Grants

NSF

This NSF project aims to design and evaluate honeybee-inspired virtual electric peer-to-peer networks to enable efficient and resilient control of distributed energy resources. These resources include electric vehicles, heat pumps, electric water heaters, and battery energy storage systems at the distribution level. Existing electrical infrastructures are undersized to handle increasing loads, and a lack of effective coordination among these resources further exacerbates this challenge. Inspired by the decentralized coordination mechanisms observed in honeybee colonies—where energy (food) is exchanged among members in a process called trophallaxis—this project will develop a bio-inspired cyber-physical system where distributed resources (“bees”) and storage systems (“hive”) dynamically allocate energy. By applying principles from collective insect behavior, this research seeks to transform energy coordination, benefiting grid operators and consumers alike. The intellectual merits of the project include novel mathematical models based on trophallaxis, development of bio-inspired control strategies, and validation through virtual testbeds and real-world demonstrations. The broader impacts include advancing non-wire alternatives that enhance grid resilience, improving access to electricity services, and fostering interdisciplinary knowledge exchange between biology, computing, and engineering. Additionally, the project will provide publicly available open-source software, engage students through an undergraduate design competition, and disseminate findings through workshops and outreach initiatives. This project will address existing technical challenges in energy coordination by translating honeybee trophallaxis into mathematical models and integrating them into an innovative cyber-physical framework. It will develop predictive models for uncertain building loads and energy behaviors using stochastic transfer learning. Additionally, it will create bidirectional biology-technology knowledge transfer frameworks to inform control-oriented models across multiple system layers. New bio-inspired control methods will be designed to optimize peer-to-peer energy sharing and grid operations. The project will leverage virtual testbeds using Python and GridLAB-D for rigorous evaluation, with experimental demonstrations conducted at the University of Colorado Boulder’s microgrid. By combining expertise from biology, computer science, and engineering, this research will generate novel strategies for resilient, adaptive, and efficient grid operations. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

NSF

This NSF project aims to design and evaluate honeybee-inspired virtual electric peer-to-peer networks to enable efficient and resilient control of distributed energy resources. These resources include electric vehicles, heat pumps, electric water heaters, and battery energy storage systems at the distribution level. Existing electrical infrastructures are undersized to handle increasing loads, and a lack of effective coordination among these resources further exacerbates this challenge. Inspired by the decentralized coordination mechanisms observed in honeybee colonies—where energy (food) is exchanged among members in a process called trophallaxis—this project will develop a bio-inspired cyber-physical system where distributed resources (“bees”) and storage systems (“hive”) dynamically allocate energy. By applying principles from collective insect behavior, this research seeks to transform energy coordination, benefiting grid operators and consumers alike. The intellectual merits of the project include novel mathematical models based on trophallaxis, development of bio-inspired control strategies, and validation through virtual testbeds and real-world demonstrations. The broader impacts include advancing non-wire alternatives that enhance grid resilience, improving access to electricity services, and fostering interdisciplinary knowledge exchange between biology, computing, and engineering. Additionally, the project will provide publicly available open-source software, engage students through an undergraduate design competition, and disseminate findings through workshops and outreach initiatives. This project will address existing technical challenges in energy coordination by translating honeybee trophallaxis into mathematical models and integrating them into an innovative cyber-physical framework. It will develop predictive models for uncertain building loads and energy behaviors using stochastic transfer learning. Additionally, it will create bidirectional biology-technology knowledge transfer frameworks to inform control-oriented models across multiple system layers. New bio-inspired control methods will be designed to optimize peer-to-peer energy sharing and grid operations. The project will leverage virtual testbeds using Python and GridLAB-D for rigorous evaluation, with experimental demonstrations conducted at the University of Colorado Boulder’s microgrid. By combining expertise from biology, computer science, and engineering, this research will generate novel strategies for resilient, adaptive, and efficient grid operations. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

NSF

Air traffic control is a vast, distributed operation that requires the efficient and safe coordination of approximately 45,000 commercial airline flights per day in the United States. Safely managing this volume of traffic requires extensive human coordination combined with sophisticated algorithmic planning. Unfortunately, despite multiple overlapping safety layers, serious safety incidents occur at an alarming frequency. The proposed research combines artificial intelligence with formal methods to improve the safety, reliability, and efficiency of air traffic management. Using a combination of voice recognition, predictive models, and safety checks, the project aims to help detect problems before they occur, such as a misunderstanding causing a future runway incursion or a weather-driven delay that cascades across multiple airports. Beyond air traffic control, the developed framework can enhance other cyber-physical systems that combine human coordination with intelligent automation, improving the safety of firefighting operations, strengthening the resilience of the power grid to adverse events, and advancing national security by preventing human error in military operations. This research aims to advance the theory and application of cyber-physical systems (CPS) by improving the safety and resilience of air traffic management. The project investigates a multi-layered approach that integrates formal verification, robust speech understanding, and data-driven disruption analysis. At the airport level, compositional hybrid automata and signal temporal logic (STL) will be used for predictive monitoring of aircraft trajectories and controller-issued commands, enabling early detection of safety violations. At the interface layer, robust machine learning models will extract semantic intent from noisy, domain-specific voice data to support online reasoning and decision-making. At the regional level, scheduling algorithms will be analyzed under operational uncertainty, using formal sensitivity analysis and probabilistic post-mortem inference to identify failure modes and propose mitigation strategies. While focused on air traffic control, the general methods developed are applicable to a wide range of CPS domains that involve human-in-the-loop operation and algorithmic oversight in distributed safety-critical settings. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

