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1. Development of high performance computing tools for estimation of high-resolution surface energy balance products using sUAS information

   https://doi.org/10.1117/12.2587763  

   Nassar, Ayman; Torres-Rua, Alfonso F.; Merwade, Venkatesh; Dey, Sayan; Zhao, Lan; Kim, I. Luk; Kustas, William; Nieto, Hector; Hipps, Lawrence; Gao, Rui; et al (April 2021, Development of high performance computing tools for estimation of high-resolution surface energy balance products using sUAS information)

   Thomasson, J. Alex; Torres-Rua, Alfonso F. (Ed.)

   sUAS (small-Unmanned Aircraft System) and advanced surface energy balance models allow detailed assessment and monitoring (at plant scale) of different (agricultural, urban, and natural) environments. Significant progress has been made in the understanding and modeling of atmosphere-plant-soil interactions and numerical quantification of the internal processes at plant scale. Similarly, progress has been made in ground truth information comparison and validation models. An example of this progress is the application of sUAS information using the Two-Source Surface Energy Balance (TSEB) model in commercial vineyards by the Grape Remote sensing Atmospheric Profile and Evapotranspiration eXperiment - GRAPEX Project in California. With advances in frequent sUAS data collection for larger areas, sUAS information processing becomes computationally expensive on local computers. Additionally, fragmentation of different models and tools necessary to process the data and validate the results is a limiting factor. For example, in the referred GRAPEX project, commercial software (ArcGIS and MS Excel) and Python and Matlab code are needed to complete the analysis. There is a need to assess and integrate research conducted with sUAS and surface energy balance models in a sharing platform to be easily migrated to high performance computing (HPC) resources. This research, sponsored by the National Science Foundation FAIR Cyber Training Fellowships, is integrating disparate software and code under a unified language (Python). The Python code for estimating the surface energy fluxes using TSEB2T model as well as the EC footprint analysis code for ground truth information comparison were hosted in myGeoHub site https://mygeohub.org/ to be reproducible and replicable. 

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2. A Requirements-Driven Platform for Validating Field Operations of Small Uncrewed Aerial Vehicles

   https://doi.org/10.1109/RE57278.2023.00013  

   Agrawal, Ankit; Zhang, Bohan; Shivalingaiah, Yashaswini; Vierhauser, Michael; Cleland-Huang, Jane (September 2023, IEEE)

   Flight-time failures of small Uncrewed Aerial Systems (sUAS) can have a severe impact on people or the environment. Therefore, sUAS applications must be thoroughly evaluated and tested to ensure their adherence to specified requirements, and safe behavior under real-world conditions, such as poor weather, wireless interference, and satellite failure. However, current simulation environments for autonomous vehicles, including sUAS, provide limited support for validating their behavior in diverse environmental contexts and moreover, lack a test harness to facilitate structured testing based on system-level requirements. We address these shortcomings by eliciting and specifying requirements for an sUAS testing and simulation platform, and developing and deploying it. The constructed platform, DroneWorld (\DW), allows sUAS developers to define the operating context, configure multi-sUAS mission requirements, specify safety properties, and deploy their own custom sUAS applications in a high-fidelity 3D environment. The DroneWorld Monitoring system collects runtime data from sUAS and the environment, analyzes compliance with safety properties, and captures violations. We report on two case studies in which we used our platform prior to real-world sUAS deployments, in order to evaluate sUAS mission behavior in various environmental contexts. Furthermore, we conducted a study with developers and found that DroneWorld simplifies the process of specifying requirements-driven test scenarios and analyzing acceptance test results. 

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3. Explaining Autonomous Decisions in Swarms of Human-on-the-Loop Small Unmanned Aerial Systems

   Ankit Agrawal; Jane Cleland-Huang (October 2021, Proceedings the AAAI Conference on Human Computation and Crowdsourcing)

   Rapid advancements in Artificial Intelligence have shifted the focus from traditional human-directed robots to fully autonomous ones that do not require explicit human control. These are commonly referred to as Human-on-the-Loop (HotL) systems. Transparency of HotL systems necessitates clear explanations of autonomous behavior so that humans are aware of what is happening in the environment and can understand why robots behave in a certain way. However, in complex multi-robot environments, especially those in which the robots are autonomous and mobile, humans may struggle to maintain situational awareness. Presenting humans with rich explanations of autonomous behavior tends to overload them with lots of information and negatively affect their understanding of the situation. Therefore, explaining the autonomous behavior of multiple robots creates a design tension that demands careful investigation. This paper examines the User Interface (UI) design trade-offs associated with providing timely and detailed explanations of autonomous behavior for swarms of small Unmanned Aerial Systems (sUAS) or drones. We analyze the impact of UI design choices on human awareness of the situation. We conducted multiple user studies with both inexperienced and expert sUAS operators to present our design solution and initial guidelines for designing the HotL multi-sUAS interface. 

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4. Interlocking safety cases for unmanned autonomous systems in urban environments

   https://doi.org/10.1145/3183440.3195035  

   Vierhauser, Michael; Bayley, Sean; Wyngaard, Jane; Cheng, Jinghui; Xiong, Wandi; Lutz, Robyn; Huseman, Joshua; Cleland-Huang, Jane (January 2018, 40th International Conference on Software Engineering)

   The growing adoption of small unmanned aircraft systems (sUAS) for tasks such as eCommerce, aerial surveillance, and environmental monitoring introduces the need for new safety mechanisms in an increasingly cluttered airspace. Safety assurance cases (SAC) provide a state-of-the-art solution for reasoning about system and software safety in numerous safety-critical domains. We propose a novel approach based on the idea of interlocking safety cases. The sUAS infrastructure safety case (iSAC) specifies assumptions and applies constraints upon the behavior of sUAS entering the airspace. Each sUAS then demonstrates compliance to the iSAC by presenting its own (partial) safety case (uSAC) which connects to the iSAC through a set of interlock points. To enforce a “trust but verify” policy, sUAS conformance is monitored at runtime while it is in the airspace and its behavior is described using a reputation model based on the iSAC’s expectations of its behavior. 

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5. Learning from Users: an Elicitation Study and Taxonomy for Communicating Small Unmanned Aerial System States Through Gestures

   https://doi.org/10.1109/hri.2019.8673010  

   Firestone, Justin W.; Quinones, Rubi; Duncan, Brittany A. (March 2019, 14th ACM/IEEE International Conference on Human-Robot Interaction (HRI))

   This paper presents a gesture set for communicating states to novice users from a small Unmanned Aerial System (sUAS) through an elicitation study comparing gestures created by participants recruited from the general public with varying levels of experience with an sUAS. Previous work in sUAS flight paths sought to communicate intent, destination, or emotion without focusing on concrete states such as Low Battery or Landing. This elicitation study uses a participatory design approach from human-computer interaction to understand how novice users would expect an sUAS to communicate states, and ultimately suggests flight paths and characteristics to indicate those states. We asked users from the general public (N=20) to create gestures for seven distinct sUAS states to provide insights for human-drone interactions and to present intuitive flight paths and characteristics with the expectation that the sUAS would have general commercial application for inexperienced users. The results indicate relatively strong agreement scores for three sUAS states: Landing (0.455), Area of Interest (0.265), and Low Battery (0.245). The other four states have lower agreement scores, however even they show some consensus for all seven states. The agreement scores and the associated gestures suggest guidance for engineers to develop a common set of flight paths and characteristics for an sUAS to communicate states to novice users. 

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