car racing by leveraging a high-fidelity physical car simulation, a course-progress proxy reward, and deep reinforcement learning. We deploy our system in Gran Turismo Sport, a world-leading car simulator known for its realistic physics simulation of different race cars and tracks, which is even used to recruit human race car drivers. Our trained policy achieves autonomous racing performance that goes beyond what had been achieved so far by the built-in AI, and, at the same time, outperforms the fastest driver in a dataset of over 50,000 human players., Comment: Accepted for Publication at the IEEE Robotics and Automation Letters (RA-L) 2021, and International Conference on Robots and Automation (ICRA) 2021

Published
2020
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31. Learning High-Level Policies for Model Predictive Control

Author

Song, Yunlong and Scaramuzza, Davide

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

The combination of policy search and deep neural networks holds the promise of automating a variety of decision-making tasks. Model Predictive Control (MPC) provides robust solutions to robot control tasks by making use of a dynamical model of the system and solving an optimization problem online over a short planning horizon. In this work, we leverage probabilistic decision-making approaches and the generalization capability of artificial neural networks to the powerful online optimization by learning a deep high-level policy for the MPC (High-MPC). Conditioning on robot's local observations, the trained neural network policy is capable of adaptively selecting high-level decision variables for the low-level MPC controller, which then generates optimal control commands for the robot. First, we formulate the search of high-level decision variables for MPC as a policy search problem, specifically, a probabilistic inference problem. The problem can be solved in a closed-form solution. Second, we propose a self-supervised learning algorithm for learning a neural network high-level policy, which is useful for online hyperparameter adaptations in highly dynamic environments. We demonstrate the importance of incorporating the online adaption into autonomous robots by using the proposed method to solve a challenging control problem, where the task is to control a simulated quadrotor to fly through a swinging gate. We show that our approach can handle situations that are difficult for standard MPC., Comment: Accepted for Publication at the 2020 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)

Published
2020
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37. Synergistic Therapeutic Effects and Immunoregulatory Mechanism of Maxing Shigan Decoction Combined with Sijunzi Decoction on Viral Pneumonia in Mice.

Author

Huang, Huimin, Yang, Huanhua, Zhang, Zurong, Song, Yunlong, Li, Li, Li, Ke, Zhang, Junjie, Qi, Xiaoyu, Wu, Ying, and Wang, Chuan

Subjects
TREATMENT effectiveness, CHINESE medicine, HERBAL medicine, LUNGS, INFLUENZA viruses
Abstract

Influenza is defined in traditional Chinese medicine (TCM) as an epidemic febrile illness and is usually treated with herbal compound formulas under the guidance of the "Qu Xie and Fu Zheng" theories. Ma Xing Shi Gan Tang (MXSGD) is a prominent remedy for clearing heat and detoxifying toxins in the clinical treatment of influenza in TCM, playing the role of "Qu Xie." Si Jun Zi Tang (SJZD) is recognized as one of the "Fu Zheng" formulas for strengthening the spleen and nourishing the stomach, with immunomodulatory effects. In this study, we followed the principles of "Qu Xie and Fu Zheng" to explore the effects of MXSGD combined with SJZD on viral pneumonia and its mechanism. Results showed that the couse of MXSGD and SJZD was effective in reducing the mortality rates and severity of lung pathology in lethally infected FM1 mice compared to the use of either drug alone. Moreover, further research demonstrated that the combined use suppressed TLRs and NLRP3 inflammatory signaling pathways at 4 dpi while promoting them at 7 dpi. At 10 dpi, there was a significant increase in CD11c+ and CD103+ DCs in the lungs. Together, SJZD improved the therapeutic effectiveness of MXSGD in treating influenza virus pneumonia than when used alone. MXSGD and SJZD exhibit synergistic effects in the treatment of influenza, as evidenced by the inhibition of TLR7 and NLRP3 inflammatory pathways early in the infection and facilitation of the response later. They also increase CD11c+ and CD103+ DC levels, as well as balancing Th1/Th2 cytokines. [ABSTRACT FROM AUTHOR]

Published
2024
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41. Autonomous Drone Racing: A Survey

Author

Hanover, Drew, primary, Loquercio, Antonio, additional, Bauersfeld, Leonard, additional, Romero, Angel, additional, Penicka, Robert, additional, Song, Yunlong, additional, Cioffi, Giovanni, additional, Kaufmann, Elia, additional, and Scaramuzza, Davide, additional

Published
2024
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43. Study on Water Quality and Trophic Status of Subtropical Cascade Reservoirs in Dongjiang River Basin in Dry Season

Author

Song Yunlong

Subjects
Environmental sciences, GE1-350
Abstract

The Dongjiang River Basin is an important water source for Guangdong Province, providing water for living, production and ecology for more than 40 million people. The three large reservoirs, Xinfengjiang Reservoir, Fengshuba Reservoir and Baipenzhu Reservoir, are the three largest reservoirs in the Dongjiang River Basin. The quality of the water environment in the three reservoirs plays an important role in ensuring the safety of drinking water and promoting the overall protection, systematic restoration and comprehensive management of the water ecosystem. 11 indicators, including water temperature, transparency, pH, DO, turbidity, conductivity, ammonia nitrogen, TN, TP, CODMn and chlorophyll a, were tested in October 2022 to study the water quality characteristics and trophic status of the three cascade reservoirs. The results of the single-factor evaluation of water quality showed that all three reservoirs reached the surface water class II level. TN is the primary pollutant in Fengshuba and Baipenzhu reservoirs. The concentration of Chla in Baekpongju Reservoir was 3.4 μg/L, with a mild risk of algal bloom. TLI (Σ) of the three cascade reservoirs were about 16.41~32.14.The results of the integrated nutrient status evaluation showed that Xinfengjiang Reservoir was in a depleted nutrient status, while Mapeshuba and Bailuanzhu Reservoirs were in a medium nutrient status. Factor analysis showed that 11 water quality factors can be classified into four categories. F1 represents the organic pollution. F2represents the phytoplankton biomass. F3 represents the concentration of nitrogen. F4 represents the suspended solids in water.

Published
2023
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47. Role Classification and Transition of OSS Developers

Author

Song, Yunlong

Subjects
Computer science, developer, OSS, role
Abstract

It has been acknowledged that many open source software (OSS) projects are successful evenwhen compared with their commercial counterparts. Previous research has investigated theartifacts developed by OSS projects and the communities behind those OSS projects. Thedifferent roles that developers play have been studied to provide insights on developers’behavior and their impact on the OSS projects. By presenting the composition of developersin a project and a community, these studies can provide guidance for the development ofa successful OSS project and a flourishing community. As for the individual developers,they can also benefit from obtaining awareness of their roles and the possible role evolutionpaths. By reviewing the existing role classifications and transition patterns, I aim to provideinsights as a basis for construction of a systematic and universal role classification modeland role transition patterns of OSS developers.In this paper, I performed a systematic literature review of research on developers’ roles androle transition in the OSS community. I identified six role classification models, five majorrole identification methods, and role transition patterns that have been studied. I alsoprovide a series of discussions about methods used by these studies and the roles studied.

Published
2021

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