NSF

This project aims to design a Cyber-Physical System (CPS) comprising networked Autonomous Underwater Vehicles (AUVs) to perform Machine Learning (ML)-assisted identification of marine plumes via modeling, multi-AUV coordination and swarming, and dynamic collaboration between AUVs and a Land-based computational cluster. Although ground and air settings have seen the increased use of Internet-of-Things (IoTs) systems, robot swarms, and distributed sensor networks, CPSs remain extremely rare in the underwater domain. To address this and promote the progress of science, this project aims to use an adaptive and intelligent network of heterogeneous AUVs for plume search, classification, and mapping in scientific understanding and forecasting. The ability to sense in real time the ocean is highly beneficial for oceanography and environmental monitoring as well as for national defense/port surveillance and industry, such as aquaculture and oil & gas. This project will help answer the fundamental question of whether there is a correlation between plumes and the presence of gas/oil hydrocarbons. This project will perform sampling/mapping of ocean bottom plumes such as oil spills and chemical release from minerals, which is useful for exploration and extraction of ocean resources or for the monitoring of seabed mineral exploitation activities. This project will provide a better understanding of temporally and spatially limited ocean features, and could well be adapted for sensing other small-scale and dynamic phenomena, such as biological distributions in the water column. Last but not least, this project will develop a pipeline of computer-literate individuals who can solve research-related scientific problems trying to generalize to CPS as a science. This project includes three interconnected high-risk/high-reward innovative research tasks centered on science and engineering: (1) Developing multi-fidelity numerical models of multiphase plumes to understand their current state and enable real-time forecasting. (2) Designing the physical underwater sensor network, which will consist of heterogeneous AUVs acting as mobile sensor nodes, equipped with heterogeneous plume sensors and acoustic array communications and positioning systems, and a surface gateway acting both as an underwater and above-water communication relay as well as as a centralized node for AUV positioning and operator command and control of the network; and devising novel adaptive control schemes that allow the AUVs to autonomously explore the extent of the plume. (3) Proposing novel ML-based methods for collaboration between AUVs and the Land-based computational cluster to balance network resources while taking into account communication failures, constraints on data storage on each node, their processing resources, the limited acoustic communication bandwidth and high latency, and the sensing and control capabilities of each node. This project will verify and quantify the capabilities of this CPS using a combination of hardware-in-the-loop emulations, field tests, and experimentations. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

NSF

This project aims to design a Cyber-Physical System (CPS) comprising networked Autonomous Underwater Vehicles (AUVs) to perform Machine Learning (ML)-assisted identification of marine plumes via modeling, multi-AUV coordination and swarming, and dynamic collaboration between AUVs and a Land-based computational cluster. Although ground and air settings have seen the increased use of Internet-of-Things (IoTs) systems, robot swarms, and distributed sensor networks, CPSs remain extremely rare in the underwater domain. To address this and promote the progress of science, this project aims to use an adaptive and intelligent network of heterogeneous AUVs for plume search, classification, and mapping in scientific understanding and forecasting. The ability to sense in real time the ocean is highly beneficial for oceanography and environmental monitoring as well as for national defense/port surveillance and industry, such as aquaculture and oil & gas. This project will help answer the fundamental question of whether there is a correlation between plumes and the presence of gas/oil hydrocarbons. This project will perform sampling/mapping of ocean bottom plumes such as oil spills and chemical release from minerals, which is useful for exploration and extraction of ocean resources or for the monitoring of seabed mineral exploitation activities. This project will provide a better understanding of temporally and spatially limited ocean features, and could well be adapted for sensing other small-scale and dynamic phenomena, such as biological distributions in the water column. Last but not least, this project will develop a pipeline of computer-literate individuals who can solve research-related scientific problems trying to generalize to CPS as a science. This project includes three interconnected high-risk/high-reward innovative research tasks centered on science and engineering: (1) Developing multi-fidelity numerical models of multiphase plumes to understand their current state and enable real-time forecasting. (2) Designing the physical underwater sensor network, which will consist of heterogeneous AUVs acting as mobile sensor nodes, equipped with heterogeneous plume sensors and acoustic array communications and positioning systems, and a surface gateway acting both as an underwater and above-water communication relay as well as as a centralized node for AUV positioning and operator command and control of the network; and devising novel adaptive control schemes that allow the AUVs to autonomously explore the extent of the plume. (3) Proposing novel ML-based methods for collaboration between AUVs and the Land-based computational cluster to balance network resources while taking into account communication failures, constraints on data storage on each node, their processing resources, the limited acoustic communication bandwidth and high latency, and the sensing and control capabilities of each node. This project will verify and quantify the capabilities of this CPS using a combination of hardware-in-the-loop emulations, field tests, and experimentations. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

