Applications and Challenges of Artificial Intelligence in Space Missions

Oche, Paul A.; Ewa, Gideon A.; Ibekwe, Nwanneka

doi:10.1109/access.2021.3132500

Cited by 15 publications

(6 citation statements)

References 219 publications

(235 reference statements)

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“…With advancements in Artificial Intelligence (AI) and Machine Learning (ML) [34], there is also an unprecedented opportunity to enhance the optimization of propulsion systems for space missions, and further conceptualize the proposed framework. These technologies can be leveraged to dynamically adjust propulsion strategies in response to real-time data and evolving mission conditions, thereby improving the efficiency and mission adaptability.…”

Section: Ai and ML Techniques In Propulsion Optimizationmentioning

confidence: 99%

Optimizing Propellant Distribution for Interorbital Transfers

De Curtò,

De Zarzà

2024

Mathematics

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The advent of space exploration missions, especially those aimed at establishing a sustainable presence on the Moon and beyond, necessitates the development of efficient propulsion and mission planning techniques. This study presents a comprehensive analysis of chemical and electric propulsion systems for spacecraft, focusing on optimizing propellant distribution for missions involving transfers from Low-Earth Orbit (LEO) to Geostationary Orbit (GEO) and the Lunar surface. Using mathematical modeling and optimization algorithms, we calculate the delta-v requirements for key mission segments and determine the propellant mass required for each propulsion method. The results highlight the trade-offs between the high thrust of chemical propulsion and the high specific impulse of electric propulsion. An optimization model is developed to minimize the total propellant mass, considering a hybrid approach that leverages the advantages of both propulsion types. This research contributes to the field of aerospace engineering by providing insights into propulsion system selection and mission planning for future exploration missions to the Moon, Mars, and Venus.

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Section: Ai and ML Techniques In Propulsion Optimizationmentioning

confidence: 99%

Optimizing Propellant Distribution for Interorbital Transfers

De Curtò,

De Zarzà

2024

Mathematics

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“…The transfer of high-quality visual information from space to Earth may experience latency issues because of restricted bandwidth, which could delay timely medical assessment and intervention [ 57 ]. Recent advancements in AI have the potential to significantly improve the diagnostic capabilities in spaceflight [ 58 ]. AI algorithms can process large amounts of medical data quickly and accurately, allowing for the detection of subtle changes in ocular anatomy that could indicate the development of SANS.…”

Section: Introduction To Artificial Intelligence-based Diagnosis In O...mentioning

confidence: 99%

Artificial Intelligence Frameworks to Detect and Investigate the Pathophysiology of Spaceflight Associated Neuro-Ocular Syndrome (SANS)

Ong,

Waisberg,

Masalkhi

et al. 2023

Brain Sciences

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Spaceflight associated neuro-ocular syndrome (SANS) is a unique phenomenon that has been observed in astronauts who have undergone long-duration spaceflight (LDSF). The syndrome is characterized by distinct imaging and clinical findings including optic disc edema, hyperopic refractive shift, posterior globe flattening, and choroidal folds. SANS serves a large barrier to planetary spaceflight such as a mission to Mars and has been noted by the National Aeronautics and Space Administration (NASA) as a high risk based on its likelihood to occur and its severity to human health and mission performance. While it is a large barrier to future spaceflight, the underlying etiology of SANS is not well understood. Current ophthalmic imaging onboard the International Space Station (ISS) has provided further insights into SANS. However, the spaceflight environment presents with unique challenges and limitations to further understand this microgravity-induced phenomenon. The advent of artificial intelligence (AI) has revolutionized the field of imaging in ophthalmology, particularly in detection and monitoring. In this manuscript, we describe the current hypothesized pathophysiology of SANS and the medical diagnostic limitations during spaceflight to further understand its pathogenesis. We then introduce and describe various AI frameworks that can be applied to ophthalmic imaging onboard the ISS to further understand SANS including supervised/unsupervised learning, generative adversarial networks, and transfer learning. We conclude by describing current research in this area to further understand SANS with the goal of enabling deeper insights into SANS and safer spaceflight for future missions.

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“…We are living in the information age and experiencing the emergence of artificial intelligence for diverse fields such as academic works, [1] the design of new drugs, [2] or space exploration. [3] Although the adequate use of these technologies is still under debate, [4] there are not many doubts that the paradigm of future society will include very sophisticated computers. Even though silicon-based devices played a central role in computer science, novel, and innovative systems combining higher processing DOI: 10.1002/adom.202301058 performance with low energy and capital costs will perhaps require bottomup nanotechnology, exploiting atoms and molecules as the building blocks.…”

Section: Introductionmentioning

confidence: 99%

Designing Next‐Generation Molecular Logic Circuits: Photonic Concatenation in Upconverting Nanocrystals

Zanella,

Hernández‐Rodríguez,

et al. 2023

Advanced Optical Materials

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Computers and computing systems are getting an increasingly essential role in society, as revealed by the current emergence of Artificial Intelligence. The further increase in computer systems and digitalization of society will certainly demand innovative computing systems with higher processing speeds at low energetic and capital costs. Remarkable developments in the last five years have been reported for quantum computing; nevertheless, photonic and molecular computing has also been evolving with the potential of reaching the maximum possible miniaturization by using molecules as building blocks for basilar logic systems. One of the main challenges for molecular logic is the logical connection between molecular elements, called concatenation. Until now, concatenation of molecular logic gates has been exclusively reported using chemical species, with obvious practical limitations. In this work, the first photonic concatenation of a NAND with an AND molecular logic gate is presented. The logic system is implemented on nanoplatforms of Yb3+/Er3+ core@shell Sr2YF7 nanocrystals that are used to define combinatory logic gates and temperature‐reconfigurable logic systems. The results show that upconverting nanocrystals are promising platforms for the development of solid‐state molecular logic devices. These devices can reproduce the logical operations that are currently implemented in electronic devices.

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Applications and Challenges of Artificial Intelligence in Space Missions

Cited by 15 publications

References 219 publications

Optimizing Propellant Distribution for Interorbital Transfers

Optimizing Propellant Distribution for Interorbital Transfers

Artificial Intelligence Frameworks to Detect and Investigate the Pathophysiology of Spaceflight Associated Neuro-Ocular Syndrome (SANS)

Designing Next‐Generation Molecular Logic Circuits: Photonic Concatenation in Upconverting Nanocrystals

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