NSF

Cyber-physical systems (CPS), for example, autonomous vehicles and delivery drones, consist of computational units tightly integrated with their physical environments. They are often built using small, constrained platforms and multiple control tasks shape the common platform. Thus the computation that is available to each control task is limited and may vary over time, which threatens to compromise the quality of control. This project will address this challenge through co-design of control algorithms and real-time scheduling techniques for control tasks. The new control algorithms developed in this project will be robust to early termination, with guarantees on the quality of control, and the scheduling frameworks will be capable of dynamically adapting scheduling decisions in response to changes in computational demand. The developed techniques will be applied to automated drone delivery in collaboration with industrial partners. The hand-on experimentation plan enables technology transfer to commercial delivery applications, as well as provides a valuable educational tool for engineering students studying robotics and autonomous systems. The approach will target optimization based control algorithms, such as model-predictive control and apply novel solvers based on state-of-the-art Robust to EArly termination oPtimization (REAP). The core idea of REAP is to construct a continuous-time dynamical system whose trajectory converges to the optimal solution, while a sub-optimal and feasible solution is guaranteed even in the event of early termination. Towards achieving this, the project will investigate i) closed-loop stability guarantees and discrete-time implementation; ii) proactive and safe real-time scheduling in CPSs; iii) cooperative computation-aware distributed model predictive control; and iv) control of systems subject to time-varying constraints. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

NSF

Cyber-physical systems (CPS), for example, autonomous vehicles and delivery drones, consist of computational units tightly integrated with their physical environments. They are often built using small, constrained platforms and multiple control tasks shape the common platform. Thus the computation that is available to each control task is limited and may vary over time, which threatens to compromise the quality of control. This project will address this challenge through co-design of control algorithms and real-time scheduling techniques for control tasks. The new control algorithms developed in this project will be robust to early termination, with guarantees on the quality of control, and the scheduling frameworks will be capable of dynamically adapting scheduling decisions in response to changes in computational demand. The developed techniques will be applied to automated drone delivery in collaboration with industrial partners. The hand-on experimentation plan enables technology transfer to commercial delivery applications, as well as provides a valuable educational tool for engineering students studying robotics and autonomous systems. The approach will target optimization based control algorithms, such as model-predictive control and apply novel solvers based on state-of-the-art Robust to EArly termination oPtimization (REAP). The core idea of REAP is to construct a continuous-time dynamical system whose trajectory converges to the optimal solution, while a sub-optimal and feasible solution is guaranteed even in the event of early termination. Towards achieving this, the project will investigate i) closed-loop stability guarantees and discrete-time implementation; ii) proactive and safe real-time scheduling in CPSs; iii) cooperative computation-aware distributed model predictive control; and iv) control of systems subject to time-varying constraints. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

NSF

Cyber-physical systems (CPS), for example, autonomous vehicles and delivery drones, consist of computational units tightly integrated with their physical environments. They are often built using small, constrained platforms and multiple control tasks shape the common platform. Thus the computation that is available to each control task is limited and may vary over time, which threatens to compromise the quality of control. This project will address this challenge through co-design of control algorithms and real-time scheduling techniques for control tasks. The new control algorithms developed in this project will be robust to early termination, with guarantees on the quality of control, and the scheduling frameworks will be capable of dynamically adapting scheduling decisions in response to changes in computational demand. The developed techniques will be applied to automated drone delivery in collaboration with industrial partners. The hand-on experimentation plan enables technology transfer to commercial delivery applications, as well as provides a valuable educational tool for engineering students studying robotics and autonomous systems. The approach will target optimization based control algorithms, such as model-predictive control and apply novel solvers based on state-of-the-art Robust to EArly termination oPtimization (REAP). The core idea of REAP is to construct a continuous-time dynamical system whose trajectory converges to the optimal solution, while a sub-optimal and feasible solution is guaranteed even in the event of early termination. Towards achieving this, the project will investigate i) closed-loop stability guarantees and discrete-time implementation; ii) proactive and safe real-time scheduling in CPSs; iii) cooperative computation-aware distributed model predictive control; and iv) control of systems subject to time-varying constraints. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

NSF

Grasses are beneficial to human society by creating habitat for bees, and other pollinators, that ensure crops produce fruit and seeds, improve the quality of water, trap carbon, and provide food for animals upon which people rely for nutrition. However, grasses are a large group of over 11,000 species, which cover ~50% of the earth’s surface, and there are differences in their ability to perform beneficial ecological functions. For example, they can differ in the time of year they grow (also called phenology), how fast they grow, and their ability to tolerate and survive droughts. Importantly, there are often trade-offs between these characteristics, such that species that only grow in the spring may not be very tolerant of drought, and species that only grow during the summer generally do not grow very fast. Therefore, environmental changes during different seasons may prevent some species from thriving in their current locations, altering the ecosystem services they provide. To effectively manage resilient grasslands for the future, we need better information on the phenology, growth rates, and drought tolerance of a broader range of grass species. Most projects that measure these characteristics have focused on trees, leaving major gaps in our understanding of these traits in grasses. Using novel techniques to observe processes occurring inside the leaf and new mapping methods, our project will provide critical information about plant traits and tradeoffs in different environments to help predict how grass distributions will respond to changing weather patterns and environmental conditions. Changes to plant communities are continually occurring as plants disappear, appear, and re-arrange in ecosystems across the globe as rising temperatures and changing precipitation patterns reduce the available water for plant growth. Plant responses to these dynamic conditions dictate whether a species can persist in a region or must shift distributionally. Modern approaches to modeling species distributions rarely include the mechanistic underpinnings of organismal responses but, instead, rely on bivariate relationships between individual traits and annual summaries of abiotic conditions. This approach ignores the fact that networks of traits, rather than any single trait, generate different drought-coping strategies and that drastic differences in grass phenology decouples plant growth conditions from annual summaries of abiotic conditions. To improve predictions of future species distributions and inform restoration projects of ideal seed-mixes, the overall objective of our study is to improve the accuracy of species distribution models through a better understanding of grass species resilience by including trait networks and growth phenology. Using a set of species that spans the entire grass family, the investigators will identify mechanistic trait networks leading to different drought-coping strategies, including mechanisms leading to embolism formation, a key drought-coping trait rarely studied in grasses. Integrating these key traits will provide information on species responses and distribution shifts and the experimental design will also provide information on how these traits may evolve independently or in unison within the grass family. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

NSF

Grasses are beneficial to human society by creating habitat for bees, and other pollinators, that ensure crops produce fruit and seeds, improve the quality of water, trap carbon, and provide food for animals upon which people rely for nutrition. However, grasses are a large group of over 11,000 species, which cover ~50% of the earth’s surface, and there are differences in their ability to perform beneficial ecological functions. For example, they can differ in the time of year they grow (also called phenology), how fast they grow, and their ability to tolerate and survive droughts. Importantly, there are often trade-offs between these characteristics, such that species that only grow in the spring may not be very tolerant of drought, and species that only grow during the summer generally do not grow very fast. Therefore, environmental changes during different seasons may prevent some species from thriving in their current locations, altering the ecosystem services they provide. To effectively manage resilient grasslands for the future, we need better information on the phenology, growth rates, and drought tolerance of a broader range of grass species. Most projects that measure these characteristics have focused on trees, leaving major gaps in our understanding of these traits in grasses. Using novel techniques to observe processes occurring inside the leaf and new mapping methods, our project will provide critical information about plant traits and tradeoffs in different environments to help predict how grass distributions will respond to changing weather patterns and environmental conditions. Changes to plant communities are continually occurring as plants disappear, appear, and re-arrange in ecosystems across the globe as rising temperatures and changing precipitation patterns reduce the available water for plant growth. Plant responses to these dynamic conditions dictate whether a species can persist in a region or must shift distributionally. Modern approaches to modeling species distributions rarely include the mechanistic underpinnings of organismal responses but, instead, rely on bivariate relationships between individual traits and annual summaries of abiotic conditions. This approach ignores the fact that networks of traits, rather than any single trait, generate different drought-coping strategies and that drastic differences in grass phenology decouples plant growth conditions from annual summaries of abiotic conditions. To improve predictions of future species distributions and inform restoration projects of ideal seed-mixes, the overall objective of our study is to improve the accuracy of species distribution models through a better understanding of grass species resilience by including trait networks and growth phenology. Using a set of species that spans the entire grass family, the investigators will identify mechanistic trait networks leading to different drought-coping strategies, including mechanisms leading to embolism formation, a key drought-coping trait rarely studied in grasses. Integrating these key traits will provide information on species responses and distribution shifts and the experimental design will also provide information on how these traits may evolve independently or in unison within the grass family. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

NSF

Categorization is a fundamental, but complex, cognitive ability. Depending on the context, the same feature could place an object or event in different categories. For example, categorizing animals as “big” vs. “small” varies when a house cat is considered “big” when compared to an ant and an elephant is considered “small” compared to whale. How brains handle these categorization decisions flexibly and adaptively remains elusive. This project investigates the role of brain waves in the prefrontal cortex in categorization task. The project studies brain activity in humans and animals while performing a decision-making task to leverage a computational model to better understand the brain mechanisms involved. This project has potential to open a new window into understanding of decision making and will set the stage for future investigations into disorders, such as Parkinson’s disease and schizophrenia, in which both brain waves and cognitive function are impaired. This project tests the novel hypothesis that beta oscillations at different frequencies could act as separate channels to selectively transmit decision information downstream, akin to frequency-division multiplexing. Specifically, beta frequency shifts in dorsolateral prefrontal cortex appear to synchronize different neuronal ensembles that represent specific decision outcomes. This research involves a close collaboration between computational and experimental neuroscientists, utilizing a neural modeling framework uniquely designed to link macroscale oscillatory activity to the underlying cellular- and circuit-level dynamics that can be assessed electrophysiologically. The modeling work will be informed by spectrotemporal analysis of previously collected human and rodent data, as well as new electrophysiological recordings and optogenetic neuromodulation experiments in rodents to test hypotheses on cell- and circuit-level generation of beta frequency shifts and their causal implications in the context of decision making. This approach, combining electrophysiological recordings, causal manipulation and modeling, is designed to answer core questions regarding a crucial brain mechanism underlying decision making, and will provide a grounded understanding of consistency in brain dynamics across species and tasks, and their implications for behavior. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

NSF

Categorization is a fundamental, but complex, cognitive ability. Depending on the context, the same feature could place an object or event in different categories. For example, categorizing animals as “big” vs. “small” varies when a house cat is considered “big” when compared to an ant and an elephant is considered “small” compared to whale. How brains handle these categorization decisions flexibly and adaptively remains elusive. This project investigates the role of brain waves in the prefrontal cortex in categorization task. The project studies brain activity in humans and animals while performing a decision-making task to leverage a computational model to better understand the brain mechanisms involved. This project has potential to open a new window into understanding of decision making and will set the stage for future investigations into disorders, such as Parkinson’s disease and schizophrenia, in which both brain waves and cognitive function are impaired. This project tests the novel hypothesis that beta oscillations at different frequencies could act as separate channels to selectively transmit decision information downstream, akin to frequency-division multiplexing. Specifically, beta frequency shifts in dorsolateral prefrontal cortex appear to synchronize different neuronal ensembles that represent specific decision outcomes. This research involves a close collaboration between computational and experimental neuroscientists, utilizing a neural modeling framework uniquely designed to link macroscale oscillatory activity to the underlying cellular- and circuit-level dynamics that can be assessed electrophysiologically. The modeling work will be informed by spectrotemporal analysis of previously collected human and rodent data, as well as new electrophysiological recordings and optogenetic neuromodulation experiments in rodents to test hypotheses on cell- and circuit-level generation of beta frequency shifts and their causal implications in the context of decision making. This approach, combining electrophysiological recordings, causal manipulation and modeling, is designed to answer core questions regarding a crucial brain mechanism underlying decision making, and will provide a grounded understanding of consistency in brain dynamics across species and tasks, and their implications for behavior. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

NSF

The activity and interconnectivity of neurons, a key type of brain cell, are crucial to the brain's ability to compute and process information. However, recent studies suggest that astrocytes, a different type of brain cell, may also play an important role. This project combines experiments and computational modeling to study how astrocytes contribute to brain function. Astrocytes affect many aspects of neuronal activity and communication, providing a potential mechanism by which they can alter signaling in the brain. The computational modeling and mathematical analysis within the project will enable a deeper biological understanding of these astrocyte-neuron interactions, generate new ideas for why they may be important for information processing in the brain, and suggest ways to integrate these principles into artificial intelligence systems. In conjunction with the modeling will be experiments to observe and manipulate astrocytes in living brains. In so doing, the project will validate new ideas about astrocytes' roles in the brain, providing an enhanced understanding of neural circuits and brain function. The scientific premise of this project is the "contextual guidance" hypothesis, which postulates that astrocytes act as switchboards that transmit information about the environment and the physiological state of the organism to neurons and networks thereof. As such, astrocytes may act as a force multiplier that can expand the repertoire of dynamics that neurons can realize, thus enabling computation. The project will explore two ideas in this regard: (i) that astrocytes actively modulate neuronal dynamics in response to signals sensed from the environment, and (ii) this modulation enables neuronal networks to tailor their dynamics in response to context-specific circumstances. To substantiate these ideas, the project will investigate the role of astrocytes in neuromodulatory systems and subsequent effects on neuronal activity and synaptic plasticity. Furthermore, the project will examine network-level interaction between neurons and astrocytes, exploring features like "tiling," where astrocytes overlay neuron clusters to influence signal routing. In addition to scientific insights, the research will examine how brain-inspired computing may be enhanced by new artificial neural network designs that incorporate astrocytes, with a focus on context-dependent computational paradigms. Additionally, the project includes initiatives to engage trainees in interdisciplinary neuroscience research and exchange, including new mini-courses that bridge neuroscience, engineering and artificial intelligence. A companion project is being funded by the French National Research Agency (ANR). This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

NSF

The activity and interconnectivity of neurons, a key type of brain cell, are crucial to the brain's ability to compute and process information. However, recent studies suggest that astrocytes, a different type of brain cell, may also play an important role. This project combines experiments and computational modeling to study how astrocytes contribute to brain function. Astrocytes affect many aspects of neuronal activity and communication, providing a potential mechanism by which they can alter signaling in the brain. The computational modeling and mathematical analysis within the project will enable a deeper biological understanding of these astrocyte-neuron interactions, generate new ideas for why they may be important for information processing in the brain, and suggest ways to integrate these principles into artificial intelligence systems. In conjunction with the modeling will be experiments to observe and manipulate astrocytes in living brains. In so doing, the project will validate new ideas about astrocytes' roles in the brain, providing an enhanced understanding of neural circuits and brain function. The scientific premise of this project is the "contextual guidance" hypothesis, which postulates that astrocytes act as switchboards that transmit information about the environment and the physiological state of the organism to neurons and networks thereof. As such, astrocytes may act as a force multiplier that can expand the repertoire of dynamics that neurons can realize, thus enabling computation. The project will explore two ideas in this regard: (i) that astrocytes actively modulate neuronal dynamics in response to signals sensed from the environment, and (ii) this modulation enables neuronal networks to tailor their dynamics in response to context-specific circumstances. To substantiate these ideas, the project will investigate the role of astrocytes in neuromodulatory systems and subsequent effects on neuronal activity and synaptic plasticity. Furthermore, the project will examine network-level interaction between neurons and astrocytes, exploring features like "tiling," where astrocytes overlay neuron clusters to influence signal routing. In addition to scientific insights, the research will examine how brain-inspired computing may be enhanced by new artificial neural network designs that incorporate astrocytes, with a focus on context-dependent computational paradigms. Additionally, the project includes initiatives to engage trainees in interdisciplinary neuroscience research and exchange, including new mini-courses that bridge neuroscience, engineering and artificial intelligence. A companion project is being funded by the French National Research Agency (ANR). This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

NSF

This project aims to serve the national interest by modernizing the teaching of physics at the college level. Specifically, the project will enable college instructors to integrate specialized computational physics methods into their classes, and to rate their students' learning against a standard scale. Teaching computational physics is important because these methods are quickly becoming essential for physicists and other scientists around the world. This work will help colleges and universities keep up with these changes. Rating students against a standard scale will enable individual instructors and departments to determine how effective their teaching efforts are, and to make improvements that further benefit their students. Adding computational methods to college classes will enhance the effectiveness of the U.S. scientific workforce, one of the key goals of NSF and the IUSE program. This Engaged Student Learning: Level II project is the first effort to establish standards (and training materials for using the standards) designed specifically for evaluating students' achievement of seven essential learning goals in computational physics. The goals of this project are to expand and improve the teaching of computational physics at five universities in the midwestern U.S: Indiana University Indianapolis, Bradley University, Purdue University, University of Indianapolis, and University of Wisconsin - Stout. The project team will develop seven student learning objectives: 1) use generative AI effectively and ethically, 2) read, understand, and modify existing code, 3) apply common computational tools, 4) test code, 5) explore physics, 6) write clear code, and 7) communicate physics. Each partner institution will have a specific role and responsibility with respect to developing these learning objectives. The project will also develop, test, and improve rubrics related to these objectives that instructors can use to rate students' learning of these methods. Instructors are accustomed to evaluating students within a single class when they assign grades, but this type of rating does not give information about how a student has progressed over years. To measure progress, it is necessary to rate students against objective standards, therefore this project will also produce documents and procedures a department can use to help its members learn to use the rubrics to rate students objectively. This project will also study how students' development as rated by instructors compares to their own view of how much they have learned. Project work and findings will be disseminated through publications, presentations, and workshops for faculty. The NSF IUSE: EDU Program supports research and development projects to improve the effectiveness of STEM education for all students. Through the Engaged Student Learning track, the program supports the creation, exploration, and implementation of promising practices and tools. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

NSF

This project aims to serve the national interest by modernizing the teaching of physics at the college level. Specifically, the project will enable college instructors to integrate specialized computational physics methods into their classes, and to rate their students' learning against a standard scale. Teaching computational physics is important because these methods are quickly becoming essential for physicists and other scientists around the world. This work will help colleges and universities keep up with these changes. Rating students against a standard scale will enable individual instructors and departments to determine how effective their teaching efforts are, and to make improvements that further benefit their students. Adding computational methods to college classes will enhance the effectiveness of the U.S. scientific workforce, one of the key goals of NSF and the IUSE program. This Engaged Student Learning: Level II project is the first effort to establish standards (and training materials for using the standards) designed specifically for evaluating students' achievement of seven essential learning goals in computational physics. The goals of this project are to expand and improve the teaching of computational physics at five universities in the midwestern U.S: Indiana University Indianapolis, Bradley University, Purdue University, University of Indianapolis, and University of Wisconsin - Stout. The project team will develop seven student learning objectives: 1) use generative AI effectively and ethically, 2) read, understand, and modify existing code, 3) apply common computational tools, 4) test code, 5) explore physics, 6) write clear code, and 7) communicate physics. Each partner institution will have a specific role and responsibility with respect to developing these learning objectives. The project will also develop, test, and improve rubrics related to these objectives that instructors can use to rate students' learning of these methods. Instructors are accustomed to evaluating students within a single class when they assign grades, but this type of rating does not give information about how a student has progressed over years. To measure progress, it is necessary to rate students against objective standards, therefore this project will also produce documents and procedures a department can use to help its members learn to use the rubrics to rate students objectively. This project will also study how students' development as rated by instructors compares to their own view of how much they have learned. Project work and findings will be disseminated through publications, presentations, and workshops for faculty. The NSF IUSE: EDU Program supports research and development projects to improve the effectiveness of STEM education for all students. Through the Engaged Student Learning track, the program supports the creation, exploration, and implementation of promising practices and tools. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

NSF

This project aims to serve the national interest by modernizing the teaching of physics at the college level. Specifically, the project will enable college instructors to integrate specialized computational physics methods into their classes, and to rate their students' learning against a standard scale. Teaching computational physics is important because these methods are quickly becoming essential for physicists and other scientists around the world. This work will help colleges and universities keep up with these changes. Rating students against a standard scale will enable individual instructors and departments to determine how effective their teaching efforts are, and to make improvements that further benefit their students. Adding computational methods to college classes will enhance the effectiveness of the U.S. scientific workforce, one of the key goals of NSF and the IUSE program. This Engaged Student Learning: Level II project is the first effort to establish standards (and training materials for using the standards) designed specifically for evaluating students' achievement of seven essential learning goals in computational physics. The goals of this project are to expand and improve the teaching of computational physics at five universities in the midwestern U.S: Indiana University Indianapolis, Bradley University, Purdue University, University of Indianapolis, and University of Wisconsin - Stout. The project team will develop seven student learning objectives: 1) use generative AI effectively and ethically, 2) read, understand, and modify existing code, 3) apply common computational tools, 4) test code, 5) explore physics, 6) write clear code, and 7) communicate physics. Each partner institution will have a specific role and responsibility with respect to developing these learning objectives. The project will also develop, test, and improve rubrics related to these objectives that instructors can use to rate students' learning of these methods. Instructors are accustomed to evaluating students within a single class when they assign grades, but this type of rating does not give information about how a student has progressed over years. To measure progress, it is necessary to rate students against objective standards, therefore this project will also produce documents and procedures a department can use to help its members learn to use the rubrics to rate students objectively. This project will also study how students' development as rated by instructors compares to their own view of how much they have learned. Project work and findings will be disseminated through publications, presentations, and workshops for faculty. The NSF IUSE: EDU Program supports research and development projects to improve the effectiveness of STEM education for all students. Through the Engaged Student Learning track, the program supports the creation, exploration, and implementation of promising practices and tools. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

NSF

Many researchers across a myriad of scientific domains generate and analyze data. In order to make this data reproducible and reusable, it is important to also include metadata describing the context for the data. However, most current schemas for reading and writing metadata are optimized for machine use rather than directly accessible to citizens or scientists who are not expert programmers or data technicians. This project involves developing a toolset and a language, MEDFORD, that provides an easy and accessible structured approach for researchers who are not expert programmers to create metadata in a form that is easily human readable and writable. This metadata is then structured enough to be easily translated into popular metadata standards and included in databases that are FAIR (Findable, Accessible, Interoperable, and Reusable). The MEDFORD language and supporting toolbox will be tested for usability with scientists, students, and members of the general public across several scientific domains, including marine biologists studying coral reefs, and biologists studying the animal hosts of tick-borne diseases. The involvement of scientific experts in the collection and analysis of the metadata than accompanies the complex scientific data is crucial; however, many of the recommended practices and processes focused on making these data FAIR (findable, accessible, interoperable, and reusable), as well as replicable and reproducible, can be cumbersome and difficult to implement, particularly for users that are not experts in computer science. This project posits that increasing the widespread community adoption of processes around efficient, robust, trustworthy, and FAIR data and metadata will require a new focus on making these data easily human-readable, writable, and correctable, in addition to all the valuable past effort that continues to go into making them easy for machines and database systems to ingest, validate, and parse. Thus it is focusing on a critical but under-served piece of the problem of frictionless FAIR data and metadata collection for science. The proposed solution involves inserting an intermediate layer between unstructured human annotation and existing machine-parsable metadata standards - the MEDFORD language and parser. Further development of the MEDFORD language will be informed by principled user studies in scientific communities with different needs. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

NSF

Many researchers across a myriad of scientific domains generate and analyze data. In order to make this data reproducible and reusable, it is important to also include metadata describing the context for the data. However, most current schemas for reading and writing metadata are optimized for machine use rather than directly accessible to citizens or scientists who are not expert programmers or data technicians. This project involves developing a toolset and a language, MEDFORD, that provides an easy and accessible structured approach for researchers who are not expert programmers to create metadata in a form that is easily human readable and writable. This metadata is then structured enough to be easily translated into popular metadata standards and included in databases that are FAIR (Findable, Accessible, Interoperable, and Reusable). The MEDFORD language and supporting toolbox will be tested for usability with scientists, students, and members of the general public across several scientific domains, including marine biologists studying coral reefs, and biologists studying the animal hosts of tick-borne diseases. The involvement of scientific experts in the collection and analysis of the metadata than accompanies the complex scientific data is crucial; however, many of the recommended practices and processes focused on making these data FAIR (findable, accessible, interoperable, and reusable), as well as replicable and reproducible, can be cumbersome and difficult to implement, particularly for users that are not experts in computer science. This project posits that increasing the widespread community adoption of processes around efficient, robust, trustworthy, and FAIR data and metadata will require a new focus on making these data easily human-readable, writable, and correctable, in addition to all the valuable past effort that continues to go into making them easy for machines and database systems to ingest, validate, and parse. Thus it is focusing on a critical but under-served piece of the problem of frictionless FAIR data and metadata collection for science. The proposed solution involves inserting an intermediate layer between unstructured human annotation and existing machine-parsable metadata standards - the MEDFORD language and parser. Further development of the MEDFORD language will be informed by principled user studies in scientific communities with different needs. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

NSF

This project will study data management practices at user facilities with the goal of improving how research data is organized, stored, and shared. User facilities represent a major investment from NSF and each one has unique data formats and cyberinfrastructure. The project will target selected NSF Major and mid-scale facilities to examine current practices in order to create a roadmap aligned with FAIR principles that facilities can use for improvements in data management and to support open science and improve the national research infrastructure ecosystem. Current data management practices at selected user facilities will be assessed through surveys of the facility personnel and of the facilities' users. The assessment will include topics relevant to the FAIR principles, including data provenance, transfer, packaging, and storage, as well as how data is enriched and deposited for dissemination and citation. Best practices and data formats will be identified, and a roadmap will be created. The roadmap will be shared publicly for feedback through community-building workshops, and elements will be evaluated with hands-on pilot projects at the surveyed facilities. The findings are expected to be useful not only to the surveyed facilities, but to other user facilities and research facilities broadly for assessing and improving their data infrastructure. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

NSF

This project will study data management practices at user facilities with the goal of improving how research data is organized, stored, and shared. User facilities represent a major investment from NSF and each one has unique data formats and cyberinfrastructure. The project will target selected NSF Major and mid-scale facilities to examine current practices in order to create a roadmap aligned with FAIR principles that facilities can use for improvements in data management and to support open science and improve the national research infrastructure ecosystem. Current data management practices at selected user facilities will be assessed through surveys of the facility personnel and of the facilities' users. The assessment will include topics relevant to the FAIR principles, including data provenance, transfer, packaging, and storage, as well as how data is enriched and deposited for dissemination and citation. Best practices and data formats will be identified, and a roadmap will be created. The roadmap will be shared publicly for feedback through community-building workshops, and elements will be evaluated with hands-on pilot projects at the surveyed facilities. The findings are expected to be useful not only to the surveyed facilities, but to other user facilities and research facilities broadly for assessing and improving their data infrastructure. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

NSF

Collaborative Research: CS2: A Comprehensive Pipeline for Formal Verification of Floating-Point Errors and Compilation for Scientific Computing

NSF

Collaborative Research: CS2: DANUBE: Formal Methods for Scientific Computing Bridging the Data-Numerics Behavior Tug-of-War

NSF

Computer simulations are central to science and engineering activities across tasks as varied as weather prediction and electrical grid optimization. Simulation relies on numerical solvers whose continued improvements in terms of speed and accuracy are of pivotal national importance. Unfortunately, the progress of solvers is hampered by two emerging challenges: (1) the problems being modeled and solved, including their data captured through matrices, are becoming numerically harder, causing many solvers to fail; (2) newer arithmetic hardware, increasingly second-purposed from those developed to support artificial intelligence (AI), ends up having suboptimal precision while also deviating from established numerical standards. The project's novelties are: (1) the development of practical formal methods that are capable of capturing the correctness expectations of numerical algorithm designers as formal requirements; (2) the development of formal models capable of modeling non-standard hardware while bridging their behavioral differences to present uniform higher level formal abstractions; and (3) methods to carry out end-to-end correctness verification that help establish that the formal models of the underlying hardware meet the numerical algorithm correctness requirements. The project's contributions will help advance the nation's simulation-based scientific exploration capabilities. It will also help recoup the investments already made in today's numerical solvers, allowing them to be easily and reliably adapted to new problems and hardware. Without these capabilities, scientific computing and data-enabled discoveries can experience multiple productivity gaps, negatively impacting scientific research and engineering advances. The project will also train students to have the debugging skills necessary to solve numerical issues arising in the context of future solver design and deployment. This project handles data hardness using iterative refinement algorithms that are followed by the linear algebra routines underlying linear solvers. These algorithms can be verifiably guarded by novel formal properties that stem from how the problem eigenvalues appear in the problem’s data matrices. This project's techniques adapt the numerical hardware to pre-existing solvers (and their assumptions) and help develop new solvers that employ mixed numerical precision schemes during iterative refinement. These adaptations will be aided by novel emulation schemes that help match and formally verify numerical precision, rounding rules, and floating-point exception handling rules. The goals of these techniques are to resolve the "Data/Numerics Tug of War" so that each solver developer obtains their preferred starting point: from algorithms down to hardware or vice-versa. This project will contribute key scientific principles and algorithms to support future research and development activities in adapting solvers to newer hardware. It will have a broad impact, including (1) sustain established solvers across new generations of hardware and (2) solve numerical issues that arise when solvers and optimizers used in AI are enhanced to handle larger scale and newer problems. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.